Semaphorin 1a and semaphorin 1b are required for correct epidermal cell positioning and adhesion during morphogenesis in C. elegans

The semaphorin family comprises secreted and transmembrane proteins involved in axon guidance and cell migration. We have isolated and characterized deletion mutants of C. elegans semaphorin 1a (Ce-sema-1a or smp-1) and semaphorin 1b (Ce-sema-1b or smp-2) genes. Both mutants exhibit defects in epidermal functions. For example, the R1.a-derived ray precursor cells frequently fail to change anterior/posterior positions completely relative to their sister tail lateral epidermal precursor cell R1.p, causing ray 1 to be formed anterior to its normal position next to ray 2. The ray cells, which normally separate from the lateral tail seam cell (SET) at the end of L4 stage, remains connected to the SET cell even in adult mutant males. The ray 1 defects are partially penetrant in each single Ce-sema-1 mutant at 20 degrees C, but are greatly enhanced in Ce-sema-1 double mutants, suggesting that Ce-Sema-1a and Ce-Sema-1b function in parallel to regulate ray 1 position. Both mutants also have defects in other aspects of epidermal functions, including head and tail epidermal morphogenesis and touch cell axon migration, whereas, smp-1 mutants alone have defects in defecation and brood size. A feature of smp-1 mutants that is shared with mutants of mab-20 (which encodes Sema-2a) is the abnormal perdurance of contacts between epidermal cells.     

Chemistry of vinylidene complexes XI. Synthesis of trinuclear MnFePt complexes by means of consecutive assembling out of mono- and dimetal vinylidene precursors

The dimetal μ-vinylidene complexes Cp(CO)₂MnPt(μ-C = CHPh)L₂ (L = tert.-phosphine or -phosphite), which have been obtained by coupling of the mononuclear complex Cp(CO)₂Mn=C=CHPh and unsaturated PtL₂ unit, add smoothly the Fe(CO)₄ moiety to produce trimetal MnFePt compounds. The μ₃-vinylidene cluster CpMnFePt(μ₃-C=CHPh)(CO)₆(PPh₃) was prepared in quantitative yields from the reactions of Cp(CO)₂MnPt(μ-C=CHPh)(PPh₃)L (L = PPh₃ or CO) with Fe₂(CO)₉ in benzene at 20 °C. The phosphite-substituted complexes Cp(CO)₂Mnpt(μ-C=CHPh)L₂ (L = P(OEt)₃ or P(OPrⁱ)₃) react under analogous conditions with Fe₂(CO)₉ to give mixtures (2:3) of the penta- and hexacarbonyl clusters, CpMnFePt(μ₃-C = CHPh)(CO)₅L₂ and CpMnFePt(μ₃-C = CHPh)(CO)₆L, respectively. The similar reaction of the dimetal complex Cp(CO)₂MnPt(μ-C = CHPh)(dppm), in which the Pt atom is chelated by dppm = Ph₂PCH₂PPhPin2 ligand, gives only a 15% yield of the analogous trimetal μ₃-vinylidene hexacarbonyl product CpMnFePt(μ₃-C = CHPh)(CO)(dppm), but the major product (40%) is the tetranuclear μ₄-vinylidene cluster (dppm)PtFe₃(μ₄-C = CHPh)(CO)₉. The IR and ¹H, ¹³C and ³¹P NMR data for the new complexes are reported and discussed.     

Functionally impaired tRNA from ethionine treated rats as detected in injected Xenopus oocytes.

Treatment of rats with ethionine was found to cause severe impairment in the aminoacylation capacity of tRNA. This effect was only observed when assayed in injected oocytes, while invitro assays of aminoacylation failed to detect differences between normal tRNA and tRNA from ethionine treated animals. The effect of ethionine on the tRNA population was not uniform and differed for various amino acid specific tRNAs. Thus liver tRNA from ethionine treated rats showed a decreased capacity for phenylalanine aminoacylation, while no change was found in the case of leucine. On the other hand, the level of histidine aminoacylation was higher for tRNA from ethionine treated animals. An even more complex response was observed with methionine aminoacylation where tRNA from ethionine treated animals showed an initially faster rate than control tRNA. With more prolonged incubation periods, the methionyl-tRNA from ethionine treated animals was deacylated at an accelerated rate while the level of normal methionyl-tRNA remained almost constant.In addition to the aminoacylation reaction, the participation of aminoacyl-tRNA in protein synthesis was severely impaired. In this case, both the injected oocyte system and the cell-free wheat germ assay revealed these differences which were manifested with various mRNA and viral RNA preparations.     

