Epigenetic marks in the mature pollen of Quercus suber L. (Fagaceae)

We have analysed the distribution of epigenetic marks for histone modifications at lysine residues H3 and H4, and DNA methylation, in the nuclei of mature pollen cells of the Angiosperm tree Quercus suber; a monoecious wind pollinated species with a protandrous system, and a long post-pollination period. The ultrasonic treatment developed for the isolation of pollen nuclei proved to be a fast and reliable method, preventing the interference of cell wall autofluorescence in the in situ immunolabelling assays. In contrast with previous studies on herbaceous species with short progamic phases, our results are consistent with a high level of silent (5-mC and H3K9me2) epigenetic marks on chromatin of the generative nucleus, and the prevalence of active marks (H3K9me3 and H4Kac) in the vegetative nucleus. The findings are discussed in terms of the pollination/fertilization timing strategy adopted by this plant species.     

The developmental fate of angiosperm pollen is associated with a preferential decrease in the level of histone H1 in the vegetative nucleus

In angiosperm pollen, the vegetative cell is assumed to function as a gametophytic cell in pollen germination and growth of the pollen tube. The chromatin in the nucleus of the vegetative cell gradually disperses after microspore mitosis, whereas the chromatin in the nucleus of the other generative cell remains highly condensed during the formation of two sperm nuclei. In order to explain the difference in chromatin condensation between the vegetative and generative nuclei, we analyzed the histone composition of each nucleus in Lilium longiflorum Thunb. and Tulipa gesneriana immunocytochemically, using specific antisera raised against histones H1 and H2B of Lilium. We found that the level of histone H1 decreased gradually only in the vegetative nucleus during the development of pollen within anthers and that the vegetative nucleus in mature pollen after anther dehiscence contained little histone H1. By contrast, the vegetative nucleus contained the same amount or more of histone H2B than the generative nucleus. The preferential decrease in the level of histone H1 occurred in anomalous pollen with one nucleus (uninucleate pollen) or with two similar nuclei (equally divided pollen), which had been induced by treatment with colchicine. The nuclei in the anomalous pollen resembled vegetative nuclei in terms of structure and staining properties. The anomalous pollen was able to germinate and extend a pollen tube. From these results, it is suggested that the preferential decrease in level of histone H1 in pollen nuclei is essential for development of the male gametophytic cell through large-scale expression of genes that include pollen-specific genes, which results in pollen germination and growth of the pollen tube. Received: 9 May 1998 / Accepted: 4 June 1998     

Use of a nuclear-targeted β-glucuronidase fusion protein to demonstrate vegetative cell-specific gene expression in developing pollen

To examine the site of expression of the tomato anther-specific gene, LAT52, in the developing male gametophyte, the LAT52 gene promoter was fused to a nuclear-targeted version of the β-glucuronidase (GUS) gene and introduced into tobacco. Transformed plants expressing GUS activity showed nuclear localization of the GUS reaction product to the vegetative cell of the pollen grain. No staining or localization was detected in the generative cell, at pollen maturation or during pollen tube growth in vitro. These results clearly demonstrate differential gene expression within the male gametophyte, and highlight regulatory events which determine the differing fates of the vegetative and generative cells following microspore mitosis.     

Histone H3 variants in male gametic cells of lily and H3 methylation in mature pollen

Histones are vital structural proteins of chromatin that influence its dynamics and function. The tissue-specific expression of histone variants has been shown to regulate the expression of specific genes and genomic stability in animal systems. Here we report on the characterization of five histone H3 variants expressed in Lilium generative cell. The gcH3 and leH3 variants show unique sequence diversity by lacking a conserved lysine residue at position 9 (H3K9). The gH3 shares conserved structural features with centromeric H3 of Arabidopsis. The gH3 variant gene is strongly expressed in generative cells and gH3 histone is incorporated in to generative cell chromatin. The lysine residue of H3 at position 4 (H3K4) is highly methylated in the nuclei of generative cells of mature pollen, while methylation of H3K4 is low in vegetative cell nuclei. Taken together, these results suggest that male gametic cells of Lilium have unique chromatin state and histone H3 variants and their methylation might be involved in gene regulation of male gametic cells.Accession numbers for the sequence data The sequences reported in this paper have been deposited in the DDBJ database gcH3 GC1174 (accession no. AB195644), gH3 GC1008 (accession no. AB195646), leH3 GC1126 (accession no. AB195648), soH3-1 GC0075 (accession no. AB195650), soH3-2 GC1661 (accession no. AB195652), genomic sequence of gcH3 (accession no. AB195645), genomic sequence of gH3 (accession no. AB195647), genomic sequence of leH3 (accession no. AB195649), genomic sequence of soH3-2 (accession no. AB195651), genomic sequence of soH3-2 (accession no. AB195653).     

