A biomechanical model of anther opening reveals the roles of dehydration and secondary thickening.

Understanding the processes that underlie pollen release is a prime target for controlling fertility to enable selective breeding and the efficient production of hybrid crops. Pollen release requires anther opening, which involves changes in the biomechanical properties of the anther wall. In this research, we develop and use a mathematical model to understand how these biomechanical processes lead to anther opening. Our mathematical model describing the biomechanics of anther opening incorporates the bilayer structure of the mature anther wall, which comprises the outer epidermal cell layer, whose turgor pressure is related to its hydration, and the endothecial layer, whose walls contain helical secondary thickening, which resists stretching and bending. The model describes how epidermal dehydration, in association with the thickened endothecial layer, creates forces within the anther wall causing it to bend outwards, resulting in anther opening and pollen release. The model demonstrates that epidermal dehydration can drive anther opening, and suggests why endothecial secondary thickening is essential for this process (explaining the phenotypes presented in the myb26 and nst1nst2 mutants). The research hypothesizes and demonstrates a biomechanical mechanism for anther opening, which appears to be conserved in many other biological situations where tissue movement occurs.

The Arabidopsis MALE STERILITY1 (MS1) gene is a transcriptional regulator of male gametogenesis, with homology to the PHD-finger family of transcription factors.

We report here the molecular characterisation of the Arabidopsis MALE STERILITY1 gene, which is a critical sporophytic controlling factor for anther and pollen development. Homozygous ms1 mutants do not produce viable pollen, but are otherwise phenotypically normal. Degeneration of pollen occurs soon after microspore release from the tetrads, at which time the tapetum also appears abnormally vacuolated. The MS1 gene is expressed at low levels in anthers from closed buds, with expression in the tapetum at the stage of microspore release. No expression is seen in open flowers. The deduced MS1 protein sequence shows strong homology to the PHD-finger motif found in known transcription factors from humans, yeast and higher plants. Six alleles of ms1 have been identified; all result in premature termination of the MS1 protein and loss of the PHD-finger motif. MS1 is likely to play a key role in regulating transcription during specific stages of male gametogenesis and anther development. As such, MS1 provides a valuable tool for the manipulation of male sterility in higher plants.

Arabidopsis YAC restriction mapping.

The approach of partial restriction mapping and vector hybridisation has been used to restriction map and align six yeast artificial chromosomes (YACs) corresponding to the top arm (approximately 27.9 centiMorgans, cM) of Arabidopsis chromosome 5 and confirm the chimeric nature of a further four clones which map to this region. The restriction endonucleases Sma1 and Sfi1 which recognise rare-medium frequency sites in the Arabidopsis genome were used. This work has restriction mapped a 315 kb region that includes a number of genes implicated in floral development, namely PISTILLATA and TOUSLED, and a number of uncharacterized genes involved in male gametogenesis (e.g., Ms1 and Ms37). The information generated can be used to transcriptionally map genes to this contig and will provide data for the isolation of several uncharacterized floral development genes which lie in this region. This approach has demonstrated how large tracts of YAC DNA can be mapped and aligned to show the presence/absence of chimeric YAC clones and provide detailed restriction knowledge for a large genomic region to help facilitate the positional cloning of genes.

The Arabidopsis MALE STERILITY 2 protein shares similarity with reductases in elongation/condensation complexes.

The Arabidopsis thaliana MALE STERILITY 2 (MS2) gene product is involved in male gametogenesis. The first abnormalities in pollen development of ms2 mutants are seen at the stage in microsporogenesis when microspores are released from tetrads. Expression of the MS2 gene is observed in tapetum of wild-type flowers at, and shortly after, the release of microspores from tetrads. The MS2 promoter controls GUS expression at a comparable stage in the tapetum of transgenic tobacco containing an MS2 promoter-GUS fusion. The occasional pollen grains produced by mutant ms2 plants have very thin pollen walls. They are also sensitive to acetolysis treatment, which is a test for the presence of an exine layer. The MS2 gene product shows sequence similarity to a jojoba protein that converts wax fatty acids to fatty alcohols. A possible function of the MS2 protein as a fatty acyl reductase in the formation of pollen wall substances is discussed.

