Distinct roles of the two isoforms of the dynamin-like GTPase Mgm1 in mitochondrial fusion

The mitochondrial dynamin-like GTPase Mgm1 exists as a long (l-Mgm1) and a short isoform (s-Mgm1). They both are essential for mitochondrial fusion. Here we show that the isoforms interact in a homotypic and heterotypic manner. Their submitochondrial distribution between inner boundary membrane and cristae was markedly different. Overexpression of l-Mgm1 exerts a dominant negative effect on mitochondrial fusion. A functional GTPase domain is required only in s-Mgm1 but not in l-Mgm1. We propose that l-Mgm1 acts primarily as an anchor in the inner membrane that in concert with the GTPase activity of s-Mgm1 mediates the fusion of inner membranes.     

Evolutionary conservation of mechanisms for neural regionalization, proliferation and interconnection in brain development

Comparative studies of brain development in vertebrate and invertebrate model systems demonstrate remarkable similarities in expression and action of developmental control genes during embryonic patterning, neural proliferation and circuit formation in the brain. Thus, comparable sets of developmental control genes are involved in specifying the early brain primordium as well as in regionalized patterning along its anteroposterior and dorsoventral axes. Furthermore, similar cellular and molecular mechanisms underlie the formation and proliferation of neural stem cell-like progenitors that generate the neurons in the central nervous systems. Finally, neural identity and some complex circuit interconnections in specific brain domains appear to be comparable in vertebrates and invertebrates and may depend on similar developmental control genes.     

Transcriptional response to alcohol exposure in Drosophila melanogaster

Background  

Alcoholism presents widespread social and human health problems. Alcohol sensitivity, the development of tolerance to alcohol and susceptibility to addiction vary in the population. Genetic factors that predispose to alcoholism remain largely unknown due to extensive genetic and environmental variation in human populations. Drosophila, however, allows studies on genetically identical individuals in controlled environments. Although addiction to alcohol has not been demonstrated in Drosophila, flies show responses to alcohol exposure that resemble human intoxication, including hyperactivity, loss of postural control, sedation, and exposure-dependent development of tolerance.     

The follicle-stimulating hormone (FSH) receptor in testis: interaction with FSH, mechanism of signal transduction, and properties of the purified receptor

The follicle-stimulating hormone (FSH) receptor purified from calf bovine testis membranes appears to be an oligomeric glycoprotein, consisting of 4 disulfide-linked monomers of molecular weight about 60,000 each. Polyclonal antibodies to the hormone binding sites of the receptor have been developed. FSH interaction with the receptor seems to involve multiple discrete binding regions, which include amino acids 34-37 and 49-52 of the human FSH beta subunit. The interaction between FSH and the membrane-bound receptor is reversible at low temperatures but becomes increasingly irreversible as the temperature increases. FSH interaction with the soluble receptor is reversible over a wider temperature range. The hydrophobic effect is a significant factor in the initial hormone receptor interaction in each system. FSH bound to membrane receptors on cultured immature rat Sertoli cells is internalized and degraded to the level of amino acids. Current evidence suggests that the membrane receptor may exist as free receptor, and complexed with G-protein. A functional receptor/G-protein/adenylate cyclase complex has been reconstituted in liposomes. The G-protein of testis membranes contains both high and low affinity guanosine triphosphate (GTP) binding sites. Both are capable of modulating FSH receptor binding, whereas only the high affinity sites seem to be required for activation of adenylate cyclase. Although testis membranes contain a phosphatidylinositide hydrolysis system, the latter is not directly influenced by FSH.     

Second international conference on accelerating biopharmaceutical development

The Second International Conference on Accelerating Biopharmaceutical Development was held in Coronado, California. The meeting was organized by the Society for Biological Engineering (SBE) and the American Institute of Chemical Engineers (AIChE); SBE is a technological community of the AIChE. Bob Adamson (Wyeth) and Chuck Goochee (Centocor) were co‐chairs of the event, which had the theme “Delivering cost‐effective, robust processes and methods quickly and efficiently.” The first day focused on emerging disruptive technologies and cutting‐edge analytical techniques. Day two featured presentations on accelerated cell culture process development, critical quality attributes, specifications and comparability, and high throughput protein formulation development. The final day was dedicated to discussion of technology options and new analysis methods provided by emerging disruptive technologies; functional interaction, integration and synergy in platform development; and rapid and economic purification process development. © This meeting report was written for and published by Landes Bioscience in the journal, mAbs. Reichert JM, Jacob N, Amanullah A. Second International Conference on Accelerating Biopharmaceutical Development: March 9–12, 2009, Coronado, CA USA. mAbs 2009 1(3); http://www. landesbioscience.com/journals/mabs/article/8491 Biotechnol. Prog., 2009     

Bacterial swimming strategies and turbulence

Most bacteria in the ocean can be motile. Chemotaxis allows bacteria to detect nutrient gradients, and hence motility is believed to serve as a method of approaching sources of food. This picture is well established in a stagnant environment. In the ocean a shear microenvironment is associated with turbulence. This shear flow prevents clustering of bacteria around local nutrient sources if they swim in the commonly assumed "run-and-tumble" strategy. Recent observations, however, indicate a "back-and-forth" swimming behavior for marine bacteria. In a theoretical study we compare the two bacterial swimming strategies in a realistic ocean environment. The "back-and-forth" strategy is found to enable the bacteria to stay close to a nutrient source even under high shear. Furthermore, rotational diffusion driven by thermal noise can significantly enhance the efficiency of this strategy. The superiority of the "back-and-forth" strategy suggests that bacterial motility has a control function rather than an approach function under turbulent conditions.