Characterisation and recombinant expression of antigens for the rapid diagnosis of West Nile virus infection

Jody Hobson-Peters

Unknown Date

West Nile Virus (WNV) is a mosquito-borne pathogen of global significance. It is active on several continents and is responsible for recent outbreaks of fever and fatal encephalitis in humans and horses. While highly virulent strains have been reported in Europe, North, Central and South America, only a benign subtype of WNV (Kunjin virus – KUNV) occurs in Australia. However, virulent, exotic WNV strains are seen as a significant threat to Australia due to the ease with which this virus can move between continents and the presence of suitable vectors and hosts already within Australia. KUNV and WNV subtypes are antigenically and genetically very closely related and cross-react in traditional serological tests. This cross-reactivity makes it very difficult to differentiate between KUNV and WNV infections using standard serological tests. The aim of this thesis was to identify immunogenic epitopes unique to KUNV or WNV and to use these epitopes in the development of a rapid assay that would enable the diagnosis of and surveillance for exotic virulent strains of WNV in Australia. The rapid diagnostic platform chosen was a red blood cell (RBC) agglutination assay that was originally patented and commercialised by AGEN Biomedical Ltd. The RBC agglutination assay reagent consists of the Fab region of a human erythrocyte-specific monoclonal antibody (mAb) conjugated to the epitope of interest (in this instance, a WNV-specific peptide). This bi-functional reagent causes the agglutination of the patient’s erythrocytes in the presence of WNV-specific antibody in the patient’s serum. Traditionally, these RBC agglutination reagents have been produced by chemical conjugation. However, a potentially easier and cheaper method involves the linking of the gene encoding the erythrocyte-specific antibody to that encoding the epitope to create a recombinant version of the bi-functional agglutination reagent through expression using prokaryotic or eukaryotic systems. To identify potential differential epitopes, 18 mAbs to WNV (NY99 strain) prM and envelope (E) proteins were assessed. One mAb (17D7) differentially recognised WNV and KUNV in ELISA and maintained recognition of its corresponding epitope upon reduction and carboxymethylation of the viral antigen, suggesting a continuous (linear) epitope. Using synthetic peptides, the epitope was mapped to a 19 amino acid sequence (WN19: E147-165) encompassing the WNV NY99 E protein glycosylation site at position 154. An amino acid substitution at position E156 of many KUNV strains abolishes this glycosylation moiety. The inability of WNV-positive horse and mouse sera to bind the synthetic peptides indicated that glycosylation was required for recognition of peptide WN19 by WNV-specific antibodies in sera. N-linked glycosylation of WN19 was achieved through expression of the peptide as a C-terminal fusion protein in mammalian cells and specific reactivity of WNV-positive horse sera to the glycosylated WN19 fusion protein was shown by Western blot. Additional sera collected from horses that had been infected with Murray Valley encephalitis virus (MVEV), which is similarly glycosylated at position E154 and exhibits high sequence identity to WNV NY99 in this region, also recognised the recombinant peptide. In contrast, no reactivity with the recombinant peptide was observed by sera from horses infected with the unglycosylated WNV subtype, KUNV. Failure of most WNV- and MVEV-positive horse sera to recognise the epitope as a deglycosylated fusion protein (75% and 100% respectively) confirmed that the N-linked glycan is important for antibody recognition of the peptide. Together, these results suggest that the induction of antibodies to the WN19 epitope during WNV infection of horses is generally associated with E protein glycosylation of the infecting viral strain. To assess the feasibility of using peptide WN19 in a rapid immunoassay, the peptide was recombinantly fused to a RBC (glycophorin)-specific single chain antibody (scFv) using previously published constructs which were developed for the bacterial expression of similar bi-functional reagents. To facilitate glycosylation of peptide WN19, the genes for the bi-functional agglutination reagents were subsequently cloned into eukaryotic expression vectors. An additional set of constructs were also produced in which the genes for the variable regions of the anti-RBC antibody were cloned into a vector for the secreted expression of an intact, humanised IgG1 molecule. Stable cell lines were produced for each of these constructs and secreted up to 700 ng/mL glycophorin-reactive antibody. The secreted recombinant protein could be harvested directly from the cell culture medium and used in RBC agglutination assays, where these bi-functional agglutination reagents could be cross-linked either with mAb 17D7 or by anti-peptide WN19 antibodies present in WNV-positive horse serum. The WNV NY99 prM protein was also identified as a useful marker of WNV-infection in horses, as well as a putative antigen to differentiate equine WNV NY99 and KUNV infections using Western blot. Two anti-WNV prM mAbs were also generated in this study and will be extremely valuable in future studies. Preliminary analysis of the prM epitope(s) bound by these mAbs and WNV-immune sera indicate that the binding site(s) is likely to be localised to pr and is conformational.

