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Discovery and development of HIV-protease inhibitors

January 11, 2023

Many major physiological processes depend on regulation of proteolytic enzyme activity and there can be dramatic consequences when equilibrium between an enzyme and its substrates is disturbed. In this prospective, the discovery of small-molecule ligands, like protease inhibitors, that can modulate catalytic activities has an enormous therapeutic effect.[1] Hence, inhibition of the HIV protease is one of the most important approaches for the therapeutic intervention in HIV infection[2] and their development is regarded as major success of structure-based drug design.[3] They are highly effective against HIV[4] and have, since the 1990s, been a key component of anti-retroviral therapies for HIV/AIDS.[5]

History

Human immunodeficiency virus (HIV) is a lentivirus that has two major species, HIV-1 which causes the majority of the epidemic, and HIV-2, a close relative whose distribution is concentrated in western Africa.[6] HIV infection was first described in 1981 in San Francisco and New York City.[7] In 1985, HIV was identified as the causative agent of acquired immune deficiency syndrome (AIDS) and its complete genome was immediately available. This knowledge paved the way for the development of selective inhibitors.[6]

HIV-2 carries a slightly lower risk of transmission than HIV-1 and infection tends to progress more slowly to AIDS.[7] In common usage HIV usually implies HIV-1.[8]

HIV-1 protease is one of the best known aspartic proteases, and an attractive target for the treatment of AIDS.[9]

After the discovery of HIV protease it only took 10 years for its first inhibitor to reach the market.[10] The first reports of highly selective antagonists against the HIV protease were revealed in 1987. Phase I trials of saquinavir began in 1989 and it was the first HIV protease inhibitor to be approved for prescription use in 1995. Four months later, two other protease inhibitors, ritonavir and indinavir, were approved.[6] In 2009, ten protease inhibitors have reached the market for treatment against HIV but one protease inhibitor, amprenavir, was withdrawn from the market in 2004.[6][11]

Life cycle of HIV

 
The HIV replication cycle

HIV belongs to the class of viruses called retroviruses, which carry genetic information in the form of RNA. HIV infects T cells that carry the CD4 antigen on their surface. When HIV infects its target cell it requires fusion of the viral and cellular membranes.[12] The first step is the interaction between envelope proteins of the virus (gp120, gp41) and specific host-cell surface receptors (e.g. CD4 receptor) on the target cell. Then the virus binds to the chemokine coreceptors CXCR4 or CCR5, resulting in conformational changes in the envelope proteins. This fusion creates a pore through which the viral capsid enters the cell.[13] Following entry into the cell the RNA of the virus is reverse-transcribed to DNA by the first virally encoded enzyme, the reverse transcriptase. The viral DNA enters the nucleus where it is integrated into the genetic material of the cell by the integrase, a second virally encoded enzyme. Activation of the host cell leads to the transcription of the viral DNA into mRNA. The mRNA is then translated into viral proteins and the third virally encoded enzyme, namely HIV protease, is required to cleave a viral polyprotein precursor into individual mature proteins. The viral RNA and viral proteins assemble at the surface of the cell into new virions. The virions bud from the cell and are released to infect other cells. All infected cells are eventually killed because of this extensive cell damage, from the destruction of the host's genetic system to the budding and release of virions.[12]

Mechanism of action

There are several steps in the HIV life cycle that may be interfered with, thus stopping the replication of the virus. A very critical step is the proteolytic cleavage of the polypeptide precursors into mature enzymes and structural proteins catalyzed by HIV protease.[12] HIV protease inhibitors are peptide-like chemicals that competitively inhibit the action of the virus aspartyl protease. These drugs prevent proteolytic cleavage of HIV Gag and Pol polyproteins that include essential structural and enzymatic components of the virus. This prevents the conversion of HIV particles into their mature infectious form.[6]

Protease inhibitors can alter adipocyte metabolism causing lipodystrophy, a common side effect associated with the use of most HIV protease inhibitors. Many mechanisms have been proposed, for example inhibition of adipocyte differentiation, triglyceride accumulation and increased lipolysis. Theories considering the effect of protease inhibitors on insulin-stimulated glucose uptake have also been linked to the lipodystrophic syndrome. It is possible that protease inhibitors can cause a decrease in insulin-stimulated tyrosine phosphorylation of IRS-1, representing inhibition of early steps in insulin signaling. Decreased adiponectin secretion and induced expression of interleukin-6 associated with HIV protease inhibitors may also contribute to inhibition of insulin-stimulated glucose uptake.[14]

Design

Protease inhibitors were designed to mimic the transition state of the protease's actual substrates. A peptide linkage consisting of –NH-CO- is replaced by an hydroxyethylen group (-CH2-CH(OH)-) which the protease is unable to cleave. HIV protease inhibitors fit the active site of the HIV aspartic protease and were rationally designed utilizing knowledge of the aspartyl protease's mode of action. The most promising transition state mimic was hydroxyethylamine which led to the discovery of the first protease inhibitor, saquinavir. Following that discovery, other HIV protease inhibitors were designed using the same principle.[15]

Binding site

 
A schematic structure of a HIV-1 protease. The monomers are shown in green and cyan, the Asp-25 and Asp-25´ residues are shown in red, and Ile50 and Ile50´ residues linked to a water molecule are shown in purple.

The HIV protease is a C2-symmetric homodimeric enzyme consisting of two 99 amino acid monomers. Each monomer contributes an aspartic acid residue that is essential for catalysis,[6] Asp-25 and Asp-25´. The HIV protease has the sequence Asp-Thr-Gly, which is conserved among other mammalian aspartic protease enzymes. An extended beta-sheet region on the monomers, known as the flap, constitutes in part the substrate binding site with the two aspartyl residues lying on the bottom of a hydrophobic cavity.[12][16][17] Each flexible flap contains three characteristic regions: side chains that extend outward (Met46, Phe53), hydrophobic chains extending inward (Ile47, Ile54), and a glycine rich region (Gly48, 49, 51, 52). Ile50 remains at the tip of the turn and when the enzyme is unliganded a water molecule makes hydrogen bonds to the backbone of Ile50 on each monomer.[17]

HIV proteases catalyze the hydrolysis of peptide bonds with high sequence selectivity and catalytic proficiency. The mechanism of the HIV protease shares many features with the rest of the aspartic protease family although the full detailed mechanism of this enzyme is not fully understood.[12] The water molecule seems to play a role in the opening and closing of the flaps as well as increasing the affinity between enzyme and substrate. The aspartyl residues are involved in the hydrolysis of the peptide bonds.[17] The preferred cleavage site for this enzyme is the N-terminal side of proline residues, especially between phenylalanine and proline or tyrosine and proline.[6][16]

