Characterization of Human Anti-Dengue NS1 Monoclonal Antibodies Derived from Patients Infected with DENV-2.

Mouse antibodies specific to dengue NS1 have been widely investigated for their cross-reactivity with several human biomolecules. This is the first study demonstrating the cross-reactivity of human monoclonal antibodies (HuMAbs) specific to dengue NS1 isolated from patients infected with dengue virus serotype-2 (DENV-2). Nine anti-NS1 HuMAbs, which were mainly derived from patients in convalescent-phase after secondary infection of DENV-2, were characterized. Their cross-reactivity with plasminogen, thrombin, and endothelial cells was investigated, following which plasmin-formation assays were performed. All anti-NS1 HuMAbs exhibited cross-reactivity with human plasminogen (Plg), but not with thrombin or endothelial cells. Moreover, all HuMAbs exhibiting cross-reactivity with Plg converted Plg to plasmin in the plasmin-formation assay. These results suggest the implications and drawbacks of using anti-NS1 antibodies in immunotherapy.

Human single-chain variable fragment antibody expressed in E. coli with optimal in vitro cross-neutralizing and no enhancing activity.

Single chain fragment variable (scFv) is a small molecule antibody comprising of only the variable region of heavy and light chain responsible for antigen binding. For dengue disease, the Fc region of antibody molecule was reported to be involved with dengue complication caused by Antibody-dependent enhancement (ADE). We attempted to produce small molecule scFv human monoclonal antibody (HuMAb), which lacking the Fc portion to eliminate the ADE effect of the IgG. This scFv antibody was produced in Escherichia coli. The biologically active form of scFv antibody was successfully generated. 23-1C2D2-scFv showed neutralizing activity similar to the IgG obtained from parental hybridoma, but lacked enhancing activity in all studied concentrations. This antibody was targeted to the 101WXN103 motif of dengue envelop protein domain II, studied by western blot analysis with truncated E protein and random peptide phage display. This scFv is verified as a candidate for further development as therapeutic candidate for DENV infection.

Generation and characterization of cross neutralizing human monoclonal antibody against 4 serotypes of dengue virus without enhancing activity.

BACKGROUND: Dengue disease is a leading cause of illness and death in the tropics and subtropics. Most severe cases occur among patients secondarily infected with a different dengue virus (DENV) serotype compared with that from the first infection, resulting in antibody-dependent enhancement activity (ADE). Our previous study generated the neutralizing human monoclonal antibody, D23-1B3B9 (B3B9), targeting the first domain II of E protein, which showed strong neutralizing activity (NT) against all four DENV serotypes. However, at sub-neutralizing concentrations, it showed ADE activity in vitro. METHODS: In this study, we constructed a new expression plasmid using the existing IgG heavy chain plasmid as a template for Fc modification at position N297Q by site-directed mutagenesis. The resulting plasmid was then co-transfected with a light chain plasmid to produce full recombinant IgG (rIgG) in mammalian cells (N297Q-B3B9). This rIgG was characterized for neutralizing and enhancing activity by using different FcγR bearing cells. To produce sufficient quantities of B3B9 rIgG for further characterization, CHO-K1 cells stably secreting N297Q-B3B9 rIgG were then established. RESULTS: The generated N297Q-B3B9 rIgG which targets the conserved N-terminal fusion loop of DENV envelope protein showed the same cross-neutralizing activity to all four DENV serotypes as those of wild type rIgG. In both FcγRI- and RII-bearing THP-1 cells and FcγRII-bearing K562 cells, N297Q-B3B9 rIgG lacked ADE activity against all DENV serotypes at sub-neutralizing concentrations. Fortunately, the N297Q-B3B9 rIgG secreted from stable cells showed the same patterns of NT and ADE activities as those of the N297Q-B3B9 rIgG obtained from transient expression against DENV2. Thus, the CHO-K1 stably expressing N297Q-B3B9 HuMAb can be developed as high producer stable cells and used to produce sufficient amounts of antibody for further characterization as a promising dengue therapeutic candidate. DISCUSSION: Human monoclonal antibody, targeted to fusion loop of envelope domainII (EDII), was generated and showed cross-neutralizing activity to 4 serotypes of DENV, but did not cause any viral enhancement activity in vitro. This HuMAb could be further developed as therapeutic candidates.

CONSTRUCTION AND EXPRESSION OF H5N1 INFLUENZA VIRUS HEMAGGLUTININ-SPECIFIC scFv-Fc MONOCLONAL ANTIBODIES IN HEK293T CELLS.

