Characterization of mutations that feminize gametophytes of the fern Ceratopteris.

Gametophytes of the fern Ceratopteris are either male or hermaphroditic. Their sex is epigenetically determined by the pheromone antheridiogen, which is secreted by the hermaphrodite and induces male and represses female development in other young, sexually undetermined gametophytes. To understand how antheridiogen represses the development of female traits at the genetic level, 16 new mutations that feminize the gametophyte in the presence of antheridiogen were identified and characterized. Seven are very tightly linked to the FEM1 locus previously described. Nine others define another locus named NOTCHLESS1 (NOT1), as several of the not1 mutants lack a meristem notch. Some not1 mutations also affect sporophyte development only when homozygous, indicating that the not1 mutations are recessive and that NOT1 is also required for normal sporophyte development. The epistatic interactions among FEM1, NOT1, and other sex-determining genes are described. This information was used to expand the genetic model of the sex-determining pathway in Ceratopteris. On the basis of this model, we can say that the presence of antheridiogen leads to the activation of the FEM1 gene, which not only promotes the differentiation of male traits, but also represses female development by activating the NOT1 gene. NOT1 represses the TRA genes necessary for the development of female traits in the gametophyte.     

蕨类植物性别分化对环境的响应

蕨类植物是维管植物中唯一的孢子体和配子体都能独立生活的类群.同型孢子蕨类配子体的性别分化受到激素和环境因子的影响.生理学研究表明,成精子囊素与赤霉素能诱导雄配子体发育,抑制雌配子体发育;脱落酸阻止成精子囊素诱导的精子器形成;乙烯合成前体ACC促进赤霉素诱导的精子器形成,而乙烯合成抑制因子AOA通过抑制细胞分化来抑制精子器形成.光照对不同种类蕨类配子体分化的影响存在差异.糖类能够促进雄配子体形成,并可加速成熟雌配子体向两性分化.钙离子、钴离子和甲硫氨酸等分别参与了蓝光和赤霉素对配子体性别分化的调控过程.培养密度影响配子体生长及性别表达,高密度下雄性和无性配子体居多,而低密度下两性和雌性配子体居多.近年来的突变体表型分析与分子生物学研究表明,成精子囊素通过影响ANI1、HER、TRA、FEM和MAN等基因的表达调控配子体性别分化.综述了蕨类植物性别分化对环境响应的研究进展.     

Generating Autotetraploid Sporophytes and Their Use in Analyzing Mutations Affecting Gametophyte Development in the Fern Ceratopteris

The haploid gametophytes of the fern Ceratopteris richardii are autotrophic and develop independently of the diploid sporophyte plant. While haploid genetics is useful for screening and characterizing mutations affecting gametophyte development in Ceratopteris, it is difficult to assess whether a gametophytic mutation is dominant or recessive or to determine allelism by complementation analysis in a haploid organism. This report describes how apospory can be used to produce genetically marked polyploid sporophytes whose gametophyte progeny are heterozygous for mutations affecting sex determination in the gametophyte and a known recessive mutation affecting the phenotype of both the gametophyte and sporophyte. The segregation ratios of wild-type to mutant phenotypes in the gametophyte progeny of polyploid sporophyte plants indicate that all of the mutations examined are recessive. The presence of many multivalents and few univalents in meiotic chromosome preparations of spore mother cells confirm that the sporophyte plants assayed are polyploid. The DNA content of the sperm of their progeny gametophytes was also found to be approximately twice that of sperm from wild-type haploid gametophytes.     

