The human immunodeficiency virus type-1 (HIV-1) Vif protein neutralizes the cellular defense mechanism against the virus. The C-terminal domain of Vif (CTD, residues 141-192) mediates many of its interactions. Full-length Vif is difficult to purify in large amounts, hence the only available structure of Vif is of residues 140-155 within the ElonginBC complex. Other structural information, derived from modeling and indirect experiments, indicates that the Vif CTD may be unstructured. Here, we chemically synthesized the Vif CTD using pseudo-proline-building blocks, studied its solution structure in the unbound state using biophysical techniques and found that it is unstructured under physiological conditions. The circular dichroism (CD) spectrum of Vif CTD showed a pattern of random coil with residual helical structure. The (15)N-HSQC nuclear magnetic resonance (NMR) spectrum was characteristic of natively unfolded peptides. Vif CTD eluted from an analytical gel filtration column earlier than expected, indicating an extended conformation. Disorder predictions found the CTD to be unstructured, in agreement with our experimental results. CD experiments showed that Vif CTD underwent a conformational change upon interacting with membrane-mimicking DPC micelles, but not upon binding to a peptide derived from its binding region in ElonginC. Our results provide direct evidence for the unfolded structure of the free Vif CTD and indicate that it may gain structure upon binding its natural ligands.
The chaperonins are ubiquitous and essential nanomachines that assist in protein folding in an ATP-driven manner. They consist of two back-to-back stacked oligomeric rings with cavities in which protein (un)folding can take place in a shielding environment. This review focuses on GroEL from Escherichia coli and the eukaryotic chaperonin-containing t-complex polypeptide 1, which differ considerably in their reaction mechanisms despite sharing a similar overall architecture. Although chaperonins feature in many current biochemistry textbooks after being studied intensively for more than three decades, key aspects of their reaction mechanisms remain under debate and are discussed in this review. In particular, it is unclear whether a universal reaction mechanism operates for all substrates and whether it is passive, i.e., aggregation is prevented but the folding pathway is unaltered, or active. It is also unclear how chaperonin clients are distinguished from nonclients and what are the precise roles of the cofactors with which chaperonins interact. Expected final online publication date for the Annual Review of Biophysics, Volume 51 is May 2022. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.
Isoniazid (INH) is a cornerstone of antitubercular therapy. Mycobacterium tuberculosis complex bacteria are the only mycobacteria sensitive to clinically relevant concentrations of INH. All other mycobacteria, including M. marinum and M. avium subsp. paratuberculosis are resistant. INH requires activation by bacterial KatG to inhibit mycobacterial growth. We tested the role of the differences between M. tuberculosis KatG and that of other mycobacteria in INH sensitivity. We cloned the M. bovis katG gene into M. marinum and M. avium subsp. paratuberculosis and measured the MIC of INH. We recombinantly expressed KatG of these mycobacteria and tested in vitro binding to, and activation of, INH. Introduction of katG from M. bovis into M. marinum and M. avium subsp. paratuberculosis rendered them 20 to 30 times more sensitive to INH. Analysis of different katG sequences across the genus found KatG evolution diverged from RNA polymerase-defined mycobacterial evolution. Biophysical and biochemical tests of M. bovis and nontuberculous mycobacteria (NTM) KatG proteins showed lower affinity to INH and substantially lower enzymatic capacity for the conversion of INH into the active form in NTM. The KatG proteins of M. marinum and M. avium subsp. paratuberculosis are substantially less effective in INH activation than that of M. tuberculosis, explaining the relative INH insensitivity of these microbes. These data indicate that the M. tuberculosis complex KatG is divergent from the KatG of NTM, with a reciprocal relationship between resistance to host defenses and INH resistance. Studies of bacteria where KatG is functionally active but does not activate INH may aid in understanding M. tuberculosis INH-resistance mechanisms, and suggest paths to overcome them.
ARTS (Sept4_i2) is a mitochondrial pro-apoptotic protein that functions as a tumor suppressor. Its expression is significantly reduced in leukemia and lymphoma patients. ARTS binds and inhibits XIAP (X-linked Inhibitor of Apoptosis protein) by interacting with its Bir3 domain. ARTS promotes degradation of XIAP through the proteasome pathway. By doing so, ARTS removes XIAP inhibition of caspases and enables apoptosis to proceed. ARTS contains 27 unique residues in its C-terminal domain (CTD, residues 248–274) which are important for XIAP binding. Here we characterized the molecular details of this interaction. Biophysical and computational methods were used to show that the ARTS CTD is intrinsically disordered under physiological conditions. Direct binding of ARTS CTD to Bir3 was demonstrated using NMR and fluorescence spectroscopy. The Bir3 interacting region in ARTS CTD was mapped to ARTS residues 266–274, which are the nine C-terminal residues in the protein. Alanine scan of ARTS 266–274 showed the importance of several residues for Bir3 binding, with His268 and Cys273 contributing the most. Adding a reducing agent prevented binding to Bir3. A dimer of ARTS 266–274 formed by oxidation of the Cys residues into a disulfide bond bound with similar affinity and was probably required for the interaction with Bir3. The detailed analysis of the ARTS – Bir3 interaction provides the basis for setting it as a target for anti cancer drug design: It will enable the development of compounds that mimic ARTS CTD, remove IAPs inhibition of caspases, and thereby induce apoptosis.
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