Contribution of astrocyte-derived IL-15 to CD8 T cell effector functions in multiple sclerosis

The contribution of local factors to the activation of immune cells infiltrating the CNS of patients with multiple sclerosis (MS) remains to be defined. The cytokine IL-15 is pivotal in the maintenance and activation of CD8 T lymphocytes, a prominent lymphocyte population found in MS lesions. We investigated whether astrocytes are a functional source of IL-15 sufficient to enhance CD8 T lymphocyte responses and whether they provide IL-15 in the inflamed CNS of patients with MS. We observed that human astrocytes in primary cultures increased surface IL-15 levels upon activation with combinations of proinflammatory cytokines. Expanded human myelin autoreactive CD8 T lymphocytes cultured with such activated astrocytes displayed elevated lytic enzyme content, NKG2D expression, and Ag-specific cytotoxicity. These functional enhancements were abrogated by anti-IL-15-blocking Abs. Immunohistochemical analysis of brain tissue sections obtained from patients with MS demonstrated colocalization for IL-15 and the astrocyte marker glial fibrillary acidic protein within white matter lesions. The majority of astrocytes (80-90%) present in demyelinating MS lesions expressed IL-15, whereas few astrocytes in normal control brain sections had detectable IL-15. IL-15 could be detected in the majority of Iba-1-expressing microglia in the control sections, albeit in lower numbers when compared with microglia/macrophages in MS lesions. Furthermore, infiltrating CD8 T lymphocytes in MS lesions were in close proximity to IL-15-expressing cells. Astrocyte production of IL-15 resulting in the activation of CD8 T lymphocytes ascribes a role for these cells as contributors to the exacerbation of tissue damage during MS pathogenesis.     

The fatty acid desaturase 3 gene encodes for different FADS3 protein isoforms in mammalian tissues

In 2000, Marquardt et al. (A. Marquardt, H. Stöhr, K. White, and B. H. F. Weber. 2000. cDNA cloning, genomic structure, and chromosomal localization of three members of the human fatty acid desaturase family. Genomics. 66: 176–183.) described the genomic structure of the fatty acid desaturase (FADS) cluster in humans. This cluster includes the FADS1 and FADS2 genes encoding, respectively, for the Δ5- and Δ6-desaturases involved in polyunsaturated fatty acid biosynthesis. A third gene, named FADS3, has recently been identified but no functional role has yet been attributed to the putative FADS3 protein. In this study, we investigated the FADS3 occurrence in rat tissues by using two specific polyclonal antibodies directed against the N-terminal and C-terminal ends of rat FADS3. Our results showed three potential protein isoforms of FADS3 (75 kDa, 51 kDa, and 37 kDa) present in a tissue-dependent manner. The occurrence of these FADS3 isoforms did not depend on the mRNA level determined by real-time PCR. In parallel, mouse tissues were also tested and showed the same three FADS3 isoforms but with a different tissue distribution. Finally, we reported the existence of FADS3 in human cells and tissues but different new isoforms were identified. To conclude, we showed in this study that FADS3 does exist under multiple protein isoforms depending on the mammalian tissues. These results will help further investigations to determine the physiological function of FADS3.     

A Western-like fat diet is sufficient to induce a gradual enhancement in fat mass over generations

The prevalence of obesity has steadily increased over the last few decades. During this time, populations of industrialized countries have been exposed to diets rich in fat with a high content of linoleic acid and a low content of α-linolenic acid compared with recommended intake. To assess the contribution of dietary fatty acids, male and female mice fed a high-fat diet (35% energy as fat, linoleic acid:α-linolenic acid ratio of 28) were mated randomly and maintained after breeding on the same diet for successive generations. Offspring showed, over four generations, a gradual enhancement in fat mass due to combined hyperplasia and hypertrophy with no change in food intake. Transgenerational alterations in adipokine levels were accompanied by hyperinsulinemia. Gene expression analyses of the stromal vascular fraction of adipose tissue, over generations, revealed discrete and steady changes in certain important players, such as CSF3 and Nocturnin. Thus, under conditions of genome stability and with no change in the regimen over four generations, we show that a Western-like fat diet induces a gradual fat mass enhancement, in accordance with the increasing prevalence of obesity observed in humans.     

