Generation of a nanobody against HER2 tyrosine kinase using phage display library screening for HER2-positive breast cancer therapy development.

Human epidermal growth factor receptor 2 (HER2) protein overexpression is found in ~30% of invasive breast carcinomas and in a high proportion of noninvasive ductal carcinomas in situ. Targeted cancer therapy is based on monoclonal antibodies and kinase inhibitors and reflects a new era of cancer therapy. However, delivery to tumor cells in vivo is hampered by the large size (150 kDa) of conventional antibodies. Furthermore, there are many disadvantages with the current anti-HER2 drug, including drug resistance and adverse effects. Nanobodies (15 kDa), single-domain antibody (sdAb) fragments, can overcome these limitations. This study produced the recombinant sdAb against the HER2-tyrosine kinase (HER2-TK) domain using phage display technology. Three specific anti-HER2-TK sdAbs were selected for further characterization. Hallmark VHH residue identification and amino acid sequence analysis revealed that clone numbers 4 and 22 were VH antibodies, whereas clone number 17 was a VH H antibody (nanobody). The half-maximal inhibitory concentration of VHH17 exhibited significantly greater HER2 kinase-inhibition activity than the other clones. Consistent with these results, several charges and polar residues of the HER2-TK activation loop that were predicted based on mimotope analysis also appeared in the docking result and interacted via the CDR1, CDR2 and CDR3 loops of VHH17. Furthermore, the cell-penetrable VHH17 (R9 VHH17) showed cell-penetrability and significantly decreased HER2-positive cancer cell viability. Thus, the VH H17 could be developed as an effective therapeutic agent to treat HER2-positive breast cancer.

Chebulin: Terminalia chebula Retz. fruit-derived peptide with angiotensin-I-converting enzyme inhibitory activity.

Angiotensin-I-converting enzyme (ACE) plays an important role in blood pressure regulation. In this study, an ACE-hexapeptide inhibitor (Asp-Glu-Asn-Ser-Lys-Phe) designated as chebulin was produced from the fruit protein of Terminalia chebula Retz. by pepsin digestion, ultrafiltrated through a 3 KDa cut-off membrane, a reverse-phase high-performance liquid chromatography, and nano-liquid chromatography tandem mass spectrometry analysis. Chebulin was found to inhibit ACE in a noncompetitive manner, as supported by the structural model. It bounds to ACE by the hydrogen bond, hydrophobic and ionic interactions via the interactions of C-terminal Phe (Phe-6), and N-terminal residues (Asp-1 and Glu-2) with the amino acid residues on noncatalytic sites of the ACE. The results showed that chebulin derived from fruits of T. chebula Retz. is a potential ACE-peptide inhibitor that could be used as a functional food additive for the prevention of hypertension and as an alternative to ACE inhibitor drug.

Peptide inhibitors against dengue virus infection.

Dengue virus (DENV) infection has become a public health problem worldwide. The development of anti-DENV drug is urgently needed because neither licensed vaccine nor specific drug is currently available. Inhibition of DENV attachment and entry to host cells by blocking DENV envelope (E) protein is an attractive strategy for anti-DENV drug development. A hydrophobic pocket on the DENV E protein is essential for structural transition in the membrane fusion, and inhibition of this process is able to inhibit DENV infection. To search for a safe anti-DENV drug, we identified short peptides targeting the hydrophobic pocket by molecular docking. In addition, the information of predicted ligand-binding site of reported active compounds of DENV2 hydrophobic pocket was also used for peptide inhibitors selection. The di-peptide, EF, was the most effective on DENV2 infection inhibition in vitro with a half maximal inhibition concentration (IC50) of 96 µm. Treatment of DENV2 with EF at the concentration of 200 µm resulted in 83.47% and 84.15% reduction in viral genome and intracellular E protein, respectively. Among four DENV serotypes, DENV2 was the most effective for the inhibition. Our results provide the proof of concept for the development of therapeutic peptide inhibitors against DENV infection by the computer-aided molecular design.

Generation of human single-chain variable fragment antibodies specific to dengue virus non-structural protein 1 that interfere with the virus infectious cycle.

