Evaluation of the effect of pollen irradiation on karyotype variability in M2 cotton plants

The karyotypes of biomorphologically abnormal cotton (Gossypium hirsutum L.) plants obtained in M2 after pollination with pollen irradiated at dose rates 10, 15, 20, and 25 Gy were studied. Various genomic and chromosomal mutations were detected in 57 M2 families. The primary monosomics isolated in M2 were found to be cytologically more stable and more viable, since they had higher meiotic indices, pollen fertility, and seed formation. In M2, a decrease in the number of plants with multiple karyotype aberrations and interchromosomal exchanges with high frequency of multivalent formation was observed. The multivalents had diverse patterns and types of chromosome segregation and translocation complexes. Their pollen fertility was higher than in translocants found in M1. Desynapsis often occurred in M2, including plants with chromosome deficiency or rearrangements. The variation in the number of univalents in various cells was found to result from different expression of synaptic genes. The results indicate stabilization of karyotypes, increase in cytologic stability and viability, and the absence of sterility in aberrant plants.     

Evaluation of the Effect of Pollen Irradiation on Karyotype Variability in M1 Cotton Plants

The effect of pollen irradiation at dose rates of 10, 15, 20, and 25 Gy on variability in cotton plants Gossypium hirsutum L. was studied. The modified plants showed a reduced fertility, mainly caused by chromosomal rearrangements and genomic mutations during meiosis. The genomic mutations involved primary and tertiary monosomics, monotelodisomics, and a haploid plant. The decrease in meiotic index and pollen fertility in the cotton aneuploids was related not only to aberrations in chromosome pairing but also to genetic features of the original plants. It was found that heterozygosity for interchromosomal exchanges found in M₁ plants resulted in the formation of multivalent associations of chromosomes of various forms and types of segregation from translocation complexes. Another result was high variability in pollen fertility. An increase in irradiation dose rate caused an increase in the number of translocants with a high frequency of quadrivalents. The results suggest that the great diversity of forms observed in M₁ after pollination with irradiated pollen is determined, first, by elimination of some chromosomes or their arms or the whole paternal genotype and second, by interchromosomal rearrangements. The high variability in pollen fertility of translocants hampers using this trait as a marker of heterozygosity for exchanges in cotton.     

Effects of seed-irradiation on meiosis in M1 plants of Lactuca and related plants

Meiosis was studied in control and seed-irradiated materials of Lactuca sativa, cultivars Tom, Cos and Webbs, L. serriola from the wild, and Cichorium intybus. In meiosis of the M₁ plants from irradiated seed, observations of univalent and multivalent formation, bridge formation at Anaphase I and II, micronucleus formation and persistence, and pollen fertility, were carried out, and compared with controls. Quantitative estimations of bridge formation were made in L. sativa Tom and Cos and in L. serriola, at anaphase I only. It was found that the frequency of anaphase I bridges and reduction of pollen fertility in the M₁ and also M₂ generation, were different for each variety or species; these could be sequenced radiation-resistant to sensitive in the order Tom, Cos and L. serriola.     

Estimation of efficiency of seed irradiation by thermal neutrons for inducing chromosomal aberration in M<Subscript>2</Subscript> of cotton <Emphasis Type="Italic">Gossypium hirsutum</Emphasis> L.

Cytogenetic analysis of M₂ plants after irradiation of cotton by thermal neutrons was performed in 56 families. In 40 plants of 27 M₂ families, different abnormalities of chromosome pairing were found. These abnormalities were caused by primary monosomy, chromosomal interchange, and desynapsis. The presence of chromosome aberrations in some cases decreased meiotic index and pollen fertility. Comparison of the results of cytogenetics analysis, performed in M₁ and M₂ after irradiation, showed a nearly twofold decrease in the number of plants with chromosomal aberrations in M₂, as well as narrowing of the spectrum of these aberrations. The latter result is explained by the fact that some mutations are impossible to detect in subsequent generations because of complete or partial sterility of aberrant M₁ plants. It was established that the most efficient radiation doses for inducing chromosomal aberrations in the present study were 15 and 25 Gy, since they affected survival and fertility of altered plant to a lesser extent.     

