Monitoring the process of HypF fibrillization and liposome permeabilization by protofibrils

Much information has appeared in the last few years on the low resolution structure of amyloid fibrils and on their non-fibrillar precursors formed by a number of proteins and peptides associated with amyloid diseases. The fine structure and the dynamics of the process leading misfolded molecules to aggregate into amyloid assemblies are far from being fully understood. Evidence has been provided in the last five years that protein aggregation and aggregate toxicity are rather generic processes, possibly affecting all polypeptide chains under suitable experimental conditions. This evidence extends the number of model proteins one can investigate to assess the molecular bases and general features of protein aggregation and aggregate toxicity. We have used tapping mode atomic force microscopy to investigate the morphological features of the pre-fibrillar aggregates and of the mature fibrils produced by the aggregation of the hydrogenase maturation factor HypF N-terminal domain (HypF-N), a protein not associated to any amyloid disease. We have also studied the aggregate-induced permeabilization of liposomes by fluorescence techniques. Our results show that HypF-N aggregation follows a hierarchical path whereby initial globules assemble into crescents; these generate large rings, which evolve into ribbons, further organizing into differently supercoiled fibrils. The early pre-fibrillar aggregates were shown to be able to permeabilize synthetic phospholipid membranes, thus showing that this disease-unrelated protein displays the same amyloidogenic behaviour found for the aggregates of most pathological proteins and peptides. These data complement previously reported findings, and support the idea that protein aggregation, aggregate structure and toxicity are generic properties of polypeptide chains.     

Family-based versus unrelated case-control designs for genetic associations

The most simple and commonly used approach for genetic associations is the case-control study design of unrelated people. This design is susceptible to population stratification. This problem is obviated in family-based studies, but it is usually difficult to accumulate large enough samples of well-characterized families. We addressed empirically whether the two designs give similar estimates of association in 93 investigations where both unrelated case-control and family-based designs had been employed. Estimated odds ratios differed beyond chance between the two designs in only four instances (4%). The summary relative odds ratio (ROR) (the ratio of odds ratios obtained from unrelated case-control and family-based studies) was close to unity (0.96 [95% confidence interval, 0.91-1.01]). There was no heterogeneity in the ROR across studies (amount of heterogeneity beyond chance I(2) = 0%). Differences on whether results were nominally statistically significant (p < 0.05) or not with the two designs were common (opposite classification rates 14% and 17%); this reflected largely differences in power. Conclusions were largely similar in diverse subgroup analyses. Unrelated case-control and family-based designs give overall similar estimates of association. We cannot rule out rare large biases or common small biases.     

The PAI-1 swing: microenvironment and cancer cell migration

Cancer is a complex and dynamic process caused by a cellular dysfunction leading to a whole organ or even organism vital perturbation. To better understand this process, we need to study each one of the levels involved, which allows the scale change, and to integrate this knowledge. A matricellular protein, PAI-1, is able to induce in vitro cell behaviour modifications, morphological changes, and to promote cell migration. PAI-1 influences the mesenchymo-amaeboid transition. This matricellular protein should be considered as a potential 'launcher' of the metastatic process acting at the molecular, cellular, tissular levels and, as a consequence, at the organism's level.     

Enhanced Anti-tumor Activity by the Combination of the Natural Compounds (?)-Epigallocatechin-3-gallate and Luteolin: POTENTIAL ROLE OF p53*

