Title of Invention

A PROCESS FOR PREPARING A CONJUGATE VACCINE

Abstract The invention relates to a process for preparing a conjugate comprising combining an amino-oxy homofunctional or heterofunctional reagent with an entity chosen from polysaccharides, oligosaccharides, carbohydrates, and carbohydrate-containing molecules containing at least one carbonyl group, to form a polysaccharide, oligosaccharide, carbohydrate, or carbohydrate-containing molecule functionalized via at least one oxime linkage. The functionalized compound is then reacted either directly or indirectly with a protein moiety to form a protein-carbohydrate conjugate that may be used as a vaccine.
Full Text Use of Amino-Oxy Functional Groups in the Preparation of Vaccines
This application claims benefit of priority of U.S. Provisional Application
Nos. 60/539,573 filed January 29, 2004, and 60/589,019, filed July 20, 2004.
Background of the invention
The present invention relates to a process of covalently linking proteins and
polysaccharides to form conjugate vaccines comprising a reaction between
carbonyl-containing groups and amino-oxy functional groups.
In the process of vaccination, medical science uses the body's innate ability
to protect itself against invading agents by immunizing the body with antigens that
will not cause the disease but will stimulate the formation of antibodies that will
protect against the disease. For example, dead organisms are injected to protect
against bacterial diseases such as typhoid fever and whooping cough, toxoids are
injected to protect against tetanus and diptheria, and attenuated organisms are
injected to protect against viral diseases such as poliomyelitis and measles.
It is not always possible, however, to stimulate antibody formation merely
by injecting the foreign agent. The vaccine preparation must be immunogenic,
that is, it must be able to induce an immune response. Certain agents such as
tetanus toxoid can innately trigger the immune response, and may be
administered in vaccines without modification. Other important agents are not
immunogenic, however, and must be converted into immunogenic molecules or
constructs before they can induce the immune response.
The immune response is a complex series of reactions that can generally
be described as follows: (1) the antigen enters the body and encounters antigen-
presenting cells that process the antigen and retain fragments of the antigen on
their surfaces; (2) the antigen fragments retained on the antigen-presenting cells
are recognized by T cells that provide help to B cells; and (3) the B cells are

stimulated to proliferate and divide into antibody forming cells that secrete
antibody against the antigen.
Most antigens only elicit antibodies with assistance from the T cells and,
hence, are known as T-dependent (TD). Examples of such T-dependent antigens
are tetanus and diphtheria toxoids.
Some antigens, such as polysaccharides, cannot be properly processed by
antigen presenting cells and are not recognized by T cells. These antigens do not
require T cell assistance to elicit antibody formation but can activate B cells
directly and, hence, are known as T-independent antigens (Tl). Such T-
independent antigens include H. influenzae type b polyribosyl-ribitol-phosphate
(PRP) and pneumococcal capsular polysaccharides.
There are other differences between T-independent and T-dependent
antigens.
A) T-dependent antigens, but not T-independent antigens, can prime an
immune response so that a memory response results on secondary challenge
with the same antigen.
B) The affinity of the antibody for antigen increases with time after
immunization with T-dependent, but not T-independent antigens.
C) T-dependent antigens stimulate an immature or neonatal immune
system more effectively than T-independent antigens.
D) T-dependent antigens usually stimulate IgM, lgG1, lgG2a, and IgE
antibodies, while T-independent antigens stimulate IgM, lgG1, lgG2b, and lgG3
antibodies.
T-dependent antigens can stimulate primary and secondary responses,
which are long-lived in both adult and in neonatal immune systems, but must
frequently be administered with adjuvants (substances that enhance the immune

response). Very small proteins, such as peptides, are rarely immunogenic, even
when administered with adjuvants.
T-independent antigens, such as polysaccharides, are able to stimulate
immune responses in the absence of adjuvants, but cannot stimulate high level or
prolonged antibody responses. They are also unable to stimulate an immature or
B cell defective immune system (Mond, J. J., Immunological Reviews, 64:99
(1982); Mosier, D. E. et al., J. Immunol., 119:1874 (1977)).
For T-independent antigens, it is desirable to provide protective immunity
against such antigens to children, especially against capsular polysaccharides
found on organisms such as H. influenzae, S. pneumoniae, and Neisseria
meningiditis.
One approach to enhance the immune response to T-independent antigens
involves conjugating polysaccharides such as H. influenzae PRP (Cruse, J. M.,
Lewis, R. E. Jr., eds., Conjugate Vaccines in Contributions to Microbiology and
Immunology, Vol. 10, (1989)), or oligosaccharide antigens (Anderson, P. W. et al.,
J. Immunol., 142:2464, (1989)) to a T-dependent antigen such as tetanus or
diphtheria toxoid. Recruitment of T cell help in this way has been shown to
provide enhanced immunity to many infants that have been immunized.
Protein-polysaccharide conjugate vaccines stimulate an anti-
polysaccharide antibody response in infants who are otherwise unable to respond
to the polysaccharide alone.
Conjugation of a protein and a polysaccharide may provide other
advantageous results. For example, Applicant has found that a
protein/polysaccharide conjugate may enhance the antibody response not only to
the polysaccharide component, but also to the protein component. This effect is
described, for example, in U.S. Patent No. 5,955,079. This effect also is
described in A. Lees, et al., Vaccine, 12(13): 1160 (1994).

Techniques have been developed to facilitate coupling of proteins and
polysaccharides. See, for example, Dick, W. E. et al., "Glyconjugates of Bacterial
Carbohydrate Antigens: A Survey and Consideration of Design and Preparation
Factors," Conjugate Vaccines (Eds. Cruse, et al.), p. 48 (1989). Many techniques
for activation of carbohydrates, however, are not suitable for use in aqueous
media because the activating or functional reagents are not stable in water. For
example, N,N'-carbonyldiimidazole, as described in Marburg et al., U.S. Patent
No. 4,695,624, must be used in organic media.
Homofunctional and heterofunctional vinylsulfone reagents have been used
to activate polysaccharides. The activated polysaccharides are reacted with a
protein, peptide, or hapten, under appropriate reaction conditions, to produce the
conjugate. This is described in more detail in U.S. Patent No. 6,309,646. Another
method for producing conjugate vaccines comprises mixing a uronium salt
reagent with a soluble first moiety, such as a polysaccharide or carbohydrate, and
combining therewith a second moiety, such as a protein, peptide, or carbohydrate,
to form the conjugate vaccine. This method is described in U.S. Patent No.
6,299,881.
Most carbohydrates must be activated before conjugation, and cyanogen
bromide (CNBr) is frequently the activating agent of choice. See, e.g., Chu et al.,
Inf. & Imm., 40:245 (1983). The first licensed conjugate vaccine was prepared
with CNBr to activate HIB PRP, which was then derivatized with adipic
dihydrazide and coupled to tetanus toxoid using a water-soluble carbodiimide.
The use of 1-cyano-4-(dimethylamino)-pyridinium tetrafluoroborate, also
called "CDAP," has been described for use in aqueous media to activate
polysaccharides. These activated polysaccharides may be directly or indirectly
coupled to proteins. The use of CDAP is described in, for example, U.S. Patent
No. 5,849,301 and in Lees, et al., "Activation of Soluble Polysaccharides with 1-

Cyano-4-Dimethylamino Pyridinium Tetrafluoroborate For Use in Protein-
Polysaccharide Conjugate Vaccines and Immunological Reagents," Vaccine,
14(3):190(1996).
To briefly summarize the CNBr-activation method, CNBr is reacted with the
carbohydrate at a high pH, typically a pH of 10 to 12. At this high pH, cyanate
esters are formed with the hydroxyl groups of the carbohydrate. These, in turn,
are reacted with a bifunctional reagent, commonly a diamine or a dihydrazide.
These derivatized carbohydrates may then be conjugated via the bifunctional
group. In certain limited cases, the cyanate esters may also be directly reacted to
protein.
The high pH is necessary to ionize the hydroxyl group because the reaction
requires the nucleophilic attack of the hydroxyl ion on the cyanate ion (CN~). As a
result, CNBr produces many side reactions, some of which add neo-antigens to
the polysaccharides. Wilcheck, M. et al., Affinity Chromatography. Meth.
Enzymol., 104:3-55 (1984). More importantly, many carbohydrates or moieties
such as Hib, PRP, and capsular polysaccharides from and pneumococcal type 6
and Neisseria meningitis A can be hydrolyzed or damaged by the high pH
necessary to perform the cyanogen bromide activation.
Another problem with the CNBr activation method is that the cyanate ester
formed is unstable at high pH and rapidly hydrolyzes, reducing the yield of
derivatized carbohydrate and, hence, the overall yield of carbohydrate conjugated
to protein. Many other nonproductive side reactions, such as those producing
carbamates and linear imidocarbonates, are promoted by the high pH. This effect
is described in Kohn et al., Anal. Biochem, 115:375 (1981). Moreover, CNBr itself
is highly unstable and spontaneously hydrolyzes at high pH, further reducing the
overall yield.

Protein-polysaccharide conjugate vaccines may also be formed via
reductive amination. In this method, aldehydes on the polysaccharide are reacted
with amines on the protein to form a reversible Schiff base. The Schiff base is
subsequently reduced to form a stable linkage between the amine and the
aldehyde. This process is beset by a number of problems. The formation of the
Schiff base is slow and inefficient, and the overall reaction is further impeded by
the large size of the two components (i.e., the polysaccharide and protein), which
need to be in close proximity with each other in order to react. In order to
overcome this problem, the polysaccharide is often broken down into
oligosaccharides prior to coupling.
The use of dimethylsulfoxide (DMSO) promotes the formation of the Schiff
base, but this organic solvent can harm the protein. Sometimes a multistep
protocol is used, in which a spacer group (e.g., hexane diamine or adipic
dihydrazide) is added to the polysaccharide via reductive amination, and this
spacer is subsequently ligated to the protein. Using a high concentration of the
spacer helps to force the reaction and increase the yield. Elevated temperatures
and prolonged reaction times are also used to promote the reaction. However,
these can also be detrimental to the protein and the polysaccharide. Furthermore,
as amines must be deprotonated to react with aldehydes, the Schiff base
formation usually requires the use of alkaline solutions, i.e., solutions at a pH >. 8.
Prolonged reactions at elevated temperature and pH can be detrimental to both
the protein and the polysaccharide. Furthermore, the reductive step, which
usually involves the use of cyanoborohydride or pyridine-boranes, can be
inefficient and deleterious to the protein. Also, these reagents can be hazardous
to work with in large quantities. A further limitation of the reductive amination
method is the highly random nature of the linkage sites between the protein and
the polysaccharide.

Accordingly, there remains a need in the art for an efficient and effective
process for preparing conjugate vaccines.
Summary of the Invention
One embodiment includes a process for preparing a conjugate vaccine,
comprising:
(a) reacting a first moiety containing at least one carbonyl-containing group
with at least one amino-oxy reagent to form at least one pendent functional group
on the first moiety, wherein the first moiety is chosen from polysaccharides,
oligosaccharides, carbohydrates, and carbohydrate-containing molecules;
(b) reacting the first moiety containing at least one pendent functional group
with a second moiety to form a composition comprising a conjugate, wherein the
second moiety is chosen from proteins, peptides, and haptens; and
(c) combining the conjugate with a pharmaceutically acceptable delivery
vehicle to form a conjugate vaccine.
Another embodiment includes a process for preparing a conjugate vaccine,
comprising:
(a) reacting a first moiety containing at least one pendent amino-oxy group
with a second moiety to form a composition comprising a conjugate,
(b) wherein the first moiety is chosen from polysaccharides,
oligosaccharides, carbohydrates, and carbohydrate-containing molecules, and the
second moiety is chosen from proteins, peptides, and haptens; and
(c) combining the conjugate with a pharmaceutically acceptable delivery
vehicle to form a conjugate vaccine.
Another embodiment includes a process for preparing a conjugate vaccine,
comprising:
(a) reacting a first moiety chosen from polysaccharides, oligosaccharides,
carbohydrates, and carbohydrate-containing molecules, with

