Maintenance of Complex Life Cycles Via Cryptic Differences In The Ecophysiology Of Haploid And Diploid Spores Of An Isomorphic Red Alga1

Recognition of the wide diversity of organisms that maintain complex haploid–diploid life cycles has generated interest in understanding the evolution and persistence of such life cycles. We empirically tested the model where complex haploid–diploid life cycles may be maintained by subtle/cryptic differences in the vital rates of isomorphic haploid–diploids, by examining the ecophysiology of haploid tetraspores and diploid carpospores of the isomorphic red alga Chondrus verrucosus. While tetraspores and carpospores of this species did not differ in size or autofluorescence, concentrations of phycobiliproteins of carpospores were greater than that of tetraspores. However, tetraspores were more photosynthetically competent than carpospores over a broader range of photosynthetic photon flux densities (PPFDs) and at PPFDs found at both the depth that C. verrucosus is found at high tide and in surface waters in which planktonic propagules might disperse. These results suggest potential differences in dispersal potential and reproductive success of haploid and diploid spores. Moreover, these cryptic differences in ecological niche partitioning of haploid and diploid spores contribute to our understanding of some of the differences between these ploidy stages that may ultimately lead to the maintenance of the complex haploid–diploid life cycle in this isomorphic red alga.     

Haploid and diploid cell cultures from a haplo-diploid insect

Summary

This is the first report of haploid and diploid cell culture from the haplo-diploid parasitoid wasp, Mormoniella vitripennis. Cells were cultured from haploid and diploid wasps by collecting populations of eggs from virgin females (unfertilized, haploid, parthenogenetic eggs) and mated females (mostly fertilized, diploid eggs). Eggs were surface sterilized in 70% ethanol, followed by 50% Chlorox, and rinsed in phosphate buffered saline; larvae were allowed to hatch in culture. Larval cells were dissociated and cultured at 28°C in the presence of Grace's medium supplemented with fetal bovine serum. Most cells in the HMV (predominantly haploid) and DMV (predominantly diploid) cell cultures grew in suspension in the first week, formed monolayers of fibroblasts and epithelial cells by the second week in culture, and continued to grow in monolayers and vesicle-like structures for up to three months. Chromosome analysis of HMV. cells demonstrated over 70% haploid cells, with five chromosomes (N=5). The remainder were aneuploid. No diploid cells (2N= 10) were found in the HMV cell culture. Chromosome analysis of DMV cultures revealed 62% diploid, with ten chromosomes; 13% were haploid, with five chromosomes; the remainder were aneuploid. These data confirm that haploid and diploid cells can be cultured from a haplo-diploid insect species. The HMV cells which are predominantly haploid, and DMV cells which are predominantly diploid may be valuable models for the study of cellular and gene activity in haploid and diploid genetic milieux.     

A review of the life history,reproduction and phenology of Gracilaria

The basic life history of the red alga Gracilaria is of the three-phase Polysiphonia type but a number of species show deviations. Plants can bear both gametangia and tetrasporangia, either on separate parts of the thallus or on the same. Explanations include the in situ germination of tetraspores (allowing gametophytic thalli to be epiphytic on tetrasporophytes), the coalescence of spores or developing discs (resulting in chimaeras), mitotic recombination during cell division in the mature diploid thallus (resulting in patches of diploid male and female cells on the tetrasporophyte), a mutation eliminating the repression of female expression allowing haploid male plants to be bisexual and initial failure of cell walls to form during the development of tetraspores. Polyploids can be produced from plants with diploid gametangia. The sexes and phases are usually morphologically identical but gametophytes or their parts may be smaller. The growth rates of the sexes may differ and diploid juveniles may survive better than haploid. Neither polyploidy nor hybridization results in superior growth. The sex ratio is probably 1:1 but females may appear to be more abundant. Diploid and haploid phases are usually either about equal or diploids predominate, often depending on the type of substratum. At high latitudes reproduction peaks in late summer whereas in the tropics it may be high all year. In temperate regions growth rate is fastest and biomass highest in late summer; in the tropics peak biomass is mainly in the winter. Spermatia are effective for only a few h. Spores vary in size around 25 \m, diploid ones usually being larger. Cystocarps or tetrasporangia in the field may not currently be releasing spores. In the laboratory spore release shows a diurnal rhythm, peaking during the night or day according to the species. All the above attributes are potentially important in planning and executing Gracilaria cultivation.     

