User talk:Daniel Hausaman
From Proteopedia
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| + | '''Q3. What type of polymerase inhibitor is Remdesivir categorised as?''' | ||
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| + | '''Q4. Why does Remdesivir require metabolic activation?''' | ||
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| + | '''Q5. How many phosphate groups does the activated form of Remdesivir contain?''' | ||
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| + | '''Q6. What bond is formed that initiates the chain termination?''' | ||
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== Structural highlights == | == Structural highlights == | ||
Revision as of 16:55, 7 July 2021
Contents |
Use of Remdesivir as a treatment for COVID-19
Introduction
Remdesivir is a drug that was initially developed for use against Ebola, and has shown to be effective against coronaviruses such as SARS-CoV, MERS-CoV, SARS-CoV-2 and other coronaviruses. SARS-CoV-2 is the virus that is responsible for the disease COVID-19 which is a respiratory disease that can inflict severe damage to multiple major organs including the heart, brain and lungs. SARS-Cov2 relies upon RNA-dependent RNA polymerase (RdRp) to replicate the viral genetic material. Drugs such as nucleoside analogues can be used to inhibit this RNA dependant RNA polymerase enzyme and stop viral replication. Remdesivir initially labeled GS-5734 is an adenosine triphosphate analogue, used as a broad-spectrum antiviral drug meaning it can be used to inhibit a wide range of viruses that rely upon RNA-dependent RNA polymerase for genomic replication.
Q1. How does Remdesivir stop viral replication in COVID-19?
Q2. How can Remdesivir be used on other RNA viruses?
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Structure
Remdesivir triphosphate has the molecular formula C12H16N5O13P3 the compound is made up of a C-nucleoside, an aromatic amine, a nitrile, a pyrrolotriazine and an organic triphosphate. RNA dependant RNA Polymerase complex is an enzyme used in the replication and transcription of viral RNA. the structure of the protein is made up of an nsp12 core catalytic unit, an nsp7-nsp8 heterodimer, and an additional nsp8 subunit On the right-hand side shows the 3D structure of nsp12-nsp7-nsp8 complex also known as the RdRp bound to the template-primer RNA and the triphosphate form of remdesivir which is highlighted in blue to view remdesivir bound to the protein complex
Mechanism
Once administered remdesivir requires metabolic activation, this takes place after the drug diffuses into a cell. Phosphoamidase (HINT1) and esterases CES1 and CTSA transform remdesivir into GS-441524 mono-phosphate. This is then phosphorylated again to produce the active triphosphate analog.
Remdeisvir is a polymerase inhibitor, there are 2 main categories for polymerase inhibitors these are known as nucleoside analogues and allosteric inhibitors. Nucleoside analogues resemble viral building blocks such as Adenosine triphosphate. One of the main ways this inhibits viral replication is because of competitive inhibition between the nucleoside analogue and the viral RNA. To view the RNA highlighted in red Viral replication can also be reduced by the incorporation of incorrect nucleotides into the viral genome this can result in chain termination which is initiated by the formation of a phosphodiester bond, between the 3′ hydroxyl group of Remdesivir triphosphate and the next nucleotide resulting in the termination of the viral RNA synthesis at the position of 3 nucleotides.
Q3. What type of polymerase inhibitor is Remdesivir categorised as?
Q4. Why does Remdesivir require metabolic activation?
Q5. How many phosphate groups does the activated form of Remdesivir contain?
Q6. What bond is formed that initiates the chain termination?
Structural highlights
Structure
On the right-hand side shows the 3D structure of nsp12-nsp7-nsp8 complex bound to the template-primer RNA and the triphosphate form of remdesivir which is highlighted in blue to view remdesivir bound to the protein complex
