The first spindle formation in brown algal zygotes

Regulation of the first spindle formation in brown algal zygotes was described. It is well known that there are three types of sexual reproduction in brown algae; isogamy, anisogamy and oogamy. Paternal inheritance of centrioles can be observed in all these cases, similar to animal fertilization. In isogamy and anisogamy, female centrioles (= flagellar basal bodies) selectively disappear and male centrioles remain after fertilization. In a typical oogamy (e.g. fucoid members), liberated egg does not have centrioles, and sperm centrioles are introduced in zygote. Participation of sperm centrioles to the spindle formation in zygotes was also described using Fucus distichus as a model system. Sperm centrioles function as a part of centrosome, namely microtubule organizing center, in zygote. Therefore, they have a crucial role in the spindle formation. Observations on the spindle formation in polygyny and karyogamy-blocked zygotes strongly suggest that egg nucleus can form a mitotic spindle by itself without centrosome, even though the resulting spindles are of abnormal shapes. %     

Cytoplasmic inheritance of mitochondria and chloroplasts in the anisogamous brown alga Mutimo cylindricus (Phaeophyceae)

Based on the morphology of gametes, sexual reproduction in brown algae is usually classified into three types: isogamy, anisogamy, and oogamy. In isogamy, chloroplasts and chloroplast DNA (chlDNA) in the sporophyte cells are inherited biparentally, while mitochondria (or mitochondrial DNA, mtDNA) is inherited maternally. In oogamy, chloroplasts and mitochondria are inherited maternally. However, the patterns of mitochondrial and chloroplast inheritance in anisogamy have not been clarified. Here, we examined derivation of mtDNA and chlDNA in the zygotes through strain-specific PCR analysis using primers based on single nucleotide polymorphism in the anisogamous brown alga Mutimo cylindricus. In 20-day-old sporophytes after fertilization, mtDNA and chlDNA derived from female gametes were detected, thus confirming the maternal inheritance of both organelles. Additionally, the behavior of mitochondria and chloroplasts in the zygotes was analyzed by examining the consecutive serial sections using transmission electron microscopy. Male mitochondria were isolated or compartmentalized by a double-membrane and then completely digested into a multivesicular structure 2 h after fertilization. Meanwhile, male chloroplasts with eyespots were observed even in 4-day-old, seven-celled sporophytes. The final fate of male chloroplasts could not be traced. Organelle DNA copy number was also examined in female and male gametes. The DNA copy number per chloroplast and mitochondria in male gametes was lower compared with female organelles. The degree of difference is bigger in mtDNA. Thus, changes in different morphology and DNA amount indicate that maternal inheritance of mitochondria and chloroplasts in this species may be based on different processes and timing after fertilization.

     

Behavior and function of paternally inherited centrioles in brown algal zygotes

In brown algal cells, the centrosome, consisting of a pair of centrioles and the pericentriolar material, is primarily involved in the organization of microtubules (MTs) throughout the cell cycle. In motile cells, the centrioles participate in the formation of flagellar axoneme as flagellar basal bodies, and in somatic cells they play a crucial role in many cellular activities as a part of the centrosome. With respect to the role of the centrosome as a microtubule organizing center (MTOC), brown algal cells resemble animal cells. In most animal fertilization processes, the sperm cell introduces centrioles, the core of the centrosome, into the egg cytoplasm. In this study, the behavior of centrioles from gametogenesis and fertilization to the first cell division of the zygote was examined in the three sexual reproduction patterns occurring in brown algae, i.e., oogamy, anisogamy and isogamy, by electron- and immunofluorescence-microscopy. The pair of centrioles contained in somatic cells was shown to be derived from the male gamete, irrespective of the sexual reproductive pattern. The paternally derived centrioles were duplicated before mitosis and were involved in spindle pole formation. Moreover, MTs from the centrosome play a crucial role in the process of cytokinesis, as the position of centrosomes accompanying daughter nuclei seems to determine the cytokinetic plane. A new approach to clarifying the mode of cytokinesis in brown algae is presented in this study.Chikako Nagasato was the recipient of the Botanical Society of Japan Award for Young Scientist, 2004.     

