Growth rate, plant development and water relations of the ABA-deficient tomato mutant sitiens

Given the close relationship between a plant's growth rate and its pattern of biomass allocation and the effects of abscisic acid (ABA) on biomass allocation, we studied the influence of ABA on biomass allocation and growth rate of wildtype tomato ( Lycopersicon esculentum Mill. cv. Moneymaker) plants and their strongly ABA-deficient mutant sitiens. The relative growth rate of sitiens was 22% lower than that of the wildtype, as the result of a decreased specific leaf area. The net assimilation rate and the leaf weight ratio were not affected. The mutant showed a much higher transpiration rate and lower hydraulic conductance of the roots. These two factors resulted in sitiens having a significantly lower leaf water potential and turgor. resulting in reduced leaf expansion and, consequently, a lower specific leaf area relative to the wildtype. Addition of ABA to the sitiens roots resulted in phenotypic reversion to the wildtype. We conclude that the influence of ABA-deficiency on biomass allocation and relative growth rate is the result of altered water relations in the plants, rather than of a direct effect on sink strength of different plant organs.     

Phosphorylation of pollen proteins in relation to self-incompatibility in rye (Secale cereale L.)

The gametophytic two-locus self-incompatibility (SI) system in rye was investigated in view of a possible involvement of protein phosphorylation and Ca²⁺ as constituents of a signal transduction mechanism. Phosphorylation kinetics in pollen grains was found to be significantly different after in vitro treatment of pollen with either cross or self stigma proteins, with a pronounced phosphorylation activity in self-treated pollen grains. Loss of SI in self-compatible (SC) mutants was associated with a significantly decreased basic phosphorylation activity in untreated pollen grains as compared to SI genotypes. Separation of phosphorylated pollen proteins by SDS-PAGE reveals four major proteins in the MW range of 43–82 kDa which were differently phosphorylated in SI vs SC genotypes as well as in cross vs self-treated pollen grains. Application of different protein kinase inhibitors and the Ca²⁺ antagonists verapamil and La³⁺ to isolated stigmas resulted in an inhibition of the SI response in in vitro self-pollination. The role of protein kinases and Ca²⁺ as constituents of a putative SI-specific signal transduction mechanism is discussed.     

Genetic control of male fertility in Arabidopsis thaliana: structural analysis of premeiotic developmental mutants

We have taken a mutational approach to identify genes important for male fertility in Arabidopsis thaliana and have isolated a number of nuclear male/ sterile mutants in which vegetative growth and female fertility are not altered. Here we describe detailed developmental analyses of four mutants, each of which defines a complementation group and has a distinct developmental end point. All four mutants represent premeiotic developmental lesions. In ms3, tapetum and middle layer hypertrophy result in the degeneration of microsporocytes. In ms4, microspore dyads persist for most of anther development as a result of impaired meiotic division. In ms5, degeneration occurs in all anther cells at an early stage of development. In ms15, both the tapetum and microsporocytes degenerate early in anther development. Each of these mutants had shorter filaments and a greater number of inflorescences than congenic male-fertile plants. The differences in the developmental phenotypes of these mutants, together with the non-allelic nature of the mutations indicate that four different genes important for pollen development, have been identified.     

Chimeras for mutations induced in dormant tomato seeds

Genetic chimeras of the VFNT cherry tomato line (Lycopersicon esculentum) were produced by mutagenizing seeds with ethyl methane sulfonate (EMS). The chimeras thereby produced were evaluated by progeny-testing the fruits of the genetically mosaic tissue. A total of 2011 M₁ plants was grown from treated seeds and evaluated by screening their 95175 (M₂) progeny for mutations affecting seedling phenotype. Three vigorous and fertile M₁ plants bearing mutant progeny with definitive phenotypes were selected for systematic harvesting and analysis. The specific location of each fruit was noted at harvest time, enabling the mutated sporogenous tissue of the mosaic M₁ plants to be traced. Sectoring appeared in both branch and floral tissues. In several cases, mutant progenies were restricted to individual branches or parts thereof. True-breeding recessive mutants whose monogenic mode of inheritance was later established occasionally segregated within M₁ fruit progenies at frequencies that indicate a non-homogeneous floral meristem origin. The data emphasize the necessity of making a well-distributed harvest of mosaic plants in order to detect as many variants as possible, as mosaic sectors may or may not recur late in ontogeny and may not contribute to sporogenous tissue early in development.     