Severe forms of dengue virus (DENV) infection frequently cause high case fatality rate. Currently, there is no effective vaccine against the infection. Clinical cases are given only palliative treatment as specific anti-DENV immunotherapy is not available and it is urgently required. In this study, human single-chain variable fragment (HuScFv) antibodies that bound specifically to the conserved non-structural protein-1 (NS1) of DENV and interfered with the virus replication cycle were produced by using phage display technology. Recombinant NS1 (rNS1) of DENV serotype 2 (DENV2) was used as antigen in phage bio-panning to select phage clones that displayed HuScFv from antibody phage display library. HuScFv from two phagemid transformed E. coli clones, i.e., clones 11 and 13, bound to the rNS1 as well as native NS1 in both secreted and intracellular forms. Culture fluids of the HuScFv11/HuScFv13 exposed DENV2 infected cells had significant reduction of the infectious viral particles, implying that the antibody fragments affected the virus morphogenesis or release. HuScFv epitope mapping by phage mimotope searching revealed that HuScFv11 bound to amino acids 1-14 of NS1, while the HuScFv13 bound to conformational epitope at the C-terminal portion of the NS1. Although the functions of the epitopes and the molecular mechanism of the HuScFv11 and HuScFv13 require further investigations, these small antibodies have high potential for development as anti-DENV biomolecules.

Human single-chain variable fragment antibody inhibits macrophage migration inhibitory factor tautomerase activity.

Macrophage migration inhibitory factor (MIF) is a pro-inflammatory cytokine, secreted from a variety of immune cells, that regulates innate and adaptive immune responses. Elevation of MIF levels in plasma correlates with the severity of inflammatory diseases in humans. Inhibition of MIF or its tautomerase activity ameliorates disease severity by reducing inflammatory responses. In this study, the human single-chain variable fragment (HuScFv) antibody specific to MIF was selected from the human antibody phage display library by using purified recombinant full-length human MIF (rMIF) as the target antigen. Monoclonal HuScFv was produced from phage-transformed bacteria and tested for their binding activities to rMIF by indirect enzyme-linked immunosorbent assay as well as to native MIF by western blot analysis and immunofluorescence assay. The HuScFv with highest binding signal to rMIF also inhibited the tautomerase activities of both rMIF and native MIF in human monoblastic leukemia (U937) cells in a dose-dependent manner. Mimotope searching and molecular docking concordantly demonstrated that the HuScFv interacted with Lys32 and Ile64 in the MIF tautomerase active site. To the best of our knowledge, this is the first study to focus on MIF-specific fully-human antibody fragment with a tautomerase-inhibitory effect that has potential to be developed as anti-inflammatory biomolecules for human use.

Humanized-VH/VHH that inhibit HCV replication by interfering with the virus helicase activity.

NS3 helicase is a pivotal enzyme involved in the early and late phases of hepatitis C virus (HCV) replication. The primary sequence and tertiary structure of this virus enzyme differ from human helicase to a certain extent; thus this virus protein has potential as a novel anti-HCV target. In this study, recombinant C-terminal NS3 protein of HCV genotype 3a with endowed helicase activity was produced and used as antigen by selecting VH/V(H)H display phage clones from an established humanized-camel single domain antibody library that bound specifically to HCV helicase. The VH/V(H)H derived from phage transfected Escherichia coli clones were linked molecularly to a cell penetrating peptide, i.e., penetratin (PEN). The cell penetrable VH/V(H)H (transbodies) could reduce the amounts of the HCV RNA released into the cell culture fluid and inside Huh7 cells infected with pJFH1 replicon with a greater effect on the former compared to the latter. Regions and residues of the helicase bound by the transbodies were determined by phage mimotope searching and multiple alignments as well as homology modeling and molecular docking. The epitope of one transbody (PEN-V(H)H9) encompassed residues 588RLKPTLHGPTPLLYRLGA605 of the domain 3 necessary for helicase activity while another transbody (PEN-VH59) interacted with the areas covering the phenylalanine loop and arginine clamp of the domain 2 which are important for the proper folding of the enzyme as well as nucleic acid substrate binding. Although the molecular mechanisms of the prototypic transbodies on NS3 helicase need further investigation, these transbodies have high potential as novel, safe and mutation tolerable anti-HCV agents.

Human monoclonal ScFv specific to NS1 protein inhibits replication of influenza viruses across types and subtypes.