Destruction of maternal centrioles during fertilization of the brown alga, Scytosiphon lomentaria (Scytosiphonales, Phaeophyceae)

In brown algal fertilization, a pair of centrioles is derived from the male gamete, irrespective of the sexual reproduction pattern, i.e., isogamy, anisogamy, or oogamy. In this study, the manner in which the maternal centriole structure is destroyed in early zygotes of the isogamous brown alga Scytosiphon lomentaria was examined by electron microscopy. At fertilization, the zygote had two pairs of centrioles (flagellar basal bodies) derived from motile male and female gametes, and there was no morphological difference between the two pairs. The flagellar basal plate and the axonemal microtubules were still connected with the distal end of centrioles. Ultrastructural observations showed that the integrity of maternal-derived centrioles began to degenerate even in the 1-h-old zygote. At that time, the cylinder of triplet microtubules of the maternal centrioles became shorter from the distal end, and a section passing through the centrioles indicated that a part of the nine triplets of microtubules changed into doublet or singlet microtubules by degeneration of B and/or C tubules. In 2-h-old zygote, there was no trace of maternal centrioles ultrastructurally, and only the paternal centrioles remained. Further, reduction of centrin accompanying destruction of the maternal centrioles was examined in immunofluorescence microscopy. Centrin localized at the paternal and the maternal centrioles had the same fluorescence intensity in the early zygotes. At 4-6 h after fertilization, two spots indicating centrin localization showed different fluorescence intensity. Later, the weaker spot disappeared completely. These results showed that there is a difference in time between the destruction of the centriolar cylinders and the reduction of centrin molecules around them.     

Double Fertilization in Gnetum gnemon: The Relationship between the Cell Cycle and Sexual Reproduction

Gnetum gnemon, a nonflowering seed plant and member of the Gnetales, expresses a rudimentary pattern of double fertilization that results in the formation of two zygotes per pollen tube. The process of double fertilization in G. gnemon was examined with light and fluorescence microscopy, and the DNA content of various nuclei involved in sexual reproduction was quantified with 4[prime],6-diamidino-2-phenylindole microspectrofluorometry.Male and female gamete nuclei pass through the synthesis phase of the cell cycle and increase their DNA content from 1C to 2C before fertilization. Each of the two zygotes found in association with a pollen tube is diploid and contains the 4C quantity of DNA at inception. Based on these results as well as previous studies of nuclear DNA content in plant sperm, eggs, and zygotes, three fundamental and distinct patterns of gamete karyogamy among seed plants can be circumscribed: (1) G1 karyogamy, in which male and female gametes contain the 1C quantity of DNA throughout karyogamy and the zygote undergoes DNA replication; (2) S-phase karyogamy, in which gamete nuclei initiate fusion at 1C but pass through the S phase of the cell cycle before completely fusing; and (3) G2 karyogamy, in which male and female gamete nuclei pass through the S phase of the cell cycle before the onset of fertilization. Our results show definitively a pattern of G2 karyogamy in G. gnemon.     

Polyspermy barriers in plants: from preventing to promoting fertilization

Barriers to polyspermy (fertilization of a female gamete by more than one sperm) are essential to successful reproduction in a wide range of organisms including mammals, echinoderms, fish, molluscs, and algae. In animals and fucoid algae, polyspermy results in early death of the zygote due to transmission of extra centrioles from the sperm and consequent disruptions to the mitotic spindle. Accordingly, a variety of mechanisms have evolved to prevent penetration of an egg by more than one sperm, or more than one sperm nucleus from fusing with an egg nucleus. The evolution of internal fertilization has also provided an opportunity to limit the number of sperm that gain access to each egg, as occurs in the mammalian female reproductive tract. Polyspermy and polyspermy barriers in plants have received much less attention. Plants lack centrioles and therefore, polyspermy would not be expected to cause lethal aberrant spindle organization. However, we find evidence from cytological, genetic and in vitro fertilization studies for polyspermy barriers in plants. Angiosperms, like mammals, are internally fertilized, and exert a high level of control over the number of sperm that have access to each female gamete. In particular, regulation of pollen tube growth ensures that in general only two sperm enter each embryo sac, where one fertilizes the egg and the other the central cell. Despite this 1:1 ratio of sperm to gametes within the embryo sac, angiosperms still require a mechanism to ensure that each female gamete is fertilized by one and only one sperm. Here, we present evidence suggesting that a polyspermy block on the egg may be part of the mechanism that promotes faithful double fertilization.     

