ALTERED ZYGOSPORE WALL ULTRASTRUCTURE CORRELATES WITH REDUCED ABIOTIC STRESS RESISTANCE IN A MUTANT STRAIN OF CHLAMYDOMONAS MONOICA (CHLOROPHYTA)1

The zygospore of Chlamydomonas is a diploid resting stage that provides protection from environmental extremes. The remarkable abiotic stress resistance of the zygospore can be explained, in part, by the presence of a massive wall that includes a sporopollenin‐containing surface layer ( Van Winkle‐Swift and Rickoll 1997 ). A Chlamydomonas monoica Strehlow zygospore‐specific mutant strain (D19) was obtained previously by screening for loss of chloroform resistance in zygospore populations derived from self‐mating of post‐mutagenesis clones. Exposure of D19 zygospores to solar UV radiation or germicidal radiation also resulted in a pronounced decrease in survival of D19 zygospores relative to wildtype zygospore survival. Similarly, resistance to NaCl‐induced osmotic shock was reduced in D19 zygospores, especially when exposed to very high (e.g., 20% w/v) salt concentrations. Mature zygospores of C. monoica exhibit a UV‐induced blue surface autofluorescence that may indicate the presence of phenolic wall components. The intensity of zygospore autofluorescence was significantly reduced in D19 zygospores. As revealed by TEM, the surface layer of mature homozygous D19 zygospores was disrupted, suggesting a defect in wall assembly. Zygospore‐specific chloroform sensitivity, UV sensitivity, and reduced autofluorescence cosegregated in tetrads derived from D19 heterozygotes (i.e., if a progeny clone from a cross involving D19 and a normal strain was found to be chloroform sensitive, it was always also UV sensitive and showed reduced autofluorescence), indicating that all three characteristics were the consequence of the same Mendelian mutation.     

Zygospore formation between homothallic and heterothallic strains of Closterium

Zygospore formation in different strains of the Closterium peracerosum-strigosum-littorale complex was examined in this unicellular isogamous charophycean alga to shed light on gametic mating strains in this taxon, which is believed to share a close phylogenetic relationship with land plants. Zygospores typically form as a result of conjugation between mating-type plus (mt⁺) and mating-type minus (mt⁻) cells during sexual reproduction in the heterothallic strain, similar to Chlamydomonas. However, within clonal cells, zygospores are formed within homothallic strains, and the majority of these zygospores originate as a result of conjugation of two recently divided sister gametangial cells derived from one vegetative cell. In this study, we analyzed conjugation of homothallic cells in the presence of phylogenetically closely related heterothallic cells to characterize the reproductive function of homothallic sister gametangial cells. The relative ratio of non-sister zygospores to sister zygospores increased in the presence of heterothallic mt⁺ cells, compared with that in the homothallic strain alone and in a coculture with mt⁻ cells. Heterothallic cells were surface labeled with calcofluor white, permitting fusions with homothallic cells to be identified and confirming the formation of hybrid zygospores between the homothallic cells and heterothallic mt⁺ cells. These results show that at least some of the homothallic gametangial cells possess heterothallic mt⁻-like characters. This finding supports speculation that division of one vegetative cell into two sister gametangial cells is a segregative process capable of producing complementary mating types.     

SEXUAL REPRODUCTION AND INTERCROSSING IN VOLVULINA STEINW1

Gametes of Volvulina steinii bear near-apical mating papillae. Zygospore germination yields a single biflagellate cell that develops into a colony xuhose asexual progeny are all of the same mating type. Backcrossing of clones of progeny indicated a 1 :1 ratio of mating types among the progeny. Of 20 clones from a number of localities, none was homothallic and 3 showed no matins: reaction. Mating reactions of clones crossed in all possible combinations indicated the presence of 2 sexually isolated groups of clones producing smooth-walled zygospores and 1 group that produced spiny-walled zygospores. In the latter group weak and nonreciprocal mating reactions occurred in some clone combinations. Failure of germination of spiny-walled zygospores from certain crosses suggests further subdivision into genetically isolated groups.     

