Ligands docking to ORF8 by co-evolution. Could they reduce the inflammation levels induced by SARS-COV-2 infections?

Abstract: The unique ORF8 is an asymmetric homodimer accessory protein of SARS-COV-2 implicated in pathogenesis by activating excesive human inflammation causing numerous deaths. There is no approved drug targeting ORF8, nor it is known whether any anti-ORF8 drugs could reduce coronavirus-induced excesive inflammation. Computationally combining ligand co-evolution of parent molecules with affinity-ranking by consensus docking, children candidates for ORF8 cavities and ligands were generated. Targeting the interface cavi… Show more

“…Additionally, large numbers of candidates could be used to extract those computationally recognizing known mutations, molecular target variations, and/or off-targets, etc. Something similar was employed with other protein /ligand pair examples for instance to select anticoagulants affecting both rats and their resistant mutants but not humans 46 or monkeypox Tecovirimat-resistant variants 32 .…”

“…The non-toxic fitted-children were DW saved as special 3D *.sdf files using previously described options including mmff94s + minimization 37 . Such saving methods were critically required to preserve their 2D geometries 32 for PyMol visualization (split_states PyMol command) 34 and/or for optimal ADV re-docking.…”

“…Generation rather than screening, were employed in this work to search for new anti-KcsA ligand candidates using the DataWarrior Build Evolutionary Library (DW-BEL) algorithms [2][3][4][5] . Starting from defined parent molecules and their preliminarily identified docking cavity, DW-BEL co-evolution generated tens of thousands raw children and thousands of highly specific cavityfitting children molecules [2][3][4][5]32 selected by their docking affinities. Despite the particular toxicity and/or steric difficulties found when targeting the known KcsA central cavity and/or lipid surfaces, respectively, the random generation of children molecules was very successful.…”

Low-toxicity nanoMolar scaffolds with hundreds of variants generated by computational co-evolution into prokaryotic potassium channel cavities

“…Additionally, large numbers of candidates could be used to extract those computationally recognizing known mutations, molecular target variations, and/or off-targets, etc. Something similar was employed with other protein /ligand pair examples for instance to select anticoagulants affecting both rats and their resistant mutants but not humans 46 or monkeypox Tecovirimat-resistant variants 32 .…”

“…The non-toxic fitted-children were DW saved as special 3D *.sdf files using previously described options including mmff94s + minimization 37 . Such saving methods were critically required to preserve their 2D geometries 32 for PyMol visualization (split_states PyMol command) 34 and/or for optimal ADV re-docking.…”

“…Generation rather than screening, were employed in this work to search for new anti-KcsA ligand candidates using the DataWarrior Build Evolutionary Library (DW-BEL) algorithms [2][3][4][5] . Starting from defined parent molecules and their preliminarily identified docking cavity, DW-BEL co-evolution generated tens of thousands raw children and thousands of highly specific cavityfitting children molecules [2][3][4][5]32 selected by their docking affinities. Despite the particular toxicity and/or steric difficulties found when targeting the known KcsA central cavity and/or lipid surfaces, respectively, the random generation of children molecules was very successful.…”

Low-toxicity nanoMolar scaffolds with hundreds of variants generated by computational co-evolution into prokaryotic potassium channel cavities

“…Non-toxic nanoMolar affinities drug-like candidates 8 , have been predicted into different protein / ligand pair cavities. To briefly mention, new antibiotics fitting FtsZ of resistant Staphilococcus 9 , alternative Abaucin-derivatives against Acinetobacter lipoprotein 10 , anticoagulant non-human brodifacoum-derived raticide ligands 11 , anti-monkeypox conformers to Tecovirimat-resistance mutants 12 , anti-glycoprotein trimer inner-cavity of omicron coronavirus 13 , antiinflammatory coronavirus-coded protein 14 , new docking to prokaryotic models for human potassium channels 15 , or anti-fish rhabdovirus cross-docking their glycoprotein trimers 16 .…”

Tailoring evolved-ligands to Plasmodium circumsporozoite-protein