The biology of bacterial peptidoglycans and their impact on host immunity and physiology

Peptidoglycans (PGN) are a constituent of the bacterial cell wall, and are shed as bacteria divide. The presence of PGN is therefore a marker of bacterial activity that has been exploited by both plants and animals to induce defence mechanisms. Pattern recognition receptors that recognize PGN are extremely well conserved throughout evolution and shown to play important and diverse role in the development, homeostasis and activation of the immune system. In addition, PGN can be detected beyond mucosal surfaces, and their receptor can be expressed in tissues and cells that are far from the niches where bacteria reside. Thus, PGN affects not only the host's immunity, but also more generally the host's physiology. In this review, we discuss the biochemistry and biology of PGN, and their intriguing effects on the development of the immune system and the host physiology.     

Nucleotides and divalent cations as effectors and modulators of exocytosis in permeabilized rat mast cells.

The idea that the universal trigger to exocytosis (the terminal step in the secretory process) is an elevation of the cytosol concentration of Ca2+, and that it is dependent on ATP, is no longer tenable. Working with streptolysin-O-permeabilized mast cells (and other myeloid cells) we have shown that non-hydrolysable analogues of GTP can stimulate exocytosis after depletion of Ca2+ (i.e. at concentrations below 10(-9) M) and ATP. Such Ca2+- and ATP-independent exocytosis is strongly dependent on the presence of Mg2+, and the requirement for Mg2+ declines as the concentration of Ca2+ is brought up to 10(-7) M. We argue that Ca2+ serves to regulate the binding of guanine nucleotides to GE, a GTP-binding protein that regulates exocytosis through its interaction with CE, a calcium-binding protein which serves as an intracellular pseudo-receptor. The onset of exocytosis, following provision of Ca2+ and guanine nucleotides to the permeabilized cells, is preceded by delays which are sensitive to the order of provision of the two effectors (i.e. Ca2+ and guanine nucleotides), the presence or absence of Mg2+, and the identity of the activating guanine nucleotide. In view of the similarity of these features with the activation kinetics of adenylyl cyclase, we argue that GE behaves as a member of the heterotrimeric class of signal transducing G-proteins such as GS.     

ATP-dependent and ATP-independent pathways of exocytosis revealed by interchanging glutamate and chloride as the major anion in permeabilized mast cells.

Most investigations of the mechanism of regulated exocytosis have involved the use of secretory cells permeabilized in glutamate-based electrolyte solutions. In our previous work we have used NaCl-based electrolyte solutions. For secretion to occur from rat mast cells under these latter conditions, a dual effector system comprising Ca2+ and a guanine nucleotide are required; together they are sufficient. Here we compare the secretion from mast cells permeabilized in solutions of different electrolytes. Replacement of Na+ by K+ had little effect. Replacement of Cl- by Br-, SO4-, gluconate, isethionate, acetate, tartrate, succinate, etc. affected the maximal extent of secretion elicited by the dual effectors Ca2+ and guanosine-5'-O-(3-thiotriphosphate) (Ca2(+)-plus-GTP-gamma-S) but had little influence on the effective affinity for Ca2+. The dicarboxylic amino acids (L- and D-glutamate, and L-aspartate) permitted exocytosis to be elicited by Ca2+ or GTP-gamma-S alone. Secretion stimulated by GTP-gamma-S is strongly inhibited by Cl- (50% inhibition by 20 mM Cl-), whereas the extent of Ca2(+)-induced secretion is proportional to the concentration of glutamate in mixed electrolyte buffers. Unlike dual-effector stimulation, secretion due to the single effectors requires adenosine triphosphate (ATP) and is prevented by inhibitors of protein kinase C. These results point to the existence of two parallel pathways for control of exocytosis in permeabilized cells, one ATP dependent, the other ATP independent.     

Relationship between arachidonate generation and exocytosis in permeabilized mast cells.

Using rat mast cells permeabilized with streptolysin O we show that release of arachidonate generally occurs under similar but not identical conditions to those that cause exocytosis of beta-N-acetylglucosaminidase (hexosaminidase). Thus, hexosaminidase secretion and arachidonate release both require provision of Ca2+ together with a guanine nucleotide but exocytosis occurs at lower concentrations of both effectors. The kinetics of both processes are similar, with a delay in onset only when ATP is present. Arachidonate release occurs largely from a pool of arachidonyl phosphatidylcholine which appears to represent less than 1% of the total phosphatidylcholine of the cells. Despite the general similarity of the conditions causing exocytosis and arachidonate release, our results show that under some circumstances it is possible to obtain exocytosis without measurable release of arachidonate and that therefore phospholipase A2 activation is not an essential precursor of secretion.     

Live imaging of <Emphasis Type="Italic">Drosophila</Emphasis>gonad formation reveals roles for Six4 in regulating germline and somatic cell migration

Background  

Movement of cells, either as amoeboid individuals or in organised groups, is a key feature of organ formation. Both modes of migration occur during Drosophila embryonic gonad development, which therefore provides a paradigm for understanding the contribution of these processes to organ morphogenesis. Gonads of Drosophila are formed from three distinct cell types: primordial germ cells (PGCs), somatic gonadal precursors (SGPs), and in males, male-specific somatic gonadal precursors (msSGPs). These originate in distinct locations and migrate to associate in two intermingled clusters which then compact to form the spherical primitive gonads. PGC movements are well studied, but much less is known of the migratory events and other interactions undergone by their somatic partners. These appear to move in organised groups like, for example, lateral line cells in zebra fish or Drosophila ovarian border cells.     

Downregulation of calcineurin activity in cervical carcinoma

Background  

Calcineurin (CaN) is an important serine-threonine phosphatase (PP2B), which plays a crucial role in calcium-calmodulin mediated signal transduction events. Calcineurin has been implicated in pathogenesis of various diseases cardiac hypertrophy, diabetic neuropathy and Alzheimer's, however its role in neoplasia remains unclear.     

Local tissue interactions across the dorsal midline of the forebrain establish CNS laterality

The mechanisms that establish behavioral, cognitive, and neuroanatomical asymmetries are poorly understood. In this study, we analyze the events that regulate development of asymmetric nuclei in the dorsal forebrain. The unilateral parapineal organ has a bilateral origin, and some parapineal precursors migrate across the midline to form this left-sided nucleus. The parapineal subsequently innervates the left habenula, which derives from ventral epithalamic cells adjacent to the parapineal precursors. Ablation of cells in the left ventral epithalamus can reverse laterality in wild-type embryos and impose the direction of CNS asymmetry in embryos in which laterality is usually randomized. Unilateral modulation of Nodal activity by Lefty1 can also impose the direction of CNS laterality in embryos with bilateral expression of Nodal pathway genes. From these data, we propose that laterality is determined by a competitive interaction between the left and right epithalamus and that Nodal signaling biases the outcome of this competition.     

Mobile carrier ionophores for Fe(II).

A23187 and certain other carboxylate ionophores are capable of transferring Fe(II) but not Fe(III) across phospholipid bilayers (liposomes) and red cell membranes. A23187 is able to transfer Fe(II) from ferritin loaded liposomes when allied with a suitable redox couple and sink. The affinity of A23187 for Fe(II) is approximately five orders of magnitude greater than for Ca2+, as judged by two phase extraction techniques.