Pharma - Antivirals I (OA) PDF

Summary

This document is a lecture or presentation on antiviral agents. It includes information on HSV infections, different drug categories for treating them, mechanisms of action, and adverse effects. The document also discusses other viruses, and mentions different drugs and their uses in treating viral infections .

Full Transcript

Antiviral agents I
Dr. Omamah Alfarisi
November 2022

Case 1:
A 27-year-old man has met a woman and they became intimately
involved. After 2 months, the man started to get painful itchy sores on
the genitalia. With fever and headache. After being tested, he was
positive for Herpes-simplex-virus2 (HSV2). This was the first time he
acquired this infection
 Anti-herpes(HSV) medications: what are the main viruses that are
covered by these drugs? Are these viruses DNA or RNA viruses?

Other related viruses are VZV, CMV, EBV

What are the main categories of drugs that target HSV viruses?
 Mechanism of action of anti-HSV
Most of these drugs inhibit DNA polymerase by: Acyclo
NRTS Competing with nucleotides on the DNA polymerase substrate site:
a
Nucleoside analogues so Yeti
Acyclovir, valacyclovir, penciclovir, famciclovir, ganciclovir, valganciclovir,
cidofovir, trifluridine famci
These drugs need to be Activated by phosphorylation, analogues of ganci
deoxyribonucleosidetriphosphates (dGTP)
Require viral enzymes to phosphorylate and activate the drug: thus, inhibition of
viral DNA synthesis rather than the host cell (selectivity)
valgnci

uridine
NNRTs Inhibition of DNA polymerase: Non-nucleoside DNA polymerase inhibitors
Foscarnet

Mechanism of action
Active drug/(Pro-drug):
Acyclovir/(Valacyclovir) ~ found in HSV and VZV
Penciclovir/(Famciclovir)
Ganciclovir/(Valganciclovir)

Mechanism of action of nucleoside analogues:
Acyclovir
▪ They all require 3-steps of phosphorylation before being active:
Viral kinase
▪ One phosphorylation step by viral kinase (e.g: thymidine kinase or UL-97
P kinase),
▪ then 2 phosphorylation steps by host cell kinases to nucleotide (guanosine)
Acyclovir
analogues
Host kinase
▪ These analogues inhibit the viral DNA-polymerase
▪ Only actively replicating viruses are inhibited
P P
▪ Resistance to thymidine kinase or DNA polymerase to one of the drugs can
Acyclovir confer cross-resistance to other drugs

Host kinase

P P P

Acyclovir
Guanine analogue
 Illustration by David H. Spach, MD

What are you going to recommend to him for his HSV infection?
 Acyclovir.

Acyclovir and valacyclovir:
Requires 3 phosphorylation steps for activation, first of which is by the viral thymidine
kinase and then the di- & tri-phosphate by the host kinases
Thus, acyclovir is selectively activated, and the active metabolite accumulates only in
the infected cells
Acyclovir is Active against:
HSV2 (0.03–2.2 μg/mL),
a tenth as potent against VZV (0.8–4.0 μg/mL) and EBV,
least active against CMV (generally > 20 μg/mL) and HH-V6
Valacyclovir is a prodrug rapidly converted to acyclovir after oral administration via first-
pass enzymatic hydrolysis in the liver and intestine.
As effective as oral acyclovir in HSV and more effective in herpes zoster
Adverse effects: depend on the route
Local irritation - topical
Nausea, vomiting, diarrhea, headache - oral
Transient renal dysfunction or neurologic toxicity - high oral dose or IV
Neutropenia in neonates
 Famciclovir and penciclovir:
Famciclovir is inactive prodrug of the active drug penciclovir.
Penciclovir is similar to acyclovir in its spectrum of activity and
potency against HSV and VZV. It is also inhibitory for HBV.
Compared with acyclovir: Penciclovir is more efficiently
phosphorylated by TK (higher intracellular concentration and for
more prolonged period) but has lower affinity to viral DNA
polymerase and thus has longer half-life and exposure in the infected
cell.

