Diana Salles Sampaio

Self-sterility in the hexaploid Handroanthus serratifolius (Bignoniaceae), the national flower of Brazil

Polyploidization is common among angiosperms and might induce typically allogamous plants to become autogamous (self-compatible, relying on sexual self-fertilization) or apomictic (achieving asexual reproduction through seeds). This work aimed to determine whether neopolyploidy leads to the breakdown of the self-incompatibility system in the hexaploid non-apomictic species Handroanthus serratifolius (Vahl) S. Grose, through analyses of its floral biology, pollination biology and breeding system. Although anthesis lasted for three days, increasing the overall floral display, receptivity decreased as of the second day. Centridini and Euglossini bees were the main pollinators, and low nectar availability (1.95 ± 1.91 µl/flower) might have obliged them to visit multiple flowers. We observed low reproductive efficacy. That might be explained by self-sterility and by the great number of flowers per individual, which could increase the frequency of geitonogamy. Ovule penetration by the pollen tubes in self-pollinated pistils with posterior abscission indicated late-acting self-incompatibility in H. serratifolius, as observed in other diploid Bignoniaceae species, although inbreeding depression cannot be excluded. The self-sterility found in the monoembryonic, hexaploid individuals studied here contrasts with the results for other neopolyploid Handroanthus and Anemopaegma species, which are often autogamous and apomictic. Our results suggest that neopolyploidy is not the main factor leading to self-fertility in Handroanthus.

Ontogenia da semente de Tabebuia ochracea (Cham.) Standl. (Bignoniaceae)

The present work describes seed ontogeny in T. ochracea through histological analysis with special reference to the endospermogenesis. The ovule is anatropous, unitegmic and tenuinucelate; hypostase, nutrient passage route and endothelium are present. The endosperm is cellular with posterior development of Catalpa type. The chalazal haustorium of endosperm is primary, bicellular and it is totally degenerated during seed maturity; on the contrary the micropylar one is secondary, multicellular, differentiates latter, and remains active until the seed maturity.A latter differentiated endosperm was observed forming, together with the endothelium, a membranaceous envelope of the embryos. The endospermogenesis are in accord with previous results from other species of Tabebuia. Furthermore, the micropylar haustorium diferentiation and the membranaceous envelope origin were elucidated, the latter probably is the same in other species that present this structure.

Sporophytic apomixis in polyembryonic Handroanthus serratifolius (Vahl) S.O. Grose (Bignoniaceae) characterizes the species as an agamic polyploid complex

Neopolyploidy has been associated with gametophytic apomixis and breakdown of gametophytic self-incompatibility. Nevertheless, Bignoniaceae presents agamic polyploid complexes with neopolyploidy associated to sporophytic apomixis. Apomictic populations are commonly polyploid, polyembryonic and self-fertile, while diploids are mostly late-acting self-incompatible (LSI) and monoembryonic. Contrastingly, Handroanthus serratifolius shows hexaploid monoembryonic and polyembryonic populations, although breeding system has been studied only for monoembryonic individuals, which are LSI. Our aim here was to investigate breeding system and early embryology in polyembryonic individuals of H. serratifolius to define if they form an agamic polyploid complex. Experimental pollinations and histological analyzes of ovules and young seeds were carried out. Megasporogenesis and megagametogenesis occurred as in other sexual species of Bignoniaceae. The polyembryonic individuals were self-fertile and double fertilization was observed both after self and cross-pollinated pistils. Adventitious embryos originated from the hypostasis and integument of the ovule, indicating sporophytic apomixis. Adventitious embryo precursor cells occurred in all pistils, including unpollinated ones. But unpollinated pistils aborted possibly due to absence of endosperm, and pollination was required for fruit-set (pseudogamy). It is possible that the self-fertility in polyembryonic individuals ensues as the initial endosperm of self-fertilized ovules supply early adventitious embryos development, and these embryos would later prevent the abortion of selfed pistils. The sporophytic apomixis in polyembryonic populations and the occurrence of sexual monoembryonic populations of H. serratifolius allows us to consider the species part of an agamic polyploid complex. But in contrast with other Handroanthus agamic complexes, both apomictic and sexual LSI plants were hexaploid.

Floral ontogeny of Aeschynomene falcata and A. sensitiva (Leguminosae: Papilionoideae) supports molecular phylogenetic data

Floral ontogeny and morphology of the Leguminosae are of interest because of their potential to provide characteristics useful for phylogeny. To determine if these features corroborate the phylogenetic segregation of the section Ochopodium from Aeschynomene, this study used comparative analysis between Aeschynomene falcata and A. sensitiva, which are within the sections Ochopodium and Aeschynomene, respectively. Flower buds were analysed by use of scanning electron microscopy. Aeschynomene falcata has a unidirectional initiation of sepals from the abaxial side, and a tendency toward whorled initiation for petals and stamens. At maturity, it has a calyx tube with five lobes, a pubescent standard petal, keel petals with coherent (but not fused) margins above and below the stamens, and a carpel with a long hairy stipe. Aeschynomene sensitiva has a distinct initiation pattern of petals (1st abaxial, 2nd adaxial, and 3rd lateral) and a tendency toward whorled initiation of sepals and stamens. Overlap between sepals, petals, and antesepalous stamens initiation was observed. At maturity, A. sensitiva has a glabrous bilobed calyx and a glabrous standard petal, keel petals postgenitally fused above the stamens, and a carpel with a short and glabrous stipe. Floral ontogeny and morphology of A. falcata are very similar to those of Machaerium and Dalbergia species so far studied, corroborating the phylogenetic proximity of section Ochopodium to these genera. Important features of the floral ontogeny of A. sensitiva seem to be related to the origin of the bilobed calyx, which is shared with the rest of Aeschynomeninae except section Ochopodium, suggesting they are synapomorphies for those species.

Sexual, apomictic and mixed populations in Handroanthus ochraceus (Bignoniaceae) polyploid complex

Some tropical Bignoniaceae form sporophytic apomictic polyploid complexes are similar to better studied temperate plants. Handroanthus ochraceus is a widely distributed Neotropical savanna tree with both monoembryonic/self-sterile, and polyembryonic/apomictic and self-fertile populations, but lacking chromosome number and morphological comparative studies. We tested if monoembryonic/non-apomictic and polyembryonic/apomictic populations differed in ploidy and morphological features, as a basis to understand evolution and biogeography of these plants. Chromosome number and embryo number per seed were investigated, and uni- and multivariate analyses of flower and leaf morphology were done for five populations of H. ochraceus. We found two pure monoembryonic diploid (2n = 40), and one pure polyembryonic (62–94% of polyembryonic seeds) tetraploid population (2n = 80). One of the diploid populations presented only one individual with 3.2% polyembryonic seeds and was considered a non-apomictic population. Another population showed predominantly polyembryonic (27–66% of polyembryonic seeds) tetraploid individuals, but one diploid individual with 2% of polyembryonic seeds, and was considered a mixed apomictic and non-apomictic population. Morphological analyses confirmed breeding system clusters, and that stigma width, as well as pollen grain area, was consistently larger in polyembryonic populations. Polyploid plants showed larger cells, as well as larger organs and other distinctive features, which will be useful to identify apomictic populations and to future taxonomic discussions. The species can be considered an agamic complex with apomixis associated with neopolyploidy. This trend is also found in other tropical sporophytic apomictics, contrasting with the usual reports linking diploidy or paleopolyploidy to this kind of apomictics.