Genome Sequence of Streptococcus gallolyticus: Insights into Its Adaptation to the Bovine Rumen and Its Ability To Cause Endocarditis

Streptococcus gallolyticus (formerly known as Streptococcus bovis biotype I) is an increasing cause of endocarditis among streptococci and frequently associated with colon cancer. S. gallolyticus is part of the rumen flora but also a cause of disease in ruminants as well as in birds. Here we report the complete nucleotide sequence of strain UCN34, responsible for endocarditis in a patient also suffering from colon cancer. Analysis of the 2,239 proteins encoded by its 2,350-kb-long genome revealed unique features among streptococci, probably related to its adaptation to the rumen environment and its capacity to cause endocarditis. S. gallolyticus has the capacity to use a broad range of carbohydrates of plant origin, in particular to degrade polysaccharides derived from the plant cell wall. Its genome encodes a large repertoire of transporters and catalytic activities, like tannase, phenolic compounds decarboxylase, and bile salt hydrolase, that should contribute to the detoxification of the gut environment. Furthermore, S. gallolyticus synthesizes all 20 amino acids and more vitamins than any other sequenced Streptococcus species. Many of the genes encoding these specific functions were likely acquired by lateral gene transfer from other bacterial species present in the rumen. The surface properties of strain UCN34 may also contribute to its virulence. A polysaccharide capsule might be implicated in resistance to innate immunity defenses, and glucan mucopolysaccharides, three types of pili, and collagen binding proteins may play a role in adhesion to tissues in the course of endocarditis.Several studies have reported that the proportion of infective endocarditis due to Streptococcus gallolyticus has increased during the last decades, concomitantly with a decrease of cases due to oral streptococci (35). S. gallolyticus is now becoming the first cause of infectious endocarditis among streptococci in Europe (16). Furthermore, S. gallolyticus endocarditis is associated with rural residency, suggesting transmission from animals (29). However, the reasons for the emergence of this pathogen remain poorly understood. S. gallolyticus belongs to the Streptococcus bovis group known for more than 60 years to cause endocarditis (45). Recently, the former species S. bovis has been divided into four major species (50, 53). S. gallolyticus corresponds to S. bovis biotype I (mannitol fermentation positive), the closely related species S. pasteurianus to biotype II/2 (mannitol negative and β-glucuronidase positive), and the more distantly related species S. infantarius to biotype II/1 (mannitol negative and β-glucuronidase negative). S. macedonicus, the fourth species, commonly found in cheese, is nonpathogenic and also considered a S. gallolyticus subspecies (53, 62). A majority of endocarditis cases was due, among the formerly S. bovis group, to S. gallolyticus strains (4).Multiple studies have shown that endocarditis due to S. gallolyticus as well as positive blood culture for this species is often associated with gastrointestinal malignancy (4, 6). This association has led to a strong indication for gastrointestinal investigation and endoscopic follow-up in the case of S. gallolyticus infections (66). The association of S. gallolyticus infection with colon cancer is a major but still unsolved issue. It may be just incidental, as the alteration of the digestive mucosa may favor the translocation of the bacteria into the bloodstream. Alternatively, the tumor may contribute to the proliferation of S. gallolyticus in close proximity to the gut epithelium, increasing its probability of translocating through the gut barrier. It has also been suggested that the bacterium itself contributes to carcinogenesis (60, 69). In addition to human disease, S. gallolyticus may also cause diseases in animals, like septicemia in pigeons (19), outbreaks in broiler flocks (11), or bovine mastitis (28).Independent from its association to disease, S. gallolyticus has been isolated as a tannin-resistant bacterium from the feces of different mammalian herbivores, including the koala (48) or the Japanese large wood mouse (52), and it is also a normal inhabitant of the rumen (39). Its resistance to tannins is linked to its tannase activity, a characteristic which also led this bacterium to be named “gallolyticus” as it is able to decarboxylate gallate, an organic acid derived from tannin degradation. S. gallolyticus is also known to express other degradative functions unique among streptococci, like a bile salt hydrolase or an amylase. These properties allow its multiplication outside the animal host, as S. gallolyticus was isolated from a digester fed with shea cake (derived from the nuts of the African tree Vitellaria paradoxa) rich in tannins and aromatic compounds (12). S. gallolyticus is a commensal of the human intestinal tract but remains a rarely detected (2.5 to 15%) low-abundance species (10, 40). In herbivores, overgrowth of S. bovis may become deleterious. For example, ingestion of large amounts of rapidly fermented cereal grains leads to a destabilization of the rumen flora and to the proliferation of acid-tolerant bacteria, including S. gallolyticus. This is accompanied by the overproduction of mucopolysaccharides that stabilize the foam, resulting in feedlot bloat, a significant cause of economical loss (14).Virulence and colonization factors of S. gallolyticus in humans are largely unknown. Studies of the bird host have shown that this Streptococcus species expresses a capsular polysaccharide, and five different serotypes have been described (19). In addition, electron microscopy studies have revealed the presence of fimbria-like structures on the surface of S. gallolyticus. It was hypothesized that capsules and/or fimbriae are involved in virulence (63). S. gallolyticus isolates responsible for endocarditis exhibited heterogeneous patterns of adherence to extracellular matrix (ECM) proteins, which suggests that they produce different surface components (55). Recently, a collagen binding adhesin together with 10 putative ECM binding proteins were identified in the draft genome sequence of a human isolate of S. gallolyticus (54).Here we describe the sequence and analysis of the genome of S. gallolyticus strain UCN34 isolated from a human case of endocarditis associated with colon cancer. Analysis of the predicted proteins revealed unique metabolic and cell surface features among streptococci, which contribute to its adaptation to the rumen and to its ability to cause endocarditis. We showed by comparative genomics that many of the corresponding genes were probably acquired by lateral gene transfer (LGT) from other Firmicutes of the gut microbiota.     