06 Biological Sciences

West Nile virus

Kunjin Virus

Flavivirus

Monoclonal Antibody

single chain antibody

red blood cell agglutination

Recombinant Antibody

Epitope mapping

prM

Envelope Protein

Diagnostic Assay

Characterisation and recombinant expression of antigens for the rapid diagnosis of West Nile virus infection

Jody Hobson-Peters

Unknown Date

West Nile Virus (WNV) is a mosquito-borne pathogen of global significance. It is active on several continents and is responsible for recent outbreaks of fever and fatal encephalitis in humans and horses. While highly virulent strains have been reported in Europe, North, Central and South America, only a benign subtype of WNV (Kunjin virus – KUNV) occurs in Australia. However, virulent, exotic WNV strains are seen as a significant threat to Australia due to the ease with which this virus can move between continents and the presence of suitable vectors and hosts already within Australia. KUNV and WNV subtypes are antigenically and genetically very closely related and cross-react in traditional serological tests. This cross-reactivity makes it very difficult to differentiate between KUNV and WNV infections using standard serological tests. The aim of this thesis was to identify immunogenic epitopes unique to KUNV or WNV and to use these epitopes in the development of a rapid assay that would enable the diagnosis of and surveillance for exotic virulent strains of WNV in Australia. The rapid diagnostic platform chosen was a red blood cell (RBC) agglutination assay that was originally patented and commercialised by AGEN Biomedical Ltd. The RBC agglutination assay reagent consists of the Fab region of a human erythrocyte-specific monoclonal antibody (mAb) conjugated to the epitope of interest (in this instance, a WNV-specific peptide). This bi-functional reagent causes the agglutination of the patient’s erythrocytes in the presence of WNV-specific antibody in the patient’s serum. Traditionally, these RBC agglutination reagents have been produced by chemical conjugation. However, a potentially easier and cheaper method involves the linking of the gene encoding the erythrocyte-specific antibody to that encoding the epitope to create a recombinant version of the bi-functional agglutination reagent through expression using prokaryotic or eukaryotic systems. To identify potential differential epitopes, 18 mAbs to WNV (NY99 strain) prM and envelope (E) proteins were assessed. One mAb (17D7) differentially recognised WNV and KUNV in ELISA and maintained recognition of its corresponding epitope upon reduction and carboxymethylation of the viral antigen, suggesting a continuous (linear) epitope. Using synthetic peptides, the epitope was mapped to a 19 amino acid sequence (WN19: E147-165) encompassing the WNV NY99 E protein glycosylation site at position 154. An amino acid substitution at position E156 of many KUNV strains abolishes this glycosylation moiety. The inability of WNV-positive horse and mouse sera to bind the synthetic peptides indicated that glycosylation was required for recognition of peptide WN19 by WNV-specific antibodies in sera. N-linked glycosylation of WN19 was achieved through expression of the peptide as a C-terminal fusion protein in mammalian cells and specific reactivity of WNV-positive horse sera to the glycosylated WN19 fusion protein was shown by Western blot. Additional sera collected from horses that had been infected with Murray Valley encephalitis virus (MVEV), which is similarly glycosylated at position E154 and exhibits high sequence identity to WNV NY99 in this region, also recognised the recombinant peptide. In contrast, no reactivity with the recombinant peptide was observed by sera from horses infected with the unglycosylated WNV subtype, KUNV. Failure of most WNV- and MVEV-positive horse sera to recognise the epitope as a deglycosylated fusion protein (75% and 100% respectively) confirmed that the N-linked glycan is important for antibody recognition of the peptide. Together, these results suggest that the induction of antibodies to the WN19 epitope during WNV infection of horses is generally associated with E protein glycosylation of the infecting viral strain. To assess the feasibility of using peptide WN19 in a rapid immunoassay, the peptide was recombinantly fused to a RBC (glycophorin)-specific single chain antibody (scFv) using previously published constructs which were developed for the bacterial expression of similar bi-functional reagents. To facilitate glycosylation of peptide WN19, the genes for the bi-functional agglutination reagents were subsequently cloned into eukaryotic expression vectors. An additional set of constructs were also produced in which the genes for the variable regions of the anti-RBC antibody were cloned into a vector for the secreted expression of an intact, humanised IgG1 molecule. Stable cell lines were produced for each of these constructs and secreted up to 700 ng/mL glycophorin-reactive antibody. The secreted recombinant protein could be harvested directly from the cell culture medium and used in RBC agglutination assays, where these bi-functional agglutination reagents could be cross-linked either with mAb 17D7 or by anti-peptide WN19 antibodies present in WNV-positive horse serum. The WNV NY99 prM protein was also identified as a useful marker of WNV-infection in horses, as well as a putative antigen to differentiate equine WNV NY99 and KUNV infections using Western blot. Two anti-WNV prM mAbs were also generated in this study and will be extremely valuable in future studies. Preliminary analysis of the prM epitope(s) bound by these mAbs and WNV-immune sera indicate that the binding site(s) is likely to be localised to pr and is conformational.