Development

The first HIV protease inhibitor, saquinavir, is a peptidomimetic hydroxyethylamine[6] and was marketed in 1995.[18] It is a transition state analogue of a native substrate of the protease.[6] The observation that HIV-1 protease cleaves the sequences containing the dipeptides Tyr-Pro or Phe-Pro was the basic design criterion.[19] Addition of the decahydroisoquinoline (DIQ) group was one of the most significant modifications that led to the discovery of saquinavir. This substituent improves aqueous solubility and potency by limiting the conformational freedom of the inhibitor.[20] Saquinavir is effective against both HIV-1 and HIV-2[5] and is usually well tolerated but high serum concentration is not achieved.[11]

Ritonavir, a peptidomimetic HIV protease inhibitor, was marketed in 1996.[18] It was designed to fit the C2-symmetry in the binding site of the protease.[6] The developers of ritonavir, Abbott Laboratories, started with compounds that were active against the virus but had poor bioavailability. Some improvements were made, for example the terminal phenyl residues were removed and pyridyl groups put instead to add water solubility. The final product of these improvements was ritonavir.[19] Significant gastrointestinal side effects and a large pill burden are ritonavir's main drawbacks and is therefore not used as a single treatment.[11] However, it is a strong inhibitor of the cytochrome P450 enzyme mediated metabolism[19] and it is only used in a combination therapy with other protease inhibitors for pharmacokinetic boosting.[11]

Indinavir, which is a peptidomimetic hydroxyethylene HIV protease inhibitor, reached the market in 1996.[6][18] The design of indinavir was guided by molecular modeling and the X-ray crystal structure of the inhibited enzyme complex. The terminal phenyl constituents contribute hydrophobic binding to increase potency.[19] It is an analogue of the phenylalanine-proline cleavage site of the HIV Gag-polyprotein.[6]

Nelfinavir was the first protease inhibitor that was not peptidomimetic. In the design process of nelfinavir, an orally bioavailable and nonpeptidic inhibitor, iterative protein cocrystal structure analysis of peptidic inhibitors was used and parts of the inhibitors were replaced by nonpeptidic substituents.[19] Nelfinavir contains a novel 2-methyl-3-hydroxybenzamide group, whereas its carboxyl terminal contains the same DIQ group as saquinavir.[19] Nelfinavir was marketed in 1997[18] and was the first protease inhibitor to be indicated for pediatric AIDS.[19]

Amprenavir reached the market in 1999.[18] It is an N,N-disubstituded amino-sulfonamide nonpeptide HIV protease inhibitor[6] and shares some common features with previous protease inhibitors. It has a core similar to that of saquinavir but with different functional groups on both ends. On one end it has a tetrahydrofuran carbamate group and on the other end is an isobutylphenyl sulfonamide with an added amide. This structure results in fewer chiral centers, that makes it easier to synthesize and gives it enhanced aqueus solubility. That in turn gives better oral bioavailability.[19] However, amprenavir was withdrawn from the market in 2004 since fosamprenavir, its prodrug, proved superior in many aspects.[6]

Lopinavir was marketed in 2000[18] and was originally designed to diminish the interactions of the inhibitor with Val82 of the HIV-1 protease, a residue that is often mutated in the drug resistant strains of the virus.[19] It is a peptidomimetic HIV protease inhibitor[6] and its core is identical to that of ritonavir. Instead of the 5-thiazolyl end group in ritonavir, lopinavir has a phenoxyacetyl group and the 2-isopropylthiazolyl group in ritonavir was replaced by a modified valine in which the amino terminal had a six-membered cyclic urea attached.[19]

Fosamprenavir was marketed in 2003[18] and is a phosphoester prodrug that is rapidly and extensively metabolized to amprenavir.[21] The solubility and bioavailability is better than of amprenavir[6] which results in reduced daily pill burden.[22]

Atazanavir was marketed in 2003[18] and is an azapeptide protease inhibitor[18] designed to fit the C2-symmetry of the enzyme binding site.[11] Atazanavir showed better resistant profiles than previous HIV protease inhibitors.[4] It is unique among the other protease inhibitors as it can only be absorbed in an acidic environment.[11]

Tipranavir is a nonpeptidic HIV-1 protease inhibitor[11] and reached the market in 2005.[18] Unlike other HIV protease inhibitors on the market, tipranavir was developed from a nonpeptidic coumarin template and its antiprotease activity was discovered by high-throughput screening.[23] This sulfonamide containing 5,6-dihydro-4-hydroxy-2-pyrone had emerged from screenings of 3-substituted coumarins and dihydropyrones.[24] It possesses broad antiviral activity against multiple protease inhibitor resistant HIV-1.[25]

Darunavir reached the market in 2006[18] and is a nonpeptidic analogue of amprenavir, with a critical change at the terminal tetrahydrofuran (THF) group. Instead of a single THF group, darunavir contains two THF groups fused in the compound, to form a bis-THF moiety which makes it more effective than amprenavir. With this structural change, the stereochemistry around the bis-THF moiety confers orientational changes, that allows for continued binding with the protease which has developed a resistance for amprenavir.[26]

All the FDA approved protease inhibitors are listed below.

HIV protease inhibitors the FDA has approved
       
Saquinavir Nelfinavir Ritonavir Lopinavir
     
Amprenavir Fosamprenavir Darunavir
     
Indinavir Atazanavir Tipranavir

Structure-activity relationship

 
A simplified image of a protease inhibitor binding to the active site of the HIV-1 protease. The central core motif is shown in blue with the hydroxyl group forming hydrogen bonds with Asp-25 and Asp-25´. Hydrogen bonds also connect carbonyl groups on the inhibitor to the water molecule linked to Ile50 and Ile50´. Hydrophobic groups are shown in pink and their complementing pockets referred to as S1, S1´, S2 and S2´.

All the HIV protease inhibitors on the market contain a central core motif consisting of a hydroxyethylen scaffold, with the only exception being the central core of tipranavir, which is based on a coumarin scaffold.[15] A very important group on the HIV protease inhibitors is a hydroxyl group on the core motif which forms a hydrogen bond with the carboxylic acid on the Asp-25 and Asp-25´ residues in the binding site.[16][27] Hydrogen bonds between the water molecule, which is linked to Ile50 and Ile50', and carbonyl groups of the peptidomimetic inhibitors seem to connect them with the flap regions.[19] On the other hand, on the nonpeptidic inhibitors, there is a proton acceptor which replaces the tetracoordinated water molecule and interacts directly with the two Ile50 residues on the flap of the enzyme.[28] Specific pockets in the binding site of the HIV protease, often referred to as S1, S1',S2 and S2', recognize hydrophobic amino acids on natural substrates. The potency of inhibitors bearing hydrophobic groups complementing these areas is therefore increased.[29] Some residues in the enzyme binding site are capable of forming hydrogen bonds with hydrophilic groups on the inhibitor, for example with the THF moieties on amprenavir and darunavir. Since darunavir has a bis-THF moiety, instead of a single THF moiety like on amprenavir, it can form more hydrogen bonds and increase binding energy.[26]

