Zanamivir

From Proteopedia

(Difference between revisions)

Current revision

Better Known as: Relenza

Marketed By: GlaxoSmithKline
Major Indication: Influenza Infection
Drug Class: Neuraminidase Inhibitor
Date of FDA Approval (Patent Expiration): 1999 (2016)
2009 Sales: $1.1 Billion
Importance: It was the first neuraminidase inhibitor to be approved by the FDA, followed a few months later by Oseltamivir. It was designed to be a Sialic acid analog. Newer strains of flu virus, primarily H1N1, have developed varying levels of resistance to Oseltamivir, but a lesser extent to Zanamivir. Sales have increased dramatically since 2006 with scares of bird flu and swine flu pandemics.
See Pharmaceutical Drugs for more information about other drugs and diseases.

Mechanism of Action

Viral Neuraminidase is one of two major glycoproteins found on the surface of influenza viral membranes, the other being hemagglutinin. When the influenza virus infects a host cell, it attaches itself to the host via hemagglutinin interactions with host glycans, facilitating the fusion of host endosomal membrane with the viral membrane. After the virus has successfully infected the host and replicated extensively, the viral cargo is released from the cell via budding. During the budding process, the viral cargo is attached to the host cell once again via hemagglutinins, allowing the viral particle to form completely. Once the viral particle is formed, Neuraminidase cleaves the terminal sialic (neuraminic) acid residues from the glycan structures on the surface of the infected cell, breaking the hemmaglutinin-glycan interaction and promoting release of the viral particle to infect other cells. Zanamivir functions by inhibiting the function of , preventing the viral particle from being released from the infected cell, thus limiting the severity and spread of viral infections.^[1] It binds to the active site of Neuraminidase causing dramatic conformational adjustments which render the protein non-functional. This prevents neuraminidase from cleaving the hemmaglutinin-glycan tethers and releasing the viral cargo after viral replication. Zanamivir binding causes the (residues 147-151) to shift, , while Zanamivir situates itself using significant hydrogen bonding Arg 118, Asp 151, Arg 152, Arg 224, Glu 276, Arg 292, Arg 371 and Tyr 406. Of note, His 274, for which the H274Y mutation confers resistance to inhibitors like Oseltamivir, , explaining why the H274Y Neuraminidase mutant is not resistant to treatment with Zanamvir.^[2]

Pharmacokinetics

Neuraminidase Inhibitor Pharmacokinetics
Parameter	Zanamivir	Oseltamivir
T_max (hr)	1.25	1.5
C_max (ng/ml)	31.6	57
Bioavailability (%)	2	75
Protein Binding (%)	10	42
T_1/2 (hr)	3	3.2
AUC (ng/ml/hr)	185	204
Clearance (L/h)	54.1	18.8
Dosage (mg)	10	300
Metabolism	None	Hepatic

For References to Pharmacokinetic data, see: References

References

↑ Varghese JN, McKimm-Breschkin JL, Caldwell JB, Kortt AA, Colman PM. The structure of the complex between influenza virus neuraminidase and sialic acid, the viral receptor. Proteins. 1992 Nov;14(3):327-32. PMID:1438172 doi:http://dx.doi.org/10.1002/prot.340140302
↑ Xu X, Zhu X, Dwek RA, Stevens J, Wilson IA. Structural characterization of the 1918 influenza virus H1N1 neuraminidase. J Virol. 2008 Nov;82(21):10493-501. Epub 2008 Aug 20. PMID:18715929 doi:10.1128/JVI.00959-08

Proteopedia Page Contributors and Editors (what is this?)

David Canner, Alexander Berchansky

Retrieved from "http://52.214.119.220/wiki/index.php/Zanamivir"