06 Biological Sciences

West Nile virus

Kunjin Virus

Flavivirus

Monoclonal Antibody

single chain antibody

red blood cell agglutination

Recombinant Antibody

Epitope mapping

prM

Envelope Protein

Diagnostic Assay

Characterisation and recombinant expression of antigens for the rapid diagnosis of West Nile virus infection

Jody Hobson-Peters

Unknown Date

West Nile Virus (WNV) is a mosquito-borne pathogen of global significance. It is active on several continents and is responsible for recent outbreaks of fever and fatal encephalitis in humans and horses. While highly virulent strains have been reported in Europe, North, Central and South America, only a benign subtype of WNV (Kunjin virus – KUNV) occurs in Australia. However, virulent, exotic WNV strains are seen as a significant threat to Australia due to the ease with which this virus can move between continents and the presence of suitable vectors and hosts already within Australia. KUNV and WNV subtypes are antigenically and genetically very closely related and cross-react in traditional serological tests. This cross-reactivity makes it very difficult to differentiate between KUNV and WNV infections using standard serological tests. The aim of this thesis was to identify immunogenic epitopes unique to KUNV or WNV and to use these epitopes in the development of a rapid assay that would enable the diagnosis of and surveillance for exotic virulent strains of WNV in Australia. The rapid diagnostic platform chosen was a red blood cell (RBC) agglutination assay that was originally patented and commercialised by AGEN Biomedical Ltd. The RBC agglutination assay reagent consists of the Fab region of a human erythrocyte-specific monoclonal antibody (mAb) conjugated to the epitope of interest (in this instance, a WNV-specific peptide). This bi-functional reagent causes the agglutination of the patient’s erythrocytes in the presence of WNV-specific antibody in the patient’s serum. Traditionally, these RBC agglutination reagents have been produced by chemical conjugation. However, a potentially easier and cheaper method involves the linking of the gene encoding the erythrocyte-specific antibody to that encoding the epitope to create a recombinant version of the bi-functional agglutination reagent through expression using prokaryotic or eukaryotic systems. To identify potential differential epitopes, 18 mAbs to WNV (NY99 strain) prM and envelope (E) proteins were assessed. One mAb (17D7) differentially recognised WNV and KUNV in ELISA and maintained recognition of its corresponding epitope upon reduction and carboxymethylation of the viral antigen, suggesting a continuous (linear) epitope. Using synthetic peptides, the epitope was mapped to a 19 amino acid sequence (WN19: E147-165) encompassing the WNV NY99 E protein glycosylation site at position 154. An amino acid substitution at position E156 of many KUNV strains abolishes this glycosylation moiety. The inability of WNV-positive horse and mouse sera to bind the synthetic peptides indicated that glycosylation was required for recognition of peptide WN19 by WNV-specific antibodies in sera. N-linked glycosylation of WN19 was achieved through expression of the peptide as a C-terminal fusion protein in mammalian cells and specific reactivity of WNV-positive horse sera to the glycosylated WN19 fusion protein was shown by Western blot. Additional sera collected from horses that had been infected with Murray Valley encephalitis virus (MVEV), which is similarly glycosylated at position E154 and exhibits high sequence identity to WNV NY99 in this region, also recognised the recombinant peptide. In contrast, no reactivity with the recombinant peptide was observed by sera from horses infected with the unglycosylated WNV subtype, KUNV. Failure of most WNV- and MVEV-positive horse sera to recognise the epitope as a deglycosylated fusion protein (75% and 100% respectively) confirmed that the N-linked glycan is important for antibody recognition of the peptide. Together, these results suggest that the induction of antibodies to the WN19 epitope during WNV infection of horses is generally associated with E protein glycosylation of the infecting viral strain. To assess the feasibility of using peptide WN19 in a rapid immunoassay, the peptide was recombinantly fused to a RBC (glycophorin)-specific single chain antibody (scFv) using previously published constructs which were developed for the bacterial expression of similar bi-functional reagents. To facilitate glycosylation of peptide WN19, the genes for the bi-functional agglutination reagents were subsequently cloned into eukaryotic expression vectors. An additional set of constructs were also produced in which the genes for the variable regions of the anti-RBC antibody were cloned into a vector for the secreted expression of an intact, humanised IgG1 molecule. Stable cell lines were produced for each of these constructs and secreted up to 700 ng/mL glycophorin-reactive antibody. The secreted recombinant protein could be harvested directly from the cell culture medium and used in RBC agglutination assays, where these bi-functional agglutination reagents could be cross-linked either with mAb 17D7 or by anti-peptide WN19 antibodies present in WNV-positive horse serum. The WNV NY99 prM protein was also identified as a useful marker of WNV-infection in horses, as well as a putative antigen to differentiate equine WNV NY99 and KUNV infections using Western blot. Two anti-WNV prM mAbs were also generated in this study and will be extremely valuable in future studies. Preliminary analysis of the prM epitope(s) bound by these mAbs and WNV-immune sera indicate that the binding site(s) is likely to be localised to pr and is conformational.