Diversity of Monomers in Nonribosomal Peptides: towards the Prediction of Origin and Biological Activity

Nonribosomal peptides (NRPs) are molecules produced by microorganisms that have a broad spectrum of biological activities and pharmaceutical applications (e.g., antibiotic, immunomodulating, and antitumor activities). One particularity of the NRPs is the biodiversity of their monomers, extending far beyond the 20 proteogenic amino acid residues. Norine, a comprehensive database of NRPs, allowed us to review for the first time the main characteristics of the NRPs and especially their monomer biodiversity. Our analysis highlighted a significant similarity relationship between NRPs synthesized by bacteria and those isolated from metazoa, especially from sponges, supporting the hypothesis that some NRPs isolated from sponges are actually synthesized by symbiotic bacteria rather than by the sponges themselves. A comparison of peptide monomeric compositions as a function of biological activity showed that some monomers are specific to a class of activities. An analysis of the monomer compositions of peptide products predicted from genomic information (metagenomics and high-throughput genome sequencing) or of new peptides detected by mass spectrometry analysis applied to a culture supernatant can provide indications of the origin of a peptide and/or its biological activity.Nonribosomal peptides (NRPs) are molecules produced by microorganisms and synthesized by huge multienzymatic complexes (38, 41), called nonribosomal peptide synthetases (NRPSs). These megaenzymes are organized into modules, one for each amino acid to be built into the peptide product. This is accomplished by division of each catalytic step into specialized semiautonomous domains. The basic set of domains (adenylation, thiolation, and condensation) within a module can be extended by substrate-modifying domains, including domains for substrate epimerization, β hydroxylation, N methylation, and heterocyclic ring formation. The peptide release is catalyzed by a thioesterase domain which can also, in many cases, be involved in an intramolecular reaction leading to a cyclic or partially cyclic peptide or, in fewer cases, in the oligomerization of peptide units (iterative biosynthesis). NRPs show a broad spectrum of biological activities and pharmaceutical applications. They can harbor antimicrobial, immunomodulator, or antitumor activities. Cyclosporine (5), an immunosuppressant drug widely used in organ transplantation, daptomycin (60) (marketed in the United States under the trade name Cubicin), used in the treatment of certain infections caused by Gram-positive bacteria, aminoadipyl-cysteinyl-valine (ACV)-tripeptide, which is the precursor of cephalosporin and penicillin (29), the most famous antibiotic, and also bleomycin (57), used in the treatment of several cancers, are some common examples of NRPs of high therapeutic importance. Two main structural traits distinguish these peptides from ribosomally synthesized peptides: first, their primary structure is more frequently cyclic (partially or totally) branched or polycyclic rather than linear and, second, the biodiversity of monomers incorporated in NRPs goes far beyond the 20 proteogenic amino acids residues. NRP monomers include modified versions of the proteogenic amino acids (e.g., methylated, hydroxylated, and d-forms) but also other monomers, such as, for example, 2-aminoisobutyric acid (Aib), hydroxyphenylglycine (Hpg), and 2,3-dihydroxybenzoic acid (diOH-Bz). However, essential characteristics of this diversity and its relationship with biological functions and producing organisms have been poorly understood until now.The development of the Norine database, the first resource entirely dedicated to NRPs (8, 9), filled this gap. Based on Norine data, we performed the first large-scale analysis of about a thousand peptides which represent a total coverage of more than 10,000 monomer occurrences, revealing the presence of as many as 500 different monomer types. A data-mining analysis of the monomeric compositions of NRPs allowed us to reveal a strong relationship between certain monomeric characteristics of NRPs and their biological function and producing organism. In addition to providing a comprehensive overview of monomeric biodiversity in NRPs, this work demonstrated (i) a dissimilarity of structural properties between bacterial and fungal NRPs; (ii) a significant relationship between NRPs synthesized by bacteria and those isolated from metazoa, especially from sponges, supporting the hypothesis that the peptides isolated from sponges are in reality synthesized by symbiotic bacteria rather than by the sponges themselves; and (iii) a certain monomer specificity to a class of biological activities. Those observations are supported by successful statistical predictions of biological activities of NRPs based on their monomeric compositions.     

