Genetically engineered cytoplasmic male sterility

Cytoplasmic male sterility, conditioned by some maternally inherited plant mitochondrial genomes, is the most expedient method to produce uniform populations of pollen-sterile plants on a commercial scale. Plant mitochondrial genomes are not currently amenable to genetic transformation, but genetic manipulation of the plastid genome allows engineering of maternally inherited traits in some species. A recent study has shown that the Acinetobacter beta-ketothiolase gene, expressed in the Nicotiana tabacum plastid, conditions maternally inherited male sterility, laying the groundwork for new approaches to control pollen fertility in crop plants.     

Ultrastructural aspects of cytoplasmic male sterility inPetunia hybrida

Summary Anther development of isogenic male fertile and cytoplasmic male sterile types ofPetunia hybrida cv. Blue Bedder is studied by electron microscopy. First deviation in sporogenesis of the sterile type, is observed during leptotene stage of the meiocytes. Initial aberration is represented by the presence of large vacuoles in the cytoplasm of the tapetal cells. These vacuoles reveal the first aspects of degeneration; no other ultrastructural differences are observed. Vacuolation is accompanied by the condensation of cytoplasmic organelles. The tapetal cells become distorted and ultrastructural aberrations in mitochondria do occur. The mitochondria elongate and contain several tubular cristae.Substantial evidence suggests, that cytoplasmic male sterility in petunia is encoded by the mitochondrial genome (Boeshore el al. 1983). However, before degeneration becomes manifest, no consistent ultrastructural differences in mitochondrial organization are observed.Abortion of the tapetum and the sporogenous tissue in cytoplasmic male sterile plants, generally follows a corresponding pattern. Ultimately, the cells are highly distorted, the nucleus is disrupted and the cytoplasm disorganized. Mitochondria and plastids degenerate and many lipid droplets are present.     

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.     

Influencing of the cytoplasmic male sterility and fertility in beets

Attempts have been made to find a method to control the male sterility-male fertility balance in beets. It proved not possible to induce male sterility in O-types by means of grafting. Nor was transmission by infection with aphids or by rubbing with juice successful. In some cases exposure of germinated seed of plasmatic male sterile annual beet material to temperatures of up to 55°C resulted in the occurrence of male fertile plants. The accompanying change could not be uniformly explained from the propagation obtained. It is possible that S-plasm has changed into N-plasm. Further investigations are in progress.     

Timing of callase activity and cytoplasmic male sterility in Petunia

A study of callase activity in relation to cytogenetical expressions in cytoplasmic male sterile and male fertile Petunia indicated differential timing of the localized enzyme activity. Enzyme activity was determined by a new test. The possible relations between the mode of action of the extrachromosomal gene, timing of the enzyme activity, and male sterility are discussed.Paper No. 1360-E, 1968 Series of the Volcani Institute of Agricultural Research. Supported in part by grant No. FG-Is-171 of the United States Department of Agriculture, Authorized by U.S. Public Law 480.Deceased.     

Mitochondrial DNA modifications associated with cytoplasmic male sterility in rice

Summary Mitochondrial DNA was isolated from fertile and cytoplasmic male sterile lines of rice. Restriction analysis showed specific modifications in the male sterile cytoplasm. In addition to the major mitochondrial DNA, three small plasmid-like DNA molecules were detected by agarose gel electrophoresis in both cytoplasms. An additional molecule was specifically found in the sterile cytoplasm. These mitochondrial DNA modifications support the hypothesis of the mitochondrial inheritance of the cytoplasmic male sterility in rice.     