Distinct localization of histone H3 methylation in the vegetative nucleus of lily pollen

We analysed the distribution of histone H3 modifications in the nucleus of the vegetative cell (the vegetative nucleus) during pollen development in lily (Lilium longiflorum). Among the modifications specifically and/or abundantly present in the vegetative nucleus, dimethylation of histone H3 at lysine 9 (H3K9me2) and lysine 27 (H3K27me2) were found in heterochromatin, whereas trimethylation of histone H3 at lysine 27 (H3K27me3) was localized in euchromatin in the vegetative nucleus. Such unique localization of the histone H3 methylation marks, particularly of H3K27me3, within a nucleus was not observed in lily nuclei other than the vegetative nucleus. The level of H3K27me3 increased in the euchromatic region of the vegetative nucleus during pollen maturation. The results suggest that H3K27me3 controls the gene expression of the vegetative cell during pollen maturation.     

The Arabidopsis SDG4 contributes to the regulation of pollen tube growth by methylation of histone H3 lysines 4 and 36 in mature pollen

Plant SET domain proteins are known to be involved in the epigenetic control of gene expression during plant development. Here, we report that the Arabidopsis SET domain protein, SDG4, contributes to the epigenetic regulation of pollen tube growth, thus affecting fertilization. Using an SDG4-GFP fusion construct, the chromosomal localization of SDG4 was established in tobacco BY-2 cells. In Arabidopsis, sdg4 knockout showed reproductive defects. Tissue-specific expression analyses indicated that SDG4 is the major ASH1-related gene expressed in the pollen. Immunological analyses demonstrated that SDG4 was involved in the methylation of histone H3 in the inflorescence and pollen grains. The significant reduction in the amount of methylated histone H3 K4 and K36 in sdg4 pollen vegetative nuclei resulted in suppression of pollen tube growth. Our results indicate that SDG4 is capable of modulating the expression of genes that function in the growth of pollen tube by methylation of specific lysine residues of the histone H3 in the vegetative nuclei.     

Histone H4 acetylation and DNA methylation dynamics during pollen development

Summary The first pollen mitosis results in generative and vegetative cells which are characterised by a striking difference in their chromatin structure. In this study, histone H4 acetylation and DNA methylation have been analysed during pollen development inLilium longiflorum. Indirect immunofluorescence procedures followed by epifluorescence and laser scanning microscopy enabled a relative quantification of H4 acetylation and DNA methylation in microspores, immature binucleate pollen, mature pollen, and pollen tubes. The results show that histone H4 of the vegetative nucleus, in spite of its decondensed chromatin structure, is strongly hypoacetylated at lysine positions 5 and 8 in comparison with both the original microspore nucleus and the generative-cell nucleus. These H4 terminal lysines in the vegetative nucleus are, however, progressively acetylated during the following pollen tube growth. The DNA methylation analysis inversely correlates with the histone acetylation data. The vegetative nucleus in mature pollen grains is heavily methylated, but a dramatic nonreplicative demethylation occurs during the pollen tube development. Changes neither in H4 acetylation nor in DNA methylation have been found during development of the generative nucleus. The results obtained indicate that the vegetative nucleus enters the quiescent state (accompanied by DNA hypermethylation and H4 underacetylation) during the maturation of pollen grain which enables pollen grains a long-term survival without external source of nutrients until they reach the stigma.     

