Quantitative cytology of the alfalfa generative cell and its relation to male plastid inheritance patterns in three genotypes

Summary Studies utilizing restriction analysis of plastid DNA, as well as those employing chlorophyll-deficient mutants, have shown a high frequency of paternal plastid transmission in alfalfa. Recent research has also shown that plastid inheritance patterns among alfalfa genotypes and are under genetic control. In a previous study we were unable to detect any correlations between qualitative, three-dimensional ultrastructure of generative cells and male plastid transmission strength in certain genotypes. In the present study we used serial ultrathin sectioning, computerized reconstruction and quantitation, and stereology to further analyze generative cells within mature pollen. Measurements included volumes and surface areas of cells, nuclei, and organelles, as well as organelle number and distribution. Three genotypes were investigated, one that is a strong transmitter of male plastids (genotype 301), one that is a weaker transmitter of male plastids (genotype 7W), and a third that is an even weaker male plastid transmitter (genotype MS-5). Our results show that genotype MS-5 has significantly fewer plastids/generative cell than either of the other genotypes, which may account for it being a relatively poor transmitter of male plastids. However, plastid number does not explain known differences in male plastid inheritance between genotypes 301 and 7W, since plastid number does not differ significantly between these two genotypes. Regarding the other features of generative cells measured in this study, no consistent correlations were found that might account for differences in male plastid inheritance patterns between genotypes. Plastid distribution is equal in each end of the spindle-shaped generative cell in all genotypes studied. Similar relative results were found with regard to mitochondria within generative cells; however, comparative genetic data are not available on mitochondrial transmission patterns in alfalfa genotypes.     

Quantitative,three-dimensional analysis of alfalfa egg cells in two genotypes: Implications for biparental plastid inheritance

In alfalfa (Medicago sativa L.), plastids are inherited biparentally. Patterns of plastid transmission vary according to the genotypes involved, but there is a strong bias in favor of male plastid transmission. Previous cytological studies on the male gametophyte of this species have not provided an adequate explanation for the differences in plastid transmission frequencies among genotypes. In the present study, we compared egg cells from genotypes classified as strong or weak plastid transmitters to determine whether plastid transmission strength is correlated with egg cell structure before fertilization. We found that plastids in the mature egg cells of the strong female (genotype 6–4) are significantly larger than in mature eggs of the weak female (genotype CUF-B), and that significantly more plastids are positioned in the apical portion of the mature egg cell of genotype 6–4 than in CUF-B. Immature eggs in the two genotypes show the same pattern as mature eggs with regard to plastid number and polarization. Since only the apical portion of the egg cell/zygote gives rise to the functional embryo, these results indicate that the potential input of female plastids, in terms of plastid size and number, may be an important factor in determining the inheritance patterns of these organelles in alfalfa.Support for this work by the United States Department of Agriculture under grant 88-37234-3876, the National Science Foundation under grant DCB-9103658, the Organized Research Fund of Northern Arizona University, and the Arizona Agricultural Experiment Station is gratefully acknowledged. We are indebted to Dr. Craig Caldwell, Northern Arizona University Computer Visualization Laboratory, for his expert help with the computer graphics.     

The zygote and proembryo of alfalfa: quantitative,three-dimensional analysis and implications for biparental plastid inheritance