Variations of the Surface Sculpture and Cell Wall Ultrastructure of the Zygospores in Chlamydomonas geitleri (Chlorophyta)

The superficial cell wall ornamentation in the zygospores of the alga Chlamydomonas geitleri Ettl (Chlorophyta) is formed by thickenings of the cell wall which are shaped into a network of anastomosing ribs, sometimes with local wart-like protuberances. Clearly different sculpture patterns (given by presence, arrangement and/or morphological modification of sculpture elements) were accompanied by many transient forms. Sculpture variations occurred even in clonal cultures. In the zygospore cell wall of C. geitleri, the inner, outer and middle layer can be distinguished from the morphological point of view. The relatively thin outer (sporopollenin) layer covers the whole surface of the zygospore wall. The thicker inner layer adhering to the zygospore protoplast forms, either solely or together with the middle layer (possessing a fine meshwork substructure), variously shaped thickening of the zygospore cell wall. Discussed are the ultrastructural morphology of the cell wall in Chlamydomonas zygospores, the striking similarity of the cell wall ultrastructure of zygospores in C. geitleri to the ultrastructure of the cell wall of vegetative cells in some green algae (subfamily Scotiellocystoideae), as well as the extensive morphological variability of the zygospore wall sculpture in C geitleri and its species specificity.     

Molecular structure of the resistant biopolymer in zygospore cell walls of Chlamydomonas monoica

The unicellular green alga Chlamydomonas monoica Strehlow is known to produce zygospores with a cell wall that is resistant against microbial and chemical attack. This resistance is thought to be due to the presence of a sporopollenin-like material. However, the resistant nature of sporopollenin-like materials seriously hampers their structural analysis. With complementary techniques such as ¹³C-nuclear magnetic resonance spectroscopy, Curie-point pyrolysis-gas chromatography/mass spectroscopy and RuO₄ chemical degradation, the chemical composition of resistant biopolymer in the isolated cell walls of C. monoica zygospores was determined. This material is composed of C₂₂–C₃₀ linear alcohols and carboxylic acids, intermolecularly linked via ester and ether-linkages similar to the resistant aliphatic biopolymers encountered in the walls of the vegetative cells of the algae Tetraedron minimum, Scenedesmus communis and Pediastrum boryanum. Received: 29 April 1998 / Accepted: 2 October 1998     

SELF-STERILE AND MATURATION-DEFECTIVE MUTANTS OF THE HOMOTHALLIC ALGA,CHLAMYDOMONAS MONOICA (CHLOROPHYCEAE).1

Homothallic sexual reproduction in Chlamydomonas monoica Strehlow culminated in the formation of mature, chloroform-resistant zygospores (zygotes) in clonal culture. Early in the zygote maturation process, a distinctive “primary zygote wall” was released into the culture medium where it remained stable for at least several days. This wall appeared as a rigid, darkly-outlined, and often multilayered structure, as viewed by phase contrast microscopy. From a sample, of 2500 individual clones isolated after ethyl methanesulfonate mutagenesis, five maturation-defective strains (zym) produced abnormal zygotes which failed to release a primary zygote wall, failed to develop the normal reticulate zygospore wall, and disintegrated within five days. These strains were utilized to identify additional mutants which were sexually competent, but self-sterile (het). Mixed cultures of the zym and het mutant strains were found to contain numerous, fully-matured, chloroform-resistant zygospores and discarded primary zygote walls. In combination, the two types of mutants provided a useful system for the selective recovery of heterozygous zygospores, thus facilitating genetic studies on a homothallic Chlamydomonas.     

SEXUAL REPRODUCTION IN CLOSTERIUM MONILIFERUM AND CLOSTERIUM EHRENBERGII1

Sexual reproduction in C. moniliferum is described for the first time. The morphology of conjugation is quite like that of C. ehrenbergii. Homothallic strains of both species usually produce single zygospores between daughter cells that have just divided. However, 2 homothallic clones of C. moniliferum form twin zygospores between conjugants which have paired before division and conjugation. This has not been observed in C. ehrenbergii. Heterothallic strains of both species form twin zygospores in the same manner. Heterotfiallisrn seems a well-established feature in both species. Germination and the survival of 2 products of meiosis arc typical of other desmids which have been investigated.     