Differentiation of generative and vegetative cells in angiosperm pollen

 Cellular differentiation of a generative and a vegetative cell is an important event during microspore and pollen development and is requisite for double fertilization in angiosperms. The generative cell produces two sperm cells, or male gametes, whereas the vegetative cell produces an elongated pollen tube, a gametophytic cell, to deliver the male gametes to the embryo sac. For typical differentiation of the gametic and gametophytic cells, cell polarity, including nuclear positioning, must be established prior to microspore mitosis and be maintained during mitosis. Microtubules are closely involved in the process of asymmetric cell division. On the other hand, alteration of the chromatin composition seems to be responsible for the differential gene expression between the generative and vegetative cells. Cytoplasmic regulatory molecules, which affect chromatin configuration, are postulated to be unequally distributed to the two cells at the asymmetric cell division. Thus, typical differentiation of the cells is accomplished by a cellular mechanism and a molecular mechanism, which might be independent of each other. These results are discussed in relation to one model that accounts for the different fates of generative and vegetative cells during sexual plant reproduction. Received: 3 September 1996 / Revision accepted: 23 September 1996     

Cytophotometric study of nuclear differentiation during pollen development in Tradescantia Paludosa

Summary During pollen development the dry weight, total protein, histone, DNA, arginine, and lysine content were analysed by cytophotometric methods in partially isolated nuclei. The amount of analysed substances increased from the end of the meiosis to the mitosis of the microspores to the double of the initial values. After mitosis the ratio histone/DNA remained almost unchanged in both vegetative and generative nuclei. On the other hand a large difference in the ratio non-histone protein/DNA could be observed, the vegetative nucleus containing more non-histone protein than the generative nucleus. The rate of RNA synthesis being higher in the vegetative nuclei, these non-histone proteins may have some function in nuclear activation. The DNA of the generative nucleus is duplicated before anthesis, whilst in the vegetative nucleus the DNA content remains constant.     

Epigenetic control of reproductive development

Epigenetics is a rapidly expanding research field focused on gene regulation and differentiation. Due to a sessile life, plants have evolved diverse adaptive mechanisms that are controlled by epigenetic processes. Epigenetic molecular mechanisms are in principle shared by plants and animals. There are two basic stages in plant development: The germline is formed after the vegetative period of life. Similarly, a unique stage in plant life is a haploid gametophyte, a short but important period requiring gene expression. These transitions in plant life are controlled by epigenetic processes such as DNA methylation, nucleosomal histone modifications, and regulation via small RNAs. In this review we summarize epigenetic events in the course of transition from vegetative to generative development, formation of spores and gametes, and fertilization and embryogenesis.     

Changing patterns of nucleic acids, basic and acidic proteins in generative nuclei during pollen germination and pollen tube growth in Hippeastrum belladona

Generative and vegetative nuclei of mature and germinated pollen grains from Hippeastrum belladonna were separated in a continuous Ficoll gradient. Less than 3% contamination was observed between the generative and vegetative nuclear fractions. The vegetative nuclei were composed of two populations; the larger population consisted of nuclei with 1C levels of DNA and the smaller with 2C levels. The generative nuclei consisted of a homogeneous population composed of nuclei possessing 2C levels of DNA. Histone synthesis did not occur in vegetative nuclei. Changes appeared in the gel-electrophoretic banding patterns of the F1 histones of vegetative nuclei during germination. Changes were not observed in the generative nuclei. A reduction of general proteins and RNA was observed in vegetative nuclei by 20 h of germination. The phenol-soluble nuclear proteins of vegetative nuclei revealed transitions in electrophoretic banding patterns during pollen germination that were greater than those shown by the histones. These changes in the PSNP primarily involved reduced concentrations of certain proteins rather than synthesis of new ones. However, a new band was observed in the electrophoretic pattern of the PSNP of vegetative nuclei after 12 h of pollen tube growth. No transition was seen in the PSNP of generative nuclei during pollen germination and tube growth. The regulatory role of the PSNP in cell differentiation is discussed in the light of these findings.     

