Id2 reverses cell cycle arrest induced by {gamma}-irradiation in human HaCaT keratinocytes

Id2 plays a key role in epithelial cells, regulating differentiation, the cell cycle, and proliferation. Because human skin constantly renews itself and is the first target of irradiation, it is of primary interest to evaluate whether such a gene may be regulated in keratinocytes exposed to ionizing radiation. We show here that Id2 is induced in response to gamma-irradiation and have investigated the consequence of this regulation on cell fate. Using RNA interference, we observed that Id2 extinction significantly reduces cell growth in human keratinocytes through the control of the G(1)-S transition of the cell cycle. We have investigated whether the impact of Id2 on the cell cycle may have a physiological role on the cell's ability to cope with radiative stress. Indeed, when Id2 is down-regulated through interfering RNA, cells are more sensitive to irradiation. Conversely, when Id2 is overexpressed, this somehow protects the cell. We propose that Id2 favors reentering the cell cycle after radiation-induced cell cycle arrest to permit the recovery of keratinocytes exposed to ionizing radiation.     

First passage time problem for a drifted Ornstein-Uhlenbeck process

We consider a continuous stochastic process defined as a drifted Ornstein-Uhlenbeck, for which the first passage time is of interest. The process being non-homogeneous, the first passage time probability density function cannot be found analytically, but numerical methods enable to find its estimate. Estimating the first passage time implies solving an unsteady convection-diffusion equation, with variable coefficients, and we use an implicit Euler scheme to solve it. This work is applied to simulated data, and the continuous process is inspired from recent work on biological marker modelling for HIV-positive patients. The first passage time probability density function can be useful to compare the marker progression in different groups. Numerical results show that the first passage time is highly dependent from the process perturbation, and is then more relevant than methods not considering the stochastic process directly to compare the progression.     

Patterns of protein oxidation in Arabidopsis seeds and during germination

Increased cellular levels of reactive oxygen species are known to occur during seed development and germination, but the consequences in terms of protein degradation are poorly characterized. In this work, protein carbonylation, which is an irreversible oxidation process leading to a loss of function of the modified proteins, has been analyzed by a proteomic approach during the first stages of Arabidopsis (Arabidopsis thaliana) seed germination. In the dry mature seeds, the legumin-type globulins (12S cruciferins) were the major targets. However, the acidic alpha-cruciferin subunits were carbonylated to a much higher extent than the basic (beta) ones, consistent with a model in which the beta-subunits are buried within the cruciferin molecules and the alpha-subunits are more exposed to the outside. During imbibition, various carbonylated proteins accumulated. This oxidation damage was not evenly distributed among seed proteins and targeted specific proteins as glycolytic enzymes, mitochondrial ATP synthase, chloroplastic ribulose bisphosphate carboxylase large chain, aldose reductase, methionine synthase, translation factors, and several molecular chaperones. Although accumulation of carbonylated proteins is usually considered in the context of aging in a variety of model systems, this was clearly not the case for the Arabidopsis seeds since they germinated at a high rate and yielded vigorous plantlets. The results indicate that the observed specific changes in protein carbonylation patterns are probably required for counteracting and/or utilizing the production of reactive oxygen species caused by recovery of metabolic activity in the germinating seeds.     

Production and secretion of a heterologous protein by turnip hairy roots with superiority over tobacco hairy roots

A fully contained and efficient heterologous protein production system was designed using Brassica rapa rapa (turnip) hairy roots. Two expression cassettes containing a cauliflower mosaic virus (CaMV) 35S promoter with a duplicated enhancer region, an Arabidopsis thaliana sequence encoding a signal peptide and the CaMV polyadenylation signal were constructed. One cassette was used to express the green fluorescent protein (GFP)-encoding gene in hairy roots grown in flasks. A stable and fast-growing hairy root line secreted GFP at >120 mg/l culture medium. GFP represented 60 % of the total soluble proteins in the culture medium. Turnip hairy roots retained sustainable growth and stable GFP production over 3 years. These results were superior to those obtained using tobacco hairy roots.     

