Characterization of anti-ricin monoclonal antibodies and the construction of a chimeric murine-human IgG2/K anti-ricin monoclonal antibody

Vendramelli, Robert Matthew

12 April 2011

Ricin toxin is a very deadly plant protein that is synthesized by the plant Ricinus communis. The molecular structure of ricin toxin places it in a group of similar proteins classified as a Type II RIP due to its heterodimeric construction; it is composed of a toxic A-chain possessing enzymatic action, and a receptor binding B-chain. Monoclonal antibodies were obtained with binding activities against either the A-chain or B-chain, and a surrogate non-toxic ricin analogue, TST10114, was determined to be suitable for characterization of the anti-ricin monoclonal antibodies. One potent anti-ricin A-chain neutralizing monoclonal antibody was chosen for chimerization, RAC18, which exhibited strong binding affinity and neutralizing properties. The constant regions of a human immunoglobulin G2 (IgG2) were used as the backbone for the recombinant chimeric antibody. The resulting chimeric RAC18-huG2 was transiently expressed in human-derived HEK 293F cells, purified, and assessed for binding characteristics and functional attributes.

Immunology

ricin

toxin

monoclonal

antibody

chimeric

Development of an Electrochemical Immunosensor for the Detection of HIV Antibodies Using Surface Modification of SU-8

Bhimji, Alyajahan

21 November 2013

The negative epoxy-based photoresist of SU-8 has a variety of applications within microelectromechanical systems (MEMS) and lab-on-a-chip systems. Herein, SU-8 was functionalized with antigenic peptides to HIV-1 gp41 or HIV-2 gp36 and the detection of antibody against HIV-1/2 was carried out by an electrochemical immunoassay combining an alkaline phosphatase conjugated secondary antibody and p-aminophenyl phosphate. The by- product of the reaction (p-aminophenol) was quantitated electrochemically using differential pulse voltammetry, and the current derived from the oxidation of the hydrolysis product increased linearly over a wide primary antibody concentration range (0.001 – 1 μg/mL), with a detection limit of 1 ng mL-1 (6.7 pM) for both HIV-1 and HIV-2. This level of sensitivity is clinically relevant, and feasibility of this approach for clinical sample testing was also evaluated with HIV clinical patient samples.

Immunosensor

Electrochemistry

HIV

Antibody

SU-8

0541

Development of an Electrochemical Immunosensor for the Detection of HIV Antibodies Using Surface Modification of SU-8

Bhimji, Alyajahan

21 November 2013

The negative epoxy-based photoresist of SU-8 has a variety of applications within microelectromechanical systems (MEMS) and lab-on-a-chip systems. Herein, SU-8 was functionalized with antigenic peptides to HIV-1 gp41 or HIV-2 gp36 and the detection of antibody against HIV-1/2 was carried out by an electrochemical immunoassay combining an alkaline phosphatase conjugated secondary antibody and p-aminophenyl phosphate. The by- product of the reaction (p-aminophenol) was quantitated electrochemically using differential pulse voltammetry, and the current derived from the oxidation of the hydrolysis product increased linearly over a wide primary antibody concentration range (0.001 – 1 μg/mL), with a detection limit of 1 ng mL-1 (6.7 pM) for both HIV-1 and HIV-2. This level of sensitivity is clinically relevant, and feasibility of this approach for clinical sample testing was also evaluated with HIV clinical patient samples.