同形鳞毛蕨成精子囊素系统的初步研究

研究了同形鳞毛蕨成精子囊素对该种和水蕨孢子萌发和配子体发育的影响,结果表明：同形鳞毛蕨配子体能产生成精子囊素,该成精子囊素能抑制同种孢子的萌发,抑制作用随配子体成熟度的增加而增强;同形鳞毛蕨成精子囊素还可促进同种孢子发育为雄配子体;光照条件下,同形鳞毛蕨成精子囊素对水蕨孢子萌发和配子体发育影响不大,黑暗条件下,同形鳞毛蕨成精子囊素能显著的促使水蕨孢子提早萌发,但都不影响其孢子最终萌发率和配子体的性别分化,表明同形鳞毛蕨和水蕨的成精子囊素不属于同一系统。     

狭眼凤尾蕨配子体发育及其成精子囊素对水蕨配子体发育的影响

对狭眼凤尾蕨（Pteris biaurita）配子体发育特征及其外源成精子囊素对模式植物水蕨（Ceratopteris thalictroides）在黑暗和光照条件下孢子萌发和配子体发育的影响进行了研究。结果表明：（1）狭眼凤尾蕨孢子深褐色,三裂缝,孢子萌发为书带蕨型,原叶体发育为水蕨型,无毛状体产生;培养发现,其配子体能产生精子器,但不产生颈卵器,当接种密度适中时,可进行无配子生殖。（2）在光照和黑暗条件下狭眼凤尾蕨成精子囊素有促进和抑制水蕨孢子萌发的作用,但效果均不显著。（3）在光照条件下,狭眼凤尾蕨成精子囊素可以延迟水蕨心脏形配子体分生组织缺刻的形成,但对其配子体形态和性别分化无明显影响;而在黑暗条件下狭眼凤尾蕨成精囊素对水蕨长条形配子体的形态发育具有一定影响,与对照组相比其顶端分生组织发达,整体呈长楔形,对性别分化影响不显著。可见,狭眼凤尾蕨和水蕨不具有同种成精子囊素系统。     

Do antheridiogens act via gametophyte size? A study of Woodwardia radicans (Blechnaceae)

For many plants, sex is not fixed by genotype but determined by environmental conditions during development. In homosporous pteridophytes, sex is environmentally determined by the presence or absence of antheridiogens, maleness-inducing pheromones. It has been proposed that antheridiogens primarily reduce growth rate, with small gametophyte size responsible for maleness. To test this hypothesis, the effects of antheridiogen and intergametophytic competition on gender expression and gametophyte size were studied in a culture experiment with Woodwardia radicans. We found that (1) antheridiogen inhibited growth of gametophytes; and (2) slow growth favored maleness, whereas fast growth favored femaleness, irrespective of the presence or absence of antheridiogen. Both conclusions are consistent with the hypothesis that, in W. radicans, antheridiogen effect is mediated by size. They also agree with the "size-advantage" hypothesis in which energetic limitations associated with relatively small individual size impose a less severe limitation for male reproductive success than for female reproductive success. The results are also discussed with regard to a genetic sex-determining pathway that has recently been identified.     

An in vitro whole plant selection system: paraquat tolerant mutants in the fern Ceratopteris

Summary A whole plant selection system using the haploid gametophyte generation of the fern Ceratopteris richardii has been developed to select for mutations that confer resistance or tolerance to various selection pressures. The expression of the mutations can be analyzed and characterized in both the haploid gametophyte and diploid sporophyte generations. Genetic analyses are facilitated by the fern's rapid life cycle and the ease of manipulating the gametophyte generation. Selection for tolerance to the herbicide paraquat has yielded two mutants which have an increased tolerance to the herbicide in both the gametophyte and sporophyte generations. Both mutants exhibit single nuclear gene inheritance patterns and appear to be closely linked or allelic.     

Characterization and genetic analysis of antheridiogen-insensitive mutants in the fern Ceratopteris

WARNE, T. R., HICKOK, L. G. & SCOTT, R. S., 1988. Characterization and genetic analysis of antheridiogen-insensitive mutants in the fern Ceratopteris . The pheromone antheridiogen mediates the differentiation of male gametophytes in the fern Ceratopteris . Mutants insensitive to antheridiogen were isolated using an in vitro selection procedure. Antheridiogen-insensitive mutants exhibited partial or complete insensitivity to antheridiogen, but were normal in all other respects. Two mutants were completely insensitive to antheridiogen, whereas, another mutant was insensitive to supplemented antheridiogen, but produced male gametophytes in multispore cultures. Genetic analysis suggested a single gene basis for each mutant.     

