A light and electron microscopy analysis of the events leading to male sterility in Ogu-INRA CMS of rapeseed (Brassica napus)

Ogura cytoplasmic male sterility (CMS) occurs naturally in radishand has been introduced into rapeseed (Brassica napus) by protoplastfusion. As with all CMS systems, it involves a constitutivelyexpressed mitochondrial gene which induces male sterility tootherwise hermaphroditic plants (so they become females) anda nuclear gene named restorer of fertility that restores pollenproduction in plants carrying a sterility-inducing cytoplasm.A correlative approach using light and electron microscopy wasapplied to define what stages throughout development were affectedand the subcellular events leading to the abortion of the developingpollen grains upon the expression of the mitochondrial protein.Three central stages of development (tetrad, mid-microsporeand vacuolate microspore) were compared between fertile, restored,and sterile plants. At each stage observed, the pollen in fertileand restored plants had similar cellular structures and organization.The deleterious effect of the sterility protein expression startedas early as the tetrad stage. No typical mitochondria were identifiedin the tapetum at any developmental stage and in the vacuolatemicrospores of the sterile plants. In addition, some strikingultrastructural alterations of the cell's organization werealso observed compared with the normal pattern of development.The results showed that Ogu-INRA CMS was due to premature celldeath events of the tapetal cells, presumably by an autolysisprocess rather than a normal PCD, which impairs pollen developmentat the vacuolate microspore stage, in the absence of functionalmitochondria. Key words: Brassica napus, cell death, light and electron microscopy, mitochondria, plastids, pollen development, Ogu-INRA cytoplasmic male sterility, transgenic-restored plants, tapetum Received 30 September 2007; Revised 11 December 2007 Accepted 20 December 2007     

Mitochondrially-targeted expression of a cytoplasmic male sterility-associated <Emphasis Type="Italic">orf220</Emphasis> gene causes male sterility in <Emphasis Type="Italic">Brassica juncea</Emphasis>

Background  

The novel chimeric open reading frame (orf) resulting from the rearrangement of a mitochondrial genome is generally thought to be a causal factor in the occurrence of cytoplasmic male sterility (CMS). Both positive and negative correlations have been found between CMS-associated orfs and the occurrence of CMS when CMS-associated orfs were expressed and targeted at mitochondria. Some orfs cause male sterility or semi-sterility, while some do not. Little is currently known about how mitochondrial factor regulates the expression of the nuclear genes involved in male sterility. The purpose of this study was to investigate the biological function of a candidate CMS-associated orf220 gene, newly isolated from cytoplasmic male-sterile stem mustard, and show how mitochondrial retrograde regulated nuclear gene expression is related to male sterility.     

The protein-encoding gene T-urf13 is not edited in maize mitochondria

RNA editing of T-urf13, a gene specific to the mitochondria of cytoplasmic male-sterile, type-T (cms-T) maize, and an adjacent, cotranscribed geneorf221, have been studied by cDNA sequencing. No editing was detected in 22 cDNA clones. This is the only report of a polypeptide-encoding gene in higher-plant mitochondria that is not edited. T-urf13 may not be edited because it is derived largely from the coding and flanking regions, which are rarely edited, of a ribosomal RNA gene.orf221 is edited; however, the similarity between the predicted amino acid sequences oforf221 incms-T and normal cytoplasms is not increased.     

Restoration of Fertility in Cytoplasmic Male-Sterile Nicotiana tabacum (Cytoplasm N. bigelovii) by Protoplast Fusion with X-Irradiated Protoplasts of N. tabacum, SR-1

The ‘donor–recipient’ fusion method was usedto investigate the intraspecific transfer of organelles andorganelle-encoded traits from donor to recipient Nicotiana speciesunder conditions which were selective for chloroplast transfer.An alloplasmic male sterile line of N. tabacum carrying thecytoplasm of N. bigelovii as the recipient and N. tabacum SR-1,a mutant with maternallyinherited streptomycin resistance, asthe cytoplasm donor were used. Organelle composition of 13 cybridplants was investigated by analysis of tentoxin and streptomycinsensitivities, chloroplast and mitochondrial DNA restrictionpatterns, and alloplasmic male sterility Chloroplast DNA analysisand the tentoxin test both showed that all 13 cybrid plantspossessed chloroplasts from the N. tabacum, SR-1 parent only.Analysis of mitochondrial DNA from second generation plantsderived from 11 of the original cybrid plants indicated verylittle heterogeneity with nine of the plants expressing pureparental-type mtDNAs. Although conditions were selective fordonor-type chloroplast transfer, the results indicate the generationof novel cytoplasmic combinations; pure donor chloroplasts incombination with either pure or recombinant-type recipient mitochondria.Our results support previous findings that the ‘donor-recipient’fusion method can be used to restore fertility of CMS linesof Nicotiana Key words: Nicotiana, cytoplasmic male sterility, chloroplast DNA, mitochondrial DNA, somatic hybridization     