Mitotype-specific sequences related to cytoplasmic male sterility in Oryza species

Plant mitochondrial genomes contain a large number of mitotype-specific sequences (MSS) which establish a mitochondrial genome structure distinct from other mitotypes. In rice, nine mitochondrial genomes have been sequenced, which provides us with the possibility of characterizing the MSS of rice and probing their relationship to cytoplasmic male sterility (CMS) in rice. We therefore analyzed the mitochondrial genomes of CW-CMS, LD-CMS, WA-CMS, N and Nipponbare lines, and found 57 MSS with sizes ranging from 102 to 5,745 bp, and with an aggregate length of 92.4 kb. The MSS account for more than 14.5 % of the rice mitochondrial genome and are a significant contributing factor in the variation of mitochondrial genome sizes. Of the MSS tested, 34 MSS exhibited polymorphism among rice lines, and 14 MSS were further confirmed as being specific to CMS. This includes nine MSS specific to sporophytic CMS, three specific to gametophytic CMS, and two shared by all types of CMS. Interestingly, except for CMS genes orf(H)79 and orf352 which are partly or fully overlapping with some MSS fragments, there are ten more open reading frames of unknown function that were detected in CMS-specific MSS, hinting at their possible roles in plant CMS. These novel findings provide us with potential new molecular tools to direct the breeding of CMS lines in hybrid rice breeding programs.     

QTL analysis of fertility-restoration against cytoplasmic male sterility in wheat

The cytoplasm of Triticum timopheevi causes cytoplasmic male sterility (CMS) in common wheat (T. aestivum) cv. 'Chinese Spring' (CS), and that of Aegilops kotschyi causes CMS in spelt wheat (T. spelta) var. duhamelianum (Sp). CS has fertility-restoring (Rf) genes against the latter cytoplasm and Sp has the ones against the former. To know the genetic system concerning to CMS, we crossed 66 F8 recombinant inbred lines (RILs) derived from a cross between CS and Sp as males to the alloplasmic lines of CS and Sp having the cytoplasms of T. timopheevi and Ae. kotschyi, respectively. The fertilities of respective F1 plants derived from the crosses were examined for QTL analysis. The major QTLs detected in both systems were located on the short arm of chromosome 1B. One minor QTL on chromosome 2B was also commonly detected in both of the systems, while other minor QTLs against T timopheevi cytoplasm were distributed on the chromosomes 2A, 4B, and 6A.     

Molecular-genetic analysis of maize mitochondrion regions associated with cytoplasmic male sterility

Molecular-genetic polymorphism of 86 world and Ukrainian breeding maize lines with S-, C- and T-types of cytoplasmic male sterility (CMS) and with normal wild type mitochondrion has been researched via mitochondrion regions PCR-analysis. Molecular marker system allowed to detect and identify definite type of CMS within maize lines, as well as to differentiate lines with definite CMS type either from lines with another CMS type or from normal wild type cytoplasm lines.     

Expression of ogu cytoplasmic male sterility in cybrids of Brassica napus

Summary A light and electron microscopic investigation revealed that ogu cytoplasmic male sterility (CMS) in cybrids of Brassica napus is primarily a deficiency of the tapetum and clearly time and site specific. Three patterns of ogu CMS were found, and specific conclusions drawn. First, the partially male fertile cybrid 23 was highly variable. It sometimes produced heterogeneous stamens with an endothecium formed exclusively around the fertile locules, thus delineating each microsporangium as a functional unit. The second type, including cybrids 27, 58 and 85, on the contrary, was stable and completely male sterile. In the four locules of normal length, microspores were observed to die at the vacuolate polarized stage while the tapetum disappeared prematurely through excessive vacuolization by the end of meiosis followed by a rapid autolysis during the tetrad or early free microspore stage. The subepidermal layer of the locule wall failed to form characteristic thickenings. The male-sterile stamens were completely indehiscent. At the time of anthesis they contained only collapsed empty exines adhering to each other. These cybrids, 27, 58 and 85, were closest to the ogu CMS trait of radish and seemed to be the best suited for further use in plant breeding. The third pattern was found in cybrids 77 and 118, which besides showing abortion of the microsporangia also showed a feminization of the stamens. We suggest that this feminization might be due to an alloplasmic situation associating Brassica napus nuclear genes with the mitochondrial DNA of radish.     

