Genetic regulation of the centromere division in rye and wheat univalent chromosomes in dimonosomics during meiotic anaphase I

Cytogenetic analysis of meiosis in the wheat--rye dimonosomics 1Rv-1A, 1Ron-1A, 2R-2D, 5R-5A, and 6R-6A was conducted. C-banding was used to study the segregation pattern of each of two univalent chromosomes during the first meiotic division. It has been shown that the division frequency of the centromeric regions of all rye chromosomes in the pair studied is significantly higher than in the wheat chromosomes. The ANOVA performed suggest that the plant genotype contributes significantly (at P = 0.05) to the behavior pattern of univalent chromosomes in meiosis. The data obtained demonstrate that the rye and wheat chromosomes studied are involved in genetic regulation of centromere division in meiotic anaphase I (AI). The presence of rye chromosome 2R and wheat chromosome 2D suppresses the division of centromeres of the sister chromatids in AI. Rye chromosomes 1Rv, 1Ron, 5R, and 6R induce equational division; however, rye chromosome 1Rv increases to a greater degree the frequency of equational division of wheat chromosome 1A as compared with chromosome 1Ron.     

The effect of wheat-rye substitution on chromosome elimination: An analysis of univalents’ behavior in wheat meiosis with dimonosomy and tetramonosomy

The effect of wheat-rye chromosome 1Rv/1A, 2R/2D and 6R/6A substitutions characterized by differences in the expression of the equational division of sister centromeres in anaphase I on segregation and the elimination of wheat and rye univalents was investigated. To determine the individual effect of each of the studied chromosomal pairs, a comparative analysis of the univalent behavior in the meiosis of dimonosomic 1Rv-1A, 2R-2D, 6R-6A and tetramonosomics 1Rv-2R-1A-2D, 1Rv-6R-1A-6A, 2R-6R-2D-6A was conducted. 2R/2D substitution was experimentally demonstrated to suppress an equational univalents division, while 6R/6A substitution resulted in high frequency chromosomes’ elimination, especially in the meiosis of 2R-6R-2D-6A tetramonosomics. Other meiotic mechanisms, together with the sister chromatids separation at anaphase I, may affect the elimination of the final products of univalent segregation. It was demonstrated that the number and pattern of univalent chromosomal behavior affected hybrid plant fertility.     

Chromosome pairing in meiosis of partially fertile wheat/rye hybrids

The normal course of meiosis depends on regular pairing of homologous chromosomes. In intergeneric hybrids, including those of wheat, there is no chromosome pairing because there are no homologs. In F₁ wheat/rye hybrids, pairing is largely prevented by the pairing homoeologous1 (Ph1) gene. In its presence, there are only rare instances of pairing; most chromosomes are univalent, and their orientation at metaphase I initiates different pathways of the meiotic cycle. The meiotic-like pathway includes a combination of the reductional and the equational + reductional steps at AI followed by the second division. The resulting gametes are mostly non-functional. The mitotic-like pathway involves equational division of univalents at AI and the absence of the second division. Any fertility of wheat/rye hybrids depends on the production of unreduced gametes arising from meiotic restitution (mitotic-like division). We examined the meiotic pairing in wheat/rye hybrids created from wheat lines with single rye chromosome substitutions and Ph1 present. This guaranteed F₁ meiosis with one pair of rye homologs. All hybrids formed bivalents, but proportions of meiocytes with bivalents varied. In the meiocytes where bivalents were present, there was a higher tendency for the meiotic-like pathway, while in meiocytes where bivalent pairing failed, the tendency was stronger for the mitotic-like pathway. Among the equationally dividing cells, we observed more than 90 % of meiocytes without bivalents, where rye homologs did not form bivalents, too. The data indicate a potential application of wheat/rye lines in producing genetic stocks of amphidiploids with designated genomic constitutions.     

Role of rye chromosome 2R from wheat-rye substitution line 2R(2D)1 (Triticum aestivum L. cv. Saratovskaya 29-Secale cereale L. cv. Onokhoiskaya) in genetic regulation of meiotic restitution in wheat-rye polyhaploids

A study was made of the role of rye chromosome 2R from the wheat-rye substitution line 2R(2D)1 (Triticum aestivum L. cv. Saratovskaya 29-Secale cereale L. cv. Onokhoiskaya) in genetic regulation of meiotic restitution in wheat-rye polyhaploids 2R(2D)1 x S. cereale L. cv. Onokhoiskaya. Rye chromosome 2R proved to affect the completeness of the meiotic program, suppressing the formation of restitution gametes. This was evident from the reductional division of univalent chromosomes in AI and the occurrence of the second meiotic division. The interrelationships between the type of chromosome division in AI and the two-step character of meiosis are discussed. The structural and functional organization of the centromeric regions of chromosomes undergoing reductional division is assumed to determine the two-step character of division.     