Currently, there is a need of new anti-influenza agents that target influenza virus proteins other than ion channel M2 and neuraminidase. Non-structural protein-1 (NS1) is a highly conserved multifunctional protein which is indispensable for the virus replication cycle. In this study, fully human single chain antibody fragments (HuScFv) that bound specifically to recombinant and native NS1 were produced from three huscfv-phagemid transformed Escherichia coli clones (nos. 3, 10 and 11) selected from a human ScFv phage display library. Western blot analysis, mimotope searching/epitope identification, homology modeling/molecular docking and phage mimotope ELISA inhibition indicated that HuScFv of clone no. 3 reacted with NS1 R domain important for host innate immunity suppression; HuScFv of clone nos. 10 and 11 bound to E domain sites necessary for NS1 binding to the host eIF4GI and CPSF30, respectively. The HuScFv of all clones could enter the influenza virus infected cells and interfered with the NS1 activities leading to replication inhibition of viruses belonging to various heterologous A subtypes and type B by 2-64-fold as semi-quantified by hemagglutination assay. Influenza virus infected cells treated with representative HuScFv (clone 10) had up-expression of IRF3 and IFN-ß genes by 14.75 and 4.95-fold, respectively, in comparison with the controls, indicating that the antibodies could restore the host innate immune response. The fully human single chain antibodies have high potential for developing further as a safe (adjunctive) therapeutic agent for mitigating, if not abrogating, severe symptoms of influenza.

The molecular prevalence and MSA-2b gene-based genetic diversity of Babesia bovis in dairy cattle in Thailand.

Bovine babesiosis is an economically significant disease that affects dairy farming operations in Thailand. In the present study, 1824 blood-DNA samples prepared from cattle bred in 4 different regions of the country (North, Northeast, Central, and South) were screened using a nested PCR for the specific detection of Babesia bovis. While the overall prevalence of B. bovis was 8.8%, the Central region of Thailand was found to be a high-risk area of the country, as the prevalence of the parasite was 15.0%. The positive rate was relatively higher among the animals of 1-5 years of age. The genetic diversity among the B. bovis parasites was also studied based on their MSA-2b gene, and the findings showed that the Thai sequences were dispersed across 8 of 13 total clades observed in the phylogram. Three of these clades were formed only of Thai sequences. Similarity among the deduced MSA-2b amino acid sequences determined in the present study was 68.3-100%. In conclusion, the present study found that all the locations surveyed were infected with B. bovis and that the parasite populations in Thailand were genetically diverse. Our findings highlight the need for further studies in Thailand to generate more information before a sound control strategy could be implemented against B. bovis.

Human monoclonal ScFv that bind to different functional domains of M2 and inhibit H5N1 influenza virus replication.

BACKGROUND: Novel effective anti-influenza agent that tolerates influenza virus antigenic variation is needed. Highly conserved influenza virus M2 protein has multiple pivotal functions including ion channel activity for vRNP uncoating, anti-autophagy and virus assembly, morphogenesis and release. Thus, M2 is an attractive target of anti-influenza agents including small molecular drugs and specific antibodies. METHODS: Fully human monoclonal single chain antibodies (HuScFv) specific to recombinant and native M2 proteins of A/H5N1 virus were produced from huscfv-phagemid transformed E. coli clones selected from a HuScFv phage display library using recombinant M2 of clade 1 A/H5N1 as panning antigen. The HuScFv were tested for their ability to inhibit replication of A/H5N1 of both homologous and heterologous clades. M2 domains bound by HuScFv of individual E. coli clones were identified by phage mimotope searching and computerized molecular docking. RESULTS: HuScFv derived from four huscfv-phagemid transformed E. coli clones (no. 2, 19, 23 and 27) showed different amino acid sequences particularly at the CDRs. Cells infected with A/H5N1 influenza viruses (both adamantane sensitive and resistant) that had been exposed to the HuScFv had reduced virus release and intracellular virus. Phage peptide mimotope search and multiple alignments revealed that conformational epitopes of HuScFv2 located at the residues important for ion channel activity, anti-autophagy and M1 binding; epitopic residues of HuScFv19 located at the M2 amphipathic helix and cytoplasmic tail important for anti-autophagy, virus assembly, morphogenesis and release; epitope of HuScFv23 involved residues important for the M2 activities similar to HuScFv2 and also amphipathic helix residues for viral budding and release while HuScFv27 epitope spanned ectodomain, ion channel and anti-autophagy residues. Results of computerized homology modelling and molecular docking conformed to the epitope identification by phages. CONCLUSIONS: HuScFv that bound to highly conserved epitopes across influenza A subtypes and human pathogenic H5N1clades located on different functional domains of M2 were produced. The HuScFv reduced viral release and intracellular virus of infected cells. While the molecular mechanisms of the HuScFv await experimental validation, the small human antibody fragments have high potential for developing further as a safe, novel and mutation tolerable anti-influenza agent especially against drug resistant variants.

Cell penetrable humanized-VH/V(H)H that inhibit RNA dependent RNA polymerase (NS5B) of HCV.