Variation in mitochondrial translation products in fertile and cytoplasmic male-sterile sugar beets

Summary Intact and functional mitochondria were isolated from sugar beet plants (Beta vulgaris L.) containing normal fertile (F) or cytoplasmic male-sterile (S₁–S₄) cytoplasms. Incorporation of ³⁵S-methionine by mitochondria isolated from both roots and leaves showed approximately 20 major and ten minor translation products. Comparison of the polypeptide synthesis patterns produced by leaf mitochondria from fertile plants of three different species within the genus Beta revealed several taxonomically related differences. Contrary to this, the patterns of polypeptides synthesized by mitochondria from roots and leaves of sugar beet plants containing the F and S₁–S₄ cytoplasms were very similar; in the S₁ and S₂ cytoplasms no qualitative, and only a few quantitative, differences from the F cytoplasm were observed. Thus, in these cases, cytoplasmic male sterility in sugar beet is not correlated with the constitutive expression of variant polypeptides. In the S₃ cytoplasm, however, an additional 6 kDa polypeptide was synthesized and in the S₄ cytoplasm an additional 10 kDa polypeptide was observed when compared with the F cytoplasm. The expression of cytoplasmic male sterility in sugar beet may be associated with these variant polypeptides. The mitochondrial polypeptides synthesized were identical in plants with different nuclear backgrounds but with identical S₁ cytoplasms. Mitochondria from plants with variants of the S₄ cytoplasm in the same nuclear genotype also showed identical patterns of polypeptide synthesis, including the synthesis of the 10 kDa S₄-specific polypeptide. Pulse-chase experiments did not affect the synthesis of this polypeptide.     

Plastid DNA diversity in natural populations of Beta maritima showing additional variation in sexual phenotype and mitochondrial DNA

Summary Plants of two natural populations of Beta maritima, characterized by high percentages of male-sterile plants, have been investigated for organelle DNA polymorphism. We confirm the two classes of mitochondrial DNA variation previously described: (i) mitochondrial DNA (mtDNA) type N is associated with male fertility, whereas mtDNA type S can cause cytoplasmic male sterility (CMS); (ii) the 10.4-kb linear plasmid is observed in both types of mitochondria and is not correlated with the cytoplasmic male sterility occurring in this plant material. A third polymorphism is now described for chloroplast DNA (ctDNA). This polymorphism occurs within single populations of Beta maritima. Three different ctDNA types have been identified by HindIII restriction analysis. Among the plants studied, ctDNA type 1 is associated with N mitochondria and type 2 with S mitochondria. Chloroplast DNA type 3 has been found both in a fertile N plant and in a sterile S plant. This finding suggests that the chloroplast DNA polymorphism reported is not involved in the expression of male sterility. A comparison with Beta vulgaris indicates that ctDNA type 3 of Beta maritima corresponds to the ctDNA of fertile sugar beet maintainer lines. The three types of Beta maritima ctDNA described in this study differ from the ctDNA of male-sterile sugar beet.     

URF13, a ligand-gated,pore-forming receptor for T-toxin in the inner membrane ofcms-T mitochondria