Cytogenetics of a new type of barley with 16 chromosomes

In the progeny of a trisomic type for chromosome 6, Purple, a 16-chromosome type was obtained, which had a pair of new metacentric chromosome 6 in excess. The new metacentric chromosome 6 was shorter than any of the 14 chromosomes of normal barley complement and showed a heteropycnotic nature at late prophase in somatic mitosis. At metaphase I in the plants with 14+one metacentric chromosome 6 (2n=15) the chromosome configuration was exclusively 7_II+1_I indicating that the extra metacentric chromosome 6 could not associate with the normal chromosome 6. At diakinesis and metaphase I in the new 16-chromosome plants most of the sporocytes showed 8_IIor 7_II+2_I. Neither tetravalents nor trivalents were observed at meiosis. The chromosome behaviour at anaphase I and later stages of meiosis was regular in general, resulted in a fairly high pollen fertility of about 61 per cent. Seed fertility however, was very low. The transmission rate of the new metacentric chromosome 6 through the pollen was extremely low in 16-chromosome plants. Possible origin of new basic number and B-chromosome in diploid level through trisomic condition was suggested (Summary see p. 138).Contribution No. 141 of the Department of Plant Science, University of Manitoba.     

Estimation of the efficiency of seed irradiation by thermal neutrons for inducing chromosomal aberrations in M<Subscript>1</Subscript> of cotton <Emphasis Type="Italic">Gossypium hirsutum</Emphasis> L.

Exposure of cotton seeds to thermal neutrons at doses of 15, 25, and 35 Gy was shown to induce many biomorphologically abnormal plants, including sterile and chimeric ones. Most of these phenotypic changes were shown to result from novel genomic, chromosomal, and desynaptic mutations. The presence of these mutations in the karyotype of M₁ plants often decreased meiotic index and pollen fertility. In translocation forms, the decrease in pollen fertility was caused by the prevalence of quadrivalents in form of rings and chains with adjacent segregation of chromosomes from the translocation complexes. Based on the shapes and sizes of multivalent associations, we performed preliminary localization of translocation breakpoints. A specific feature of the effect of thermal neuron irradiation in M₁ was induction of numerous unique chromosomal aberrations, consisting in the appearance in the same plant of several types of mutations (genomic and chromosomal), interchange complexes in the same nucleus, and multiple interchanges involving three nonhomologous chromosomes.     

Introduction of a gene from fertility restored radish (Raphanus sativus) into Brassica napus by fusion of X-irradiated protoplasts from a radish restorer line and iodacetoamide-treated protoplasts from a cytoplasmic male-sterile cybrid of B. napus

To establish a cytoplasmic male-sterile/restored fertility (cms-Rf) system for F₁ seed production in Brassica napus, we transferred a gene from fertillity restored radish to B. napus by protoplast fusion. X-irradiated protoplasts, isolated from shoots of Raphanus sativus cv Kosena (Rf line), were fused with iodoacetamide-treated protoplasts of a B. napus cms cybrid. Among 300 regenerated plants, six were male-fertile. The fertile plants were characterized for petal color, chromosome number and the percentage of viable pollen grains. Three fertile plants had aneuploid chromosome numbers and white or cream petals, which is a dominant marker in radish. Of these three plants, one which had 2n = 47 chromosomes and white petals was used for further backcrosses. After two backcrosses, chromosome number and petal color became identical to that of B. napus. No female sterility was observed in the BC₃ generations.     

