Your search keyword '"Salunke, Dinakar M."' showing total 9 results

1. A structure and knowledge-based combinatorial approach to engineering universal scFv antibodies against influenza M2 protein.

Author

Kumar, Ujjwal, Goyal, Priya, Madni, Zaid K., Kamble, Kajal, Gaur, Vineet, Rajala, Maitreyi S., and Salunke, Dinakar M.

Subjects

PEPTIDES, INFLUENZA, INFLUENZA A virus, H1N1 subtype, IMMUNOGLOBULINS, INFLUENZA viruses, FIBRIN fragment D, VIRAL envelope proteins

Abstract

Background: The influenza virus enters the host via hemagglutinin protein binding to cell surface sialic acid. Receptor-mediated endocytosis is followed by viral nucleocapsid uncoating for replication aided by the transmembrane viral M2 proton ion channel. M2 ectodomain (M2e) is a potential universal candidate for monoclonal antibody therapy owing to its conserved nature across influenza virus subtypes and its importance in viral propagation. Methods: The phage-displayed naive human antibody libraries were screened against the short stretch of the N-terminal 10-mer peptide (SLLTEVETPI) of the M2e. ELISA, BLI, and flow cytometry assays were used to examine scFv binding to M2e epitopes. The scFv crystal structures were determined to examine the nature of the interactions. The potencies of the scFvs against the influenza virus were demonstrated by real-time PCR and confocal microscopy imaging. Results: The four unique scFv clones were obtained from the scFv phage-display antibody libraries and shown to exhibit binding with the 10-mer conserved part of the M2e and with full-length M2 protein expressed on the HEK293T cells. The crystal structure of scFv AU1 with M2e peptide showed the peptide as a dimer in the parallel beta-sheet conformation bound at the interface of two scFv CDRs. The scFv AU1 significantly restricted the release of H1N1 virus progeny from the infected A549 cells. Conclusion: This structural and biochemical study showcased the binding of antibody scFv molecules with M2e peptide dimer, providing the structural insights for the function effect in terms of recognizing and restricting the release of new viral particles from an infected host cell. [ABSTRACT FROM AUTHOR]

Published

2023

2. Directed evolution -- bringing the power of evolution to the laboratory: 2018 Nobel Prize in Chemistry.

Author

Verma, Sheenam and Salunke, Dinakar M.

Subjects

*NOBEL Prize in Chemistry, *BIOMASS energy, *IMMUNOGLOBULINS

Abstract

The article talks about 2018 Nobel Prize in Chemistry winners Frances H. Arnold, George P. Smith, and Gregory P. Winter. It is mentioned that the scientists used Darwinian revolution to work to design molecules from living organisms that eventually led to the development of cleaner biofuels and drugs for treating diseases including psoriasis. The article they used principles of selectively reproducing desired traits to make specific molecules, namely enzymes and antibodies.

Published

2018

3. Antibody promiscuity: Understanding the paradigm shift in antigen recognition.

Author

Kaur, Harmeet and Salunke, Dinakar M.

Subjects

*IMMUNOGLOBULINS, *IMMUNE recognition, *PROMISCUITY, *CONFORMATIONAL analysis, *EPITOPES, *GERM cells

Abstract

Affinity maturation is associated with reduced malleability of the paratope that optimizes an antibody to bind to the bonafide antigen with high specificity and affinity. However, it has been illustrated that mature antibodies tend to exhibit promiscuity despite acquisition of a relatively rigid binding pocket. Such an attribute is contrary to the established paradigm of specificity in antigen recognition. In this review, an explicit dissection of the underlying mechanisms fostering such versatility in mature antibodies has been done. Polyspecificity is essentially achieved by undergoing minimal structural rearrangement at the paratope complemented with plasticity in interaction with antigen. Besides, the structural invariance of the antigen across species could modulate mature antibody specificity. Polyreactivity has been well documented for germline antibodies as broad spectrum antibody repertoire amplification is primarily governed by recombination event of the genetic machinery, which is further expanded at the structural and functional level of interaction. Degenerate specificity in antigen recognition obviates the need to produce distinct antibody for every incoming epitope © 2015 IUBMB Life, 67(7):498-505, 2015 [ABSTRACT FROM AUTHOR]

Published

2015

4. Adjustable Locks and Flexible Keys: Plasticity of Epitope-Paratope Interactions in Germline Antibodies.

Author

Khan, Tarique and Salunke, Dinakar M.