A biomimetic platform for studying root-environment interaction

Aims

Microstructure plays an important role in biological systems. Microstructural features are critical in the interaction between two biological organisms, for example, a microorganism and the surface of a plant. However, isolating the structural effect of the interaction from all other parameters is challenging when working directly with the natural system. Replicating microstructure of leaves was recently shown to be a powerful research tool for studying leaf-environment interaction. However, no such tool exists for roots. Roots present a special challenge because of their delicacy (specifically of root hairs) and their 3D structure. We aim at developing such a tool for roots.

Methods

Biomimetics use synthetic systems to mimic the structure of biological systems, enabling the isolation of structural function. Here we present a method which adapts tools from leaf microstructure replication to roots. We introduce new polymers for this replication.

Results

We find that Polyurethane methacrylate (PUMA) with fast UV curing gives a reliable replication of the tomato root surface microstructure. We show that our system is compatible with the pathogenic soilborne bacterium Ralstonia solanacearum.

Conclusions

This newly developed tool may be used to study the effect of microstructure, isolated from all other effects, on the interaction of roots with their environment.

     

Possibility of major gene control over scale E of Cattel's test

The segregation analysis is made of inheritance of the E factor of the Cattell's 16PF Questionnaire on the basis of a population sample consisting of 108 free-structured pedigrees. The possibility of major gene control of inheritance for this quantitative trait is confirmed.     

Heterogeneity of Tau proteins during mouse brain development and differentiation of cultured neurons.

Tau microtubule-associated proteins constitute a group of developmentally regulated neuronal proteins. Using the high-resolution two-dimensional polyacrylamide gel electrophoresis system, we have resolved more than 60 distinct Tau isoforms in the adult mouse brain. Tau protein heterogeneity increases drastically during the second week of brain development. In neuronal primary cell cultures, some of these developmental changes can be observed. The increase of Tau heterogeneity in culture is more limited and reaches a plateau after a period corresponding to the second week of development. Most, if not all, of the vast Tau heterogeneity can be attributed to intensive post-translational phosphorylation, which may affect the structure of the proteins.     

Distribution of methane in waters of the Okhotsk and western Bering Seas,and the area of the Kuril Islands

Investigations of distribution and possible sources of methane dissolved in waters of the Okhotsk and western Bering Seas, and in the areaof the Kuril Islands were conducted in summer 1993 during the 24th cruise ofR/V ‘Akademik Nesmeyanov’. In open waters, the background content ofmethane was 30–80 nl CH₄ l⁻¹. At somestations, subsurface maxima of CH₄ up to 523 nll⁻¹ (up to 683% of saturation), were registered. Theywere associated with biological production. Maximal concentrations ofmethane, up to 5710 nl CH₄ l⁻¹ (1363% ofsaturation), were observed in areas of discharge from anaerobic zones ofbottom sediments and oil gas deposits, destruction of crystallohydrates, andemission along fractures in the earth's crust. Migration ofCH₄ from bottom sediments resulted in the establishment of amaximum at intermediate depths. This revised version was published online in July 2006 with corrections to the Cover Date.     

A salt-sensitive Dunaliella mutant I. Growth and osmoregulatory responses to increases in salt concentration

Dunaliella is a genus of green unicellular algae distributedin all the oceans and saline bodies of water throughout theworld and distinguished by unusual tolerance to salt. Sincethe cells of this genus do not possess a rigid cell-wall, theyrespond to changes in salt concentration by rapid alterationsin cell volume and then return to their original volume as aresult of adjustments in the amounts of intracellular ions andglycerol, this latter being the major organic osmoticum. Thepaper describes the behaviour of a mutant of D. parva 19/9 withreduced capabilities of growth above 0.5 kmol m^–3 NaCl.The mutant is unusual in that its abilities to synthesize glyceroland pump out Na⁺ and Cl^– do not appear to be impaired;volume changes in the hyperosmotic range also appear to be roughlythe same as in D. parva. The average cell volume of mutant cellsis reduced (206µm³ as opposed to 255 µm³ in D. parva)and their rate of change of cell volume after an increase insalt concentration is lower; it took about 10 min for mutantcells in the light to reach a new cell volume whereas D. parvacells reached their new volume in less than 1 min. Both factorsmay be dependent on components of the cytoskeleton. The mutantthrows light on adaptations necessary to allow Dunaliella cellsto grow at high salt concentrations and demonstrates that halotoleranceincludes, but is not equivalent to, osmoregulation. Key words: Dunaliella, salt tolerance, mutant