Evolutionary regularities of development of somatic polyploidy in salivary glands of gastropod mollusks: V. Subclasses Opisthobranchia and Pulmonata

Salivary glands of 25 species of Opisthobranchia and Pulmonata gastropod mollusks were studied with the use of histochemical methods and cytophotometry of DNA in cellular nuclei. In the secretory epithelium, cells of three main types are identified: granular cells (with granular glycoprotein inclusions), mucocytes-I (containing sulphatized acid mucopolysaccharides), and mucocytes-II (containing neutral and acid nonsulphatized polysaccharides and protein), as well as epithelial ciliated cells and cells of ducts. It is shown that the salivary gland secretory cells of all studied mollusk species are polyploidized, but to different degree. In most species, the maximal degree of polyploidy estimated by the DNA content amounts to 64–128c. Giant polyploidy—up to 4096c—is revealed in salivary gland cells of Tritonia diomedea. The functional properties due to the peculiarities of nutrition of different molluscan species and phylogenetic tendencies of development of somatic polyploidy in the class of Gastropoda are discussed. The high degree of obligatory polyploidization revealed in salivary gland cells of the opisthobranchian and pulmonate mollusks is considered as a peculiar cytological arogenesis as compared with allogenic, facultative, and slight manifestations of polyploidy in prosobranchian gastropod mollusks. The probable causes of such differences are due to the euthyneural type of organization of the central nervous system and to the giant neuronal polyploidy in opisthobranchian and pulmonate mollusks. The causes, mechanisms, and significance of such correlations are so far unclear.     

Patterns of endopolyploidy and 2C nuclear DNA content (Feulgen) inScilla (Liliaceae)

The Feulgen-DNA content of 3558 nuclei from 21 different tissues and organs ofScilla decidua (Liliaceae) was measured by a scanning cytophotometer interfaced to a computer. The basic nuclear DNA content (2 C value) was 13.62 pg, and 71 per cent of the nuclei were polyploid. The highest DNA values were found in the antipodal cells of the ovule, and the elaiosomes of the seeds (512 C). In addition to polyploidy, the 2 C values exhibited tissue-specific variation which was statistically significant (0.05% level of probability), It is suggested that differential DNA replication and endopolyploidization may be basic factors in the complex mechanism of cell and tissue differentiation.Dedicated to Professor Dr.Lothar Geitler in honour of his 80th birthday.     

Nuclear DNA content in differentiated tissues of sunflower (Helianthus annuus L.)

Summary Scanning cytophotometry following Feulgen-staining was used to determine nuclear DNA content in many differentiated tissues of nine cultivars, hybrids or selfed lines ofHelianthus annuus. Apart from such ephemeral tissues as endosperm and anther tapetum, it was found that tissue differentiation in sunflower occurs in the diploid condition, cells being arrested in the DNA presynthetic phase (G₁). In certain cases, however, the nuclear DNA content of differentiated G₁ cells does not exactly match the 2C DNA content found in meristematic cells, but may be either higher or lower. In endosperm and anther tapetum cells, nuclear DNA content may be as high as 24 C and 32 C, respectively. Cytological and autoradiographic analyses after³H-thymidine incorporation reveal that polyploidy in the tapetal cells is due to chromosome endoreduplication. No detectable difference between male-fertile and male-sterile plants exists as far as occurrence and level of cell polyploidy are concerned. The results are discussed in the context of previous investigations on the nuclear condition of differentiatedHelianthus annuus tissue.     

A comparative study of the effect of RNA and DNA treatment on somatic nuclei in plant cells

Summary The effect of different concentrations of ribonucleic acid (RNA) and desoxyribonucleic acid (DNA) has been studied on meristematic somatic cells ofAllium cepa. The principal effects noted with both are polyploidy and reductional separation of chromosomes.It has been assumed that RNA causes viscosity change in the plasma, which is responsible for polyploidy. DNA, though entering in a minute quantity due to its high molecular weight, gets ultimately converted into RNA precursors and finally causes the same effect. Somatic reduction is caused by an increase in the DNA content of the plasma and as such, application of this chemical causes reductional separation of chromosomes. RNA, on the other hand, needs gradual conversion into DNA precursors to cause the effect. The concurrent nature of the two processes allows the simultaneous occurrence of polyploidy and somatic reduction after a brief interval following artificial treatment.With 8 Figures in the Text     

Somatic Polyploid Petals: Regeneration Offers New Roads for Breeding Belgian Pot Azaleas