Valganciclovir and Ganciclovir:
It is monophosphorylated intracellularly by viral TK during HSV infection and by a viral phosphotransferase
encoded by the UL97 gene during CMV infection. Especially active against CMV
About 100X more active than acyclovir against CMV and achieves 10X higher intracellular concentration-
allowing for reducing dose frequency
Valganciclovir is a prodrug of ganciclovir
Resistance:
Mutation in UL97 –kinase phosphotransferase- (more common)
Mutation in UL54 –DNA polymerase- (high resistance, cross resistance with cidofovir and foscarnet)
Adverse effects:
Myelosuppression (with IV)
Nausea, diarrhea, fever, rash, headache, peripheral neuropathy
CNS toxicity (confusion, seizure, psychiatric disturbance)
2. Non-nucleoside DNA polymerase inhibitors: -
Foscarnet-
Does not require phosphorylation by viral or host kinases for activation
Foscarnet inhibits viral nucleic acid synthesis by interacting directly, at the
pyrophosphate site of the herpesvirus DNA polymerase or HIV reverse transcriptase.
Foscarnet has ~100fold greater inhibitory effects against herpesvirus DNA polymerases
than against host cellular DNA polymerase. (Selectivity)
Herpesviruses resistant to foscarnet: mutations in the viral DNA polymerase.
Intravenous foscarnet is effective for treatment of CMV retinitis, including ganciclovir-
resistant infections, other types of CMV infection, and acyclovir-resistant HSV and VZV
infections.
Adverse effect:
Nephrotoxicity (25%) – metabolic abnormalities (decrease Ca, Phosphate, Mg, K) – CNS
toxicity
Anti-influenza virus
Influenza virus types: A, B, C
A is the most common and most pathogenic
Virus through its Hemagglutinin attaches to
host cell’s sialic-acid receptors
The influenza virions is then internalized in
endosome where the viral M2 proton
channel leads to uncoating of the virus
The virus genetic material is released,
replicated, and the virus is assembled
At the end: viral budding:
Virus is cleaved by the sialidase activity of NA
proteins. The virion is then released from the cell.

Virus Drug class Example
Influenza A virus M2 inhibitor Amantadine
Influenza A & B virus Neuraminidase inhibitor Oseltamivir
 Amantadine
Mechanism of action: primarily block the M2 proton channel in influenza A
leading to:
▪ Early-stage inhibition effect: primarily inhibit the viral M2 proton channel while
in the host cell endosome leading to prevention of viral uncoating at early stage

▪ Late-stage inhibition effect: prevention of M2 proton channel also lead to
deformation in the HA protein and inhibition of proper viral assembly.
▪ M2 is only in influenza A, thus amantadine is not active against influenza B

▪ useful for the prevention and treatment of infections caused by influenza A virus
Side effects: CNS-related side effects (dose-related). The CNS toxic effect can be
increased with concomitant administration of antihistamine and anticholinergic
drugs.

Oseltamivir:
Mechanism of action: neuraminidase
inhibitor
Viral Hemagglutinin is bound to host
cell sialic acid on host-cell receptor
Virus need to be released by cleaving
this bond by viral neuraminidase
Inhibition of this neuraminidase lead
to inhibition of the viral release

The neuraminidase inhibitors are active against many NA in both influenza A and B:
Used for treatment of both Influenza A & B.
Resistance is less compared to amantadine
Side effects: are less toxic than amantadine. GI disturbances (resolve within 1-2days)
Anti-hepatitis drugs
Hepatitis viruses identified are (A, B, ,C, D). B and C are the most
common pathogenic viruses.
Hepatitis B virus HBV is a DNA double-stranded virus
hepatitis C (HCV) is a single RNA virus
 Nucleotide/nucleoside analogues
▪ They require phosphorylation to di- or tri-
phosphate for activation.
▪ Some can competitively inhibit:
▪ HBV-related DNA polymerase
▪ Or inhibit HCV-related RNA-dependent-RNA
polymerase.
▪ Ribavirin: exerts several mechanism of actions:
1. Monophosphated-ribavirin: inhibit viral GTP synthesis
2. Triphosphate ribavirin: directly inhibits viral mRNA
polymerase by acting as nucleotide analogue.
3. It also inhibit the processing of the synthesized mRNA

Drug Some side effects
Adefovir Nephrotoxicity, hepatomegaly
Entecavir Headache, dizziness, fatigue
Ribavirin Hemolytic anaemia, teratogenicity
Tenofovir Nephrotoxicity, bone loss

Interferons
Interferons are potent cytokines that possess antiviral, immunomodulatory, and antiproliferative activities.
Three major classes of human IFNs: α, β, and γ.
Mechanism of action: How does interferon work as antiviral?
❑ The binding of interferon to cell surface receptor molecules signals the cell to produce a series of antiviral proteins
leading to several antiviral effects:
❑ Most of these interferons act to inhibit the translation of viral proteins by producing enzymes (methylase and
ribonuclease) that degrade the viral mRNA.

❑ INF-a also activate macrophages and other neutrophils and cytotoxic T-lymphocytes to attack the virus.
Attachment of IFN proteins to large inert polyethylene glycol (PEG) molecules (pegylation):
slows absorption, decreases clearance, and provides higher and more prolonged serum concentrations that enable once weekly dosing.
Adverse effects: GI irritation, flu-like symptoms, neutropenia, profound fatigue, alopecia, thyroid dysfunction.
Simeprevir:

Inhibits the non-structural3/4A protease
The NS3/4A protease:
essential for generating mature viral proteins
required for viral replication,
suppress the host antiviral immune system.
Adverse effects: anaemia, pruritus, transient
increase bilirubin