Subjects

*IMMUNOGLOBULINS, *EPITOPES, *GERM cells, *MOLECULAR conformation, *PEPTIDES

Abstract

Ag recognition by independent primary Abs against a small flexible Ag with overlapping epitopes was analyzed to address the determinants of Ag specificity during the initial encounter. Crystal structures of two distinct dodecapeptide Ags, GDPRPSYISHLL and PPYPAWHAPGNI, in complex with the germline mAb 36-65 were determined and compared with the structures of the same Ags bound to another independent germline mAb, BBE6.12H3. For each peptide Ag, the two germline mAbs recognized overlapping epitopes, but in different topologies. The peptide structures differed, and the two paratopes attained discrete conformations, leading to different surface topologies, in a mode that can be described as adjustable locks and flexible keys. This is in contrast to mature mAbs, in which conformational convergence of different paratopes while binding to a common epitope in a similar conformation has been reported. These results suggest that the primary immune receptor repertoire is highly versatile as compared with its mature counterpart. Germline and mature mAbs adopt distinct mechanisms for recognizing a flexible epitope. Whereas conservation of conformational repertoire is a key characteristic of mature mAbs achieved through affinity maturation, the germline mAbs, at the initial stages of Ag encounter, maintain substantial plasticity, accommodating a broad specificity repertoire. [ABSTRACT FROM AUTHOR]

Published

2014

5. Antigen exposure leads to rigidification of germline antibody combining site.

Author

Gill, Jasmita, Jayaswal, Praapti, and Salunke, Dinakar M.

Subjects

ANTIGENS, SEROTYPES, IMMUNOGLOBULINS, FORCE & energy, MATHEMATICS

Abstract

Immune complexes involving diverse antigens and corresponding antibodies were analyzed for mapping conformational transitions of an antibody before antigen binding, upon antigen binding and after antigen release. Molecular dynamics simulations of the two comprehensive datasets consisting of the antigen-free and antigen-bound structures of the germline antibodies 36-65 and BBE6.12H3 provided mechanistic model of antigen encounter by primary antibodies. While native germline antibodies exhibit substantial mobility in the antigen-combining sites, their antigen-bound states exhibit relatively rigid conformations, even in the absence of the antigen suggesting preservation of the structural state after antigen release. It is proposed that acquired rigidity by a germline antibody upon antigen binding may be the first step in affinity maturation in favor of that antigen. [ABSTRACT FROM AUTHOR]

Published

2014

6. Deciphering evolution of immune recognition in antibodies.

Author

Kaur, Harmeet, Sain, Neetu, Mohanty, Debasisa, and Salunke, Dinakar M.

Subjects

IMMUNE recognition, IMMUNOGLOBULINS, IMMUNE system, ANTIGENS, STRUCTURAL analysis (Science)

Abstract

Background: Antibody, the primary effector molecule of the immune system, evolves after initial encounter with the antigen from a precursor form to a mature one to effectively deal with the antigen. Antibodies of a lineage diverge through antigen-directed isolated pathways of maturation to exhibit distinct recognition potential. In the context of evolution in immune recognition, diversity of antigen cannot be ignored. While there are reports on antibody lineage, structural perspective with respect to diverse recognition potential in a lineage has never been studied. Hence, it is crucial to evaluate how maturation leads to topological tailoring within a lineage enabling them to interact with significantly distinct antigens. Results: A data-driven approach was undertaken for the study. Global experimental mouse and human antibody-antigen complex structures from PDB were compiled into a coherent database of germline-linked antibodies bound with distinct antigens. Structural analysis of all lineages showed variations in CDRs of both H and L chains. Observations of conformational adaptation made from analysis of static structures were further evaluated by characterizing dynamics of interaction in two lineages, mouse VH1–84 and human VH5–51. Sequence and structure analysis of the lineages explained that somatic mutations altered the geometries of individual antibodies with common structural constraints in some CDRs. Additionally, conformational landscape obtained from molecular dynamics simulations revealed that incoming pathogen led to further conformational divergence in the paratope (as observed across datasets) even while maintaining similar overall backbone topology. MM-GB/SA analysis showed binding energies to be in physiological range. Results of the study are coherent with experimental observations. Conclusions: The findings of this study highlight basic structural principles shaping the molecular evolution of a lineage for significantly diverse antigens. Antibodies of a lineage follow different developmental pathways while preserving the imprint of the germline. From the study, it can be generalized that structural diversification of the paratope is an outcome of natural selection of a conformation from an available ensemble, which is further optimized for antigen interaction. The study establishes that starting from a common lineage, antibodies can mature to recognize a wide range of antigens. This hypothesis can be further tested and validated experimentally. [ABSTRACT FROM AUTHOR]

Published

2018

7. Recombinant human scFv antibody fragments against phospholipase A2 from Naja naja and Echis carinatus snake venoms: In vivo neutralization and mechanistic insights.

Author

Kumar, Amit, Madni, Zaid Kamal, Chaturvedi, Shivam, and Salunke, Dinakar M.