GENETIC ANALYSIS OF ANTHERIDIOGEN SENSITIVITY IN CERATOPTERIS RICHARDII

The pheromone antheridiogen promoted the production of males in gametophyte populations of the fern Ceratopteris richardii. Two homozygous strains of this species exhibited markedly different sensitivities to the pheromone, resulting in populations with either high or low frequencies of males. The two strains were characterized by dose responses to antheridiogen and by gametophyte population density studies to investigate the effect of antheridiogen produced within cultures. Analyses of Fl hybrids and an F2 generation indicated that differences in the antheridiogen responses of the two parental strains are associated with either one or two nuclear genes.     

KNOX homeobox genes potentially have similar function in both diploid unicellular and multicellular meristems, but not in haploid meristems

Members of the class 1 knotted-like homeobox (KNOX) gene family are important regulators of shoot apical meristem development in angiosperms. To determine whether they function similarly in seedless plants, three KNOX genes (two class 1 genes and one class 2 gene) from the fern Ceratopteris richardii were characterized. Expression of both class 1 genes was detected in the shoot apical cell, leaf primordia, marginal part of the leaves, and vascular bundles by in situ hybridization, a pattern that closely resembles that of class 1 KNOX genes in angiosperms with compound leaves. The fern class 2 gene was expressed in all sporophyte tissues examined, which is characteristic of class 2 gene expression in angiosperms. All three CRKNOX genes were not detected in gametophyte tissues by RNA gel blot analysis. Arabidopsis plants overexpressing the fern class 1 genes resembled plants that overexpress seed plant class 1 KNOX genes in leaf morphology. Ectopic expression of the class 2 gene in Arabidopsis did not result in any unusual phenotypes. Taken together with phylogenetic analysis, our results suggest that (a) the class 1 and 2 KNOX genes diverged prior to the divergence of fern and seed plant lineages, (b) the class 1 KNOX genes function similarly in seed plant and fern sporophyte meristem development despite their differences in structure, (c) KNOX gene expression is not required for the development of the fern gametophyte, and (d) the sporophyte and gametophyte meristems of ferns are not regulated by the same developmental mechanisms at the molecular level.     

Identification of genes expressed in the angiosperm female gametophyte

Until recently, identification of gene regulatory networks controlling the development of the angiosperm female gametophyte has presented a significant challenge to the plant biology community. The angiosperm female gametophyte is fairly inaccessible because it is a highly reduced structure relative to the sporophyte and is embedded within multiple layers of the sporophytic tissue of the ovule. Moreover, although mutations affecting the female gametophyte can be readily isolated, their analysis can be difficult because most affect genes involved in basic cellular processes that are also required in the diploid sporophyte. In recent years, expression-based approaches in multiple species have begun to uncover gene sets expressed in specific female gametophyte cells as a means of identifying regulatory networks controlling cell differentiation in the female gametophyte. Here, recent efforts to identify and analyse gene expression programmes in the Arabidopsis female gametophyte are reviewed.     

脊椎动物性别决定和分化的分子机制研究进展

哺乳类性别决定是多种转录因子和生长因子相继表达和相互调控的结果。SRY的表达启动雄性通路并诱导下游雄性特异基因SOX9、AMH等的表达。FOXL2在雌性未分化性腺表达,WNT-4和DAX1也在雌性性别决定或分化时期表达,表明雌性通路也是受特定基因调控的,而并非“默认通路”。鸟类的性别也是由遗传基因决定的,EFT1(雌性)和DMRT1(雄性)可能是性别决定候选基因。爬行类为温度性别决定的典型,温度可能通过调节雌激素水平和控制性别特异遗传基因表达决定性别。大部分两栖类性别受环境因素影响,但发现DMRT1和DAX1可能与其精巢发育有关。鱼类性别决定和分化方式差异很大,多种因素(遗传基因、环境因素、类固醇激素等)参与了这一过程。从青Q鳉Y染色体定位克隆的DMY,被认为是第一个非哺乳类脊椎动物雄性性别决定基因。所有这些表明脊椎动物性别决定和分化机制是多样化的。     