Role of rye chromosome 2R from wheat-rye substitution line 2R(2D)1 ( Triticum aestivum L. cv. Saratovskaya 29- Secale cereale L. cv. Onokhoiskaya) in genetic regulation of meiotic restitution in wheat-rye polyhaploids

A study was made of the role of rye chromosome 2R from the wheat-rye substitution line 2R(2D)₁ (Triticum aestivum L. cv. Saratovskaya 29-Secale cereale L. cv. Onokhoiskaya) in genetic regulation of meiotic restitution in wheat-rye polyhaploids 2R(2D)₁ × S. cereale L. cv. Onokhoiskaya. Rye chromosome 2R proved to affect the completeness of the meiotic program, suppressing the formation of restitution gametes. This was evident from the reductional division of univalent chromosomes in AI and the occurrence of the second meiotic division. The interrelationships between the type of chromosome division in AI and the two-step character of meiosis are discussed. The structural and functional organization of the centromeric regions of chromosomes undergoing reductional division is assumed to determine the two-step character of division. Original Russian Text ? O.G. Silkova, A.I. Shchapova, V.K. Shumny, 2007, published in Genetika, 2007, Vol. 43, No. 7, pp. 971–981.     

Mitotic behavior of centromeres in meiosis as the fertility restoration mechanism in wheat-rye amphihaploids

The regulation of chromosomal behavior in meiosis in partly fertile wheat-rye amphihaploids was studied using the centromere specific probes pAWRC1 and Ae. tauschii pAet6-09. Comparative analysis of the probe localization patterns in mitosis, normal meiosis in wheat Triticum aestivum L. and rye Secale cereale L., and meiosis in amphihaploids was performed. The differences in the structure of centromeres in monopolar- and bipolaroriented chromosomes were revealed. Single dense hybridization signals were observed in the diplotene and the metaphase of the first meiotic division, while hybridization signals appeared as stretched bands with diffuse structure located across the centromere region in mitosis and the second round of meiotic division. Based upon the obtained data, we used the corresponding centromere-specific probes as a tool for the analysis of chromosomal behavior in meiosis in amphihaploids. In meiocytes with three types of chromosome behavior (reductional, equational plus reductional, and equational), dense point-like hybridization signals for the pAet6-09 probe were observed for univalents with the reductional division type and stretched bands with diffuse structure for those with the equational division type. Thus, pAet6-09 probe localization patterns suggest some structural and functional specificities of centromeres in the meiosis in wheat-rye amphihaploids that reflect special regulation of chromosomal behavior during equational division. Meiocytes with true mitotic division were also observed in anthers predominantly containing meiocytes with chromosomes undergoing equational division.     

Features of the regulation of meiotic restitution in androgenic haploids of wheat-rye substitution lines 2R(2D)1, 2R(2D)3, and 6R(6A) (Triticum aestivum L., cultivar Saratovskaya 29/Secale cereale L., cultivar Onokhoiskaya)

Regulation of meiotic restitution in androgenic haploids generated by cultivation of isolated anthers of three wheat-rye substitution lines 2R(2D)₁, 2R(2D)₃, and 6R(6A) (Triticum aestivum L., cultivar Saratovskaya 29/Secale cereale L., cultivar Onokhoiskaya) was studied. The presence of rye chromosomes and the absence of homeologous wheat chromosomes in the haploid plant genome was shown to cause meiotic restitution, as observed in the case of androgenic haploids 6R(6A), or to inhibit it—in meiosis of haploids 2R(2D)₁ and 2R(2D)₃. In haploids of lines 2R(2D)₁ and 2R(2D)₃, the reductional type of division of univalent chromosomes was observed, leading to preferential formation of tetrads. In haploids of line 6R(6A), the equational type of division of univalents into sister chromatids, resulting in the block of the second division and formation of diads in approximately 50% of cells, was detected. These results confirm data on the effect of the genotype of line 2R(2D)₁ on the induction of reductional type division of univalents and two-phase meiosis, which were earlier obtained in studies of meiosis in polyhaploids 2R(2D)₁ × S. cereale L., cultivar Onokhoiskaya.     

