The recombination activating genes,RAG 1 and RAG 2, are on chromosome 11p in humans and chromosome 2p in mice

The recombination activating genes RAG-1 and RAG-2 are adjacent genes that act synergistically to activate variable-diversity-joining (V(D)J) recombination. Southern analysis of hybrid cell lines derived from patients with the Wilms tumor-aniridia-genitourinary defects-mental retardation (WAGR) syndrome and from mutagenized cell hybrids selected for deletions in chromosome 11 has allowed us to map the chromosomal location of the human RAG locus. The RAG locus defines a new interval of human chromosome 11p, but is not associated with any genetically mapped human disease. Guided by the chromosomal localization of the human recombination activating genes, we have also mapped the location of the mouse Rag locus.     

Influence of FADS polymorphisms on tracking of serum glycerophospholipid fatty acid concentrations and percentage composition in children

Background

Tracking of fatty acid (FA) contribution to plasma or serum lipids over time was shown in children and adults. However, the potential role of FADS gene variants has not been investigated.

Methods and Principal Findings

Serum GP FA composition of 331 children aged 2 and 6 years, participating in an ongoing birth cohort study, was analyzed. Correlation coefficients were estimated to describe FA tracking over 4 years and to assess the influence of FADS variants on tracking. We found low to moderate tracking (r = 0.12–0.49) of FA compositions and concentration between 2 and 6 years. Concentration changes of total monounsaturated FA and total saturated FA over time correlated closely (r = 0.79) but percentage values were unrelated (r = −0.02). Tracking for n-6 long chain polyunsaturated fatty acid (LC-PUFA) concentrations was lower in subjects homozygous for the major allele of FADS variants and higher in carriers of at least one minor allele, whereas for total n-3 LC-PUFA concentrations and compositions this was vice versa. For individual n-3 PUFA inconsistent results were found.

Conclusions and Significance

Serum GP FA composition shows low to moderate tracking over 4 years with a higher tracking for LC-PUFA metabolites than for their precursor FA. Serum PUFA levels and their tracking seem to be more influenced by lipid and lipoprotein metabolism than by FA specific pathways.     

Electrorotation of lymphocytes—The influence of membrane events and nucleus

Electrorotation—the spin of cells in rotating high frequency electric fields—has been used to investigate properties of human peripheral blood lymphocytes. The rotation spectra of lymphocytes deviate from those of single shell spheres. The deviations are caused by the electrical properties of the nucleus in the cell interior.Electrorotation allows the distinction between successfully stimulated lymphocytes and unstimulated cells after application of concanavalin A. Notwithstanding the fact that only a proportion of the cells will be mitogenically stimulated we detected an enhanced cell membrane conductivity for the whole cell population immediately after the addition of mitogen.     

Concentration-dependent realignment of the antimicrobial peptide PGLa in lipid membranes observed by solid-state 19F-NMR

The membrane-disruptive antimicrobial peptide PGLa is found to change its orientation in a dimyristoyl-phosphatidylcholine bilayer when its concentration is increased to biologically active levels. The alignment of the alpha-helix was determined by highly sensitive solid-state NMR measurements of (19)F dipolar couplings on CF(3)-labeled side chains, and supported by a nonperturbing (15)N label. At a low peptide/lipid ratio of 1:200 the amphiphilic peptide resides on the membrane surface in the so-called S-state, as expected. However, at high peptide concentration (>/=1:50 molar ratio) the helix axis changes its tilt angle from approximately 90 degrees to approximately 120 degrees , with the C-terminus pointing toward the bilayer interior. This tilted "T-state" represents a novel feature of antimicrobial peptides, which is distinct from a membrane-inserted I-state. At intermediate concentration, PGLa is in exchange between the S- and T-state in the timescale of the NMR experiment. In both states the peptide molecules undergo fast rotation around the membrane normal in liquid crystalline bilayers; hence, large peptide aggregates do not form. Very likely the obliquely tilted T-state represents an antiparallel dimer of PGLa that is formed in the membrane at increasing concentration.     

Group B Streptococcus: global incidence and vaccine development

An ongoing public health challenge is to develop vaccines that are effective against infectious diseases that have global relevance. Vaccines against serotypes of group B Streptococcus (GBS) that are prevalent in the United States and Europe are not optimally efficacious against serotypes common to other parts of the world. New technologies and innovative approaches are being used to identify GBS antigens that overcome serotype-specificity and that could form the basis of a globally effective vaccine against this opportunistic pathogen. This Review highlights efforts towards this goal and describes a template that can be followed to develop vaccines against other bacterial pathogens.     

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.     

Multiple epigenetic maintenance factors implicated by the loss of Mll2 in mouse development

Epigenesis is the process whereby the daughters of a dividing cell retain a chromatin state determined before cell division. The best-studied cases involve the inheritance of heterochromatic chromosomal domains, and little is known about specific gene regulation by epigenetic mechanisms. Recent evidence shows that epigenesis pivots on methylation of nucleosomes at histone 3 lysines 4, 9 or 27. Bioinformatics indicates that mammals have several enzymes for each of these methylations, including at least six histone 3 lysine 4 methyltransferases. To look for evidence of gene-specific epigenetic regulation in mammalian development, we examined one of these six, Mll2, using a multipurpose allele in the mouse to ascertain the loss-of-function phenotype. Loss of Mll2 slowed growth, increased apoptosis and retarded development, leading to embryonic failure before E11.5. Using chimera experiments, we demonstrated that Mll2 is cell-autonomously required. Evidence for gene-specific regulation was also observed. Although Mox1 and Hoxb1 expression patterns were correctly established, they were not maintained in the absence of Mll2, whereas Wnt1 and Otx2 were. The Mll2 loss-of-function phenotype is different from that of its sister gene Mll, and they regulate different Hox complex genes during ES cell differentiation. Therefore, these two closely related epigenetic factors play different roles in development and maintain distinct gene expression patterns. This suggests that other epigenetic factors also regulate particular patterns and that development entails networks of epigenetic specificities.     

Proteolytic mechanism of a novel mitochondrial and chloroplastic PreP peptidasome

The 2.1-A-resolution crystal structure of the novel mitochondrial and chloroplastic metalloendopeptidase, AtPreP1, revealed a unique peptidasome structure, in which the two halves of the enzyme completely enfold a huge proteolytic cavity. Based on the structure, we proposed a novel mechanism for proteolysis involving hinge-bending motions, which cause the protease to open and close in response to substrate binding. We generated four double-mutants of AtPreP1 by introducing cysteines at positions where disulfide bonds can be formed in order to lock and unlock the protease and tested the activity under oxidizing and reducing conditions. The overall results support the proposed mechanism.     

Sequence analysis and receptor specificity of the hemagglutinin of a recent influenza H2N2 virus isolated from chicken in North America

Influenza viruses bind host cells following an interaction between the viral hemagglutinin (HA) protein and host cell sialylated glycoproteins and glycolipids. Differences in binding affinities of the HAs for different types of sialic acid linkages (α2-3 vs. α2-6) contribute to determining the host range of an influenza virus. The ability of an avian influenza virus HA to bind the human form of the receptor may be one requirement for an avian virus to propagate in the human population. In this paper, we describe the characterization of the HA from an H2N2 virus isolated from a Pennsylvania chicken farm in 2004. Sequence analysis revealed that this HA is a member of the Eurasian clade, and receptor binding studies show that it maintains its specificity for the avian influenza virus α2-3 linked sialic acid receptor.