STERILITY BARRIERS OF SOME ARTIFICIAL F1 ORCHID HYBRIDS: MALE STERILITY. I. MICROSPOROGENESIS AND POLLEN GERMINATION

Microsporogenesis, pollen germination and fertility of males gametes were studied in 24 artificial intergeneric and interspecific F₁ hybrids of orchids. Although parental species had the same chromosome number (2n = 40), microsporogenesis of the hybrids was irregular due to the lack of homology of the chromosomes of the parental species. This led to formation of tetrads of microspores without micronuclei, tetrads with 1–8 micronuclei, triads, dyads with and without micronuclei, and monads. Chromosomes numbers found in haploid microsporocytes ranged from 7 to 40; in micronuclei the chromosome number varied between 1 and 5. In terms of pollen germination, three situations were observed: 1) hybrids whose pollen grains did not germinate in the stigma; 2) hybrids in which the pollen tubes grew down in the style, but did not penetrate into the ovary; 3) hybrids in which the pollen tubes grew down normally through the ovary, reaching the ovules. When the pollen tubes did not penetrate the ovary no fruit was formed. Therefore germination tests carried out in vitro may not indicate pollen fertility, because pollen tube growth in the style of the flower may be insufficient to induce fruit formation or to accomplish fertilization.     

Occurrence of aneuploid progenies from an asynaptic amphidiploid ofScilla scilloides (lindley) druce II. Mechanism of production of the various aneuploid progenies

The mechanism of production of the various aneuploid progenies was clarified in the asynaptic amphidiploid plants (2n=34+4f+2F, AABB) ofScilla scilloides. Its asynaptic nature and chromosomal stickiness lead to the unequal segregation at anaphase I (AI) in PMC's. The observed values in 18 segregation patterns, 17:17 to 0: 34, were different from the expected values estimated from random segregation of chromosomes. Nevertheless, the preferential transmission of special chromosomes among genomes A (x=8=a₁−a₈) and B (x=9=b₁−b₉) had not occurred. As the result of unequal segregation, the pollen grains with various chromosome numbers were observed. Almost all of the 200 pollen grains contained chromosome numbers more than 17 (range 8 to 34). The observed values of each chromosome number were roughly similar to the expected values of containing the complete set of genome A or B in the random distribution without preferential segregation of chromosomes at AI. The difference between the index of polien mitosis and the pollen fertility was significant in the Wilcoxon matched-pairs signed rank test and suggested the selection for some genomically unbalanced pollen grains during maturation. Consequently, viable pollen grains with various chromosome constitutions are a few (mean pollen fertility of 5.8%) but might produce many aneuploids by self- and cross-pollination.     

Investigations into causes of sterility IV. Gametocide-induced male-sterilePhaseolus aureus Roxb.

Phaseolus aureus Roxn, cultivar T₅₁ was treated with aqueous foliar sprays of 0.01, 0.025% and 0.05% 2,2-dichloropropionic acid (DPA) just before the initiation of floral buds when the plants were 25 days old. Flower buds were fixed 10 days after treatment. The plants in the two latter treatments were 100% pollen sterile. Meiosis in these treatments was characterized by multivalent associations at diakinesis and metaphase I. These associations were found to be due to stickiness, produced by agglutination of chromatin. Both the divisions of meiosis were characterized by sticky chromosome bridges and laggards, resulting in the formation of micronuclei and consequently polysporads. Histology of anthers revealed a vagary in the behaviour of the tapetum.     

Colchicine induced polyploidy in chickpeas (Cicer arietinum L.)

Summary The most successful induction of tetraploidy was obtained with 2 hour treatment by 0.25% aqueous colchicine solution of 18-hour watersoaked desi chickpeas material. However, kabuli types needed only 1 hour treatment under similar conditions. Gigantism accompanied induction of polyploidy in desi as well as kabuli types but yield and fertility were greatly reduced. The meiotic abnormalities accompanying polyploidy were multivalent association of chromosomes followed by unequal disjunction, chromosome bridges, laggards etc. The percentage of stainable pollen, however, was at par between diploids and tetraploids. Gene control of percentage seed setting was observed in both levels of ploidy. A striking feature of the studies was the high seed setting percentage in 4n F ₁ material resulting from diverse crosses, viz., desi×kabuli. A probable reduction in multivalent association coupled with yield increases in segregants from the later generation of tetraploids indicates the possibility of selection for higher yield and fertility from polyploids, particularly from some hybrid material.     

