Folding Regulates Autoprocessing of HIV-1 Protease Precursor

Chatterjee, Amarnath; Mridula, P.; Mishra, Ram Kumar; Mittal, Rohit; Hosur, Ramakrishna V.

doi:10.1074/jbc.m412603200

Cited by 39 publications

(31 citation statements)

References 55 publications

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“…These experiments have revealed that there can be both native-like and non-native secondary structure present, the exact structure depending upon the protein and experimental conditions. For example, both native and non-native secondary structural preferences were observed in the urea-denatured state of barstar (Bhavesh et al, 2004), in the GdmCldenatured state of HIV-1 protease (Bhavesh et al, 2001;Chatterjee et al, 2005), and in the acid-denatured state of hUBF HMG box 1 (Zhang et al, 2005). In contrast, ␤-type preferences were seen in denatured apomyoglobin which is a highly helical protein (Mohana-Borges et al, 2004).…”

Section: A Superstable Core Of Gfp Characterized At Extreme Conditionsmentioning

confidence: 84%

The extremely slow‐exchanging core and acid‐denatured state of green fluorescent protein

et al. 2008

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Section: A Superstable Core Of Gfp Characterized At Extreme Conditionsmentioning

confidence: 84%

The extremely slow‐exchanging core and acid‐denatured state of green fluorescent protein

et al. 2008

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“…In this regard, sequences adjacent to the PR region have been demonstrated to influence the dimerization efficiency of the Gag-Pol precursors and proper folding of the embedded PR domains, thereby triggering PR autoprocessing (6,10,21,22,23,30,33,42). Accordingly, dimerization defects of PR mutants carrying an inactivated dimer interface were successfully compensated for when the PR was expressed as part of the Gag-Pol precursor (30).…”

Section: Discussionmentioning

confidence: 99%

“…Proper folding of the embedded homodimeric protease (PR) is an essential prerequisite for full activity following sequential autocleavage from the full-length Gag-Pol polyprotein (summarized in reference 13). Indeed, the p6* residues have been demonstrated to stabilize the PR dimer and dictate the folding propensities of PR precursors, thereby influencing the rate of PR maturation (6,10,21). Interestingly, the autoprocessing of a truncated Gag-PR precursor was clearly accelerated when the p6* sequence was deleted, leading to the proposal that the active site of the PR might be less accessible in the presence of p6* (26).…”

mentioning

confidence: 99%

Uncoupling Human Immunodeficiency Virus Type 1 gag and pol Reading Frames: Role of the Transframe Protein p6* in Viral Replication

Leiherer

Ludwig

Wagner

2009

J Virol

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Apart from its regulatory role in protease (PR) activation, little is known about the function of the human immunodeficiency virus type 1 transframe protein p6* in the virus life cycle. p6* is located between the nucleocapsid and PR domains in the Gag-Pol polyprotein precursor and is cleaved by PR during viral maturation. We have recently reported that the central region of p6* can be extensively mutated without abolishing viral infectivity and replication in vitro. However, mutagenesis of the entire p6*-coding sequence in the proviral context is not feasible without affecting the superimposed frameshift signal or the overlapping p1-p6 gag sequences. To overcome these limitations, we created a novel NL4-3-derived provirus by displacing the original frameshift signal to the 3 end of the gag gene, thereby uncoupling the p6* gene sequence from the p1-p6 gag reading frame. The resulting virus (AL) proved to be replication competent in different cell cultures and thus represents an elegant tool for detailed analysis of p6* function. Hence, extensive deletions or substitutions were introduced into the p6* gene sequence of the AL provirus, and effects on particle release, protein processing, and viral infectivity were evaluated. Interestingly, neither the deletion of 63% of all p6* residues nor the partial substitution by a heterologous sequence affected virus growth and infectivity, suggesting that p6* is widely dispensable for viral in vitro replication. However, the insertion of a larger reporter sequence interfered with virus production and maturation, implying that the length or conformation of this spacer region might be critical for p6* function.

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“…Nuclear magnetic resonance analysis of recombinant p6* protein revealed a widely flexible structure (3,22), and its presence directly upstream of the PR is reminiscent of the propeptides flanking eukaryotic aspartic proteases and has been proven to prevent folding of the PR to its dimeric structure (6). Indeed, we could provide evidence that recombinant p6* protein is a strong competitive inhibitor of PR activity in vitro, and we proposed a model in which the carboxyl-terminal tetrapeptide of p6* following release from the Pol precursor, blocks the substrate binding cleft of the PR, thereby delaying overall processing (37).…”

mentioning

confidence: 99%

Importance of Protease Cleavage Sites within and Flanking Human Immunodeficiency Virus Type 1 Transframe Protein p6* for Spatiotemporal Regulation of Protease Activation

Ludwig

Leiherer

Wagner

2008

J Virol

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The human immunodeficiency virus type 1 (HIV-1) protease (PR) has recently been shown to be inhibited by its propeptide p6* in vitro. As p6* itself is a PR substrate, the primary goal of this study was to determine the importance of p6* cleavage for HIV-1 maturation and infectivity. For that purpose, short peptide variants mimicking proposed cleavage sites within and flanking p6* were designed and analyzed for qualitative and quantitative hydrolysis in vitro. Proviral clones comprising the selected cleavage site mutations were established and analyzed for Gag and Pol processing, virus maturation, and infectivity in cultured cells. Amino-terminal cleavage site mutation caused aberrant processing of nucleocapsid proteins and delayed replication kinetics. Blocking the internal cleavage site resulted in the utilization of a flanking site at a significantly decreased hydrolysis rate in vitro, which however did not affect Gag-Pol processing and viral replication. Although mutations blocking cleavage at the p6* carboxyl terminus yielded noninfectious virions exhibiting severe Gag processing defects, mutations retarding hydrolysis of this cleavage site neither seemed to impact viral infectivity and propagation in cultured cells nor seemed to interfere with overall maturation of released viruses. Interestingly, these mutants were shown to be clearly disadvantaged when challenged with wild-type virus in a dual competition assay. In sum, we conclude that p6* cleavage is absolutely essential to allow complete activation of the PR and subsequent processing of the viral precursors.

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Folding Regulates Autoprocessing of HIV-1 Protease Precursor

Cited by 39 publications

References 55 publications

The extremely slow‐exchanging core and acid‐denatured state of green fluorescent protein

The extremely slow‐exchanging core and acid‐denatured state of green fluorescent protein

Uncoupling Human Immunodeficiency Virus Type 1 gag and pol Reading Frames: Role of the Transframe Protein p6* in Viral Replication

Importance of Protease Cleavage Sites within and Flanking Human Immunodeficiency Virus Type 1 Transframe Protein p6* for Spatiotemporal Regulation of Protease Activation

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