Extraction and reconstitution of calponin and consequent contractile ability in permeabilized smooth muscle fibers

We demonstrate reduction and restoration of contractile ability in response to protein extraction and reconstitution in Triton X-100/glycerol-permeabilized smooth muscle fibers. Through significant reduction in the content of caldesmon (CaD), calponin (CaP), and the 20-kDa regulatory light chain (RLC) of myosin, but not other contractile proteins in "chemically skinned" fibers, we substantially reduced the contractile ability of these fibers, as measured by their ability to generate isometric force and to hydrolyze ATP by actomyosin Mg2+ ATPase. When the protein-depleted fibers were then reconstituted (either with a mixture of purified protein standards of CaD, CaP, and myosin RLC or with a protein extract from the demembranized muscle fibers containing CaD, CaP, and myosin RLC plus several low-molecular-mass proteins), all proteins used for reincorporation returned nearly to control levels, as did isometric force generation and rate of ATP hydrolysis. The fact that the low-molecular-mass proteins do not affect contractility in this model system indicates that our methods for reversible modulation of the content of CaP and CaD may provide a valuable tool for studying the thin-filament-based regulation of contractility.     

The non-coding RNAs as riboregulators

The non-coding RNAs database (http://biobases.ibch.poznan.pl/ncRNA/) contains currently available data on RNAs, which do not have long open reading frames and act as riboregulators. Non-coding RNAs are involved in the specific recognition of cellular nucleic acid targets through complementary base pairing to control cell growth and differentiation. Some of them are connected with several well known developmental and neuro-behavioral disorders. We have divided them into four groups. This paper is a short introduction to the database and presents its latest, updated edition.     

Spatial and temporal localization of SPIRRIG and WAVE/SCAR reveal roles for these proteins in actin-mediated root hair development

Root hairs are single-cell protrusions that enable roots to optimize nutrient and water acquisition. These structures attain their tubular shapes by confining growth to the cell apex, a process called tip growth. The actin cytoskeleton and endomembrane systems are essential for tip growth; however, little is known about how these cellular components coordinate their activities during this process. Here, we show that SPIRRIG (SPI), a beige and Chediak Higashi domain-containing protein involved in membrane trafficking, and BRK1 and SCAR2, subunits of the WAVE/SCAR (W/SC) actin nucleating promoting complex, display polarized localizations in Arabidopsis thaliana root hairs during distinct developmental stages. SPI accumulates at the root hair apex via post-Golgi compartments and positively regulates tip growth by maintaining tip-focused vesicle secretion and filamentous-actin integrity. BRK1 and SCAR2 on the other hand, mark the root hair initiation domain to specify the position of root hair emergence. Consistent with the localization data, tip growth was reduced in spi and the position of root hair emergence was disrupted in brk1 and scar1234. BRK1 depletion coincided with SPI accumulation as root hairs transitioned from initiation to tip growth. Taken together, our work uncovers a role for SPI in facilitating actin-dependent root hair development in Arabidopsis through pathways that might intersect with W/SC.     

The aminoacyl-tRNA Synthetase Data Bank (AARSDB).

Aminoacyl-tRNA synthetases (AARSs) are the key components of the protein biosynthesis machinery. They are responsible for maintaining the fidelity of transfer of genetic information from DNA into protein. The database is a compilation of amino acid sequences of all aminoacyl-tRNA synthetases known to date. It contains 422 primary structures of the AARSs available as separate entries or alignments of related proteins. The database is available via the World Wide Web at http://rose.man.poznan.pl/aars/index.html     

Diversity in the Protein N-Glycosylation Pathways Within the Campylobacter Genus

The foodborne bacterial pathogen, Campylobacter jejuni, possesses an N-linked protein glycosylation (pgl) pathway involved in adding conserved heptasaccharides to asparagine-containing motifs of >60 proteins, and releasing the same glycan into its periplasm as free oligosaccharides. In this study, comparative genomics of all 30 fully sequenced Campylobacter taxa revealed conserved pgl gene clusters in all but one species. Structural, phylogenetic and immunological studies showed that the N-glycosylation systems can be divided into two major groups. Group I includes all thermotolerant taxa, capable of growth at the higher body temperatures of birds, and produce the C. jejuni-like glycans. Within group I, the niche-adapted C. lari subgroup contain the smallest genomes among the epsilonproteobacteria, and are unable to glucosylate their pgl pathway glycans potentially reminiscent of the glucosyltransferase regression observed in the O-glycosylation system of Neisseria species. The nonthermotolerant Campylobacters, which inhabit a variety of hosts and niches, comprise group II and produce an unexpected diversity of N-glycan structures varying in length and composition. This includes the human gut commensal, C. hominis, which produces at least four different N-glycan structures, akin to the surface carbohydrate diversity observed in the well-studied commensal, Bacteroides. Both group I and II glycans are immunogenic and cell surface exposed, making these structures attractive targets for vaccine design and diagnostics.In eukaryotes, glycosylated proteins are ubiquitous components of extracellular matrices and cellular surfaces. Their oligosaccharide moieties are implicated in a wide variety of essential cell-cell and cell-matrix processes ranging from immune recognition to cancer development. The first general protein glycosylation (pgl)¹ pathway was discovered in the epsilonproteobacterium Campylobacter jejuni (1). The organism transfers a conserved heptasaccharide en bloc to asparagine residues within the sequon D/E- X₁-N-X₂-S/T (X₁, X₂ ≠ P) of >60 glycoproteins (2–4). Furthermore, the pathway can be functionally transferred into Escherichia coli, and the oligosaccharyltransferase (OTase), PglB, is capable of adding foreign sugars to acceptor proteins (5–7). C. jejuni PglB also possesses hydrolase activity, influenced by the cellular growth phase and osmotic environment, releasing free oligosaccharides (fOS) into the periplasmic space in a 10:1 ratio relative to the amount of heptasaccharide N-linked to protein (8, 9).The C. jejuni N-linked heptasaccharide is conserved in structure in both C. jejuni and C. coli, the two most commonly isolated pathogenic Campylobacter species and major causes of human enteritis worldwide (10, 11). All campylobacters, but one, possess conserved pgl genes required for N-linked protein glycosylation ((12) and this study). This post-translational modification in C. jejuni influences DNA uptake, chicken and mouse colonization, epithelial cell adherence and invasion, recognition by human sera, and binding to the macrophage galactose lectin (MGL) receptor on dendritic cells (2, 13–17). Several Campylobacter species have now been recognized as emerging pathogens and causative agents of human gastroenteritis (e.g. C. upsaliensis and C. hyointestinalis), gingivitis, periodontitis, and human abortions (e.g. C. rectus, C. concisus, C. gracilis, C. showae, and C. upsaliensis) and inflammatory bowel disease in children (e.g. C. concisus) (18). Other species cause venereal disease and infertility in cattle (C. fetus subsp. venerealis; Cfv) or abortions in sheep (C. fetus subsp. fetus; Cff) (19).In this study, we used phylogenetic, immunological, structural and glycoproteomic studies to compare the N-glycosylation systems of 29 Campylobacter species and identified unexpected variations. Thus, although the pathway is a common feature within this genus, variability in the N-glycans and fOS at the species level suggests that each species possess a unique array of glycosyltransferases, which correlate with their phylogenetic relatedness.