Summary Genetic studies have demonstrated biparental inheritance of plastids in alfalfa. The ratio of paternal to maternal plastids in the progeny varies according to the genotypes of the parents, which can be classified as strong or weak transmitters of plastids. Previous cytological investigations of generative cells and male gametes have provided no consistent explanation for plastid inheritance patterns among genotypes. However, plastids in the mature egg cells of a strong female genotype (6–4) were found to be more numerous and larger than in mature eggs of a weak female genotype (CUF-B), and the plastids in 6–4 eggs are positioned equally around the nucleus. In CUF-B, the majority of plastids are positioned below (toward the micropyle) the mid level of the nucleus, which is the future division plane of the zygote. Since only the apical portion of the zygote produces the embryo proper, plastids in the basal portion were predicted to become included in the suspensor cells and not be inherited. In the present study, we examined zygotes and a two-celled proembryo from a cross between CUF-B and a strong male genotype (301), a cross that results in over 90% of the progeny possessing paternal plastids only. Our results indicate that the distribution of plastids observed in the CUF-B egg cell is maintained through the first division of the zygote. Further, paternal plastids are similarly distributed; however, within the apical portion of the zygote and in the apical cell of the two-celled proembryo, the number of paternal plastids is typically much greater than the number of maternal plastids. These findings suggest that maternal and paternal plastid distribution within the zygote is a significant factor determining the inheritance of maternal and paternal plastids in alfalfa.     

Variation in generative cell plastid nucleoids and male fertility in Medicago sativa

Biparental inheritance of plastids has been documented in numerous angiosperm species. The adaptive significance of the mode of plastid inheritance (unior biparental) is poorly understood. In plants exhibiting paternal inheritance of plastids, DNA-containing plastids in the microgametophyte may affect survival or growth of the gametophyte or the embryo. In this study the number of plastids containing DNA (nucleoids) in generative cells and generative cell and pollen volumes were evaluated in a range of genotypes of Medicago sativa (alfalfa). M. sativa exhibits biparental inheritance of plastids with strong paternal bias. The M. sativa genotypes used were crossed as male parents to a common genotype and the relationships between the gametophytic traits measured and male reproductive success were assessed. Generative cell plastid number and pollen grain size exhibited opposing associations with male fertility. Path analysis showed that generative cell plastid number was negatively associated with male fertility. This study provides evidence that there may be a competitive advantage at fertilization afforded sperm that have minimized their organelle content. The apparent lack of strong selection for reduced plastid number in generative cells of M. sativa may be a reflection of the diminished importance of reproductive success due to its perenniality or its long use in cultivation.     

被子植物质体遗传的细胞学研究

植物细胞质遗传涉及细胞质中含DNA的两种细胞器——质体和线粒体从亲代至子代的传递。相对来说线粒体遗传的研究远不及质体的多,这可能是线粒体这种细胞器缺乏合适的表型突变体之故。高等植物质体遗传的研究历史可追溯到本世纪初在杂交试验中对叶色遗传的非孟德尔定律的发现,Baur在马蹄纹天竺葵(Pelargonium zonale)中从叶色突变体(白化体)的杂交遗传分析,发现了双亲质体遗传;而Correns在紫茉莉(Mirabilis jalapa)中则发现了单亲母本质体遗传(见Kuroiwa)。此后,对质体基因组突变性状遗传分析的研究,大量的资料说明了在被子植物中存在双亲质体遗传和单亲母系质体遗传两种类型,而后一种占大多数,仅少数是比较有规律的为双亲质体遗传或偶尔是双亲质体遗传。几十年来应用遗传分析的方法对被子植物质体遗传的研究,着重于揭示不同植物种质体的遗传是单亲母系或是双亲质体传递,以及探索杂种核基因对质体传递方式的影响。     

Influence of parental genotype on plastid inheritance in Medicago sativa

Research using chlorophyll-deficient mutants has shown that plastids are inherited biparentally in Medicago sativa L. (alfalfa). Variation in plastid transmission behavior was observed among crosses in earlier studies, but it was not determined whether this variation was under genetic control. In my research, genetic analyses of the frequencies of normal (G), chlorophyll-deficient (CD), and sectored (G and CD) progenies produced from G x CD crosses demonstrated that plastid inheritance patterns in alfalfa are influenced by both maternal and paternal genotypes. A strong paternal bias in plastid transmission existed in the majority of crosses despite the potential developmental disadvantages associated with paternally contributed CD plastids. The high frequencies of uniparental progenies suggest that genetic control of plastid inheritance in alfalfa may be exerted through effects on the number and distribution of maternal and paternal plastids early in embryo development.     