STABLE DIPLOIDS FROM INTRAGROUP ZYGOSPORES OF CLOSTERIUM EHRENBERGII MENEGH. (CONJUGATOPHYCEAE)1

Two pairs of stable diploid clones were obtained as aberrant forms among F₁ progeny of an intragroup (intraspecific) cross between R-11-4 (mating type +) and M-16-4b (mating type -) of Group A of Closterium ehrenbergii Menegh. Each pair was derived from the two germination products of a single zygospore, and both clones were mating type minus. The cell size range of these four diploid minus clones was considerably above that of normal (haploid) Group A clones. Chromosome counts at the second meiotic metaphase indicated that these clones were diploid with approximately 200 chromosomes, which was double the number for normal Group A clones. Diploid minus clones conjugated normally with any haploid Group A plus clones, and yielded many triploid zygospores. Triploid zygospores germinated normally as did intragroup diploid zygospores. In metaphase I preparations, only bivalents were observed except on a few occasions where some uni- and multivalents were also detected. Viability of F₁ progeny from triploid zygospores (55–74%) was somewhat lower than from diploid zygospores of Japanese Group A populations (65–90%), but higher than intergroup (interspecific) hybrid zygospores from Groups A, B and H (0–12%). In addition to lower viability, some F₁ progeny from triploid zygospores exhibited slow vegetative growth. Almost all pairs of F₁ clones from single triploid zygospores were of opposite mating type, similar to normal diploid zygospores of the intragroup cross. Morphological variability of F₁ progeny of triploid zygospores was great. The apparently normal meiosis of triploid zygospores and the high viability of F₁ progeny suggested that the genome of Group A contains several sets of chromosome complements with mechanisms by which bivalents are regularly formed in the first meiotic division.     

Disappearance of the heteroplasmic state for chloroplast markers in zygospores of Chlamydomonas reinhardtii

In the investigations reported here, the length of zygospore incubation or “maturation” prior to the induction of meiosis was found to affect the inheritance pattern of chloroplast genes. The frequency of zygospores transmitting chloroplast alleles from both parents drops with increasing zygospore age following mating, while the frequencies of zygospores homoplasmic for maternal or paternal chloroplast alleles increase correspondingly. Since there is a negligible reduction in viability, zygospores which are initially biparental appear to become pure for the chloroplast genes from one or the other parent prior to the occurrence of cell division. These results are amplified in crosses of mt⁺ cells which have been irradiated with ultraviolet (uv) light or grown in the presence of the base analog, 5-fluorodeoxyuridine, which also perturbs maternal inheritance. Low doses of uv irradiation, applied to zygospores derived from crosses in which the maternal parent was also irradiated prior to mating, increase the biparental zygospore frequency while reducing the proportion of maternal zygospores. This indicates that at least some maternal zygospore clones are actually derived from zygospores which still contain both parental chloroplast genomes prior to the induction of germination. Thus, a subclass of zygospores must contain paternal chloroplast genomes which are either eliminated upon germination or are not expressed in the resulting zygospore clone. Tetrad analysis of biparental zygospores derived from uv-irradiated mt⁺ gametes demonstrates that the frequency of maternal chloroplast alleles in biparental zygospores decreases as they age. One result is an increase in the proportion of meiotic products homoplasmic for all paternal markers. The increased segregation of homoplasmic daughter cells during the meiotic divisions may result from a reduction in chloroplast ploidy by elimination of maternal genomes. Alternatively, it may reflect an altered ratio of maternal:paternal genomes due to continuous rounds of pairing and gene conversion between heterologous chloroplast DNAs leading to genetic drift within the DNA population of the organelle.     

