Chiou-Ying Yang

A novel technology for the production of a heterologous lipoprotein immunogen in high yield has implications for the field of vaccine design

We have developed a novel platform technology that can express high levels of recombinant lipoproteins with intrinsic adjuvant properties. In this study, Ag473 (a lipoprotein from Neisseria meningitidis) can be produced in high yields using Escherichia coli strain C43 (DE3). After testing a non-lipoimmunogen (E3, from dengue virus) fused with different lipid signal peptides from other lipoproteins as well as Ag473 fragments of different lengths, we identified that the fusion sequence has to contain at least the N-terminal 40 residues, D1, of Ag473 to achieve high expression levels of the recombinant lipo-immunogen (rlipo-D1E3). The rlipo-D1E3 was found to elicit stronger anti-E3 and virus neutralizing antibody responses in animal studies than those from rE3 alone or rE3 formulated with alum adjuvant. These results have successfully demonstrated the merit of lipo-immunogens for novel vaccine development.

Immunoproteomic identification of the hypothetical protein NMB1468 as a novel lipoprotein ubiquitous in Neisseria meningitidis with vaccine potential

Many potential vaccine candidates for serogroup B Neisseria meningitidis (NMB) have been identified by reverse vaccinology, a genome‐based approach. However, some candidates may be unseen owing to uncertain annotation or their peculiar properties. In this study, we describe the preparation and identification of a novel lipoprotein expressed in all meningococcal strains tested. mAb were first prepared from mice immunized with a meningococcal B strain isolated in Taiwan. Total proteins from the immunizing strain were separated by 2‐DE in duplicate. Clone 4‐7‐3, which crossreacted to 174 tested meningococcal isolates, was used as the primary antibody for Western blotting. The immunoreactive spot was identified by LC‐mass spectrometric analysis of the corresponding spot from the silver‐stained gel and confirmed by molecular biology approach to be a novel lipoprotein encoded by the hypothetical NMB1468 gene. The potential use of this protein, designated Ag473/NMB1468, as a vaccine component was evaluated using the recombinant protein produced in Escherichia coli. Immunized mice were found to be protected from developing meningococcal disease after intraperitoneal inoculation with a lethal dose of meningococcal strain Nm22209, suggesting that Ag473/NMB1468 may be a promising vaccine candidate. This study also demonstrates the usefulness of the immunoproteomic approach in identification of novel vaccine candidates.

On‐line SERS Detection of Single Bacterium Using Novel SERS Nanoprobes and A Microfluidic Dielectrophoresis Device

The integration of novel surface-enhanced Raman scattering (SERS) nanoprobes and a microfluidic dielectrophoresis (DEP) device is developed for rapid on-line SERS detection of Salmonella enterica serotype Choleraesuis and Neisseria lactamica. The SERS nanoprobes are prepared by immobilization of specific antibody onto the surface of nanoaggregate-embedded beads (NAEBs), which are silica-coated, dye-induced aggregates of a small number of gold nanoparticles (AuNPs). Each NAEB gives highly enhanced Raman signals owing to the presence of well-defined plasmonic hot spots at junctions between AuNPs. Herein, the on-line SERS detection and accurate identification of suspended bacteria with a detection capability down to a single bacterium has been realized by the NAEB-DEP-Raman spectroscopy biosensing strategy. The practical detection limit with a measurement time of 10 min is estimated to be 70 CFU mL(-1) . In comparison with whole-cell enzyme-linked immunosorbent assay (ELISA), the SERS-nanoprobe-based biosensing method provides advantages of higher sensitivity and requiring lower amount of antibody in the assay (100-fold less). The total assay time including sample pretreatment is less than 2 h. Hence, this sensing strategy is promising for faster and effective on-line multiplex detection of single pathogenic bacterium by using different bioconjugated SERS nanoprobes.

Genome, Integration, and Transduction of a Novel Temperate Phage of Helicobacter pylori

ABSTRACT Helicobacter pylori is a common human pathogen that has been identified to be carcinogenic. This study isolated the temperate bacteriophage 1961P from the lysate of a clinical strain of H. pylori isolated in Taiwan. The bacteriophage has an icosahedral head and a short tail, typical of the Podoviridae family. Its double-stranded DNA genome is 26,836 bp long and has 33 open reading frames. Only 9 of the predicted proteins have homologs of known functions, while the remaining 24 are only similar to unknown proteins encoded by Helicobacter prophages and remnants. Analysis of sequences proximal to the phage-host junctions suggests that 1961P may integrate into the host chromosome via a mechanism similar to that of bacteriophage lambda. In addition, 1961P is capable of generalized transduction. To the best of our knowledge, this is the first report of the isolation, characterization, genome analysis, integration, and transduction of a Helicobacter pylori phage.