Heritable paternal cytoplasmic organelles in alfalfa sperm cells: ultrastructural reconstruction and quantitative cytology.

Sperm cells within pollen grains and pollen tubes of alfalfa (Medicago sativa L.) were observed at the ultrastructural level, and their plastid DNA was detected by DAPI (4,6-diamidino-2-phenylindole) staining. One sperm pair within the pollen grain and three sperm pairs within pollen tubes were reconstructed in three-dimensions from serial ultrathin sections. The two sperm cells are linked by cytoplasmic bridges in both pollen grains and tubes, and the vegetative nucleus is closely associated with the sperm cells within the pollen tube. The number of plastids and plastid nucleoids (DNA aggregates) in the sperm cell pair, collectively, is not significantly different from that in the generative cell; however, over 60% of the sperm cell plastids contain no DNA detectable with DAPI. The mean number of mitochondria in sperm cells is reduced from that in the generative cell (from 54 to 17), which suggests that paternal mitochondrial inheritance probably does not occur in the genotype investigated. Sperm cells of a pair may vary in their shape within the pollen grain and tube, but the number of plastids and mitochondria is not significantly different between the sperm cells. Therefore, heterospermy is not a factor determining cytoplasmic inheritance patterns in this species.     

Biparental inheritance of chloroplast DNA and the existence of heteroplasmic cells in alfalfa

Summary Mapping of chloroplast DNA (ctDNA) restriction fragment patterns from a chlorophyll deficient mutant and two phenotypically normal alfalfa genotypes (Medicago sativa L.) has demonstrated the existence of a distinct ctDNA genotype from each source. These unique restriction fragment patterns were utilized to identify maternal or paternal origin of ctDNA in hybrid plants from crosses involving the normal alfalfa genotypes as females and the yellow-green chlorophyll deficient sectors as males. Progeny from these crosses expressing the yellow-green sectored phenotypes contained paternal ctDNA in the chlorophyll deficient sectors and maternal ctDNA in the normal sectors, confirming biparental plastid inheritance. The existence of mixed cells containing both mutant and normal plastids at various stages of sorting-out was observed by transmission electron microscopy of mesophyll cells in mosaic tissue from hybrid plants. This observation verified the biparental transmission of plastids in alfalfa.     

Ultrastructural studies on plastids of generative and vegetative cells in Liliaceae

Summary The behaviour of plastids and mitochondria during the formation and development of the male gametophyte of Chlorophytum comosum has been investigated using electron microscopy. During first pollen mitosis an intracellular polarization of plastids occurs in that the plastids are clustered in the centre of the microspore. The originating generative cell normally lacks plastids. Only in a small number of microspores have plastids been observed near the dividing nucleus of the microspore and later on in the generative cell. These observations agree with the genetic investigations of Collins (1922) on the mode of plastid inheritance which demonstrated a small amount of biparental plastid inheritance in Chlorophytum. The cytological mechanisms underlying plastid polarization during the first pollen mitosis are discussed.     

Investigation on the Development of Male Cametophyte in Anemarrhena Asphodeloides

