Cytoplasmic male sterility in the olive (Olea europaea L.)

The olive tree is usually hermaphrodite but self-incompatible. In the Western Mediterranean some cultivars are totally male-sterile. Three different male-sterile phenotypes have been recognised. To infer the genetic basis of male sterility we studied its inheritance and cytoplasmic diversity in wild (oleaster) and cultivated Mediterranean olive. In the cross Olivière×Arbequina, the male-sterile trait was maternally inherited and affected all progenies. We also checked that both chloroplast and mitochondrial DNAs are maternally inherited. RFLP studies on chloroplast and mitochondrial DNAs revealed several cytotypes: two chlorotypes and four mitotypes in cultivars and oleaster (wild or feral Mediterranean olive). Furthermore, a total linkage desequilibrium between the CCK chlorotype and the MCK mitotype in cultivars and oleaster from different regions supports the fact that paternal leakage of organelles was not observed. The male sterility (ms 2) displayed by Olivière, plus six other cultivars and three oleaster was strictly associated with the CCK chlorotype and the MCK mitotype. These facts suggest that Olivière carries cytoplasmic male sterility. Male-fertile and male-sterile oleasters carrying this cytotype showed the presence of restorer alleles. This CMS might be due to a distant cross between olive taxa. The two other male-sterile phenotypes displayed by Lucques (ms 1) and Tanche (ms 3) were associated with the ME1 mitotype but we have not demonstrated CMS. Received: 26 July 1999 / Accepted: 27 August 1999     

Two new male-sterile mutants of Zea mays (Poaceae) with abnormal tapetal cell morphology

Two new recessive male-sterile mutants of Zea mays (Poaceae), or maize, were studied to identify the timing of pollen abortion and to examine the involvement of anther wall cell layers. The results of test crosses indicated that these mutants were not allelic with any known male-sterile mutants of maize. Light and transmission electron microscopy were used to compare pollen development in homozygous male-sterile mutants to that in fertile heterozygous siblings. In both mutants, microspores abort soon after release from the meiotic tetrad. However, the two mutations have strikingly different phenotypes. Large lipid bodies accumulate in the tapetal cells as the microspores vacuolate and die in the mutant ms25. Large vacuoles appear in both the tapetal cells and the young microspores as they begin to disintegrate in the mutant ms26. Because abnormal tapetal cell morphology is detected in both mutants, it is possible that both of these mutations affect the expression of genes in tapetal cells.     

Fusion of male-sterile tobacco causes modifications of mtDNA leading to changes in floral morphology and restoration of fertility in cybrid plants

Protoplasts from male-sterile Nicotiana tabacum cultivars with cytoplasms of N. suaveolens, N. bigelovii and N. undulata were fused in different pairwise combinations. Cybrid plants were obtained and categorized according to their flower morphologies into groups as parental male-sterile types, recombined biparentals, novel male-steriles and male fertiles. Restriction enzyme analyses and DNA gel blot hybridizations of the mitochondrial DNA (mtDNA) of these cybrid plants revealed that all plants with parental male-sterile morphologies had banding patterns identical to the parental patterns, whereas all cybrids with flower morphologies different from their parents had novel patterns. Several restriction fragments were found to be unique to the mtDNA of male-fertile plants with perfectly restored stamen morphologies when compared to the mtDNA from cybrid plants with incomplete restoration. MtDNA gel blot hybridization analysis of fertile plants revealed that the probe for atpA hybridized to two restriction fragments, one from each parent. Further, fertile plants with complete stamen restoration lacked an expressed sequence in the 3'flanking region of atpA , in contrast to both male-sterile parents.     

Modifications of Mitochondrial DNA Cause Changes in Floral Development in Homeotic-like Mutants of Tobacco

