{"id":27,"date":"2023-11-02T18:20:42","date_gmt":"2023-11-02T18:20:42","guid":{"rendered":"https:\/\/www-cxcp1.tifrh.res.in\/~kmandal\/?page_id=27"},"modified":"2025-05-07T08:52:54","modified_gmt":"2025-05-07T08:52:54","slug":"publications","status":"publish","type":"page","link":"https:\/\/www.tifrh.res.in\/~kmandal\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

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PUBLICATIONS<\/h3>\n

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\"\"<\/a><\/p>\n

(* Corresponding author; \u00a7 Equal contribution)<\/p>\n

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  1. Mannuthodikayil J, Malik V, Kar A, Singh S, Mandal K*<\/font><\/strong> (2025)<\/b> Chemical Protein Engineering: Backbone Cyclization Rescues Folding of a Truncated 183-Residue Domain 1 of Malaria Parasite Protein Pf<\/em>AMA1.<\/a> Chemistry \u2013 A European Journal<\/b><\/em>,\u00a0e202500894.<\/li>\n

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  2. Biswas A, Narayan A, Sinha S, Mandal K*<\/font><\/strong> (2025)<\/b> Chemically Engineered Peptide Efficiently Blocks Malaria Parasite Entry into Red Blood Cells.<\/a> Biochemistry<\/b><\/em> (DOI: 10.1021\/acs.biochem.4c00465).<\/li>\n

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  3. Sinha S, Biswas A, Sahil M, Mondal J, Mandal K*<\/font><\/strong> (2025)<\/b> A Cryptic Loop that Modulates Protein-Protein Interaction: Implications in PfAMA1-PfRON2 Late-stage Binding Event.<\/a> ChemBioChem<\/b><\/em> (DOI: 10.1002\/cbic.202400894).<\/li>\n

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  4. Biswas A, Sarkar A, Kurussi S R*, Mandal K*<\/font><\/strong> (2025)<\/b> Optimizing SARS-CoV-2 RBD Boundaries for Enhanced E. coli Expression.<\/a> bioRxiv<\/b><\/em>\u00a0doi:\u00a0https:\/\/doi.org\/10.1101\/2025.01.16.633331.<\/li>\n

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  5. Singh S, Mandal K<\/font><\/strong>, Chakravarty M* (2025)<\/b> Tetra-benzimidazoles flanking from divinyl-phenothiazine: AIEgens as aza-Michael acceptors in concentration-tuned responses to biogenic amine vapors.<\/a> Chemical Communications<\/b><\/em> 61: 728\u2013731.<\/li>\n

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  6. Kar A, Narayan A, Malik V, Mandal K*<\/font><\/strong> (2024)<\/b> Rational Engineering of an Antimalarial Peptide with Enhanced Proteolytic Stability and Preserved Parasite Invasion Inhibitory Activity.<\/a> RSC Chemical Biology<\/b><\/em> 6: 65-72.<\/li>\n

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  7. Singh S, Mandal K*<\/font><\/strong>, Chakravarty M* (2024)<\/b> Access to Diverse Glutamic Acid Dendrons and a Janus Peptide Dendrimer Using an Atypical Solid Phase Synthesis.<\/a> The Journal of Organic Chemistry<\/b><\/em> 89: 11261\u221211271.<\/li>\n

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  8. Maity T, Sarkar S, Kundu S, Panda S, Sarkar A, Hammad R, Mandal K<\/font><\/strong>, Ghosh S*, Mondal J*, Haldar R* (2024)<\/b> Steering diffusion selectivity of chemical isomers within aligned nanochannels of metal-organic framework thin film.<\/a> Nature Communications<\/b><\/em> 15: 9636.<\/li>\n

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  9. Ghatage T, Singh S, Mandal K<\/font><\/strong>, Dhar A* (2024)<\/b> Co-activation of Mas and pGCA receptors suppresses Endothelin-1-induced endothelial dysfunction via nitric oxide\/cGMP system.<\/a> Biochimica et Biophysica Acta (BBA) – Molecular Basis of Disease<\/b><\/em> 1870(4): 167110.<\/li>\n