Construction of Mutant Genes for a Non-Toxic Verotoxin 2 Variant (VT2vp1) of Escherichia coli and Characterization of Purified Mutant Toxins

The gene encoding a Verotoxin 2 variant, VTvp1, was mutated by oligonucleotide-directed site-specific mutagenesis. Among 6 mutant toxins encoded by the mutated genes, E167Q-R170L (glutamic acid at position 167 and arginine at position 170 from N-terminus of the A subunit were replaced by glutamine and leucine, respectively) was found to have markedly decreased activities; inhibition of protein synthesis, Vero cell cytotoxicity and mouse lethality of the purified E167Q-R170L were 1/1,900, 1/125,000 and 1/2,000, respectively, of those of the purified wild-type VT2vp1. Since the antigenic property of the E167Q-R170L was demonstrated to be similar to that of the wild-type VT2vp1 by Ouchterlony double gel diffusion test and by neutralization test of Vero cell cytotoxicity of the VT2vp1, a possibility to use the mutant VT2vp1, E167Q-R170L, as a toxoid is discussed.     

A lack of locomotor activity rhythms inDrosophila melanogaster larvae (Diptera: Drosophilidae)

We examined the locomotor activity ofDrosophila melanogaster for the existence of circadian rhythms, using the wild type and two mutants of theperiod (per) gene,per ^o andper ^s. This was accomplished using a newly described apparatus for the recording and measurement of larval path lengths over a 96-h test period. None of the larvae examined exhibited appreciable diel rhythms under cycling conditions of light or temperature. Larvae were also not rhythmic under free-running conditions. Our results suggest that theper gene does not influence an observable locomotor behavioral phenotype in the larval stage of development.     

Round-cell mutants of Salmonella typhimurium produced by transposition mutagenesis: Lethality of rodA and mre mutations

Summary Thirty-three insertions of transposon Tn10l6l7 into genes involved in the control of rod cell shape were isolated in Salmonella typhimurium by the characteristic glossy appearance of colonies composed of spherical cells. Genetic tests demonstrated that 25 (76%) were insertions in the rodA gene, 7 (21 %) were mre mutants, and 1 (3%) was a divD mutant. No insertion in the pbpA gene were found. Insertions in cell shape genes only appeared when strains displaying resistance to mecillinam (not caused by -lactamase production) were employed. Neither rodA nor mre insertions could be transduced to wild-type strains but they were normally accepted by mecillinam-resistant derivatives and by cya and crp mutants, which, unlike the corresponding Escherichia coli strains, did not display resistance to mecillinam. On the other hand, the divD insertion could be efficiently transduced to any strain. It is concluded that the rodA, mre, and divD genes are involved in the control of rod cell shape but, in addition, the RodA and Mre products perform some function(s) that is essential for wild-type cells but dispensable for some mecillinam-resistant strains, and for cya and crp mutants.     