06 Biological Sciences

West Nile virus

Kunjin Virus

Flavivirus

Monoclonal Antibody

single chain antibody

red blood cell agglutination

Recombinant Antibody

Epitope mapping

prM

Envelope Protein

Diagnostic Assay

Characterisation and recombinant expression of antigens for the rapid diagnosis of West Nile virus infection

Jody Hobson-Peters

Unknown Date

West Nile Virus (WNV) is a mosquito-borne pathogen of global significance. It is active on several continents and is responsible for recent outbreaks of fever and fatal encephalitis in humans and horses. While highly virulent strains have been reported in Europe, North, Central and South America, only a benign subtype of WNV (Kunjin virus – KUNV) occurs in Australia. However, virulent, exotic WNV strains are seen as a significant threat to Australia due to the ease with which this virus can move between continents and the presence of suitable vectors and hosts already within Australia. KUNV and WNV subtypes are antigenically and genetically very closely related and cross-react in traditional serological tests. This cross-reactivity makes it very difficult to differentiate between KUNV and WNV infections using standard serological tests. The aim of this thesis was to identify immunogenic epitopes unique to KUNV or WNV and to use these epitopes in the development of a rapid assay that would enable the diagnosis of and surveillance for exotic virulent strains of WNV in Australia. The rapid diagnostic platform chosen was a red blood cell (RBC) agglutination assay that was originally patented and commercialised by AGEN Biomedical Ltd. The RBC agglutination assay reagent consists of the Fab region of a human erythrocyte-specific monoclonal antibody (mAb) conjugated to the epitope of interest (in this instance, a WNV-specific peptide). This bi-functional reagent causes the agglutination of the patient’s erythrocytes in the presence of WNV-specific antibody in the patient’s serum. Traditionally, these RBC agglutination reagents have been produced by chemical conjugation. However, a potentially easier and cheaper method involves the linking of the gene encoding the erythrocyte-specific antibody to that encoding the epitope to create a recombinant version of the bi-functional agglutination reagent through expression using prokaryotic or eukaryotic systems. To identify potential differential epitopes, 18 mAbs to WNV (NY99 strain) prM and envelope (E) proteins were assessed. One mAb (17D7) differentially recognised WNV and KUNV in ELISA and maintained recognition of its corresponding epitope upon reduction and carboxymethylation of the viral antigen, suggesting a continuous (linear) epitope. Using synthetic peptides, the epitope was mapped to a 19 amino acid sequence (WN19: E147-165) encompassing the WNV NY99 E protein glycosylation site at position 154. An amino acid substitution at position E156 of many KUNV strains abolishes this glycosylation moiety. The inability of WNV-positive horse and mouse sera to bind the synthetic peptides indicated that