Spectral trees as a robust annotation tool in LC–MS based metabolomics

The identification of large series of metabolites detectable by mass spectrometry (MS) in crude extracts is a challenging task. In order to test and apply the so-called multistage mass spectrometry (MS ⁿ ) spectral tree approach as tool in metabolite identification in complex sample extracts, we firstly performed liquid chromatography (LC) with online electrospray ionization (ESI)?CMS ⁿ , using crude extracts from both tomato fruit and Arabidopsis leaf. Secondly, the extracts were automatically fractionated by a NanoMate LC-fraction collector/injection robot (Advion) and selected LC-fractions were subsequently analyzed using nanospray-direct infusion to generate offline in-depth MS ⁿ spectral trees at high mass resolution. Characterization and subsequent annotation of metabolites was achieved by detailed analysis of the MS ⁿ spectral trees, thereby focusing on two major plant secondary metabolite classes: phenolics and glucosinolates. Following this approach, we were able to discriminate all selected flavonoid glycosides, based on their unique MS ⁿ fragmentation patterns in either negative or positive ionization mode. As a proof of principle, we report here 127 annotated metabolites in the tomato and Arabidopsis extracts, including 21 novel metabolites. Our results indicate that online LC?CMS ⁿ fragmentation in combination with databases of in-depth spectral trees generated offline can provide a fast and reliable characterization and annotation of metabolites present in complex crude extracts such as those from plants.     

RLIP mediates downstream signalling from RalB to the actin cytoskeleton during Xenopus early development

The Ras protein activates at least three different pathways during early development. Two of them regulate mesodermal gene expression and the third is thought to participate in the control of actin cytoskeleton dynamics via the Ral protein. From a yeast two-hybrid screen of a Xenopus maternal cDNA library, we identified the Xenopus orthologue of the Ral interacting protein (RLIP, RIP1 or RalBP1), a putative effector of small G protein Ral. Previously, we observed that a constitutively activated form of Ral GTPase (XralB G23V) induced bleaching of the animal hemisphere and disruption of the cortical actin cytoskeleton. To demonstrate that RLIP is the effector of RalB in early development, we show that the artificial targeting of RLIP to the membrane induces a similar phenotype to that of activated RalB. We show that overexpression of the Ral binding domain (RalBD) of XRLIP, which binds to the effector site of Ral, acts in competition with the endogenous effector of Ral and protects against the destructive effect of XralB G23V on the actin cytoskeleton. In contrast, the XRLIP has a synergistic effect on the activated form of XralB, which is dependent on the RalBD of RLIP. We provide evidence for the involvement of RLIP by way of its RalBD on the dynamics of the actin cytoskeleton and propose that signalling from Ral to RLIP is required for gastrulation.     

Pendrin: the thyrocyte apical membrane iodide transporter?

In the thyroid, the transport of iodide from the extracellular space to the follicular lumen requires two steps: the transport in the cell at the basal side and in the lumen at the apical side. The first step is mediated by the Na(+)/I(-) symporter (NIS). In most reviews and textbooks, the second step is presented as mediated by pendrin. In this review, we analyze this assumption. There are several arguments supporting the concept that indeed pendrin plays an important role in thyroid physiology. However, biochemical, clinical and histological data on the thyroid of a patient with Pendred syndrome do not suggest an essential role in iodide transport, which is corroborated by the lack of a thyroid phenotype in pendrin knockout mice. Experiments in vivo and in vitro on polarized and unpolarized cells show that iodide is transported transport of iodide at the apex of the thyroid cell. Moreover, ectopic expression of pendrin in transfected non-thyroid cells is capable of mediating iodide efflux. It is concluded that pendrin may participate in the iodide efflux into thyroid lumen but not as the unique transporter. Moreover, another role of pendrin in mediating Cl(-)/HCO(3)(-) exchange and controlling luminal pH is suggested.     

