Physical basis of the inducer-dependent cooperativity of the Central glycolytic genes Repressor/DNA complex

The Central glycolytic genes Repressor (CggR) from Bacillus subtilis belongs to the SorC family of transcription factors that control major carbohydrate metabolic pathways. Recent studies have shown that CggR binds as a tetramer to its tandem operator DNA sequences and that the inducer metabolite, fructose 1,6-bisphosphate (FBP), reduces the binding cooperativity of the CggR/DNA complex. Here, we have determined the effect of FBP on the size, shape and stoichiometry of CggR complexes with full-length and half-site operator sequence by small-angle X-ray scattering, size-exclusion chromatography, fluorescence cross-correlation spectroscopy and noncovalent mass spectrometry (MS). Our results show that CggR forms a compact tetrameric assembly upon binding to either the full-length operator or two half-site DNAs and that FBP triggers a tetramer–dimer transition that leaves a single dimer on the half-site or two physically independent dimers on the full-length target. Although the binding of other phospho-sugars was evidenced by MS, only FBP was found to completely disrupt dimer–dimer contacts. We conclude that inducer-dependent dimer–dimer bridging interactions constitute the physical basis for CggR cooperative binding to DNA and the underlying repression mechanism. This work provides experimental evidences for a cooperativity-based regulation model that should apply to other SorC family members

Physical basis of the inducer-dependent cooperativity of the Central glycolytic genes Repressor/DNA complex.

The Central glycolytic genes Repressor (CggR) from Bacillus subtilis belongs to the SorC family of transcription factors that control major carbohydrate metabolic pathways. Recent studies have shown that CggR binds as a tetramer to its tandem operator DNA sequences and that the inducer metabolite, fructose 1,6-bisphosphate (FBP), reduces the binding cooperativity of the CggR/DNA complex. Here, we have determined the effect of FBP on the size, shape and stoichiometry of CggR complexes with full-length and half-site operator sequence by small-angle X-ray scattering, size-exclusion chromatography, fluorescence cross-correlation spectroscopy and noncovalent mass spectrometry (MS). Our results show that CggR forms a compact tetrameric assembly upon binding to either the full-length operator or two half-site DNAs and that FBP triggers a tetramer-dimer transition that leaves a single dimer on the half-site or two physically independent dimers on the full-length target. Although the binding of other phospho-sugars was evidenced by MS, only FBP was found to completely disrupt dimer-dimer contacts. We conclude that inducer-dependent dimer-dimer bridging interactions constitute the physical basis for CggR cooperative binding to DNA and the underlying repression mechanism. This work provides experimental evidences for a cooperativity-based regulation model that should apply to other SorC family members

Use of virtual screening for discovering antiretroviral compounds interacting with the HIV-1 nucleocapsid protein.

The HIV-1 nucleocapsid protein (NC) is considered as an emerging drug target for the therapy of AIDS. Several studies have highlighted the crucial role of NC within the viral replication cycle. However, although NC inhibition has provided in vitro and in vivo antiretroviral activity, drug-candidates which interfere with NC functions are still missing in the therapeutic arsenal against HIV. Based on previous studies, where the dynamic behavior of NC and its ligand binding properties have been investigated by means of computational methods, here we used a virtual screening protocol for discovering novel antiretroviral compounds which interact with NC. The antiretroviral activity of virtual hits was tested in vitro, whereas biophysical studies elucidated the direct interaction of most active compounds with NC(11-55), a peptide corresponding to the zinc finger domain of NC. Two novel antiretroviral small molecules capable of interacting with NC are presented here

The RYMV-encoded viral suppressor of RNA silencing P1 is a zinc-binding protein with redox-dependent flexibility

Viral suppressors of RNA interference (VSRs) target host gene silencing pathways, thereby operating important roles in the viral cycle and in host cells, in which they counteract host innate immune responses. However, the molecular mechanisms of VSRs are poorly understood. We provide here biochemical and biophysical features of the dual suppressor/activator VSR P1 protein encoded by the rice yellow mottle virus. In silico analyses of P1 suggested common features with zinc finger proteins and native mass spectrometry unambiguously confirmed that recombinant P1 binds reversibly two zinc atoms, each with a different strength. Additionally, we demonstrate that the reaction of P1 with H2O2 leads to zinc release, disulfide bond formation, and protein oligomerization. A reversible protein modification by redox alterations has only been described for a limited number of zinc finger proteins and has never been reported for VSRs. Those reported here for P1 might be a general feature of Cys-rich VSRs and could be a key regulatory mechanism for the control of RNA silencing

Functional and structural characterization of 2-amino-4-phenylthiazole inhibitors of the HIV-1 nucleocapsid protein with antiviral activity.

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Poly(ADP-ribose) polymerase 3 (PARP3), a newcomer in cellular response to DNA damage and mitotic progression

The ADP ribosyl transferase [poly(ADP-ribose) polymerase] ARTD3(PARP3) is a newly characterized member of the ARTD(PARP) family that catalyzes the reaction of ADP ribosylation, a key posttranslational modification of proteins involved in different signaling pathways from DNA damage to energy metabolism and organismal memory. This enzyme shares high structural similarities with the DNA repair enzymes PARP1 and PARP2 and accordingly has been found to catalyse poly(ADP ribose) synthesis. However, relatively little is known about its in vivo cellular properties. By combining biochemical studies with the generation and characterization of loss-of-function human and mouse models, we describe PARP3 as a newcomer in genome integrity and mitotic progression. We report a particular role of PARP3 in cellular response to double-strand breaks, most likely in concert with PARP1. We identify PARP3 as a critical player in the stabilization of the mitotic spindle and in telomere integrity notably by associating and regulating the mitotic components NuMA and tankyrase 1. Both functions open stimulating prospects for specifically targeting PARP3 in cancer therapy

para-sulfonato-calix[n]arenes inhibit staphylococcal bicomponent leukotoxins by supramolecular interactions.

Panton-Valentine leukocidin (PVL) and other S. aureus β-stranded pore-forming toxins are important virulence factors involved in various but often necrotizing pathologies. This study characterized leukotoxin inhibition by selected para-sulfonato-calix[n]arenes (SCn): SC4, SC6 and SC8. These chemicals have no toxic effects on human erythrocytes or neutrophils, and some are able to inhibit both activity and cell lysis by leukotoxins in a dose-dependent manner. Depending on leukotoxins and SCn, flow cytometry revealed IC50 values between 6-22 µM for Ca2+-activation and between 2-50 µM for cell lysis. SCn were observed to affect membrane binding of class S proteins responsible for cell specificity. Electrospray Mass Spectrometry and Surface Plasmon Resonance established supramolecular interactions (1:1 stoichiometry) between SCn and class S proteins in solution, but not class F proteins. The membrane binding affinity of S proteins ranged from KD = 0.07-6.2 nM. The binding ability was completely abolished by SCn at concentrations according to the number of benzenes (30-300 µM; SC8 < SC6 << SC4). The inhibitory properties of SCn were also observed in vivo in a rabbit model of PVL-induced endophthalmitis. These calixarenes may represent new therapeutic avenues aimed at minimizing inflammatory reactions and necrosis due to certain virulence factors