Resistance

Mutations that code for alterations of the conformational shape facilitate resistance of HIV to protease inhibitors.[26] The locations of these mutations are primarily in the active site of the HIV protease enzyme as well as outside of the active site, including those at protease cleavage sites in the Gag-Pol polyprotein precursors. The cleavage sites have highly diverse sequences, so the protease recognizes its substrates not based on sequence but rather the conserved 3D shape the substrates share when bound at the active site. This conserved shape has been named the substrate envelope.[30] The active site mutations have been shown to directly change the interactions of the inhibitors, and mostly occur at positions where inhibitors contact protease residues beyond the substrate envelope.[31] The non-active site mutations are considered to affect by other mechanisms, like influencing dimer stability and conformational flexibility.[32][33]

Over 100 single gene point mutations have been described, of which at least 26 are specific to protease inhibitors. Of these, there are about 15 primary or major mutations that are significant enough to change drug activity.[26] Many mutated residues have been found in HIV-1 protease which cause drug resistance, for example Leu33 changes to Ile, Val, or Phe; Val82 to Ala, Phe, Leu, or Thr; Ile84 to Val; and Leu90 to Met.[34] Different mutations affects different protease inhibitors. For instance, mutations at Leu90 evidently affect saquinavir and nelfinavir while indinavir activity is affected by mutations at Met46, Val82, and Ile84, and fosamprenavir is affected when Ile50 changes to Val and at Ile84. A combination of mutations can render high-level drug resistance but single mutations normally do not equate with drug resistance to protease inhibitors.[26] The mutations can be divided into primary mutations and secondary mutations. Primary mutations often have only a small effect on resistance. The chemical structures of most protease inhibitors are quite similar, so it is not surprising that some primary mutations lead simultaneously to resistance to multiple protease inhibitors. Cross-resistance is one of the major problems of protease inhibitor treatment.[35] Additional mutations emerging in the protease during continuous protease inhibitor therapy are commonly referred to as secondary mutations. This can lead to high-level protease inhibitor resistance.[35]

The Stanford HIV RT and Protease Sequence Database (also called the “HIV Drug Resistance Database”) was formed in 1998 with HIV reverse transcriptase and protease sequences from persons with well-characterized antiretroviral treatment histories, and is publicly available to query resistance mutations and genotype-treatment, genotype-phenotype, and genotype-outcome correlations[citation needed]

Although the substrate envelope provides the general strategy of designing inhibitors that mimic the substrate and stay within the envelope to avoid resistance conferred by most active site mutations,[36][37] there is no general strategy to tackle the problem of drug resistance, especially due to those away from the active site. Researches directed towards development of new therapies to cure AIDS are focused on avoiding cross-resistance to drugs that are already on the market.[12]

Current status

In January 2018 darunavir was still the most recent HIV protease inhibitor to reach the market.[38]

In 2006, GlaxoSmithKline discontinued the phase II clinical development of brecanavir, an investigational protease inhibitor for the treatment of HIV, due to insurmountable issues regarding formulation.[39]

In the summer of 2009, GlaxoSmithKline and Concert Pharmaceuticals announced their collaboration to develop and commercialise deuterium-containing medicines. One of them is CTP-518, a protease inhibitor for the treatment of HIV, expected to enter phase I clinical trials in the second half of 2009. CTP-518 is a novel HIV protease inhibitor developed by replacing certain key hydrogen atoms of atazanavir with deuterium. Pre-clinical studies have demonstrated that this modification fully retains the antiviral potency but can evidently slow hepatic metabolism and thereby increase the half life and plasma trough levels. CTP-518, therefore, has the potential to be the first HIV protease inhibitor to eliminate the need to co-dose with a boosting agent, such as ritonavir.[40]

