Patterns of Point Mutations Associated With Antiretroviral Drug Treatment Failure in CRF01_AE (Subtype E) Infection Differ From Subtype B Infection

Ariyoshi, K; Matsuda, Masakazu; Miura, Hideka; Tateishi, Sachiko; Yamada, Katsushi; Sugiura, Wataru

doi:10.1097/00126334-200307010-00007

Cited by 93 publications

(79 citation statements)

References 19 publications

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“…Mutations at codon 75 have been also detected in treated patients infected with other clades of HIV-1. Thus, V75M has been found in CRF01_AE-infected patients (30), whereas V75A and V75M have been selected in the absence and in the presence of TAMs, respectively, in stavudine-treated patients infected with HIV-1 group O (31).…”

Section: * This Work Was Supported By Spanish Ministry Of Science Andmentioning

confidence: 99%

Thymidine Analogue Resistance Suppression by V75I of HIV-1 Reverse Transcriptase

Matamoros

Nevot

Martı́nez

et al. 2009

Journal of Biological Chemistry

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Val75 of HIV-1 reverse transcriptase (RT) plays a role in positioning the template nucleotide ؉1 during the formation of the ternary complex. Mutations, such as V75M and V75A, emerge in patients infected with HIV-1 group M subtype B and group O variants, after failing treatment with stavudine (d4T) and other nucleoside RT inhibitors. V75I is an accessory mutation of the Q151M multidrug resistance complex of HIV-1 RT and is rarely associated with thymidine analogue resistance mutations (TAMs). In vitro, it confers resistance to acyclovir. TAMs confer resistance to zidovudine (AZT) and d4T by increasing the rate of ATP-mediated excision of the terminal nucleotide monophosphate (primer unblocking). In a wild-type HIV-1 group O RT sequence context, V75A and V75M conferred increased excision activity on d4T-terminated primers, in the presence of PP i . In contrast, V75I decreased the PP i -mediated unblocking efficiency on AZT and d4T-terminated primers, in different sequence contexts (i.e. wild-type group M subtype B or group O RTs). Interestingly, in the sequence context of an excision-proficient RT (i.e. M41L/A62V/T69SSS/K70R/ T215Y), the introduction of V75I led to a significant decrease of its ATP-dependent excision activity on AZT-, d4T-, and acyclovir-terminated primers. The excision rate of d4T-monophosphate in the presence of ATP (3.2 mM) was about 10 times higher for M41L/A62V/T69SSS/K70R/T215Y than for the mutant M41L/A62V/T69SSS/K70R/V75I/T215Y RT. The antagonistic effect of V75I with TAMs was further demonstrated in phenotypic assays. Recombinant HIV-1 containing the M41L/A62V/ T69SSS/K70R/V75I/T215Y RT showed 18.3-and 1.5-fold increased susceptibility to AZT and d4T, respectively, in comparison with virus containing the M41L/A62V/T69SSS/K70R/ T215Y RT.

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Section: * This Work Was Supported By Spanish Ministry Of Science Andmentioning

confidence: 99%

Thymidine Analogue Resistance Suppression by V75I of HIV-1 Reverse Transcriptase

Matamoros

Nevot

Martı́nez

et al. 2009

Journal of Biological Chemistry

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“…For the most part, resistance mutation patterns are very similar in HIV-1 clade B and non-B clade proteases (19). However, several alternative resistance pathways have been observed for non-B clade proteases compared with those of clade B protease (1,12,13,26). Limited data are available on how sequence polymorphisms, some of which are associated with drug resistance in clade B protease, might influence the pathway to drug resistance in non-B clade proteases.…”

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“…1A). Interestingly, AE protease develops a different resistance pathway from that of clade B protease to confer resistance to the protease inhibitor nelfinavir (NFV) (1). In patients infected with AE, the protease acquires predominantly the N88S mutation in response to NFV therapy, whereas in patients with clade B infection, the protease acquires the D30N/N88D mutations.…”

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confidence: 99%

The Effect of Clade-Specific Sequence Polymorphisms on HIV-1 Protease Activity and Inhibitor Resistance Pathways

Bandaranayake

Kolli

King

et al. 2010

J Virol

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The majority of HIV-1 infections around the world result from non-B clade HIV-1 strains. The CRF01_AE (AE) strain is seen principally in Southeast Asia. AE protease differs by ϳ10% in amino acid sequence from clade B protease and carries several naturally occurring polymorphisms that are associated with drug resistance in clade B. AE protease has been observed to develop resistance through a nonactive-site N88S mutation in response to nelfinavir (NFV) therapy, whereas clade B protease develops both the active-site mutation D30N and the nonactive-site mutation N88D. Structural and biochemical studies were carried out with wild-type and NFV-resistant clade B and AE protease variants. The relationship between clade-specific sequence variations and pathways to inhibitor resistance was also assessed. AE protease has a lower catalytic turnover rate than clade B protease, and it also has weaker affinity for both NFV and darunavir (DRV). This weaker affinity may lead to the nonactive-site N88S variant in AE, which exhibits significantly decreased affinity for both NFV and DRV. The D30N/N88D mutations in clade B resulted in a significant loss of affinity for NFV and, to a lesser extent, for DRV. A comparison of crystal structures of AE protease shows significant structural rearrangement in the flap hinge region compared with those of clade B protease and suggests insights into the alternative pathways to NFV resistance. In combination, our studies show that sequence polymorphisms within clades can alter protease activity and inhibitor binding and are capable of altering the pathway to inhibitor resistance.