Studies on the cytotypes of Atrichum undulatum (Hedw.) P. Beauv. II. Chromosome length and relative DNA content

Abstract

Evidence is presented showing that the chromosomes of diploid and triploid races of Atrichum undulatum are significantly shorter than those of haploid plants. Relative DNA contents of the three cytotypes have been estimated and they differ significantly from an expected 1:2:3 ratio in haploid, diploid and triploid races.     

Chromosomal loci of genes controlling site-specific restriction endonucleases of Bacillus subtilis

Summary In Saccharomyces cerevisiae, diploid strains which are respiratory deficient (e.g., rho^–) or are homozygous for the mating-type locus (i.e., either a/a or /) are unable to sporulate. In order to induce sporulation in these nonsporulating strains, the technique of protoplast fusion mediated by polyethylene glycol was adopted. In this study, the products of protoplast fusion were induced to sporulate without reversion to normal cells.Protoplasts from a respiratory-deficient diploid strain were mixed with those from a respiratory-competent haploid one carrying mitochondrial drug resistance markers, treated with 30% polyethylene glycol-4000 and 25 mM CaCl₂, and incubated in 0.1 M potassium acetate containing 0.8 M sorbitol as an osmotic stabilizer. After two days' incubation, asci with three to eight spores were formed at a frequency of 1×10^–3 to 2×10^–4. Sporulation was also observed in products of fusion between an a/a diploid and haploid strains and between an / diploid and a haploid strains. The analysis of the genotypes of spores revealed that when fusion products were cultured under conditions for sporulation, karyogamy did not take place, diploid nuclei underwent meiosis, and both diploid and haploid nuclei were able to develop into spores.     

Micropopulation differentiation in phenol content and susceptibility to herbivory in the Chilean kelp Lessonia nigrescenss (Phaeophyta,Laminariales)

Micropopulation differences in phenol content between intertidal and subtidal individuals of the kelp Lessonia nigrescens were found. Subtidal plants showed: (1) significantly higher phenol content than intertidal individuals, in vegetative and reproductive tissues, (2) intra-plant differences, with higher content in apical frond tissues, (3) higher resistance to consumption by herbivorous fishes. The microscopic progeny of subtidal plants showed the same trend as adult plants: (1) haploid spores from subtidal plants had higher phenol content than spores from intertidal individuals, and (2) the microscopic sporophytes derived from subtidal spores and gametophytes were less consumed by herbivorous snails (Tegula tridentata) than those derived from intertidal plant propagules. No increase in phenol content was detected after mechanical injury to experimental fronds, or after transplantation to the subtidal environment.In addition to the absence of inducible responses, the different phenol content between intertidal and subtidal individuals, in adult diploid plants and also in the haploid progeny, suggests that both environments differ someway enough to fix the mentioned features on the plants of Lessonia nigrescens. It is likely that the differences in herbivory between the two distributional extremes contributed to the observed pattern.     

Viability of Physarum polycephalum spores and ploidy of plasmodial nuclei.

Amoebae of Physarum polycephalum carrying the mth mating-type allele may differentiate into plasmodia in the absence of mating. Such plasmodia are haploid and, upon sporulation, produce mainly inviable spores. We have asked whether the viable spores arise from meiotic or mitotic divisions. Using a microfluorometric measurement of the deoxyribonucleic acid content of individual nuclei, we found the fraction of viable spores to be correlated with the proportion of rare, diploid nuclei containing in the generally haploid plasmodium. When homozygous diploid plasmodia were created by heat shocking, spore viability increased dramatically. We suggest that viable spores are produced via meiosis in mth plasmodia, that the mth allele has no effect on sporulation per se, and that the normal source of viable haploid spores is a small fraction of diploid nuclei ubiquitous in haploid plasmodia.     