A cytoplasmic male sterility (CMS) system in durum wheat

Cytoplasmic male sterility (CMS) systems are based in the incompatible interaction between nucleus and cytoplasm and are commonly used for hybrid seed production in many crop species. The msH1 CMS system in common wheat results from the incompatibility between the nuclear genome of wheat and the cytoplasm of Hordeum chilense. Fertility restoration of the CMS phenotype is associated with the addition of the short arm of chromosome 6H^ch from H. chilense. In this work, we attempt to transfer the msH1 system to durum wheat and to evaluate its potential as a new source of CMS for the production of hybrid durum wheat. For that purpose, an alloplasmic durum wheat line was developed by substituting wheat cytoplasm by that from H. chilense. This line was completely male sterile. Also, the double translocation T6H^chS·6DL was transferred from common wheat into durum wheat, to test its potential as a restorer line. Finally, the system was tested by using the double T6H^chS·6DL translocation in durum wheat as pollen donor for the alloplasmic male sterile line, which confirmed the fertility restoration ability of 6H^chS in durum wheat.     

Coexistence of cytoplasmic and nuclear genes for male sterility in Petunia

Summary Cytoplasmic male sterility (cms) and nuclear male sterility (nms) in Petunia were described respectively as possible autonomous and integrated states of the same genetic element by Frankel (1971). In the present study we describe genetic analysis of the interaction between the cms, the nuclear gene for male sterility (e) and the fertility restorer allele (Rf). The main findings in this study are: (1) The nuclear sterility allele can coexist in one or two dosages with the cytoplasmic male sterility elements (ste) in somatic cells or female gametes; (2) the presence of the fertility restorer allele Rf is not required for the coexistence of ste and e and (3) Rf does not interact epistatically with e, e.g., the expression of e is independent of Rf—the genotypes (S) RfRfee and (S) Rfrfee are male sterile.Contribution from the Agricultural Research Organization. The Volcani Center, Bet Dagan, Israel. 1983 series No. 846 E     

Metabolism of reactive oxygen species in cotton cytoplasmic male sterility and its restoration

To elucidate reactive oxygen species (ROS) metabolism of cotton cytoplasmic male sterility and the effects of restorer gene on the metabolism of ROS, the metabolism changes in the production and scavenging of ROS and gene expression related to ROS-scavenging enzymes were investigated in the anther mitochondria of CMS line, maintainer line and hybrid F₁. During the abortion preliminary stage (sporogenous cell division stage), anthers of CMS line had a little higher superoxide (O₂ ⁻) production rate and hydrogen peroxide (H₂O₂) and malondialdehyde (MDA) contents than those of maintainer or hybrid F_1. Simultaneously, a little higher ROS contents might serve as a signal to increase the activity of superoxide dismutase (SOD) in anthers of CMS line to reduce the ROS damage to the anther development. But at the abortion peak (pollen mother cell meiosis stage), anthers of CMS line had extraordinarily higher ROS contents and lower ROS-scavenging enzymic activities compared with the hybrid F₁, during which the ROS contents and ROS-scavenging enzymic activities in hybrid F₁ were approximate to those of maintainer line. The expression of Mn-sod and apx mRNA in anther of CMS line was obviously inhibited when ROS produced with a great deal during anther abortion, however the gene expression in hybrid F₁ kept normal with the maintainer. Excessive accumulation of O₂^·−, H₂O₂ and MDA, significant reduction of ROS-scavenging enzymic activities and lower gene expression level of ROS-scavenging enzyme were coinstantaneous with male cells death in anthers of CMS line. But when the restorer gene was transferred into CMS line, excessive production of ROS could be eliminated in the anthers of hybrid F₁. The restorer gene likely plays an important role in keeping the dynamic balance between the production and elimination of ROS.