LONG-TERM MAINTENANCE OF FERTILE ALGAL CLONES: EXPERIENCE WITH PANDORINA (CHLOROPHYCEAE)1,2

There is a need for simple, inexpensive methods to maintain algal clones of constant genotype over long periods of time. Pandorina zygospores survive many environmental rigors which destroy the vegetative cells. The zygospores are the preferable from for storage of the alga and remain viable for at least 15 yr. storage procedures and germination techniques are described for zygospores of 2 species. These are compared with reports in the literature concerning other algal genera. General procedures for storage and maintenance of both vegetative cells and spores are proposed.     

Effect of certain environmental factors on zygospore germination ofSpirogyra hyalina

The present study focusses on the effects of pH, temperature, intensity of white, red far-red light on zygospore germination in the filamentous green algaSpirogyra hyalina. Maximum germination of zygospores occurred at pH 8.0 and 25°C. Germination of zygospores was favored by white light at an intensity of 3–4 klx. Red light resulted in higher germination when applied at the beginning or in the middle of the dark period, while far-red light decreased zygospore germination. Red light in the middle of the dark period was found to be most effective for germination. These observations suggest a possible presence of the phytochrome system in the test alga contributing to its morphogenetic response.     

Revision of the genus Absidia (Mucorales, Zygomycetes) based on physiological, phylogenetic, and morphological characters; thermotolerant Absidia spp. form a coherent group, Mycocladiaceae fam. nov.

The genus Absidia comprises ubiquitously distributed soil fungi inhabiting different growth temperature optima ranging from 20–42 °C. Some of the mesophilic species are important biotechnologically in the biotransformation of steroids or as producers of rennin-like components, whereas species with higher growth temperature optima are of clinical relevance as opportunistic human pathogens. The aim of this study was to investigate the phylogenetic relationships between these species and to establish a revision of their systematics. For this purpose single and combined genealogies based on distance, MP, ML, and Bayesian analyses of aligned nucleotide sequences of the nuclear-encoded genes for actin (act) and for the 5.8S ribosomal RNA flanked by the ITS regions 1 and 2 (comprising 807 and 828 characters, respectively) of 16 Absidia species were reconstructed. The phylogenetic reconstructions suggest a trichotomy of the Absidia genus consisting of a mesophilic, a fast-growing thermotolerant, and a slowly-growing mycoparasitic Absidia group. The trichotomous phylogenetic grouping is concordant with the morphology of the zygospores, which are zygotes resulting from sexual conjugation between two compatible mating partners. Whereas the mesophilic group comprises the majority of absidiaceaeous species forming sterile hair-like, mycelial appendages on the suspensors of their zygospores, the thermotolerant group is characterised by the formation of smooth-walled zygospores, and the mycoparasitic group, namely Absidia parricida and A. zychae, by Mucor-like rough-walled zygospores. Based on the phylogenetic coherence of mesophilic and thermotolerant Absidia species, we propose that the two groups are separated into two distinct genera, Absidia for the mesophilic Absidia species resembling the Absidiaceae and Mycocladus for the thermotolerant species A. corymbifera, A. blakesleeana and A. hyalospora. Because Mycocladus is physiologically, phylogenetically, and morphologically distinct from the Absidiaceae s. str. we suggest that they are classified as a separate family, Mycocladiaceae fam. nov., which comprises the three species M. corymbifer, M. blakesleeanus and M. hyalospora.     

A peculiar method of sexual reproduction in certain new members of the Chlamydomonadaceae

Summary In the course of a study of Algae from Indian soils two new species of Chlamydomonas (C. Iyengari, C. indica) and a new species of Carteria (C. eugametos) were observed which are distinctive in the fact that their gametes conjugate by their posterior ends. Diagnoses of the new species are given. The gametes are provided with membranes. One of the fusing gametes receives the contents of the other, and the membrane of the active gamete, which has fused with that of the recipient gamete, forms a loose envelope around the zygote. The zygotes retain only the flagella of the recipient gamete. They are larger than the vegetative cells and may remain motile for some days. They frequently divide without a resting period, although zygospores were formed in old cultures of two of the species. Germination of these zygospores was observed.The author is indebted to Prof. F. E. Fritsch, F. R. S. for advice and guidance in the course of this investigation.     