To investigate the influence of mitochondrial genes on stamen development of higher plants, protoplasts from three different, male-sterile tobacco cultivars were fused. The fused cells were cultured individually into calli, from which plants were regenerated. Cybrid plants were obtained that exhibited flowers with recombined biparental male-sterile morphology and with novel male-sterile stamens that differed from any types from sexual or somatic hybridizations described previously. The male-sterile morphologies of these cybrids and their parents support the hypothesis that nuclear-mitochondrial interaction occurs at several stages in tobacco floral development and that several mitochondrial genes are necessary for normal stamen and corolla development. Analysis by restriction endonuclease digestion of mitochondrial DNA of male-sterile cybrids and their parents revealed that the mitochondrial DNA of male-sterile cybrids with parental floral morphology was unchanged when compared with parental mitochondrial DNA. Cybrids that were morphologically similar to one parent's male-sterile phenotype had mitochondrial DNA almost identical to that parent, whereas cybrids with recombined biparental or novel male-sterile phenotypes contained mitochondrial DNA different from both male-sterile parents and from each other. A set of mitochondrial DNA fragments could be correlated with split corollas, a feature found in several tobacco male-sterile cultivars. DNA gel blot analysis using a number of mitochondrial genes confirmed the conclusions based on ethidium bromide staining of mitochondrial DNA restriction digests.     

Linkage between an isozyme marker and a restorer gene in radish cytoplasmic male sterility of rapeseed (Brassica napus L.)

Summary Co-segregation studies of isozyme markers and male fertility restoration showed that a restorer gene from radish was introduced into rapeseed along with an isozyme marker (Pgi-2). The radish chromosome segment carrying these genes was introgressed into rapeseed through homoeologous recombination, substituting for some of the rapeseed alleles. By crossing heterozygous restored plants to male-sterile lines and to maintainers, tight linkage was found between the restorer gene and the marker. The recombination fraction was estimated at 0.25 ± 0.02%. Although few restored plants lacked the radish isozyme marker, it was still possible to distinguish male-fertile from male-sterile plants by their PGI-2 patterns. Furthermore, homozygous and heterozygous restored plants could be separated by specific PGI-2 phenotypes. Thus, the Pgi-2 marker is now currently used in restorer breeding programs.     

Ontogenetic origin of mermithogenic Myrmica phenotypes (Hymenoptera, Formicidae)

Entomo-pathogen parasites typically induce alternative ”parasitogenic” phenotypes in ants and other insects. However, the basis of generated developmental changes is poorly understood. Parasitic mermithid nematodes also cause the formation of three discrete and aberrant morphologies within Myrmica ants. These have been called ”worker-like” (”mermithergate”), ”intermorphic” (”gynaecoid mermithergate”) and ”gyne-like” (”mermithogyne”) and their formation has been attributed to infection of worker- and queen-presumptive larvae, respectively. In order to better understand the developmental mechanisms that lead to the formation of these alternative parasitogenic phenotypes we observed allometric patterns of parasitogenic Myrmica gallienii phenotypes in comparison with uninfected workers and gynes from the same nests. It was revealed that the three discrete morphologies of parasitogenic female phenotypes did not differ significantly from each other in their scaling indicating that these were trapped in the same developmental pathway. Infected individuals scaled according to basically gyne-like allometry, however significantly differed from workers in their scaling. Based on the observed scaling patterns we herein raise an alternative explanation according to which both ”mermithergate”, ”gynaecoid mermithergate” and ”mermithogyne” Myrmica phenotypes develop from the same type of larvae, namely from the queen-presumptive larvae and their formation, therefore, is rendered as a diverging process. According to the mechanism we propose effect of nematodes may turn out to be the determining factor in the formation of alternative parasitogenic morphologies. Received 16 June 2008; revised 15 September and 7 November 2008; accepted 18 November 2008.     

Analyses of mitochondrial DNA structure and expression in three cytoplasmic male-sterile chicories originating from somatic hybridisation between fertile chicory and CMS sunflower protoplasts

Cytoplasmic male-sterile (CMS) chicories have been previously obtained by somatic hybridisation between fertile industrial chicory protoplasts and CMS sunflower protoplasts. In this study, we compared three different CMS chicory cybrids that originated from three different fusion events. The cybrids were backcrossed with different witloof chicories in order to transfer the three male-sterile cytoplasms from an industrial chicory nuclear environment to a witloof chicory nuclear context. Southern hybridisation, using different mitochondrial genes as probes, revealed that the three cybrid mitochondrial genomes were different and that they were stable throughout backcrossing generations regardless of the pollinator. However, pollinators were found to influence floral morphologies – with one being able to restore fertility – showing that nuclear context can affect the sterility of the cybrids. PCR and RFLP analyses revealed that the orf522 sequence, responsiblefor CMS in PET1 sunflower, was present in two out of the three cytoplasms studied, namely 411 and 523, but was absent from the other cytoplasm, 524. We thus concluded that orf522 is not responsible for CMS in the 524 cybrid. Although the orf522 gene is present in the 411 and 523 cytoplasms, it is probably not responsible for the sterile phenotype of these cybrids. Received: 3 June 1998 / Accepted: 30 April 1999     