Bud sporting, the consequence of sudden variations in gene expression of somatic cells, leads to the occurrence of phenotypically altered shoots in many vegetatively propagated plant species. In ornamentals, such as azalea (Rhododendron simsii), flower colour bud sports are appreciated as a valuable additional source of variation, and it is evident that both genetic and epigenetic mechanisms are involved in the creation of the whole colour range. Flowers exhibiting two-coloured petals, i.e. the margin is coloured differently than the central zone, characterize one of the sport types, namely picotees. This particular sporting type contributes to the enlargement of the available variation not only because of its coloration pattern but interestingly displays somatic polyploidy in its petals. The differently coloured petal margin is tetraploid while the rest of the corolla, as well as the entire plant are diploid. Aiming at introducing polyploidy in the completely diploid breeding collection, in vitro regeneration of tetraploid petal marginal tissue was performed. This led to the production of the first induced tetraploid Belgian azalea. The markedly increased robustness of the flowers as well as their polyploid status is exceptionally interesting for breeding programs.     

Detection of protoplast-derived DNA tetraploid Lisianthus (Eustoma grandiflorum) plants by leaf and flower characteristics and by flow cytometry

Plants of lisianthus (Eustoma grandiflorum (Griesbach)Schinners=Lisianthus russellianus Hook.) were regenerated from protoplasts and grown in pots until flowering. Vegetative and floral characteristics were measured and compared with parent plants. Larger leaves and petals and longer guard cells, sepals and filaments were recorded from protoplast-derived plants suggestive of polyploidy. The nuclear DNA contents of protoplast-derived and parental plants were determined by flow cytometry. Protoplast-derived plants were confirmed as DNA tetraploid by flow cytometry with a DNA index of 1.95. Their nuclear DNA content was measured as 6.33±0.04 pg DNA per 2C nucleus compared with 3.26±0.10 pg DNA per 2C nucleus from parental plants. Polyploidisation induced during protoplast regeneration offers an alternative to that of colchicine treatment.     

Genome size and polyploidy variation in the tropical hardwood genusTerminalia (Combretaceae)

Chromosome complements and 2C DNA amounts of six species ofTerminalia have been studied.Terminalia oliveri, T. myriocarpa andT. arjuna are diploid (2n = 24),T. chebula andT. bellirica are tetraploid (2n = 48),T. muelleri shows a triploid number (2n = 36). Two well demarcated groups of species are recognizable on the basis of chromosome length and 2C DNA values which range from 3.60 pg (T. oliveri) to 12.80 pg (T. bellirica) showing a 3.5-fold difference. Differences of DNA per basic genome or per chromosome are greatest (1.97-fold) betweenT. oliveri andT. arjuna. Two species groups (1)T. oliveri andT. chebula, and (2)T. myriocarpa, T. arjuna, T. muelleri, T. bellirica, therefore are well differentiated by DNA per basic genome, irrespective of polyploidy. The mean values of the two groups are 1.81 pg and 3.34 pg, respectively, showing a 1.84-fold difference. Within diploids and tetraploids there is 1.97-fold and 1.76-fold variation, respectively.     

Evolution of genome size inAllium (Alliaceae)

The 4C DNA amounts of 86 species fromAllium subgg.Allium, Rhizirideum, Bromatorrhiza, Melanocrommyum, Caloscordum andAmerallium show a 8.35-fold difference ranging from 35.60 pg (A. ledebourianum, 2n = 16) to 297.13 pg (A. validum 2n = 56). At diploid level the difference is 3.57-fold betweenA. ledebourianum (35.60 pg) andA. ursinum (127.14 pg). This shows that a significant loss and/or gain of DNA has occurred during evolution. On average subgg.Rhizirideum andAllium have less DNA amount than subgg.Melanocrommyum andAmerallium. The distribution of nuclear DNA amounts does not show discontinuous pattern and regular groups. The evolution of genome size has been discussed in relation to polyploidy and genomes, heterochromatin, adaptive changes in morphological characteristics, phenology and ecological factors, and infrageneric classification.     

