Bacterial community changes during bioremediation of aliphatic hydrocarbon-contaminated soil

The microbial community response during the oxygen biostimulation process of aged oil-polluted soils is poorly documented and there is no reference for the long-term monitoring of the unsaturated zone. To assess the potential effect of air supply on hydrocarbon fate and microbial community structure, two treatments (0 and 0.056 mol h?1 molar flow rate of oxygen) were performed in fixed bed reactors containing oil-polluted soil. Microbial activity was monitored continuously over 2 years throughout the oxygen biostimulation process. Microbial community structure before and after treatment for 12 and 24 months was determined using a dual rRNA/rRNA gene approach, allowing us to characterize bacteria that were presumably metabolically active and therefore responsible for the functionality of the community in this polluted soil. Clone library analysis revealed that the microbial community contained many rare phylotypes. These have never been observed in other studied ecosystems. The bacterial community shifted from Gammaproteobacteria to Actinobacteria during the treatment. Without aeration, the samples were dominated by a phylotype linked to the Streptomyces. Members belonging to eight dominant phylotypes were well adapted to the aeration process. Aeration stimulated an Actinobacteria phylotype that might be involved in restoring the ecosystem studied. Phylogenetic analyses suggested that this phylotype is a novel, deep-branching member of the Actinobacteria related to the well-studied genus Acidimicrobium.     

NAD(P)H Quinone-Oxydoreductase 1 Protects Eukaryotic Translation Initiation Factor 4GI from Degradation by the Proteasome

The eukaryotic translation initiation factor 4GI (eIF4GI) serves as a central adapter in cap-binding complex assembly. Although eIF4GI has been shown to be sensitive to proteasomal degradation, how the eIF4GI steady-state level is controlled remains unknown. Here, we show that eIF4GI exists in a complex with NAD(P)H quinone-oxydoreductase 1 (NQO1) in cell extracts. Treatment of cells with dicumarol (dicoumarol), a pharmacological inhibitor of NQO1 known to preclude NQO1 binding to its protein partners, provokes eIF4GI degradation by the proteasome. Consistently, the eIF4GI steady-state level also diminishes upon the silencing of NQO1 (by transfection with small interfering RNA), while eIF4GI accumulates upon the overexpression of NQO1 (by transfection with cDNA). We further reveal that treatment of cells with dicumarol frees eIF4GI from mRNA translation initiation complexes due to strong activation of its natural competitor, the translational repressor 4E-BP1. As a consequence of cap-binding complex dissociation and eIF4GI degradation, protein synthesis is dramatically inhibited. Finally, we show that the regulation of eIF4GI stability by the proteasome may be prominent under oxidative stress. Our findings assign NQO1 an original role in the regulation of mRNA translation via the control of eIF4GI stability by the proteasome.In eukaryotes, eukaryotic translation initiation factor 4G (eIF4G) plays a central role in the recruitment of ribosomes to the mRNA 5′ end and is therefore critical for the regulation of protein synthesis (14). Two homologues of eIF4G, eIF4GI and eIF4GII, have been cloned (15). Although they differ in various respects, both homologues clearly function in translation initiation. The most thoroughly studied of these is eIF4GI, which serves as a scaffolding protein for the assembly of eIF4F, a protein complex composed of eIF4E (the mRNA cap-binding factor) and eIF4A (an ATP-dependent RNA helicase). Thus, via its association with the mRNA cap-binding protein eIF4E and with another translation initiation factor (eIF3) which is bound to the 40S ribosomal subunit, eIF4GI creates a physical link between the mRNA cap structure and the ribosome, thus facilitating cap-dependent translation initiation (25). eIF4GI functions also in cap-independent, internal ribosome entry site (IRES)-mediated translation initiation. For instance, upon picornavirus infection, eIF4G is rapidly attacked by viral proteases. The resulting eIF4GI cleavage products serve to reprogram the cell''s translational machinery, as the N-terminal cleavage product inhibits cap-dependent translation of host cell mRNAs by sequestering eIF4E while the C-terminal cleavage product stimulates IRES-mediated translation of viral mRNAs (23). Similarly, apoptotic caspases cleave eIF4G into an N-terminal fragment that blocks cap-dependent translation and a C-terminal fragment that is utilized for IRES-mediated translation of mRNAs encoding proapoptotic proteins (22).The regulation of eIF4GI cleavage by viral proteases or apoptotic caspases has been extensively studied. Little is known, however, about the regulation of eIF4GI steady-state levels. Yet the eIF4GI amount that exists at a given moment results from the sum of the effects of de novo synthesis and ongoing degradation. Many cellular proteins are physiologically degraded by the proteasome. This has been shown to be true for eIF4GI, as the factor can be degraded by the proteasome in vitro (5) and in living cells (6). However, how eIF4GI targeting for or protection from destruction by the proteasome is regulated remains unknown.There are two major routes to degradation by the proteasome. In the more conventional route, polyubiquitinated proteins are targeted to the 26S proteasome. Alternatively, a few proteins can be degraded by the 20S proteasome (and sometimes by the 26S proteasome) in a ubiquitin-independent manner (16). Interestingly, it has been shown recently that a few of these proteins (1, 2, 13) can be protected from degradation by the 20S proteasome by binding to the NAD(P)H quinone-oxydoreductase 1 (NQO1). It has been proposed that NQO1 may interact with the 20S proteasome and may consequently block access of target proteins to the 20S degradation core. Because eIF4GI can be degraded in vitro by the 20S proteasome (5) and since it appears that proteasomes can degrade eIF4GI in living cells independently of ubiquitination (6), we asked whether NQO1 could protect eIF4GI from degradation by the proteasome.     