Loss of CMS-specific mitochondrial DNA arrangement in fertile segregants of Petunia hybrids

The progeny of somatic hybrid Petunia plants derived from the fusion of a male-fertile line and a cytoplasmic male-sterile (cms) line were examined. Male-fertile progeny derived from three different male-sterile somatic hybrid plants did not exhibit the mitochondrial DNA (mtDNA) arrangement which has previously been correlated with cms in Petunia. The cms-associated mtDNA arrangement was present in the male-sterile predecessors of these fertile revertants. Thus, it is concluded that the loss of this mtDNA arrangement is associated with reversion to fertility in the progeny of the unstable somatic hybrid petunia plants.     

Genetics and cytology of a new genic male-sterile soybean [Glycine max (L.) Merr.]

 Genetic and cytological studies were conducted with a new male-sterile, female-fertile soybean [Glycine max (L.) Merr.] mutant. This mutant was completely male sterile and was inherited as a single-recessive gene. No differences in female or male gamete transmission of the recessive allele were observed between reciprocal cross-pollinations in the F₁ or F₂ generations. This mutant was not allelic to any previously identified soybean genic male-sterile mutants: ms1, ms2, ms3, ms4, ms5, or ms6. No linkage was detected between sterility and flower color (W1 locus), or between sterility and pubescence color (T1 locus). Light microscopic and cytological observations of microsporogenesis in fertile and sterile anthers were conducted. The structure of microspore mother cells (MMC) in male-sterile plants was identical to the MMCs in male-fertile plants. Enzyme extraction analyses showed that there was no callase activity in male-sterile anthers, and this suggests that sterility was caused by retention of the callose walls, which normally are degraded around tetrads at the late tetrad stage. The tapetum from male-sterile anthers also showed abnormalities at the tetrad stage and later stages, which were expressed by an unusual formation of vacuoles, and by accumulation of densely staining material. At maturity, anthers from sterile plants were devoid of pollen grains. Received: 13 May 1996 / Revision accepted: 19 August 1996     

Characterization of sexual progenies of male-sterile somatic cybrids between Brassica napus and Brassica tournefortii

Cytogenetic studies were performed on four male-sterile progenies derived from four different cybrids produced between Brassica napus and B. tournefortii using the donor-recipient protoplast fusion method. The objective of these studies was to characterize the nuclear constitution of the plants. Mitotic investigation revealed that three of the four male-sterile lines had 38 chromosomes, which is equal to that of B. napus. The fourth line, C6, had variable chromosome numbers, ranging from 39 to 42 in different plants. The meiotic behavior in each progeny varied distinctly. Of the plants having 38 chromosomes, fairly high chromosome pairing, on average 18.08 bivalents per cell, was detected at metaphase-I. However, univalents with an average of 1.39 per cell, and very low frequencies of trivalents and/or tetravalents, were also observed in the lines. These results revealed that male-sterile cybrid lines were obtained with 38 chromosomes and a relatively high level of chromosome-pairing ability, indicating their potential for establishing a stable male-sterile rapeseed line. Received:15 December 1998 / Accepted:30 January 1999     

Construction of backcrossedGelidium male-sterile and male-fertile lines and their growth comparison

The male sterility gene from a male-sterile, green,Gelidium vagum line was introduced to a wild-type line through repeated backcrossing and selection for five generations. The plants from the recurrent parent, the male-sterile green, the backcross-5 fertile and the backcross-5 male-sterile lines were compared for their growth performance. The backcross-5, red, male-sterile plants grew at a significantly higher rate than the plants from other lines, suggesting that male-sterile gametophytes would likely be better candidates for aquaculture than normal wild-type plants of this species. This study also provides evidence that the growth rate ofG. vagum decreases as a consequence of reproduction.     