FERTILIZATION AND ZYGOTE DEVELOPMENT IN THE BINUCLEATE DINOFLAGELLATE PERIDINIUM BALTICUM (PYRRHOPHYTA)

Peridinium balticum (Pyrrhophyta) exists as a symbiosis between a nonphotosynthetic dinoflagellate host and a chlorophyll c-containing alga. It is hypothesized that P. balticum is an evolutionary link between primitive nonphotosynthetic and advanced photosynthetic dinoflagellates. This study documents pre- and postfertilization events of sexual reproduction in this unusual dinoflagellate for the first time. Light microscopy and TEM observations showed that gametes resemble vegetative cells except in the organization of their chloroplasts. Fusion of gametes occurred in a specific orientation, i.e., apical to sulcal area. The presence of an intact membrane between fusing pairs prior to plasmogamy was suggestive of enzymatic digestion of plates during fertilization. Rupture of this membrane triggers plasmogamy and karyogamy of the host, followed by that of the algal symbiont. A discussion of the cellular processes involved in gamete formation, fertilization, and zygote development is presented. The results of this investigation demonstrate that a synchronous sexual reproduction cycle has evolved for the symbiont and its dinoflagellate host.     

离体受精作为技术平台在被子植物有性生殖研究中的应用

被子植物的离体受精10a前在玉米中已获得成功,尽管目前只在玉米获得完全成功和小麦获得部分成功,但离体受精技术的研究成果非常显著。目前离体受精技术已被用于其他的研究,如用分离的精细胞和卵细胞筛选配子细胞的特异基因和蛋白质：研究合子细胞被激活的机理：用不同种植物的精、卵细胞体外融合进行新的远缘杂交尝试;利用合子细胞易分裂和胚胎发生特征探索用其作为转基因研究的受体细胞等。以离体受精技术为基础在高等植物发育生物学和生殖生物学领域的基础研究和应用探索显示了巨大潜力。介绍了离体受精技术在被子植物有性生殖的研究成果和应用前景,为研究和利用被子植物有性生殖过程中的生殖细胞特征提供线索。     

The behaviour of mitochondria in the zygote ofChlamydomonas reinhardii

Summary The gametes ofChlamydomonas reinhardii ready for copulation have essentially one highly branched mitochondrion. Yet in zygotes 15 minutes old, such mitochondrial networks may no longer be observed. Long, stretched and partially branched mitochondria may still be found in young zygotes, but they disintegrate with increasing age of the zygote into many, small, unbranched mitochondrial fragments.Indications of mitochondrial fusions could not be found. It cannot be excluded, however, that fusions occur within the first 10 minutes after gamete fusion or in zygotes older than 7 hours. The fusion of chloroplasts was again confirmed.     