Site-specific attachment of polyethylene glycol-like oligomers to proteins and peptides

Modification of proteins with polymers is a viable method to tune protein properties, e.g., to render them more water-soluble by using hydrophilic polymers. We have utilized precision-length, polyethylene glycol-based oligomers carrying a thioester moiety in transthioesterification and native chemical ligation reactions with internal and N-terminal cysteine residues in proteins and peptides. These reactions lead to uniquely modified proteins with an increased solubility in chaotrope- and detergent-free aqueous systems. Polymer modification of internal cysteines is fully reversible and allows generation of stable protein-polymer conjugates for enzymatic manipulations as demonstrated by proteolytic cleavage of a protein construct that was only soluble in buffers incompatible with protease activity before polymer modification. The permanent polymer modification of a Rab protein at its N-terminal cysteine produced a fully active Rab variant that was efficiently prenylated. Thus, PEGylation of prenylated proteins might be a viable route to increase water solubility of such proteins in order to carry out experiments in detergent- and lipid-free systems.     

Mycobacterium marinum Lipooligosaccharides Are Unique Caryophyllose-containing Cell Wall Glycolipids That Inhibit Tumor Necrosis Factor-�� Secretion in Macrophages

Earlier studies have reported a role for lipooligosaccharides (LOSs) in sliding motility, biofilm formation, and infection of host macrophages in Mycobacterium marinum. Although a LOS biosynthetic gene cluster has recently been identified in this species, many structural features of the different LOSs (LOS-I–IV) are still unknown. This clearly hampers assessing the contribution of each LOS in mycobacterial virulence as well as structure-function-based studies of these important cell wall-associated glycolipids. In this study, we have identified an M. marinum isolate, M. marinum 7 (Mma7), which failed to produce LOS-IV but instead accumulated large amounts of LOS-III. Local genomic comparison of the LOS biosynthetic cluster established the presence of a highly disorganized region in Mma7 compared with the standard M strain, characterized by multiple genetic lesions that are likely to be responsible for the defect in LOS-IV production in Mma7. Our results indicate that the glycosyltransferase LosA alone is not sufficient to ensure LOS-IV biosynthesis. The availability of different M. marinum strains allowed us to determine the precise structure of individual LOSs through the combination of mass spectrometric and NMR techniques. In particular, we established the presence of two related 4-C-branched monosaccharides within LOS-II to IV sequences, of which one was never identified before. In addition, we provided evidence that LOSs are capable of inhibiting the secretion of tumor necrosis factor-α in lipopolysaccharide-stimulated human macrophages. This unexpected finding suggests that these cell wall-associated glycolipids represent key effectors capable of interfering with the establishment of a pro-inflammatory response.A key feature of all members of the genus Mycobacterium is a cell wall of unique and complex structure, which plays an important role in antibiotic resistance and pathogenesis of mycobacteria by modulating the host immune system and phagocytic cell functions (1). The mycobacterial cell wall includes essentially two types of lipids, the mycolic acids, which are very long chain fatty acids covalently bound to the arabinogalactan polysaccharide attached to a peptidoglycan backbone (2), and a vast array of extractable lipids/glycolipids (3). The latter include the ubiquitous trehalose dimycolate (TDM)³ and phosphatidyl mannosides (PIM) (4) as well as a vast array of species-specific lipids such as phenol glycolipids (5), phthiocerol dimycocerosates (5), sulfolipids (4), glycopeptidolipids, and lipooligosaccharides (LOSs).LOSs were found and described in Mycobacterium kansasii (6–8), Mycobacterium gastri (8, 9), Mycobacterium szulgai (10), Mycobacterium malmoense (11), Mycobacterium gordonae (12), Mycobacterium butyricum (13), Mycobacterium mucogenicum (14), the Canetti variant of Mycobacterium tuberculosis (15) and, more recently in Mycobacterium marinum (Mma) (16). However, they remain among the less studied mycobacterial glycolipids at a biosynthetic, structural, and functional point of view. To date, only three genes have been experimentally demonstrated to be involved in the late steps of LOS biosynthesis in M. marinum (16, 17), and one gene encodes a polyketide synthase responsible for the synthesis of the polymethyl-branched fatty acid in the Mycobacterium smegmatis LOS (18).LOSs represent highly antigenic glycoconjugates exposed to the cell surface and useful target molecules for serotyping in a given mycobacterial species. Their precise role in mycobacteria virulence as well as in the colony morphology remains unclear (19, 20). Early studies demonstrated that rough variants of M. kansasii, devoid of all LOSs, induce chronic systemic infections in mice, whereas smooth variants containing LOSs are rapidly cleared from the organs of infected animals (19, 21). It was therefore proposed that LOSs may act as avirulence factors by masking other cell wall-associated virulence factors. Accordingly, LOSs are absent in most clinical isolates of M. tuberculosis as well as in the laboratory strain H37Rv. A recent genetically based comparison of the LOS biosynthetic cluster in M. marinum and M. tuberculosis revealed that only about one-third of the genes are conserved between the two species, with the genetic locus of M. tuberculosis H37Rv containing fewer genes (17). Although recent studies suggested a possible role of LOSs in sliding motility, biofilm formation, and infection of macrophages by M. marinum (17), the precise contribution of LOSs to M. marinum pathogenesis or virulence is seriously hampered by the restricted number of isogenic strains deficient in their production and the lack of precise structural data of LOS variants. LOSs from different mycobacterial species exhibit considerable variations in the glycan core. A previous work identified the presence of four major LOS variants in M. marinum, designated LOS-I to LOS-IV (16). Through partial characterization, the structure of LOS-I was previously established as 3-O-Me-Rhap-(1–3)-Glcp-(1–3)-Glcp-(1–4)-Glcp-(1–1)-Glcp. Although all LOSs were shown to contain this common oligosaccharidic core substituted by an additional Xylp unit, LOS-II, -III, and -IV are further substituted by other unidentified monosaccharides, designated X and YZ, which leave their exact sequence largely unknown (16).In this study, we report the identification of a natural mutant of M. marinum, devoid of LOS-IV production, which allowed the production of large amounts of LOS-III and the determination of the fine structure of all LOSs. In addition, the availability of all LOS variants with defined structures has opened the possibility to undertake structure-function relationship studies. These molecules were therefore used in in vitro assays to uncover their potent biological roles.     