Fine-scale molecular genetic (RFLP) and physical mapping of a 8.9 cM region on the top arm of Arabidopsis chromosome 5 encompassing the male sterility gene, ms1.

Fine-scale molecular mapping has been conducted using 183 recombinants between the markers lutescens (lu; 17.6 cM) and transparent testa glabra (ttg; 35.5 cM) on the top arm of Arabidopsis thaliana chromosome 5. This region contains a number of genes involved in floral development including Ms1, a gene required for the post-meiotic development of pollen. In homozygous ms1 mutant plants, pollen development is aborted soon after microspore release, regardless of environmental conditions. The ms1 mutation is located at 29.8 +/- 0.8 cM on chromosome 5. Markers have been identified which co-segregate with ms1 and should lie within 39 kb of the gene. The fine-scale map of the lu-ms1-ttg region that has been generated is significantly different from the published integrated map and provides substantially more accurate and higher marker density than the current recombinant inbred map for this region. Using clones derived from four yeast artificial chromosome libraries, a contig has been established between the RFLP markers 4111 and 4556, which encompasses the ms1 gene. This covers a genetic distance of 8.9 cM which corresponds to a physical distance of approximately 1.44 Mb, representing about 1.5-2.0% of the Arabidopsis genome. In this region, 1 cM represents a physical distance of approximately 160 kb.

Isolation of deficiencies in the Arabidopsis genome by gamma-irradiation of pollen.

Chromosomal deficiencies are a useful genetic tool in fine-scale genetic mapping and the integration of physical and visible marker genetic maps. Viable overlapping deficiencies may permit gene cloning by subtractive procedures and provide a means of analyzing the functional importance of different chromosomal regions. A method is described for isolation of deficiencies in the Arabidopsis genome which encompass specific loci and other extended chromosomal regions. The technique employs pollen mutagenized by gamma-irradiation to pollinate marker lines homozygous for recessive mutations. Deficiencies at specific loci were detected by screening for marker phenotypes in the F1. Screening for lethal mutations in the F1/F2 confirmed specific deficiencies and revealed other deficiencies that did not overlap the marker loci. Further evidence for such mutations was provided by distorted F2 segregation of the chromosomal markers linked to putative deficiencies. Maintainable (transmissible) and non-transmissible deficiencies were demonstrated by their pattern of inheritance in subsequent generations.

DNA fingerprinting of Peronospora parasitica, a biotrophic fungal pathogen of crucifers.

The fungus Peronospora parasitica (Pers. ex Fr.) Fr. is an obligate biotroph infecting a wide range of host species in the family Cruciferae. Isolates from different hosts are morphologically similar, and pathotypes are usually distinguished on the basis of host range. Random Amplified Polymorphic DNA (RAPD) fingerprints were generated from a range of P. parasitica isolates from different Brassica species. Reaction conditions, in particular DNA template, primer and Mg(2+) concentrations, were optimized to ensure that amplifications were reproducible. Possible artefacts arising through host plant DNA were assessed by including such DNA in control reactions. Confirmation that diagnostic RAPD bands were generated from fungal DNA was also obtained by Southern hybridization of a RAPD band to genomic fungal DNA. By screening 20 decamer primers, 2 were found to detect sufficient genetic variation to allow complete differentiation between pathotypes. These results illustrate the potential value of RAPDs for detecting polymorphisms between isolates of a non-culturable plant pathogenic fungus.

Elimination of systemic contamination in explant and protoplast cultures of rubber (Hevea brasiliensis Muell. Arg.).

Ten systemic microorganisms (bacteria and yeasts) were isolated from stem sections of ex vitro grown rubber plants. Antibiotics were screened for their efficacy against these microorganisms and for possible tissue phytotoxicity. Erythromycin, nystatin and streptomycin at bactericidal levels were asymptomatic in relation to tissue stress nor was callusing capacity reduced. Contamination of stem explants as used for callus initiation, was reduced from 95.8 to 43.8% by the incorporation of these three antibiotics, at concentrations of 32.0, 16.0, 16.0 µg/ml respectively. Contamination was eliminated from protoplast cultures by these antibiotics, at half strength, in the plasmolysis and enzyme solutions. Rubber protoplast survival was promoted by these antibiotics.