Anemarrhena asphodeloides is a monotypic genus of Liliaceae, endemic to China and Korea. This genus is characterized by possessing three stamens. From development of male gametophyte, three features of the species are noteworthy. (1) During meiosis of the micros- pore mother cells, the Golgi vesicles are immediately incorporated into the formation of the material of callose wall; The latter lying at the outer tangential is about 4 gm in thickness dining formation of the tetrad. In the outer tangential callose wall there are certain cytoplasmic canals, which are about 0.6 to 1 μm in diameter. During the development of pollen grains, there are a number of other vesicles dispersing in the cytoplasm of the microspores. The activity of these vesicles seems to be involved in accumulation and formation of lipid bodies. But the above vesicles, which were derivxed from Golgi or endoplasmic reticulum, have not been known in this genus. (2) By two-celled stage of pollen grains, the unequal distribution of lipid bodies is very prominent, and they are singular in being placed on the boundary between the plasmalemma of vegetative and generative cells. While the generative cell is delached from the intine of pollen grain, the generative cell is surrounded by the lipid bodies which had been called the corona of them. By the observation of TEM, these lipid bodies come from the cytoplasm of vegetative cell and did not remain a constant surrounding layer. Towards the stage of pollen maturation, the lipid bodies lying oppositely to the nucleus of vegetative cell were gradually dispersed in the cytoplasm. Their function is unknown but the observation shows that some of them move to the plasmalemma of the pollen grain. (3) An important feature of the mature pollen grain in Anemarrhena is that the generative cell does not contain plastids during polle development. On the basis of cytological mechanisms of the plastid inheritance, Hagemann (1983) has classified the angiosperms into four groups of species, of which the Lycopersicum type, Solanum type, and Triticum type belong to the mode of a uniparental maternal inheritance of plastids; while the Pelargonium type represents the mode of biparental inheritance of plastids. Our studies have confirmed that the mode of plastid inheritance in Anemarrhena asphodeloides is similar to Gasteria verrucosa, both show the same mode of plastid inheritance of Lycopersicum type.     

Cytological Basis of Plastid Inheritance in Phaseolus vulgaris-Investigations of Plastids,Mitochondria and Their DNA Nucleoids During Pollen Development

Electron microscopic and DNA fluorescence microscopic observations of the plastids, mitochondria and their DNA in the developing pollen of Phaseolus vulgaris L. have demonstrated that the male plastids were excluded during microspore mitosis. The formed generative cell was free of plastids because of regional localization of plastids in early developing microspore and the extremely unequal distribution during division. The fluorescence observations of DNA showed that cytoplasmic (plastid and mitochondria) nucleoids degenerated and disappeared during the development of microspore/pollen, and were never presented in the generative cell at different development stages. These results provided precise cytological evidence of maternal plastid inheritance in Phaseolus vulgaris, which was not in accord with the biparental plastid inheritance identified from early genetic analysis. Based on authors' previous observations in a variety of common bean that the organelle DNA of male gamete was completely degenerated, the early genetic finding of the biparental plastid inheritance was unlikely to be effected by genotypic difference. Thus those biparental plastid inheritance might be caused by occational male plastid transmission, and plastid uniparental maternal inheritance was the species character of Phaseolus vulgaris.     

菜豆花粉发育中质体和线粒体及其DNA存在的状况——着重阐明质体遗传的细胞学基础

应用电镜和DNA的DAPI荧光检测技术研究了菜豆(Phaseolus vulgaris L.)小孢子/花粉发育中质体和线粒体及其DNA存在的状况。观察表明:在小孢子分裂时质体全部分配到营养细胞中,初形成的生殖细胞已不含质体。线粒体和质体的DNA在花粉发育中也先后降解,生殖细胞从刚形成时发育至成熟花粉时期这两种细胞器DNA均不存在。研究结果为菜豆质体母系遗传提供了确切的细胞学证据。遗传分析的研究曾确定菜豆质体为双亲遗传,对与本研究结论不同的原因进行了讨论。     

Populations of plastids and mitochondria during male reproductive cell maturation in Nicotiana tabacum L.: A cytological basis for occasional biparental inheritance

The dynamics of plastid and mitochondrial populations in male reproductive cells of tobacco (Nicotiana tabacum L.) were examined during development using serial ultrathin sections and transmission electron microscopy to reconstruct 58 generative cells and 31 sperm cells at selected stages of maturation from generative cell formation through gametic fusion. The first haploid mitosis resulted in incomplete exclusion of plastids providing an average of 2.81 plastids and 82.7 mitochondria for each newly formed generative cell. During generative-cell maturation, plastid content decreased to an average of 0.48 plastids/generative cell at anthesis owing to autophagy of organelles. Plastids were present in low frequency within generative and sperm cells in the pollen tube and appeared to be transmitted, according to observations immediately prior to fertilization. This forms a cytological basis for genetic reports of occasional biparental plastid inheritance. In contrast, mitochondria were transmitted in larger numbers, and approximately 80 mitochondria per generative cell or sperm cell pair were retained throughout development. This provides a potentially stable source for the transmission of male mitochondrial DNA, if present at fertilization.Abbreviations GC generative cell - SC sperm cell We thank Dr. Frank J. Sonleitner, for helpful suggestions on the statistical calculations and Dr. Bing-Quan Huang for technical assistance in the preparation of embryo sacs during fertilization. This research was supported in part by U.S. Department of Agriculture grant 91-37304-6471. We gratefully acknowledge use of the Samuel Roberts Noble Electron Microscopy Laboratory of the University of Oklahoma.     

