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     

Molecular evidence that most RNAs required for germination and pollen tube growth are stored in the mature pollen grain in petunia

After landing on the stigma, the pollen grain germinates and elongates a tube to deliver its generative nuclei to the egg cell of the ovule. The molecular mechanisms involved in the drastic morphological changes in the pollen grain during this fertilization process remain largely unknown. In this study, the expression of 732 randomly selected genes in petunia pollen and pollen tubes was analyzed by microarray and quantitative PCR analyses. We found no evidence for up-regulation of any of these genes in the pollen tube. Our findings provide support at the gene level for the longstanding hypothesis that pollen germination and tube growth are not dependent on new RNA synthesis and that the large number of RNAs required for germination and tube growth are stored in mature pollen grains.     

Division of the generative nucleus in cultured pollen tubes of the Bromeliaceae

Pollen germination, division of the generative nucleus and position of the generative nucleus in the pollen tube during in vitro germination were examined for six bromeliad cultivars. The influence of mixed amino acids (casein hydrolysate) and individual amino acids (Arg, Asn, Asp, Glu, Gly, Met, Phe, Orn, Tyr) were tested. Aechmea fasciata and A. chantinii pollen tubes showed more generative nuclear division in cultured pollen tubes than the other four cultivars tested. Casein hydrolysate did not stimulate generative nuclear division. In general arginine (1 mM) improved division of the Aechmea generative nucleus and to a lesser extent this of Vriesea `Christiane', Guzmania lingulata and Tillandsia cyanea. A concentration of 2 mM arginine reduced pollen tube growth of Aechmea. The vegetative nucleus was ahead of the generative nucleus in approximately 50% of the pollen tubes of all cultivars studied. In about 25% of the pollen tubes, the generative nucleus was ahead and in ±25% pollen tubes the vegetative and generative nuclei were joined together. The distance between the two generative nuclei and the distance from the generative nuclei to the pollen tube tip differed significantly for Aechmea fasciata and A. chantinii. The influence of different amino acids for Aechmea fasciata and A. chantinii varied with respect to pollen germination and generative nuclear division. Arg and Met improved nuclear division of both Aechmea cultivars. Pollen germination and sperm cell production were not linked. This information is important to ameliorate in vitro pollination methods used to overcome fertilization barriers in Bromeliaceae and other higher plants.     

An autoradiographic study of RNA synthesis during maturation and germination of pollen grains ofHyoscyamus niger

Summary The pattern of RNA synthesis during maturation and germination of pollen grains ofHyoscyamus niger was studied using³H-uridine autoradiography. Incorporation of label during pollen maturation was periodic with peak RNA synthesis occurring in the uninucleate, nonvacuolate pollen grains and in the vegetative cell of the bicellular pollen grains. During the early stages of germination, isotope incorporation occurred predominantly in the nucleus of the vegetative cell with little or no incorporation in the generative cell. With the appearance of the pollen tube, incorporation of³H-uridine in the vegetative cell nucleus decreased and completely disappeared at later stages of germination. No incorporation of isotope was observed in the sperms formed in the pollen tube by the division of the generative cell. From a comparison of the results of this study with those of previous works on RNA synthesis during pollen embryogenesis in cultured anthers ofH. niger, it is concluded that in contrast to embryogenic development, there is no requirement for sustained RNA synthesis by the generative cell nucleus for normal gametophytic development.     

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.     

Cdi gene is required for pollen germination and tube growth in Arabidopsis

Pollen germination and tube growth are of essential importance to sexual reproduction of flowering plants. Several biological processes including cell wall biosynthesis and modification are known to be involved in pollen tube growth, though the underlying molecular mechanisms remain largely to be investigated. Here we report the identification and functional characterization of the Arabidopsis gene Cdi, which encodes a putative nucleotide-diphospho-sugar transferase. Cdi is preferentially expressed in pollen grains and pollen tubes. Transient expression of Cdi:GFP fusion protein showed that CDI is localized in the cytosol. Mutation in Cdi impaired pollen germination and pollen tube growth thus leading to disrupted male transmission. These results suggest that Cdi is an essential gene required for pollen germination and tube growth.     

Differential localization of the LIM domain protein PLIM-1 in microspores and mature pollen grains from sunflower

 PLIM-1 is a LIM domain protein specifically expressed in pollen grains. Using two PLIM-1-specific monoclonal antibodies we studied its expression and intracellular location at various developmental stages of sunflower (Helianthus annuus L.) pollen. Our studies show that the protein appears at the microspore stage in a limited number of cytoplasmic bodies, becomes undetectable in bicellular pollen, and reappears in tricellular pollen grains in cortical patches particularly concentrated in the F-actin-enriched germination cones of the vegetative cell. The developmental stage-dependent, different location of the protein suggests a dual function during pollen development. While this function in microspore development remains obscure, the high concentration of PLIM-1 in the germination cones of mature pollen suggests that it participates in the germination process as well as in pollen tube growth. Received: 11 August 1998 / Revision accepted: 15 December 1998