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  10. Kar A, Jana M, Malik V, Sarkar A, Mandal K*<\/font><\/strong> (2024)<\/b> Total Chemical Synthesis of the SARS-CoV-2 Spike Receptor-Binding Domain.<\/a> Chemistry \u2013 A European Journal<\/b><\/em> 30(3): e202302969.<\/li>\n

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  11. Biswas A, Narayan A, Sinha S, Mandal K*<\/font><\/strong> (2023)<\/b> A conformationally constrained synthetic peptide efficiently inhibits malaria parasite entry into human red blood cells.<\/a> bioRxiv<\/b><\/em> 2023.06.23.546305.<\/li>\n

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  12. Ghatage T, Singh S, Mandal K<\/font><\/strong>, Dhar A* (2023)<\/b> MasR and pGCA receptor activation protects primary vascular smooth muscle cells and endothelial cells against oxidative stress via inhibition of intracellular calcium.<\/a> Journal of Cellular Biochemistry<\/b><\/em> 124: 943-960.<\/li>\n

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  13. Mannuthodikayil J, Sinha S, Singh S, Biswas A, Ali I, Mashurabad PC, Tabassum W, Vydyam P, Bhattacharyya MK, Mandal K*<\/font><\/strong> (2023)<\/b> A chimeric peptide inhibits red blood cell invasion by Plasmodium falciparum<\/em> with hundredfold increased efficacy.<\/a> ChemBioChem<\/b><\/em> 24: e202200533. {Featured on the cover page}<\/strong><\/li>\n

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  14. Ghatage T, Singh S, Mandal K<\/font><\/strong>, Jadhav KB, Dhar A* (2023)<\/b> Activation of Mas and pGCA receptor pathways protects renal epithelial cell damage against oxidative-stress-induced injury.<\/a> Peptides<\/b><\/em> 162: 170959.<\/li>\n

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  15. Chakraborty S, Mandal K<\/font><\/strong>, Ramakrishnan R* (2023)<\/b> Understanding the Role of Intramolecular Ion-Pair Interactions in Conformational Stability Using an Ab Initio Thermodynamic Cycle.<\/a> Journal of Physical Chemistry B<\/b><\/em> 127: 648\u2013660.<\/li>\n

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  16. Sinha S, Biswas A, Mondal J*, Mandal K*<\/font><\/strong> (2021)<\/b> Computational and experimental studies of Plasmodium falciparum<\/em> protein PfAMA1 domain-II loop dynamics: implications in PfAMA1-PfRON2 binding event.<\/a> bioRxiv<\/b><\/em>.<\/li>\n

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  17. Das A, Yadav A, Gupta M, Purushotham R, Terse VL, Vishvakarma V, Singh S, Nandi T, Banerjee A, Mandal K<\/font><\/strong>, Gosavi S, Das R, Ainavarapu SRK, Maiti S (2021)<\/b> Rational design of protein-specific folding modifiers.<\/a> Journal of the American Chemical Society<\/b><\/em> 143: 18766-18776.<\/li>\n

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  18. Sarkar A, Mandal K*<\/font><\/strong> (2021)<\/b> Repurposing an Antiviral Drug against SARS-CoV-2 Main Protease.<\/a> Angewandte Chemie International Edition<\/b><\/em> (Highlight) 60: 23492-23494.<\/li>\n

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  19. Biswas A, Raran-Kurussi S, Narayan A, Kar A, Mashurabad PC, Bhattacharyya MK, Mandal K*<\/font><\/strong> (2021)<\/b> Efficient refolding and functional characterization of PfAMA1(DI+DII) expressed in E. coli<\/em>.<\/a> Biochemistry and Biophysics Reports<\/b><\/em> 26: 100950.<\/li>\n