Metallopolymers from ruthenium and iron pyrrole-containing π-extended complexes as model components for solid state solar cells

New metallopolymers were generated efficiently on Pt and ITO (indium-tin oxide) glass slides by repeated scan oxidation of Ru and Fe complexes containing pyrrolostyryl bipyridine ligands. The UV-Vis spectrum and voltammogram of Ru-based polymer films showed blue-shifts of the MLCT absorption bands and increased oxidation potentials indicating conjugation cut in the π-extended system. In contrast, formation of polypyrrole occurred in Fe-based polymers due to oxidation of pyrrole groups by the initially oxidised metal centres. The coated ITO electrodes displayed promising wide absorption domains for use in light conversion devices.     

Occurrence of molecular abnormalities of cell cycle in L132 cells after in vitro short-term exposure to air pollution PM2.5

To improve the knowledge of the underlying mechanisms implying in air pollution Particulate Matter (PM)-induced lung toxicity in humans, we were interested in the sequential occurrence of molecular abnormalities from TP53-RB gene signaling pathway activation in the L132 target human lung epithelial cell model. The most toxicologically relevant physical and chemical characteristics of air pollution PM_2.5 collected in Dunkerque, a French highly-industrialized sea-side city, were determined. L132 cells were exposed during 24, 48 and 72 h to Dunkerque City's PM_2.5 (i.e. Lethal Concentration (LC)₁₀ = 18.84 μg PM/mL or 5.02 μg PM/cm²; LC₅₀ = 75.36 μg PM/mL or 20.10 μg PM/cm²), TiO₂ and desorbed PM (i.e. dPM; EqLC₁₀ = 15.42 μg/mL or 4.11 μg PM/cm²; EqLC₅₀ = 61.71 μg/mL or 16.46 μg PM/cm²), benzene (7 μM) or Benzo[a]Pyrene (B[a]P; 1 μM). Dunkerque City's PM_2.5 altered the gene expression and/or the protein concentration of several key cell cycle controllers from TP53-RB gene signaling pathway (i.e. P53; BCL2; P21; cyclin D1, cyclin-dependent kinase 1; retinoblastoma protein) in L132 cells, thereby leading to the occurrence of cell proliferation and apoptosis together. The activation of the critical cell cycle controllers under study might be related to PM-induced oxidative stress, through the possible involvement of covalent metals in redox systems, the metabolic activation of organic chemicals by enzyme-catalyzed reactions, and phagocytosis. Taken together, these results might ask the critical question whether there is a balance or, in contrast, rather an imbalance between the cell proliferation and the apoptosis occurring in PM-exposed L132 cells, with possible consequences in term of PM-induced lung tumorgenesis.