Immunosensor

Electrochemistry

HIV

Antibody

SU-8

0541

DEVELOPMENT AND CHARACTERIZATION OF NOVEL MONOCLONAL ANTIBODIES FOR STUDYING PRION PATHOGENESIS

Weng, Chu-Chun

01 January 2011

Monoclonal antibodies (mAbs) recognizing different regions of PrP are potential tools in the study of prion diseases and immunotherapy. We used shuffled recombinant prion protein containing elk and mouse PrP as antigen to produce monoclonal antibodies in mice. We found that mAb 5C6 mapped to a discontinuous epitope comprised of amino acid 132 and 158 (mouse numbering). Monoclonal anibody 9E9 which maps to a unique N-terminal epitope at amino acid preferentially recognized cervid PrP. In contrast, the epitope of mAb 9H9 is located in the C-terminus and only reacted with mouse and hamster. The epitope for mAb 7H11 appears to be affected by the glycosylation of PrP and by the presence or absence of the disulfide bond. To confirm the epitopes of these mAbs, we constructed elk and mouse mutants both with and without reactivity to 5C6 and 9E9. We then used these mutants to investigate the effect of each epitope on the conversion of PrPC to PrPsc. In one approach to map the epitopes of newly-generated monoclonal antibodies (mAbs), we generated a series of contiguous ten amino acids deletion constructs spanning amino acids 107 to 230 and expressed these recombinant proteins in mammalian cells (RK13) or bacteria. Using Western blotting, all deletion constructs could be recognized with antibodies to the extreme C-terminus of PrP, or the N-terminal region upstream of the structured globular domain of PrP. However, mAb 5C6 failed to react with all internally deleted PrP constructs expressed in mammalian cells, and to a lesser extent bacterially produced mutant recombinant proteins. We confirmed the surprising result using the well-defined antibodies 6H4 and D18, which recognize epitopes in the same internal region as 5C6. Our results suggest the formation of an ultra-stable, SDS-resistant conformation in PrP harboring deletions mutations in the globular domain of PrP. We hypothesize that epitope burying within this stable conformation(s) precludes mAb recognition by 5C6, 6H4 and D18. It will be of extreme interest to determine the relationship of this previously undefined PrP conformation to the pathogenic process of PrP conformational change.

Prion

epitope

Monoclonal antibody

Medicine and Health Sciences

De novo donor-specific antibodies in renal transplantation

Wiebe, Chris

10 1900

The natural history for patients with de novo donor-specific antibodies (dnDSA) and the risk factors for its development have not been well defined. Furthermore, clinical and histologic correlation with serologic data is limited. We studied 315 consecutive renal transplants without pre-transplant donor-specific antibody (DSA), with a mean follow-up of 6.2 ± 2.9 years. Protocol (n = 215) and for cause (n = 163) biopsies were analyzed. Solid phase assays were used to screen for dnDSA post-transplant. A total of 47 out of 315 (15%) patients developed dnDSA at a mean of 4.6 ± 3.0 years post-transplant. Independent predictors of dnDSA were HLA-DRβ1 MM > 0 (OR 5.66, p < 0.006); and non-adherence (OR 8.75, p < 0.001); with a strong trend toward clinical rejection episodes preceding dnDSA (OR 1.57 per rejection episode, p=0.061). The median 10-year graft survival for those with dnDSA was lower than the No dnDSA group (57% vs. 96%, p < 0.0001). Pathology consistent with antibody-mediated injury occurred and progressed in patients with dnDSA in the absence of graft dysfunction. Furthermore, non-adherence and cellular rejection contributed to both dnDSA development and the risk of progression to graft loss. (Human leukocyte antigen) HLA epitope matching is a novel strategy that may minimize dnDSA development. HLAMatchmaker software was used to characterize epitope mismatches at 395 potential HLA-DR/DQ/DP conformational epitopes for a subset of 286 donor–recipient pairs in which samples were available for high-resolution HLA-typing. Epitope specificities were assigned using single antigen HLA bead analysis and correlated with known monoclonal alloantibody epitope targets. Locus-specific epitope mismatches were more numerous in patients who developed HLA-DR dnDSA alone (21.4 vs. 13.2, p<0.02) or HLA-DQ dnDSA alone (27.5 vs. 17.3, p<0.001). An optimal threshold for epitope mismatch (10 for HLA-DR, 17 for HLA-DQ) was defined that was associated with minimal development of Class II dnDSA using a receiver operating characteristic analysis. Applying these thresholds, 0% and 2.7% of patients developed dnDSA against HLA-DR and HLA-DQ, respectively, after a median of 6.9 years follow-up. Epitope specificity analysis revealed that 3 HLA-DR and 3 HLA-DQ epitopes were independent multivariate predictors of Class II dnDSA when mismatched between the donor and recipient. HLA-DR and DQ epitope matching outperforms traditional low-resolution antigen-based matching and has the potential to minimize the risk of de novo Class II DSA development, thereby improving long-term graft outcome.