See also

References

  1. ^ Cuccioloni, M; Mozzicafreddo, M; Bonfili, L; Cecarini, V; Eleuteri, A. M.; Angeletti, M (2009). "Natural occurring polyphenols as template for drug design. Focus on serine proteases". Chemical Biology & Drug Design. 74 (1): 1–15. doi:10.1111/j.1747-0285.2009.00836.x. PMID 19519739.
  2. ^ Chen, X; Kempf, D. J.; Li, L; Sham, H. L.; Vasavanonda, S; Wideburg, N. E.; Saldivar, A; Marsh, K. C.; McDonald, E; Norbeck, D. W. (2003). "Synthesis and SAR studies of potent HIV protease inhibitors containing novel dimethylphenoxyl acetates as P2 ligands". Bioorganic & Medicinal Chemistry Letters. 13 (21): 3657–60. doi:10.1016/j.bmcl.2003.08.043. PMID 14552751.
  3. ^ Adachi, M; Ohhara, T; Kurihara, K; Tamada, T; Honjo, E; Okazaki, N; Arai, S; Shoyama, Y; Kimura, K; Matsumura, H; Sugiyama, S; Adachi, H; Takano, K; Mori, Y; Hidaka, K; Kimura, T; Hayashi, Y; Kiso, Y; Kuroki, R (2009). "Structure of HIV-1 protease in complex with potent inhibitor KNI-272 determined by high-resolution X-ray and neutron crystallography". Proceedings of the National Academy of Sciences. 106 (12): 4641–6. Bibcode:2009PNAS..106.4641A. doi:10.1073/pnas.0809400106. PMC 2660780. PMID 19273847.
  4. ^ a b Yanchunas Jr, J; Langley, D. R.; Tao, L; Rose, R. E.; Friborg, J; Colonno, R. J.; Doyle, M. L. (2005). "Molecular basis for increased susceptibility of isolates with atazanavir resistance-conferring substitution I50L to other protease inhibitors". Antimicrobial Agents and Chemotherapy. 49 (9): 3825–32. doi:10.1128/AAC.49.9.3825-3832.2005. PMC 1195399. PMID 16127059.
  5. ^ a b Brower, E. T.; Bacha, U. M.; Kawasaki, Y; Freire, E (2008). "Inhibition of HIV-2 protease by HIV-1 protease inhibitors in clinical use". Chemical Biology & Drug Design. 71 (4): 298–305. doi:10.1111/j.1747-0285.2008.00647.x. PMID 18312292. S2CID 8461472.
  6. ^ a b c d e f g h i j k l m n o p Brunton, L.L.; Lazo, J.S.; Parker, K.L. (2006). Goodman and Gilmans's The Pharmacological Basis of Therapeutics (11th ed.). McGraw-Hill.[page needed]
  7. ^ a b HIV Disease at eMedicine
  8. ^ Kurup, Alka; Mekapati, Suresh; Garg, Rajni; Hansch, Corwin (2003). "HIV-1 Protease Inhibitors: A Comparative QSAR Analysis". Current Medicinal Chemistry. 10 (17): 1679–88. doi:10.2174/0929867033457070. PMID 12871116.
  9. ^ Shi, Haibin; Liu, Kai; Leong, Wendy W.Y.; Yao, Shao Q. (2009). "Expedient solid-phase synthesis of both symmetric and asymmetric diol libraries targeting aspartic proteases". Bioorganic & Medicinal Chemistry Letters. 19 (14): 3945–8. doi:10.1016/j.bmcl.2009.03.041. PMID 19328682.
  10. ^ Turk, Boris (2006). "Targeting proteases: successes, failures and future prospects". Nature Reviews Drug Discovery. 5 (9): 785–99. doi:10.1038/nrd2092. PMID 16955069. S2CID 4156908.
  11. ^ a b c d e f g Graziani, Amy L (June 17, 2014). "HIV protease inhibitors". UpToDate.
  12. ^ a b c d e f Brik, A. and Wong, C.H. (2003) HIV-1 protease: mechanism and drug discovery. Organic & Biomolecular Chemistry. 1(1); 5–14.
  13. ^ Warnke, D., Barreto, J. and Temesgen, Z. (2007) Antiretroviral drugs. Journal of Clinical Pharmacology. 47(12); 1570–1579.
  14. ^ Kim, R.J., Wilson, C.G., Wabitsch, M., Lazar, M.A. and Steppan, C.M. (2006) HIV protease inhibitor-specific alterations in human adipocyte differentiation and metabolism. Obesity. 14; 994–1002.
  15. ^ a b De Clercq, E. (2009) The history of antiretrovirals: key discoveries over the past 25 years. Reviews in Medical Virology. 19; 287–299.
  16. ^ a b c Mimoto, T., Hattori, N., Takaku, H. et al. (2000) Structure-activity relationship of orally potent tripeptide-based HIV protease inhibitors containing hydroxymethylcarbonyl isostere. Chemical & Pharmaceutical Bulletin. 48(9); 1310–1326.
  17. ^ a b c Perez, M.A.S., Fernandes, P.A. and Ramos, M.J. (2007) Drug design: New inhibitors for HIV-1 protease based on Nelfinavir as lead. Journal of Molecular Graphics and Modelling. 26; 634–642.
  18. ^ a b c d e f g h i j k Flexner, C. (2007) HIV drug development: the next 25 years. Nature Reviews Drug Discovery. 6; 959–966.
  19. ^ a b c d e f g h i j k Wlodawer, A. (2002) Rational approach to AIDS drug design through structural biology. Annual Review of Medicine. 53; 595–614.
  20. ^ Smith, H.J. and Simons, C. (2005) Enzymes and Their Inhibition: Drug Development (6th edition). United States of America: CRC press
  21. ^ Luber, A.D. et al. (2007) Steady-state pharmacokinetics of once-daily fosamprenavir/ritonavir and atazanavir/ritonavir alone and in combination with 20mg omeprazole in healthy volunteers. HIV medicine. 8;457–464
  22. ^ Chapman, T.M., Plosker, G.L. and Perry, C.M. (2004) Fosamprenavir – A Review of its Use in the Management of Antiretroviral Therapy-naive Patients with HIV Infection. Drugs. 64; 2101–2124.
  23. ^ Larder, B.A. et al. (2000) Tipranavir inhibits broadly protease inhibitor-resistant HIV-1 clinical samples. AIDS. 14;1943–1948
  24. ^ Schobert, R., Stehle, R. and Walter, H. (2008) Tipranavir analogous 3-sulfonylanilidotetronic acids: new synthesis and structure-dependent anti-HIV activity. Tetrahedron. 64;9401–9407.
  25. ^ Doyon, L. Et al. (2005) Selection and characterization of HIV-1 showing reduced susceptibility to the non-peptidic protease inhibitor tipranavir. Antiviral Research. 68;27–35.
  26. ^ a b c d e McCoy, C. (2007) Darunavir: A nonpeptidic antiretroviral protease inhibitor. Clinical Therapeutics. 29(8); 1559–1576.
  27. ^ Liu, F., Kovalevsky, A.Y., Tie, Y., Ghosh, A.K., Harrison, R.W. and Weber, I.T. (2008) Effect of Flap Mutations on Structure of HIV-protease and Inhibition by Saquinavir and Darunavir. Journal of Molecular Biology. 381(1); 102–115
  28. ^ Lebon, F. and Ledecq, M. (2000) Approaches to the Design of Effective HIV-1 Protease Inhibitors. Current Medicinal Chemistry. 7; 455–477.
  29. ^ Blum, A. et al. (2008) Achiral oligoamines as versatile tool for the development of aspartic protease inhibitors. Bioorganic & Medicinal Chemistry. 16; 8574–8586.
  30. ^ Prabu-Jeyabalan, Nalivaika E, Schiffer CA. (2002) Substrate shape determines specificity of recognition for HIV-1 protease: analysis of crystal structures of six substrate complexes. "Structure" 10(3):369-81.
  31. ^ King NM, Prabu-Jeyabalan M, Nalivaika EA, Schiffer CA (2004) Combating susceptibility to drug resistance: lessons from HIV-1 protease.Chem Biol. Oct;11(10):1333-8.
  32. ^ Bihani, S. C., Das, A., Prashar, V., Ferrer, J.-L. and Hosur; M.V. (2009) Resistance mechanism revealed by crystal structures of unliganded nelfinavir-resistant HIV-1 protease non-active site mutants N88D and N88S. Biochemical and Biophysical Research Communications. 389; 295–300.
  33. ^ de Vera IM, Smith AN, Dancel MC, Huang X, Dunn BM, Fanucci GE. (2013) Biochemistry. Elucidating a relationship between conformational sampling and drug resistance in HIV-1 protease. 14;52(19):3278-88. doi: 10.1021/bi400109d. Epub 2013 May 1.
  34. ^ Lemke, T.L., Williams, D.A., Roche, V.F. and Zito, S.W. (2008) Foye´s Principles of Medicinal Chemistry ( 6th edition). United States of America: Lippincott williams & Wilkins, a Wolters Kluwer business.
  35. ^ a b Maarseveen, N.V. and Boucher, C. (2008) Antiretroviral Resistance in Clinical Practice. London: Mediscript Ltd.
  36. ^ Kairys V, Gilson MK, Lather V, Schiffer CA, Fernandes MX. (2009) Toward the design of mutation-resistant enzyme inhibitors: further evaluation of the substrate envelope hypothesis. Chem Biol Drug Des. Sep;74(3):234-45. doi: 10.1111/j.1747-0285.2009.00851.x
  37. ^ Nalam MN, Ali A, Altman MD, Reddy GS, Chellappan S, Kairys V, Ozen A, Cao H, Gilson MK, Tidor B, Rana TM, Schiffer CA. (2010) Evaluating the substrate-envelope hypothesis: structural analysis of novel HIV-1 protease inhibitors designed to be robust against drug resistance. J Virol. 2010 May;84(10):5368-78. doi: 10.1128/JVI.02531-09. Epub 2010 Mar 17.
  38. ^ De Clercq, E. (2009) Anti-HIV drugs: 25 compounds approved within 25 years after the discovery of HIV. International Journal of Antimicrobial Agents. 33; 307–320.
  39. ^ . Archived from the original on 2008-12-03. Retrieved 2008-06-11. GlaxoSmithKline discontinues clinical development of investigational protease inhibitor brecanavir (640385). Retrieved November 4th. 2009.
  40. ^ . Archived from the original on 2009-08-31. Retrieved 2009-11-05.GSK and Concert Pharmaceuticals form alliance to develop novel deuterium-modified drugs. Retrieved November 4th. 2009.