Nuclear DNA content of somatic and zygotic embryos ofVitis vinifera cv. Grenache noir at the torpedo stage

Summary A flow cytometric analysis and an in situ DNA microspectrophotometric study were made concomitantly to establish why somatic grapevine (Vitis viniferacv. Grenache noir) embryos showed a low level of conversion into plantlets. In somatic embryos at the torpedo stage and in zygotic embryos at the same stage of development, ploidy level, DNA content per 2 C nucleus, and the cell-cycle state of the shoot apical meristem were examined. The frequency distribution histograms of nuclear DNA values were similar in the two types of embryos. At the torpedo stage both types of embryos had a majority of nuclei with 2 C DNA content equal to 1.6pg. In the shoot apices of somatic and zygotic embryos, DNA microspectrophotometry showed preferential blockage of the cell cycle at the G_0–1 stage; however, 20% of somatic embryo shoot apices were blocked at the G_0–2 stage. Analogies between somatic embryos and their zygotic homologues were shown. The genetical and environmental causes of the low level of conversion of grapevine somatic embryos into plantlets are discussed. Our work suggests that the in vitro culture conditions which were used could be incompatible with normal morphogenesis from the torpedo stage.     

Evidence for dosage compensation in parthenogenetic Hymenoptera

Amount of DNA-Feulgen staining in individual somatic nuclei and mature sperm of the parthenogenetic wasps, Habrobracon juglandis, H. serinopae, and Mormoniella vitripennis, were determined with a scanning microdensitometer. The haploid genome for both species of Habrobracon was estimated to be 0.15–0.16×10^–12 g DNA, corresponding to a molecular weight of roughly 10×10¹⁰ daltons. The haploid genome of M. vitripennis is approximately twice this value, 0.33–0.34×10^–12 g, or about 20×10¹⁰ daltons. Measurements made on dividing nuclei from syncytial preblastoderm embryos of H. juglandis and M. vitripennis showed that the chromosomes of impaternate males were present in the haploid number and contained the C amount of DNA; whereas nuclei from female preblastoderm embryos contained the diploid number of chromosomes and the 2C amount of DNA. However, hemocyte and brain cell nuclei from either male or female adult wasps contained 2C and 4C amounts of DNA. Both sexes also showed equivalent levels of polyploidy (8C, 16C, or 32C) in Malpighian tubule nuclei. Therefore, in these parthenogenetic species, a mechanism must exist that compensates during later development for the initial two-fold difference in the chromatin content of somatic nuclei in haploid male and diploid female embryos. Hemocytes from impaternate Mormoniella diploid males and triploid females contain the 2C and 3C amounts of DNA, respectively. Therefore dosage compensation involves an additional cycle of DNA replication only in haploid cells, and it insures that a certain minimum quantity of DNA is received by each somatic cell.     

Quantitative nuclear DNA changes inEleusine (Gramineae)

2C nuclear DNA amounts were determined in 30 collections belonging to 10 species ofEleusine. About a 2.5-fold variation in genome size is evident in the genus. The 2C DNA amount in the diploid species ranged from 2.50 pg inE. verticillata to 3.35 pg inE. intermedia. In contrast, the tetraploid species showed a range from 4.95 pg inE. africana to 6.13 pg inE. floccifolia. At intraspecific level 10 collections ofE. coracana, 6 ofE. indica, 4 ofE. africana, 2 ofE. tristachya, and 2 ofE. kigeziensis did not show any significant variation. However, 2 collections ofE. floccifolia, connected with polyploidy, displayed about 90% variation. Polyploid species showed approximately double the genome size of that of their corresponding diploids. An evolutionary increase in DNA amount is evident inE. coracana during the course of its origin and domestication fromE. africana.     

Intergeneric somatic hybridization in Gramineae: somatic hybrid plants between tall fescue (Festuca arundinacea Schreb.) and Italian ryegrass (Lolium multiflorum Lam.)

Summary Tall fescue (Festuca arundinacea Schreb.) protoplasts, inactivated by iodoacetamide, and non-morphogenic Italian ryegrass (Lolium multiflorum Lam.) protoplasts, both derived from suspension cultures, were electrofused and putative somatic hybrid plants were recovered. Two different genotypic fusion combinations were carried out and several green plants were regenerated in one of them. With respect to plant habitus, leaf and inflorescence morphology, the regenerants had phenotypes intermediate between those of the parents. Southern hybridization analysis using a rice ribosomal DNA probe revealed that the regenerants contained both tall fescue- and Italian ryegrass-specific-DNA fragments. A cloned Italian ryegrass-specific interspersed DNA probe hybridized to total genomic DNA from Italian ryegrass and from the green regenerated somatic hybrid plants but not to tall fescue. Chromosome counts and zymograms of leaf esterases suggested nuclear genome instability of the somatic hybrid plants analyzed. Four mitochondrial probes and one chloroplast DNA probe were used in Southern hybridization experiments to analyze the organellar composition of the somatic hybrids obtained. The somatic hybrid plants analyzed showed tall fescue, additive or novel mtDNA patterns when hybridized with different mitochondrial gene-specific probes, while corresponding analysis using a chloroplast gene-specific probe revealed in all cases the tall fescue hybridization profile. Independently regenerated F. arundinacea (+) L. multiflorum somatic hybrid plants were successfully transferred to soil and grown to maturity, representing the first flowering intergeneric somatic hybrids recovered in Gramineae.     