URF13 is the product of a mitochondrial-encoded gene (T-urfl3) found only in maize plants containing the Texas male-sterile cytoplasm (cms-T), and it is thought to be responsible for both cytoplasmic male sterility and the susceptibility ofcms-T maize to the fungal pathogensBipolaris maydis race T andPhyllosticta maydis. Mitochondria isolated fromcms-T maize are uniquely sensitive to pathotoxins (T-toxin) produced by these fungi and to methomyl (a commercial insecticide). URF13 acts as a receptor that specifically binds T-toxin to produce hydrophilic pores in the inner mitochondrial membrane. When expressed inEscherichia coli cells, URF13 also forms hydrophilic pores in the plasma membrane if exposed to T-toxin or methomyl. Topological studies established that URF13 contains three membrane-spanning -helices, two of which are amphipathic and can contribute to pore formation. Chemical crosslinking of URF13 was used to demonstrate the existence of URF13 oligomers incms-T mitochondria andE. coli cells. The ability of the carboxylate-specific reagent,N,N-dicyclohexycarbodiimide, to cross-link URF13 was used in conjunction with site-directed mutagenesis to establish that the URF13 tetramer has a central core consisting of a four--helical bundle which undergoes a conformational change after interaction with T-toxin or methomyl. Overall, the experimental evidence indicates that URF13 functions as a ligand-gated, pore-forming T-toxin receptor incms-T mitochondria.     

DCW11, down-regulated gene 11 in CW-type cytoplasmic male sterile rice, encoding mitochondrial protein phosphatase 2c is related to cytoplasmic male sterility

Causes of cytoplasmic male sterility (CMS) in plants have beenstudied for two decades, and mitochondrial chimeric genes havebeen predicted to induce CMS. However, it is unclear what happensafter CMS-associated proteins accumulate in mitochondria. Inour previous study of microarray analysis, we found that 140genes are aberrantly regulated in anthers of CW-type CMS ofrice (Oryza sativa L.). In the present study, we investigatedDCW11, one of the down-regulated genes in CW-CMS encoding aprotein phosphatase 2C (PP2C). DCW11 mRNA was preferentiallyexpressed in anthers, with the highest expression in maturepollen. As predicted by the N-terminal sequence, DCW11 signalpeptide–green fluorescent protein (GFP) fusion proteinwas localized in mitochondria. Knockdown of DCW11 in wild-typerice by RNA interference caused a major loss of seed-set fertility,without visible defect in pollen development. Since this knockdownphenotype resembled that of CW-CMS, we concluded that the down-regulationof DCW11 is correlated with CW-CMS. This idea was supportedby the up-regulation of alternative oxidase 1a (AOX1a), whichis known to be regulated by mitochondrial retrograde signaling,in DCW11 knockdown lines. Down-regulation of DCW11 and up-regulationof AOX1a were also observed in two other types of rice CMS.Our result indicates that DCW11 could play a role as a mitochondrialsignal transduction mediator in pollen germination.     

高等植物细胞质雄性不育分子机理的研究进展

从线粒体DNA、叶绿体DNA和线粒体质粒DNA方面较详细地阐述了高等植物细胞质雄性不育的分子机理及最新进展;探讨了细胞核DNA和细胞质DNA之间的相互关系。     

Mitochondrial genome organization and cytoplasmic male sterility in plants

Plant mitochondrial genomes are much larger and more complex than those of other eukaryotic organisms. They contain a very active recombination system and have a multipartite genome organization with a master circle resolving into two or more subgenomic circles by recombination through repeated sequences. Their protein coding capacity is very low and is comparable to that of animal and fungal systems. Several subunits of mitochondrial functional complexes, a complete set of tRNAs and 26S, 18S and 5S rRNAs are coded by the plant mitochondrial genome. The protein coding genes contain group II introns. The organelle genome contains stretches of DNA sequences homologous to chloroplast DNA. It also contains actively transcribed DNA sequences having open reading frames. Plasmid like DNA molecules are found in mitochondria of some plants Cytoplasmic male sterility in plants, characterized by failure to produce functional pollen grains, is a maternally inherited trait. This phenomenon has been found in many species of plants and is conveniently used for hybrid plant production. The genetic determinants for cytoplasmic male sterility reside in the mitochondrial genome. Some species of plants exhibit more than one type of cytoplasmic male sterility. Several nuclear genes are known to control expression of cytoplasmic male sterility. Different cytoplasmic male sterility types are distinguished by their specific nuclear genes(rfs) which restore pollen fertility. Cytoplasmic male sterility types are also characterized by mitochondrial DNA restriction fragment length polymorphism patterns, variations in mitochondrial RNAs, differences in protein synthetic profiles, differences in sensitivity to fungal toxins and insecticides, presence of plasmid DNAs or RNAs and also presence of certain unique sequences in the genome. Recently nuclear male sterility systems based on (i) over expression of agrobacterialrol C gene and (ii) anther specific expression of an RNase gene have been developed in tobacco andBrassica by genetic engineering methods.     