Prions in Milk from Ewes Incubating Natural Scrapie

Since prion infectivity had never been reported in milk, dairy products originating from transmissible spongiform encephalopathy (TSE)-affected ruminant flocks currently enter unrestricted into the animal and human food chain. However, a recently published study brought the first evidence of the presence of prions in mammary secretions from scrapie-affected ewes. Here we report the detection of consistent levels of infectivity in colostrum and milk from sheep incubating natural scrapie, several months prior to clinical onset. Additionally, abnormal PrP was detected, by immunohistochemistry and PET blot, in lacteal ducts and mammary acini. This PrP^Sc accumulation was detected only in ewes harbouring mammary ectopic lymphoid follicles that developed consequent to Maedi lentivirus infection. However, bioassay revealed that prion infectivity was present in milk and colostrum, not only from ewes with such lympho-proliferative chronic mastitis, but also from those displaying lesion-free mammary glands. In milk and colostrum, infectivity could be recovered in the cellular, cream, and casein-whey fractions. In our samples, using a Tg 338 mouse model, the highest per ml infectious titre measured was found to be equivalent to that contained in 6 µg of a posterior brain stem from a terminally scrapie-affected ewe. These findings indicate that both colostrum and milk from small ruminants incubating TSE could contribute to the animal TSE transmission process, either directly or through the presence of milk-derived material in animal feedstuffs. It also raises some concern with regard to the risk to humans of TSE exposure associated with milk products from ovine and other TSE-susceptible dairy species.     

The Calcium-Dependent Interaction between S100B and the Mitochondrial AAA ATPase ATAD3A and the Role of This Complex in the Cytoplasmic Processing of ATAD3A