January 11, 2023
discovery, development, protease, inhibitors, many, major, physiological, processes, depend, regulation, proteolytic, enzyme, activity, there, dramatic, consequences, when, equilibrium, between, enzyme, substrates, disturbed, this, prospective, discovery, smal. Many major physiological processes depend on regulation of proteolytic enzyme activity and there can be dramatic consequences when equilibrium between an enzyme and its substrates is disturbed In this prospective the discovery of small molecule ligands like protease inhibitors that can modulate catalytic activities has an enormous therapeutic effect 1 Hence inhibition of the HIV protease is one of the most important approaches for the therapeutic intervention in HIV infection 2 and their development is regarded as major success of structure based drug design 3 They are highly effective against HIV 4 and have since the 1990s been a key component of anti retroviral therapies for HIV AIDS 5 Contents 1 History 2 Life cycle of HIV 3 Mechanism of action 4 Design 4 1 Binding site 4 2 Development 4 3 Structure activity relationship 4 4 Resistance 5 Current status 6 See also 7 ReferencesHistory EditHuman immunodeficiency virus HIV is a lentivirus that has two major species HIV 1 which causes the majority of the epidemic and HIV 2 a close relative whose distribution is concentrated in western Africa 6 HIV infection was first described in 1981 in San Francisco and New York City 7 In 1985 HIV was identified as the causative agent of acquired immune deficiency syndrome AIDS and its complete genome was immediately available This knowledge paved the way for the development of selective inhibitors 6 HIV 2 carries a slightly lower risk of transmission than HIV 1 and infection tends to progress more slowly to AIDS 7 In common usage HIV usually implies HIV 1 8 HIV 1 protease is one of the best known aspartic proteases and an attractive target for the treatment of AIDS 9 After the discovery of HIV protease it only took 10 years for its first inhibitor to reach the market 10 The first reports of highly selective antagonists against the HIV protease were revealed in 1987 Phase I trials of saquinavir began in 1989 and it was the first HIV protease inhibitor to be approved for prescription use in 1995 Four months later two other protease inhibitors ritonavir and indinavir were approved 6 In 2009 ten protease inhibitors have reached the market for treatment against HIV but one protease inhibitor amprenavir was withdrawn from the market in 2004 6 11 Life cycle of HIV Edit The HIV replication cycle HIV belongs to the class of viruses called retroviruses which carry genetic information in the form of RNA HIV infects T cells that carry the CD4 antigen on their surface When HIV infects its target cell it requires fusion of the viral and cellular membranes 12 The first step is the interaction between envelope proteins of the virus gp120 gp41 and specific host cell surface receptors e g CD4 receptor on the target cell Then the virus binds to the chemokine coreceptors CXCR4 or CCR5 resulting in conformational changes in the envelope proteins This fusion creates a pore through which the viral capsid enters the cell 13 Following entry into the cell the RNA of the virus is reverse transcribed to DNA by the first virally encoded enzyme the reverse transcriptase The viral DNA enters the nucleus where it is integrated into the genetic material of the cell by the integrase a second virally encoded enzyme Activation of the host cell leads to the transcription of the viral DNA into mRNA The mRNA is then translated into viral proteins and the third virally encoded enzyme namely HIV protease is required to cleave a viral polyprotein precursor into individual mature proteins The viral RNA and viral proteins assemble at the surface of the cell into new virions The virions bud from the cell and are released to infect other cells All infected cells are eventually killed because of this extensive cell damage from the destruction of the host s genetic system to the budding and release of virions 12 Mechanism of action EditThere are several steps in the HIV life cycle that may be interfered with thus stopping the replication of the virus A very critical step is the proteolytic cleavage of the polypeptide precursors into mature enzymes and structural proteins catalyzed by HIV protease 12 HIV protease inhibitors are peptide like chemicals that competitively inhibit the action of the virus aspartyl protease These drugs prevent proteolytic cleavage of HIV Gag and Pol polyproteins that include essential structural and enzymatic components of the virus This prevents the conversion of HIV particles into their mature infectious form 6 Protease inhibitors can alter adipocyte metabolism causing lipodystrophy a common side effect associated with the use of most HIV protease inhibitors Many mechanisms have been proposed for example inhibition of adipocyte differentiation triglyceride accumulation and increased lipolysis Theories considering the effect of protease inhibitors on insulin stimulated glucose uptake have also been linked to the lipodystrophic syndrome It is possible that protease inhibitors can cause a decrease in insulin stimulated tyrosine phosphorylation of IRS 1 representing inhibition of early steps in insulin signaling Decreased adiponectin secretion and induced expression of interleukin 6 associated with HIV protease inhibitors may also contribute to inhibition of insulin stimulated glucose uptake 14 Design EditProtease inhibitors were designed to mimic the transition state of the protease s actual substrates A peptide linkage consisting of NH CO is replaced by an hydroxyethylen group CH2 CH OH which the protease is unable to cleave HIV protease inhibitors fit the active site of the HIV aspartic protease and were rationally designed utilizing knowledge of the aspartyl protease s mode of action The most promising transition state mimic was hydroxyethylamine which led to the discovery of the first protease inhibitor saquinavir Following that discovery other HIV protease inhibitors were designed using the same principle 15 Binding site Edit A schematic structure of a HIV 1 protease The monomers are shown in green and cyan the Asp 25 and Asp 25 residues are shown in red and Ile50 and Ile50 residues linked to a water molecule are shown in purple The HIV protease is a C2 symmetric homodimeric enzyme consisting of two 99 amino acid monomers Each monomer contributes an aspartic acid residue that is essential for catalysis 6 Asp 25 and Asp 25 The HIV protease has the sequence Asp Thr Gly which is conserved among other mammalian aspartic protease enzymes An extended beta sheet region on the monomers known as the flap constitutes in part the substrate binding site with the two aspartyl residues lying on the bottom of a hydrophobic cavity 12 16 17 Each flexible flap contains three characteristic regions side chains