glycosylation was required for recognition of peptide WN19 by WNV-specific antibodies in sera. N-linked glycosylation of WN19 was achieved through expression of the peptide as a C-terminal fusion protein in mammalian cells and specific reactivity of WNV-positive horse sera to the glycosylated WN19 fusion protein was shown by Western blot. Additional sera collected from horses that had been infected with Murray Valley encephalitis virus (MVEV), which is similarly glycosylated at position E154 and exhibits high sequence identity to WNV NY99 in this region, also recognised the recombinant peptide. In contrast, no reactivity with the recombinant peptide was observed by sera from horses infected with the unglycosylated WNV subtype, KUNV. Failure of most WNV- and MVEV-positive horse sera to recognise the epitope as a deglycosylated fusion protein (75% and 100% respectively) confirmed that the N-linked glycan is important for antibody recognition of the peptide. Together, these results suggest that the induction of antibodies to the WN19 epitope during WNV infection of horses is generally associated with E protein glycosylation of the infecting viral strain. To assess the feasibility of using peptide WN19 in a rapid immunoassay, the peptide was recombinantly fused to a RBC (glycophorin)-specific single chain antibody (scFv) using previously published constructs which were developed for the bacterial expression of similar bi-functional reagents. To facilitate glycosylation of peptide WN19, the genes for the bi-functional agglutination reagents were subsequently cloned into eukaryotic expression vectors. An additional set of constructs were also produced in which the genes for the variable regions of the anti-RBC antibody were cloned into a vector for the secreted expression of an intact, humanised IgG1 molecule. Stable cell lines were produced for each of these constructs and secreted up to 700 ng/mL glycophorin-reactive antibody. The secreted recombinant protein could be harvested directly from the cell culture medium and used in RBC agglutination assays, where these bi-functional agglutination reagents could be cross-linked either with mAb 17D7 or by anti-peptide WN19 antibodies present in WNV-positive horse serum. The WNV NY99 prM protein was also identified as a useful marker of WNV-infection in horses, as well as a putative antigen to differentiate equine WNV NY99 and KUNV infections using Western blot. Two anti-WNV prM mAbs were also generated in this study and will be extremely valuable in future studies. Preliminary analysis of the prM epitope(s) bound by these mAbs and WNV-immune sera indicate that the binding site(s) is likely to be localised to pr and is conformational.

06 Biological Sciences

West Nile virus

Kunjin Virus

Flavivirus

Monoclonal Antibody

single chain antibody

red blood cell agglutination

Recombinant Antibody

Epitope mapping

prM

Envelope Protein

Diagnostic Assay

Pilus antigen incidence and conferred immunity of whole bacterins and pilus vaccines in guinea pigs and pregnant gilts