Discovery of protective B-cell epitopes for development of antimicrobial vaccines and antibody therapeutics

Protective antibodies play an essential role in immunity to infection by neutralizing microbes or their toxins and recruiting microbicidal effector functions. Identification of the protective B‐cell epitopes, those parts of microbial antigens that contact the variable regions of the protective antibodies, can lead to development of antibody therapeutics, guide vaccine design, enable assessment of protective antibody responses in infected or vaccinated individuals, and uncover or localize pathogenic microbial functions that could be targeted by novel antimicrobials. Monoclonal antibodies are required to link in vivo or in vitro protective effects to specific epitopes and may be obtained from experimental animals or from humans, and their binding can be localized to specific regions of antigens by immunochemical assays. The epitopes are then identified with mapping methods such as X‐ray crystallography of antigen–antibody complexes, antibody inhibition of hydrogen–deuterium exchange in the antigen, antibody‐induced alteration of the nuclear magnetic resonance spectrum of the antigen, and experimentally validated computational docking of antigen–antibody complexes. The diversity in shape, size and structure of protective B‐cell epitopes, and the increasing importance of protective B‐cell epitope discovery to development of vaccines and antibody therapeutics are illustrated through examples from different microbe categories, with emphasis on epitopes targeted by broadly neutralizing antibodies to pathogens of high antigenic variation. Examples include the V‐shaped Ab52 glycan epitope in the O‐antigen of Francisella tularensis, the concave CR6261 peptidic epitope in the haemagglutinin stem of influenza virus H1N1, and the convex/concave PG16 glycopeptidic epitope in the gp120 V1/V2 loop of HIV type 1.

Molecular epidemiology of Bordetella pertussis isolated in Taiwan, 1992-1997.

In Taiwan, the number of pertussis cases including various types of infection has been increasing in recent years, especially in 1997. Since 71% of the reported cases concentrated in the densely populated Taipei metropolitan area, concerns have been raised that a highly contagious strain of Bordetella pertussis might have appeared in Taipei. In this study, 114 strains of B. pertussis including those isolated in 1992–1996 (n = 53) and 1997 (n=61) were subjected to pulsed‐field gel electrophoresis (PFGE) of the XbaI digests from their chromosomes. Based on the band patterns, they were divided into 21 subtypes, P1 to P21. The strains isolated in 1997 consist of 17 subtypes including 9 new subtypes which did not appear in the previous years, indicating that the outbreaks in 1997 were not caused by a sole specific virulent strain. Dendrogram analysis indicated that the 21 subtypes can be grouped into five clusters, with the first four subtypes possessing 60 to 95% relatedness to one another, whereas relatedness between cluster 5 (containing P21 only) and the other clusters is less than 50%. Notably, all the subtypes except P12 and P21 appeared at least once in Taipei and the majority of the strains (54%) belong to two clusters, 3 and 4. These results suggest that highly dense population may facilitate spread and accelerate genetic divergence of this pathogen. This is the first report on pertussis molecular epidemiology in Taiwan.

Polyclonal Fab phage display libraries with a high percentage of diverse clones to Cryptosporidium parvum glycoproteins

The protozoan parasite Cryptosporidium parvum is regarded as a major public health problem world-wide, especially for immunocompromised individuals. Although no effective therapy is presently available, specific immune responses prevent or terminate cryptosporidiosis and passively administered antibodies have been found to reduce the severity of infection. Therefore, as an immunotherapeutic approach against cryptosporidiosis, we set out to develop C. parvum-specific polyclonal antibody libraries, standardised, perpetual mixtures of polyclonal antibodies, for which the genes are available. A combinatorial Fab phage display library was generated from the antibody variable region gene repertoire of mice immunised with C. parvum surface and apical complex glycoproteins which are believed to be involved in mediating C. parvum attachment and invasion. The variable region genes used to construct this starting library were shown to be diverse by nucleotide sequencing. The library was subjected to one round of antigen selection on C. parvum glycoproteins or a C. parvum oocyst/sporozoite preparation. The two selected libraries showed specific reactivity to the glycoproteins as well as to the oocyst/sporozoite preparation, with 50-73% antigen-reactive members. Fingerprint analysis of individual clones from the two antigen-selected libraries showed high diversity, confirming the polyclonality of the selected libraries. Furthermore, immunoblot analysis on the oocyst/sporozoite and glycoprotein preparations with selected library phage showed reactivity to multiple bands, indicating diversity at the antigen level. These C. parvum-specific polyclonal Fab phage display libraries will be converted to libraries of polyclonal full-length antibodies by mass transfer of the selected heavy and light chain variable region gene pairs to a mammalian expression vector. Such polyclonal antibody libraries would be expected to mediate effector functions and provide optimal passive immunity against cryptosporidiosis.