Natural dietary agents have drawn a great deal of attention toward cancer prevention because of their wide safety margin. However, single agent intervention has failed to bring the expected outcome in clinical trials; therefore, combinations of chemopreventive agents are gaining increasingly popularity. In the present study, we investigated a combinatorial approach using two natural dietary polyphenols, luteolin and EGCG, and found that their combination at low doses (at which single agents induce minimal apoptosis) synergistically increased apoptosis (3–5-fold more than the additive level of apoptosis) in both head and neck and lung cancer cell lines. This combination also significantly inhibited growth of xenografted tumors in nude mice. The in vivo findings also were supported by significant inhibition of Ki-67 expression and increase in TUNEL-positive cells in xenografted tissues. Mechanistic studies revealed that the combination induced mitochondria-dependent apoptosis in some cell lines and mitochondria-independent apoptosis in others. Moreover, we found more efficient stabilization and ATM-dependent Ser¹⁵ phosphorylation of p53 due to DNA damage by the combination, and ablation of p53 using shRNA strongly inhibited apoptosis as evidenced by decreased poly(ADP-ribose) polymerase and caspase-3 cleavage. In addition, we observed mitochondrial translocation of p53 after treatment with luteolin or the combination of EGCG and luteolin. Taken together, our results for the first time suggest that the combination of luteolin and EGCG has synergistic/additive growth inhibitory effects and provides an important rationale for future chemoprevention trials of head and neck and lung cancers.     