HAPLOID PARTHENOGENETIC SPOROPHYTES OF LAMINARIA JAPONICA (PHAEOPHYCEAE)1

Parthenogenetic sporophytes were obtained from three strains of Laminaria japonica Areschoug. These sporophytes grew to maturity in the sea, producine spores that all grew into female gametophytes. These female gametophytes gave rise to another generation of parthenogenetic sporophytes during the next year, so that by the year 1990 parthenogenetic sporophytes had been cultivated for 12, 9, and 7 generations, respectively, for the three strains. When female gametophytes from parthenogenetic sporophytes were combined with normal male gametophytes, normal sporophytes that reproduced and gave rise to both female and male gametophytes were obtained. The parthenogenetic sporophytes were shorter and narrower than the normal sporophytes of the same strain. Chromosome counts on mature sporophytes showed that normal sporophytes (from fertilized eggs) were diploid (2n = approximately 40) and that the spores they produced were haploid (n = approximately 20), while nuclei from both somatic and sporangial cells in parthenogenetic sporophytes were haploid. All gametophytes were haploid. Young sporophytes derived from cultures with both female and male gametophytes were diploid, while young, sporophytes obtained from female gametophytes from parthenogenetic sporophytes had haploid, diploid, or polyploidy chromosome numbers. Polyploidy was associated with abnormal cell shapes. The presence of haploid parthenogenetic sporophytes should be use in breeding kelp strains with useful characteristics, since the sporophyte phenotype is expressed from a haploid genotype which can be more readily selected.     

Conditions Favoring Differentiation and Stabilization of the Life Cycle of the Yeast <Emphasis Type="Italic">Pachysolen tannophilus</Emphasis>

Conditions favoring differentiation and stabilization of the life cycle of the yeast Pachysolen tannophilus have been studied. When concentrations of the carbon source in the medium were lower than 100 g/l, it was found to be favorable to the mating of vegetative cells, both haploid and diploid. The addition of nitrogen and sulfur sources to the medium influenced the life phases of haploid cells and partially stabilized the vegetative growth of diploid cells. Enrichment of the nutrient medium with potassium, vitamins, and microelements was shown to be necessary for the formation and maturation of conjugated ascospores. Microelements, vitamins, and phosphorus in excessive amounts activated conjugation but did not provide for the distinct phases of formation of unconjugated asci and spores in the diploid cells. Possible reasons for the unstable diplophase in the yeast P. tannophilus have been discussed.__________Translated from Mikrobiologiya, Vol. 74, No. 4, 2005, pp. 483–488.Original Russian Text Copyright © 2005 by Bolotnikova, Mikhailova, Shabalina, Bodunova, Ginak.     

The Ultrastructure of the Spores of the Devonian Plant Parka decipiens

The ultrastructure of the spores of Parka decipiens Flemingwas investigated by SEM and TEM. The spores are shown to havea structured wall consisting of two distinct layers, one ofwhich exhibits a lamellate organization. The deposition of thespore wall by a tapetum is suggested to account for these lamellae.Comparison is made between the spore ultrastructure of Parkaand that of algae and bryophytes. It is suggested that the sporewall of Parka bears some similarities with the lamellate exinefound in the Hepaticae. Parka decipiens, Devonian, fossil, spore wall, ultrastructure, lamellae, tapetum     

Mal3, the Schizosaccharomyces pombe homolog of EB1, is required for karyogamy and for promoting oscillatory nuclear movement during meiosis

Two successive rounds of chromosome segregation following a single round of DNA replication enable the production of haploid gametes during meiosis. In the fission yeast Schizosaccharomyces pombe, karyogamy is the process where the nuclei from 2 haploid cells fuse to create a diploid nucleus, which then undergoes meiosis to produce 4 haploid spores. By screening a collection of S. pombe deletion strains, we found that the deletion of 2 genes, mal3 and mto1, leads to the production of asci containing up to 8 spores. Here, we show that Mal3, the fission yeast member of the EB1 family of conserved microtubule plus-end tracking proteins, is required for karyogamy, oscillatory nuclear movement, and proper segregation of chromosomes during meiosis. In the absence of Mal3, meiosis frequently initiates before the completion of karyogamy, thus producing up to 8 nuclei in a single ascus. Our results provide new evidence that fission yeast can initiate meiosis prior to completing karyogamy.     

