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"Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) merupakan agen penyebab Coronavirus Disease 2019 (COVID-19) yang telah menginfeksi hampir dua ratus juta orang dan menyebabkan hampir empat juta kematian di dunia. Saat ini, belum ada obat yang spesifik ditemukan untuk virus ini. Drug repurposing merupakan salah satu alternatif strategi pengembangan obat di masa pandemi. Pada penelitian ini, non-structural protein 3 (NSP3) dan non-structural protein 13 (NSP13) SARS-CoV-2, yang mengkode papain-like protease dan helikase, terpilih sebagai target potensial yang berperan penting dalam replikasi virus. Drug repurposing berbasis pemodelan farmakofor dilakukan menggunakan program LigandScout. Ligan kokristal NSP3 dan NSP13 SARS-CoV-2 dari Protein Data Bank dipilih sebagai training set. Sebelumnya, sekuens protein disejajarkan dengan Clustal Omega dan interaksi protein-ligan diidentifikasi dengan Protein-Ligand Interaction Profiler. Model farmakofor divalidasi menggunakan test set yang terdiri dari ligan terpilih sebagai senyawa aktif dan decoy dari A Database of Useful Decoys-Enhanced sebagai senyawa inaktif. Model farmakofor NSP3 pada akhirnya tidak terbentuk karena sedikitnya ligan yang tersedia. Model farmakofor NSP13 yang memiliki satu cincin aromatik (AR), satu daerah hidrofobik (H), satu akseptor ikatan hidrogen (HBA), dan satu donor ikatan hidrogen (HBD) dengan penambahan feature tolerance sebesar 0,15 Å dan feature weight sebesar 0,1 pada fitur AR, H, dan HBA menghasilkan nilai AUC100%, EF1%, EF5%, sensitivitas, dan spesifisitas sebesar 0,83; 21,2; 8,8; 0,792; dan 0,790. Model ini digunakan sebagai kueri penapisan terhadap obat yang telah disetujui FDA dari The Binding Database. Ticarcillin, sulfisoxazole, lacosamide, sulfathiazole, cefaclor, penicillin G, cephalexin, carbenicillin, atenolol, dan tolazoline diperoleh sebagai senyawa kandidat dengan pharmacophore-fit score tertinggi.

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Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), causal agent of Coronavirus Disease 2019 (COVID-19), has infected almost two hundred millions of people and caused nearly four millions of deaths worldwide. Currently, no treatment has been identified to be effective against the virus. In the outbreak, drug repurposing emerges as a promising strategy to develop efficient therapeutics. This study selected SARS-CoV-2 non-structural protein 3 (NSP3) and non-structural protein 13 (NSP13), that encodes papain-like protease and helicase, respectively, as potential targets based on their crucial role in virus replication. Drug repurposing was carried out by LigandScout pharmacophore modeling using SARS-CoV-2 NSP3 and NSP13 co-crystallized ligands from Protein Data Bank as training set. Prior to that, crystal structures were aligned by Clustal Omega and analyzed by Protein-Ligand Interaction Profiler for interaction profiling. Generated pharmacophore model was validated by a test set consisting of above-mentioned ligands as actives and A Database of Useful Decoys-Enhanced decoys as inactives. Unfortunately, NSP3 model cannot be generated due to insufficient ligands. NSP13 model that has one aromatic ring (AR), one hydrophobic area (H), one hydrogen bond acceptor (HBA), and one hydrogen bond donor (HBD) features with 0,15 Å feature tolerance and 0,1 feature weight additions on AR, H, and HBA resulted AUC100%, EF1%, EF5%, sensitivity, and specificity of 0,83; 21,2; 8,8; 0,792; and 0,790. This model was chosen for screening against FDA-approved drugs from The Binding Database. Ticarcillin, sulfisoxazole, lacosamide, sulfathiazole, cefaclor, penicillin G, cephalexin, carbenicillin, atenolol, and tolazoline were obtained as hits with the highest pharmacophore-fit score."

"Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) merupakan agen penyebab Coronavirus Disease 2019 (COVID-19) yang telah menginfeksi hampir dua ratus juta orang dan menyebabkan hampir empat juta kematian di dunia. Saat ini, belum ada obat yang spesifik ditemukan untuk virus ini. Drug repurposing merupakan salah satu alternatif strategi pengembangan obat di masa pandemi. Pada penelitian ini, non-structural protein 3 (NSP3) dan non-structural protein 13 (NSP13) SARS-CoV-2, yang mengkode papain-like protease dan helikase, terpilih sebagai target potensial yang berperan penting dalam replikasi virus. Drug repurposing berbasis pemodelan farmakofor dilakukan menggunakan program LigandScout. Ligan kokristal NSP3 dan NSP13 SARS-CoV-2 dari Protein Data Bank dipilih sebagai training set. Sebelumnya, sekuens protein disejajarkan dengan Clustal Omega dan interaksi protein-ligan diidentifikasi dengan Protein-Ligand Interaction Profiler. Model farmakofor divalidasi menggunakan test set yang terdiri dari ligan terpilih sebagai senyawa aktif dan decoy dari A Database of Useful Decoys-Enhanced sebagai senyawa inaktif. Model farmakofor NSP3 pada akhirnya tidak terbentuk karena sedikitnya ligan yang tersedia. Model farmakofor NSP13 yang memiliki satu cincin aromatik (AR), satu daerah hidrofobik (H), satu akseptor ikatan hidrogen (HBA), dan satu donor ikatan hidrogen (HBD) dengan penambahan feature tolerance sebesar 0,15 Å dan feature weight sebesar 0,1 pada fitur AR, H, dan HBA menghasilkan nilai AUC100%, EF1%, EF5%, sensitivitas, dan spesifisitas sebesar 0,83; 21,2; 8,8; 0,792; dan 0,790. Model ini digunakan sebagai kueri penapisan terhadap obat yang telah disetujui FDA dari The Binding Database. Ticarcillin, sulfisoxazole, lacosamide, sulfathiazole, cefaclor, penicillin G, cephalexin, carbenicillin, atenolol, dan tolazoline diperoleh sebagai senyawa kandidat dengan pharmacophore-fit score tertinggi.