SufU Is an Essential Iron-Sulfur Cluster Scaffold Protein in Bacillus subtilis

Bacteria use three distinct systems for iron-sulfur (Fe/S) cluster biogenesis: the ISC, SUF, and NIF machineries. The ISC and SUF systems are widely distributed, and many bacteria possess both of them. In Escherichia coli, ISC is the major and constitutive system, whereas SUF is induced under iron starvation and/or oxidative stress. Genomic analysis of the Fe/S cluster biosynthesis genes in Bacillus subtilis suggests that this bacterium''s genome encodes only a SUF system consisting of a sufCDSUB gene cluster and a distant sufA gene. Mutant analysis of the putative Fe/S scaffold genes sufU and sufA revealed that sufU is essential for growth under minimal standard conditions, but not sufA. The drastic growth retardation of a conditional mutant depleted of SufU was coupled with a severe reduction of aconitase and succinate dehydrogenase activities in total-cell lysates, suggesting a crucial function of SufU in Fe/S protein biogenesis. Recombinant SufU was devoid of Fe/S clusters after aerobic purification. Upon in vitro reconstitution, SufU bound an Fe/S cluster with up to ∼1.5 Fe and S per monomer. The assembled Fe/S cluster could be transferred from SufU to the apo form of isopropylmalate isomerase Leu1, rapidly forming catalytically active [4Fe-4S]-containing holo-enzyme. In contrast to native SufU, its D43A variant carried a Fe/S cluster after aerobic purification, indicating that the cluster is stabilized by this mutation. Further, we show that apo-SufU is an activator of the cysteine desulfurase SufS by enhancing its activity about 40-fold in vitro. SufS-dependent formation of holo-SufU suggests that SufU functions as an Fe/S cluster scaffold protein tightly cooperating with the SufS cysteine desulfurase.Iron-sulfur (Fe/S) clusters are one of the most ubiquitous and versatile cofactors employed by nature for catalyzing a variety of redox reactions or for serving as redox sensors in a broad range of regulatory processes (10). Iron and sulfide are toxic for the cells in concentrations needed for spontaneous chemical Fe/S protein maturation. Hence, cells have developed complex biosynthesis machineries which are essential in vivo to assemble Fe/S proteins. Three phylogenetically distinct biosynthesis systems have been found in bacteria: ISC (iron-sulfur cluster), SUF (sulfur mobilization), and NIF (nitrogen fixation) (9, 11, 24). The ISC machinery is the most widely distributed bacterial Fe/S cluster biogenesis system and is also present in eukaryotes (31). In Escherichia coli a second system for Fe/S cluster assembly, SUF, is induced under conditions of iron limitation and/or oxidative stress, thus replacing the housekeeping ISC system for assembly of Fe/S proteins. In contrast, SUF was found as the exclusive Fe/S biogenesis system in mycobacteria (22) and Enterococcus faecalis (39) and hence may also serve as a constitutive system. Furthermore, SUF is present in plastids of green plants, resembling the situation found in their cyanobacterial ancestors (25, 53). The NIF system is responsible for the dedicated maturation of the complex Fe/S protein nitrogenase involved in nitrogen fixation, e.g., in Azotobacter vinelandii. Some NIF genes are associated with anaerobic or microaerobic growth in Helicobacter pylori and Entamoeba histolytica (24).Common principles for Fe/S protein assembly in each system have been defined (30). The de novo assembly of an Fe/S cluster occurs on scaffold proteins which transiently bind the Fe/S cluster before transfer to target apoproteins. Cysteine desulfurases such as IscS and SufS serve as sulfur donors, which acquire sulfur from free l-cysteine by pyridoxal-5′-phosphate-dependent desulfuration. The sulfur is transiently bound in the form of a persulfide to an active-site cysteine of the desulfurase and is subsequently transferred to the scaffold protein. Several SUF systems contain SufE, which specifically forms a complex with the cysteine desulfurase SufS (36, 42). SufE enhances SufS activity significantly and assists the sulfur transfer to scaffold proteins. In this case the persulfide is transiently bound to SufE and not to the desulfurase. Recent studies show that the E. coli cysteine desulfurase CsdA is able to complement the SUF system and interacts with SufE if SufS is inactivated (50). A general iron donor involved in Fe/S cluster assembly is not known yet; however, frataxin homologs in prokaryotes and eukaryotes are postulated to deliver iron to the scaffold protein IscU in the ISC system (5, 9, 31, 34).Several components have been suggested to act as scaffold proteins. U-type scaffold proteins such as bacterial NifU, IscU, and eukaryotic Isu1 preferentially bind [2Fe-2S] clusters. However, the assembly of [4Fe-4S] clusters was described to proceed by reductive coupling of two [2Fe-2S] clusters that bind successively to an IscU dimer (1). A-type scaffolds like bacterial SufA or IscA can bind [2Fe-2S] clusters in their monomeric state and were found to be involved in the maturation of [4Fe-4S] proteins such as aconitase (17, 32, 47). Overproduced IscA was also shown to bind mononuclear iron which could be used for Fe/S cluster assembly on IscU in vitro.The ISC system characteristically contains the molecular chaperone pair HscA and HscB that are involved in Fe/S cluster transfer from the IscU scaffold protein to the target proteins. The Hsp70-type HscA specifically binds to a highly conserved LPPVK motif located near the third strictly conserved cluster-binding cysteine in IscU. Specific IscU-HscA complex formation was found to be necessary and sufficient to stimulate the ATPase activity of HscA (12, 21, 48). The SUF system, in contrast, does not contain HscA and HscB chaperones in the suf gene cluster. Instead it comprises the SufBCD proteins. The SufC protein has intrinsic ATPase activity and forms a complex with SufB, a putative scaffold protein, and SufD (29). The precise molecular function of the ATP-hydrolyzing SufBCD complex is not yet clear.The best-characterized SUF system from E. coli contains the gene cluster sufABCDSE (5). However, many bacteria, in particular members of the phylum Firmicutes, contain a different suf gene cluster encoding sufCDSUB, which has been studied so far only by bioinformatic approaches (39, 46). While SufS and SufBCD in the two gene clusters appear to be similar proteins, SufE is lacking in most Firmicutes and also in the mycobacterial and Thermotoga maritima SUF machineries (22, 24). The additionally present SufU shares similarities with IscU of the ISC system (39). The protein contains all three conserved cysteine residues involved in Fe/S cluster association and yet characteristically lacks the LPPVK motif, consistent with the absence of HscA and HscB proteins in sufCDSUB species.In this study, we made use of the Gram-positive bacterium Bacillus subtilis to initiate functional analysis of the sufCDSUB genes in Fe/S cluster biosynthesis by genetic and biochemical approaches. In particular, since no functional information is available for SufU, we tested its putative role as an Fe/S scaffold protein. SufU was found to be crucial for cell viability and for Fe/S-dependent enzyme activities in crude cell lysates. In vitro cluster reconstitution with recombinant SufU indicated that SufU binds a labile Fe/S cluster which can be transferred to apo-Leu1 in a fast and efficient way, fully activating its catalytic function as a [4Fe-4S] cluster-dependent isopropylmalate isomerase. The B. subtilis SufU was found to activate the desulfurase activity of purified B. subtilis SufS. Our results suggest that SufS and the SufU scaffold protein closely act together in the Fe/S cluster biogenesis in B. subtilis.     