ATRACTOMORPHA PORCATA SP. NOV., A NEW MEMBER OF THE SPHAEROPLEACEAE (CHLOROPHYCEAE) FROM CALIFORNIA1

Atractomorpha porcata sp. nov. is described from culture isolates derived in 1981 from zygotes present in a 28 year old, dried soil sample collected from near Lemon-cove, Tulare County, California. Vegetative individuals are coenocytic, spindle-shaped unicells with long, thin-pointed apices. Asexual reproduction is by means of large, biflagellate zoospores or, frequently, by aplanospores. Sexual reproduction is usually monoecious, with a single spindle-shaped gametangial cell producing small, biflagellate male gametes at either end, and larger female gametes in the midportion. Female gametes are often biflagellate, but more commonly they lack flagella and are liberated by squeezing through slit-like openings in the gametangial wall. Sexual reproduction may thus be considered as either oogamous or anisogamous, depending on whether or not a particular female gamete has flagella; most often it is oogamous. Atractomorpha porcata is readily distinguished from A. echinata, the only other known member of the genus, by (1) its greater tendency toward oogamy (versus anisogamy), (2) its bisexual gametangia, (3) its frequent production of aplanospores in asexual reproduction, (4) its unusual primary membranes that frequently bear long, delicate bristles, and (5) its distinctive zygote wall ornamentation.     

Inheritance of mitochondrial and chloroplast genomes in the isogamous brown alga Scytosiphon lomentaria (Phaeophyceae)

Patterns of inheritance of chloroplasts and mitochondria were examined by fluorescence microscopy and haplotype genome markers in the isogamous brown alga Scytosiphon lomentaria (Lyngbye) Link. Germination of the zygote in this species was unilateral, the growing thallus developed entirely from the germ tube, and the original zygote cell did not develop except for the formation of a hair. Inheritance of chloroplasts was biparental, and partitioning of the two parental chloroplasts into the first sporophytic cells was accidental: either the maternal or the paternal chloroplast was migrated from the zygote into the germ tube cell, whereas the other chloroplast remained in the original cell. In contrast, the mitochondrial genome in all cells of the sporophyte came only from the female gamete (maternal inheritance). These inheritance patterns are similar to those of the isogamous brown alga Ectocarpus siliculosus (Dillwyn) Lyngbye. Maternal inheritance of mitochondria might be universal in brown algae.     

Localization of arabinogalactan proteins in egg cells, zygotes, and two-celled proembryos and effects of beta-D-glucosyl Yariv reagent on egg cell fertilization and zygote division in Nicotiana tabacum L

Arabinogalactan proteins (AGPs) have been implicated in a variety of plant development processes including sexual plant reproduction. As a crucial developmental event, plant sexual reproduction generally occurs inside an ovule embedded in an ovary. The inaccessibility of the egg cells, zygotes, and embryos has hindered our understanding of the importance of AGPs in the early events involving fertilization, zygotic division, and early embryogenesis. In this study, the well-established in vitro zygote and ovary culture systems, together with immunofluorescence and immunogold labelling techniques, were employed to investigate the role of AGPs in the early events of sexual reproduction in Nicotiana tabacum. Dramatic changes in AGP content during ovule development were evidenced by western blotting. Subcellular localization revealed that AGPs are localized in the plasma membrane, cell wall, and cytoplasm of pre- and post-fertilized egg cells, and cytoplasm and vacuoles of two-celled proembryos. Abundant AGPs were detected in unfertilized egg cells; however, the level of AGPs substantially decreased in fertilized egg cells. Polar distribution of AGPs in elongated zygotes was observed. The early two-celled proembryos just from zygote division displayed accumulation of AGPs at a low level, while in the elongated two-celled proembryos at the late stage, the AGP content clearly increased. Provision of betaGlcY, a synthetic phenylglycoside that specifically binds AGPs, to the in vitro cultures of isolated zygote and fertilized ovaries increased abnormal symmetrical division of zygotes. In the culture of pollinated but unfertilized ovaries, addition of betaGlcY resulted in arrest of fertilization of the egg cells, but had no effect on fertilization of the central cells. The possible roles of AGPs in fertilization, zygotic division, and proembryo development are discussed.     