NS5B is pivotal RNA dependent RNA polymerase (RdRp) of HCV and NS5B function interfering halts the virus infective cycle. This work aimed to produce cell penetrable humanized single domain antibodies (SdAb; VH/V(H)H) that interfere with the RdRp activity. Recombinant NS5BΔ55 of genotype 3a HCV with de novo RNA synthetic activity was produced and used in phage biopanning for selecting phage clones that displayed NS5BΔ55 bound VH/V(H)H from a humanized-camel VH/V(H)H display library. VH/V(H)H from E. coli transfected with four selected phage clones inhibited RdRp activity when tested by ELISA inhibition using 3'di-cytidylate 25 nucleotide directed in vitro RNA synthesis. Deduced amino acid sequences of two clones showed V(H)H hallmark and were designated V(H)H6 and V(H)H24; other clones were conventional VH, designated VH9 and VH13. All VH/V(H)H were linked molecularly to a cell penetrating peptide, penetratin. The cell penetrable VH9, VH13, V(H)H6 and V(H)H24 added to culture of Huh7 cells transfected with JHF-1 RNA of genotype 2a HCV reduced the amounts of RNA intracellularly and in culture medium implying that they inhibited the virus replication. VH/V(H)H mimotopes matched with residues scattered on the polymerase fingers, palm and thumb which were likely juxtaposed to form conformational epitopes. Molecular docking revealed that the antibodies covered the RdRp catalytic groove. The transbodies await further studies for in vivo role in inhibiting HCV replication.

Humanized-single domain antibodies (VH/VHH) that bound specifically to Naja kaouthia phospholipase A2 and neutralized the enzymatic activity.

Naja kaouthia (monocled cobra) venom contains many isoforms of secreted phospholipase A2 (sPLA(2)). The PLA(2) exerts several pharmacologic and toxic effects in the snake bitten subject, dependent or independent on the enzymatic activity. N. kaouthia venom appeared in two protein profiles, P3 and P5, after fractionating the venom by ion exchange column chromatography. In this study, phage clones displaying humanized-camel single domain antibodies (VH/V(H)H) that bound specifically to the P3 and P5 were selected from a humanized-camel VH/V(H)H phage display library. Two phagemid transfected E. coli clones (P3-1 and P3-3) produced humanized-V(H)H, while another clone (P3-7) produced humanized-VH. At the optimal venom:antibody ratio, the VH/V(H)H purified from the E. coli homogenates neutralized PLA(2) enzyme activity comparable to the horse immune serum against the N. kaouthia holo-venom. Homology modeling and molecular docking revealed that the VH/V(H)H covered the areas around the PLA(2) catalytic groove and inserted their Complementarity Determining Regions (CDRs) into the enzymatic cleft. It is envisaged that the VH/V(H)H would ameliorate/abrogate the principal toxicity of the venom PLA(2) (membrane phospholipid catabolism leading to cellular and subcellular membrane damage which consequently causes hemolysis, hemorrhage, and dermo-/myo-necrosis), if they were used for passive immunotherapy of the cobra bitten victim. The speculation needs further investigations.

Human ScFv that block sodium ion channel activity of tetrodotoxin.

Tetrodotoxin (TTX) is a heterocyclic guanidinium alkaloid (C11H17N3O8) with molecular mass of ∼320 Da. The TTX and toxic analogs block sodium ion activity of mammalian nerve cells resulting in failure to conduct nerve impulse which manifested clinically in host as variable degrees of organ paralysis. Human intoxication occurs after consuming food containing the toxins. Current treatment of the poisoning is supportive and symptomatic. There has been no specific drug or antidote for the TTX mediated malady. In this study, phage clones displaying human single chain antibody fragments (HuScFv) were selected from a human ScFv phage display library. HuScFv derived from phagemid transformed Escherichia coli clones (clones s16 and s35) bound to the TTX as tested by indirect ELISA and band shift assay. Homology modeling and molecular docking revealed that VL domain of the s16-HuScFv interacted with the hydroxyl groups of C6, C9, C10 and C11 of the TTX by means of Tyr 223, Ser226 and Tyr228, while the Asp53 and Asp55 of the VH domain of s35-HuScFv interacted with the positions 1 and 2 of the guanidinium group and the hydroxyl groups at C9 and C10 of the TTX. The s16- and s35-HuScFv neutralized the TTX bioactivity in nerve cell based- and mouse bio-assays. Moreover, the HuScFv could rescue the intoxicated mice from the TTX mediated lethality. Thus, the HuScFv derived from the transformed E. coli clones have high potential as a safe, effective and specific therapeutic remedy for TTX intoxication in humans and warrant further trials.