水稻不育系261S矮化突变体及其F_1‘新闵优香粳’杂交稻的性状分析

以两系杂交稻'闵优香粳'品种的父本W香99075和母本不育系261S及其261S矮化突变株系为材料,对两种母本及其F1植株分别进行形态特征、产量和F2稻米品质比较分析,以明确不育系261S矮化突变株系的育种应用价值.结果显示:(1)不育系261S矮化突变株系与原不育系261S相比,花粉不育性相似,株高、穗长、千粒重分别极显著降低13.8 cm、4.5 cm、5.2 g,但有效穗比原不育系261S极显著增加62.8%;(2)261S矮化突变株系×W香99075组合的F1"新闵优香粳"植株高度较'闵优香粳'极显著降低11 cm,而单株产量两者差异不显著;(3)两组合F2稻米胶稠度和碱消值几乎没有变化,但"新闵优香粳" 比'闵优香粳'的蛋白质含量提高9.57%、直链淀粉含量极显著降低10.17%,稻米品质较优.研究表明,以植株较矮、分蘖性较强、单株有效穗多的261S矮化突变株系为母本与W香99075杂交,可在不影响杂交稻产量表现的基础上有效降低原品种'闵优香粳'植株的高度,同时稻米品质也得到改善;说明261S矮化突变株系可作为水稻两系杂交育种的新不育系材料.     

FLP/FRT-mediated restoration of normal phenotypes and clonal sectors formation in rolC transgenic tobacco

Site-specific recombination systems have been shown to excise transgene DNA sequences positioned between their cognate target sites, and thus be used to generate clonal sectors in transgenic plants. Here we characterized clonal sectors derived from genetic reversion of rolC (A. rhizogenes) – induced vegetative and reproductive phenotypes, mediated by FLP recombinase from S. cerevisiae, in tobacco. The constitutive expression of rolC induces pleiotropic effects including reduced apical dominance and plant height, lanceolate and pale green leaves and small, male-sterile flowers. Two transgenic male-sterile tobacco lines (N. tabacum, Samsun NN) expressing a 35sP-rolC gene construct flanked by two FRT (FLP recombinase target) sites, were cross-pollinated with pollen from a constitutive 35sP-FLP expressing line. Three main phenotypes were generated in result of recombinase-mediated excision of the 35sP-rolC locus in the F₁ (FLP×FRT-35sP-rolC-FRT) hybrid progenies: (a) restoration of male fertility, associated with reversion to normal leaf phenotypes prior to flower bud formation, (b) development of normal and fertile lateral shoot sectors on the background of rolC-type plants, (c) restoration of partially fertile flowers, associated with display of peripheral normal leaf sectors surrounding rolC-type inner-leaf tissues, consistent with periclinal chimeras. These results, supported by DNA molecular analysis, indicate that site-specific recombination might be used as a relatively efficient tool for generation of transgenic periclinal chimeric plants.     

Chloroplast ultrastructure and fluorescence response of oilseed rape containing male-sterile radish cytoplasm

Summary The production of hybrid seed is facilitated if one parent possesses a male-sterile cytoplasm. Introduction of the cytoplasm of male-sterile radish (Raphanus sativus L.) into rapeseed (Brassica napus L.) results not only in transfer of the desirable male-sterile trait but induces a chlorophyll defect in the backcrossed male-sterile plants. In this study we show that the defect manifests itself in two different ways in the alloplasmic plants: a) smaller and fewer chloroplasts with an impaired ultrastructure and b) an increase in chlorophyll fluorescence. Defective chloroplasts were characterized by a reduction in both the number and size of grana, the latter due to poor stacking of thylakoids and with frequent discontinuity in the intergranal thylakoid systems. The changed chloroplast morphology and the increase in chlorophyll fluorescence are probably the cause of the lowered photosynthetic efficiency associated with the alloplasmic plants. We propose that the deficiency is the result of incompatibility between the genomes of the radish chloroplast and the rapeseed nucleus. Supporting this hypothesis are studies of male-sterile rapeseed plants in which, by protoplast fusion, the radish chloroplasts were substituted by those of normal male-fertile rapeseed. Such plants showed complete restoration of their photosynthetic potential and displayed both normal chloroplast ultrastructure and normal levels of chlorophyll fluorescence.     