Variable presence of the 1.94kb mitochondrial plasmid in maize S cytoplasm and its relationship to cytoplasmic male sterility

Mitochondrial DNA (mtDNA) was isolated from over 100 different maize nucleo-cytoplasmic combinations. DNA preparations were assayed for the presence of the 1.94kb mitochondrial plasmid by agarose gel electrophoresis and hybridization to a recombinant clone of the plasmid. The plasmid was present in all tested inbreds which carried N, male fertile, cytoplasm or the cytoplasmically male sterile (cms) groups,cms-T andcms-C. However, members of thecms-S group differed with respect to the presence of the plasmid. Cytoplasms I, J and S possessed the plasmid, whereas cytoplasms B, CA, D, G, H, IA, ME, ML, PS, RD and VG did not.Cms-S group lines which had spontaneously reverted to fertility (nuclear and cytoplasmic revertants) did not exhibit a concomitant change in 1.94kb plasmid levels, although all such lines showed the previously reported alteration in levels of the linear mtDNAs, S1 and S2. The presence or absence of the plasmid was not correlated with (i) frequency of reversion to fertility, (ii) the degree of male sterility expressed, (iii) the presence or absence of standard nuclear restorer to fertility genes and (iv) nuclear genotype. Latin American races carrying RU cytoplasm possessed the plasmid, as did sweet corn varieties. The relevance of the data tocms and evolution of thecms-S group is discussed.     

Morphological characteristics and chloroplast DNA distribution in different cytoplasmic parasexual hybrids of Nicotiana tabacum

Summary Protoplast fusion makes possible the fusion of two different cytoplasms, allowing genetical analysis of cytoplasmic factors. Two varieties of Nicotiana tabacum differing by their cytoplasms have been used. Techne, the first variety, obtained by an interspecific cross between N. debneyi (female) and N. tabacum (male) is characterized by the nuclear tabacum genome inside the debneyi cytoplasm. Techne plants present abnormal flowers with cytoplasmic male sterility (cytoplasmic marker) and sessile leave (nuclear marker). Techne leaf protoplasts were fused with leaf protoplasts of N. tabacum var. Samsun (or Xanthi). The last variety is characterized by petiolated leaves and normal flowers, because it possesses the nuclear tabacum genome associated with the tabacum cytoplasm. The nuclear marker (leaf shape) and the cytoplasmic one (flower shape inducing male sterility or fertility) have been used to distinguish among the whole regenerated plants the somatic nuclear hybrids and the cytoplasmic hybrids (cybrids) displaying the nuclear phenotype of one of the two parents associated with a modified flower type, intermediate between the parental ones.The chloroplastic (cp) DNA contained in each parent has been specifically identified by using EcoRI restriction nuclease and gel electrophoresis. EcoRI fragment patterns of cp DNA isolated from the first progeny of the regenerated cytoplasmic hybrids revealed that only one of the two parental cp DNAs is present in all cases; neither mixture of both parental cp DNAs nor recombinant cp DNA molecules were observed. This indicates that a specific elimination of one or the other parental cp DNAs occurs after the initial mixing of the cytoplasms. The study of the association of the modified flower type with the cp DNA isolated from the corresponding plant showed that cp DNA seems independent from the mechanism of cytoplasmic male sterility in tobacco.     

Genetic analyses supported by molecular methods provide evidence of a new genic (st1) and a new cytoplasmic (st2) male sterility in Allium schoenoprasum L.

Spontaneous mutations leading to male sterility have been described for many different crops and are of great importance to hybrid breeding, provided that their inheritance is resolved. This paper describes an efficient method to characterise male sterilities with respect to cytoplasmic factors that might be causally related to them. The differentiation of cytoplasmic (CMS) and genic (GMS) male sterility is achieved by a specific transfer of nuclear male sterility factors to different cytoplasm types which have previously been distinguished by means of RFLP analyses using mitochondrial gene probes. The nuclear sterility factors of Allium schoenoprasum used, st1 and st2, showed a monogenic recessive inheritance in their original cytoplasms. While st1 was expressed in four different cytoplasm types, st2 did not show itself in a cytoplasm type differing from the original. Therefore, the st1-sterility is a GMS, while a cytoplasmic factor is necessary for the occurrence of st2-sterility. This cytoplasmic factor was verified by a reciprocal cross, and the CMS system was completed by the selection of maintainer genotypes. Neither of these new sterilities were influenced by high temperatures or tetracycline. The benefits of a new CMS system to practical breeding and the advantages and disadvantages of the environmental influences on the expression of male sterility are discussed. Received: 24 November 1999 / Accepted: 3 December 1999     

Identification of a mitochondrial protein associated with cytoplasmic male sterility in petunia.

