Cytological events in explants of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> during early callogenesis

Leaf explants of diploid (2n = 2x = 10) and autotetraploid (2n = 4x = 20) plants of Arabidopsis thaliana ecotype Columbia were cytologically and cytogenetically analysed to determine the time and the mechanisms of the process of polyploidization. The first polyploid cells were observed after the third day of culture in both genotypes of explants. Polyploid cells were the result of pre-existing mixoploidy in explants of A. thaliana. Other factors such as endoreduplication, endomitosis, abnormal microtubules arrangement and DNA damage may have induced polyploidization during early stages of callogenesis.     

Chromosome variations in regenerants of Arabidopsis thaliana derived from 2- and 6-week-old callus detected using flow cytometry and FISH analyses

Shoot organogenesis was induced from 2- and 6-week-old callus derived from the leaves of Arabidopsis thaliana ecotype Columbia (2n = 10). Regenerated plants were evaluated for chromosomal variations by means of flow cytometry and fluorescent in situ hybridization (FISH). Flow cytometric measurements revealed the occurrence of diploid, tetraploid, and octoploid plants among the regenerants of 2-week-old calli, whereas only diploid and tetraploid plants were regenerated from the 6-week-old calli. Chromosome counting showed that plants developed from the 2-week-old calli exhibited mixoploidy and a high frequency of aneuploid cells. These plants were infertile and displayed altered morphology. FISH with 5S and 25S rDNA probes allowed to detect some structural chromosomal rearrangements in regenerated plants. Along with cells which exhibited correct localisation of rDNA loci, also cells bearing chromosomal translocations, deletions or duplications were found. The type of structural aberrations varied between diploid and tetraploid regenerants.     

ENDOMITOSIS IN TAPETAL CELLS OF EREMURUS (LILIACEAE)

True endomitosis in the anther tapetum of the liliaceous plant Eremurus is described. The nuclear membrane does not disappear, but during metaphase the chromosomes are condensed, often considerably more than in normal mitosis. When the pollen mother cells (PMCs) go through the last premeiotic mitosis, the tapetal cells have one diploid nucleus which divides while the cell remains undivided. The two diploid nuclei may undergo an endomitosis and the resulting tetraploid nuclei a second endomitosis. An alternative pathway is an ordinary mitosis—again without cell division—instead of one of the endomitotic cycles. The cytological picture in the tapetum is further complicated by restitution in anaphase and fusion of metaphase and anaphase groups during mitosis, processes which could give rise to cells with one, two, or three nuclei, instead of the expected two or four. No sign of the so-called “inhibited” mitosis is seen in these tapetal cells. When the PMCs are in leptotene-zygotene, very few tapetal nuclei are in endomitosis. When the PMCs have reached diplotene, almost 100% of cells which are not in interphase show an endomitotic stage.     

Procedure for whole mount fluorescence in situ hybridization of interphase nuclei on Arabidopsis thaliana

A procedure for whole mount fluorescence in situ hybridization (FISH) on plant tissue is reported. The technique was demonstrated on seedlings and flowers of Arabidopsis thaliana L. with rDNA as a probe, labelled, both for direct and indirect detection. It was found that fixation in 1% formaldehyde yielded the best results with respect to morphology and hybridization efficiency. The combination of whole mount FISH and confocal scanning laser microscopy allowed the nuclear localization of the rDNA loci in all tissues of both seedlings and flowers. Direct labelling yielded the best signal-to-noise ratio, especially in the apical zones of the seedlings. The technique was further illustrated on seedlings of A. thaliana in double labelling experiments with rDNA and a tandemly repeated, 500 bp sequence of A. thaliana. Although nuclei in all tissues in the seedling exhibited both signals, hybridization efficiency for both signals was reduced in the dense, apical zones as compared with single labelling experiments with rDNA.     

