Membrane fluidization by alcohols inhibits DesK-DesR signalling in Bacillus subtilis

After cold shock, the Bacillus subtilis desaturase Des introduces double bonds into the fatty acids of existing membrane phospholipids. The synthesis of Des is regulated exclusively by the two-component system DesK/DesR; DesK serves as a sensor of the state of the membrane and triggers Des synthesis after a decrease in membrane fluidity. The aim of our work is to investigate the biophysical changes in the membrane that are able to affect the DesK signalling state. Using linear alcohols (ethanol, propanol, butanol, hexanol, octanol) and benzyl alcohol, we were able to suppress Des synthesis after a temperature downshift. The changes in the biophysical properties of the membrane caused by alcohol addition were followed using membrane fluorescent probes and differential scanning calorimetry.We found that the membrane fluidization induced by alcohols was reflected in an increased hydration at the lipid-water interface. This is associated with a decrease in DesK activity. The addition of alcohol mimics a temperature increase, which can be measured isothermically by fluorescence anisotropy. The effect of alcohols on the membrane periphery is in line with the concept of the mechanism by which two hydrophilic motifs located at opposite ends of the transmembrane region of DesK, which work as a molecular caliper, sense temperature-dependent variations in membrane properties.     

The genome of <Emphasis Type="Italic">Bacillus aryabhattai</Emphasis> T61 reveals its adaptation to Tibetan Plateau environment

Tibetan Plateau is called ‘the Roof of the World’. Organisms survive there have to adapt to the high altitude environment. By shotgun method, we sequenced the genome of Bacillus aryabhattai T61, which inhabits in the soil at the altitude of 4123 m in Shigatse, Tibetan. Further, we explored the genomic basis for its adaptations to the plateau environment. The results showed that B. aryabhattai T61 has evolved an array of ROS defense systems and sporulation system for adaptations to the stresses caused by the plateau strong ultraviolet radiation, extreme oxygen limitation and low temperature. Specifically, B. aryabhattai T61 encodes the ResE–ResD two-component to sense the oxygen limitation and regulates COX15 for aerobic and anaerobic respiration. The two-component system DesK–DesR, which regulates the gene Des initiating the biosynthesis of unsaturated fatty acids, along with 33 temperature-shock proteins contribute to low temperature adaptation. With the comparative analysis, we deduced the novel gene cbiY may be involved in cobalamin biosynthesis. We also found that B. aryabhattai T61 may have novel regulatory mechanisms for sporulation initiation. B. aryabhattai T61 is the first Tibetan strain with high quality genome sequenced. The genome provides a paradigm for understanding the adaptations to the plateau environment in Bacteria kingdom.     

A six-membrane-spanning topology for yeast and Arabidopsis Tsc13p, the enoyl reductases of the microsomal fatty acid elongating system

The very long chain fatty acids are crucial building blocks of essential lipids, most notably the sphingolipids. These elongated fatty acids are synthesized by a system of enzymes that are organized in a complex within the endoplasmic reticulum membrane. Although several of the components of the elongase complex have recently been identified, little is known about how these proteins are organized within the membrane or about how they interact with one another during fatty acid elongation. In this study the topology of Tsc13p, the enoyl reductase of the elongase system, was investigated. The N and C termini of Tsc13p reside in the cytoplasm, and six putative membrane-spanning domains were identified by insertion of glycosylation and factor Xa cleavage sites at various positions. The N-terminal domain including the first membrane-spanning segment contains sufficient information for targeting to the endoplasmic reticulum membrane. Studies of the Arabidopsis Tsc13p protein revealed a similar topology. Highly conserved domains of the Tsc13p proteins that are likely to be important for enzymatic activity lie on the cytosolic face of the endoplasmic reticulum, possibly partially embedded within the membrane.     

Regulation of the desaturation of fatty acids and its role in tolerance to cold and salt stress

The expression of cold-inducible genes is regulated by a two-component system in Synechocystis and Bacillus subtilis. The cold sensors are membrane-bound histidine kinases and it seems likely that they sense and transduce changes in the fluidity of membranes. Desaturation of fatty acids in membrane lipids has been implicated in tolerance to cold and salt stress.     

温度响应的细菌生理生化特性调控研究进展

针对细菌对温度变化响应呈现的生理生化特性变化,总结了细胞内作为温度感应元件DNA、RNA及蛋白质分子如何响应温度变化,以及细胞调控生理生化特性的机制。重点介绍了典型的温度响应双组分系统的组成、结构及调控方式,如铜绿假单胞菌PG1480的CorS/CorR双组分系统响应温度的刺激调控细胞基因的表达,枯草芽胞杆菌的DesK/DesR双组分系统响应外界温度变化,调节编码脂肪酸去饱和酶基因des的表达,以及在嗜麦芽单胞菌中发现的LotS/LotR双组分系统,调控低温响应蛋白酶的表达。同时总结c-di-GMP作为第二信使参与温度响应双组分调控的机制;提出研究的热点问题和关键技术以及建议的研究策略。     

Extracellular Ca2+ transients affect poly-(R)-3-hydroxybutyrate regulation by the AtoS-AtoC system in Escherichia coli