<Emphasis Type="Italic">Multiple impairments in male reproduction 1 (mimr1)</Emphasis>, a novel male-sterile mutant of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>, shows several defects in male reproductive development

We have characterized a new male-sterile mutant in Arabidopsis that exhibits conditional sterility but has restored fertility when drought-stressed. This mutant, multiple impairments in male reproduction 1 (mimr1), shows pleiotropic defects in both vegetative and reproductive development. Examination with dissecting and scanning electron microscopes revealed that its pollen grains are not effectively released from the anther locule after dehiscence, and anther differentiation is defective. Growth of the style and stamen filaments are also abnormal. Histological analysis demonstrated that these phenomena are due not only to a noticeably reduced extension of the stamen but also greater elongation of the pistil. Genetic analysis indicated that mimr1 is a single locus recessive nuclear mutant. The mutation can be mapped to a locus strongly linked to a 1200-kb region on Chromosome 3. Meta-analysis of expression patterning presented several candidate genes in that region. No mutants with similar phenotypes have previously been reported, suggesting that mimr1 is a novel male-sterile locus. Characterization of MIMR1 will provide further insights into the molecular basis for the development of plant reproductive organs.     

The use of a Spacer DNA fragment insulates the tissue-specific expression of a cytotoxic gene (barnase) and allows high-frequency generation of transgenic male sterile lines in Brassica juncea L.

Male-sterile lines were generated in oilseed mustard (Brassica juncea) with a cytotoxic gene (barnase) in conjunction with either of two tapetum-specific promoters, TA29 and A9. Several transformation vectors based on different promoter and marker gene combinations were developed and tested for their efficacy in generating agronomically viable male-sterile lines. Use of strong constitutive promoters (e.g. CaMV 35S or its double-enhancer variant) to express the marker gene (bar) in barnase constructs generated male-sterile plants at an extremely low frequency with most plants showing abnormalities in vegetative morphology, poor female fertility, low seed germination frequencies and/or distortion in segregation ratios of transgenes. Such abnormalities were considerably reduced on using weaker promoters (e.g. nos) to drive the marker gene (nptII) in barnase constructs and could therefore be attributed to leaky expression of the barnase gene under enhancing effects of strong constitutive promoters. We show that the use of a Spacer DNA fragment between the barnase gene (driven by a tapetum-specific promoter) and the CaMV 35S promoter-driven bar gene insulates tissue-specific expression of the barnase gene over all developmental stages of transgenic plants and significantly enhances recovery of agronomically viable male-sterile lines. All TA29-barnase male-sterile lines containing the Spacer DNA fragment exhibited normal morphology, growth and seed set on backcrossing as observed for wild-type plants. Around 75% of single-copy events tested further also showed proper segregation of the marker gene/male-sterile phenotype among backcross progeny. Constructs based on the use of Spacer DNA fragments as insulators could be successfully used to alleviate limitations associated with transformation of plant systems using cytotoxic genes for development of agronomically viable male-sterile lines in crop plants and for cell/tissue ablation studies in general.     

Relationship of phenotypic and genetic variation in Plantago lanceolata to disease caused by Fusarium moniliforme var. subglutinans

Summary Naturally established individuals of Plantago lanceolata with the inflorescence disease caused by Fusarium moniliforme var. subglutinans had more inflorescences and were more likely to be male-sterile than healthy plants. Half-sib families planted in the field varied in the percentage of diseased plants, the number of inflorescences per plant, the incidence of male-sterility, and the pattern of inflorescence phenology. The rankings of families with respect to disease incidence was, however, not simply related to their reproductive phenotypes. Plants derived from field genotypes with a history of disease were slightly more likely to become diseased than plants derived from healthy genotypes. Inflorescence infection was more severe on plants derived from genotypes with a known history of disease. Since the fungus reduces seed production in the plants it infects, differential incidence of disease based on plant phenotype and genotype may have ecological and evolutionary consequences for the host population.     

Correction of chlorophyll-defective male-sterile winter oilseed rape (Brassica napus) through organelle exchange: molecular analysis of the cytoplasm of parental lines and corrected progeny

Summary Cytoplasmic differences between male-fertile and male-sterile Brassica napus as well as Raphanus sativus were investigated. Plastids of the male-fertile B. napus were found to differ from those of male-sterile B. napus and R. sativus with respect to DNA restriction enzyme patterns. Differences between male-fertile and male-sterile B. napus mitochondria were detected not only in the restriction fragment patterns of their DNA, but also at the level of expression by in organello translation of mitochondrial polypeptides.The chlorophyll deficiency obtained upon transferral of the male-sterility-conferring radish cytoplasm to a winter variety of B. napus had been corrected earlier through protoplast fusion. The cytoplasmic composition of the corrected lines was analysed using DNA restriction analysis and in organello translation. The stability of the recombined cytoplasm in the corrected lines was confirmed by analysis of the subsequent seed-derived generation.