that extend outward Met46 Phe53 hydrophobic chains extending inward Ile47 Ile54 and a glycine rich region Gly48 49 51 52 Ile50 remains at the tip of the turn and when the enzyme is unliganded a water molecule makes hydrogen bonds to the backbone of Ile50 on each monomer 17 HIV proteases catalyze the hydrolysis of peptide bonds with high sequence selectivity and catalytic proficiency The mechanism of the HIV protease shares many features with the rest of the aspartic protease family although the full detailed mechanism of this enzyme is not fully understood 12 The water molecule seems to play a role in the opening and closing of the flaps as well as increasing the affinity between enzyme and substrate The aspartyl residues are involved in the hydrolysis of the peptide bonds 17 The preferred cleavage site for this enzyme is the N terminal side of proline residues especially between phenylalanine and proline or tyrosine and proline 6 16 Development Edit The first HIV protease inhibitor saquinavir is a peptidomimetic hydroxyethylamine 6 and was marketed in 1995 18 It is a transition state analogue of a native substrate of the protease 6 The observation that HIV 1 protease cleaves the sequences containing the dipeptides Tyr Pro or Phe Pro was the basic design criterion 19 Addition of the decahydroisoquinoline DIQ group was one of the most significant modifications that led to the discovery of saquinavir This substituent improves aqueous solubility and potency by limiting the conformational freedom of the inhibitor 20 Saquinavir is effective against both HIV 1 and HIV 2 5 and is usually well tolerated but high serum concentration is not achieved 11 Ritonavir a peptidomimetic HIV protease inhibitor was marketed in 1996 18 It was designed to fit the C2 symmetry in the binding site of the protease 6 The developers of ritonavir Abbott Laboratories started with compounds that were active against the virus but had poor bioavailability Some improvements were made for example the terminal phenyl residues were removed and pyridyl groups put instead to add water solubility The final product of these improvements was ritonavir 19 Significant gastrointestinal side effects and a large pill burden are ritonavir s main drawbacks and is therefore not used as a single treatment 11 However it is a strong inhibitor of the cytochrome P450 enzyme mediated metabolism 19 and it is only used in a combination therapy with other protease inhibitors for pharmacokinetic boosting 11 Indinavir which is a peptidomimetic hydroxyethylene HIV protease inhibitor reached the market in 1996 6 18 The design of indinavir was guided by molecular modeling and the X ray crystal structure of the inhibited enzyme complex The terminal phenyl constituents contribute hydrophobic binding to increase potency 19 It is an analogue of the phenylalanine proline cleavage site of the HIV Gag polyprotein 6 Nelfinavir was the first protease inhibitor that was not peptidomimetic In the design process of nelfinavir an orally bioavailable and nonpeptidic inhibitor iterative protein cocrystal structure analysis of peptidic inhibitors was used and parts of the inhibitors were replaced by nonpeptidic substituents 19 Nelfinavir contains a novel 2 methyl 3 hydroxybenzamide group whereas its carboxyl terminal contains the same DIQ group as saquinavir 19 Nelfinavir was marketed in 1997 18 and was the first protease inhibitor to be indicated for pediatric AIDS 19 Amprenavir reached the market in 1999 18 It is an N N disubstituded amino sulfonamide nonpeptide HIV protease inhibitor 6 and shares some common features with previous protease inhibitors It has a core similar to that of saquinavir but with different functional groups on both ends On one end it has a tetrahydrofuran carbamate group and on the other end is an isobutylphenyl sulfonamide with an added amide This structure results in fewer chiral centers that makes it easier to synthesize and gives it enhanced aqueus solubility That in turn gives better oral bioavailability 19 However amprenavir was withdrawn from the market in 2004 since fosamprenavir its prodrug proved superior in many aspects 6 Lopinavir was marketed in 2000 18 and was originally designed to diminish the interactions of the inhibitor with Val82 of the HIV 1 protease a residue that is often mutated in the drug resistant strains of the virus 19 It is a peptidomimetic HIV protease inhibitor 6 and its core is identical to that of ritonavir Instead of the 5 thiazolyl end group in ritonavir lopinavir has a phenoxyacetyl group and the 2 isopropylthiazolyl group in ritonavir was replaced by a modified valine in which the amino terminal had a six membered cyclic urea attached 19 Fosamprenavir was marketed in 2003 18 and is a phosphoester prodrug that is rapidly and extensively metabolized to amprenavir 21 The solubility and bioavailability is better than of amprenavir 6 which results in reduced daily pill burden 22 Atazanavir was marketed in 2003 18 and is an azapeptide protease inhibitor 18 designed to fit the C2 symmetry of the enzyme binding site 11 Atazanavir showed better resistant profiles than previous HIV protease inhibitors 4 It is unique among the other protease inhibitors as it can only be absorbed in an acidic environment 11 Tipranavir is a nonpeptidic HIV 1 protease inhibitor 11 and reached the market in 2005 18 Unlike other HIV protease inhibitors on the market tipranavir was developed from a nonpeptidic coumarin template and its antiprotease activity was discovered by high throughput screening 23 This sulfonamide containing 5 6 dihydro 4 hydroxy 2 pyrone had emerged from screenings of 3 substituted coumarins and dihydropyrones 24 It possesses broad antiviral activity against multiple protease inhibitor resistant HIV 1 25 Darunavir reached the market in 2006 18 and is a nonpeptidic analogue of amprenavir with a critical change at the terminal tetrahydrofuran THF group Instead of a single THF group darunavir contains two THF groups fused in the compound to form a bis THF moiety which makes it more effective than amprenavir With this structural change the stereochemistry around the bis THF moiety confers orientational changes that allows for continued binding with the protease which has developed a resistance for amprenavir 26 All the FDA approved protease inhibitors are listed below HIV protease inhibitors the FDA has approved Saquinavir Nelfinavir Ritonavir Lopinavir Amprenavir Fosamprenavir Darunavir Indinavir Atazanavir TipranavirStructure activity relationship Edit A simplified image of a protease inhibitor binding to the active site of the HIV 1 protease The central core motif is shown in blue with the hydroxyl group forming hydrogen bonds with Asp 25 and Asp 25 Hydrogen bonds also connect carbonyl groups on the inhibitor to the water molecule linked to Ile50 and Ile50 Hydrophobic groups are shown in pink and their complementing pockets referred to as S1 S1 S2 and S2 