transplantation

donor-specific antibody

allograft rejection

HLA

Stability in antigenic reactivity of the major outer surface protein, OspA, in borrelia burgdorferi, during persistent infection in Syrian hamsters

Mummert, Mark E.

January 1992

The spirochete Borrelia burgdorferi is the causative agent of Lyme disease, a multisystem disorder that can cause a variety of disorders in susceptible mammalian hosts. The immune response of infected mammals, including humans, is ineffective in clearing B. burgdorferi as demonstrated by the ability to reisolate the spirochete from naturally and experimentally infected hosts after extended periods of time. Recent evidence suggests that this pathogen evades the immune response in part through changes in antigenic reactivity.The purpose of this study was to determine if outer surface protein A (OspA) of B. burqdorferi varies in the course of infection in Syrian hamsters and thus potentially plays a role in evading the host immune response. To assess the degree of change, differences in the binding of a murine monoclonal antibody (H5332) were measured using IFA and ELISA techniques over a 9-week period of time.Results of this study suggest that OspA is persistently expressed in infected Syrian hamsters for at least 9-weeks. Moreover, this protein, or at least the epitope that H5332 binds with, is stably expressed. These results indicate OspA, or at least the epitope of OspA that I probed, does not appear to contribute to the evasive mechanisms of 8. burgdorferi in Syrian hamsters. / Department of Biology

Lyme disease.

Borrelia.

Antigen-antibody reactions.

Proteomic Analysis of Chinese Hamster Ovary Cells Producing Glycosylated Monoclonal Antibodies

Ho, Raymond

January 2013

Therapeutic monoclonal antibodies (MAb) are produced as secreted complex glycoproteins from mammalian cell systems and represent one of the most important classes of therapeutic medicines for the treatment of a variety of human diseases. Their benefit in health care and high economic impact provide the driving force for the development of improved production levels with the focus of optimizing clinical efficacy. One important issue is the optimization of monoclonal antibody production. A frequent approach used to address this challenge is the engineering of mammalian cell lines to increase antibody production levels through genetic manipulation. Valuable information can then be obtained by monitoring the effects of genetic changes on the biochemistry of the cell associated with MAb production. Global protein expression profiling of mammalian cells used for the production of biopharmaceuticals may reveal key biochemical characteristics associated with MAb-producing cell lines. A better understanding of these characteristics can in turn lead to more rational strategies for cell line and process development. The proposed research relates to a larger NSERC Strategic Network (MAbNet) Grant to develop and establish a novel platform for the large-scale manufacture of specific glycoforms of therapeutic monoclonal antibodies. The efficacy of these recombinant MAbs will be enhanced by the control of their glycosylation profiles. The work presented in this thesis will assist MAbNet in meeting their objectives. Specifically, we use 2D-Differential In-Gel Electrophoresis (2D-DIGE) to quantify protein expression differences between EG2-hFc1-producing Chinese Hamster Ovary cells (CHO-1A7) with its parental cell line (CHO-BRI). Here, we identified 34 unique differentially expressed proteins associated with EG2-hFc1 production that relate to various biological processes including protein processing, carbohydrate metabolism, amino acid metabolism, energy metabolism, apoptosis, and cell proliferation pathways. The majority of identified significant protein expression changes and their associated metabolic processes seem to prioritize energy production in CHO-1A7 cells. Due to the metabolic load of recombinant antibody production, the CHO-1A7 cell line attempts to meet the energy requirements needed for recombinant protein biosynthesis while maintaining cell viability and efficient protein folding mechanisms. A 2-D proteome reference map was also constructed for the CHO-BRI host cell line containing 131 identified protein spots. The map provides information that will further expand our understanding of this particular cell line. It will be a useful tool for studies investigating physiological responses and protein expression patterns of CHO-BRI to genetic and environmental perturbations. The set of identified differentially expressed proteins provides data on the downstream changes in protein expression due to genetic manipulation, and furthermore can provide targets for cell-line specific optimization of antibody production. The work described in this thesis furthers our understanding of antibody production in a specific CHO cell line.