Baughman, Gary Loyd

January 2011

Typescript (photocopy). / Digitized by Kansas Correctional Industries

Veterinary immunology

Escherichia coli infections

Antigen-antibody reactions

Immunity and Autoimmunity: Host Mimicry by HIV-1

Yang, Guang

January 2015

<p>Many human monoclonal antibodies that neutralize multiple clades of HIV-1 are polyreactive and bind avidly to mammalian autoantigens. Indeed, the generation of neutralizing antibodies to the 2F5 and 4E10 epitopes of HIV-1 gp41 in man may be proscribed by immune tolerance since mice expressing the VH and VL of 2F5 have an arrested B-cell development characteristic of central tolerance. This developmental blockade implies the presence of tolerizing autoantigens that mitigate effective humoral responses. I hypothesize that discreet human antigens are mimicked by the membrane-proximal external region (MPER) of HIV-1 gp41, and that such mimicry is a wide-spread strategy for HIV-1 to evade immune attacks to its vulnerable neutralizing epitopes.</p><p>In the first part of the study, I propose to identify autoantigens mimicked by the 2F5 and 4E10 epitopes. I used immunoprecipitation coupled with mass spectrometry as well as protein arrays to identify the self-antigens recognized by 2F5 and 4E10. The binding of antigens was confirmed using serological assays and targeted mutagenesis was used to map the binding epitope. We identified human kynureninase (KYNU) and splicing factor 3b subunit 3 (SF3B3) as the primary conserved, vertebrate self-antigens recognized by the 2F5 and 4E10 antibodies, respectively. 2F5 binds the H4 domain of KYNU which contains the complete 2F5 linear epitope (ELDKWA). 4E10 recognizes a conformational epitope of SF3B3 that is strongly dependent on hydrophobic interactions. Opossums carry a rare KYNU H4 domain that abolishes 2F5 binding, but retain all SF3B3 4E10 epitopes. Immunization of opossums with HIV-1 gp140 induced extraordinary titers of serum antibody to the 2F5 ELDKWA epitope but little or nothing to the 4E10 determinant.</p><p>Our identification of structural motif shared by vertebrates and HIV-1 provides direct evidence that immunological tolerance can impair humoral responses to HIV-1. In the second part of the project, I propose to study the mechanisms of immune tolerance to B cells expressing the 2F5 antibodies. To determine the B cell repertoire before and after tolerance checkpoints, I used the Nojima-Kitamura single B-cell culture that supports differentiation into IgG-secreting plasma cells, even autoreactive cells that are normally subject to tolerization in vivo. I found that the pre-tolerance compartment (small pre-B) from 2F5 KI mice are cells that express the 2F5 V(D)J rearrangements and bind HIV-1 gp41, KYNU, and cardiolipin. Mature, post-tolerance B cells from 2F5 KI mice, however, are purged of gp41- and KYNU-reactivity, but retain cardiolipin-binding, and sequence analysis revealed extensive light-chain editing. The anergic B cells in the post-tolerance compartment are enriched with self-reactivity to KYNU and maintain binding to HIV-1 gp41. Our results demonstrate that tolerance of the 2F5 epitope is driven by specific reactivity to KYNU, but not general cross-reactivity to cardiolipin. In addition, that the peripheral anergic B cells retain self-reactivity and binding to HIV-1 gp41 suggests a potential target for activation by immunizations.</p><p>Lastly, we sought to determine whether the host mimicry by 4E10 and 2F5 epitopes is also present in other HIV-1 epitopes, including additional conserved neutralizing epitopes and more importantly, non-neutralizing epitopes. We used protein microarrays to assess autoreactivity of HIV-1 broadly neutralizing antibodies (bnAbs) and non-neutralizing antibodies (nnAbs) and found that as a class, bnAbs are more polyreactive and autoreactive than nnAbs. The poly- and autoreactive property is therefore not a result of chronic inflammation, but rather uniquely associated with neutralization, consistent with the role of heteroligation for HIV-1 neutralizing activity. In addition, mutation frequencies of bNAbs and nnAbs per se do not correlate with poly- and autoreactivity. Our results demonstrate that HIV-1 bnAbs are significantly more polyreactive and self-reactive than non-neutralizers, which may subject them to immunological tolerance control in vivo. Infrequent poly- or autoreactivity among nnAbs implies that their dominance in humoral responses is due to the absence of negative control by immune tolerance.</p><p>The results of this study indicate that mimicry of host antigens by HIV-1 is an effective mechanism to camouflage vulnerable neutralizing epitopes of HIV-1 and evade host immune responses. As a result, protective HIV-1 bnAbs are rare and often poly- or autoreactive, constituting a major hurdle that must be overcome to effectively elicit protective responses by an HIV-1 vaccine.</p> / Dissertation

Immunology

Virology

Antibody

bnAb

HIV-1

Host mimicry

tolerance

Identification and characterization of a positive regulatory region for activation induced cytidine deaminase mediated gene conversion in chicken B cells