All the HIV protease inhibitors on the market contain a central core motif consisting of a hydroxyethylen scaffold with the only exception being the central core of tipranavir which is based on a coumarin scaffold 15 A very important group on the HIV protease inhibitors is a hydroxyl group on the core motif which forms a hydrogen bond with the carboxylic acid on the Asp 25 and Asp 25 residues in the binding site 16 27 Hydrogen bonds between the water molecule which is linked to Ile50 and Ile50 and carbonyl groups of the peptidomimetic inhibitors seem to connect them with the flap regions 19 On the other hand on the nonpeptidic inhibitors there is a proton acceptor which replaces the tetracoordinated water molecule and interacts directly with the two Ile50 residues on the flap of the enzyme 28 Specific pockets in the binding site of the HIV protease often referred to as S1 S1 S2 and S2 recognize hydrophobic amino acids on natural substrates The potency of inhibitors bearing hydrophobic groups complementing these areas is therefore increased 29 Some residues in the enzyme binding site are capable of forming hydrogen bonds with hydrophilic groups on the inhibitor for example with the THF moieties on amprenavir and darunavir Since darunavir has a bis THF moiety instead of a single THF moiety like on amprenavir it can form more hydrogen bonds and increase binding energy 26 Resistance Edit Mutations that code for alterations of the conformational shape facilitate resistance of HIV to protease inhibitors 26 The locations of these mutations are primarily in the active site of the HIV protease enzyme as well as outside of the active site including those at protease cleavage sites in the Gag Pol polyprotein precursors The cleavage sites have highly diverse sequences so the protease recognizes its substrates not based on sequence but rather the conserved 3D shape the substrates share when bound at the active site This conserved shape has been named the substrate envelope 30 The active site mutations have been shown to directly change the interactions of the inhibitors and mostly occur at positions where inhibitors contact protease residues beyond the substrate envelope 31 The non active site mutations are considered to affect by other mechanisms like influencing dimer stability and conformational flexibility 32 33 Over 100 single gene point mutations have been described of which at least 26 are specific to protease inhibitors Of these there are about 15 primary or major mutations that are significant enough to change drug activity 26 Many mutated residues have been found in HIV 1 protease which cause drug resistance for example Leu33 changes to Ile Val or Phe Val82 to Ala Phe Leu or Thr Ile84 to Val and Leu90 to Met 34 Different mutations affects different protease inhibitors For instance mutations at Leu90 evidently affect saquinavir and nelfinavir while indinavir activity is affected by mutations at Met46 Val82 and Ile84 and fosamprenavir is affected when Ile50 changes to Val and at Ile84 A combination of mutations can render high level drug resistance but single mutations normally do not equate with drug resistance to protease inhibitors 26 The mutations can be divided into primary mutations and secondary mutations Primary mutations often have only a small effect on resistance The chemical structures of most protease inhibitors are quite similar so it is not surprising that some primary mutations lead simultaneously to resistance to multiple protease inhibitors Cross resistance is one of the major problems of protease inhibitor treatment 35 Additional mutations emerging in the protease during continuous protease inhibitor therapy are commonly referred to as secondary mutations This can lead to high level protease inhibitor resistance 35 The Stanford HIV RT and Protease Sequence Database also called the HIV Drug Resistance Database was formed in 1998 with HIV reverse transcriptase and protease sequences from persons with well characterized antiretroviral treatment histories and is publicly available to query resistance mutations and genotype treatment genotype phenotype and genotype outcome correlations citation needed Although the substrate envelope provides the general strategy of designing inhibitors that mimic the substrate and stay within the envelope to avoid resistance conferred by most active site mutations 36 37 there is no general strategy to tackle the problem of drug resistance especially due to those away from the active site Researches directed towards development of new therapies to cure AIDS are focused on avoiding cross resistance to drugs that are already on the market 12 Current status EditIn January 2018 darunavir was still the most recent HIV protease inhibitor to reach the market 38 In 2006 GlaxoSmithKline discontinued the phase II clinical development of brecanavir an investigational protease inhibitor for the treatment of HIV due to insurmountable issues regarding formulation 39 In the summer of 2009 GlaxoSmithKline and Concert Pharmaceuticals announced their collaboration to develop and commercialise deuterium containing medicines One of them is CTP 518 a protease inhibitor for the treatment of HIV expected to enter phase I clinical trials in the second half of 2009 CTP 518 is a novel HIV protease inhibitor developed by replacing certain key hydrogen atoms of atazanavir with deuterium Pre clinical studies have demonstrated that this modification fully retains the antiviral potency but can evidently slow hepatic metabolism and thereby increase the half life and plasma trough levels CTP 518 therefore has the potential to be the first HIV protease inhibitor to eliminate the need to co dose with a boosting agent such as ritonavir 40 See also EditAntiretroviral drug Reverse transcriptase inhibitor Integrase inhibitor Entry inhibitor Discovery and development of non nucleoside reverse transcriptase inhibitors Discovery and development of NS5A inhibitorsReferences Edit Cuccioloni M Mozzicafreddo M Bonfili L Cecarini V Eleuteri A M Angeletti M 2009 Natural occurring polyphenols as template for drug design Focus on serine proteases Chemical Biology amp Drug Design 74 1 1 15 doi 10 1111 j 1747 0285 2009 00836 x PMID 19519739 Chen X Kempf D J Li L Sham H L Vasavanonda S Wideburg N E Saldivar A Marsh K C McDonald E Norbeck D W 2003 Synthesis and SAR studies of potent HIV protease inhibitors containing novel dimethylphenoxyl acetates as P2 ligands Bioorganic amp Medicinal Chemistry Letters 13 21 3657 60 doi 10 1016 j bmcl 2003 08 043 PMID 14552751 Adachi M Ohhara T Kurihara K Tamada T Honjo E Okazaki N Arai S Shoyama Y Kimura K Matsumura H Sugiyama S Adachi H Takano K Mori Y Hidaka K Kimura T Hayashi Y Kiso Y Kuroki R 2009 Structure of HIV 1 protease in complex with potent inhibitor KNI 272 determined by high resolution X ray and neutron crystallography Proceedings of the National Academy of Sciences 106 12 4641 6 Bibcode 2009PNAS 