The petunia fused gene (pcf), which is associated with cytoplasmic male sterility (CMS), is composed of sequences derived from atp9, coxII, and an unidentified reading frame termed urfS. To determine whether the pcf gene is expressed at the protein level, we produced antibodies to synthetic peptides specified by the coxII and urfS portions of the pcf gene. Anti-COXII peptide antibodies recognized petunia COXII but no other mitochondrial proteins. Anti-URF-S peptide antibodies recognized a 20-kilodalton protein present in both cytoplasmic male sterile and fertile lines and a protein with an apparent molecular mass of 25 kilodaltons present only in cytoplasmic male sterile lines. The 25-kilodalton protein was found to be synthesized by isolated mitochondria and to fractionate into both the soluble and membrane portions of disrupted mitochondria, whereas the 20-kilodalton protein was found only in the membrane fraction. The abundance of the 25-kilodalton protein was much lower in fertile plants carrying the cytoplasmic male sterile cytoplasm and a single dominant nuclear fertility restorer gene, Rf. Thus, the pcf gene is correlated with cytoplasmic male sterility not only by its co-segregation with the phenotype in somatic hybrids, but also by the modification of its expression at the protein level through the action of a nuclear gene that confers fertility.     

Allelic relationship of four male sterility genes and nucleo-cytoplasmic interactions in the expression of male sterility in pearl millet,Pennisetum americanum (L.) leeke

Summary Male sterility genes isolated in four inbred lines of pearl millet were found allelic. The differences between male fertile and male sterile phenotypes is mainly due to a single gene. Presence of a dominant gene (Ms) resulted in male fertility and double recessiveness (ms ms) in male sterility. However, genic male sterility (GMS) in Pennisetum is not a simply inherited case of monogenic recessive condition but is influenced by cytoplasmic and several nuclear factors. In a male sterile, the stage at which the male sterility gene is expressed during the development of the male gametophyte resulting in breakdown of the cells is influenced by cytoplasmic and other nuclear factors. Two types of cytoplasm, C-1 and C-2, are recognized. Presence of any two recessive male sterility alleles in C-1 led to breakdown of male development before differentiation of an archesporium in the anther (Arc-type); in C-2 cytoplasm, degeneration started during meiosis with fusion of meiocytes and syncyte formation (Syn-type), or at post-meiotic stages terminating in abortion of microspores before first pollen mitosis (PGM type). The triggering of activity of recessive male sterility genes in C-2 cytoplasm appeared to be regulated by two nuclear factors, R ₁ and R ₂ with duplicate gene action. Recessiveness for both the R factors in C-2 cytoplasm resulted in PGM-type expression. The action of R ₁ and R ₂ is specific to C-2 cytoplasm. Mutation of cytoplasm from C-1 to C-2 and C-2 to C-1 was observed.     

Male Sterility and Anther Wall Structure in Copper-deficient Plants

Anther development and pollen sterility were followed in plantsof wheat, oat, barley, sweetcorn, sunflower, petunia and subterraneumclover grown at a range of copper supplies. Copper-deficientplants had increased pollen sterility. Lignified wall thickenings were reduced or absent in the endotheciaof anthers from Cu-deficient plants. Reduced seed set may resultboth from reduced pollen fertility or failure of the stomiato rupture due to decreased lignification of anther walls. Triticum aestivum L., wheat, Hordeum vulgare L., barley, Avena sativa L., oat, Zea mays L., corn, sweetcorn, maize, Helianthus annuus L., sunflower, Petunia hybrida L., Trifolium subterraneum L., subterranean clover, male sterility, anther development, copper deficiency     

CYTOLOGICAL DIFFERENCES BETWEEN A CYTOPLASMIC MALE STERILE TOBACCO CYBRID AND ITS FERTILE COUNTERPART DURING EARLY ANTHER DEVELOPMENT