@@ Line 1: / Line 1: @@
-<applet   load="" size="450" color="" frame="true"  spin="on" Scene ="Amprenavir/Amprenavi/2" align="right" caption="Amprenavir, better known as Agenerase, ([[3nu4]])"/>
+<StructureSection load='' size='340' side='right' caption='Zanamivir, better known as Relenza, ([[3b7e]])' scene='Zanamivir/Zanamivir/2'>
-===Better Known as: Agenerase===
+===Better Known as: Relenza===
-* Marketed By: GlaxoSmithKline<br />
+* Marketed By: GlaxoSmithKline
-* Major Indication: [[Human Immunodeficiency Virus]] Infection<br />
+* Major Indication: [[Influenza]] Infection
-* Drug Class: [[HIV Protease]] Inhibitor
+* Drug Class: [[Neuraminidase]] Inhibitor
-* Date of FDA Approval (Discontinued): 1999 (2004) <br />
+* Date of FDA Approval (Patent Expiration): 1999 (2016)
-* 2004 Sales: ~$50 Million
+* 2009 Sales: $1.1 Billion
-* Importance: It was the first [[HIV Protease]] inhibitor which required only twice-a-day dosing as opposed to every 8 hours. It was replaced by a longer acting prodrug version called [[Fosamprenavir]].
+* Importance: It was the first [[neuraminidase]] inhibitor to be approved by the FDA, followed a few months later by [[Oseltamivir]]. It was designed to be a [[Sialic acid]] analog. Newer strains of flu virus, primarily [[User:Michael Strong/H1N1|H1N1]], have developed varying levels of resistance to Oseltamivir, but a lesser extent to Zanamivir. Sales have increased dramatically since 2006 with scares of bird flu and swine flu pandemics.
 * See [[Pharmaceutical Drugs]] for more information about other drugs and diseases.
 ===Mechanism of Action===
-When [[HIV]] first infects someone, it directs the synthesis of several polyproteins. The maturation of the virus to its infectious form requires that these polyproteins be cleaved to their component proteins by [[HIV Protease]]. The subunits of <scene name='Amprenavir/Protease/1'>HIV Protease</scene> come together to form a catalytic tunnel capable of tightly binding the nascent peptides and cleaving them into their mature, infectious form. Within this tunnel lies <scene name='Amprenavir/Proteasec/1'>two Asp-Thr-Gly conserved sequences</scene>, which contain the <scene name='Amprenavir/Proteasecas/2'>catalytic Asp residues</scene>. These catalytic Asp residues carry out the hydrolytic cleavage of the polyprotein. Amprenavir <scene name='Amprenavir/Bound/1'>binds specifically</scene> to these conserved sequences within the HIV Protease tunnel, preventing the nascent polyproteins from entering. Unable to actively cleave the nascent proteins into their infectious form, HIV is unable to mature and proliferate, allowing the patients immune system to fight off the infection more easily.<ref>PMID:1799632</ref><ref>doi:10.1038/nrd1907</ref>
+Viral [[Neuraminidase]] is one of two major glycoproteins found on the surface of [[influenza]] viral membranes, the other being [[hemagglutinin]]. When the influenza virus infects a host cell, it attaches itself to the host via hemagglutinin interactions with host glycans, facilitating the fusion of host endosomal membrane with the viral membrane. After the virus has successfully infected the host and replicated extensively, the viral cargo is released from the cell via budding. During the budding process, the viral cargo is attached to the host cell once again via hemagglutinins, allowing the viral particle to form completely. Once the viral particle is formed, Neuraminidase cleaves the terminal sialic (neuraminic) acid residues from the glycan structures on the surface of the infected cell, breaking the hemmaglutinin-glycan interaction and promoting release of the viral particle to infect other cells. Zanamivir functions by inhibiting the function of <scene name='Zanamivir/Neuro/1'>viral neuraminidase</scene>, preventing the viral particle from being released from the infected cell, thus limiting the severity and spread of [[viral infections]].<ref>PMID:1438172</ref> It binds to the active site of Neuraminidase causing dramatic conformational adjustments which render the protein non-functional. This prevents neuraminidase from cleaving the hemmaglutinin-glycan tethers and releasing the viral cargo after viral replication. Zanamivir binding causes the <scene name='Zanamivir/150/1'>so-called 150 loop</scene> (residues 147-151) to shift, <scene name='Zanamivir/Active/2'>covering part of the binding pocket</scene>, while Zanamivir situates itself <scene name='Zanamivir/Active_site/1'>firmly within the active site</scene> using significant hydrogen bonding <scene name='Zanamivir/Bound/4'>interactions with residues</scene> Arg 118, Asp 151, Arg 152, Arg 224, Glu 276, Arg 292, Arg 371 and Tyr 406. Of note, His 274, for which the H274Y mutation confers resistance to inhibitors like [[Oseltamivir]], <scene name='Zanamivir/His/2'>does not interact with Zanamivir</scene>, explaining why the H274Y Neuraminidase mutant is not resistant to treatment with Zanamvir.<ref>doi: 10.1128/JVI.00959-08</ref>
+</StructureSection>
-===Drug Resistance===
-The biggest difficulty with treating [[HIV]] is the rapidity at which it mutates and becomes resistant to treatments. To view a comprehensive and interactive analysis of the mutations which confer drug resistance to [[HIV Protease]], See: [[HIV Protease Inhibitor Resistance Profile]]
 ===Pharmacokinetics===
-<table style="background: cellspacing="0px"  align="" cellpadding="0px" width="42%">
+<table style="background: cellspacing="0px"  align="" cellpadding="0px" width="52%">
 <tr>
 <td style="width:100%; vertical-align:top;border-width:0px; border-style:inset">

Zanamivir

From Proteopedia

Current revision

Better Known as: Relenza

Mechanism of Action

Pharmacokinetics

References

Proteopedia Page Contributors and Editors (what is this?)

Views

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