Cytological Studies of the Cytoplasmic Inheritance in Lilium regale and L. davidii

The distribution and characteristics of plastids and mitochondria in the generative and sperm cells of Lilium regale Wils. and L. davidii Duch. were described. In L. regale there were few plastids and abundant mitochondria in the newly formed generative cell. When the generative cell became free in the vegetative cytoplasm, the plastids degenerated completely within the generative cell. It was further proved by DAPI fluorescent technique that there was no organell DNA in the generative cell within the mature pollen grain or the pollen tube. However, distribution of the plastids was strictly polarizable during the division of the micmspore in L. davidii, resulting the lack of plastids in the newly formed generative cell. Data of RFLP analysis comparable between L. davidii, L. longifiorum and their interspecific hybrid have also proved the plastid inheritance in L. davidii to be of uniparental maternal transmission. Although the mitoehondria were observed both in the generative and sperm cells of L. regale and L. davidii but their DNA was decomposed in the male gametophyte stage. Therefore the mitochondda in the sperm cell could not be transmitted into the offspring. The results provided the detail, cytological evidence that organelles in the microgametophyte are incapable of genetic transmission in the two species of Lilium.     

Mechanisms of maternal inheritance of plastids and mitochondria: Developmental and ultrastructural evidence

Summary A number of maternally inherited characters are now known to be associated with mitochondria or chloroplasts, which contain small genomes segregating separately from that of the nucleus. The reason often given for maternal inheritance of plastid-associated characters in plants is the absence of plastids in the generative cell of pollen following an unequal mitosis (Vaughn, 1980). However, fine ultrastructural studies have not established “exclusion” as the sole mechanism for maternal inheritance; in many cases, other mechanisms may be operating. Three lines of evidence concerning the mechanism of maternal inheritance will be discussed: First, while it is true that thorough fine ultrastructural studies have failed to find plastids in generative cells of many seed plants (Cass and Karas, 1975), similar studies in some seed plants have found plastids or structures taken to be plastids in generative cells, and a few studies using serial section electron microscopy to re-examine some plants in the first group have found plastids in generative cells and even in the sperm. Also, the exclusion model fails to account at all for maternal inheritance of mitochondria, which are found nearly universally in the generative cells and sperm which have been studied ultrastructurally. Second, maternal inheritance of plastid characters is seen in many lower plants and algae, despite the presence of plastids and mitochondria in the male gametes and their reported deposition in the zygote. Third, there is evidence for an alternative or additional mechanism which may occur in many plants: mitochondria and plastids in male gametes may be altered during development or syngamy so that, although not excluded, they are genetically and perhaps functionally debilitated, which would result in maternal inheritance. This evidence derives both from ultrastructural studies of pollen and fertilization, and from genetic and developmental analysis of algal zygotes and of embryos derived from pollen tissue culture. This mechanism is logically attractive in that it allows for the observed continuum of variation from strict uniparental inheritance in a number of plants, which cannot be explained by the “all-or-nothing” exclusion hypothesis. Indeed, it may be appropriate to think of both mechanisms as part of a continuum ranging from destruction within the zygote, to exclusion during syngamy, to pre-fertilization debilitation, to absence from male gametes and generative cells (Russell and Cass, 1981).     