Subjects

*SNAKE venom, *VENOM, *COBRAS, *PHOSPHOLIPASE A2, *PHOSPHOLIPASES, *MONOCLONAL antibodies, *IMMUNOGLOBULINS, *SNAKEBITES, *ANTIVENINS

Abstract

Snake envenomation results in a range of clinical sequelae, and widely used animal-based conventional antivenoms exhibit several limitations including the adverse immunological effects in human snake bite victims. Therefore, human monoclonal anti-snake venom antibodies or fragments can be an alternate therapy for overcoming the existing limitations. We developed venom-neutralizing humanized scFv antibodies and analyzed biochemical mechanisms associated with the inhibition of toxicity. Tomlinson I and J human scFv antibody libraries were screened against Naja naja and Echis carinatus venoms, and seven unique scFv antibodies were obtained. Further, specific toxins of snake venom interacting with each of these scFvs were identified, and phospholipase A2 (PLA2) was found to be prominently captured by the phage-anchored scFv antibodies. Our study indicated PLA2 to be one of the abundant toxins in Naja naja and Echis carinatus venom samples. The scFvs binding to PLA2 were used to perform in vivo survival assay using the mouse model and in vitro toxin inhibition assays. scFv N194, which binds to acidic PLA2, protected 50% of mice treated with Naja naja venom. Significant prolongation of survival time and 16% survival were observed in Echis carinatus venom-challenged mice treated with scFv E113 and scFv E10, respectively. However, a combination comprised of an equal amount of two scFvs, E113 and E10, both interacting with basic PLA2, exhibited synergistically enhanced survival of 33% in Echis carinatus venom-challenged mice. No such synergistically enhanced survival was observed in the case of combinatorial treatment with anti- Naja naja scFvs, N194, and N248. These scFvs demonstrated partial inhibition of venom-induced myotoxicity, and E113 also inhibited hemolysis by 50%, which corroborates the enhanced survival during combinatorial treatment in Echis carinatus venom-challenged mice. • Conventional antivenoms exhibit adverse effects in snakebite victims. • Seven human scFvs antibody fragments against two prominent Indian snake venoms were isolated. • Majority of antibodies were specific to phospholipase A2, which is an abundant toxin in both venoms. • These antibodies partially inhibited venom-induced myotoxicity, and one of them also exhibited partial hemolysis inhibition. • Antibodies developed against PLA2 exhibited partial in vivo venom neutralization. [ABSTRACT FROM AUTHOR]

Published

2024

8. Antibody multispecificity: A necessary evil?

Author

Jaiswal, Deepika, Verma, Sheenam, Nair, Deepak T., and Salunke, Dinakar M.

Subjects

*IMMUNOGLOBULINS, *HUMORAL immunity, *MONOCLONAL antibodies, *VIROIDS, *ANTIBODY diversity, *IMMUNE response, *IMMUNE system

Abstract

Antibodies represent key effectors of the adaptive immune system. The specificity of antibodies is an established hallmark of the immune response. However, a certain proportion of antibodies exhibit limited promiscuity or multireactivity. Germline antibodies display plasticity which imparts multispecificity to enhance the antibody repertoire. Surprisingly, even affinity matured antibodies display such plasticity and multireactivity enabling their binding to more than one antigen. We propose that antibody multispecificity is a physiological requirement to expand the antibody repertoire at the germline level and to tolerate plasticity in antigens at the mature level. This property of the humoral immune response may attenuate the ability of infectious RNA viruses such as influenza, HIV and SARS-CoV-2 to acquire mutations that render resistance to neutralizing antibodies. • Antibodies (Abs) ensure specificity and fidelity of immune response. • Multispecificity is a physiological requirement of the immune system. • Ability of germline Abs to recognize distinct antigens enhances Ab diversity. • Multispecificity of mature Abs may retard evolution of highly mutable pathogens. [ABSTRACT FROM AUTHOR]

Published

2022

9. MP-4 Contributes to Snake Venom Neutralization by Mucuna pruriens Seeds through an Indirect Antibody-mediated Mechanism.

Author

Kumar, Ashish, Gupta, Chitra, Nair, Deepak T., and Salunke, Dinakar M.

Subjects

*SNAKE venom, *COWHAGE, *IMMUNOGLOBULINS, *SNAKEBITES, *MORTALITY, *PUBLIC health

Abstract

Mortality due to snakebite is a serious public health problem, and available therapeutics are known to induce debilitating side effects. Traditional medicine suggests that seeds of Mucuna pruriens can provide protection against the effects of snakebite. Our aim is to identify the protein(s) that may be important for snake venom neutralization and elucidate its mechanism of action. To this end, we have identified and purified a protein from M. pruriens, which we have named MP-4. The full-length polypeptide sequence of MP-4 was obtained through N-terminal sequencing of peptide fragments. Sequence analysis suggested that the protein may belong to the Kunitz-type protease inhibitor family and therefore may potentially neutralize the proteases present in snake venom. Using various structural and biochemical tools coupled with in vivo assays, we are able to show that MP-4 does not afford direct protection against snake venom because it is actually a poor inhibitor of serine proteases. Further experiments showed that antibodies generated against MP-4 cross-react with the whole venom and provide protection to mice against Echis carinatus snake venom. This study shows that the MP-4 contributes significantly to the snake venom neutralization activity of M. pruriens seeds through an indirect antibody- mediated mechanism. [ABSTRACT FROM AUTHOR]

Published

2016