Analysis of nuclear and organellar DNA of somatic hybrid calli and plants between Lycopersicon spp. and Nicotiana spp.

Protoplast fusion experiments between Lycopersicon esculentum or L. peruvianum and Nicotiana tabacum or N. plumbaginifolia were performed to investigate the possibility of producing symmetric and asymmetric somatic hybrids between these genera. These fusions, which involved 1.7 × 10⁸ protoplasts, yielded 35 viable hybrid calli. Plant regeneration was successful with two calli. One of these regenerants flowered, but developed no fruits. Analysis of the nuclear DNA by means of dot blot hybridization with species-specific repetitive DNA probes combined with flow cytometry, revealed that the nuclei of most hybrid calli contained the same absolute amount of Nicotiana DNA as the Nicotiana parent or (much) less, whereas the amount of Lycopersicon DNA per nucleus was 2–5 times that of the parental genotype. Eighteen of the 34 hybrids analyzed possessed Lycopersicon chloroplast DNA (cpDNA), whereas the other 16 had DNA from Nicotiana chloroplasts. The cpDNA type was correlated with the nuclear DNA composition; hybrids with more than 2C Nicotiana nuclear DNA possessed Nicotiana chloroplasts, whereas hybrids with 2C or less Nicotiana nuclear DNA contained Lycopersicon chloroplasts. Mitochondrial DNA (mtDNA) composition was correlated with both nuclear DNA constitution and chloroplast type. Hybrids possessed only or mainly species-specific mtDNA fragments from the parent predominating in the nucleus and often providing the chloroplasts. The data are discussed in relation to somatic incompatibility which could explain the low frequency at which hybrids between Lycopersicon and Nicotiana species are obtained and the limited morphogenetic potential of such hybrids.     

Mitochondrial DNA polymorphism induced by protoplast fusion in Cruciferae

Summary The mitochondrial genomes of five rapeseed somatic hybrid plants, which combine in a first experimentBrassica napus chloroplasts and a cytoplasmic male sterility trait coming fromRaphanus sativus, and in a second experiment chloroplasts of a triazine resistantB. compestris and a cytoplasmic male sterility trait fromR. sativus, were analyzed by restriction endonucleases. Restriction fragment patterns indicate that these genomes differ from each other and from both parents. The presence of new bands in the somatic hybrid mitochondrial DNA restriction patterns is evidence of mitochondrial recombination in somatic hybrid cells. In both parental and somatic hybrid plants large quantitative variations in a mitochondrial plasmid-like DNA have been observed. Our results suggest that the cytoplasmic support for male sterility is located in the chromosomal mitochondrial DNA instead of the plasmid-like DNA.     

Flow cytometric measurements do not reveal different ploidy levels in Minthostachys (Lamiaceae)

Ten of the 17 species of the taxonomically difficult Andean mint genus Minthostachys (Lamiaceae) were submitted to flow cytometric measurements of nuclear DNA content to test the hypothesis of the occurrence of different ploidy levels within the genus. Nuclear DNA content was found to vary from 1.643 to 1.775 pg, i.e by only ca. 8% between individual accessions, thus providing no evidence for polyploidy in Minthostachys. While these results do not preclude the possibility that the genus contains polyploid species nor the occurrence of heteroploidy with nearly identical nuclear DNA contents, they suggest that polyploidy did not play a major role in its diversification.     

Flow cytometric and morphological analyses of Pinus pinaster somatic embryogenesis

An approach combining morphological profiling and flow cytometric analysis was used to assess genetic stability during the several steps of somatic embryogenesis in Pinus pinaster. Embryogenic cell lines of P. pinaster were established from immature zygotic embryos excised from seeds obtained from open-pollinated trees. During the maturation stage, phenotype of somatic embryos was characterized as being either normal or abnormal. Based upon the prevalent morphological traits, different types of abnormal embryos underwent further classification and quantification. Nuclear DNA content of maritime pine using the zygotic embryos was estimated to be 57.04 pg/2C, using propidium iodide flow cytometry. According to the same methodology, no significant differences (P ≤ 0.01) in DNA ploidy were detected among the most frequently observed abnormal phenotypes, embryogenic cell lines, zygotic and normal somatic embryos, and somatic embryogenesis-derived plantlets. Although the differences in DNA ploidy level do not exclude the occurrence of a low level of aneuploidy, the results obtained point to the absence of major changes in ploidy level during the somatic embryogenesis process of this economically important species. Therefore, our primary goal of true-to-typeness was assured at this level.     

