In vivo interaction between RGS4 and calmodulin visualized with FRET techniques: possible involvement of lipid raft

Regulators of G-protein signaling (RGS) are a family of proteins which accelerate intrinsic GTP-hydrolysis on heterotrimeric G-protein-alpha-subunits. Although it has been suggested that the function of RGS4 is reciprocally regulated by competitive binding of the membrane phospholipid, phosphatidylinositol-3,4,5,-trisphosphate(PtdIns(3,4,5)P(3)), and Ca(2+)/calmodulin (CaM), it remains to be shown that these interactions occur in vivo. Here, using fluorescence resonance energy transfer (FRET) techniques, we show that an elevation of intracellular Ca(2+) concentration by ionomycin increased the FRET efficiency from ECFP (a variant of cyan fluorescent protein)-labeled calmodulin to Venus (a variant of yellow fluorescent protein)-labeled RGS4. The increase in FRET efficiency was greatly attenuated by pre-treating the cells with methyl-beta-cyclodextrin, which depletes membrane cholesterol and thus disrupts lipid rafts. These results provide the first demonstration of a Ca(2+)-dependent interaction between RGS4 and CaM in vivo and show that association in lipid rafts of the plasma membrane might be involved in this physiological regulation of RGS proteins.     

细菌细胞壁生长调控机制研究进展

在细菌生长过程中,细胞壁起到维持细胞形状和完整性,抵抗内部膨胀压的作用。细胞壁的合成、分裂、再生、循环再利用等与细菌自身生长繁殖和应对环境压力息息相关。目前,细胞壁生长机理,细菌如何调控细胞壁生长及如何与其他细胞过程相协调的机制尚未研究清楚。细胞壁调控机制的解析对了解细菌细胞壁功能、确定药物的作用方式和发展新一代的治疗方法至关重要。对细菌调控细胞壁生长机制的国外研究进展进行了概述,重点阐述了支架蛋白、转录因子、非编码小RNA及蛋白相互作用调控细胞壁的合成、细胞分裂、压力响应的机制,总结了细胞壁调控机制在抗菌药物研发中的应用,并对未来的研究方向进行了展望。     

Biochemical interaction between chelonine wasps and their lepidopteran hosts: after a decade of research - the parasite is in control

A decade of research on the biochemical interaction between chelonine wasps and their lepidopteran hosts has yielded considerable data on the underlying basis for the developmental, immunological and reproductive effects that these parasites inflict upon their hosts. These egg-larval parasites induce their immunologically compromised host larvae to precociously initiate metamorphosis, followed by suppression of development of the precocious prepupa, in addition to castration of the host. The results from numerous laboratories have shown that the parasite egg that is normally injected by the adult female into the host along with venom, polydnavirus and calyx fluid proteins need not hatch or even be present for the host to exhibit each of these alterations. In addition to these aspects the parasite larva, when present, itself releases hormones and proteins into the hemolymph of the host. A review of the data amassed to date leads inexorably to the conclusion that it is the chelonine wasp that is the biochemically dominant partner. Thus, after 10 years of research, it still appears that in chelonine-lepidopteran parasite-host systems, the parasite is in control of specific points of the biochemistry and development of its host.     

Genetic analyses of putative two-element systems regulating somatic mutability in Mutator-induced aleurone mutants of maize

The Mutator transposable element system (Mu) of maize has been responsible for the induction of numerous mutable aleurone mutants of maize. Unlike similar mutants induced by other transposable element systems, the mutability of Mu-induced mutants did not seem initially to be regulated by an independent autonomous or regulator element. However, in a continuing study of two Mu-induced a1 mutable mutants (a1-Mum2) and a1-Mum3, lines have been obtained that give evidence of an independently segregating regulator of somatic mutability. Data from several generations of crossing are presented indicating that intense somatic mutability in many of these stocks is under the control of an independent regulator. However, testing of other lines, which initially gave evidence of the presence of an independent regulator, were negative. Some of these latter lines could be expected to have Mutator elements that were modified (methylated) at sites recognized by certain restriction endonucleases. Modification of Mu elements, which is known to affect the expression of somatic mutability, might, at times, be responsible for producing conditions that mimic the segregation of an independent regulator. Lines with stable derivatives of the a1-Mum2 and a1-Mum3 can recover intense somatic mutability by crossing with germinally active Mutator stocks. Thus, active Mutator lines contain regulator elements and evidence is presented suggesting that such lines have multiple copies of these elements. Most a1- Mum2 and a1-Mum3 stocks segregating for a regulator do not have germinal Mutator activity. Thus the presence of one or a few putative regulator elements does not necessarily account for the high level of germinal activity in most Mutator stocks.     