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  20. Thakur P, Mannuthodikayil J*, Kalita G, Mandal K*<\/font><\/strong>, Narayanan TN* (2021)<\/b> In Situ Surface Modification of Bulk or Nano Materials by Cytochrome-c for Active Hydrogen Evolution Catalysis.<\/a> Materials Chemistry Frontiers<\/b><\/em> 5: 1295-1300. {Featured on the cover page}<\/strong><\/li>\n

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  21. Kar A, Mannuthodikayil J, Singh S, Biswas A<\/strong>, Dubey P, Das A, Mandal K*<\/font><\/strong> (2020)<\/b> Efficient Chemical Protein Synthesis using Fmoc-Masked N-Terminal Cysteine in Peptide Thioester Segments.<\/a> Angewandte Chemie International Edition<\/b><\/em> 59: 14796-14801.<\/li>\n

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  22. Kumar M, Mandal K<\/font><\/strong>, Blakeley MP, Wymore T, Kent SBH, Louis JM, Das A, Kovalevsky A (2020)<\/b> Visualizing Tetrahedral Oxyanion Bound in HIV-1 Protease Using Neutrons: Implications for the Catalytic Mechanism and Drug Design.<\/a> ACS Omega<\/b><\/em> 5: 11605\u221211617.<\/li>\n

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  23. Mannuthodikayil J*, Narayanaru S, Thakur P, Bawari S, Narayanan TN*, Mandal K*<\/font><\/strong> (2020)<\/b> Protein denaturation induced electrocatalytic hydrogen evolution.<\/a> Carbon<\/b><\/em> 165: 378\u2013385.<\/li>\n

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  24. Mannuthodikayil J, Singh S, Biswas A, Kar A, Tabassum W, Vydyam P, Bhattacharyya MK, Mandal K*<\/font><\/strong> (2019)<\/b> Benzimidazolinone-free peptide o-aminoanilides for chemical protein synthesis.<\/a> Organic Letters<\/b><\/em> 21: 9040\u20139044.<\/li>\n

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  25. Dang B, Shen R, Kubota T, Mandal K<\/font><\/strong>, Bezanilla F, Roux B, Kent SBH* (2017)<\/b> Inversion of the Side-Chain Stereochemistry of Individual Thr or Ile Residues in a Protein Molecule: Impact on the Folding, Stability, and Structure of the ShK Toxin.<\/a> Angewandte Chemie International Edition<\/b><\/em> 56: 3324\u20133328.<\/li>\n

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  26. Dhayalan B, Mandal K<\/font><\/strong>, Rege N, Weiss MA, Eitel SH, Meier T, Schoenleber RO, Kent SBH* (2017)<\/b> Scope and limitations of Fmoc chemistry SPPS-based approaches to the total synthesis of insulin lispro via ester insulin.<\/a> Chemistry \u2013 A European Journal<\/b><\/em> 23: 1709\u20131716.<\/li>\n

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  27. Mandal K*<\/font><\/strong>, Dhayalan B, Avital-Shmilovici M, Tokmakoff A, Kent SBH (2016)<\/b> Crystallization of enantiomerically pure proteins from quasiracemic mixtures: structure determination by X-ray diffraction of isotope-labeled ester insulin and human insulin.<\/a> ChemBioChem<\/b><\/em> 17: 421\u2013425.<\/li>\n

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  28. Dhayalan B, Fitzpatrick A, Mandal K<\/font><\/strong>, Whittaker J, Weiss MA, Tokmakoff A, Kent SBH* (2016)<\/b> Efficient Total Chemical Synthesis of 13<\/sup>C=18<\/sup>O Isotopomers of Human Insulin for Isotope-Edited FTIR.<\/a> ChemBioChem<\/b><\/em> 17: 415\u2013420.<\/li>\n