chinese hamster ovary

proteomic

glycosylation

monoclonal antibody

Evidence for the N-Acetylglucosaminidase Activity of a Cell Wall-associated Autolysin ISPC and its Suitability as a Diagnostic Marker for 'Listeria Monocytogenes' Serotype 4B

Ronholm, Jennifer

10 January 2013

Listeria monocytogenes is the etiological agent of a life-threatening, opportunistic infection caused by the ingestion of contaminated foods. Although L. monocytogenes is divided into 13 serotypes, 98% of human illness is caused by serotype 1/2a, 1/2b and 4b strains, with serotype 4b accounting for almost all the major outbreaks of human listeriosis. The principle objective of this work was to develop surface-binding monoclonal antibodies (MAbs) highly specific for serotype 4b, as well as characterize their antigen targets to aid in the detection and isolation of serotype 4b strains using an antibody based procedure. To create such antibodies, mice were immunized with formalin killed whole cells of L. monocytogenes serotype 4b strain LI0521. A total of 15 MAbs reactive to serotype 4b isolates were shown to recognize a ~77 kDa surface antigen subsequently identified by mass spectrometry as surface associated autolysin, IspC. Epitope mapping experiments further revealed that each of the 15 MAbs bound to the cell wall binding GW domain of IspC and can be essentially divided into 4 major groups based on epitope localization. ELISA analysis of the reactivity of each of the MAbs with various L. monocytogenes serotypes indicated that several MAbs were 100% specific for serotype 4b isolates. Surface plasmon resonance experiments showed that the affinity constants for each of these MAbs fell within the range of 1.0 x 10-7 to 6.4 x 10-9 M. To determine whether IspC, shown to be well conserved among various serotype 4b strains, is a useful diagnostic marker with antibody-based methods, the expression of IspC was assessed in L. monocytogenes cultured under normal and stress conditions. A functional promoter directing the transcription of ispC gene was identified immediately upstream of the ispC open reading frame by constructing the promoterless lacZ gene fusion with the putative ispC promoter region and by 5'RACE analysis. Data obtained with the lacZ reporter gene system and immunofluorescent microscopy revealed that IspC is expressed on the cell surface under all growth conditions tested (temperature, osmotic stress, pH, ethanol, oxidative stress, anaerobic conditions, carbon source and enrichment media) that allow for cellular division, although the level of ispC gene expression varies. In addition, a significant effort were put into elucidating the hydrolytic bond specificity of IspC by HPLC and mass spectrometry analysis of muropeptides released from IspC-mediated hydrolysis of L. monocytogenes peptidoglycan (PG). The results demonstrated that IspC functions as an N-acetylglucosaminidase capable of cleaving the β-1,4-glycosidic bond of the PG glycan strand. Furthermore, IspC was more efficient at hydrolysing fully Nacetylated PG from a PG deacetylase gene (pgdA) deletion mutant of L. monocytogenes than partially de-N-acetylated wild-type PG, indicating that modification of PG by de-Nacetylation of GlcNAc residues renders PG resistant to IspC hydrolysis. In conclusion, the surface autolysin IspC with the N-acetylglucosaminidase activity is a novel diagnostic marker for the 4b serotype strains, which can be explored , in conjunction with specific MAbs developed here, for detection and isolation of L. monocytogenes serotype 4b strains directly from food, environmental and clinical samples with the need for minimal or no culture enrichment.

listeria

peptidoglycan hydrolase

food safety

antibody

A Crucial Epitope in the Influenza A and B Viral Neuraminidase and its Broad Inhibition by a Universal Antibody