A SEX DETERMINING MECHANISM IN THE CLOSTERIUM EHRENBERGII (CHLOROPHYTA) SPECIES COMPLEX1

Homozygous mt^?/mt^? diploid clones of the Closterium ehrenbergii Menegh. ex Ralfs species complex were obtained by hypertonic treatment from minus vegetative cells, and mating type segregation ratios in the F₁ progeny of “triploid” zygospores between wild type mt⁺ haploid and mt^?/mt^? homozygous diploui were analyzed. The ratio of plus to minus individuals was 1:4.8, and the ratio of the pairs of opposite mating types to those of minus mating type was 1:2.1. The results clearly show that mt^? is dominant to mt⁺ and that the mating type inheritance in these zygospores follows the triploid-like pattern. The validity of our assumption that the two mating types are determined by one genetic factor (mt^? allele dominant) was confirmed in B₁ progeny analyses as well. The results suggest that this sex determining mechanism is working effectively in the C. ehrenbergii species complex, in which several biological species have evolved through polyploidization.     

Conjugation morphology of Zygogonium ericetorum (Zygnematophyceae,Charophyta) from a high alpine habitat

Reproductive characteristics are important for defining taxonomic groups of filamentous Zygnematophyceae, but they have not been fully observed in the genus Zygogonium. Specimens of Z. ericetorum previously studied and used to clarify the generic concept lacked fertile material, which was obtained recently. This study illustrates for the first time, using color light microscopic and fluorescence images, a consequent conjugation stage in Z. ericetorum, including completely developed zygospores and purple cytoplasmic residue content left outside the zygospores, similar to aplanospore formation. Structures confirmed earlier reports and provided new observation informative regarding phylogenetically relevant reproductive characters of Z. ericetorum.     

Biparental Inheritance of Non-Mendelian Gene Markers in CHLAMYDOMONAS MOEWUSII

The first two non-Mendelian gene mutations to be identified in Chlamydomonas moewusii are described. These putative chloroplast gene mutations include one for resistance to streptomycin (sr-nM1) and one for resistance to erythromycin (er-nM1). In one- and two-factor reciprocal crosses, usually over 90% of the germinating zygospores transmitted these mutations and their wild-type alternatives from both parents (biparental zygospores); the remaining zygospores transmitted exclusively the non-Mendelian markers of the mating-type "plus" parent. Among the biparental zygospores, a strong bias in the transmission of non-Mendelian alleles from the mating-type "plus" parent was indicated by an excess of meiotic and postmeiotic mitotic progeny that were homoplasmic for non-Mendelian alleles from this parent compared to those that were homoplasmic for the non-Mendelian alleles from the mating-type "minus" parent. At best, weak linkage was detected between the sr-nM1 and er-nM1 loci. Non-Mendelian, chloroplast gene markers in Chlamydomonas eugametos and Chlamydomonas reinhardtii showed a predominantly uniparental mode of transmission from the mating-type "plus" parent in crosses performed under the same conditions used for the C. moewusii crosses.     