Nuclear fusions contribute to polyploidization of the gigantic nuclei in the chalazal endosperm of<Emphasis Type="Italic"> Arabidopsis</Emphasis>

Somatic polyploidization is recognized as a means to increase gene expression levels in highly active metabolic cells. The most common mechanisms are endoreplication, endomitosis and cell fusion. In animals and plants the nuclei of multinucleate cells are usually prevented from fusing. Here, we report that the nuclei from the syncytial cyst of the chalazal endosperm of Arabidopsis thaliana (L.) Heynh. are polyploid with some intermediate ploidy levels that cannot be attributed to endoreplication, suggesting nuclear fusion. Analysis of isolated nuclei, together with fluorescent in situ hybridization (FISH), revealed that nuclei from the chalazal endosperm are two or three times bigger than the nuclei from the peripheral endosperm and have a corresponding increase in ploidy. Together with the consistent observation of adjoined nuclei, we propose that nuclear fusion contributes, at least in part, to the process of polyploidization in the chalazal endosperm. Confocal analysis of intact seeds further suggested that free nuclei from the peripheral endosperm get incorporated into the chalazal cyst and likely participate in nuclear fusions.Abbreviations BAC Bacterial artificial chromosome - CZE Chalazal endosperm - DAPI 4,6-Diamino-2-phenylindole - FISH Fluorescent in situ hybridization - NOR Nucleolar organizing region - NCD Nuclear cytoplasmic domain - PEN Peripheral endosperm     

Molecular Cytogenetics of the Genus Arabidopsis: In situ Localization of rDNA Sites, Chromosome Numbers and Diversity in Centromeric Heterochromatin

We have used in situ hybridization to determine the number ofsites of rDNA in species in the genus Arabidopsis. A. wallichii(2n = 16) has one major pair of sites and one minor pair ofsites, while A. pumila and A. griffithiana (both 2n = 32) havesix major and two minor rDNA sites. A. thaliana (2n = 10) isknown to have two pairs of rDNA sites. a highly repeated para-centromericsequence from A. thaliana, pAL1, is absent in the other threespecies. Hence the A.thaliana genome is not present (or thecentromeric DNA has evolved substantially) in the polyploidspecies A. pumila and A. griffithiana. Analysis of Arabidopsisspecies is a valuable complement to the large programmes forgenetic analysis of A. thaliana.Copyright 1993, 1999 AcademicPress Arabidopsis, centromeric DNA, maps (genetic), nuclear architecture, repetitive DNA, ribosomal DNA, rDNA, evolution, Brassicaceae, Crucifereae, in situ hybridization     

Aneuploidy and genetic variation in the Arabidopsis thaliana triploid response

Polyploidy, the inheritance of more than two genome copies per cell, has played a major role in the evolution of higher plants. Little is known about the transition from diploidy to polyploidy but in some species, triploids are thought to function as intermediates in this transition. In contrast, in other species triploidy is viewed as a block. We investigated the responses of Arabidopsis thaliana to triploidy. The role of genetic variability was tested by comparing triploids generated from crosses between Col-0, a diploid, and either a natural autotetraploid (Wa-1) or an induced tetraploid of Col-0. In this study, we demonstrate that triploids of A. thaliana are fertile, producing a swarm of different aneuploids. Propagation of the progeny of a triploid for a few generations resulted in diploid and tetraploid cohorts. This demonstrated that, in A. thaliana, triploids can readily form tetraploids and function as bridges between euploid types. Genetic analysis of recombinant inbred lines produced from a triploid identified a locus on chromosome I exhibiting allelic bias in the tetraploid lines but not in the diploid lines. Thus, genetic variation was subject to selection contingent on the final ploidy and possibly acting during the protracted aneuploid phase.     

Occurrence and Inheritance of 2 n Pollen in Musa

Sexual polyploidization explains the formation of most polyploidcrop species and provides means for their genetic improvement.This paper reports the occurrence and inheritance of 2n pollenin diploid and polyploidMusa . Pollen samples of male fertileaccessions available in the field gene bank of the InternationalInstitute of Tropical Agriculture were microscopically examinedthroughout a calendar year. Based on pollen diameter 2n pollenproducers were identified. The presence of 2n pollen in diploidspecies suggests that unilateral sexual polyploidization (2nxn) could have been involved in the origin of triploidMusa species.Segregation data suggests that at least one dominant gene controls2n pollen production inMusa . Further introgression of desirablealleles from diploid species to polyploids could be achievedeither through unilateral or bilateral (2nx2n ) sexual polyploidizationinMusa . Musa spp.; Musa hybrids; 2n gametes; evolution; ploidy manipulations; sexual polyploidization     

Stimulation of Cell Elongation by Tetraploidy in Hypocotyls of Dark-Grown Arabidopsis Seedlings