(b) a second moiety reacted with at least one amino-oxy reagent, wherein
the second moiety is chosen from proteins, peptides, and haptens, to form a
composition comprising a conjugate; and
(c) combining the conjugate with a pharmaceutical^ acceptable delivery
vehicle to form a conjugate vaccine.
Yet another embodiment includes a process for preparing a conjugate
vaccine, comprising:
(a) reacting a first moiety with a second moiety containing at least one
pendent amino-oxy group to form a composition comprising a conjugate,
wherein the first moiety is chosen from polysaccharides, oligosaccharides,
carbohydrates, and carbohydrate-containing molecules, and the second moiety is
chosen from proteins, peptides, and haptens; and
(b) combining the conjugate with a pharmaceutically acceptable delivery
vehicle to form a conjugate vaccine.
A further embodiment includes a process for preparing a conjugate
vaccine, comprising:
(a) providing a first moiety chosen from polysaccharides, oligosaccharides,
carbohydrates, and carbohydrate-containing molecules;
(b) providing a second moiety chosen from N-terminal 1,2-aminoalcohols
which can be oxidized to contain at least one aldehyde group;
(c) functionalizing said second moiety with at least one amino-oxy reagent;
(d) reacting said first moiety with the functionalized second moiety to form
a composition comprising a conjugate; and
(e) combining the conjugate with a pharmaceutically acceptable delivery
vehicle to form a conjugate vaccine.
A further embodiment includes a process for preparing a conjugate
vaccine, comprising:

(a) reacting a first moiety containing at least one pendent amino-oxy
group, wherein the first moiety is chosen from polysaccharides, oligosaccharides,
carbohydrates, and carbohydrate-containing molecules;
(b) reacting the first moiety with a second moiety to form a composition
comprising a conjugate, wherein the second moiety is chosen from glycoproteins
containing at least one carbonyl group; and
(c) combining the conjugate with a pharmaceutically acceptable delivery
vehicle to form a composition comprising an conjugate vaccine.
Still another embodiment includes a process for preparing a conjugate
vaccine, comprising:
(a) reacting a first moiety chosen from polysaccharides, oligosaccharides,
carbohydrates, and carbohydrate-containing molecules with a second moiety
chosen from proteins, peptides, and haptens to form a composition comprising a
conjugate,
(b) wherein the first moiety contains at least one reducing end derivatized
with an amino-oxy reagent, and
(c) combining the conjugate with a pharmaceutically acceptable delivery
vehicle to form a conjugate vaccine.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is an SDS-page chromatogram showing a high degree of protein-
polysaccharide conjugation.
Figure 2 is an SDS-page chromatogram showing BSA-polysaccharide
conjugation.
Figure 3 shows the results of a resorcinol assay for protein and
carbohydrate of fractions eluting from an S-400HR™ (Pharmacia) gel filtration
column.

Figure 4 shows an SDS-PAGE chromatogram indicating the occurrence of
protein-polysaccharide conjugation.
Figures 5A-5D indicate the presence of higher molecular weight conjugates
of fractions eluting from an S-400HR™ (Pharmacia) gel filtration column.
Figure 6 is an SDS-PAGE chromatogram showing the presence of
conjugate fractions.
Figure 7 is a chromatogram comparing a conjugate with its unconjugated
components.
Figure 8 illustrates the results of an opsonic assay.
Definitions
Amino-oxy reagent refers to a reagent with the structure NH2-0-R. R can
be any group capable of bonding to the amino-oxy nitrogen. According to one
aspect of the disclosure, R is a functional group, e.g., an amine, thiol, or other
chemical group facilitating coupling to, e.g., a protein.
Conjugate means to chemically link or join together.
Functionalize means to add at least one group that facilitates further
reaction. Typical functional groups include amino-oxy, thiol, maleimide, halogen,
haloacyl, aldehyde, hydrazide, hydrazine, and carboxyl. Other functional groups
would be well known to the person of ordinary skill in the art and can be found
discussed in Hermanson, Bioconjugation Techniques.
Hapten refers to a small molecule such as a chemical entity that by itself is
not able to elict an antibody response, but can elicit an antibody response once it
is coupled to a carrier.
Homofunctional, when discussing an amino-oxy reagent, refers to a
reagent that has at least two amino-oxy functional groups. The homofunctional
agent may be homobifunctional or homomultifunctional, i.e., having two, three,
four or more amino-oxy functional groups.

Heterofunctional, when discussing an amino-oxy reagent, refers to a
reagent that has at least one amino-oxy functional group and at least one other
non-amino-oxy functional group. The heterofunctional agent may be
heterobifunctional or heteromultifunctional, i.e., having two, three, four or more
amino-oxy functional groups. It may also have more than one other non-amino-
oxy functional group, such as two, three, or four or more, of either the same type
or different types.
Moiety refers to one of the parts of a conjugate.
Pendent functional group refers to a functional group that is exists on or
is exposed on a molecule.
Spacer refers to an additional molecule that is used to indirectly couple the
first moiety to the second moiety.
Detailed Description of the Invention
A. Strategy for Conjugation
The present invention provides an alternative to prior art processes for
preparing conjugate vaccines. Specifically, the invention provides for new
methods of conjugating a first moiety to a second moiety, where the first moiety is
chosen from polysaccharides, oligosaccharides, carbohydrates, and
carbohydrate-containing molecules and the second moiety is chosen from
proteins, peptides, and haptens, and the conjugation proceeds using at least one
amino-oxy functional group.
There are a number of ways of reacting the first and second moiety within
the scope of the invention and each of these methods rely on using at least one
amino-oxy group in the process.
At least one amino-oxy reagent with one amino-oxy group may be reacted
with the first moiety to form a composition with at least one non-amino-oxy
pendent functional group.

At least one amino-oxy reagent with more than one amino-oxy group may
be reacted with the first moiety to form a composition with at least one amino-oxy
pendent functional group. In this embodiment, there may optionally additionally
be present at least one non-amino-oxy pendent functional group.
At least one amino-oxy reagent with one amino-oxy group may be reacted
with the second moiety to form a composition with at least one non-amino-oxy
pendent functional group.
At least one amino-oxy reagent with more than one amino-oxy group may
be reacted with the second moiety to form a composition with at least one amino-
oxy pendent functional group. In this embodiment, there may optionally
additionally be present at least one non-amino-oxy pendent functional group.
Thus, in this invention, at least one of the first moiety and the second
moiety will be reacted with an amino-oxy reagent, and will result in a composition
with at least one pendent functional group (at least one of an amino-oxy or non-
amino-oxy pendent functional group). It is possible to functionalize both the first
moiety and the second moiety according to any combination of strategies 1 or 2
(first moiety) and 3 or 4 (second moiety), as set forth immediately above. In
another embodiment, either the first moiety or the second moiety may be
functionalized.
The first moiety and the second moiety may then be conjugated together.
This conjugation may proceed directly, by linking the pendent functional group on
the first moiety directly to the second moiety. Alternatively, this conjugation may
proceed indirectly, by linking the pendent functional group on the first moiety to an
additional agent called a spacer, which is then linked to the second moiety.
Certainly, a similar strategy may be followed with a pendent functional group on
the second moiety, simply by reversing the positions of the first and second
moiety.

B. The First Moiety: Polysaccharide, Oligosaccharide, Carbohydrate,
and Carbohydrate-Containing Molecules
As used herein, "carbohydrate" means any soluble monosaccharide,
disaccharide, oligosaccharide, or polysaccharide. Examples of suitable
polysaccharides for use in the process of the invention include bacterial, fungal,
and viral polysaccharides. Soluble polysaccharides (i.e., polysaccharides present
in solution), such as water-soluble polysaccharides, are suitable for use in
accordance with the present invention. Specific examples of suitable
polysaccharides include Salmonella typhi V\ antigen; Neisseria meningiditis
polysaccharide C; and Pneumococcal polysaccharides, such as Pneumococcal
polysaccharide type 14
According to certain embodiments of the present invention, the
carbohydrate is naturally occurring, a semisynthetic, or a totally synthetic large
molecular weight molecule. According to one embodiment, at least one
carbohydrate-containing moiety is selected from E. coli polysaccharides, S.
aureus polysaccharides, dextran, carboxymethyl cellulose, agarose,
Pneumococcal polysaccharides (Pn), Ficoll, Cryptococcus neoformans,
Haemophilus influenzae PRP, P. aeroginosa, S. pneumoniae, Group A and B
streptococcus, N. meningitidis, and combinations thereof.
According to one embodiment, the carbohydrate-containing moiety is a
dextran. As used herein, "dextran" (dex) refers to a polysaccharide composed of
a single sugar, which may be obtained from any number of sources (e.g.,
Pharmacia). Another preferred carbohydrate-containing moiety is Ficoll, which is
an inert, semisynthetic, non-ionized, high molecular weight polymer. Additional
non-limiting examples of moieties that may be used in accordance with the
present invention include lipopolysaccharides ("LPS"), lipooligopolysaccharides
("LOS"), lipotechoic acid ("LTA"), deaceylated LPS, deaceylated LTA, delipidated

LPS, delipidated LTA, and related molecules. Generally, a carbohydrate-
containing molecule that has been coupled using reductive amination requires the
formation of an aldehyde moiety. In those instances, for example, these
aldehydes may also be coupled using amino-oxy chemistry described herein.
Reductive amination has been used to couple LPS and LOS, both of which
can be coupled using amino-oxy chemistry. Examples of coupling of LPS and
LOS using reductive amination chemistry may be found in Mieszala et al.,
Carbohydrate Research, 338:167 (2003); Jennings et al., Inf. & Immun., 43:407
(1984); and U.S. Patent No. 4,663,160.
C. The Second Moiety: Proteins, Peptides and Haptens
In accordance with the present invention, various different proteins can be
coupled to various different polysaccharides. The following list includes examples
of suitable proteins that may be used in accordance with the invention: viral
proteins, bacterial proteins, fungal proteins, parasitic proteins, animal proteins.
Glycoproteins from any of the above sources may also be used to form a
conjugate with the first moiety. Lipids, glycolipids, peptides, and haptens are also
suitable for use as a second moiety in this invention. Haptenated proteins, i.e.,
proteins derivatized with haptens, are also suitable for use as a second moiety in
this invention.
Specific proteins include tetanus toxoid (TT), pertussis toxoid (PT), bovine
serum albumin (BSA), lipoproteins, diptheria toxoid (DT), heat shock protein, T-
cell superantigens, protein D, CRM197, and bacterial outer-membrane protein. All
of these protein starting materials may be obtained commercially from biochemical
or pharmaceutical supply companies (e.g., American Tissue Type Collection in
Rockville, MD or Berna Laboratories of Florida) or may be prepared by standard
methodologies, such as those described in J. M. Cruse and R. E. Lewis (Eds.),

"Conjugate Vaccines in Contributions to Microbiology and Immunology", Vol. 10
(1989).
D. Methods for Functionalizing the First or Second Moiety with an
Amino-Oxy Group
The amino-oxy (also referred to as oxy-amine, amino-oxy, aminooxy, and
amino-oxy) functional group, NH2-0-R, has a lower pKa than the amines found on
proteins, and is nucleophilic at much lower pH. Amino-oxy groups react well with
carbonyl-containing groups, e.g., aldehydes and ketones, to form highly stable
oximes. The optimum pH for the reaction can range from 4 to 8, for example from
5 to 7. According to one aspect of the invention, the optimum pH is around 5.
Since oximes are stable, the reductive step in the reductive amination process,
discussed above, is optional. The high efficiency of the reaction may result in
shorter reaction times. Furthermore, it is possible to exert some control over the
reaction sites between the complementary reagents. By contrast, the reaction of
hydrazides and amines with groups such as, for example, ketones, is slower and
far less efficient.
The protein and polysaccharide are functionalized with complementary
oxime-forming groups, and reacted to form oxime-linked protein-polysaccharide
conjugate vaccines. According to one aspect of the invention, the protein is
directly linked to the polysaccharide.
According to one embodiment, there is provided a process comprising
combining an amino-oxy homofunctional or heterofunctional reagent with an entity
chosen from polysaccharides, oligosaccharides, carbohydrates, and
carbohydrate-containing molecules containing at least one carbonyl group, to form
a polysaccharide, oligosaccharide, carbohydrate, or carbohydrate-containing
molecule functionalized via at least one oxime linkage. Functionalized means to
add a group which facilitates further reaction, for example, thiol, carboxy, amino-

oxy, halogen, aldehydes, and the like. This embodiment may be illustrated by the
following non-limiting illustration ("Ps" denotes a polysaccharide):

R is a functional group, e.g., an amino-oxy, amine, thiol, or other chemical group,
such as those listed below, for facilitating coupling to the protein:

The at least one pendent functional group is then reacted directly or
indirectly with the protein moiety to yield a protein-polysaccharide conjugate.
According to another embodiment, the protein is functionalized with at least
one pendent amino-oxy group, which is subsequently reacted with a carbonyl
group on a polysaccharide, oligosaccharide, carbohydrate, or carbohydrate-
containing moiety. The carbonyl group is formed with, for example, sodium
periodate. For example, in the case of a polysaccharide, the functionalized
protein is reacted with the polysaccharide to form a protein-polysaccharide
conjugate. The following scheme illustrates a non-limiting aspect of this process:


Methods for functionalizing a protein with an amino-oxy group are known to
those of ordinary skill in the art. The protein can be functionalized with amino-oxy
groups chemically, enzymatically or by genetic engineering. Described herein are
methods for functionalizing the protein on either amines or carboxyl groups, and
for controlling the number of amino-oxy groups on the protein.
In yet another embodiment, the polysaccharide is functionalized with
pendent amino-oxy groups and subsequently reacted with a glycoprotein
containing carbonyl groups. These may be present, for example, by oxidizing the
carbohydrate on the glycoprotein. Aldehydes may be created by selective
oxidation of N-terminal serine or threonine.
In accordance with the present invention, for example when the
polysaccharide, oligosaccharide, carbohydrate, or carbohydrate-containing moiety
is functionalized with an amino-oxy group, the protein advantageously contains at
least one carbonyl group in the form of, e.g., a ketone or aldehyde moiety.
Aldehydes may be created on proteins containing an N-terminal serine or
threonine, and the resulting protein can be reacted with an amino-oxy reagent,

thus uniquely functionalizing the N-terminal. This monovalently-functionalized
protein can then be reacted directly, for example, with a carbonyl-containing
polysaccharide, if the amino-oxy reagent is homofunctional or indirectly, using
spacers. N-terminal serine or threonine can occur naturally, or be engineered into
a protein.
In the instances where the protein is functionalized with at least one amino-
oxy group, the polysaccharide, oligosaccharide, or carbohydrate contains at least
one carbonyl group. The carbonyl groups may be a natural part of the
polysaccharide structure, e.g., the reducing end of the polymer, or created, for
example, by oxidation. Reductive amination has been widely used to produce
protein-polysaccharide conjugates. As a result, means to produce carbonyl-
containing polysaccharides are well-known to those versed in the art.
Some polysaccharides contain a reducing sugar on their end, e.g., Hib
PRP and Neisseria PsC. These contain aldehydes as hemiacetals and can be
reacted with amino-oxy reagents. Additional aldehydes may be created by
specific degradation of the polysaccharide. General procedures are described in,
for example, Lindberg et al. "Specific Degradation of Polysaccharides - Adv in
Carbohydrate Chemistry and Biochemistry," Tipson et al., eds. Vol 31, pp. 185-
240 (Academic Press, 1975). For example, when PRP is oxidized with sodium
periodate, the polysaccharide chain is cleaved so as to produce oligosaccharides
with an aldehyde on each end.
Many other methods for creating aldehydes are known to those versed in
the art. For example Jennings et al., U.S. Patent No. 4,356,170 entitled
"Immunogenic Polysaccharide-Protein Conjugates"; Tai et al., U.S. Patent No.
5,425,946 entitled "Vaccines against Group C Neisseria Meningitidis"; Porro, U.S.
Patent No. 5,306,492 entitled "Oligosaccharide Conjugate Vaccines"; Yang et al.,
U.S. Patent No. 5,681,570 entitled "Immunogenic conjugate molecules";

Constantino et al., "Development and phase 1 clinical testing of a conjugate
vaccine against meningococcus A and C," Vaccine 10:691 (1992); Laferriere et
al., "The synthesis of Streptococcus pneumoniae polysaccharide-tetanus toxoid
conjugates and the effect of chain length on immunogenicity," Vaccine, 15:179
(1997).
In accordance with the present invention, it may be desirable to add
aldehyde moieties to proteins and/or polysaccharides. Those of ordinary skill in
the art will appreciate that there are many acceptable methods for doing so.
Suitable non-limiting examples of methods to add aldehydes to proteins and
polysaccharides include the following:
1. Hydroxyl groups are reacted with chlorohexanol dimethyl acetal in a
base, and the masked aldehyde is subsequently revealed by mild acid hydrolysis.
Dick et al., Conjugate Vaccines (Eds. Cruse, et al.), pp. 91-93 (1989).
Scheme A

2. Glucouronic lactone and sodium cyanoborohydride are used to
reductively aminate protein amines. Saponification is used to open the lactone.
The sugar is then oxidized to an aldehydes using sodium periodate.
Scheme B


3. A carboxylated carbohydrate, for example, glucuronic acid, galactaric
acid, glyceric acid, or tartaric acid is added to protein amines using a carbodiimide
reagent. The glycosylated protein is then oxidized to create aldehyde moieties
using sodium periodate.

Galactaric acid Glucuronic acid
4. Aldehydes can also be created via enzymatic oxidation, using suitable
oxidizing enzymes such as, for example, glucose oxidase, galactose oxidase, and
neuraminidase. For example, neuraminidase may be used to remove terminal
sialic acid, followed by galactose oxidase. (Hermanson, Bioconjugation
Techniques, p. 116-117).
5. Chemical addition of aldehydes to amines on proteins or
polysaccharides can be effected using succinimidyl-p-formyl benzoate or
succinimidyl-p-formylphenoxyacetate. These NHS esters of aldehydes react with
amines and result in the addition of an aldehyde.


6. Still another method uses the reaction of a bis-aldehyde (e.g.,
gluteraldehyde) with an amine. (Hermanson, Bioconjugation Techniques, p. 119-
120).
Scheme C

7. Another suitable process is the addition of glyceraldehydes to protein
amines using reductive amination, followed by oxidation with sodium periodate to
create aldehydes.
Optionally, if the conjugate contains residual free amino-oxy groups or
aldehydes, and if it is desired to quench these groups, an additional step may be
taken. One of the methods for quenching a conjugate having an aldehyde is by
reduction, e.g., using sodium borohydride. Alternatively, residual carbonyls may
be quenched with a mono amino-oxy reagent, e.g., amino-oxy-acetate. Residual
amino-oxy groups can be quenched with a monofunctionalcarbonyl, e.g.,
glyceraldehyde, acetone or succinic semialdehyde.
E. Amino-Oxy Reagents
The preparation of conjugate vaccines may be accomplished by the use of
various amino-oxy reagents. A variety of useful homofunctional and
heterofunctional amino-oxy reagents may be prepared by one skilled in the art,
and may also be obtained from Solulink, Inc.™, 9853 Pacific Heights Blvd., Suite
H, San Diego, California 92121, and still others are described in the literature.
Many more can be conceived of and easily synthesized. Toyokuni et al.,
"Synthesis of a new heterofunctional linker, N-[4-(amino-oxy)butyl]maleimide for

facile access to a thiol-reactive 18F-labeling agent." Bioconjugate Chem. 14:1253
(2003).
Suitable non-limiting examples of reagents that may be used in accordance
with the present invention include those prepared by Solulink™ (San Diego,
California). For example, bis(amino-oxy)cystamine is a homofunctional amino-
oxy-reagent that can be converted to a heterofunctional thiol-amino-oxy reagent.
"Boc" is the art-recognized acronym for the t-butoxy carbonyl protecting group.
Boc-amino-oxy acetate can be used to synthesize a number of suitable amino-oxy
reagents according to, for example, the following scheme:

The ligands identified by R" are suitable, non-limiting examples of
nucleophilic ligands that may be used in accordance with the present invention.
The above reagents are based on 2-(Boc-amino-oxy) acetic acid, available
from Bachem (Prod. No. A4605.005). Other useful starting reagents for making
amino-oxy reagents include N-Boc-hydroxylamine and N-Fmoc-hydroxylamine.
These reagents are available from Aldrich Chemical. N-Boc-Hydroxylamine can
be used to prepare a useful amino-oxy reagent as follows:


Homofunctional amino-oxy reagents may be used in accordance with the
present invention. Suitable homofunctional amino-oxy reagents that may be used
include, for example, bis(amino-oxy)ethylene diamine, bis(amino-oxy) butane, and
bis(amino-oxy)tetraethylene glycol, all of which are known and can be prepared by
art-recognized methods. For example, bis(amino-oxy)butane may be prepared as
follows:

Synthesis of various useful heterofunctional amino-oxy reagents have been
described in the literature, for example Mikolajczyk et al., Bioconjugate Chem.
5:636 (1994) (a maleimide-amino-oxy reagent); Mikola & Hanninen Bioconjugate
Chem. 3:182 (1992) (amino-oxy alklyamines); Webb & Kaneko Bioconjugate
Chem. 1:96 (1990) (amino-oxy- dithionitropyridyl reagents). Jones et al. describe
the synthesis of amino-oxy ethers from N-Boc hydroxylamine and alkyl iodides
and bromides, which provide another route to useful amino-oxy reagents. Dixon &
Weiss, J. Org Chem. 49:4487 (1984), describe bis-amino-oxy reagents that may
be used in accordance with the present invention.
Ketones may be added to amines using, for example, reagents like NHS
levulate (from Solulink™). Carbohydrate groups on a protein, e.g., glycoproteins,
can be oxidized to carbonyls with, for example, sodium periodate. In addition,
reverse proteolysis may be used to add carbonyls or amino-oxy groups as
described in Rose et al., "Preparation of well-defined protein conjugates using
enzyme-assisted reverse proteolysis," Bioconjugate Chem. 2:154 (1991). N-

terminal threonines or serines on proteins may be selectively oxidized to
aldehydes.
Small linker molecules may also be used to functionalize proteins and
polysaccharides with amino-oxy groups. See, for example, Vilaseca et al.,
"Protein conjugates of defined structure: synthesis and use of a new carrier
molecule," Bioconj. Chem. 4:515 (1993); and Jones et al., "Synthesis of UP 993,
a multivalent conjugate of the N-terminal domain of b2GPI and suppression of an
anti-b2GPI immune response," Bioconj. Chem. 12:1012 (2001).
As is known to those of ordinary skill in the art, amino-oxy, aminooxy,
aminoxy, and oxy-amine are all synonymous terms.
F. Indirect Conjugation
As stated above, the conjugation between the first moiety and the second
moiety may proceed either indirectly or directly. In certain instances, the process
of combining a protein and a polysaccharide may lead to undesirable side effects.
In some cases, direct coupling can place the protein and the polysaccharide in
very close proximity to one another and encourage the formation of excessive
crosslinks between the protein and the polysaccharide. Under the extreme of
such conditions, the resultant material can become very thick (e.g., in a gelled
state).
Over-crosslinking also can result in decreased immunogenicity of the
protein and polysaccharide components. In addition, the crosslinking process can
result in the introduction of foreign epitopes into the conjugate or can otherwise be
detrimental to production of a useful vaccine. The introduction of excessive
crosslinks exacerbates this problem.
Control of crosslinking between the protein and the polysaccharide can be
controlled by the number of active groups on each, concentration, pH, buffer

composition, temperature, the use of spacers and/or charge, and other means
well-known to those skilled in the art.
For example, a spacer may be provided between the protein and
polysaccharide in order to control the degree of crosslinking. The spacer helps
maintain physical separation between the protein and polysaccharide molecules,
and it can be used to limit the number of crosslinks between the protein and
polysaccharide. As an additional advantage, spacers also can be used to control
the structure of the resultant conjugate. If a conjugate does not have the correct
structure, problems can result that can adversely affect the immunogenicity of the
conjugate material. The speed of coupling, either too fast or too slow, also can
affect the overall yield, structure, and immunogenicity of the resulting conjugate
product. Schneerson etal., Journal of Experimental Medicine, 152:361 (1980).
G. Vaccine Compositions
This invention further relates to vaccines and other immunological reagents
that can be prepared from the conjugates produced by the method in accordance
with the invention. For example, to produce a vaccine or other immunological
reagent, the conjugates produced by the method according to the invention may
be combined with a pharmaceutically acceptable medium or delivery vehicle by
conventional techniques known to those skilled in the art. Such vaccines or
immunological reagents will contain an effective therapeutic amount of the
conjugate according to the invention, together with a suitable amount of vehicle so
as to provide the form for proper administration to the patient. These vaccines
may include alum or other adjuvants.
Exemplary pharmaceutically acceptable media or vehicles include, for
example, sterile liquids, such as water and oils, including those of petroleum,
animal, vegetable or synthetic origin, such as peanut oil, soybean oil, mineral oil,
sesame oil, and the like. Saline is a preferred vehicle when the pharmaceutical