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“…HIV-1 protease is one of the major proteins targeted for anti-HIV drug development. The pol gene, which codes for protease, differs by 10 to 15% between clades (7), and sequence diversity within HIV-1 clades has been an important area of study in recent years due to its possible role in altering resistance pathways within the protease (1,10). In particular, the HIV-1 CRF01_AE protease acquires nelfinavir resistance via an alternative mutational pathway (1), making the detailed study of non-B proteases strongly warranted.…”

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confidence: 99%

Structural Analysis of Human Immunodeficiency Virus Type 1 CRF01_AE Protease in Complex with the Substrate p1-p6

Bandaranayake

Prabu-Jeyabalan

Kakizawa

et al. 2008

J Virol

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The effect of amino acid variability between human immunodeficiency virus type 1 (HIV-1) clades on structure and the emergence of resistance mutations in HIV-1 protease has become an area of significant interest in recent years. We determined the first crystal structure of the HIV-1 CRF01_AE protease in complex with the p1-p6 substrate to a resolution of 2.8 Å. Hydrogen bonding between the flap hinge and the protease core regions shows significant structural rearrangements in CRF01_AE protease compared to the clade B protease structure.Based on its genomic diversity, the human immunodeficiency virus type 1 (HIV-1) has been classified into three groups, M (major), N (nonmajor), and O (other/outlier) (16). Group M has been further defined into nine clades (clades A to D, F to H, and J and K) and a number of subclades and circulating recombinant forms (CRFs). HIV-1 protease is one of the major proteins targeted for anti-HIV drug development. The pol gene, which codes for protease, differs by 10 to 15% between clades (7), and sequence diversity within HIV-1 clades has been an important area of study in recent years due to its possible role in altering resistance pathways within the protease (1, 10). In particular, the HIV-1 CRF01_AE protease acquires nelfinavir resistance via an alternative mutational pathway (1), making the detailed study of non-B proteases strongly warranted.Structural studies of clade B protease have led to the successful development of a number of protease inhibitors (PIs). However, the majority of HIV-1 infection cases in the world result from non-clade B variants, and there is limited evidence that non-clade B variants respond differently to currently available PIs (3, 23). Although a large number of clade B protease structures have been solved over the years, to date, very little structural information is available for non-B HIV proteases. The first non-clade B protease structures for clade F were published recently by Sanches et al. (18), and the crystallization of clade C PI complexes has been reported by Coman et al. (4). We present here the crystal structure of an inactive HIV-1 CRF01_AE protease variant (D25N) in complex with a decameric peptide corresponding to the p1-p6 cleavage site within the Gag and Gag-Pro-Pol polyproteins. CRF01_AE was one of the first CRFs to be identified and is now the predominant HIV-1 variant in Southeast Asia (12). The protease was derived from a Japanese patient isolate and has 10 amino acid substitutions (R14K, K20R, E35D, M36I, R41K, P63L, V64I, H69K, L89M, and I93L) compared to that of clade B (Fig. 1A and B).Crystallization and structure determination. The CRF01_AE protease was expressed and purified as previously described (14). The protein was concentrated to 1.8 mg ml Ϫ1 using a 10-kDa molecular size limit Amicon Ultra-15 centrifugal filter device. The decameric p1-p6 peptide (Arg-Pro-Gly-Asn-PheLeu-Gln-Ser-Arg-Pro; Quality Controlled Biochemicals, Inc., Hopkinton, MA) was solubilized in dimethyl sulfoxide and equilibrated with the protein with a fiv...

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Patterns of Point Mutations Associated With Antiretroviral Drug Treatment Failure in CRF01_AE (Subtype E) Infection Differ From Subtype B Infection

Cited by 93 publications

References 19 publications

Thymidine Analogue Resistance Suppression by V75I of HIV-1 Reverse Transcriptase

Thymidine Analogue Resistance Suppression by V75I of HIV-1 Reverse Transcriptase

The Effect of Clade-Specific Sequence Polymorphisms on HIV-1 Protease Activity and Inhibitor Resistance Pathways

Structural Analysis of Human Immunodeficiency Virus Type 1 CRF01_AE Protease in Complex with the Substrate p1-p6

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