Containment of Extended Length Polymorphisms in Silk Proteins

The spider silk gene family to the current date has been developed by gene duplication and homogenization events as well as conservation of crucial sequence parts. These evolutionary processes have created an amazing diversity of silk types each associated with specific properties and functions. In addition, they have led to allelic and gene variants within a species as exemplified by the major ampullate spidroin 1 gene of Nephila clavipes. Due to limited numbers of individuals screened to date little is known about the extent of these heterogeneities and how they are finally manifested in the proteins. Using expanded sample sizes, we show that sequence variations expressed as deletions or insertions of tri-nucleotides lead to different sized and structured repetitive units throughout a silk protein. Moreover, major ampullate spidroins 1 can quite dramatically differ in their overall lengths; however, extreme variants do not spread widely in a spider population. This suggests that a certain size range stabilized by purifying selection is important for spidroin 1 gene integrity and protein function. More than one locus for spidroin 1 genes possibly exist within one individual genome, which are homogenized in size, are differentially expressed and give a spider a certain degree of adaptation on silk’s composition and properties. Such mechanisms are shared to a lesser extent by the second major ampullate spidroin gene.     

Shiga toxin B-subunit binds to the chaperone BiP and the nucleolar protein B23

BACKGROUND INFORMATION: In many cell lines, such as HeLa cells, STxB (Shiga toxin B-subunit) is transported from the plasma membrane to the ER (endoplasmic reticulum), via early/recycling endosomes and the Golgi apparatus, bypassing the late endocytic pathway. In human monocyte-derived macrophages and dendritic cells that are not sensitive to Shiga toxin-induced protein biosynthesis inhibition, STxB is not detectably targeted to the retrograde route and is degraded in late endosomes/lysosomes. RESULTS: We have identified B-subunit interacting proteins in HeLa cells and macrophages. In HeLa cells, the ER-localized chaperone BiP (binding protein) was co-immunoprecipitated with the B-subunit. This interaction was not observed in macrophages, consistent with our previous trafficking results. In both cell types, the B-subunit also interacted with the nucleolar protein B23. Consistently, the B-subunit could be detected on nucleoli, suggesting that it could serve to bring the holotoxin to the site of synthesis of its molecular target, rRNA. The nucleolar localization data are critically discussed. CONCLUSION: The interaction of STxB with BiP, involved in the retrotranslocation process to the cytosol and nucleolar B23, as described in this study, might be of relevance for explaining the efficiency of even low doses of Shiga toxin to inactivate cellular ribosomes, and for the use of STxB as a vector for targeting antigens to cytosolic proteasomes of the MHC I-restricted antigen presentation pathway.     

The association of Shiga-like toxin with detergent-resistant membranes is modulated by glucosylceramide and is an essential requirement in the endoplasmic reticulum for a cytotoxic effect

Receptor-mediated internalization to the endoplasmic reticulum (ER) and subsequent retro-translocation to the cytosol are essential sequential processes required for the productive intoxication of susceptible mammalian cells by Shiga-like toxin-1 (SLTx). Recently, it has been proposed that the observed association of certain ER-directed toxins and viruses with detergent-resistant membranes (DRM) may provide a general mechanism for their retrograde transport to endoplasmic reticulum (ER). Here, we show that DRM recruitment of SLTx bound to its globotriosylceramide (Gb(3)) receptor is mediated by the availability of other glycosphingolipids. Reduction in glucosylceramide (GlcCer) levels led to complete protection against SLTx and a reduced cell surface association of bound toxin with DRM. This reduction still allowed efficient binding and transport of the toxin to the ER. However, toxin sequestration within DRM of the ER was abolished under reduced GlcCer conditions, suggesting that an association of toxin with lipid microdomains or rafts in the ER (where these are defined by detergent insolubility) is essential for a later step leading to or involving retro-translocation of SLTx across the ER membrane. In support of this, we show that a number of ER residents, proteins intimately involved in the process of ER dislocation of misfolded proteins, are present in DRM.     

Meta-All: a system for managing metabolic pathway information

Background  

Many attempts are being made to understand biological subjects at a systems level. A major resource for these approaches are biological databases, storing manifold information about DNA, RNA and protein sequences including their functional and structural motifs, molecular markers, mRNA expression levels, metabolite concentrations, protein-protein interactions, phenotypic traits or taxonomic relationships. The use of these databases is often hampered by the fact that they are designed for special application areas and thus lack universality. Databases on metabolic pathways, which provide an increasingly important foundation for many analyses of biochemical processes at a systems level, are no exception from the rule. Data stored in central databases such as KEGG, BRENDA or SABIO-RK is often limited to read-only access. If experimentalists want to store their own data, possibly still under investigation, there are two possibilities. They can either develop their own information system for managing that own data, which is very time-consuming and costly, or they can try to store their data in existing systems, which is often restricted. Hence, an out-of-the-box information system for managing metabolic pathway data is needed.     

Short-term weightlessness produced by parabolic flight maneuvers altered gene expression patterns in human endothelial cells

This study focused on the effects of short-term microgravity (22 s) on the gene expression and morphology of endothelial cells (ECs) and evaluated gravisensitive signaling elements. ECs were investigated during four German Space Agency (Deutsches Zentrum für Luft- und Raumfahrt) parabolic flight campaigns. Hoechst 33342 and acridine orange/ethidium bromide staining showed no signs of cell death in ECs after 31 parabolas (P31). Gene array analysis revealed 320 significantly regulated genes after the first parabola (P1) and P31. COL4A5, COL8A1, ITGA6, ITGA10, and ITGB3 mRNAs were down-regulated after P1. EDN1 and TNFRSF12A mRNAs were up-regulated. ADAM19, CARD8, CD40, GSN, PRKCA (all down-regulated after P1), and PRKAA1 (AMPKα1) mRNAs (up-regulated) provide a very early protective mechanism of cell survival induced by 22 s microgravity. The ABL2 gene was significantly up-regulated after P1 and P31, TUBB was slightly induced, but ACTA2 and VIM mRNAs were not changed. β-Tubulin immunofluorescence revealed a cytoplasmic rearrangement. Vibration had no effect. Hypergravity reduced CARD8, NOS3, VASH1, SERPINH1 (all P1), CAV2, ADAM19, TNFRSF12A, CD40, and ITGA6 (P31) mRNAs. These data suggest that microgravity alters the gene expression patterns and the cytoskeleton of ECs very early. Several gravisensitive signaling elements, such as AMPKα1 and integrins, are involved in the reaction of ECs to altered gravity.     

Dietary hardness, loading behavior, and the evolution of skull form in bats

The morphology and biomechanics of the vertebrate skull reflect the physical properties of diet and behaviors used in food acquisition and processing. We use phyllostomid bats, the most diverse mammalian dietary radiation, to investigate if and how changes in dietary hardness and loading behaviors during feeding shaped the evolution of skull morphology and biomechanics. When selective regimes of food hardness are modeled, we found that species consuming harder foods have evolved skull shapes that allow for more efficient bite force production. These species have shorter skulls and a greater reliance on the temporalis muscle, both of which contribute to a higher mechanical advantage at an intermediate gape angle. The evolution of cranial morphology and biomechanics also appears to be related to loading behaviors. Evolutionary changes in skull shape and the relative role of the temporalis and masseter in generating bite force are correlated with changes in the use of torsional and bending loading behaviors. Functional equivalence appears to have evolved independently among three lineages of species that feed on liquids and are not obviously morphologically similar. These trends in cranial morphology and biomechanics provide insights into behavioral and ecological factors shaping the skull of a trophically diverse clade of mammals.