Evaluation of the effect of pollen irradiation on karyotype variability in cotton plants

The effect of pollen irradiation at dose rates of 10, 15, 20, and 25 Gy on variability in cotton plants Gossypium hirsutum L. was studied. The modified plants showed a reduced fertility, mainly caused by chromosomal rearragements and genomic mutations during meiosis. The genomic mutations involved primary and tertiary monosomics, monotelodisomics, and a haploid plant. The decrease in meiotic index and pollen fertility in the cotton aneuploids was related not only to aberrations in chromosome pairing but also to genetic features of the original plants. It was found that heterozygosity for interchromosomal exchanges found in M1 plants resulted in the formation of multivalent associations of chromosomes of various forms and types of segregation from translocation complexes. Another result was high variability in pollen fertility. An increase in irradiation dose rate caused an increase in the number of translocants with a high frequency of quadrivalents. The results suggest that the great diversity of forms observed in M1 after pollination with irradiated pollen is determined, first, by elimination of some chromosomes or their arms or the whole paternal genotype and second, by interchromosomal rearrangements. The high variability in pollen fertility of translocants hampers using this trait as a marker of heterozygosity for exchanges in cotton.     

CYTOLOGICAL STUDIES OF NONTRUE–BREEDING MUTANTS IN SORGHUM OBTAINED AFTER COLCHICINE TREATMENT

Sanders , Mary E., and Clifford J. Franzke . (South Dakota State Coll.. Brookings.) Cytological studies of nontrue-breeding mutants in sorghum obtained after colchicine treatment. Amer. Jour. Bot. 49(9): 990–996. Illus. 1962.—Although pollen mother cells of nontrue-breeding mutant plants obtained after colchicine treatment of sorghum seedlings, line ‘Experimental 3,’ showed normal chromosome behavior (10 bivalents) at phases of meiosis I, some abnormalities were found at corresponding stages in first- and second-generation self-progeny plants of some of them. The most frequent chromosome irregularities were an increase over ‘Experimental 3’ in number of cells containing univalents, and mixoploid tissues with tetraploid and diploid cells. The higher polyploid groups (6n, 8n, 10n) also present in 2 plants might be related to their male-sterile condition rather than being an indication of the chromosome complement. Abnormalities in progenies suggest that some of the mutants might have been chimeras in which abnormalities were missed and raise the question whether chromosome changes are involved in the formation of the mutants in spite of the preponderance of normal diploid cells with 10 bivalents during prophase and metaphase of meiosis I. This could occur if sorghum contains a genetic mechanism which promotes bivalent rather than multivalent pairing. That such might be a possibility is indicated by the large numbers of bivalents and small numbers of multivalents found in polyploid cells or groups.     

Production of somatic hybrids between Brassica oleracea and the C3–C4 intermediate species Moricandia nitens

Protoplast fusion between Brassica oleracea and Moricandia nitens, a C₃–C₄ intermediate wild species, was carried out. Four hundred and twenty five plants were regenerated from 1995 calli. More than 90% of the regenerated plants were verified as true intergeneric hybrids on the basis of morphological observation and molecular-marker analysis. The hybrids were morphologically intermediate between both fusion parents. Variations in flower color and petal number were also observed. The chromosome number and pollen fertility varied across the individual hybrids. Although after self-pollination pollen germinated on the stigma and pollen tubes were visible in the style, the pods did not develop properly without in vitro culture. Measurements of the CO₂ compensation point revealed that six out of eight hybrid plants expressed a gas-exchange character that was intermediate between the C₃–C₄ M. nitens and C₃ B. oleracea parents. Received: 20 January 1999 / Accepted: 16 June 1999     

Fertile progeny of a hybridization between soybean [Glycine max (L.) Merr.] and G. tomentella Hayata