Male Gametic Cell-specific Histone <Emphasis Type="Italic">gH2A</Emphasis> Gene of <Emphasis Type="Italic">Lilium longiflorum</Emphasis>: Genomic Structure and Promoter Activity in the Generative Cell

A genomic clone containing the gH2A gene, a histone variant specifically expressed in male gametic cells within the pollen of Lilium longiflorum, was isolated. Sequence analysis revealed that the coding region of the gene is interrupted by one intron, as is the case with the somatic type of plant histone H2A genes, suggesting derivation from the same ancestral gene containing one intron. In addition, a 2.8-kbp fragment of the 5′ upstream region of gH2A contained TATA and CAAT boxes, but neither a plant histone-specific regulatory DNA element nor vegetative cell-specific cis-elements were found. A histochemical study of stable transformants demonstrated that the 5′ upstream region of the gene can drive gene expression specifically in the generative cell of pollen; no activity was detectable in the vegetative cell or in other reproductive and vegetative tissues of transgenic Nicotiana tabacum. These results strongly suggest that the generative cell can direct specific gene expression, that this expression may be regulated by a putative male gametic factor, and that the gH2A promoter may therefore serve as a useful male gametic cell fate marker in angiosperms.     

Behavior of organelle nuclei (nucleoids) in generative and vegetative cells during maturation of pollen inLilium longiflorum andPelargonium zonale

Summary The behavior of organelle nuclei during maturation of the male gametes ofLilium longiflorum andPelargonium zonale was examined by fluorescence microscopy after staining with 4,6-diamidino-2-phenylindole (DAPI) and Southern hybridization. The organelle nuclei in both generative and vegetative cells inL. longiflorum were preferentially degraded during the maturation of the male gametes. In the mature pollen grains ofL. longiflorum, there were absolutely no organelle nuclei visible in the cytoplasm of the generative cells. In the vegetative cells, almost all the organelle nuclei were degraded. However, in contrast to the situation in generative cells, the last vestiges of organelle nuclei in vegetative cells did not disappear completely. They remained in evidence in the vegetative cells during germination of the pollen tubes. InP. zonale, however, no evidence of degradation of organelle nuclei was ever observed. As a result, a very large number of organelle nuclei remained in the sperm cells during maturation of the pollen grains. When the total DNA isolated from the pollen or pollen tubes was analyzed by Southern hybridization with a probe that contained therbc L gene, for detection of the plastid DNA and a probe that contained thecox I gene, for detection of the mitochondrial DNA, the same results were obtained. Therefore, the maternal inheritance of the organelle genes inL. longiflorum is caused by the degradation of the organelle DNA in the generative cells while the biparental inheritance of the organelle genes inP. zonale is the result of the preservation of the organelle DNA in the generative and sperm cells. To characterize the degradation of the organelle nuclei, nucleolytic activities in mature pollen were analyzed by an in situ assay on an SDS-DNA-gel after electrophoresis. The results revealed that a 40kDa Ca²⁺-dependent nuclease and a 23 kDa Zn²⁺ -dependent nuclease were present specifically among the pollen proteins ofL. longiflorum. By contrast, no nucleolytic activity was detected in a similar analysis of pollen proteins ofP. zonale.     

Absence of microspore polarity, symmetric divisions and pollen cell fate in Brachiaria decumbens (Gramineae).

Meiotic division and male gametophyte development were analyzed in one tetraploid (2n = 4x = 36) accession of Brachiaria decumbens cv. Basilisk that showed some pollen sterility. Meiotic process was typical of polyploids in that it consisted of multiple chromosome associations. Precocious chromosome migration to the poles, laggards, and micronucleus formation were abundant in both meiosis I and II and resulted in tetrads with micronuclei. After callose dissolution, microspores were released into the anther locule and had the semblance of being normal. Although each microspore initiated its differentiation by pollen mitosis, in 43.24% of the microspores, nuclear polarization was not observed and the typical hemispherical cell plate was not detected. Division was symmetric and microspores lacked differentiation between the vegetative and the generative cell. Both nuclei were of equal size, presented equal chromatin condensation, and had a spherical shape. After the first pollen mitosis and cytokinesis, each cell underwent a new symmetric mitosis without nuclear polarization. At the end of the second pollen mitosis, four equal nuclei were observed in each pollen grain. After the second cytokinesis, the cells gave rise to four equal-sized pollen grains with a similar tetrad configuration that initially remained together. Sterile pollen grains resulted from abnormal pollen mitosis. This anomaly may be explained by a mutation, probably affecting microtubule cytoskeleton formation. The importance of this male-sterile mutation for Brachiaria breeding programs is discussed.