composition is administered intravenously. Aqueous dextrose and glycerol
solutions can be employed as liquid vehicles, particularly for injectable solutions.
Suitable pharmaceutical vehicles are well known in the art, such as those
described in E. W. Martin, Remington's Pharmaceutical Sciences.
The vaccines that may be prepared in accordance with the invention
include, but are not limited, to Diphtheria vaccine; Pertussis (subunit) vaccine;
Tetanus vaccine; H. influenzae type b (polyribose phosphate); S. pneumoniae, all
serotypes; E. coli, endotoxin or J5 antigen (LPS, Lipid A, and Gentabiose); E. coli,
O polysaccharides (serotype specific); Klebsiella, polysaccharides (serotype
specific); S. aureus, types 5 and 8 (serotype specific and common protective
antigens); S. epidermidis, serotype polysaccharide I, II, and III (and common
protective antigens); N. meningitidis, serotype specific or protein antigens; Polio
vaccine; Mumps, measles, rubella vaccine; Respiratory syncytial virus; Rabies;
Hepatitis A, B, C, and others; Human immunodeficiency virus I and II (GP120,
GP41, GP160, p24, others); Herpes simplex types 1 and 2; CMV
(cytomegalovirus); EBV (Epstein-Barr virus); Varicella/Zoster; Malaria;
Tuberculosis; Candida albicans, other Candida; Pneumocystis carinii;
Mycoplasma; Influenzae viruses A and B; Adenovirus; Group A streptococcus,
Group B streptococcus, serotypes, la, lb, II, and III; Pseudomonas aeroginosa
(serotype specific); Rhinovirus; Parainfluenzae (types 1, 2, and 3); Coronaviruses;
Salmonella; Shigella; Rotavirus; Enteroviruses; Chlamydia trachomatis and
pneumoniae (TWAR); and Cryptococcus neoformans.
The invention also relates to the treatment of a patient by administering an
immunostimulatory amount of the vaccine. The term "patient" refers to any
subject for whom the treatment may be beneficial and includes mammals,
especially humans, horses, cows, pigs, sheep, deer, dogs, and cats, as well as
other animals, such as chickens. An "immunostimulatory amount" refers to that

amount of vaccine that is able to stimulate the immune response of the patient for
prevention, amelioration, or treatment of diseases. The vaccines of the invention
may be administered by any suitable route, but they preferably are administered
by intravenous, intramuscular, intranasal, or subcutaneous injection. For
example, carbohydrate-based vaccines can be used in cancer therapy.
In addition, the vaccines and immunological reagents according to the
invention can be administered for any suitable purpose, such as for therapeutic,
prophylactic, or diagnostic purposes.
The invention also relates to a method of preparing an immunotherapeutic
agent against infections caused by bacteria, viruses, parasites, fungi, or chemicals
by immunizing a patient with the vaccine described above so that the donor
produces antibodies directed against the vaccine. Antibodies may be isolated or
B cells may be obtained to later fuse with myeloma cells to make monoclonal
antibodies. The making of monoclonal antibodies is generally known in the art
(see Kohler et al., Nature, 256:495 (1975)). As used herein, "immunotherapeutic
agent" refers to a composition of antibodies that are directed against specific
immunogens for use in passive treatment of patients. A plasma donor is any
subject that is injected with a vaccine for the production of antibodies against the
immunogens contained in the vaccine.
EXAMPLES
Example 1: Preparation of an Amino-Oxy Functionalized Protein
The following example illustrates the preparation of an amino-oxy
functionalized protein that can be conjugated to a polysaccharide. Bovine serum
albumin (BSA) was used as a model protein.
Bis(amino-oxy)tetraethylene glycol was linked to carboxyl groups on bovine
serum albumin (BSA) with carbodiimide. Monomer BSA was prepared as
described in (Lees et al., Vaccine 14:190, 1996). Bis(amino-oxy)tetraethylene

glycol (85 mg) (prepared by Solulink™, MW 361) was made up in 850 ul of 0.5 M
HCI. 5 N NaOH was added to adjust to a pH -4.5. 1 ml of BSA mono (42.2
mg/ml in saline) was added. The reaction was initiated by the addition of 25 ul of
freshly prepared EDC (1-(3-dimethylamino)propyl)-3-ethylcarbodiimide
hydrochloride, 100 mg/ml in water). After approximately 3 hours, the solution was
dialyzed overnight against saline at 4°C. The solution was then made up to 4 ml
with saline and concentrated with an Amicon Ultra 4™ centrifugal device (30 kDa
cutoff) to -0.5 ml, and was further desalted on a 1x15 cm G-10 column
(Pharmacia) equilibrated with saline. The void volume fraction was then
concentrated to - 1ml using the Amicon Ultra 4™ device. Using the BCA assay
(Pierce Chemical Co), the protein concentration was estimated to be 34 mg/ml
BSA. Trinitrobenzene sulfonic acid assay gave an intense red/orange, indicating
the presence of amino-oxy group.
Example 2: Preparation of an Amino-Oxy Derivatized Polysaccharide
The following example illustrates the preparation of any amino-oxy
functionalized polysaccharide that can be conjugated to a protein, peptide, or
hapten.
Pn14 (10 ml at 5 mg/ml in water) was activated by the addition of 40 mg of
CDAP (100 mg/ml stock in acetonitrile), followed by triethylamine to raise the pH
to 9.4. After approximately 2.5 minutes, 4 ml of 0.5 M hexanediamine (pH 9.4)
was added. The reaction was permitted to proceed for about 2 hours. Excess
reagent was then removed by dialysis against saline to yield amino-Pn14.
Amino-Pn14 was then reacted with excess NHS bromoacetate at pH 8 and
dialyzed against saline in the dark at 4°C. The bromoacetylated Pn14 was
concentrated by pressure filtration and then dialyzed against water.
Amino-oxy cysteamine was prepared from bis amino-oxy cystamine by
TCEP reduction followed by ion exchange on a Dowex 1X-8 column as follows:

Bis(amino-oxy)cystamine (obtained from Solulink)was made up in 50%
NMP/water at 0.1 M. TCEP was made up in water at 0.5 M and 3x molar
equivalents of 1 M sodium bicarbonate was added. A 1.5 molar excess of TCEP
was combined with Bis(AO)cystamine, and adjusted to pH ~7 with sodium
carbonate. After 10 minutes, the mixture was diluted 5-fold into 10 mM bistris at
pH 5. The reaction mixture was applied to a 1x3 cm Dowex 1-x8 column that had
been washed with 1 M NaCI and equilibrated with 10 mM bistris, pH 5. The
reduced amino-oxy cysteamine is found in the flow through of the column.
Amino-oxy cysteamine was added to the bromoacetylated Pn14 and
reacted at pH 8 in the dark. The reaction mixture was then concentrated,
diafiltered, and then dialyzed against water.
Pn14 concentration was determined to be 9.1 mg/ml by the
resorcinol/sulfuric acid method. Using the TNBS assay and amino-oxy acetate as
the standard, the amino-oxy concentration was estimated at 0.74 mM, resulting in
about 8 amino-oxy groups per 100 kDa of polysaccharide.
Example 3: Preparation of a BSA-Dextran Conjugate
The following example illustrates the preparation of a conjugate vaccine
using an amino-oxy functionalized protein and an oxidized polysaccharide.
Specifically, the amino-oxy functionalized BSA prepared in Example 2 was linked
to oxidized dextran.
Dextran was oxidized using sodium periodate as follows: A 10 mg/ml
solution of T2000 dextran (Pharmacia) was made to 10 mM in sodium acetate, pH
5 and then 10 mM sodium periodate (from a 0.5 M stock in water), and incubated
at room temperature in the dark. At 1, 5, 10 and 15 min, an aliquot was removed,
quenched by the addition of glycerol, and dialyzed against water in the dark. The
final concentration of dextran was determined to be about 4.5 mg/ml.

The protein was conjugated to the polysaccharide as follows: 110 µl of
each oxidized dextran preparation (1-15 min oxidation) was combined with 15 µl
BSA- amino-oxy (0.5 mg each). After an overnight reaction in the dark at room
temperature, the samples were analyzed by SDS PAGE (4-12% gradient gel,
NuPAGE, Invitrogen). With reference to Figure 1, lanes are conjugates prepared
with (A) dex ox 1 min; (B) dex ox 5 min; (C) dex ox 10 min; (D) dex ox 15 min;
BSA- amino-oxy only. It is evident that each of the conjugation reactions resulted
in high molecular weight material that did not enter the gel. Essentially no
unconjugated protein is evident, indicating a high degree of conjugation.
The four conjugates were pooled & fractionated on a S-400HR™ gel
filtration column (1x60 cm), equilibrated with saline. The void volume fractions
were pooled and assayed for protein and polysaccharide. It was determined that
the pool contained 0.21 mg/ml BSA and 0.27 mg/ml dextran. At least 50% of the
initial protein and polysaccharide were recovered. Thus, the amino-oxy-protein
with oxidized polysaccharide yielded soluble conjugate in excellent yield.
Example 4: Preparation of AO-Functionalized TT.
The following hypothetical example illustrates the preparation of Tetanus
toxoid derivatized with amino-oxy groups using a two-step method.
1 ml tetanus toxoid (10 mg/ml) in 2 M NaCI is made to pH 8 by the addition
of 50 µl 1 M HEPES, pH 8. The protein is bromoacetylated by the addition of 7 µl
of 0.1 M NHS bromoacetate. After a 1 hour incubation, 2 µmoles of
aminocysteamine is added. After an overnight reaction, excess reagent is
removed by dialysis against 2 M NaCI.
The protein concentration is determined using the BCA assay (Pierce
Chemical) and the presence of the amino-oxy group confirmed using TNBS.

Example 5: Preparation of amino-oxy-derivatized BSA using a two-step
method
Bromoacetylation of BSA:
4.1 ml of monomeric BSA (48.5 mg/ml) was made to pH 8 by the addition
of 400 µl 1 M HEPES, pH 8 and 5.5 ml water. 1 ml of 0.2 M NHS bromoacetate
(ProChem) in NMP was slowly added while vortexing. After an overnight reaction
at room temperature in the dark, the solution was dialyzed against saline for 2
days, centrifuged and filtered. 10.6 ml of BSA at 15.3 mg/ml was obtained.
Preparation of Amino-oxy cysteamine:
51.5 mg of Bisaminoxocystamine was added to a solution of 56 mg TCEP
made up in 1.1 ml 1 M sodium carbonate, 586 µl DMSO, and 586 µl water. After
15 minutes, the TCEP was removed on a 1x5 cm Dowex 1x-8 column,
equilibrated with 10 mM Bistris, pH 6. The DTNB positive flow thru was pooled
and found to be 22.6 mM thiol.
6 ml was added to the bromoacetylated BSA and the pH adjusted to 8. The
reaction was allowed to proceed overnight in the dark, and was then dialyzed for 2
days at 4° C against multiple changes of saline. The amino-oxy BSA was
determined to be about 8.6 mg/ml. Reaction of an aliquot with TNBS at pH 8 gave
an orangish color, indicating the presence of the amino-oxy group.
Example 6: Use of CDAP to Prepare Amino-Oxy Derivatized
Polysaccharide and Amino-oxy Conjugates
This experiment illustrates the use of CDAP to prepare amino-oxy
derivatized polysaccharide and amino-oxy conjugates. It illustrates how chemistry
other than oxidation can be used to functionalize a polysaccharide with amino-oxy
groups.

I. Preparation of an amino-oxy derivatized polysaccharide using CDAP
chemistry
A solution of bifunctional amino-oxy reagent was prepared by solubilizing
29 mg of bis-amino-oxy acetate (ethylene diamine) (prepared by Solulink™) in
200 µl 1 M NaAc, pH 5. Dextran was activated using CDAP chemistry as follows.
To a solution of 0.5 ml T2000 dextran at 10 mg/ml in water, 25 ul of CDAP
(100mg/ml acetonitrile) was added and 30 seconds later the pH was raised by the
addition of 25 pi 0.2 M triethylamine (TEA) and three 5 µl of TEA neat.
At 2.5 minutes, the pH was reduced by the addition of 100 µl 1 M NaAc, pH
5. 200 µl of the BisAO solution was then added. After ~30 minutes reaction, the
solution was desalted on a 1 x 15 cm P6DG column (BioRad) equilibrated with
NaAc buffer (10 mM NaAc, 150 mM NaCI, 5 mM EDTA, pH 5). The desalted
polysaccharide was estimated at 1.7 mg/ml dextran, using the resorcinol assay,
and about 11 amino-oxy groups/100 kDa dex using a TNBS assay.
II. Preparation of oxidized ovalbumin
To a 0.4 ml solution of ovalbumin (14.4 mg) (OVA), 10 µl of 1 M sodium
acetate, pH 5 was added, followed by the addition of 10 µl 0.5 M sodium periodate
(in water). After a 15 minutes incubation at room temperature in the dark, the
reaction was quenched with the addition of a few drops of 50% glycerol. The
reaction mixture was then dialyzed in the dark against NaAc buffer. By adsorption
at 280 nm, the concentration of oxidized ovalbumin ("OVA(ox)") was 6.6 mg/ml.
III. Preparation of conjugates and controls
The following solutions were prepared and each was incubated overnight at
room temperature in the dark:
A. 500 µl Dex AO (0.85 mg) + 75 µl OVA(ox) + 100 µl 1 M NaAc pH 5.
B. 250 µl Dex AO (0.0.43 mg) + 37.5 µl NaAc buffer + 50 µl 1 M NaAc
C. 250 µl NaAc buffer + 37.5 µl OVA(ox) + 50 µl 1 M NaAc.