Summary A colchicine-doubled F₁ hybrid (2n=118) of a cross between PI 360841 (Glycine max) (2n=40) x PI 378708 (G. tomentella) (2n=78), propagated by shoot cuttings since January 1984, produced approximately 100 F₂ seed during October 1988. One-fourth of the F₂ plants or their F₃ progeny have been analyzed for chromosome number, pollen viability, pubescence tip morphology, seed coat color, and isoenzyme variation. Without exception, all plants evaluated possessed the chromosome number of the G. max parent (2n=40). Most F₂ plants demonstrated a high level of fertility, although 2 of 24 plants had low pollen viability and had large numbers of fleshy pods. One F₂ plant possessed sharp pubescence tip morphology, whereas all others were blunt-tipped. All evaluated F₂ and F₃ plants expressed the malate dehydrogenase and diaphorase isoenzyme patterns of the G. max parent and the endopeptidase isoenzyme pattern of the G. tomentella parent. Mobility variants were observed among progeny for the isoenzymes phosphoglucomutase, aconitase, and phosphoglucoisomerase. This study suggests that the G. Tomentella chromosome complement has been eliminated after genetic exchange and/or modification has taken place between the genomes.Journal Paper No. J-13776 of the Iowa Agriculture and Home Economics Experiment Station, Ames, IA, USA, Project 2763     

Tissue culture in Haworthia

Summary Plants regenerated on two different media (NK and I) from the calluses of simple or cloned subcultures, which were originated from a single stock callus of Haworthia setata derived from its flower bud, were observed for eight characters, i.e., somatic chromosome number in root tips, growth vigor, leaf shape, leaf color, number of stomata per unit leaf area, esterase zymogram, chromosome association at meiotic metaphase I in pollen mother cells, and pollen fertility. From these regenerates plants with different characters from those of the parental plant were obtained. With regards to chromosomal aberrations, tetraploids, aneuploids, plants with a part of the chromosome segment deleted, with reciprocal and non-reciprocal translocations, or with paracentric inversions and those showing sub-chromatid aberrations at meiosis were obtained. The NK medium tended to regenerate more tetraploids and less plants carrying translocation than the I medium.Chromosome variabilities in somatic cells of the regenerates correlated with those of the calluses, from which they regenerated, while they did not correlate with either the meiotic irregularities (chromosome association at MI) or pollen fertility of the regenerates. From these facts, it was concluded that a rather large number of callus cells participate in the regeneration of an individual plant, although, however, only a few limited types of the cells form its germ line.Polyploidy affected growth vigor, leaf shape, stomata number and chromosome association at MI, but its effects were not detected on other characters. Chromosomal aberrations at the diploid level produced no clear changes in the regenerate's phenotype except in meiotic chromosome configuration and pollen fertility.Most chromosomal variants obtained in the present study are already reported in plants collected from wild populations, but plants with the deletion of a whole chromosome (karyotype 7L+6S) or chromosome segment (7L+1M+6S and 14L+2M+12S) have never been reported: this fact suggests that tissue culture is a powerful tool for producing plants with novel karyotypes.Contribution from the Laboratory of Genetics, Faculty of Agriculture, Kyoto University, Japan, No. 436     

Molecular cytogenetic study on the plants of Elymus nutans with varying fertility on the Qinghai-Tibet Plateau

A molecular cytogenetic investigation was conducted on plants of the allohexaploid species Elymus nutans with varying fertility on the Qinghai-Tibet Plateau. Molecular karyotyping revealed that chromosome variants were distributed unevenly among genomes and among different homologue chromosomes in each genome. The plants with varying fertility exhibited significantly higher numbers of chromosome variants than did the normal fertility samples, although both kinds of plants showed the same pattern of high-to-low polymorphism from the Y to St and H genomes. Heterozygosis and karyotype heterozygosity in the plants with varying fertility were 3- and 13-fold higher than those in normal samples, respectively. Significant negative correlations were found not only between seed setting rates and total genome heterozygosity but also between seed setting rates and heterozygosity of each genome in the plants of varying fertility. Chromosome pairing analysis was performed using genomic in situ hybridization in selected plants of different fertility levels. The pairing of chromosomes at meiotic metaphase I was mostly bivalent, although univalent, trivalent, quadrivalent, and other polyvalents also occurred; in addition, chromosome configuration forms and frequencies varied among the studied samples. ANOVA results showed that the average number of ring bivalents in the Y genome was significantly higher than those in the St and H genomes. Significant positive correlations between pollen grain fertility and ring bivalent number were found in the St and H genomes but not in the Y genome. Furthermore, chromosome configuration parameters (total bivalents, numbers of ring and rod bivalents) were found to be significantly correlated with heterozygosity and seed setting rates in the St and H genomes, respectively, but not in the Y genome. It was inferred that the seed setting rate and pollen grain fertility in E. nutans are strongly influenced by the heterozygosity of each genome, but the Y genome differs from the St and H genomes due to chromosome pair alterations. The St and H genomes may contain more chromosome structural variations than the Y genome in E. nutans.     