Doyle, Tracey

20 December 2013

The antigenic variability of the Influenza virus hinders our ability to develop new therapeutic and vaccine strategies which provide a broad protection against all influenza strains. It has been previously suggested that a means to approach this challenge is to identify conserved sequences within viral proteins and use these for future therapeutic targets. Although such conserved sequences are plentiful amongst the internal viral proteins, their lack of exposure to the host immune system makes mounting an immune response against these regions difficult. Alternatively, the surface glycoproteins hemagglutinin (HA) and neuraminidase (NA) have been shown to provide host protection against a limited number of influenza strains when used as vaccine targets; however conserved regions within these proteins which are also antibody accessible are extremely rare. My Ph.D. thesis project is focused on investigating the functional role of a conserved region within the NA protein and to further determine the protection afforded by a monoclonal antibody to this region. In a comprehensive bioinformatics analysis, the only universally conserved sequence amongst all influenza A and B viral NA has been previously identified as being located between amino acids (a.a.) 222-230 (dubbed the HCA-2 region). However, the potential role of this region remains largely unknown. Through an array of experimental approaches including mutagenesis, reverse genetics and growth kinetics, I have found that substitutions in this sequence significantly affect viral replication by impairing the catalytic activity, substrate-binding and thermostability of NA. These findings prompted me to further investigate if antibody to this region may provide protection against influenza infection. Indeed, universal monoclonal antibody (HCA-2 MAb) against this peptide provided broad inhibition against all nine subtypes of NA in vitro and heterosubtypic protection in mice challenged with lethal doses of mouse-adapted viruses. I further demonstrated that residues within this peptide that are exposed on the surface of NA and located in close proximity to the active site, I222 and E227, are indispensable for antibody-mediated inhibition. These data are the first to demonstrate a monoclonal antibody against the NA protein which provides heterosubtypic protection. Since I observed that the HCA-2 antibody provided a broad inhibition against all nine subtypes of influenza A NA, I decided to investigate whether this inhibitory effect could be extended against Influenza B. Here, I have further reported that HCA-2 MAb provides a broad inhibition against various strains of influenza B viruses of both Victoria and Yamagata genetic lineage. I also demonstrate that the growth and NA enzymatic activity of two drug resistant influenza B strains are also inhibited by the HCA-2 antibody. The findings of my Ph.D. thesis project have thus demonstrated that the HCA-2 region is paramount to optimal viral function. Additionally, my data show that antibodies generated against this region provide heterosubtypic protection both in vitro and in vivo and against drug resistant strains. These results indicate that this universally conserved epitope should be further explored as a potential target for future antiviral intervention and vaccine-induced immune responses.

Influenza

Antibody

Universal Epitope

Vaccine

Neuraminidase

Characterization of anti-ricin monoclonal antibodies and the construction of a chimeric murine-human IgG2/K anti-ricin monoclonal antibody

Vendramelli, Robert Matthew

12 April 2011

Ricin toxin is a very deadly plant protein that is synthesized by the plant Ricinus communis. The molecular structure of ricin toxin places it in a group of similar proteins classified as a Type II RIP due to its heterodimeric construction; it is composed of a toxic A-chain possessing enzymatic action, and a receptor binding B-chain. Monoclonal antibodies were obtained with binding activities against either the A-chain or B-chain, and a surrogate non-toxic ricin analogue, TST10114, was determined to be suitable for characterization of the anti-ricin monoclonal antibodies. One potent anti-ricin A-chain neutralizing monoclonal antibody was chosen for chimerization, RAC18, which exhibited strong binding affinity and neutralizing properties. The constant regions of a human immunoglobulin G2 (IgG2) were used as the backbone for the recombinant chimeric antibody. The resulting chimeric RAC18-huG2 was transiently expressed in human-derived HEK 293F cells, purified, and assessed for binding characteristics and functional attributes.

Immunology

ricin

toxin

monoclonal

antibody

chimeric