BRCA1 role in the mitigation of radiotoxicity and chromosomal instability through repair of clustered DNA lesions

Oxidatively-induced clustered DNA lesions are considered the signature of any ionizing radiation like the ones human beings are exposed daily from various environmental sources (medical X-rays, radon, etc.). To evaluate the role of BRCA1 deficiencies in the mitigation of radiation-induced toxicity and chromosomal instability we have used two human breast cancer cell lines, the BRCA1 deficient HCC1937 cells and as a control the BRCA1 wild-type MCF-7 cells. As an additional control for the DNA damage repair measurements, the HCC1937 cells with partially reconstituted BRCA1 expression were used. Since clustered DNA damage is considered the signature of ionizing radiation, we have measured the repair of double strand breaks (DSBs), non-DSB bistranded oxidative clustered DNA lesions (OCDLs) as well as single strand breaks (SSBs) in cells exposed to radiotherapy-relevant γ-ray doses. Parallel measurements were performed in the accumulation of chromatid and isochromatid breaks. For the measurement of OCDL repair, we have used a novel adaptation of the denaturing single cell gel electrophoresis (Comet assay) and pulsed field gel electrophoresis with Escherichia coli repair enzymes as DNA damage probes. Independent monitoring of the γ-H2AX foci was also performed while metaphase chromatid lesions were measured as an indicator of chromosomal instability. HCC1937 cells showed a significant accumulation of all types of DNA damage and chromatid breaks compared to MCF-7 while BRCA1 partial expression contributed significantly in the overall repair of OCDLs. These results further support the biological significance of repair resistant clustered DNA damage leading to chromosomal instability. The current results combined with previous findings on the minimized ability of base clusters to induce cell death (mainly induced by DSBs), enhance the potential association of OCDLs with breast cancer development especially in the case of a BRCA1 deficiency leading to the survival of breast cells carrying a high load of unrepaired DNA damage clusters.     

Calcium-dependent Conformational Changes in Inositol Trisphosphate Receptors

We have used limited trypsin digestion and reactivity with PEG-maleimides (MPEG) to study Ca²⁺-induced conformational changes of IP₃Rs in their native membrane environment. We found that Ca²⁺ decreased the formation of the 95-kDa C-terminal tryptic fragment when detected by an Ab directed at a C-terminal epitope (CT-1) but not with an Ab recognizing a protected intraluminal epitope. This suggests that Ca²⁺ induces a conformational change in the IP₃R that allows trypsin to cleave the C-terminal epitope. Half-maximal effects of Ca²⁺ were observed at ∼0.5 μm and was sensitive to inhibition by IP₃. Ca²⁺ also stimulated the reaction of MPEG-5 with an endogenous thiol in the 95-kDa fragment. This effect was eliminated when six closely spaced cysteine residues proximal to the transmembrane domains were mutated (C2000S, C2008S, C2010S, C2043S, C2047S, and C2053S) or when the N-terminal suppressor domain (amino acids 1–225) was deleted. A cysteine substitution mutant introduced at the C-terminal residue (A2749C) was freely accessible to MPEG-5 or MPEG-20 in the absence of Ca²⁺. However, cysteine substitution mutants in the interior of the tail were poorly reactive with MPEG-5, although reactivity was enhanced by Ca²⁺. We conclude the following: a) that large conformational changes induced by Ca²⁺ can be detected in IP₃Rs in situ; b) these changes may be driven by Ca²⁺ binding to the N-terminal suppressor domain and expose a group of closely spaced endogenous thiols in the channel domain; and c) that the C-terminal cytosol-exposed tail of the IP₃R may be relatively inaccessible to regulatory proteins unless Ca²⁺ is present.