Ploidy chimeras induced in haploid sporophytes of <Emphasis Type="Italic">Osmunda claytoniana</Emphasis> and <Emphasis Type="Italic">Osmunda japonica</Emphasis>

Haploid sporophytes of Osmunda claytoniana (2n = x = 22) were apogamously produced from calli when cultivated on a hormone-free medium. Flow cytometric analysis showed that ploidy chimeras were spontaneously produced in a haploid sporophyte of O. claytoniana and those of O. japonica that were obtained in the previous study. In the haploid sporophyte of O. claytoniana, a diploid pinnule and a partially diploid terminal segment were produced in a haploid pinna. In O. japonica, a haploid sporophyte yielded a diploid pinna in a haploid frond, and another haploid sporophyte yielded a diploid pinnule in a haploid pinna. Diploid chimeras were large in size and could be readily distinguished from other haploid parts of the fronds. It is likely that the chimeras were produced clonally from a single diploid cell that established chromosome doubling.     

Reflexions sur nos cultures d'antheres de plantes cultivées

Abstract

Considerations about our anther cultures of cultivated plants. – One of the main activities performed at the Casaccia Nuclear Centre, in the framework of a contract between CNEN and the European Communities, centers on the induction of haploid plants by anther culture and the subsequent chromosome doubling in order to obtain completely homozygous diploid plants. In tobacco, it is now possible to obtain haploid plants from any cultivar; we perform in vitro culture of internodes from which homozygous diploid plants are regenerated, taking advantage of natural phenomenon of endopolyploidy. In order to try to generalize this method of producing haploid plants in other plant species, we are studying the mechanism involved in haploid embryogenesis which occurs in vitro in the microspores. Datura, Nicotiana and Atropa are among the genera in which a direct embryogenesis from the microspore is observed; it is interesting to note that all three genera belong to the family Solanaceae and are very rich in alkaloids. In almost all the other cases of in vitro induction of haploids, microspores produce calli from which plantlets can be differentiated, but this way of plant regeneration is less interesting because only few plantlets are obtained and it is not sure that each haploid comes from a single microspore. We examined the factors which could influence the transformation of microspores into embryoids in tobacco, namely: the developmental stage of microspore, the degeneration of tapaetal cells, the genotype of microspore, the composition of cultural media, the physiological conditions of the plant from which the anthers were taken. From a practical point of view, it would be desirable to have informations on methods giving a maximum number of haploid plants from one embryogenic anther and the greatest number of embryogenic anthers from the cultured anthers. Our recent experiments on anther culture in liquid shaken medium have yielded good results (about 7,000 embryoids from 25 embryogenic anthers). Further, we are conducting several experiments in order to synchronize the development of the microspores in the anthers; to this end, we analyse the effect of cold treatment, ionizing radiation and gravity force. Experiments are being performed with other cultivated species, beside tobacco, in order to solve some problems of plant breeding more easily and quickly through haploidy. With the aim of introducing, in cultivated tomato, some desirable characters from the wild species, Lycopersicum peruvianum, (self-incompatibility, disease resistance, simultaneous flowering), we have obtained the interspecific hybrid through in vitro culture of young embryos. Haploid production from this hybrid could allow to quickly obtain various genetic recombinations from these two species. For this purpose we are carrying out anther cultures as well as single microspore cultures. In rice, strawberry and L. peruvianum, several diploid and tetraploid plantlets were obtained from our anther cultures. Work is in progress to ascertain the mode of their origin.     