TRISOMICS IN SOLANUM CHACOENSE: FERTILITY AND CYTOLOGY

Twenty trisomic plants found in the progeny 3x x 2x crosses in Solatium chacoense and their F₁ trisomies obtained by 2x + 1 X 2x crosses were studied with respect to their fertility and cytology. The female transmission of the extra chromosome in the trisomics varied from 2 to 60 %. The transmission frequencies of F₁ trisomies were similar to their parent trisomies in most of the lines. The transmission through the pollen ranged from 0 to 20 %. Female and male fertility of the parent trisomies was high. They produced an average of 37 seeds per pollination as the female or as the male parent. The F₁ trisomies produced about half the seed set of their parent trisomies. The extra chromosomes of six trisomies were identified by pachytene analysis. They were isochromosomes for the long arms of chromosomes I, IV and IX and the short arms of IV, IX and XII. Chromosome morphology of the extra chromosomes in pachytene stage was described. A chromosome association of 12 II + 1 I was found in 66 % of the cells at MI. About 29 % of the cells had one trivalent and 5 % had three or five univalents. The frequency of trivalent formation was not affected by the length of the extra chromosome. The possibility of univalent shift in secondary trisomies was discussed.     

Cytological analysis of tetraploid hybrids between sweet potato and diploid Ipomoea trifida (H. B. K.) Don.

Summary Tetraploid F₁ hybrids between Ipomoea batatas, sweet potato (2n = 6x = ca. 90), and diploid (2n = 2x = 30) I. trifida (H. B. K.) Don. showed various degrees of fertility reduction. The present study aimed to clarify its causes by cytological analysis of meiotic chromosome behavior in the diploid and sweet potato parents and their tetraploid hybrids. The diploid parents showed exclusively 15 bivalents, and the sweet potato parents exhibited almost perfect chromosome pairing along with predominant multivalent formation. Their hybrids (2n = 4x= 57–63) formed 2.6–5.0 quadrivalents per cell, supporting the autotetraploid nature. The meiotic aberratios of the hybrids were characterized by the formation of univalents, micronuclei, and abnormal sporads (monad, dyad, triad, and polyad). The causes underlying these aberrations were attributed in part to the multivalent formation, and in part to a disturbance in the spindle function. Three hybrids showing serious meiotic aberrations were very low in fertility. The utilization of the sweet potato-diploid I. trifida hybrids for sweet potato improvement is described and, further, the role of interploidy hybridization in the study of the sweet potato evolution is discussed.     

ANEUPLOIDY IN CLAYTONIA VIRGINICA

Rothwell , Norman V. (Long Island U., Brooklyn, N. Y.) Aneuploidy in Claytonia virginica. Amer. Jour. Bot. 46(5): 353–360. Illus. 1959.—Within the taxon, Claytonia virginica L., an extensive aneuploid series has been found including the following chromosome numbers: 2n = 12, 14, 16, 17, 18, 19, 20, 22, 24, 26, 28, 30, 32, 34, 36, 48, and 72. Studies revealed that a population could be composed of individuals differing in chromosome number. Pollen fertility appears to be high in natural populations and in plants showing meiotic irregularities. Different karyotypes were found within the taxon; plants having the same chromosome number may have different karyotypes. Hybrids have been obtained as the result of crossing plants differing both in number and karyotype. From all the evidence, C. virginica appears to be able to tolerate transitions from one cytological type to another. The hypothesis is proposed that most of the various numbers have been derived from a haploid complement of 8 chromosomes possessing median centromeres. The following factors are suggested to account for the origin of the different numbers: nondisjunction, univalent lagging, misdivision of univalents, polyploidy, and fertile triploids.