Suppression of mitochondrial alternative oxidase can result in upregulation of the ROS scavenging network: some possible mechanisms underlying the compensation effect

Mitochondrial alternative oxidase is an important protein involved in maintaining cellular metabolic and energy balance, especially under stress conditions. AOX genes knockout is aimed at revealing the functions of AOX genes. Under unfavourable conditions, AOX-suppressed plants (mainly based on Arabidopsis AOX1a-knockout lines) usually experience strong oxidative stress. However, a compensation effect, which consists of the absence of AOX1a leading to an increase in defence response mechanisms, concomitant with a decrease in ROS content, has also been demonstrated. This review briefly describes the possible mechanisms underlying the compensation effect upon the suppression of AOX1a. Information about mitochondrial retrograde regulation of AOX is given. The importance of ROS and mitochondrial membrane potential in triggering the signal transmission from mitochondria in the absence of AOX or disturbance of mitochondrial electron transport chain functions is indicated. The few available data on the response of the cell to the absence of AOX at the level of changes in the hormonal balance and the reactions of chloroplasts are presented. The decrease in the relative amount of reduced ascorbate at stable ROS levels as a result of compensation in AOX1a-suppressed plants is proposed as a sign of stress development. Obtaining direct evidence on the mechanisms and signalling pathways involved in AOX modulation in the genome should facilitate a deeper understanding of the role of AOX in the integration of cellular signalling pathways.     

Crevice-forming mutants in the rigid core of bovine pancreatic trypsin inhibitor: crystal structures of F22A, Y23A, N43G, and F45A.

Crystal structures of four mutants of bovine pancreatic trypsin inhibitor (F22A, Y23A, N43G, and F45A), engineered to alter their stability properties, have been determined. The mutated residues, which are highly conserved among Kunitz-type inhibitors, are located in the rigid core of the molecule. Replacement of the partially buried bulky residues of the wild-type protein with smaller residues resulted in crevices open to the exterior of the molecule. The overall three-dimensional structure of these mutants is very similar to that of the wild-type protein and only small rearrangements are observed among the atoms lining the crevices.     

Mutational tests of the NMR-docked structure of the staphylococcal nuclease–metal–3′,5′-pdTp complex

In the X-ray structure of the staphylococcal nuclease–Ca²⁺ ?3′,5′-pdTp complex, the conformation of the inhibitor 3′,5′-pdTp is distroteed Lys-70* and Lys-71* from an adjacent molecule of staphylococcal nuclease (Loll, P.J., Lattman, E.E. Proteins 5 : 183-201, 1989). In order to correct this crystal packing problem, the solution conformation of enzyme-bound 3′,5′-pdTp in the staphylococcal nuclease–metal–pdTp Complex determined by NMR methods was docked into the X-ray structure of the enzyme [Weber, D. J., Serpersu, E. H., Gittis, A. G., Lattman, E. E., Mildvan, A. S. (preceding paper)]. In the NMR-docked structure, the 5′-phophate of 3′,5′-pdTp overlaps with that in the X-ray Structure. However the 3′-phosphate accepts a hydrogen bond from Lys-49 (2.89Å) rather than from Lys-84 (8.63 Å), and N3 of thymine donates a hydrogen bond to the OH of Tyr-115 (3.16 Å) which does not occur in the X-ray structure (5.28 Å). These interactions have been tested by binding studies of 3′,5′-pdTp, Ca²⁺, and Mn²⁺ to the K49A, K84A, and Y115A mutants of staphylococcal nuclease using water proton relaxation rate and EPR methods. Each mutant was fully active and structurally intact, as found by CD and two-dimensional NMR spectroscopy, but bound Ca²⁺ 9.1- to 9.9-fold more weakly than the wild-type enzyme. While thye K84A mutation did not significantly weaken 3′,5′-pdTp binding to the enzyme (1.5 ± 0.7 fold), the K49A mutation weakened 3′,5′-pdTp binding to the enzyme by the factor of 4.4 ± 1.8-fold. Similarly, the Y115A mutation weakened 3′,5′-pdTp binding to the enzyme 3.6 ± 1.6-fold. Comparable weakening effects of these mutations were found on the binding of Ca²⁺-3′,5′-pdTp. These results are more readily explained by the NMR-docked structure of staphylococcal nuclease-metal-3′,5′-pdTp than by the X-ray structure. © 1993 Wiley-Liss, Inc.