Selective disappearance of maternal centrioles after fertilization in the anisogamous brown alga Cutleria cylindrica (Cutleriales, Phaeophyceae): Paternal inheritance of centrioles is universal in the brown algae

The behavior of centrioles in zygotes and female gametes developing parthenogenetically in the anisogamous brown alga Cutieria cyiindrica Okamura was studied using electron and immunofluorescence microscopy. Two pairs of centrioles, detected using anti-centrin antibody, were observed in the vicinity of the male and female nuclei, respectively, just after plasmogamy. The fluorescence intensity of one of the two centrin foci became weak 6 h after plasmogamy and finally disappeared. It was impossible to determine whether the male- or female-derived centrioles disappeared in zygotes, because there was nothing to detect morphological differences between the two centrioles. However, a prominent anti-centrin staining focus was located at the condensed male nucleus in zygotes in which karyogamy had not occurred yet. As a result, it was considered that the maternally inherited centrioles had selectively disappeared during development in C. cylindrica. The paternal inheritance of centrioles in zygotes was also confirmed by electron microscopy. Considering previous observations from oogamous and isogamous species of brown algae, we concluded that the paternal inheriance of centrioles could be universal in the brown algae.     

CHLOROPLAST INHERITANCE IN COSMARIUM TURPINII BRÉB.

Chloroplast inheritance was studied in Cosmarium turpinii Bréb. with respect to both vegetative and zygotic transmission. Analyses were carried out on (1) reciprocal haploid x diploid crosses with respect to the number and size of the zygotic chloroplasts, (2) differential survival of chloroplasts in hypnospores of different mating type strains, and (3) the position of the chloroplasts in diploid zygotes. Morphological evidence indicates that the chloroplasts in the mature zygote are derived from the (+) mating type gamete with an infrequent contribution from the (–) mating type gamete. Additional evidence suggests that the chloroplast material of each of 2 Bones arising from the zygote is derived from the plastid material of a semicell of a gamete. Differential survival of the chloroplasts is interpreted as a result of physiological differences between cells of complementary mating types.     

Phototaxis and chemotaxis of brown algal swarmers

Brown algae exhibit three patterns of sexual reproduction: isogamy, anisogamy, and oogamy. Unicellular swarmers including gametes and zoospores bear two heterogenous flagella, an anterior flagellum with mastigonemes (fine tripartite hairs) and a posterior one. In seawater, these flagellates usually receive physico-chemical signals for finding partners and good habitats. It is well known that brown algal swarmers change their swimming direction depending on blue light (phototaxis), and male gametes do so, based on the sex pheromones from female gametes (chemotaxis). In recent years, the comparative analysis of chemotaxis in isogamy, anisogamy, and oogamy has been conducted. In this paper, we focused on the phototaxis and chemotaxis of brown algal gametes comparing the current knowledge with our recent studies.     

The origin of alternation of generations in land plants: a focus on matrotrophy and hexose transport

A life history involving alternation of two developmentally associated, multicellular generations (sporophyte and gametophyte) is an autapomorphy of embryophytes (bryophytesphytes + vascular plants). Microfossil data indicate that Mid Late Ordovician land plants possessed such a life cycle, and that the origin of alternation of generations preceded this date. Molecular phylogenetic data unambiguously relate charophycean green algae to the ancestry of monophyletic embryophytes, and identify bryophytes as early-divergent land plants. Comparison of reproduction in charophyceans and bryophytes suggests that the following stages occurred during evolutionary origin of embryophytic alternation of generations: (i) origin of oogamy; (ii) retention of eggs and zygotes on the parental thallus; (iii) origin of matrotrophy (regulated transfer of nutritional and morphogenetic solutes from parental cells to the next generation); (iv) origin of a multicellular sporophyte generation; and (v) origin of non-flagellate, walled spores. Oogamy, egg/zygote retention and matrotrophy characterize at least some modern charophvceans, and are postulated to represent pre-adaptative features inherited by embryophytes from ancestral charophyceans. Matrotrophy is hypothesized to have preceded origin of the multicellular sporophytes of' plants, and to represent a critical innovation. Molecular approaches to the study of the origins of matrotrophy include assessment of hexose transporter genes and protein family members and their expression patterns. The occurrence in modern charophyceans and bryophytes of chemically resistant tissues that exhibit distinctive morphology correlated with matrotrophy suggests that Early-Mid Ordovician or older microfossils relevant to the origin of land plant alternation of generations may be found.     