GENETIC VARIABILITY WITHIN A POPULATION AND BETWEEN DIPLOID/HAPLOID TISSUE OF MACROCYSTIS PYRIFERA (PHAEOPHYCEAE)1

Multi-locus DNA fingerprints using an M13 probe were obtained for eight individuals of giant kelp Macrocystis pyrifera (L.) C. Ag. collected from Monterey Bay, California. For each individual, DNA was extracted from a diploid blade and from ca. 10⁹ haploid spores that were released from four to Jive sporophylls. Viable or swimming spores from one individual were pooled and referred to as a spore group. A total of 34 bands (4–19 kb) was detected in DNA fingerprints from the eight blades and eight spore groups, with individual blade or spore groups exhibiting 7–18 bands (mean = 12.6). One band (4.5 kb) was present in all 16 samples. Eight bands were detected in 11–14 of the 16 samples. Similarity indices were calculated for all pairwise comparisons of fingerprint bands among all possible combinations of blades and spore groups. Mean similarity indices for the eight blades (0.51, SE = 0.032) and spore groups (0.56, SE = 0.031) were significantly lower than for the eight comparisons of the blade and spore groups from a single individual (0.86, SE = 0.052). The data indicate that DNA fingerprints can be used to measure genetic variation within populations of M. pyrifera because variation of DNA fingerprints associated with meiotic products (spores) of a given individual is small relative to variation observed among individuals within the population. Additionally, fingerprint variation between diploid vegetative tissue and haploid meiotic products may be a measure of genetic change due to recombination or DNA turnover mechanisms.     

Septins localize to microtubules during nutritional limitation in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Background  

In Saccharomyces cerevisiae, nutrient limitation stimulates diploid cells to undergo DNA replication and meiosis, followed by the formation of four haploid spores. Septins are a family of proteins that assemble a ring structure at the mother-daughter neck during vegetative growth, where they control cytokinesis. In sporulating cells, the septin ring disassembles and septins relocalize to the prospore membrane.     

Nuclear migration in Saccbaromyces cerevisiae is controlled by the highly repetitive 313 kDa NUM1 protein

Summary We have isolated a novel gene (NUM1) with unusual internal periodicity. The NUM1 gene encodes a 313 kDa protein with a potential Ca²⁺ binding site and a central domain containing 12 almost identical tandem repeats of a 64 amino acid polypeptide. num1-disrupted strains grow normally, but contain many budded cells with two nuclei in the mother cell instead of a single nucleus at the bud neck, while all unbudded cells are uninucleate: This indicates that most G2 nuclei divide in the mother before migrating to the neck, followed by the migration of one of the two daughter nuclei into the bud. Furthermore, haploid num1 strains tend to diploidize during mitosis, and homozygous num1 diploid or tetraploid cells sporulate to form many budded asci with up to eight haploid or diploid spores, respectively, indicating that meiosis starts before nuclear redistribution and cytokinesis. Our data suggest that the NUM1 protein is involved in the interaction of the G2 nucleus with the bud neck.     

Allopolyploidy and homoploid hybridization in the Sphagnum subsecundum complex (Sphagnaceae: Bryophyta)

Several complexes of species in Sphagnum (peat mosses) originated through hybridization and allopolyploidy, suggesting that these processes have played a major evolutionary role in this genus. The Sphagnum subsecundum complex includes gametophytically haploid and diploid species in North America. Analyses of 12 microsatellite loci and sequences from two plastid DNA markers show that the evolutionary history of this group is substantially more complex than previously thought. Two taxonomic species, Sphagnum lescurii and Sphagnum inundatum, include both haploid and diploid populations. Within each ploidal level, S. lescurii and S. inundatum are not genetically differentiated. The diploid taxa show patterns of fixed heterozygosity for the microsatellite markers, consistent with an allopolyploid origin. Diploid S. lescurii is an allopolyploid between haploid S. lescurii and (haploid) S. subsecundum. Sphagnum carolinianum is an allopolyploid between haploid S. lescurii and an unknown parent. We detected homoploid hybridization between the haploids Sphagnum contortum and S. subsecundum. Finally, we report three samples of diploid Sphagnum platyphyllum (otherwise haploid) that have an allopolyploid origin involving north‐eastern haploid S. platyphyllum and an unidentified taxon. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2010, 99 , 135–151.     