Karyotype analysis and heterochromatin differentiation with Giemsa C-banding and fluorescent counterstaining inCephalanthera (Orchidaceae)

Detailed studies of the chromosomes of the three Austrian species of the genusCephalanthera showed them all to have basically similar karyotypes. BothC. damasonium (2n = 36) andC. longifolia (2n = 32) have three large and several classes of smaller chromosome pairs. The karyotype ofC. rubra (2n = 44) is composed of four large and several groups of smaller pairs. The heterochromatin in these species amounts to about 10% of total karyotype length. All the chromosomes have Giemsa-positive centromeres, but only a few have intercalary or terminal bands. Using differential fluorescent staining with DAPI/actinomycin D, quinacrine/actinomycin D (both A-T specific), and chromomycin A₃/distamycin A (G-C specific) three different types of major heterochromatic bands can be characterized in respect of their satellite DNA composition: highly A-T rich, slightly A-T rich, and very G-C rich. The chromosomes ofC. longifolia contain more A-T rich C-bands than those ofC. damasonium, while the latter's have more G-C rich heterochromatin. In both species several C-bands appear as secondary constrictions or gaps in the Feulgen-stained chromosomes, but most likely, in each species there is only one pair of chromosomes where the secondary constrictions function as nucleolus organizing regions. No major intraspecific variation could be observed except on one small chromosome pair ofC. longifolia which had a heteromorphic C-band in most individuals. Possible pathways of karyotype evolution involving polyploidy and Robertsonian events are discussed.     

Transformation of lepidopteran and coleopteran insect cell lines by Glyptapanteles indiensis polydnavirus DNA

Summary Recently investigators showed that polydnavirus DNA from the parasitic wasp Glyptapanteles indiensis could transform gypsy moth L. dispar cell lines in vitro (McKelvey et al., 1996). Here we show GiPDV DNA is capable of transforming in vitro to varying degrees lepidopteran (IPLB-TN-R², IPLB-SF-21, IAL-PID2, IPLB-HvT1) and coleopteran (IPLB-DU182E) insect cell lines derived from various somatic tissue types. An insect cell line derived from dipteran Aedes albopictus (C7/10) could not be transformed with G. indiensis polydnavirus.     

Linear kalilo DNA is a Neurospora mitochondrial plasmid that integrates into the mitochondrial DNA

Summary The linear autonomous form of kalilo DNA (previously called AR-kalDNA) is shown to be resident within mitochondria rather than nuclei, as had been suggested by previous experiments. This form has been renamed mtAR-kalDNA, to signify its mitochondrial location. Experiments are described that illustrate the inheritance and somatic transmission patterns of the mitochondrial kalilo plasmid and the mitochondrial inserted form of kalilo DNA (mtlS-kalDNA). Progeny of a cross with a pre-senescent subculture as the female parent inherited mtAR-ka1DNA only; mtIS-kalDNA was not transmitted sexually. During somatic propagation of the ascospore cultures, novel kalilo DNA inserts appeared and most of them persisted until death. We propose that these inserts originated from de novo integration of mtAR-kalDNA into the mitochondrial DNA. In two of the ascopore-derived series analyzed, the first inserts detected were seen only transiently and inserts appearing subsequent to the transient inserts were retained until death. We propose that these enduring inserts originated either from rearrangements of the transient inserts or from novel integration events, either from mtAR-kalDNA or from transposition of the transient inserts.     

Mitochondrial DMA variation in somatic embryogenic cultures ofLarix

outhern hybridization analysis using wheat mitochondrial gene-specific probes indicates that changes in mitochondrial genomic organization and the relative representation of certain genomic regions occur during in vitro somatic embryogenic cell culture ofLarix species. We observed differences in the mitochondrial (mt)DNA hybridization patterns between somatic embryogenic cell cultures and trees grown from seed forLarix leptolepis,L. decidua, and the reciprocal hybrids of these twoLarix species. This is the first study to describe the correlation of molecular changes in a gymnosperm mitochondrial genome with in vitro somatic embryogenic cell culture. Quantitative differences in mtDNA hybridization signals were also observed among a 4-year-old somatic embryogenic cell culture ofLarix ×eurolepis trees regenerated from this culture, and the seed source tree from which the somatic embryogenic cell cultures were initiated.