Each was then assayed by SDS PAGE and SEC HPLC. Only sample A
contained high molecular weight (HMW) material, with ~ 20% of protein
conjugated, as estimated by SEC HPLC. Neither B nor C indicated any HMW
material by SEC HPLC or SDS PAGE.
Example 7: Use of Cyanogen Bromide to Label Polysaccharide with a Bis-
Amino-Oxy Reagent.
This prophetic example demonstrates the derivatization of a polysaccharide
with an amino-oxy reagent using cyanogen bromide (CNBr).
Polysaccharide (e.g., Pn-14) is made up at 10 mg/ml in water, and is
treated with CNBr at 1 mg per mg of polysaccharide at pH 10.5 for 6 minutes in a
pH-stat. The reaction mixture is then reduced to ~pH 7 by the addition of 0.5 M
bis-amino-oxy reagent (e.g., bis-AO(EDA). After an overnight reaction, the
solution is dialyzed into water and assayed for amino-oxy groups with TNBS, and
for carbohydrates with the resorcinol assay. This amino-oxy derivatized
polysaccharide is used for conjugation with a carbonyl-containing protein.
According to another embodiment, the CNBr-activated polysaccharide can
be reacted with amino-oxy acetate. This will result in a polysaccharide
functionalized with carboxyl groups. The carboxyl groups can then be further
functionalized and indirectly or directly linked to proteins (with, for example,
carbodiimide).
Example 8: Conjugation of Amino-Oxy Derivatized Protein with
Oxidized Polysaccharide
This example illustrates the preparation of amino-oxy derivatized protein
with the functionalization occuring on the amines. This amino-oxy derivatized
protein is then covalently linked to the clinically relevant polysaccharides Neisseria
meningididis A and C.

I. Functionalization of protein with amino-oxy groups of a protein on its
amines (protein with pendent amino-oxy groups on amines)
Amines on the protein are bromoacetylated and then reacted with a thiol-
amino-oxy reagent to produce a protein with pendent amino-oxy groups.
Bis(amino-oxy acetate)cystamine 2HCI was prepared by Solulink.™ Monomeric
BSA was at 42.2 mg/ml. NHS bromoacetate was obtained from Prochem and
made up at 0.1 M in NMP (N-methyl-2-pyrrolidone). The amino-oxy protein was
prepared as follows. In each of 2 tubes, a solution of 0.5 ml of BSA (21.1 mg) and
250 ul H2O + 100 µl 1 M HEPES, pH 8 was prepared. One tube was reacted with
a 30 fold molar excess of NHS bromoacetate (93 pi) and the other at a 10 fold
molar excess (31 µl).
After about 1 hr, each was made up to 15 ml with sodium acetate buffer (10
mM NaAc, 0.15 M NaCI, 5 mM EDTA, pH 5) and concentrated to about 200 pi
using an Amicon Ultra 15™ device (30 kDa cutoff).
Amino-oxy acetate cysteamine was prepared as follows:
To a solution of 9.8 mg of Bis(AOAc)cystamine (prepared by Solulink™) in
114 Ml 1 M sodium acetate + 114 µl NMP, 22.8 µl of 0.25 M TCEP in 1 M HEPES,
pH 8 was added as a reducing agent. After 1 hour, the partially reduced amino-
oxy thiol reagent was added to each of the bromoacetylated BSA preparations,
the pH was adjusted to about pH 8 and the reaction allowed to proceed overnight
in the dark at 4°C.
Each was desalted using the Amicon Ultra 15™ device by making volume
up to 15 ml with NaAc buffer and centrifuging. The desalting process was
repeated four times. The final volume was about 200 pi and was then made up to
about 1 ml with NaAc buffer. This product was termed BSA-S-AO. By
adsorbance at 280 nm, the 30x prep was determined to be 29.8 mg/ml and the
10x prep 24.8 mg/ml.

II. Preparation of oxidized Neisseria meninqiditis polysaccharide A and C
(Neiss PsA and Neiss PsC)
Neiss PsA and PsC were solubilized overnight at room temperature at 10
mg/ml in water and then stored at 4°C. 50 ul of 1 M sodium acetate, pH 5, was
added to 1 ml of each polysaccharide solution, followed by the addition of 25 pi
0.5 M sodium periodate (0.5 M in water). After 10 minutes in the dark at room
temperature, each was dialyzed 4 hours against 4 I water. Each was then made
up to 4 ml with water and further desalted using an Amicon Ultra 4™ device (30
kDa cutoff). Using the resorcinol assay, the oxidized Neiss PsA was determined
to be 12.1 mg/ml and the oxidized Neiss PsC was 17.8 mg/ml.
III. Conjugation of BSA-S-AQ with oxidized Neiss PsA and PsC
The following mixtures of BSA-S-AO and oxidized PsA and PsC were
prepared.

After an overnight reaction at room temperature in the dark, conjugates
were assayed by SDS PAGE using a Phast gel (8-25%)(Pharmacia) under
reducing conditions. With reference to Figure 2, from left to right the lanes are
BSA30x-PsA, BSA30x-PsC, BSA30x, BSA10x-PsA, BSA10x-PsC, BSA10x. It is
seen that there is a significant amount of high molecular weight materials that did
not enter the gel, indicating that conjugation of the protein to the polysaccharide
occurred.

The PsA conjugates were pooled and fractionated by gel filtration on a S-
400HR column (1x60 cm, Pharmacia), equilibrated with saline. Similarly, the PsC
conjugates were pooled and fractionated. Approximately 1 ml fractions were
collected and assayed for protein (by absorbance) and for carbohydrate using the
resorcinol assay. The results are provided in Figure 3.
For the PsC conjugate, tubes 18-22 were pooled and for the PsA
conjugate, tubes 19-23 were pooled and examined by SDS PAGE using reducing
conditions.
With reference to Figure 4, the BSA-Neiss PsC conjugate is on the left and
the PsA conjugate is next to it. On the right is the molecular weight standard. A
small amount of free BSA is observed in each, indicating incomplete separation of
the conjugated and free protein. Each contains a significant amount of conjugated
high molecular weight material that did enter the gel.
Example 9: Preparation of (BSA-Levulate)-Amino-Oxy-Pn14 Conjugate
This example illustrates the reaction of an amino-oxy group with a ketone
and shows that this can be used for the formation of conjugates and, more
specifically, the preparation of (BSA-Levulate)-Amino-oxy Pn14.
NHS Levulate was obtained from Solulink and made up by solubilizing 5.1
mg in 100 µl NMP. This was slowly added to a vortexed solution of 200 pi BSA at
48.5 mg/ml, 200 µl water, and 100 µl 1 M HEPES, pH 8. After an overnight
reaction, the mixture was diafiltered using an Amicon Ultra 15 device, (30 kDa
cutoff). The final volume was 0.5 ml. This product is BSA-LEV
100 µl of BSA-LEV was combined with 300 µl of amino-oxy Pn14 (4.5
mg/ml Pn14) and incubated for several days in the dark. The conjugate and the
individual components were assayed by SEC HPLC using a Superose 6 column
(Pharmacia). The conjugate was then fractionated on an S400HR column.
Protein was assayed using the Bradford dye method, and polysaccharide with the

resorcinol method. The high molecular weight fraction was found to contain 0.6
mg BSA/mg Pn14.
Example 10: Preparation of Amino-oxy-BSA- Neisseria PsC Conjugate
Neiss PsC was oxidized to create terminal aldehyde as generally
described in Jennings & Lugowski J. Imm. 127:1011 (1981). SEC HPLC indicated
the molecular weight of the PsC was significantly reduced.
After overnight conjugation of PsC and BSA-AO, analysis was conducted
via SEC HPLC Superose 6 0.5 ml/min. The conjugate was fractionated on a
1x60cm S200HR column, equilibrated 10 mM sodium acetate, 150 mM NaCI, 2
mM EDTA, pH 5. It was determined by both SEC analysis and gel filtration that
most of BSA was conjugated. The high molecular weight peak was analyzed for
protein and carbohydrate and determined to contain 0.2 mg BSA/mg PsC.
Example 11: Preparation of amino-oxy-BSA - Neisseria PsA conjugate
This example illustrates the preparation of a Neisseria PsA-BSA conjugate
by way of functionalizing the protein with an amino-oxy group.
Neiss PsA was terminally reduced to an alditol with NaBH4 and then
oxidized to create terminal aldehyde as generally described in Jennings &
Lugowski J. Imm. 127:1011 (1981).
Neisseria PsA was solubilized in water at 20 mg/ml for 15 min. To 1 ml of
the solubilized polysaccharide, 10 mg of sodium borohydride was added. The pH
was maintained to about 8-9. After 1 hour, 100 µl of 1 M NaAc was added, and
the pH was adjusted to 5. The reduced PsA was desalted on a 1x15 cm G10
column, equilibrated with saline, and the void volume fraction concentrated with
an Amicon Ultra 4(10 kDa cutoff device) to about 1 ml. 20 mg of solid sodium
periodate was added, along with 100 µl 1 M sodium acetate at pH 5. After a 15
minute oxidation in the dark at room temperature, the reaction was quenched by
the addition of a drop of glycerol and then desalted on 1x15cm G10 column

equilibrated with 10 mM NaAC, 150 mM NaCI and 2 mM EDTA, pH 5 (acetate
buffer). The void volume was pooled and found to be positive in the BCA assay,
indicating the presence of reducing sugar. The material was diafiltered and
concentrated with an Ultra 4 device into acetate buffer.
Both the amino-oxy BSA and the PsA(red/ox) were examined by SEC
HPLC. The molecular weight of the PsA was markedly reduced by the
reduction/oxidation process.
Conjugation
In the conjugation step, 150 µl amino-oxy-BSA at 6 mg/ml was combined
with 50 ul PsA (red/ox) and 25 µl 1 M NaAc at pH 5.
After an overnight incubation in the dark at 4°C, the conjugate was
analyzed by SEC HPLC (Superose6, saline, 0.5 ml/min). It was seen that the PsA
contributed very little absorbance and the AO-BSA increased in molecular weight
on conjugation.
The conjugate was fractionated on a 1x60cm S200HR gel filtration column
and the high molecular weight fraction assayed for protein and PsA and was
found to contain 0.4 mg BSA/mg PsA.
Conclusion: The reduction/oxidation method works well to create
aldehydes that can be linked to amino-oxy-protein. PsA was probably hydrolyzed
during the NaBH4 step, which is at elevated pH.
Example 12: Preparation of PRP(ox)-BSA-AO Conjugate
1. Oxidation of PRP Hib
22.7 mg PRP Hib was made up at 10 mg/ml in water, and combined with
100 µl 1 M NaAc and 46 µl 0.5 M sodium periodate. The reaction proceeded in
the dark and on ice for 15 minutes, and was then quenched with 50% glycerol.
The reaction mixture was diafiltered into water with an Amicon Ultra 4 (10 kDa
cutoff) device, 4 x 4ml, final volume was approximately 1 ml. A resorcinol assay

was conducted at 10 mg/ml. The sample was positive in the BCA assay,
indicating the presence of aldehyde.
2. Conjugation amino-oxy BSA
AO-S-BSA was provided at 15 mg/ml. 667 µl BSA-S-AO 10 mg was
combined with 100 µl 1 M sodium acetate, at pH 5, and approximately 1 ml
PRP(ox), and the reaction was permitted to proceed overnight in the dark. It was
then quenched by the addition of 50 µl 0.25 M amino-oxy acetate.
3. Assay by SEC Superose6 prep grade HR10/30, equilibrated PBS 0.5
ml/min, OP 220.
Here, 0.5 ml conjugate was fractionated on 1x60 cm S200HR, and
equilibrated PBS. All fractions eluted before BSA, indicating higher MW.