Structural insights into the acidophilic pH adaptation of a novel endo-1,4-β-xylanase from Scytalidium acidophilum

In this study, the crystal structure of a novel endo-1,4-β-xylanase from Scytalidium acidophilum, XYL1, was solved at 1.9 Å resolution. This is one of the few solved crystal structures of acidophilic proteins. The enzyme has the overall fold typical to family 11 xylanases. Comparison of this structure with other homologous acidophilic, neutrophilic and alkalophilic xylanases provides additional insights into the general features involved in low pH adaptation (stability and activity). Several sequence and structure modifications appeared to be responsible for the acidophilic characteristic: (a) the presence of an aspartic acid H bonded to the acid/base catalyst (b) the nature of specifically conserved residues in the active site (c) the negative potential at the surface (d) the decreased number of salt bridges and H bonds in comparison with highly alkaline enzymes.     

Snake venoms as a source of compounds modulating sperm physiology: Secreted phospholipases A2 from Oxyuranus scutellatus scutellatus impact sperm motility,acrosome reaction and in vitro fertilization in mice

The goal of this study was to identify new compounds from venoms able to modulate sperm physiology and more particularly sperm motility. For this purpose, we screened the effects of 16 snake venoms cleared of molecules higher than 15 kDa on sperm motility. Venoms rich in neurotoxins like those from Oxyuranus scutellatus scutellatus or Daboia russelii, were highly potent inhibitors of sperm motility. In contrast, venoms rich in myotoxins like those from Echis carinatus, Bothrops alternatus and Macrovipera lebetina, were inactive. From the main pharmacologically-active fraction of the Taipan snake O. scutellatus s., a proteomic approach allowed us to identify 16 different proteins, among which OS1 and OS2, two secreted phospholipases A2 (sPLA₂). Purified OS1 and OS2 mimicked the inhibitory effect on sperm motility and were likely responsible for the inhibitory effect of the active fraction. OS1 and OS2 triggered sperm acrosome reaction and induced lipid rearrangements of the plasma membrane. The catalytic activity of OS2 was required to modulate sperm physiology since catalytically inactive mutants had no effect. Finally, sperm treated with OS2 were less competent than control sperm to initiate in vitro normal embryo development. This is the first report characterizing sPLA₂ toxins that modulate in vitro sperm physiology.     

Identification of novel chromosomal regions associated with airway hyperresponsiveness in recombinant congenic strains of mice

Airway responsiveness is the ability of the airways to respond to bronchoconstricting stimuli by reducing their diameter. Airway hyperresponsiveness has been associated with asthma susceptibility in both humans and murine models, and it has been shown to be a complex and heritable trait. In particular, the A/J mouse strain is known to have hyperresponsive airways, while the C57BL/6 strain is known to be relatively refractory to bronchoconstricting stimuli. We analyzed recombinant congenic strains (RCS) of mice generated from these hyper- and hyporesponsive parental strains to identify genetic loci underlying the trait of airway responsiveness in response to methacholine as assessed by whole-body plethysmography. Our screen identified 16 chromosomal regions significantly associated with airway hyperresponsiveness (genome-wide P ≤ 0.05): 8 are supported by independent and previously published reports while 8 are entirely novel. Regions that overlap with previous reports include two regions on chromosome 2, three on chromosome 6, one on chromosome 15, and two on chromosome 17. The 8 novel regions are located on chromosome 1 (92–100 cM), chromosome 5 (>73 cM), chromosome 7 (>63 cM), chromosome 8 (52–67 cM), chromosome 10 (3–7 cM and >68 cM), and chromosome 12 (25–38 cM and >52 cM). Our data identify several likely candidate genes from the 16 regions, including Ddr2, Hc, Fbn1, Flt3, Utrn, Enpp2, and Tsc.