D,L-Hydantoinase activity of an Ochrobactrum anthropi strain.

AIMS: A microorganism with the ability to release methionine from D,L-(2-methylthioethyl) hydantoin (strain 245) was isolated from soil. The aim of this study was the identification of the strain and the adjustment of the conditions of growth and of the enzymatic reaction, in order to achieve high specific activities of bioconversion of the hydantoin. METHODS AND RESULTS: Strain 245 was identified as Ochrobactrum anthropi. The strain grew at alkaline pH (up to 10.0) and its hydantoinase activity was found to be inducible by the substrate D,L-(2-methylthioethyl) hydantoin. The enzyme is also alkalostable, with a pH optimum of 9.0. Under these conditions, hydantoinase activity was significantly enhanced and its half life prolonged when 200 mmol l-1 ammonium and phosphate were added. The addition of Ca2+, Na+, Cu2+, Co2+, Mg2+, Zn2+ or Fe3+ (0.5 mmol l-1) to the reaction mixture increased the hydantoinase activity of strain 245 up to tenfold after 24 h of incubation, compared with unamended controls. CONCLUSION: The adequate adjustment of some environmental parameters (pH, addition of inducer, presence of ammonium, phosphate, heavy metals and other ions) can considerably increase the D, L-hydantoinase activity of strain 245. SIGNIFICANCE AND IMPACT OF THE STUDY: The findings reported here set up the initial conditions for a further application of strain 245 in the production of methionine from hydantoine.

Growth of moderately halophilic bacteria isolated from sea water using phenol as the sole carbon source.

Moderately halophilic bacteria utilizing phenol as the sole carbon source were isolated by selective enrichment from sea water. The isolate (Gram-negative motile rods) was identified as Deleya venusta. It grew well in the presence of up to 1600 mg/L of phenol and 8% NaCl under aerobic conditions. When the cells were treated with chloramphenicol prior to the addition of phenol they did not utilize added phenol, even after prolonged incubation. Thus, the enzymes necessary for phenol metabolism appeared to be inducible.

Neurotactin functions in concert with other identified CAMs in growth cone guidance in Drosophila.

We have isolated and characterized mutations in Drosophila neurotactin, a gene that encodes a cell adhesion protein widely expressed during neural development. Analysis of both loss and gain of gene function conditions during embryonic and postembryonic development revealed specific requirements for neurotactin during axon outgrowth, fasciculation, and guidance. Furthermore, embryos of some double mutant combinations of neurotactin and other genes encoding adhesion/signaling molecules, including neuroglian, derailed, and kekkon1, displayed phenotypic synergy. This result provides evidence for functional cooperativity in vivo between the adhesion and signaling pathways controlled by neurotactin and the other three genes.

Characterization and gene cloning of neurotactin, a Drosophila transmembrane protein related to cholinesterases.

Monoclonal antibodies have served to characterize neurotactin, a novel Drosophila protein for which a role in cell adhesion is postulated. Neurotactin is a transmembrane protein, as indicated by epitope mapping and amino acid sequence. Similarly to other cell adhesion molecules, neurotactin accumulates in parts of the membrane where neurotactin-expressing cells contact each other. The protein is only detected during cell proliferation and differentiation, and it is found mainly in neural tissue and also in mesoderm and imaginal discs. Neurotactin has a large cytoplasmic domain rich in charged residues and an extracellular domain similar to cholinesterase that lacks the active site serine required for esterase activity. The extracellular domain also contains three copies of the tripeptide leucine-arginine-glutamate, a motif that forms the primary sequence of the adhesive site of vertebrate s-laminin.

Drosophila neurotactin mediates heterophilic cell adhesion.

Neurotactin is a 135 kd membrane glycoprotein which consists of a core protein, with an apparent molecular weight of 120 kd, and of N-linked oligosaccharides. In vivo, the protein can be phosphorylated in presence of radioactive orthophosphate. Neurotactin expression in the larval CNS and in primary embryonic cell cultures suggests that it behaves as a contact molecule between neurons or epithelial cells. Electron microscopy studies reveal that neurotactin is uniformly expressed along the areas of contacts between cells, without, however, being restricted to a particular type of junction. It putative adhesive properties have been tested by transfecting non adhesive Drosophila S2 cells with neurotactin cDNA. Heat shocked transfected cells do not aggregate, suggesting that neurotactin does not mediate homophilic cell adhesion. However, these transfected cells bind to a subpopulation of embryonic cells which probably possess a related ligand. The location at cellular junctions between specific neurons or epithelial cells, the heterophilic binding to a putative ligand and the ability to be phosphorylated are consistent with the suggestion that neurotactin functions as an adhesion molecule.

Dimethylmaleic anhydride, a specific reagent for protein amino groups.

The reagent dimethylmaleic anhydride does not cause a stable modification of thiol compounds under the conditions used for modification of protein amino groups, in contrast to maleic and monomethylmaleic anhydrides, which produce an irreversible modification of sulfhydryl groups. This behavior and the low reactivity toward hydroxyamino acid residues, shown in a previous work, make dimethylmaleic anhydride a specific reagent for protein amino groups.

Preparation and structural characterization of nucleosomal core particles lacking one H2A.H2B dimer.

Nucleosomal core particles lacking one H2A.H2B dimer, (H2A.H2B)1 (H3.H4)2/DNA (146 bp), have been prepared by treatment of nucleosomal cores with dimethylmaleic anhydride, a reversible reagent for protein amino groups. The preparative procedure is simple, produces quantitative conversion of nucleosomal cores into dimer-deficient cores without formation of other subnucleosomal particles, and can be applied to the preparation of different H2A.H2B-deficient mono and oligonucleosomal particles. The structural properties of the dimer-deficient cores and complete nucleosomal cores reconstituted from the deficient particles and H2A.H2B dimers have been studied by DNase I digestion, thermal denaturation and circular dichroism.