Escherichia coli is exposed to wide extracellular concentrations of Ca2+, whereas the cytosolic levels of the ion are subject to stringent control and are implicated in many physiological functions. The present study shows that extracellular Ca2+ controls cPHB [complexed poly-(R)-3-hydroxybutyrate] biosynthesis through the AtoS-AtoC two-component system. Maximal cPHB accumulation was observed at higher [Ca2+]e (extracellular Ca2+ concentration) in AtoS-AtoC-expressing E. coli compared with their DeltaatoSC counterparts, in both cytosolic and membrane fractions. The reversal of EGTA-mediated down-regulation of cPHB biosynthesis by the addition of Ca2+ and Mg2+ was under the control of the AtoS-AtoC system. Moreover, the Ca2+-channel blocker verapamil reduced total and membrane-bound cPHB levels, the inhibitory effect being circumvented by Ca2+ addition only in atoSC+ bacteria. Histamine and compound 48/80 affected cPHB accumulation in a [Ca2+]e-dependent manner directed by the AtoS-AtoC system. In conclusion, these data provide evidence for the involvement of external Ca2+ on cPHB synthesis regulated by the AtoS-AtoC two-component system, thus linking Ca2+ with a signal transduction system, most probably through a transporter.     

Hierarchy of membrane-targeting signals of phospholipase D1 involving lipid modification of a pleckstrin homology domain

The amino terminus of phospholipase D1 (PLD1) contains three potential membrane-interacting determinants: a phox homology (PX) domain, a pleckstrin homology (PH) domain and two adjacent cysteines at positions 240 and 241 within the PH domain that are fatty acylated in vivo. To understand how these determinants contribute to membrane localization, we have mutagenized critical residues of the PLD1 PH domain in the wild type or palmitate-free background in the intact protein, in a fragment that deletes the first 210 amino acids including the PX domain, and in the isolated PH domain. Mutants were expressed in COS-7 cells and examined for membrane residence, intracellular localization, palmitoylation, and catalytic activity. Our results are as follows. 1) Mutagenesis of critical residues of the PH domain results in redistribution of PLD1 from membranes to cytosol, independently of fatty acylation sites. Importantly, PH domain mutants in the wild type background showed greatly reduced fatty acylation, despite the presence of all relevant cysteines. 2) The isolated PH domain did not co-localize with PLD1 and was not palmitoylated. 3) The PX deletion mutant showed similar distribution and palmitoylation to the intact protein. Interestingly, PH domain mutants in this background showed significant palmitoylation and incomplete cytosolic redistribution. 4) PH domain mutants in the wild type or palmitate-free background maintained catalytic activity. We propose that membrane targeting of PLD1 involves a hierarchy of signals with a functional PH domain allowing fatty acylation leading to strong membrane binding. The PX domain may modulate function of the PH domain.     

Determinants of membrane association in the SH4 domain of Fyn: Roles of N-terminus myristoylation and side-chain thioacylation

The SH4 domain of Fyn, a member of the Src family of tyrosine kinases, though rich in polar amino acid residues, anchors to the cytosolic face of membranes upon fatty acylation. In order to probe the requirement of specific fatty acylation at the N-terminus and at the side-chain of this domain for membrane-association, we have studied the interaction of peptides corresponding to the polar segment of the SH4 domain of Fyn and its mono- and dually fatty acylated analogs with model membranes. While the polar segment without covalently linked fatty acids (KDKEATKLTEW-amide) does not interact with lipid vesicles, peptides with one covalently linked fatty acid at the N-terminus or in the side-chain, associate with zwitterionic and anionic lipids to varying degrees. The interaction of dually acylated peptides (Myr-GK(ε-myr)KDKEATKLTEW-amide and Myr-GC(S-pal)KDKEATKLTEW-amide) with lipids depends on the linkage between fatty acyl side-chain and peptide backbone. The peptide chain associates with membranes only when the side-chain acylation is via an amide bond and not via a thioester bond. Our investigations indicate that acylation is essential for membrane targeting and unacylated polar stretch of the SH4 domain does not have a role in membrane-anchoring. Side-chain acylation via a thioester bond not only provides membrane anchorage but also directs the peptide chain away from the bilayer which might be important to enable the full length protein to interact with other signaling partners.     

The thioredoxin reductase-thioredoxin system is involved in the entry of tetanus and botulinum neurotoxins in the cytosol of nerve terminals

Tetanus and botulinum neurotoxins cause paralysis by cleaving SNARE proteins within the cytosol of nerve terminals. They are endocytosed inside acidic vesicles and the pH gradient across the membrane drives the translocation of their metalloprotease L domain in the cytosol. This domain is linked to the rest of the molecule by a single interchain disulfide bridge that has to be reduced on the cytosolic side of the membrane to free its enzymatic activity. By using specific inhibitors of the various cytosolic protein disulfides reducing systems, we show here that the NADPH-thioredoxin reductase-thioredoxin redox system is the main responsible for this disulfide reduction. In addition, we indicate auranofin, as a possible basis for the design of novel inhibitors of these neurotoxins.