Kim, Yonghwan, 1975-

23 August 2010

B cells have unique machinery to make up a large pool of antibody repertoire. After V(D)J recombination in early B cell development, the rearranged immunoglobulin genes are further diversified by somatic hypermutation (SHM), gene conversion (GC) and class switch recombination (CSR). Acitvation induced cytidine deaminase (AID) is a key initiating factor for SHM, GC and CSR. A majority of research data supports the model that AID modifies Ig genes at the DNA level by deaminating cytosines to uracils. The mutagenic activity of AID is largely restricted to Ig genes to avoid genomic instability in general. The specificity cannot be attributed to the primary sequence of the Ig genes since unrelated DNA is mutated by AID in the context of Ig genes. A clue to this problem is that AID function is dependent on transcription. Since not all transcribed genes are mutated by AID, there must be something special about the transcription of Ig genes, and the reasoning has prompted extensive analysis of Ig promoters and enhancers. We addressed this question in chicken B cell line DT40. We identified a 2.4-kilobase regulatory region which is important for AID function both within and outside of Ig locus. This regulatory region contains binding sites for multiple transcription factors. Mutation of these binding sites impairs AID mediated gene conversion. In addition, ablation of NF-κB family member, c-Rel and p50, reduces the AID targeting function of this regulatory region. Since the implicated transcription factors have been reported to associate with histone acetylases, the regulatory region may function by facilitating the access of AID to target DNA. To test this hypothesis, we used the I-SceI endonuclease and dam methylase as probes for chromatin structure. We found that the regulatory region does not increase chromatin accessibility to these probes. In fact, the regulatory region appears to interfere with the cleavage of target DNA by I-SceI. Another possible role of the regulatory region could be direct recruitment of AID to Ig genes. To test this hypothesis, we utilized Dam identification method. Surprisingly, we found that the regulatory region facilitates AID targeting to the Igλ locus. / text

Antibody diversification

Gene conversion

DNA repair

B cells

Transcription

Identification of scFv reagents which recognise the human neural cell adhesion molecule expressed upon neuroblastoma cells

Zebedee, Zoë Anna-Marie

January 2001

No description available.

572.8

ANALYTICAL APPLICATIONS OF SEMI-SYNTHETIC BIOSURFACES.

SPORTSMAN, JOHN RICHARD.

January 1982

Antibodies specific for insulin and human immunoglobulin G (HlgG) were attached to controlled pore glass (CPG) particles which had been silanized with a diol-bearing silane. Up to 20 mg of antibody protein could be attached covalently to 1 gram of CPG. Such immobilized antibodies, or immunosorbents, would bind specific antigens, but not unrelated proteins, when used in a high pressure liquid chromatographic configuration. This technique was given the name "high performance immunoaffinity chromatography" (HPIC). The HPIC properties of these immunosorbents were evaluated by an equilibrium theory and were found to be comparable to batch values. An immunosorbent for HIgG antigen showed an HPIC association constant of 10⁷·⁶; the batch equilibrium constant for the same immunosorbent was 10⁷·⁸. Two different anti-insulin immunosorbents retained the intrinsic affinity (10⁶ and 10⁹) of the antibody used to make them. The total active antibody concentrations of these immunosorbents were evaluated by HPIC and batch methods with good agreement between the two. The immobilization reaction was seen to result typically in the loss of 90% of the original antibody activity. HPIC was shown to be applicable to the rapid analysis of antigens at levels as low as ng/mL. This was found to be possible in part because of the rapid forward kinetics which were assessed by HPIC. A forward rate constant of 3 X 10⁷ L·mol⁻¹·sec⁻¹ for the binding of insulin by a specific HPIC column could be determined. The possibility of HPIC fluorescence immunoassays was investigated using a highly sensitive fluorescence detector. An Eimac collimated xenon arc lamp provided sufficient power to detect picomolar levels of fluorescamine labeled insulin and other compounds. The limitations of HPIC in performing picomolar immunoassays were thus shown to be immunochemical rather than instrumental. The ability of immunoaffinity purifications to overcome these limitations was demonstrated.

Immunochemistry -- Technique.

Affinity chromatography.

Immunoadsorption.

Immunoassay -- Technique.

Antigen-antibody reactions.

IN VITRO PRODUCTION AND SPECIFICITY OF ANTI-DNA AUTO ANTIBODIES BY NEW ZEALAND BLACK/NEW ZEALAND WHITE F1 MICE

Babakhani, Farah Kondori, 1960-

January 1986

No description available.

Antigen-antibody reactions.

Immunoglobulins.