S100 proteins comprise a multigene family of EF-hand calcium binding proteins that engage in multiple functions in response to cellular stress. In one case, the S100B protein has been implicated in oligodendrocyte progenitor cell (OPC) regeneration in response to demyelinating insult. In this example, we report that the mitochondrial ATAD3A protein is a major, high-affinity, and calcium-dependent S100B target protein in OPC. In OPC, ATAD3A is required for cell growth and differentiation. Molecular characterization of the S100B binding domain on ATAD3A by nuclear magnetic resonance (NMR) spectroscopy techniques defined a consensus calcium-dependent S100B binding motif. This S100B binding motif is conserved in several other S100B target proteins, including the p53 protein. Cellular studies using a truncated ATAD3A mutant that is deficient for mitochondrial import revealed that S100B prevents cytoplasmic ATAD3A mutant aggregation and restored its mitochondrial localization. With these results in mind, we propose that S100B could assist the newly synthesized ATAD3A protein, which harbors the consensus S100B binding domain for proper folding and subcellular localization. Such a function for S100B might also help to explain the rescue of nuclear translocation and activation of the temperature-sensitive p53val135 mutant by S100B at nonpermissive temperatures.The S100 proteins comprise a multigene family of low-molecular-weight EF-hand calcium binding and zinc binding proteins (5, 13, 16, 24, 33). To date, 19 different S100 proteins have been assigned to this protein family, and they show different degrees of similarity, ranging from 25 to 56% identity at the amino acid level. With S100B, S100P, and S100Z being the exceptions, the majority of the S100 genes are clustered on human chromosome 1q21 (33). Most S100 proteins serve as calcium sensor proteins that, upon activation, regulate the function and/or subcellular distribution of specific target proteins (13, 33, 47), and they are characterized by common structural motifs, including two low-affinity (K_D [equilibrium dissociation constant] of ∼10 μM to 100 μM) helix-loop-helix calcium binding domains (EF hands) that are separated by a hinge region and flanked by amino- and carboxy-terminal domains. The carboxy-terminal domain is variable among S100 proteins, and it typically is the site that is responsible for the selective interaction of each individual S100 protein with specific target proteins (30). S100 proteins are often upregulated in cancers, in inflammation, and in response to cellular stress (14, 16), suggesting that they function in cell responses to stress situations. Consistent with this hypothesis, stress situations were necessary to reveal phenotypes associated with the S100 knockout in mice (11, 14, 33, 56). Moreover, recent observations revealed a new function for the S100 protein family that included their ability to assist and regulate multichaperone complex-ligand interactions (41, 50, 51).One member of the S100 protein family, S100B, has attracted much interest in the past few years because, like other proteins implicated in neurodegeneration (e.g., amyloid, superoxide dismutase, and dual-specificity tyrosine phosphorylation-regulated kinase 1A), its gene is located within a segment of chromosome 21, which is trisomic in Down''s syndrome (DS). Its expression in the brain of mammals coincides with defined periods of central nervous system (CNS) maturation and cell differentiation (43). In oligodendrocyte progenitor cells (OPC), S100B expression is associated with differentiation, and S100B contributes to OPC differentiation in response to demyelinating insult (11). To understand the contribution of S100B to OPC differentiation, we searched for high-affinity S100B target proteins in this cell type by using far-Western analysis. A major and highly specific S100B target protein was identified, the mitochondrial ATAD3A protein.ATAD3A belongs to a new family of eukaryote-specific mitochondrial AAA⁺ ATPase proteins (17). In the human genome, two genes, Atad3A and Atad3B, are located in tandem on chromosome 1p36.33. The Atad3A gene is ubiquitous among multicellular organisms but absent in yeast. The Atad3B gene is specific to the human genome (27). ATAD3A is a mitochondrial protein anchored into the mitochondrial inner membrane (IM) at contact sites with the outer membrane (OM). Thanks to its simultaneous interaction with the two membranes, ATAD3A regulates mitochondrial dynamics at the interface between the inner and outer membranes and controls diverse cell responses ranging from mitochondrial metabolism, cell growth, and mitochondrial fission 20a, 25). The ATAD3A protein has also been identified as a mitochondrial DNA binding protein (23) and as a cell surface antigen in some human tumors (20, 21). The plasma membrane localization of ATAD3A in tumor cells is suggestive that ATAD3A mitochondrial routing can be compromised in pathological situations such as cancer. To understand the functional response resulting from the interaction between S100B and ATAD3A, we first characterized the minimal interaction domain on ATAD3A for S100B binding using thermodynamic studies of wild-type and ATAD3A variants as well as via nuclear magnetic resonance (NMR) spectroscopy techniques. These studies allowed us to further refine the consensus S100B binding motif, which is conserved in several other S100B target proteins, including the p53 protein and several newly discovered target proteins associated with the cell translational machinery. We next analyzed the cellular interaction of S100B with truncated ATAD3A mutants that harbor the S100B binding domain but that are deficient for mitochondrial import. These studies revealed that S100B could assist ATAD3A mutant proteins during cytoplasmic processing by preventing dysfunctional aggregation events. Our results are discussed in light of the possible function of S100B in assisting the cytoplasmic processing of proteins for proper folding and subcellular localization.     

Diversity of commensal Bacillus cereus sensu lato isolated from the common sow bug (Porcellio scaber, Isopoda)

Although Bacillus cereus sensu lato are important both from an ecological and an economical point of view, little is known about their population structure, ecology, and relationships with other organisms. In the present work, the genotypic similarity of arthropod-borne B. cereus s.l. isolates, and their symbiotic relationship with the host are assessed. Bacilli of this group were recovered from the digestive tracts of sow bugs (Porcellio scaber) collected in three closely located sites. Their genotypic diversity was investigated using pulse-field gel electrophoresis (PFGE) following the whole-genome DNA digestions with NotI and AscI, and PCR amplification of virulence genes. The majority of the sow-bug Bacillus cereus sensu stricto isolates originating from the same but also from different sites displayed identical PFGE patterns, virulence gene content and enterotoxicity, indicating strong genetic and genomic relationships. The sow-bug Bacillus mycoides/Bacillus pseudomycoides strains displayed a higher diversity. The isopod-B. cereus s.l. relationship was also evaluated using antibiotic-resistant derivatives of B. cereus s.s., B. mycoides/B. pseudomycoides and Bacillus thuringiensis reintroduced into sow bugs. Both spores and vegetative cells of B. cereus s.l. were recovered from sow bugs over a 30-day period, strongly suggesting that these bacteria are natural residents of terrestrial isopods.