Plant size is largely determined by the size of individual cells. A number of studies showed a link between ploidy and cell size in land plants, but this link remains controversial. In this study, post-germination growth, which occurs entirely by cell elongation, was examined in diploid and autotetraploid hypocotyls of Arabidopsis thaliana (L.) Heynh. Final hypocotyl length was longer in tetraploid plants than in diploid plants, particularly when seedlings were grown in the dark. The longer hypocotyl in the tetraploid seedlings developed as a result of enhanced cell elongation rather than by an increase in cell number. DNA microarray analysis showed that genes involved in the transport of cuticle precursors were downregulated in a defined region of the tetraploid hypocotyl when compared to the diploid hypocotyl. Cuticle permeability, as assessed by toluidine-blue staining, and cuticular structure, as visualized by electron microscopy, were altered in tetraploid plants. Taken together, these data indicate that promotion of cell elongation is responsible for ploidy-dependent size determination in the Arabidopsis hypocotyl, and that this process is directly or indirectly related to cuticular function.     

FISH mapping of 35S and 5S rRNA genes in Artemisia subgenus Dracunculus (Asteraceae): changes in number of loci during polyploid evolution and their systematic implications

Fluorescence in situ hybridization (FISH) with 35S and 5S rDNA probes was used to characterize cytogenetically representatives of Artemisia subgenus Dracunculus and allied species and to explore their evolution following polyploidization. At the diploid level two rDNA loci were observed in most species belonging to the A. dracunculus complex, a pattern considered to be the ancestral state for diploid Artemisia. In contrast, representative species from the Eurasian grade which belong to the other major lineage of the subgenus had more heterogeneous rDNA profiles, with three to five loci at the diploid level. Divergent patterns of locus evolution were also detected in polyploids, with the number and distribution of rDNA loci broadly fitting the two main diversification lineages in the subgenus. In the polyploid complex of A. dracunculus, the number of rDNA loci was almost proportional to ploidy, although monoploid genome size was shown to decrease with increasing ploidy. However, in polyploids from the Eurasian grade we found a remarkable reduction in the number of rDNA sites, suggesting that these species might have experienced either a complete loss of loci or a significant reduction in the number of repeats following polyploid formation. © 2013 The Linnean Society of London, Biological Journal of the Linnean Society, 2013 , 171 , 655–666.     

The allotetraploid <Emphasis Type="Italic">Arabidopsis thaliana–Arabidopsis lyrata</Emphasis> subsp. <Emphasis Type="Italic">petraea</Emphasis> as an alternative model system for the study of polyploidy in plants

Polyploidy is known to be common in plants and recent work has focused on the rapid changes in genome structure and expression that occur upon polyploidization. In Arabidopsis, much of this work has been done on a synthetic allotetraploid obtained by crossing a tetraploid Arabidopsis thaliana (2n = 4x = 20) with A. arenosa (2n = 4x = 32). To explore an alternative route to polyploidy in this model species, we have developed a synthetic allopolyploid by crossing two diploid species: A. thaliana (2n = 2x = 10) and Arabidopsis lyrata subsp. petraea (2n = 2x = 16). F₁ hybrids were easy to obtain and phenotypically more similar to A. lyrata. Spontaneous chromosome doubling events occurred in about 25% of the F₁s, thus restoring fertility. The resulting allotetraploids (2n = 26) exhibited many genomic changes typically reported upon polyploidization. Nucleolar dominance was observed as only the A. lyrata rDNA loci were expressed in the F₁ and allotetraploids. Changes in the degree of methylation were observed at almost 25% of the loci examined by MSAP analysis. Finally, structural genomic alterations did occur as a large deletion covering a significant portion of the upper arm of chromosome II was detected but no evidence of increased mobility of transposons was obtained. Such allotetraploids derived from two parents with sequenced (or soon to be sequenced) genomes offer much promise in elucidating the various changes that occur in newly synthesized polyploids.     

The Correlation between the Chromosome Variation in Callus and Genotype of Explants of Arabidopsis thaliana

Twelve callus lines of Arabidopsis thaliana were derived from four types of explants excised from diploid plants of two ecotypes (Columbia and Wilna) and autotetraploid plants of the Wilna ecotype. Cytogenetic analysis of the chromosome variation in particular callus lines was carried out for primary culture and callus during 5 months of culture. Ploidy levels of interphase nuclei were estimated by counting the number and size of chromocentres and nuclei of interphase cells. The first polyploid cells in all callus lines were observed during callogenesis. In primary culture the ploidy level ranged between 2 and 15x (10-75 chromosomes). The frequency of polyploid cells was higher in the 5-month old callus culture, but the ploidy level was the same. In the callus lines derived from autotetraploid plants, cells with reduced chromosome number appeared quite frequently along with diploid and polyploid cells.     