Monoclonal antibody (MAb) is a key element in the development of rapid test kits for many infectious diseases. Our group previously developed two antigen-binding fragment (Fab) MAbs, H5Fab-6 and H5Fab-9, specific to hemagglutinin (H5 HA) of influenza A virus H5N1, but these Fabs do not have a constant fragment (Fc) portion with which to bind with gold particles in a strip test. In order to overcome this impediment, we joined a single-chain variable fragment (scFv) with an Fc region to produce a scFv-Fc MAb, which was expressed in mammalian HEK293T cells. Specificity and sensitivity of each generated scFv-Fc MAb for H5 HA was tested using western blotting and dot-enzyme-linked immunosorbent assay (dot-ELISA), respectively. Two scFv-Fcs (designated H5scFvFc-6 and H5scFvFc-9) were constructed and purified to near homogeneity with a yield of 12.87 mg/l and 33.56 mg/l, respectively. Western blotting indicated that both scFv-Fcs reacted as expected with H5 HA with a sensitivity of 60 pg of H5 HA. These scFv-Fc MAbs should prove useful in the development of antibody-based diagnostic tools.

Molecular genetic characterization of rabies virus glycoprotein gene sequences from rabid dogs in Bangkok and neighboring provinces in Thailand, 2013-2014.

Because of its association with dogs, rabies virus (RABV) is still endemic in Thailand, where it is a serious public health problem. The genetic characterization of RABV in Thailand is limited. Therefore, in this study, we investigated the molecular epidemiology and genetic diversity of RABV in the endemic area. Viral RNA from 48 brain specimens from rabid dogs, collected in Bangkok and seven neighboring provinces in 2013-2014, was extracted and sequenced. The complete rabies glycoprotein (G) gene sequences (1575 nt) were aligned, and a phylogenetic analysis was performed using the maximum-likelihood method. All of the Thai rabies virus isolates belonged to lyssavirus genotype 1 and clustered in the same lineage as isolates from South East Asia (SEA) and China. The Thai rabies virus isolates formed two distinct clades, THA-1 and THA-2. Clade THA-1 was the predominant clade and could be divided into two subclades, THA-1A and THA-1B. Clade THA-2 was closely associated with human Thai isolates collected in a previous study. The overall mean rate of evolution based on the G gene was approximately 1.56 × 10(-4) substitutions/site/year. The genetic identities among the isolates from Thailand and other SEA countries were >88.4 % at the nucleotide sequence level and 95 % at the amino acid sequence level. The deduced amino acid sequences of the G proteins of the RABV isolates were compared. A single amino acid change (N194T) in subclade THA-1A distinguished the Thai RABV isolates from other RABV isolates. Our results suggest that these Thai dog RABV isolates share a common ancestor with the RABV isolates circulating in the endemic regions of SEA countries and China. Furthermore, there were strong genetic relationship to RABV from Cambodia, Vietnam and Laos. These data extend our understanding of the relatedness and genetic variation of RABV in Thailand.

Co-existence of major and minor viral populations from two different origins in patients secondarily infected with dengue virus serotype 2 in Bangkok.

Generally, RNA viruses exhibit significant genetic diversity that sometimes effect viral fitness in infected hosts and probably also pathogenesis. Dengue viruses (DENVs) consist of four antigenically distinct serotypes. All the serotypes of DENV can cause mild to severe dengue illnesses. In this study, we examined the sequence variation of DENV in plasma obtained from four patients living in Bangkok who had been secondarily infected with serotype 2 (DENV-2) in 2010. The plasma-derived RNA was directly subjected to reverse transcriptase (RT)-polymerase chain reaction (PCR) at a region including most of domain III of the envelope (E) protein gene, and the PCR products obtained were subjected to clonal sequencing. Using 19-20 clones sequenced from each patient (78 total) plus 601 corresponding sequences from a public database, phylogenetic analysis revealed that the nucleic acid sequences fell into two clusters with clearly different origins. Interestingly, all patients gave sequences indicating that they carried viral populations containing 2, 3 or 5 genetic variants that consisted of one major variant plus one or more minor variants. Three patients showed a major variant from one cluster plus one or more minor components from the other while one showed major and minor variants from a single cluster. Thus, it can be concluded that DENV belonging to two different genetic lineages were co-circulated in Bangkok in 2010. For these two genotype clusters there was also a clear difference in H or Y at the deduced amino acid position 346 (i.e. H346Y) that was consistent for our sequences and 601 sequences from the public database. Thus, one among the mixed viral genotypes introduced into human individuals seems to be variably selected as the predominant component of the carried viral population, and it is possible that the dynamics of this process could influence virus evolution and disease severity.