Microgametogenesis in Plumbago zeylanica (Plumbaginaceae). 2. Quantitative cell and organelle dynamics of the male reproductive cell lineage

Quantitative cell and organelle dynamics of the male gamete-producing lineage of Plumbago zeylanica were examined using serial transmission electron microscopic reconstruction at five stages of development from generative cell inception to sperm cell maturity. The founder population of generative cell organelles includes an average of 3.88 plastids, 54.9 mitochondria, and 3.7 vacuoles. During development the volume of the pollen grain increases from 6,200 μm³ in early microspores to 115,000 μm³ at anthesis, cell volume of the male germ lineage decreases more than 67% from 362.3 μm³ to 118.4 μm³. By the time the generative cell separates from the intine, plastid numbers increase by >600%, mitochondria by 250%, and vesicles by 43 times. A cellular projection elongates toward and establishes an association with the vegetative nucleus; this leading edge contains plastids and numerous mitochondria. When the generative cell completes its separation from the intine, organellar polarity is reversed and plastids migrate to the opposite pole of the cell. Cytoplasmic microtubules are common in association with cellular organelles. Plastids accumulate at the distal end of the cell as a linked mass, apparently adhered by lateral electron dense regions. Before division of the highly polarized generative cell, plastids decrease in number by 16%, whereas mitochondria increase by ∼90% and vacuoles increase by ∼140% from the prior stage. After mitosis, the resultant sperm cells differ in size and organelle content. The sperm cell associated with the vegetative nucleus (S_vn) contains 62.7% of the cytoplasm volume, 87% of the mitochondria, 280.4 vesicles (79% of those in the generative cell), and 0.6% of the plastids. At maturity, the S_vn mitochondria increase by 31% and the cell contains an average of 0.4 plastids, 158.9 vesicles, and 0.36 microbodies. The mature unassociated sperm (S_ua) contains 39.8 mitochondria (up 3.3%), 24.3 plastids (down 31%), 91.1 vesicles (up 54.9%), and 3.18 microbodies. The small number of organelles initially in the generative cell, followed by their rapid multiplication in a shrinking cytoplasm suggests a highly competitive cytoplasmic environment that would tend to eliminate residual organellar heterogeneity. Cell and cytoplasmic volumes vary as a consequence of fluctuations in the number and size of large vesicles or vacuoles, as well as loss of cytoplasmic volume by (1) formation of “false cells” involving amitotic cytokinesis, (2) “pinching off” of cytoplasm, and (3) dehydration of pollen contents prior to anthesis.     

Ultrastructural studies on plastids of generative and vegetative cells inLiliaceae 3. Plastid distribution during the pollen development inGasteria verrucosa (Mill.) Duval

Summary This paper describes the development of pollen grains ofGasteria verrucosa from the late microspore to the mature two-cellular pollen grain. Ultrastructural changes and the distribution of plastids as a result of the first pollen mitosis have been investigated using light and electron microscopy. The microspores as well as the generative and the vegetative cell contain mitochondria and other cytoplasmic organelles during all of the observed developmental stages. In contrast, the generative cell and the vegetative cell show a different plastid content. Plastids are randomly distributed within the microspores before pollen mitosis. During the prophase of the first pollen mitosis the plastids become clustered at the proximal pole of the microspore. The dividing nucleus of the microspore is located at the distal pole of the microspore. Therefore, the plastids are not equally distributed into both the generative and the vegetative cell. The possible reasons for the polarization of plastids within the microspore are briefly discussed. The lack of plastids in the generative cell causes a maternal inheritance of plastids inGasteria verrucosa.     