The binding sites of monoclonal antibodies to the non-reducing end of Francisella tularensis O-antigen accommodate mainly the terminal saccharide.

We have previously described two types of protective B‐cell epitopes in the O‐antigen (OAg) of the Gram‐negative bacterium Francisella tularensis: repeating internal epitopes targeted by the vast majority of anti‐OAg monoclonal antibodies (mAbs), and a non‐overlapping epitope at the non‐reducing end targeted by the previously unique IgG2a mAb FB11. We have now generated and characterized three mAbs specific for the non‐reducing end of F. tularensis OAg, partially encoded by the same variable region germline genes, indicating that they target the same epitope. Like FB11, the new mAbs, Ab63 (IgG3), N213 (IgG3) and N62 (IgG2b), had higher antigen‐binding bivalent avidity than internally binding anti‐OAg mAbs, and an oligosaccharide containing a single OAg repeat was sufficient for optimal inhibition of their antigen‐binding. The X‐ray crystal structure of N62 Fab showed that the antigen‐binding site is lined mainly by aromatic amino acids that form a small cavity, which can accommodate no more than one and a third sugar residues, indicating that N62 binds mainly to the terminal Qui4NFm residue at the nonreducing end of OAg. In efficacy studies with mice infected intranasally with the highly virulent F. tularensis strain SchuS4, N62, N213 and Ab63 prolonged survival and reduced blood bacterial burden. These results yield insights into how antibodies to non‐reducing ends of microbial polysaccharides can contribute to immune protection despite the smaller size of their target epitopes compared with antibodies to internal polysaccharide regions.

Expression of the sperm fibrous sheath protein CABYR in human cancers and identification of α-enolase as an interacting partner of CABYR-a.

Calcium-binding tyrosine phosphorylation regulated protein (CABYR), a family of isoforms resulting from alternative splicing, has been identified as a cancer/testis antigen (CT88) in lung cancer and hypothesized to be a promising target for immunotherapy. Here, we report the expression of CABYR in various cancer tissues/cell lines. Expression profiles of individual isoforms were different among cancers. Furthermore, protein and mRNA levels did not correlate for individual isoforms. While CABYR-c/d were the most abundant splicing variants, CABYR-a was the predominant protein isoform. Finally, CABYR-a, but not CABYR-c, was found to interact with α-enolase in vivo. Collectively, the data indicate that CABYR is a CT antigen widely expressed in diverse cancer cells. However, individual protein isoforms may be differentially regulated by post-transcriptional and post-translational mechanisms and may have a unique role in carcinogenesis. The protein expression pattern of various CABYR isoforms is important with regard to the consideration of using CABYR as a target antigen for the development of vaccines for cancer therapy.

Biochemical characterizations of Escherichia coli-expressed protective antigen Ag473 of Neisseria meningitides group B.

Polysaccharide-based vaccines against Neisseria meningitidis (Nm) serogroups A, C, Y and W135 have been available since 1970, but similar vaccine candidates developed for Nm group B (NmB) have not been successful due to both poor immunogenicity and their potential immunological cross-reactivity with human neurological tissue. In previous reports, a protective antigen and vaccine candidate, Ag473, was identified using proteomics and NmB-specific bactericidal monoclonal antibody. To initiate human phase one clinical trials, antigen production and characterization, pre-clinical toxicology and animal studies are required. In the present study, we report the biochemical characterization of Escherichia coli-expressed recombinant Ag473 (rAg473). Using MALDI-TOF mass analysis, chromatographically purified rAg473 was found to have two major isoforms that have molecular masses of 11,306 and 11,544amu, respectively. The isoforms were separated using RP-HPLC and pooled into two fractions. Based on the chromatogram, the ratio of lipoproteins in fractions #1 and #2 was found to be 1-2. GC-MS analysis of lipoproteins was performed, and the acylated fatty acids were identified. The results indicated that the first lipoproteins in fraction #1 contained the lipids palmitic acid (C16:0), cyclopropaneoctanoic acid (C17:1) and, predominately, stearic acid (C18:0). A different lipid composition of cyclopropaneoctanoic acid (C17:1), oleic acid (C18:1) and, predominately, palmitic acid (C16:0) was found in the second lipoprotein fraction. Both lipoprotein isoforms were tested and found to have Toll-like receptor (TLR) agonist activity in stimulating cytokine secretion from THP-1 cells. Circular dichroism (CD) analysis showed the secondary structure of rAg473 to be dominated by α-helices (48%), and the overall protein structure was stable up to 60°C and could refold after having been exposed to a temperature cycle from 20 to 90°C. In addition, the solubility of rAg473 (5mg/mL) was not affected after several freeze-thaw cycles. These biophysical and immunological properties make rAg473 a good vaccine candidate against NmB.