Ultrastructural differences were detected between a cytoplasmic male sterile tobacco cybrid (Nicotiana sp.) formed by protoplast fusion and normal, fertile tobacco. Cell structure was compared between anther primordia from normal, fertile tobacco and anther primordia from the cybrid using stereological methods. Particular emphasis was placed on the ultrastructure of mitochondria because of their known relationship to cytoplasmic male sterility in this cybrid and other plants. The volume density of mitochondria in cybrid anther primordia (6.3%) was significantly lower than in normal, fertile anther primordia (10.1%), although mitochondria from both plants contained similar amounts of cristae and profiles were of similar relative area. Dictyosomes and vacuoles also differed in volume density but not at a statistically significant level. Although the volume density of plastids did not differ, a larger amount of starch was stored within plastids in cybrid anther primordia than in normal, fertile anther primordia. These results are compatible with the hypothesis that an abnormally low rate of mitchondrial replication, and the resultant limit on adenosine triphosphate production, could contribute to cytoplasmic male sterility in the cybrid.     

A Comparison of Anther Tissue Development in Male Sterile Aloe vera and Male Fertile Aloe ciliaris

Cytological differences between the anther development of amale sterile and a male fertile Aloe species are used to explaininteractions between anther tissues. Some deviations in thelayers of the locule wall and the microspores of the male sterileanther are related to each other and their biological functionsare discussed. The cytological development of the male sterility,which can be observed shortly after meiosis, seems to be restrictedto the locular cavity. The tapetal development and breakdownare normal, apart from the size of some orbicules. However,the pollenkitt is not transported to the pollengrains, whichstrongly supports our theory that this process is mechanicallypollen-controlled. The development of the epidermal and endothecialcells is normal, except in a part of the anthers where thesecells do not expand, after which dehiscence is incomplete. Thelatter process is discussed in relation to the deviations insidethe locular cavity. Aloe vera (L.) Burm. fil., Aloe ciliaris Haw., Liliaceae, male sterility, tapetum, pollenkitt, endothecium, anther dehiscence     

Molecular basis of cytoplasmic male sterility and fertility restoration in rice

Cytoplasmic male sterility (CMS) is a maternally inherited trait that causes dysfunctions in pollen and anther development. CMS is caused by the interaction between nuclear and mitochondrial genomes. A product of a CMS-causing gene encoded by the mitochondrial genome affects mitochondrial function and the regulation of nuclear genes, leading to male sterility. In contrast, the RESTORER OF FERTILITY gene (Rf gene) in the nuclear genome suppresses the expression of the CMS-causing gene and restores male fertility. An alloplasmic CMS line is often bred as a result of nuclear substitution, which causes the removal of functional Rf genes and allows the expression of a CMS-causing gene in mitochondria. The CMS/Rf system is an excellent model for understanding the genetic interactions and cooperative functions of mitochondrial and nuclear genomes in plants, and is also an agronomically important trait for hybrid seed production. In this review article, pollen and anther phenotypes of CMS, CMS-associated mitochondrial genes, Rf genes, and the mechanism that causes pollen abortion and its agronomical application for rice are described.     

Effect of Water Deficit on Sporogenesis in Wheat (Triticum aestivum L.)

Plants of Triticum aestivum L., cv. Gabo, were grown in a glasshousefor 4 weeks and then transferred to a controlled environmentwith 20±1 °C temperature and 16 h photoperiod. Theywere subjected to water deficit by withholding the water supplyduring various stages of floral development, including thoseimmediately before meiosis and all stages until just after anthesis. The proportion of apparently normal florets which produced grainwas reduced when water deficit occurred during and immediatelyafter meiosis in the generative tissues. The effect of thisreduced grain set on total grain yield was partially compensatedby an increase in the weight of the remaining grains. Cross-pollinationbetween stressed and well-watered plants showed that grain setwas reduced as a direct consequence of the induction of malesterility by water stress, whereas female fertility was unaffected.A large proportion of the anthers on water-stressed plants weresmall and shrivelled, did not dehisce normally and containedpollen which was devoid of normal cytoplasmic constituents andshowed no staining reaction with triphenyl tetrazolium chloride.This effect on male fertility was not a result of desiccationof the sporogenous tissue, but an indirect outcome of the decreasein water potential elsewhere in the plant. Water stress, Triticum aestivum L., wheat, pollen, sporogenesis, grain set, male sterility