106 4641A doi 10 1073 pnas 0809400106 PMC 2660780 PMID 19273847 a b Yanchunas Jr J Langley D R Tao L Rose R E Friborg J Colonno R J Doyle M L 2005 Molecular basis for increased susceptibility of isolates with atazanavir resistance conferring substitution I50L to other protease inhibitors Antimicrobial Agents and Chemotherapy 49 9 3825 32 doi 10 1128 AAC 49 9 3825 3832 2005 PMC 1195399 PMID 16127059 a b Brower E T Bacha U M Kawasaki Y Freire E 2008 Inhibition of HIV 2 protease by HIV 1 protease inhibitors in clinical use Chemical Biology amp Drug Design 71 4 298 305 doi 10 1111 j 1747 0285 2008 00647 x PMID 18312292 S2CID 8461472 a b c d e f g h i j k l m n o p Brunton L L Lazo J S Parker K L 2006 Goodman and Gilmans s The Pharmacological Basis of Therapeutics 11th ed McGraw Hill page needed a b HIV Disease at eMedicine Kurup Alka Mekapati Suresh Garg Rajni Hansch Corwin 2003 HIV 1 Protease Inhibitors A Comparative QSAR Analysis Current Medicinal Chemistry 10 17 1679 88 doi 10 2174 0929867033457070 PMID 12871116 Shi Haibin Liu Kai Leong Wendy W Y Yao Shao Q 2009 Expedient solid phase synthesis of both symmetric and asymmetric diol libraries targeting aspartic proteases Bioorganic amp Medicinal Chemistry Letters 19 14 3945 8 doi 10 1016 j bmcl 2009 03 041 PMID 19328682 Turk Boris 2006 Targeting proteases successes failures and future prospects Nature Reviews Drug Discovery 5 9 785 99 doi 10 1038 nrd2092 PMID 16955069 S2CID 4156908 a b c d e f g Graziani Amy L June 17 2014 HIV protease inhibitors UpToDate a b c d e f Brik A and Wong C H 2003 HIV 1 protease mechanism and drug discovery Organic amp Biomolecular Chemistry 1 1 5 14 Warnke D Barreto J and Temesgen Z 2007 Antiretroviral drugs Journal of Clinical Pharmacology 47 12 1570 1579 Kim R J Wilson C G Wabitsch M Lazar M A and Steppan C M 2006 HIV protease inhibitor specific alterations in human adipocyte differentiation and metabolism Obesity 14 994 1002 a b De Clercq E 2009 The history of antiretrovirals key discoveries over the past 25 years Reviews in Medical Virology 19 287 299 a b c Mimoto T Hattori N Takaku H et al 2000 Structure activity relationship of orally potent tripeptide based HIV protease inhibitors containing hydroxymethylcarbonyl isostere Chemical amp Pharmaceutical Bulletin 48 9 1310 1326 a b c Perez M A S Fernandes P A and Ramos M J 2007 Drug design New inhibitors for HIV 1 protease based on Nelfinavir as lead Journal of Molecular Graphics and Modelling 26 634 642 a b c d e f g h i j k Flexner C 2007 HIV drug development the next 25 years Nature Reviews Drug Discovery 6 959 966 a b c d e f g h i j k Wlodawer A 2002 Rational approach to AIDS drug design through structural biology Annual Review of Medicine 53 595 614 Smith H J and Simons C 2005 Enzymes and Their Inhibition Drug Development 6th edition United States of America CRC press Luber A D et al 2007 Steady state pharmacokinetics of once daily fosamprenavir ritonavir and atazanavir ritonavir alone and in combination with 20mg omeprazole in healthy volunteers HIV medicine 8 457 464 Chapman T M Plosker G L and Perry C M 2004 Fosamprenavir A Review of its Use in the Management of Antiretroviral Therapy naive Patients with HIV Infection Drugs 64 2101 2124 Larder B A et al 2000 Tipranavir inhibits broadly protease inhibitor resistant HIV 1 clinical samples AIDS 14 1943 1948 Schobert R Stehle R and Walter H 2008 Tipranavir analogous 3 sulfonylanilidotetronic acids new synthesis and structure dependent anti HIV activity Tetrahedron 64 9401 9407 Doyon L Et al 2005 Selection and characterization of HIV 1 showing reduced susceptibility to the non peptidic protease inhibitor tipranavir Antiviral Research 68 27 35 a b c d e McCoy C 2007 Darunavir A nonpeptidic antiretroviral protease inhibitor Clinical Therapeutics 29 8 1559 1576 Liu F Kovalevsky A Y Tie Y Ghosh A K Harrison R W and Weber I T 2008 Effect of Flap Mutations on Structure of HIV protease and Inhibition by Saquinavir and Darunavir Journal of Molecular Biology 381 1 102 115 Lebon F and Ledecq M 2000 Approaches to the Design of Effective HIV 1 Protease Inhibitors Current Medicinal Chemistry 7 455 477 Blum A et al 2008 Achiral oligoamines as versatile tool for the development of aspartic protease inhibitors Bioorganic amp Medicinal Chemistry 16 8574 8586 Prabu Jeyabalan Nalivaika E Schiffer CA 2002 Substrate shape determines specificity of recognition for HIV 1 protease analysis of crystal structures of six substrate complexes Structure 10 3 369 81 King NM Prabu Jeyabalan M Nalivaika EA Schiffer CA 2004 Combating susceptibility to drug resistance lessons from HIV 1 protease Chem Biol Oct 11 10 1333 8 Bihani S C Das A Prashar V Ferrer J L and Hosur M V 2009 Resistance mechanism revealed by crystal structures of unliganded nelfinavir resistant HIV 1 protease non active site mutants N88D and N88S Biochemical and Biophysical Research Communications 389 295 300 de Vera IM Smith AN Dancel MC Huang X Dunn BM Fanucci GE 2013 Biochemistry Elucidating a relationship between conformational sampling and drug resistance in HIV 1 protease 14 52 19 3278 88 doi 10 1021 bi400109d Epub 2013 May 1 Lemke T L Williams D A Roche V F and Zito S W 2008 Foye s Principles of Medicinal Chemistry 6th edition United States of America Lippincott williams amp Wilkins a Wolters Kluwer business a b Maarseveen N V and Boucher C 2008 Antiretroviral Resistance in Clinical Practice London Mediscript Ltd Kairys V Gilson MK Lather V Schiffer CA Fernandes MX 2009 Toward the design of mutation resistant enzyme inhibitors further evaluation of the substrate envelope hypothesis Chem Biol Drug Des Sep 74 3 234 45 doi 10 1111 j 1747 0285 2009 00851 x Nalam MN Ali A Altman MD Reddy GS Chellappan S Kairys V Ozen A Cao H Gilson MK Tidor B Rana TM Schiffer CA 2010 Evaluating the substrate envelope hypothesis structural analysis of novel HIV 1 protease inhibitors designed to be robust against drug resistance J Virol 2010 May 84 10 5368 78 doi 10 1128 JVI 02531 09 Epub 2010 Mar 17 De Clercq E 2009 Anti HIV drugs 25 compounds approved within 25 years after the discovery of HIV International Journal of Antimicrobial Agents 33 307 320 GlaxoSmithKline discontinues clinical development of investigational protease inhibitor brecanavir 640385 Archived from the original on 2008 12 03 Retrieved 2008 06 11 GlaxoSmithKline discontinues clinical development of investigational protease inhibitor brecanavir 640385 Retrieved November 4th 2009 GSK and Concert Pharmaceuticals form alliance to develop novel deuterium modified drugs Archived from the original on 2009 08 31 Retrieved 2009 11 05 GSK and Concert Pharmaceuticals form alliance to develop novel deuterium modified drugs Retrieved November 4th 2009 Retrieved from https en wikipedia org w index php title Discovery and development of HIV protease inhibitors amp oldid 1106270703, wikipedia, wiki, book, books, library,

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