PLOIDY ANALYSIS OF THE TWO MOTILE FORMS OF CHRYSOCHROMULINA POLYLEPIS (PRYMNESIOPHYCEAE)1

In some cultures of the flagellate Chrysochromulina polylepis Manton et Parke, established from cells isolated from the massive bloom in Skagerrak and Kattegat in 1988, we observed, two motile cell types. They were termed authentic and alternate cells and differed with respect to scale morphology. To investigate whether or not the two cell forms were joined in a sexual life cycle, the relative DNA content per cell and relative size of cells of several clonal cultures of C. polylepis were determined by flow cytometry. Percentages of authentic and alternate cells in the cultures were estimated by transmission electron microscopy. Pure authentic cultures (α) contained cells with the lowest level of DNA and were termed haploid. Two pure alternate cultures (β) contained cells with double the DNA content of authentic cells and were termed diploid. Other pure alternate cultures contained haploid cells only, or both haploid and diploid cells. Three cell types were observed, each capable of vegetative propagation: authentic haploid, alternate haploid, and alternate diploid cells. Both the haploid and diploid alternate cells were larger than the haploid authentic cells. Cultures containing diploid cells appeared unstable: cell type ratio and ploidy ratio changed during the experiment where this cell type was present, particularly when grown in continuous light. In contrast, cultures with only haploid cells remained unchanged at all growth conditions tested. Light condition may influence cell type ratio and ploidy ratio. Our attempt to induce syngamy by mixing different authentic haploid clones did not result in mating. Assuming that the authentic and alternate cell types are of the same species, the life cycle of C. polylepis includes three flagellated scale-covered cell forms. Two of the cell types are haploid and may function as gametes, and the third is diploid, possibly being the result of syngamy.     

Mating-Type Functions for Meiosis and Sporulation in Yeast Act through Cytoplasm

Given a nutritional regime marked by a low nitrogen level and the absence of fermentable carbon sources, conventional a/α diploid cells of Saccharomyces cerevisiae exhibit a complex developmental sequence that includes a round of premeiotic DNA replication, commitment to meiosis and the elaboration of mature tetrads containing viable ascospores. Ordinarily, haploid cells and diploid cells of genotype a/a and α/α fail to display these reactions under comparable conditions. Here, we describe a simple technique for sporulation of α/α and a/a cells. Cells of genotype α/α are mated to haploid a cells carrying the kar1 (karyogamy defective) mutation to yield heterokaryons containing the corresponding diploid and haploid nuclei. The kar1 strains mate normally, but nuclei in the resultant zygotes do not fuse. When heterokaryotic cells are inoculated into sporulation media, they produce asci with six spores. Four spores carry genotypes derived from the diploid nucleus and the other two possess the markers originating from the haploid nucleus, i.e., the diploid nucleus divides meiotically while the haploid nucleus apparently divides mitotically. Similarly, the a/a genome is "helped" to sporulate as a consequence of mating with α kar1 strains. The results allow us to conclude that the mating-type functions essential for meiosis and sporulation are communicated and act through the cytoplasm and that sporulation can be dissociated from typical meiosis. This procedure will facilitate the genetic analysis of strains that are otherwise unable to sporulate.     

Analysis of nucleolar organizer constitution by fluorescent in situ hybridization (FISH) in diploid and artificially produced haploid sporophytes of the fernOsmunda japonica (Osmundaceae)

HaploidOsmunda japonica (2n = × = 22), produced in tissue culture by induced apogamy and acclimatized in vivo, was cytologically compared with the diploid sister plant. The haploid had smaller guard cells than the diploid and a numerically exactly reduced karyotype. Fluorescent in situ hybridization (FISH) using an rDNA probe showed four hybridization signals (one large and three small ones) in the haploid and eight signals (two large and six small ones) in the diploid plant. These results represent a cytological proof for the origin of the haploid plant by apogamy without recognizable chromosome aberrations.