Example 13: Preparation of BSA-Pn14 Conjugate via Oxidation of
Glycidic Acid
This example illustrates a protocol whereby glycidic acid was added to
amines on BSA using carbodiimide. The glycidic acid on the protein was then
oxidized and reacted with amino-oxy-Pn14.
I. BSA-Glycidic acid
Monomeric BSA and glycidic acid (obtained from Fluka Chemical) were
combined to a final concentration in water of 12.5 mg/ml and 28 mg/ml,
respectively. The pH was adjusted to about 5 and 220 µl of 100 mg/ml EDC in
water was added. The pH is kept at about 5 for approximately 1.5 hours, and the

reaction was quenched by the addition of .025 ml 1 M sodium acetate at pH 5.
The reaction mixture is then dialyzed against saline at 4°C overnight.
II. Oxidation of BSA-glycidic acid
100 µl of 1 M sodium acetate at pH 5 was added to 1 ml of BSA-glycidic
acid (7.8 mg/ml), followed by 25 µl of 0.5 M sodium periodate in water. After 10
minutes in the dark, glycerol was added to quench the reaction and excess
reagent removed using an Amicon Ultra centrifugal device with a 30 kDa cutoff.
The final volume was about 400 µl.
100 µl of the oxidized BSA-glycidic acid was combined with 250 ul of
amino-oxy Pn 14 at 9.3 mg/ml along with 50 µl 1 M sodium acetate at pH 5. An
aliquot was evaluated by SEC HPLC (Superose 6 0.5 ml/min, PBS). After an
overnight reaction, another aliquot was assayed in the same way. It was seen
that a significant portion of the absorbance eluted at the void volume (-15
minutes), indicating that the protein was linked to the high molecular weight Pn14.
Following gel filtration on an S400HR column (Pharmacia), the high
molecular weight fraction was determined to contain 0.3 mg BSA/mg Pn14. This
ratio is similar to that determined from the percentage of conjugated high
molecular weight protein in the above chromatogram.
Thus, the method of linking glycidic acid to protein using carbodiimide
provides a way to create aldehydes on proteins that can be subsequently linked to
amino-oxy groups.
Example 14: Use of Amino-Oxy Chemistry to link BSA to Dextran
This example illustrates the coupling of an oligosaccharide via its reducing
end to amino-oxy derivatized protein.
T40 dextran was made up at 100 mg/ml in water. The number of reducing
ends was estimated using the BCA assay with glucose as the standard. It was

found that there were 3.5 mM reducing ends/100 mg/ml T40 dextran, so the
average molecular weight was taken to be approximately 28,000 kDa
5 mg amino-oxy BSA containing ~8 amino-oxy/BSA was combined with 2
ratios of T40 dextran at pH 5.
(A) 830 µl BSA-AO 15.3 mg/ml was combined with 620 ul T40 dextran at
100 mg/ml and 100 µl 1 M NaAc at pH 5.
(B) 830 µl BSA-AO 15.3 mg/ml was combined with 3.1 ml T40 dextran at
100 mg/ml and 500 µl 1 M NaAc at pH 5.
Solutions were reacted at room temperature in the dark for 1 week, and
then assayed by SEC HPLC.
. Both conjugates eluted much earlier than BSA-AO, indicating that their
molecular weight has increased. Conjugates were then fractionated by anion ion
exchange (IEX). Consistent with the SEC profile, the higher the molecular weight,
the lower ionic strength the conjugate eluted. IEX elution fractions were analyzed
for the ratio of carbohydrate to protein and plotted on both a weight and mole ratio
(using 28 kDa MW for the T40 dextran)
The peak fraction from each IEX elution was analyzed by SEC HPLC
(Superose 6 1 ml/min). The absence of monomeric BSA and the increasing MW
for high vs. low ratio T40dex/BSA conjugates. SDS PAGE confirmed the high
molecular weight nature of the conjugate IEX eluants.
Example 15: Use of Amino-Oxy Chemistry to Link Oligosaccharide
and Protein
This example demonstrates the use of amino-oxy chemistry to link an
oligosaccharide indirectly via its reducing end to a protein. A general description
of the protocol is as follows. The reducing end of T40 dextran (-40 kDa MW) was
reacted with the amino-oxy group of amino-oxy acetate to create a dextran with a
single carboxyl group on one end. This carboxy group was then converted to an

amine by reaction with ethylenediamine and carbodiimide. The amine-tipped
dextran was then thiolated and reacted with maleimide-derivatized BSA, to create
a conjugate consisting of a protein with "threads" of carbohydrate extending from
it.
I. Addition of amino-oxy acetate to the reducing end of dextran
850 mg of T40 dextran (Pharmacia) was solubilized in 850 µl of water
overnight at room temperature.
235 mg of amino-oxy acetate was solubilized in a mixture of 850 µl DMSO
and 500 µl 1 M sodium acetate, pH 5 and combined with the T40 dextran solution.
An additional 500 µl of DMSO was added to make the solution approximately 50%
DMSO. After an incubation at about 68°C for about 6 hours, the solution was
extensively dialyzed against water. The product was dextran containing a single
carboxyl group on its reducing end.
1.8 g of ethylenediamine 2HCI was added to the solution (approximately 22
ml) and the pH adjusted to approximately 5 with 1 N NaOH. 220 mg of EDC (1-(3-
dimethylamino)propyl)-3-ethylcarbodiimide hydrochloride) was added and the pH
maintained at about 5 for 3 hours. The reaction was then quenched by the
addition of 1 M sodium acetate, pH 5, dialyzed against saline, and concentrated
using an Amicon Ultra 15™ (10 kDa cutoff). It was then further dialyzed against
saline and then against water.
The product was assayed for amines using TNBS and for carbohydrate
using the resorcinol assay. It was determined that there were approximately 0.45
amines per 40,000 kDa of dextran. This product was dextran containing a single
amine group on its reducing end and was termed NH2-AOAc-T40 dextran. Using
the resorcinol assay, the solution was determined to have a concentration of
about 119 mg/ml dextran. T40 dextran consists of a distribution of molecular

weights, which makes it difficult to determine the actual degree of substitution of
the reducing ends of the polymers.
II. Thiolated dextran and maleimide- BSA
Maleimide-derivatized BSA was prepared as follows: GMBS (40 µl of a 0.1
M stock in NMP) was added to a solution of 200 ul of monomeric BSA (42.2
mg/ml), 50 µl 0.75 M HEPES, 5 mM EDTA at pH 7.3, and 100 µl water. After a 2
hour reaction, the pH was reduced by the addition of 100 µl 1 M sodium acetate,
at pH 5. The solution was desalted using an Amicon Ultra 4™ (30 kDa cutoff)
ultrafiltration device and 10 mM NaAc, 0.15 M NaCI, 5 mM EDTA, pH 5.
The NH2-AOAc-T40 dextran was thiolated using SPDP as follows: 0.5 ml
of the NH2-AOAc-T40 dextran was combined with 100 µl of 1 M HEPES, pH 8 and
100 µl of 0.1 M SPDP were added. After approximately 2 hours, 50 µl of 0.1 M
EDTA pH 5 was added, followed by 100 µl of 1 M sodium acetate, pH 5 and 50 µl
of 0.5 M dithiothreitol in water. After a 1 hour incubation, the solution was
dialyzed into sodium acetate buffer overnight at 4°C.
The thiol tipped T40 dextran and the maleimide derivatized BSA were
combined (a small aliquot of the BSA-maleimide was saved for analysis). After an
overnight reaction, one half the mixture (about 1 ml) was fractionated by gel
filtration using a 1x60 cm S-400HR column, equilibrated with saline. For
comparison, a mixture of 100 µl BSA monomer (42.2 mg/ml), 300 µl T40 dextran
AOAc, and 0.5 ml saline was similarly fractionated on the same gel filtration
column. Fractions (about 1 ml) were analyzed for protein by absorbance at 280
nm and for dextran using the resorcinol assay.
With reference to Figures 5A-D, it is evident that the protein and dextran
are eluting earlier from the column when in the T40 dextran AOAc-thiol-maleimide
BSA conjugate than when the components are mixed. This indicates that a

conjugate of higher molecular weight has been formed. Furthermore, the ratio of
dextran to protein increased.
The column fractions were further analyzed by SDS PAGE, with the results
provided in Figure 6. From left to right, MW marker, conjugate fractions 18,
20,22,24,26, mixture fractions # 24,26,28, 30, unfractionated conjugate, starting
BSA-maleimide.
It is evident that the unfractionated conjugate contains only a small
proportion of free protein, indicating that the conjugate was formed in high yield.
No high molecular weight protein is evident in the mixture fractions. Only
conjugate and essentially no free protein is evident in the conjugate fractions.
This confirms that a conjugate formed in high yield.
Example 16: Preparation of BSA-Pn14 Conjugates via Glycidic Acid and
Amino-Oxy Derivatized Pn-14.
The following example is illustrative of the preparation of a conjugate using
an aldehyde-substituted protein.
I. In situ synthesis of NHS ester of glycidic acid using TSTU and addition to
BSA
In this step, 7.9 mg of glycidic acid hemi-calcium salt monohydrate (MW
143) was solubilized in 110 µl NMP. This was combined with 200 µl of 0.5 M
TSTU (Novachem) in NMP, and 100 µl of triethylamine, and was added to 1 ml of
24 mg/ml BSA. The pH was adjusted to pH 8. After approximately 2 hours, the
mixture was dialyzed on 2 x 1 liter saline. The number of free amines on BSA
was determined using TNBS. For the control, the number was 33.2 NH2/BSA.
For glycidic acid/TSTU/BSA, the number was 25 NH2/BSA. These results lead to
the conclusion that BSA was labeled with about 8 glycidic acid units /BSA

II. Oxidation of Functionalized BSA
A 5 mg aliquot was made up with 25 mM NaAc at pH 5, and 25 mM sodium
periodate. The reaction was allowed to proceed in the dark at room temperature
for 15 minutes, after which a drop of glycerol was added to quench the reaction.
The mixture was fractionated S200HR, pool main peak & concentrate.
III. Preparation of BSA(ox)-AO-Pn14 Conjugate
In this step, 444 µl of amino-oxy functionalized Pn14 was combined with
0.4 ml BSA(ox) made up at 10.1 mg/ml, and 100 µl 1 M NaAc at pH 5, and
reacted overnight at room temperature. The Fractionate by gel filtration S400HR
1x60 cm saline + 0.02% azide SEC HPLC indicated that oxidation of the Glycdic
acid/TSTU/BSA caused polymerization of the BSA.
Also observed was the progressive increase in the high molecular weight
peak, indicating that conjugation was increasing with time. The AO-Pn14 alone
had minimal absorbance.
Example 17: Preparation of Mercaptoglycerol-Bromoacetate BSA
This example illustrates a process for preparing a
BSA(mercaptoglycerol(ox))-AO-dextran conjugate.
Preparation of bromoacetylated BSA
500pl monomeric BSA (48mg/ml) was combined with 500ul 1 M HEPES, at
pH 8, and 25 µl 0.1 M NHS bromoacetate in NMP. For the control, 250 µl BSA
was combined with 250 µl HEPES and 12 µl NMP
After approximately 1 hour, each was desalted into saline using an Amican
Ultra 4 (30 kDa cutoff) device. The final volume was 450 µl BSA-bromoAc, and
300pl BSA control
Next, 50 mM mercaptoethanol and 50 mM mercaptoglycerol were prepared
in water.

Preparation E: 225 µl BSA-BromoAc was combined with 100 µl 1 M
HEPES at pH 8 and 50 µl of 50 mM mercaptoglycerol.
Preparation F: The BSA control was combined with 100 µl 1 M HEPES to
pH 8 and 50 µl 50 mM mercaptoglycerol
Preparation G: 225 µl BSA- BromoAc was combined with 100 µl 1 M
HEPES at pH 8, and 50 µl 50 mM mercaptoethanol.
After 30 minutes, each was desalted with Amicon Ultra using NaAc buffer
(10 mM NaAcetate, 150 mM NaCI, 5 mM EDTA, pH 5). Final volume was 0.5 ml
Each was then made up in 10 mM sodium periodate from a freshly
prepared 0.5 M stock and incubated for 10 minutes at 4°C in the dark, and then
quenched by the addition of glycerol and desalted using the Amicon Ultra device
and washed into NaAc buffer. By OD 280, each was determined to be about 20
mg/ml BSA.
Preparation E should contain BSA-aldehyde; Preparation F was not labeled
with the bromoacetate, and so it could not react with the mercaptoglycerol. Thus,
it should not contain aldehydes. Preparation G would have pendent
mercaptoethanol, which does not oxidize, so it should not contain aldehdydes.
315 µl of Amino-oxy dextran, at 15.9 mg/ml, was combined with 250 pi of
each BSA preparation, and incubated overnight at room temperature in the dark.
Each was then fractionated by gel filtration on a S400HR 1x60cm
equilibrated with saline. The high molecular weight fraction was analyzed for
protein and dextran.
The results indicated that only BSA containing the oxidized
mercaptoglycerol formed a conjugate, and this was confirmed by the
protein/dextran ratio of the high molecular weight fraction.
E BSA-mercaptoglycerol(ox) + AO-dex 0.97 mg BSA/mg dex.
F BSA control (ox) + AO-dex 0.1 mg BSA/mg dex.