Elimination of plastids during spermatogenesis and fertilization in the plant kingdom

Ultrastructural and genetic investigations involving diverse species of plants have demonstrated that plastids may be transmitted either biparentally or maternally during sexual reproduction. In species in which plastid transmission is maternal, elimination of plastids from the paternal parent may occur in a number of ways: exclusion from the male gamete during spermatogenesis, loss from the motile sperm, exclusion during fertilization, or degradation within the zygote. These diverse ways in which maternal inheritance of plastids is achieved suggest that this inheritance pattern may have evolved independently many times in response to different selective pressures in different phyletic lineages.     

Evolution of gamete size in primitive taxa without mating types

An ESS model to better understand the evolutionary dynamics of a primitive non-mating type gamete size was developed with reference to the PBS (Parker, Baker and Smith’s) theory, which was based on total numbers of zygotes formed and the zygote survival rates. We did not include mating types since it has been suggested that primitive mating systems did not have mating types. As input parameters, we used experimental data on gamete motility of marine green algae. Based on hard sphere collision mechanics, we detailed the fertilization kinetics of gametes that swim in water prior to fusing with their partners through a set of coupled, non-linear differential equations. These equations were integrated numerically using typical values of the constant parameters. To estimate the relative zygote survival rate, we used a function that is sigmoid in shape and examined some evolutionarily stable strategies in mating systems that depend on optimizing values of the invasion success ratio.     

Cell cycle-dependent and independent mating blocks ensure fungal zygote survival and ploidy maintenance

To ensure genome stability, sexually reproducing organisms require that mating brings together exactly 2 haploid gametes and that meiosis occurs only in diploid zygotes. In the fission yeast Schizosaccharomyces pombe, fertilization triggers the Mei3-Pat1-Mei2 signaling cascade, which represses subsequent mating and initiates meiosis. Here, we establish a degron system to specifically degrade proteins postfusion and demonstrate that mating blocks not only safeguard zygote ploidy but also prevent lysis caused by aberrant fusion attempts. Using long-term imaging and flow-cytometry approaches, we identify previously unrecognized and independent roles for Mei3 and Mei2 in zygotes. We show that Mei3 promotes premeiotic S-phase independently of Mei2 and that cell cycle progression is both necessary and sufficient to reduce zygotic mating behaviors. Mei2 not only imposes the meiotic program and promotes the meiotic cycle, but also blocks mating behaviors independently of Mei3 and cell cycle progression. Thus, we find that fungi preserve zygote ploidy and survival by at least 2 mechanisms where the zygotic fate imposed by Mei2 and the cell cycle reentry triggered by Mei3 synergize to prevent zygotic mating.

During sexual reproduction, fertilization must happen between exactly two gametes to ensure genome stability. This study shows that two mechanisms – establishment of zygotic fate and re-entry to the cell cycle – combine to prevent fission yeast zygotes fusing with further gametes.     

Selection for high gamete encounter rates explains the success of male and female mating types

Sexual reproduction occurs in many small eukaryotes by fusion of similar gametes (isogamy). In the absence of distinguishable sperm and eggs, male and female mating types are missing. However, species with distinct males and females have so prospered that almost all familiar plants and animals have these mating types. Why has sexual reproduction involving sperm and eggs been so successful? An answer is obtained by considering physical limitations on encounter rates between gametes. A biophysical model based on well-established relationships produces fitness landscapes for the evolution of gamete size and energy allocation between motility and pheromone production. These landscapes demonstrate that selection for high gamete encounter rates favors large, pheromone-producing eggs and small, motile sperm. Thus, broadcast-spawning populations with males and females can reproduce at lower population densities and survive under conditions where populations lacking males and females go extinct. It appears that physical constraints on gamete encounter rates are sufficient to explain the first two steps in the isogamy-->anisogamy-->oogamy-->internal fertilization evolutionary sequence observed in several lineages of the eukaryotes. Unlike previous models, assumptions concerning zygote fitness or decreasing speed of swimming with increasing gamete size are not required.