Cytokinin receptors in sporophytes are essential for male and female functions in Arabidopsis thaliana

Arabidopsis has three cytokinin receptors genes: CRE1, AHK2 and AHK3. Availability of plants that are homozygous mutant for these three genes indicates that cytokinin receptors in the haploid cells are dispensable for the development of male and female gametophytes. The triple mutants form a few flowers but never set seed, indicating that reproductive growth is impaired. We investigated which reproductive processes are affected in the triple mutants. Anthers of mutant plants contained fewer pollen grains and did not dehisce. Pollen in the anthers completed the formation of the one vegetative nucleus and the two sperm nuclei, as seen in wild type. The majority of the ovules were abnormal: 78% lacked the embryo sac, 10% carried a female gametophyte that terminated its development before completing three rounds of nuclear division, and about 12% completed three rounds of nuclear division but the gametophytes were smaller than those of the wild type. Reciprocal crosses between the wild type and the triple mutants indicated that pollen from mutant plants did not germinate on wild-type stigmas, and wild-type pollen did not germinate on mutant stigmas. These results suggest that cytokinin receptors in the sporophyte are indispensable for anther dehiscence, pollen maturation, induction of pollen germination by the stigma and female gametophyte formation and maturation.Key words: cytokinin, cytokinin receptor, female gametophyte, male gametophyte, stigma     

tra-2 encodes a membrane protein and may mediate cell communication in the Caenorhabditis elegans sex determination pathway.

The Caenorhabditis elegans sex-determining gene, tra-2, promotes female development in XX animals. In this paper we report the cDNA sequence corresponding to a 4.7 kb tra-2 mRNA and show that it is composed of 23 exons, is trans-spliced to SL2, and contains a perfect direct repeat in the 3' untranslated region. This mRNA is predicted to encode a 1475 amino acid protein, named pTra2A, that has a secretory signal and several potential membrane-spanning domains. The molecular analysis of tra-2 loss-of-function mutations supports our open reading frame identification and suggests that the carboxy-terminal domain is important for tra-2 activity. We propose that in XX animals the carboxy-terminal domain of pTra2A negatively regulates the downstream male promoting fem genes. In XO animals, tra-2 is negatively regulated by her-1, which acts cell nonautonomously. Because hydropathy predictions suggest that pTra2A is an integral membrane protein, pTra2A might act as a receptor for the her-1 protein. We propose that in XO animals, the her-1 protein promotes male development by binding and inactivating pTra2A. The role of cell communication in C. elegans sex determination might be to ensure unified sexual development throughout the animal. If so, then regulation of sexual fate by her-1 and tra-2 might provide a general model for the coordination of groups of cells to follow a single cell fate.     

Linkage Analysis Reveals the Independent Origin of Poeciliid Sex Chromosomes and a Case of Atypical Sex Inheritance in the Guppy (Poecilia reticulata)

Among different teleost fish species, diverse sex-determining mechanisms exist, including environmental and genetic sex determination, yet chromosomal sex determination with male heterogamety (XY) prevails. Different pairs of autosomes have evolved as sex chromosomes among species in the same genus without evidence for a master sex-determining locus being identical. Models for evolution of Y chromosomes predict that male-advantageous genes become linked to a sex-determining locus and suppressed recombination ensures their co-inheritance. In the guppy, Poecilia reticulata, a set of genes responsible for adult male ornaments are linked to the sex-determining locus on the incipient Y chromosome. We have identified >60 sex-linked molecular markers to generate a detailed map for the sex linkage group of the guppy and compared it with the syntenic autosome 12 of medaka. We mapped the sex-determining locus to the distal end of the sex chromosome. We report a sex-biased distribution of recombination events in female and male meiosis on sex chromosomes. In one mapping cross, we observed sex ratio and male phenotype deviations and propose an atypical mode of genetic sex inheritance as its basis.