A tool to operationalize dynamic LCA,including time differentiation on the complete background database

The International Journal of Life Cycle Assessment - The objective is to demonstrate an operational tool for dynamic LCA, based on the model by Tiruta-Barna et al. (J Clean Prod 116:198-206,...     

Mycobacterium tuberculosis ClpP Proteases Are Co-transcribed but Exhibit Different Substrate Specificities

Caseinolytic (Clp) proteases are widespread energy-dependent proteases; the functional ATP-dependent protease is comprised of multimers of proteolytic and regulatory subunits. Mycobacterium tuberculosis has two ClpP proteolytic subunits (ClpP1 and ClpP2), with both being essential for growth in vitro. ClpP1 and clpP2 are arranged in an apparent operon; we demonstrated that the two genes are co-expressed under normal growth conditions. We identified a single promoter region for the clpP1P2 operon; no promoter was detected upstream of clpP2 demonstrating that independent expression of clpP1 and clpP2 was highly unlikely. Promoter activity was not induced by heat shock or oxidative stress. We identified a regulatory region upstream of the promoter with a consensus sequence matching the ClgR regulator motif; we determined the limits of the region by mutagenesis and confirmed that positive regulation of the promoter occurs in M. tuberculosis. We developed a reporter system to monitor ClpP1 and ClpP2 enzymatic activities based on LacZ incorporating ssrAtag sequences. We showed that whilst both ClpP1 and ClpP2 degrade SsrA-tagged LacZ, ClpP2 (but not ClpP1) degrades untagged proteins. Our data suggest that the two proteolytic subunits display different substrate specificities and therefore have different, but overlapping roles in M. tuberculosis.