G BSA-mercaptoethanol(ox) +AO-dex 0.1 mg BSA/mg dex.
Example 18: Linking of a Protein to a Polysaccharide via Oxime Formation
The following example illustrates the linking of a protein via its N-terminal
group to a polysaccharide via oxime formation.
N-terminal threonine of lysostaphin was oxidized and derivatized with a bis-
amino-oxy reagent. Oxidation of the protein was performed as generally
described in Gaertner & Offord, "Site-specific attachment of functionalized
poly(ethylene glycol) to the amino terminus of proteins," Bioconjugate Chem. 7:38
(1996). Lysostaphin a 27 kDa protein was produced in lactococcus.
Trial No. 1
The lysostaphin used contained only about 30% free N-terminal threonine.
Conditions of Gaertner & Offord were used for oxidation of the N-terminal
threonine. In more detail, a 50 molar excess of methionine (17.5 µl from a 1M
stock in water) was added to 1 ml of a 10 mg/ml solution of lysostaphin. Sodium
bicarbonate (1M) was added to adjust the pH to 8.3. Oxidation was commenced
by the addition of sodium periodate (7 µl from a 0.5 M stock in water). The
reaction mixture was kept in the dark at room temperature for 10 minutes, at
which time 7.1 mg Bis(amino-oxy)tetraethylene glycol (obtained from Solulink™)
prepared as a 50 mg/ml solution in DMSO was added. After 1 hour in the dark,
the solution was dialyzed against saline in the dark at room temperature. The
product is termed lysotaphin AO. The lysostaphin concentration was determined
at OD 280 using 0.49 mg/ml/Absorbance unit.
An aliquot was tested with TNBS at pH 5. It has previously been found that
amino-oxy but not amines reacted with TNBS under these conditions. The assay
was performed as follows: 50 µl of lysostaphin or lysostaphin AO was added to
440 µl of 0.1 M NaAc, pH 5 and then 10 µl of 10 mg/ml TNBS in water added. 5 pi
of 1 mM Amino-oxy acetic acid was used as a standard in the above solution.

Samples were read at 500 nm after a 6 hour incubation in the dark. The sample
solution was orange, indicating presence of amino-oxy groups. Using the
standard, it was estimated about 30% of lysostaphin was derivatized with the AO
group. This lysostaphin AO was then reacted with excess oxidized T2000 dextran
in the dark at room temperature to allow conjugation via oxime formation. The
reaction was assayed by SEC HPLC to determine the shift of mass from low
molecular weight (unconjugated protein) to high molecular weight (lysostaphin-
dextran conjugate). A Phenomenex Biosep SEC2000 (300x4.6) equilibrated with
PBS and run at 0.5 ml/min with monitoring at 280 nm was used for SEC HPLC
With reference to Figure 6, the upper chromatogram is the reaction mixture
at about 1 minute, the middle chromatogram is after an overnight reaction and the
lower figure is the lysostaphin AO alone. Note the shift to high molecular weight
material after the reaction was allowed to proceed overnight. This figure suggests
that the AO group on the lysostaphin linked to the high molecular weight, oxidized
dextran. About 27% was coupled, based on the percentage of the area of the
high molecular weight peak. This is in the expected percentage since only about
a third of the lysostaphin contained a free threonine and was derivatized with AO,
as indicated by TNBS assay.
Example 19: Preparation of DT(ox)-AO-Pn14 Conjugate
This example illustrates the preparation of the DT(ox)-AO-Pn14 conjugate,
and it also demonstrates how reagents can be prepared in as "single pot"
reactions (which may simplify preparation).
I. Mercaptoglvcerol-Diptheria toxoid
0.5 ml diphtheria toxoid (~13 mg/ml) was combined with 100 µl 1 M
HEPES, pH 8 and 10 µl 0.1 M NHS bromoacetate in NMP. It was incubated in the
dark for about 30 minutes, and then 10 µl of 12.3 µl mercaptoglycerol was added.

Following an overnight reaction, the solution was desalted with an Amicon Ultra 4
(30kDa cutoff) to a final volume of about 400 ul.
Next, 50 µl of 1 M sodium acetate at pH 5 was added, followed by 9 µl of
0.5 M sodium periodate. Oxidation was allowed to proceed for 10 minutes in the
dark at room temperature. The reaction was then quenched by the addition of
50% glycerol. The low molecular weight components were removed on the same
Amicon Ultra 4 device and diafiltered into saline. The final volume was about 200
µl.
The above protocol eliminated one of the desalting steps by adding excess
mercaptoglycerol to the solution containing bromoacetylated-DT and
bromoacetate.
II. Conjugation
1 ml of amino-oxy Pn14 (~9 mg/ml) was added to the oxidized DT and 100
µl of 1 M sodium acetate at pH 5 added. The reaction was allowed to proceed
overnight at room temperature in the dark, and then fractionated on an S400HR
column (1x60 cm, equilibrated with saline).
The high molecular weight fraction was pooled. Protein was estimated
using 1 mg/ml= 1 OD and the Pn14 concentration determined using the resorcinol
assay. The fraction was found to contain about 1.3 mg DT/mg Pn14.
Example 20: Preparation of a qp350(ox)-AO-S-Pn14 conjugate.
gp350 is a glycoprotein from Epstein Barr virus that binds to human
complement receptor. It was produced recombinantly in yeast cells by Dr.
Goutam Sen (Uniformed Services University of the Health Sciences, Bethsda,
MD) and purified by hydrophobic interaction chromatography.
The pH of 0.5 ml of gp350 at 8 mg/ml in PBS was reduced by the addition
of 50 µl 1 M sodium acetate, pH 4.7, and 11 µl of 0.5 M sodium periodate (in
water) was added. After an 8 minute incubation in the dark, on ice, the reaction

was quenched by the addition of 100 µl 50% glycerol. Excess reagent was
removed by diafiltration using an Amicon Ultra 4 (30 kDa cutoff) device. A total of
four, 4 ml exchanges with PBS were used. The final volume was about 300 µl.
To this solution, 100 µl of 1 M NaAc, pH 5 was added, followed by 400 µl of AO-S-
Pn14(9.1 mg/ml).
After an overnight reaction at 4° C in the dark, the reaction was quenched
by the addition of 100 µl of 0.25 M amino-oxy acetate, pH 5. The resulting
conjugate was fractionated by gel filtration on a 1 x 60 cm S400HR column,
equilibrated with saline. The void volume fractions were pooled. The Pn14
concentration was determined by the resorcinol/sulfuric acid method and the
protein from the absorbance at 280 nm, using an extinction coefficient of 1 mg/ml
= 1 absorbance unit. The conjugate contained 0.9 mg gp350/mg Pn14.
Control gp350 was oxidized and prepared as above but amino-oxy acetate
was added instead of amino-oxy Pn14.
In competition assays with fluorescently labeled gp350, both the control
and the conjugated gp350 were capable of binding to the complement receptor of
human B cells. (Performed by Goutam Sen USUHS).
Mice were immunized on with the gp350-Pn14 conjugate on days 0 and 10,
and bled on days 10 and 23

The increase in anti-Pn14 IgG on boosting is an indication that the protein
and polysaccharide are covalently linked and acting as a T cell dependent
antigen. As a T cell independent antigen, Pn14 alone does not show an increase

in titer.
Example 21: Preparation of a [DeAcLTA(ox)-AO-SH]-GMBS-BSA Conjugate
LTA was deacylated by incubation for 1 hour in pH 10 sodium bicarbonate
at approximately 75°C. Sample is then dialyzed against water. This is deacylated
LTA (DeAcLTA).
The sample was then oxidized in 10 mM sodium periodate at pH 5
overnight in the dark at room temperature, dialyzed against water again, and
lyophilized. The sample was taken up in a small volume of water, incubated
overnight with reduced amino-oxy cysteamine and lyophilized. The sample was
taken up in about 1 ml of water and fractionated on an S200HR column,
equilibrated with 10 mM sodium acetate, 150 mM NaCI, and 5 mM EDTA, pH 5.
The low molecular weight fraction containing both Pi and thiol was pooled and
lyophilized and taken up in about 0.75 ml water. This fraction was found to
contain about 1 mM thiol and 350 micromolar phosphate. This material is thiol-
labeled DeAcLTA.
BSA was labeled with a 50 fold molar excess of GMBS (Prochem) at pH
7.2 and desalted in sodium acetate buffer and concentrated using an Amicon Ultra
4 (30kDa cutoff) device to a final concentration of about 55 mg/ml.
60 µl of the BSA-GMBS was added to the thiol labeled DeAcLTA. As the
reaction proceeded, the concentration of thiols decreased at least 10 fold, as
determined by the DTNB assay.
Conjugation was monitored by SEC HPLC on a Superose 6 column,
(equilibrated with PBS,1 ml min, OD 280). The lower trace indicated the
chromatogram for the GMBS labeled BSA alone and the upper trace indicated the
conjugate, which elutes earlier, indicating an increased molecular weight. By SDS
PAGE, the MW of the conjugate had clearly increased in a manner consistent with
the SEC chromatogram. No monomeric BSA is evident in the conjugate.

A western blot was performed to demonstrate the presence of LTA on the
high molecular weight protein. It is seen that the conjugate was reactive for LTA.
Neither BSA nor LTA alone or the combination indicate any high molecular weight
LTA.
To further demonstrate the covalent linkage between LTA and BSA, a
double ELISA was performed. The ELISA plate was coated with anti-BSA
followed by conjugate or LTA, BSA or the combination. Anti-LTA is then applied
and the amount bound determined. Thus, only material containing both BSA and
LTA would be detected. Only the conjugate was positive in this assay.
Thus by reaction monitoring, molecular weight, western blotting and double
ELISA all indicated the formation of a covalent link between the protein and LTA.
Example 22: Preparation of a LTA-TT Conjugate
Reagents were obtained from Aldrich. Aminooxyacetylcystamine was
prepared by Dr. David Schwartz of Solulink Inc. (San Diego, CA). TCEP was
purchased from Pierce.
S. Aureus serotype 5 lab strain (MSSA) was grown by Kemp Biotech
(Frederick, MD) in a 100 liter fermenter. Cells were centrifuged, resuspended and
centrifuged into aliquots approximating 10 liters of cells. The cell paste was
stored at -70°C. An aliquot was thawed and resuspended in 0.1 M sodium citrate,
pH 4.7 and disrupted with a Bead Beater (Biospec Products) using 0.1 m
zirconium beads. The device was ice cooled and run 1 min on and 1 min off for 4
cycles. The liquid was removed and the beads washed with citrate buffer.
Alternatively, cells were treated with 1 mg/ml lysostaphin at pH 5 overnight at 4°C
and then disrupted using a Microfluidizer Model 110Y (Microfluidizer, Newton, MA)
with 3 passes at 23,000 psi.

I. LTA extraction
LTA was extracted and purified from cell pellets using either the phenol
extraction method of Fischer et al., Improved preparation of lipoteichoic acids. Eur
J Biochem, 1983.133(3): p. 523-30, with minor modifications or using the butanol
method of Morath et al., Structure-function relationship of cytokine induction by
lipoteichoic acid from Staphylococcus aureus. J Exp Med, 2001. 193(3): p. 393-7.
In brief, the disrupted cell suspension was vigorously mixed for 30 min
with an equal volume of n-butanol. The solution was then centrifuged for 20 min
at 13,000 x g. The upper phase (butanol) was removed and the lower, aqueous
phase was lyophilized. Initially the butanol phase was re-extracted and the new
aqueous phase tested for LTA by ELISA, however an insignificant amount of LTA
was recovered. Pellets were resuspended in 25 ml of citrate buffer and frozen.
Pellets from several extraction runs were combined, and the disruption/extraction
process repeated.
The solubilized extract was filtered using a Whatman 0.45pm syringe filter
(#6894-2504) and loaded onto a 2.6 x 20 cm Octyl Sepharose column
(Pharmacia), equilibrated with 0.1M ammonium acetate in 15% n-propanol, pH
4.7, at a flow rate of .5ml/min. The column was then washed with 0.1 M sodium
acetate in 15% n-propanol until the absorbance at 280 nm returned to baseline.
The column was then eluted with 25mM sodium acetate in 40% n-propanol at 4
ml/min and fractions of 8 ml collected. The phosphate containing fractions were
pooled and loaded onto a 5 ml Sepharose Q FF column, equilibrated with the
same buffer. When the absorbance returned to baseline, the column was eluted
with buffer + 0.5 M KCI. Phospate containing tubes were pooled, partially
lyophilized to reduce the volume and dialyzed against water to remove salts and
lyophilized again.