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  29. Lee DJ, Uppalapati M, Mandal K<\/font><\/strong>, Li H, Miranda LP, Lowitz J, Kenney J, Adams JJ, Ault-Rich\u00e9 D, Kent SBH*, Sidhu SS* (2016)<\/b> A Potent D-Protein Antagonist of VEGF-A is Nonimmunogenic, Metabolically Stable, and Longer-Circulating in Vivo.<\/a> ACS Chemical Biology<\/b><\/em> 16: 1058\u20131065. {Featured as ACS Editors\u2019 Choice, February 3, 2016}<\/strong><\/li>\n

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  30. Bunker R, Mandal K<\/font><\/strong>, Bashiri G, Chaston J, Pentelute BL, Lott JS, Kent SBH*, Baker EN* (2015)<\/b> A Functional Role of Rv1738 in Mycobacterium tuberculosis<\/em> Persistence Suggested by Racemic Protein Crystallography.<\/a> Proceedings of the National Academy of Sciences USA<\/b><\/em> 112: 4310\u20134315. {Highlighted in Nat. Chem. Biol. (2015) 11:304}<\/strong><\/li>\n

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  31. Okamoto R, Mandal K<\/font><\/strong>, Sawaya MR, Kajihara Y, Yeates TO, Kent SBH* (2014)<\/b> (Quasi)Racemic X-ray Structures of Glycosylated and Non-Glycosylated Forms of the Chemokine Ser-CCL1 Prepared by Total Chemical Synthesis.<\/a> Angewandte Chemie International Edition<\/b><\/em> 53: 5194\u20135198.<\/li>\n

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  32. Okamoto R, Mandal K<\/font><\/strong>, Ling M, Luster AD, Kajihara Y, Kent SBH* (2014)<\/b> Total chemical synthesis and biological activities of glycosylated and non-glycosylated forms of the chemokines CCL1 and Ser-CCL1.<\/a> Angewandte Chemie International Edition<\/b><\/em> 53: 5188\u20135193. {Featured as VIP article}<\/strong><\/li>\n

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  33. Dang B, Kubota T, Mandal K<\/font><\/strong>, Kent SBH* (2013)<\/b> Native Chemical Ligation at Asx-Cys, Glx-Cys: Chemical Synthesis and High Resolution X-ray Structure of ShK Toxin by Racemic Protein Crystallography.<\/a> Journal of the American Chemical Society<\/b><\/em> 135: 11911\u201311919.<\/li>\n

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  34. Smilovici MA, Mandal K<\/font><\/strong>, Gates ZP, Phillips NB, Weiss MA, Kent SBH* (2013)<\/b> Convergent Chemical Synthesis and X-ray Crystal Structure of Ester-Insulin by Racemic Protein Crystallography.<\/a> Journal of the American Chemical Society<\/b><\/em> 135: 3173\u20133185.<\/li>\n

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  35. Mandal K<\/font><\/strong>, Uppalapati M, Ault-Rich\u00e9 D, Kenney J, Lowitz J, Sidhu SS*, Kent SBH* (2012)<\/b> Chemical Synthesis and X-ray Structure of a Heterochiral {D-Protein Antagonist Plus Vascular Endothelial Growth Factor} Protein Complex by Racemic Crystallography.<\/a> Proceedings of the National Academy of Sciences USA<\/b><\/em> 109: 14779\u201314784. {Highlighted in Chemical & Engineering News 2012, 90, 6}<\/strong><\/li>\n

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  36. Mandal K<\/font><\/strong>, Pentelute BL, Bang D, Gates ZP, Torbeev VY, Kent SBH* (2012)<\/b> Design, Total Chemical Synthesis, and X-ray Structure of a Protein having a Novel Linear-Loop Polypeptide Chain Topology.<\/a> Angewandte Chemie International Edition<\/b><\/em> 51: 1481\u20131486. {Featured as VIP article}<\/strong><\/li>\n

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  37. Kent SBH*, Sohma Y, Liu S, Bang D, Pentelute BL, Mandal K<\/font><\/strong> (2012)<\/b> Through the Looking Glass \u2013 a New World of Protein Enabled by Chemical Synthesis.<\/a> Journal of Peptide Science<\/b><\/em> 18: 428\u2013436.<\/li>\n