Natural variation in Arabidopsis lyrata vernalization requirement conferred by a FRIGIDA indel polymorphism

Species share homologous genes to a large extent, but it isnot yet known to what degree the same loci have been targetsfor natural selection in different species. Natural variationin flowering time is determined to a large degree by 2 genes,FLOWERING LOCUS C and FRIGIDA, in Arabidopsis thaliana. Here,we examine whether FRIGIDA has a role in differences in floweringtime between and within natural populations of Arabidopsis lyrata,a close outcrossing perennial relative of A. thaliana. We found2 FRIGIDA sequence variants producing potentially functionalproteins but with a length difference of 14 amino acids. Thesevariants conferred a 15-day difference in flowering time inan association experiment in 2 Scandinavian populations. Thedifference in flowering time between alleles was confirmed withtransformation to A. thaliana. Because the north European late-floweringpopulations harbor both late- and early sequence variants atintermediate frequencies and the late-flowering variant is mostfrequent in the southern early flowering European population,other genetic factors must be responsible for the floweringtime differences between the populations. The length polymorphismoccurs at high frequencies also in several North American populations.The occurrence of functional variants at intermediate frequenciesin several populations suggests that the variation may be maintainedby balancing selection. This is in contrast to A. thaliana,where independent loss-of-function mutations at the FRIGIDAgene are responsible for differences between populations andlocal adaptation.     

Localization of tandemly repeated DMA sequences in Arabidopsis thaliana

In-situ hybridization to interphase nuclei and chromosomes of Arabidopsis thaliana (2n= 10) shows that there are four sites of rDNA in a diploid nucleus. The sites are located on chromosomes 2 and 4, and the strength of hybridization indicates that copy number is similar at both pairs of sites. Hybridization to trisomic line 4 revealed five hybridization sites. Silver staining of nucleoli demonstrates that all four loci can be active in diploid interphase nuclei. The tandemly repeated probe pAL1 hybridizes near to the centromeres of all five chromosome pairs. In diploid interphase nuclei, 10 sites of hybridization are detected, while 15 are seen in triploid nuclei. The sites of hybridization co-localize with the centromeric heterochromatin visualized by staining DNA with the fluorochrome DAPI. The results demonstrate that molecular cytogenetics can be applied to A. thaliana and high resolution physical chromosome maps can be generated. Both probes may be useful for interphase cytogenetics, where they enable chromosome number and aneuploidy to be examined in tissues without divisions. The physical localization of these hybridization sites provides a starting point for linking RFLP and physical chromosome maps.     

High-resolution physical mapping in Arabidopsis thaliana and tomato by fluorescence in situ hybridization to extended DNA fibres

A technique to detect DNA sequences on extended DNA fibres (EDF) prepared from interphase nuclei from tomato (Lycopersicon esculentum) and Arabidopsis thaliana leaves by fluorescence in situ hybridization (FISH) is described. Three nuclear lysis procedures have been tested for their ability to decondense chromatin and to generate highly extended intact DNA fibres on microscopic slides. DNA probes of various sizes have been used in FISH experiments to EDFs to establish the resolution and sensitivity of the technique. The fluorescent signals of a 5S rDNA probe hybridized to tomato EDFs revealed continuous strings of about 200 µm, that corresponded to a molecular size of about 660 kb. In A. thaliana, a contig of three cosmids spanning a genomic region with a total length of about 89 kb was analysed. By means of multi-colour hybridization the physical positions of the cosmids were visualized as red and green fluorescence strings with overlapping regions in yellow. Comparison of the length of the fluorescent signals with the molecular data revealed a stretching degree of the DNA fibres at 3.27 kb µm^?1, which is close to the Watson-Crick DNA length estimate of 2.9 kb µm^?1. Other experiments on small size molecular probes with both lambda clones (13.5–17 kb insert sizes) and plasmids (4.2 and 5 kb) in a contig of A. thaliana, and the 5S rDNA region in tomato showed close agreement with molecular data. The lower limit of the detection, which was established in a hybridization experiment with two DNA probes from the 45S ribosomal gene on extended fibres of tomato, was about 0.7 kb. Consistent patterns of alternating fluorescent red and green spots were obtained reflecting the tandemly repeated arrangement of the 18S and 25S ribosomal sequences. On the basis of the microscopic distance between these hybridization spots the size of the ribosomal unit was estimated at 8.2 kb. This implies a drastic improvement of high-resolution physical mapping of DNA sequences by FISH on plant DNA.     