II. Conjugation of LTA to tetanus toxoid
LTA was deacylated by incubating 1 ml (10 mg/ml) in 0.1 M sodium
carbonate + 0.1 M hydroxylamine for 2 hr at 75° C, followed by dialysis against
water using a 3.5 kDa cutoff membrane (Pierce). The solution was then
lyophilized and taken up in 0.5 ml water. The deacylated LTA was oxidized by the
addition of 100 µI 1 M sodium acetate, pH 5 and 125 µl 0.5 M sodium
meta period ate. After 2 hrs the reaction was quenched by the addition of 100 µl
50% glycerol and dialyzed overnight in the dark against water. This material
tested positive for aldehydes in the purpald assay (Lee, C.H. and C.E. Frasch,
Quantification of bacterial polysaccharides by the purpald assay: measurement of
periodate-generated formaldehyde from glycol in the repeating unit. Anal
Biochem, 2001. 296(1): p. 73-82).
(Amino-oxyacetate)cysteamine was prepared by solubilizing 11 mg
Bis(amino-oxyacetate)cystamine in an aqueous solution of 25% NMP. TCEP (17
mg) in 1 M sodium carbonate was added and the solution incubated for 10 min
and then passed over a Dowex 1x-8 column (1x3 cm), equilibrated with 10 mM
Bistris, pH 6. The DTNB positive fractions in the flow through were pooled. The
pooled (amino-oxyacetate)cysteamine was assayed for thiols and determined to
contain 5.2 µmole SH. The reagent was combined with the oxidized deacylated
LTA and incubated overnight in the dark at 4°C and then dialyzed against 10 mM
sodium acetate, 0.15 M sodium chloride, 5 mM EDTA, pH 5 to remove excess
reagent. The final solution was 2 ml at 2.5 mM thiol and 25 mM phosphate.
Tetanus toxoid (TT) (obtained from GlaxoSmithKline, Rixensart, Belgium)
was labeled with maleimide by adding a 50-fold molar excess of GMBS (0.1 M
stock in NMP) to a 14.6 mg/ml solution of TT buffered in15 M HEPES, 5 mM
EDTA, pH 7.3. After a 1 hr reaction, the solution was desalted by diafilitration into

2 M NaCI using an Amicon Ultra 4 (30kDa cutoff) device, concentrating to a final
volume of 0.4 ml. The retained material was DTNB positive.
The thiolated, deacylated LTA was combined with the maleimide-TT under
a stream of nitrogen and the pH adjusted to 6.5 by the addition of 0.75 M HEPES,
pH 7.3. After sealing and incubating overnight at 4°C, the solution was assayed
and determined to still be 2 mM thiol. An additional 7 mg of TT was labeled with
maleimide as above, diafiltered and concentrated to 0.5 ml and added to the
reaction mixture. Over 30 min the thiol content steadily decreased and at that
time the reaction was quenched by the addition of 100 ju.1 of 0.5 M iodoacetamide
+100 µl of 1 M sodium carbonate.
The conjugate was purified using size exclusion chromatography on a
Superose 6 (Prep grade) column (1 x 30 cm), equilibrated with saline.
III. Immunization of mice
Groups of 20 Balb/c mice were immunized on days 0, 14 and 28 with 5 ug
of LTA as described above, either mixed with TT or conjugated to TT and with Ribi
MPL adjuvant and bled 14 days later. Individual sera were assayed for anti-IgG
by ELISA. The results are provided in Fig. 7. M110 (a mouse monoclonal
antibody that binds to LTA) was used as a standard. Anti-LTA levels were
assayed in the sera. Results are shown in Fig. 8. The conjugate induced high
levels, and the mixture induced only very low levels of antibody. To evaluate the
biological activity of the anti-sera, an opsonophagocytic was performed. Sera
were diluted at 1:25.
IV. Phosphate analysis
Phosphate was determined as described by Chen, P.S., T.Y. Toribara, and
H. Warner, Microdetermination of Phosphorous. Anal Biochem, (1956) 28: p.
1756-1758, with some modifications. In brief, a 100 µl sample + 30 µI magnesium

nitrate solution in a 13 x 100 mm borosilicate tube were vortexed, dried in a
heating block and flamed with a propane torch until a brown gas was emitted. 300
µl of 0.5 M HCI was added, the tubes capped with glass marbles and heated in a
boiling water bath for 15 min. The tubes were allowed to cool and 700 µl of an
ascorbic acid/ammonium molybdate mix added, incubated for 20 min at 45°C and
samples read at 820 nm. The mix was prepared by combining 6 parts of a
solution of ammonium molybdate (0.42 g + 2.86 ml sulfuric acid made up to 100
ml with water) and 1 part of 10% ascorbic acid in water. Phosphate standard was
obtained from Sigma.
Other embodiments of the invention will be apparent to those skilled in the
art from consideration of the specification and practice of the invention disclosed
herein. It is intended that the specification and examples be considered as
exemplary only, with a true scope and spirit of the invention being indicated by the
following claims.
The specification is most thoroughly understood in light of the teachings of
the references cited within the specification. The embodiments within the
specification provide an illustration of embodiments of the invention and should
not be construed to limit the scope of the invention. The skilled artisan readily
recognizes that many other embodiments are encompassed by the invention. Any
of the foregoing process are suitable in accordance with the present invention.
The above serve only as illustrative examples and are nonlimiting.
All publications and patents cited in this disclosure are incorporated by
reference in their entirety. To the extent the material incorporated by reference
contradicts or is inconsistent with this specification, the specification will
supercede any such material. The citation of any references herein is not an
admission that such references are prior art to the present invention.

Unless otherwise indicated, all numbers expressing quantities of
ingredients, reaction conditions, and so forth used in the specification, including
claims, are to be understood as being modified in all instances by the term
"about." Accordingly, unless otherwise indicated to the contrary, the numerical
parameters are approximations and may vary depending upon the desired
properties sought to be obtained by the present invention. At the very least, and
not as an attempt to limit the application of the doctrine of equivalents to the scope
of the claims, each numerical parameter should be construed in light of the
number of significant digits and ordinary rounding approaches.
Unless otherwise indicated, the term "at least" preceding a series of
elements is to be understood to refer to every element in the series. Those skilled
in the art will recognize, or be able to ascertain using no more than routine
experimentation, many equivalents to the specific embodiments of the invention
described herein. Such equivalents are intended to be encompassed by the
following claims.

WE CLAIM:
l.A process for preparing a composition comprising a conjugate for
inducing an immune response in a subject, comprising: (a) reacting a
first moiety with a second moiety containing at least one pendent amino-
oxy group to form a composition comprising a conjugate,
wherein the first moiety is chosen from polysaccharides,
oligosaccharides, carbohydrates, and carbohydrate-containing molecules,
and the second moiety is chosen from proteins, and peptides; and
(b)combining the conjugate with a pharmaceutically acceptable delivery
vehicle to form a composition comprising a conjugate for inducing an
immune response in a subject.
2. The process as claimed in claim 1, wherein the first moiety is
directly reacted with the second moiety to form a conjugate.
3. The process as claimed in claim 1, wherein the first moiety is
indirectly reacted with the second moiety to form a conjugate.
4. The process as claimed in claim 1, wherein the first moiety is
functionalized prior to its reaction with the second moiety.

5. The process as claimed in claim 1, wherein the protein is a
haptenated protein.
6. The process as claimed in claim 1, wherein the carbohydrate-
containing molecules are chosen from lipopolysaccharides,
lipooligopolysaccharides, lipotechoic acid, and deacylated lipotechoic
acid.
7. The process as claimed in claim 1, wherein the functionalized
second moiety contains at least one pendent amino-oxy group prior to
reaction with the first moiety.

8. The process as claimed in claim 1, wherein the first moiety contains at
least one carbonyl group.
9. The process as claimed in claim 8, wherein the carbonyl group is an
aldehyde.
10. The process as claimed in claim 8, wherein the carbonyl group is a
ketone.

11. The process as claimed in claim 1, wherein the amino-oxy reagent is
chosen from homofunctional and heterofunctional reagents.
12. A composition for inducing an immune response in a subject
comprising the conjugate prepared by the process as claimed in claim 1.


The invention relates to a process for preparing a conjugate comprising
combining an amino-oxy homofunctional or heterofunctional reagent with an entity
chosen from polysaccharides, oligosaccharides, carbohydrates, and
carbohydrate-containing molecules containing at least one carbonyl group, to form
a polysaccharide, oligosaccharide, carbohydrate, or carbohydrate-containing
molecule functionalized via at least one oxime linkage. The functionalized
compound is then reacted either directly or indirectly with a protein moiety to form
a protein-carbohydrate conjugate that may be used as a vaccine.

Documents:

02317-kolnp-2006 abstract.pdf

02317-kolnp-2006 claims.pdf

02317-kolnp-2006 correspondence others.pdf

02317-kolnp-2006 description (complete).pdf

02317-kolnp-2006 drawings.pdf

02317-kolnp-2006 form-1.pdf

02317-kolnp-2006 form-2.pdf

02317-kolnp-2006 form-3.pdf

02317-kolnp-2006 form-5.pdf

02317-kolnp-2006 international search report.pdf

02317-kolnp-2006 pct form.pdf

02317-kolnp-2006 priority document.pdf

02317-kolnp-2006-correspondence others-1.1.pdf

02317-kolnp-2006-correspondence-1.2.pdf

02317-kolnp-2006-form-1-1.1.pdf

02317-kolnp-2006-form-18.pdf

02317-kolnp-2006-form-26.pdf

02317-kolnp-2006-international search authority report-1.1.pdf

2317-KOLNP-2006-(27-10-2011)-ASSIGNMENT.pdf

2317-KOLNP-2006-(27-10-2011)-CORRESPONDENCE.pdf

2317-KOLNP-2006-(27-10-2011)-FORM 1.pdf

2317-KOLNP-2006-(27-10-2011)-FORM 3.pdf

2317-KOLNP-2006-(27-10-2011)-FORM 5.pdf

2317-KOLNP-2006-(27-10-2011)-FORM 6.pdf

2317-KOLNP-2006-(27-10-2011)-PA.pdf

2317-KOLNP-2006-ABSTRACT.pdf

2317-kolnp-2006-amanded claims.pdf

2317-KOLNP-2006-CANCELLED PAGES.pdf

2317-KOLNP-2006-CLAIMS.pdf

2317-KOLNP-2006-CORRESPONDENCE-1.1.pdf

2317-KOLNP-2006-CORRESPONDENCE-1.2.pdf

2317-kolnp-2006-correspondence.pdf

2317-KOLNP-2006-DESCRIPTION (COMPLETE).pdf

2317-KOLNP-2006-DRAWINGS.pdf

2317-kolnp-2006-examination report.pdf

2317-KOLNP-2006-FORM 1.pdf

2317-kolnp-2006-form 18.pdf

2317-KOLNP-2006-FORM 2.pdf

2317-kolnp-2006-form 26.pdf

2317-kolnp-2006-form 3-1.1.pdf

2317-KOLNP-2006-FORM 3.pdf

2317-kolnp-2006-form 5-1.1.pdf

2317-KOLNP-2006-FORM 5.pdf

2317-kolnp-2006-granted-abstract.pdf

2317-kolnp-2006-granted-claims.pdf

2317-kolnp-2006-granted-description (complete).pdf

2317-kolnp-2006-granted-drawings.pdf .pdf

2317-kolnp-2006-granted-form 1.pdf

2317-kolnp-2006-granted-form 2.pdf .pdf

2317-kolnp-2006-granted-specification.pdf

2317-KOLNP-2006-INTERNATIONAL SEARCH REPORT-1.1.pdf

2317-kolnp-2006-others-1.1.pdf

2317-KOLNP-2006-OTHERS.pdf

2317-KOLNP-2006-PETITION UNDER RULE 137.pdf

2317-kolnp-2006-reply to examination report.pdf


Patent Number 253359
Indian Patent Application Number 2317/KOLNP/2006
PG Journal Number 29/2012
Publication Date 20-Jul-2012
Grant Date 16-Jul-2012
Date of Filing 16-Aug-2006
Name of Patentee M/s FINA BIOSOLUTIONS LLC
Applicant Address 9610 MEDICAL CENTER DR., SUITE 200, ROCKVILLE, MD 20850, U.S.A.
Inventors:
# Inventor's Name Inventor's Address
1 LEES, ANDREW 1910 GLEN ROSS ROAD, SILVER SPRING, MD 20910
PCT International Classification Number N/A
PCT International Application Number PCT/US2005/003040
PCT International Filing date 2005-01-27
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 60/589,019 2004-07-20 U.S.A.
2 60/539,573 2004-01-29 U.S.A.