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  38. Mandal K<\/font><\/strong>, Kent SBH* (2011)<\/b> Total Chemical Synthesis of Biologically Active Vascular Endothelial Growth Factor.<\/a> Angewandte Chemie International Edition<\/b><\/em> 50: 8029\u20138033. {Highlighted in Chemical & Engineering News 2011, 89, 27\u201328}<\/strong><\/li>\n

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  39. \u00d6z\u00e7ubuk\u00e7u S, Mandal K<\/font><\/strong>, Wegner S, Jensen MP, He C* (2011)<\/b> Selective Recognition of Americium by Peptide-Based Reagents.<\/a> Inorganic Chemistry<\/b><\/em> 50: 7937\u20137939.<\/li>\n

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  40. Pentelute BL, Mandal K<\/font><\/strong>, Gates ZP, Sawaya MR, Yeates TO, Kent SBH* (2011)<\/b> Total Chemical Synthesis and X-ray Structure of Kaliotoxin by Racemic Protein Crystallography.<\/a> Chemical Communications<\/b><\/em> 46: 8174\u20138176.<\/li>\n

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  41. Banigan J, Mandal K<\/font><\/strong>, Sawaya MR, Thammavongsa V, Hendrickx APA, Schneewind O, Yeates TO, Kent SBH* (2011)<\/b> Determination of the X-Ray Structure of the Snake Venom Protein Omwaprin by Total Chemical Synthesis and Racemic Protein Crystallography.<\/a> Protein Science<\/b><\/em> 19: 1840\u20131849.<\/li>\n

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  42. Deng F\u2013K, Mandal K<\/font><\/strong>, Luisier S, Kent SBH* (2010)<\/b> Synthesis and comparative properties of two amide-generating resin linkers for use in solid phase peptide synthesis.<\/a> Journal of Peptide Science<\/b><\/em> 16: 545\u2013550.<\/li>\n

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  43. Mandal K*<\/font><\/strong>, Pentelute BL, Tereshko V, Thammavongsa V, Schneewind O, Kossiakoff AA, Kent SBH (2009)<\/b> Racemic Crystallography of Synthetic Protein Enantiomers Used to Determine the X-ray Structure of Plectasin by Direct Methods.<\/a> Protein Science<\/b><\/em> 18: 1146\u20131154. {Featured on the cover page}<\/strong><\/li>\n

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  44. Mandal K<\/font><\/strong>, Pentelute BL, Tereshko V, Kossiakoff AA, Kent SBH* (2009)<\/b> X-ray Structure of Native Scorpion Toxin BmBKTx1 by Racemic Protein Crystallography Using Direct Methods.<\/a> Journal of the American Chemical Society<\/b><\/em> 131: 1362\u20131363. {Highlighted in Chemical & Engineering News 2009, 87, 8}<\/strong><\/li>\n

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  45. Torbeev VY, Raghuraman H, Mandal K<\/font><\/strong>, Senapati S, Perozo E, Kent SBH* (2009)<\/b> Dynamics of \u201cFlap\u201d Structures in Three HIV-1 Protease\/Inhibitor Complexes Probed by Total Chemical Synthesis and Pulse-EPR Spectroscopy.<\/a> Journal of the American Chemical Society<\/b><\/em> 131: 884\u2013885.<\/li>\n

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  46. Lee DJ, Mandal K<\/font><\/strong>, Harris PWR, Brimble MA, Kent SBH* (2009)<\/b> A One-Pot Approach to Neoglycopeptides using Orthogonal Native Chemical Ligation and Click Chemistry.<\/a> Organic Letters<\/b><\/em> 11: 5270\u20135273.<\/li>\n