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Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), causal agent of Coronavirus Disease 2019 (COVID-19), has infected almost two hundred millions of people and caused nearly four millions of deaths worldwide. Currently, no treatment has been identified to be effective against the virus. In the outbreak, drug repurposing emerges as a promising strategy to develop efficient therapeutics. This study selected SARS-CoV-2 non-structural protein 3 (NSP3) and non-structural protein 13 (NSP13), that encodes papain-like protease and helicase, respectively, as potential targets based on their crucial role in virus replication. Drug repurposing was carried out by LigandScout pharmacophore modeling using SARS-CoV-2 NSP3 and NSP13 co-crystallized ligands from Protein Data Bank as training set. Prior to that, crystal structures were aligned by Clustal Omega and analyzed by Protein-Ligand Interaction Profiler for interaction profiling. Generated pharmacophore model was validated by a test set consisting of above-mentioned ligands as actives and A Database of Useful Decoys-Enhanced decoys as inactives. Unfortunately, NSP3 model cannot be generated due to insufficient ligands. NSP13 model that has one aromatic ring (AR), one hydrophobic area (H), one hydrogen bond acceptor (HBA), and one hydrogen bond donor (HBD) features with 0,15 Å feature tolerance and 0,1 feature weight additions on AR, H, and HBA resulted AUC100%, EF1%, EF5%, sensitivity, and specificity of 0,83; 21,2; 8,8; 0,792; and 0,790. This model was chosen for screening against FDA-approved drugs from The Binding Database. Ticarcillin, sulfisoxazole, lacosamide, sulfathiazole, cefaclor, penicillin G, cephalexin, carbenicillin, atenolol, and tolazoline were obtained as hits with the highest pharmacophore-fit score."

"SARS-CoV-2 merupakan penyebab COVID-19 yang melanda dunia sejak akhir 2019. Virus ini telah menyebar secara luas di dunia akibat infektifitasnya yang tinggi. Salah satu penyebab tingginya infektifitas virus ini adalah spike glycoprotein. Spike glycoprotein merupakan salah satu protein yang terdapat pada SARS-CoV-2. Spike glycoprotein berperan secara langsung alam mekanisme infeksi dengan cara membentuk ikatan dengan reseptor ACE-2 pada sel inang. Inhibisi spike glycoprotein dapat menjadi salah satu cara pengobatan COVID-19. Dalam penelitian ini, antivirus yang sudah dipasarkan sebagai basis data akan di-repurpose menjadi antivirus SARS-CoV-2, kemudian dilakukan modifikasi terhadap senyawa yang terpilih menjadi senyawa organoselen. Penelitian dilakukan dengan cara in silico. Untuk simulasi molecular docking, digunakan software MOE2014.09 untuk mendapatkan informasi tentang interaksi antara spike glycoprotein dengan ligan, baik antivirus maupun antivirus hasil modifikasi. Melalui analisa nilai energi pengikatan dan uji farmakologi, diperoleh 3 ligan terbaik dari antivirus (Ombitasvir, Elbasvir, dan Ledipasvir) serta antivirus modifikasi (ModL1, ModL2, dan ModL6).

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SARS-CoV-2 is the cause of COVID-19 that has hit the world since the end of 2019. This virus has spread widely in the world due to its high infection. One of the causes of the high infectivity of this virus is the spike glycoprotein. The spike glycoprotein is a protein found in SARS-CoV-2. The glycoprotein spike directly plays a role in the infection mechanism by forming a bond with the ACE-2 receptor on the host cell. Inhibition of spike glycoprotein can be one way of treating COVID-19. In this study, the antivirals that have been marketed as databases will be repurposed into SARS-CoV-2 antivirals, then the selected compounds will be modified into organoselenium compounds. The research was conducted through in silico. The molecular docking simulation was conducted by using MOE2014.09 to retrieve information about the interaction between the protein-ligand from unmodified antivirus as well as modified antivirus. Through the binding energy value and pharmacological tests, the three best ligands are obtained from the unmodified antivirus (Ombitasvir, Elbasvir, and Ledipasvir) and the modified antivirus (ModL1, ModL2, and ModL6)."