SYSTEMATICS OF THE GENUS ZYGNEMA (ZYGNEMATOPHYCEAE,CHAROPHYTA) FROM CALIFORNIAN WATERSHEDS1

Natural populations of Zygnema were collected from 80 stream sites across California, and eight species were identified and characterized morphologically. Generic and infrageneric concepts of Zygnema and Zygogonium were tested with cox3 and rbcL gene sequence analysis. Strains of Zygnema were positioned in a single monophyletic clade sister to Zygogonium tunetanum Gauth.‐Lièvre. In both the rbcL and cox3 phylogenies, strains of Zygnema formed two major clades. The first clade contained species that have zygospores with a blue‐colored mesospore or akinetes with a colorless mesospore. The second clade contained species that have a yellow or brown mesospore. The existing taxonomic concepts for Zygnema classification are not consistent with our molecular phylogeny and do not correspond to natural groups. We propose that mesospore color may be useful in the infrageneric classification of Zygnema. Newly described Zygnema aplanosporum sp. nov. and Zygnema californicum sp. nov. have zygospores with a blue mesospore formed in the conjugation tube and separated by a cellulosic sporangial wall. Z. aplanosporum also possessed a combination of vegetative and reproductive features characteristic of Zygogonium, such as presence of short branches, rhizoidal outgrowths, thickened vegetative cell walls, purple‐colored cell content, small compressed‐globular chloroplasts as well as predominant asexual reproduction. Z. aplanosporum and Z. californicum were deeply embedded in a larger clade of Zygnema both in rbcL and cox3 analyses. Based on our observations, there are no features or combination of features that separate Zygnema and Zygogonium. Therefore, we conclude that Zygogonium is probably a synonym of Zygnema.     

Trisporoids and carotenoids in <Emphasis Type="Italic">Blakeslea trispora</Emphasis> strains differing in capacity for zygote formation

The study of sexual interaction in seven (+) and four (−) Blakeslea trispora strains from the All-Russian Collection of Microorganisms showed that all the strains were capable of forming zygotes, albeit to a varying degree. Thus, pairs of strains with active zygote formation and not forming zygospores were identified. It was established that, irrespective of their capacity for zygote formation, all pairs of the (+) and (−) strains synthesized trisporoids in submerged culture. However, zygote-forming pairs accumulated significantly more trisporoids and carotenoids than the strain pairs incapable of forming zygospores. As a result, positive correlation between the capacity for zygote formation in surface culture and trisporoid and carotenoid synthesis in submerged culture was revealed in wild strains.     

Effects of chemical components and nitrogen sources on zygospore development inPhycomyces blakesleeanus

We examined the effects of chemical components and nitrogen sources on zygospore development, using 62 different ingredients based on Sutter's synthetic medium Sl, which has been widely used for studies of sexual physiology inPhycomyces. An increase of inorganic microelements such as ZnSO₄, NaMoO₄ and CaCl₂ promoted an increase in the number of zygospores per unit area. Glutamate (Glu) contained in Sl as the sole nitrogen source was indispensable for sexual development, and replacement of Glu with NH₄ ⁺ (Am) strongly inhibited it, mainly because of growth inhibition. However, zygospore production was enhanced 1.8-fold by equivalent amounts of both Glu and Am as compared with Glu alone. A newly developed medium, mSl+Am, enriched with Am and the above-mentioned effective microelements doubled the number of zygospores formed per unit area (density), compared with Sutter's original Sl, and increased both the density and the weight (volume) of zygospores, 1.6- and 2-fold, respectively, compared with potato-dextrose-agar medium enriched with yeast extract and casitone (PDAYC). Sexual stimulation by mSl+Am was also observed in the mating of a pair of β-carotene-deficient mutants. Methionine sulfoxime, an inhibitor of glutamine synthetase, strongly inhibited the progress of mating without significant growth inhibition. The first and the second authors contributed equally to this work.     

Numerical and structural changes in dictyosomes during zygospore germination ofClosterium ehrenbergii

Summary Numerical and structural changes in dictyosomes during the germination of zygospores inClosterium ehrenbergii were examined by electron microscopy. In the dormant mature zygospores, two parallel cisternac were seen which were derived from the disorganization of dictyosomes during the maturation of zygospores. After the induction of germination, the two parallel cisternae developed into dictyosomes with ten or eleven cisternae. The dictyosomes doubled in number by division every day for four days and reached, at the time of germination, a density of distribution similar to that found in the youngest zygospore. On the 4th day after the induction of germination, dictyosomes produced two kinds of vesicles which appear to be involved in the formation of new cell wall layers. The germination of the zygospore was effected by the escape of the cell covered with the new cell wall layers through the broken old cell wall layers.