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  47. Kotha S*, Mandal K<\/font><\/strong> (2009)<\/b> A Retrospective on the Design and Synthesis of Novel Molecules through a Strategic Consideration of Metathesis and Suzuki\u2013Miyaura Cross-coupling.<\/a> Chemistry \u2013 An Asian Journal<\/b><\/em> 4: 354\u2013362.<\/li>\n

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  48. Torbeev VY, Mandal K<\/font><\/strong>, Terechko VA, Kent SBH* (2008)<\/b> Crystal Structure of Chemically Synthesized HIV-1 Protease and a Ketomethylene Isostere Inhibitor Based on the p2\/NC Cleavage Site.<\/a> Bioorganic & Medicinal Chemistry Letters<\/b><\/em> 18: 4554\u20134557.<\/li>\n

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  49. Kotha S*, Mandal K<\/font><\/strong> (2007)<\/b> Metathesis of a Novel Dienediyne System: A Unique Example Involving the Usage of in situ<\/em> Generated Ethylene as Cross\u2013Enyne Metathesis Partner.<\/a> Journal of Organometallic Chemistry<\/b><\/em> 692: 4921\u20134927.<\/li>\n

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  50. Kotha S*, Shah VR, Mandal K<\/font><\/strong> (2007)<\/b> Formation of Arenes via Diallylarenes: Strategic Utilization of Suzuki\u2013Miyaura Cross\u2013Coupling, Claisen Rearrangement and Ring-Closing Metathesis.<\/a> Advanced Synthesis & Catalysis<\/b><\/em> 349: 1159\u20131172.<\/li>\n

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  51. Kotha S*, Mandal K<\/font><\/strong>, Banerjee S, Mobin SM (2007)<\/b> Synthesis of Novel Quinone\u2013Amino Acid Hybrids via Cross\u2013Enyne Metathesis and Diels\u2013Alder Reaction as Key Steps.<\/a> European Journal of Organic Chemistry<\/b><\/em> 2007: 1244\u20131255.<\/li>\n

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  52. Kotha S*, Mandal K<\/font><\/strong> (2006)<\/b> Suzuki\u2013Miyaura Cross\u2013Coupling and Ring\u2013Closing Metathesis: A Strategic Combination for the Synthesis of Cyclophane Derivatives.<\/a> European Journal of Organic Chemistry<\/b><\/em> 2006: 5387\u20135393. {Cited with scheme in the book \u2018Supramolecular Chemistry\u2019 (Wiley, 2nd Ed, 2009, p344) by J. W. Steed and J. L. Atwood.}<\/strong><\/li>\n

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  53. Kotha S*, Mandal K<\/font><\/strong>, Tiwari A, Mobin SM (2006)<\/b> Diversity\u2013Oriented Approach to Biologically Relevant Molecular Frameworks Starting with \u03b2-Naphthol and Using the Claisen Rearrangement and Olefin Metathesis as Key Steps.<\/a> Chemistry \u2013 A European Journal<\/b><\/em> 12: 8024\u20138038.<\/li>\n

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  54. Kotha S*, Mandal K<\/font><\/strong>, Arora KK, Pedireddi VR (2005)<\/b> New Synthetic Approach to a [1.1.6] Metapara Cyclophane Derivative via Suzuki\u2013Miyaura Cross\u2013Coupling and Ring-Closing Metathesis.<\/a> Advanced Synthesis & Catalysis<\/b><\/em> 347: 1215\u20131218.<\/li>\n

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  55. Kotha S*, Mandal K<\/font><\/strong>, Deb AC, Banerjee S (2004)<\/b> Microwave\u2013Assisted Claisen Rearrangement on a Silica Gel Support.<\/a> Tetrahedron Letters<\/b><\/em> 45: 9603\u20139605.<\/li>\n

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  56. Kotha S*, Mandal K<\/font><\/strong> (2004)<\/b> A New Protocol for Benzoannulations by Double Claisen Rearrangement and Ring\u2013Closing Metathesis Reactions as Key Steps.<\/a> Tetrahedron Letters<\/b><\/em> 45: 2585\u20132588.<\/li>\n