Occurrence of plastids in the sperm cells of Caprifoliaceae: biparental plastid inheritance in angiosperms is unilaterally derived from maternal inheritance

It is widely held that organelles inherit from the maternal lineage. However, the plastid genome in quite a few angiosperms appears to be biparentally transmitted. It is unclear how and why biparental inheritance of the genome became activated. Here, we detected widespread occurrence of plastids in the sperm cells (a cellular prerequisite for biparental inheritance) of traditional Caprifoliaceae. Of the 12 genera sampled, the sperm cells of Abelia, Dipelta, Heptacodium, Kolkwitzia, Leycesteria, Linnaea, Lonicera, Symphoricarpos, Triosteum and Weigela possessed inheritable plastids. The other genera, Sambucus and Viburnum, lacked plastids in sperm cells. Interestingly, such exclusion of plastids in the sperm cells of some Caprifoliaceae appeared to be associated with the divergence of Dipsacales phylogeny. Closer examination of Weigela florida revealed that both plastids and plastid DNA were highly duplicated in the generative cells. This implies that the appearance of plastids in sperm cells involved cellular mechanisms. Because such mechanisms must enhance the strength of plastid transmission through the paternal lineage and appear ubiquitous in species exhibiting biparental or potential biparental plastid inheritance, we presume that biparental plastid genetics may be a derived trait in angiosperms. This is consistent with our extended phylogenetic analysis using species with recently discovered modes of potential plastid inheritance. The results show that basal and early angiosperms have maternal plastid transmission, whereas all potential biparental transmission occurs at terminal branches of the tree. Thus, unlike previous studies, we suggest that biparental plastid inheritance in angiosperms was unilaterally converted from the maternal transmission mode during late angiosperm evolution.     

Divergent potentials for cytoplasmic inheritance within the genus Syringa. A new trait associated with speciogenesis

Epifluorescence microscopic detection of organelle DNA in the mature generative cell is a rapid method for determining the potential for the mode of cytoplasmic inheritance. We used this method to examine 19 of the known 22 to 27 species in the genus Syringa. Organelle DNA was undetectable in seven species, all in the subgenus Syringa, but was detected in the 12 species examined of the subgenera Syringa and Ligustrina. Therefore, species within the genus Syringa display differences in the potential cytoplasmic inheritance. Closer examination revealed that the mature generative cells of the species in which organelle DNA was detected contained both mitochondria and plastids, but cells of the species lacking detectable organelle DNA contained only mitochondria, and the epifluorescent organelle DNA signals from the mature generative cells corresponded to plastid DNA. In addition, semiquantitative analysis was used to demonstrate that, during pollen development, the amount of mitochondrial DNA decreased greatly in the generative cells of the species examined, but the amount of plastid DNA increased remarkably in the species containing plastids in the generative cell. The results suggest that all Syringa species exhibit potential maternal mitochondrial inheritance, and a number of the species exhibit potential biparental plastid inheritance. The difference between the modes of potential plastid inheritance among the species suggests different phylogenies for the species; it also supports recent conclusions of molecular, systematic studies of the Syringa. In addition, the results provide new evidence for the mechanisms of maternal mitochondrial inheritance in angiosperms.     

Cytoplasmic DNA apportionment and plastid differentiation during male gametophyte development in Pelargonium zonale

In the male gametophyte of Pelargonium zonale, generative and sperm cells contain cytoplasmic DNA in high density compared to vegetative cells. Cytoplasmic DNA was examined using the DNA fluorochrome DAPI (4'6-diamidino-2-phenylindole) and observed with epifluorescence and electron microscopy. The microspore cell contains a prominent central vacuole before mitosis; mitochondria and plastids are randomly distributed throughout the cytoplasm. Following the first pollen grain mitosis, neither the vegetative cell nor the early generative cell display a distributional difference in cytoplasmic DNA, nor is there in organelle content at this stage. During the maturation of the male gametophyte, however, a significant discrepancy in plastid abundance develops. Plastids in the generative cell return to proplastids and do not contain large starch grains, while those in the vegetative cell develop starch grains and differentiate into large amyloplasts. Plastid nucleoids in generative and sperm cells in a mature male gametophyte are easily discriminated after DAPI staining due to their compactness, while those in vegetative cells stained only weakly. The utility of the hydrophilic, non-autofluorescent resin Technovit 7100 in observing DAPI fluorescence is also demonstrated.