Tolmiea diplomenziesii: A new species from the Pacific Northwest and the diploid sister taxon of the autotetraploid T. menziesii (Saxifragaceae)

Tolmiea diplomenziesii, the diploid entity traditionally treated within a broadly circumscribed Tolmiea menziesii, is here formally described. Evidence is provided that this new species represents the diploid sister lineage to T., menziesii, which is re-circumscribed to include only autotetraploid plants. The diploid and autotetraploid entities are compared, and serve as an example of the level of taxonomic evidence for specific status that we consider appropriate for recognition of a cytological entity as a distinct species.     

Origin of triploid Arachis pintoi (Leguminosae) by autopolyploidy evidenced by FISH and meiotic behaviour

Background and Aims

Polyploidy is a dominant feature of flowering-plant genomes, including those of many important crop species. Arachis is a largely diploid genus with just four polyploid species. Two of them are economically important: the cultivated peanut and A. glabrata, a tropical forage crop. Even though it is usually accepted that polyploids within papilionoid legumes have arisen via hybridization and further chromosome doubling, it has been recently suggested that peanut arose through bilateral sexual polyploidization. In this paper, the polyploid nature of the recent, spontaneously originated triploid cytotype of the tropical lucerne, A. pintoi, was analysed, and thereby the mechanism by which polyploids may arise in the genus.

Methods

Chromosome morphology of 2x and 3x A. pintoi was determined by the Feulgeńs technique and the rDNA sites were mapped by FISH. To investigate whether polyploidization occurred by means of unreduced gametes, a detailed analysis of the microsporogenesis and pollen grains was made.

Key Results

The 2x and 3x plants presented 9m + 1sm and a satellited chromosome type 2 in each haploid genome. Physical mapping revealed a cluster of 18S–26S rDNA, proximally located on chromosome 6, and two 5S rDNA loci on chromosomes 3 and 5. Diploid plants presented 10II in meiosis while trivalents were observed in all triploids, with a maximum of 10III by cell. Diploid A. pintoi produced normal tetrads, but also triads, dyads and monads. Two types of pollen grains were detected: (1) normal-sized with a prolate shape and (2) large ones with a tetrahedral morphology.

Conclusions

Karyotype and meiotic analysis demonstrate that the 3x clone of A. pintoi arose by autopolyploidy. The occurrence of unreduced gametes strongly supports unilateral sexual polyploidization as the most probable mechanism that could have led to the origin of the triploid cytotype. This mechanism of polyploidization would probably be one of the most important mechanisms involved in the origin of economically important species of Arachis, either by triploid bridge or bilateral sexual polyploidization.     

Trends in site-number change of rDNA loci during polyploid evolution in Sanguisorba (Rosaceae)

To elucidate the evolutionary dynamics of rDNA site number in polyploid plants, we determined 5S and 18S-5.8S-26S rDNA sites for ten species of Sanguisorba (2n=14, 28, 56) and a single species of each of three outgroup genera, Agrimonia (2n=28), Rosa (2n=14), and Rubus (2n=14) by the fluorescence in situ hybridization (FISH) method. We also estimated phylogenetic relationships among these species using matK chloroplast DNA (cpDNA) sequences, and reconstructed the evolutionary history of rDNA site number based on the maximum parsimony method. The 2n=14 and 2n=28 plants of all genera except Rosa carried two 5S rDNA sites, whereas Rosa and 2n=56 plants carried four sites. The 2n=14 plants had two 18S-5.8S-26S rDNA sites, whereas Sanguisorba annua and 2n=28 plants had four or six sites. Phylogenetic analysis showed that polyploidization from 2n=14 to 2n=28 has occurred once or three times in Sanguisorba and Agrimonia. The 5S rDNA sites duplicated during each ancestral polyploidization were evidently lost after each polyploidization. However, the duplicated 18S-5.8S-26S rDNA sites were all conserved after each polyploidization. Thus, the duplicated 5S rDNA sites tend to have been eliminated, whereas those of 18S-5.8S-26S rDNA tend to have been conserved in Sanguisorba. In the most parsimonious hypothesis, 2n=14 in S. annua is a secondary, putatively dysploid state, reduced from 2n=28.