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  57. Kotha S*, Mandal K<\/font><\/strong> (2004)<\/b> Metathetic Approach to Naphthoxepin and Spirocyclic Molecular Frameworks.<\/a> Tetrahedron Letters<\/b><\/em> 45: 1391\u20131394.<\/li>\n

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  58. Kotha S*, Banerjee S, Mandal K<\/font><\/strong> (2004)<\/b> Oxidative Dehydrogenation and the Aromatization of Polycycles Using o-Iodoxybenzoic Acid (IBX).<\/a> Synlett<\/b><\/em> 2004: 2043\u20132045.<\/li>\n

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    Book Chapters<\/h2>\n

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    1. Total Chemical Protein Synthesis for the Determination of Novel X-Ray Structures by Racemic Protein Crystallography.<\/a> Mandal K*<\/font><\/strong> and Kent SBH* in Present and Future Methods for Biomolecular Crystallography: The Structural Path to Defence against CBRN Agents, Read RJ, Urzhumtsev AG and Lunin VY, Eds., Springer, 2012<\/b>. Pp 11 \u2013 22. <\/li>\n

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    2. Neoglycoprotein Synthesis Using the Copper-Catalyzed Azide-Alkyne Click Resaction and Native Chemical Ligation.<\/a> Wojnar J, Lee DJ, Evans CW, Mandal K<\/font><\/strong>, Kent SBH and Brimble MA in Click Chemistry in Glycoscience, Witczak ZJ and Bielski R, Eds., John Wiley & Sons, 2013<\/b>. P 253. <\/li>\n

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      Patent Application<\/h2>\n

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      1. A peptide capable of inhibiting bacterial biofilm\/fibril fotmation. Mandal K<\/font><\/strong>, Kar A, Malik V (2025)<\/b> IN Patent App. 202,541,002,581.<\/li>\n

        <\/p>\n

      2. GB1 peptidic compounds and methods for making and using the same. Sidhu SS, Uppalapati M, Ault-Rich\u00e9 D, Kent SBH, Mandal K<\/font><\/strong>, Lee DJ (2014)<\/b> PCT Int. Appl. WO 2014071234 A1 20140508.<\/li>\n

        <\/body><\/html>[\/et_pb_code][\/et_pb_column][\/et_pb_row][\/et_pb_section]<\/p>\n","protected":false},"excerpt":{"rendered":"

        PUBLICATIONS (* Corresponding author; \u00a7 Equal contribution)Mannuthodikayil J, Malik V, Kar A, Singh S, Mandal K* (2025) Chemical Protein Engineering: Backbone Cyclization Rescues Folding of a Truncated 183-Residue Domain 1 of Malaria Parasite Protein PfAMA1. Chemistry \u2013 A European Journal,\u00a0e202500894.Biswas A, Narayan A, Sinha S, Mandal K* (2025) Chemically Engineered Peptide Efficiently Blocks Malaria Parasite […]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_et_pb_use_builder":"on","_et_pb_old_content":"","_et_gb_content_width":"","footnotes":""},"class_list":["post-27","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/www.tifrh.res.in\/~kmandal\/wp-json\/wp\/v2\/pages\/27","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.tifrh.res.in\/~kmandal\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www.tifrh.res.in\/~kmandal\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www.tifrh.res.in\/~kmandal\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/www.tifrh.res.in\/~kmandal\/wp-json\/wp\/v2\/comments?post=27"}],"version-history":[{"count":59,"href":"https:\/\/www.tifrh.res.in\/~kmandal\/wp-json\/wp\/v2\/pages\/27\/revisions"}],"predecessor-version":[{"id":827,"href":"https:\/\/www.tifrh.res.in\/~kmandal\/wp-json\/wp\/v2\/pages\/27\/revisions\/827"}],"wp:attachment":[{"href":"https:\/\/www.tifrh.res.in\/~kmandal\/wp-json\/wp\/v2\/media?parent=27"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}