Electrophysiological evaluation of Cystic Fibrosis Conductance Transmembrane Regulator (CFTR) expression in human monocytes

Background

Cystic fibrosis is caused by mutations of CFTR gene, a protein kinase A-activated anion channel, and is associated to a persistent and excessive chronic lung inflammation, suggesting functional alterations of immune cells. Leukocytes express detectable levels of CFTR but the molecule has not been fully characterized in these cells.

Methods

Freshly isolated monocytes from healthy individuals and CF patients were assessed by protein expression, single cell electrophysiological and membrane depolarization assays.

Results

We recorded chloride currents by patch clamp in healthy monocytes, after the administration of a CFTR stimulus. Currents were sensitive to a specific blocker of the CFTR channel, CFTR_inh-172 and were absent in CF monocytes. Next, we evaluated the effects of ex vivo exposure of monocytes from cystic fibrosis patients carrying the F508del mutation to a chemical corrector, Vertex-325. We found an increase in CFTR expression by confocal microscopy and a recovery of CFTR function by both patch clamp and single cell fluorescence analysis.

Conclusions

We confirm the expression of functional CFTR in human monocytes and demonstrate that blood monocytes can represent an adequate source of primary cells to assess new therapies and define diagnosis of CF.

General significance

Tests to evaluate CFTR functional abnormalities in CF disease might greatly benefit from the availability of a convenient source of primary cells. This electrophysiological study promotes the use of monocytes as a minimally invasive tool to study and monitor CFTR function in individual patients.     

Nrc of Streptococcus pneumoniae suppresses capsule expression and enhances anti-phagocytosis

Streptococcus pneumoniae is a major pathogen of community-acquired pneumonia and one of its major virulence factors is pneumolysin, which functions as a cholesterol-dependent cytolytic pore-forming toxin. In this study, we identified the ply-like gene spd0729 in a BLAST search. Unexpectedly, hemolytic and cytotoxic assays showed no significant differences between a Δspd0729 mutant strain and the wild-type strain, whereas the mutant strain exhibited weaker anti-phagocytic activity in human peripheral blood. In addition, real-time RT-PCR analysis revealed that four capsular biosynthesis genes in the mutant strain had expressions 7- to 432-fold greater than those of the wild type, while an enzyme-linked immunoassay showed a mean 3-fold greater amount of total capsular polysaccharide in the mutant strain. These results suggest that Spd0729 is not a cytolysin, though it plays crucial roles in anti-phagocytosis and regulation of capsule expression. Thus, we named Spd0729 as a negative regulator of capsular polysaccharide synthesis (Nrc).     

Modulation of phospholipase D activity in vitro

Most phospholipases D (PLDs) occurring in microorganisms, plants and animals belong to a superfamily which is characterized by several conserved regions of amino acid sequence including the two HKD motifs necessary for catalytic activity. Most eukaryotic PLDs possess additional regulatory structures such as the Phox and Pleckstrin homology domains in mammalian PLDs and the C2 domain in most plant PLDs. Owing to recombinant expression techniques, an increasing number of PLDs from different organisms has been obtained in purified form, allowing the investigation of specific and unspecific interactions of the enzymes with regulatory components in vitro. The present paper gives an overview on different factors which can modulate PLD activity and compares their influence on the enzymes from different sources. While no biological regulator can be recognized for extracellular bacterial PLDs, the most prominent specific activator of eukaryotic PLDs is phosphatidylinositol-4,5-bisphosphate (PIP₂). In a sophisticated interplay PIP₂ seems to cooperate with several regulatory proteins in mammalian PLDs, whereas in plant PLDs it mainly acts in concert with Ca²⁺ ions. Moreover, curvature, charges and heterogeneities of membrane surfaces are assessed as unspecific modulators. A possible physiological role of the transphosphatidylation reaction catalyzed by PLDs in competition with phospholipid hydrolysis is discussed.