Wheat chromosome instability in the selfed progeny of the double monosomics 1Rv-1A

Structural alterations of chromosomes are often found in wheat-rye hybrids. In the majority of cases modifications are observed for rye chromosomes, yet chromosome aberration cases are described for wheat, including the progeny of Triticum aestivum disomic and monosomic addition lines. Since wheat-rye substitution and translocation lines are the source of rye chromatin in wheat breeding programs, the information on possible chromosome changes in the genomes of introgressive forms is important. Chromosome behavior in F₁ meiosis and chromosomal composition of F₂ karyotypes for double monosomics 1Rv-1A were studied by applying C-banding, genomic in situ hybridisation (GISH) using rye genomic DNA, and sequential in situ hybridization using repetitive sequences pAs1, pSc119.2 and centromere specific pAet-06 as probes. The double monosomics 1Rv-1A were obtained by crossing of disomic substitution line with chromosome 1A replaced by Secale cereale 1Rv in the bread wheat Saratovskaya 29 (S29) background with S29. The results indicated a high frequency of bipolar chromosome 1Rv orientation, as compared to 1A, at metaphase I (MI) (58.6 and 34.7 % of meiocytes, respectively), and, at anaphase I (AI), chromatid segregation of 1Rv compared to 1A (70.53 and 32.14 % of meiocytes, respectively). In few cases desynapsis of wheat homologues was observed, at AI, the chromosomes randomly distributed between the poles or underwent chromatid segregation. At AI, the two wheat homologues separated onto sister chromatids in 10.89 % of cells.The plants F2 karyotypes were marked with aneuploidy not only of chromosomes 1A and 1Rv, but also of 1D, 2D, 3D, 3B, 3A, 4A, 6D, 6B, 6A, and 7D. Structural changes were observed for the chromosomes of the first homoeologous group (1Rv, 1A, 1D, 1B), as well as for 2B, 5D, 6B, and 7B. The chromosomes 1Rv and 6B often demonstrated aberrations. The types of aberrations were centromeric break, deletions of various sizes, and a changed repeat pSc119.2 localization pattern.     

黑麦6R染色体在小麦背景中的减数分裂行为

减数分裂既是高等生物染色体变异的敏感期,又是变异得以顺利传递给子代的关键期。以黑麦６Ｒ染色体为例,观察其在小麦背景中的减数分裂行为,先是发现６Ｒ抑制小麦同源染色体正常配对,造成单价体数量的增加;同时注意到６Ｒ与其部分同源的小麦染色体６Ｄ几乎不能发生配对。其次是观察到单价体在减数分裂期容易产生断裂的现象,特别是首次发现单价体碎裂,对进一步深入研究异源染色体臂间易位和小片段易位的形成具有借鉴价值。     

利用杀配子染色体2C诱导中国春-黑麦二体附加系染色体畸变的研究

将中国春-黑麦(1R-7R)二体附加系与中国春-2C(Aegilops cylindrica)二体附加系杂交,获得F1,对F1体细胞染色体进行C分带鉴定和花粉母细胞减数分裂行为的观察与分析,发现减数分裂行为异常。对自交获得的430株F2进行单株染色体C分带和荧光原位分子杂交鉴定,检测到易位、缺失、等臂染色体、双着丝点染色体等染色体畸变类型。此外还检测到2C与小麦2A、2B、2D染色体的二体或单体自发代换系。杂交F。染色体畸变的规律与频率如下：研究共得到含黑麦染色体的变异22株,变异频率为5,1％。其中含黑麦染色体的易位系为10株,占2,3％;缺失12株,占2．79％;黑麦的等臂染色体3株,占O．7％。易位染色体既有含小麦着丝点的(大部分),也含有黑麦着丝点的(仅1例)。黑麦的染色体畸变中,发生于不同同祖群的频率不同,1R为5个,2R为3个;3R为1个;4R为3个;5R为6个;6R为4个。易位多为端部易位。共鉴定出小麦的缺失系54株,其中A基因组有27个,占6.27％;B基因组有20个,占4,65％;D基因组有7个,占1.66％。对杀配子染色体对小麦及黑麦不同同祖群染色体作用的差异性及作用特点进行了探讨。     

Wheat univalent orientation at anaphase I in wheat-rye derivatives

The anaphase I behaviour of wheat univalents in plants with the chromosome constitution (0–7)A(0–7)BRR was analyzed using the C-banding technique, which allows to distinguish between wheat and rye chromosomes. The equational division frequencies of univalents observed in the six plants analyzed show a large variation (0.21–0.83). Within each plant syntelic univalents segregate to the poles at random. The frequency distribution of amphitelically dividing univalents does not conform to a random distribution. The lack of fit is attributed to environmental factors which differentially affect the probability of equational division for the univalents in different PMCs. Two other possible causes of the lack of adjustment, namely, each wheat univalent has a different probability of equational division, and wheat univalents do not move independently to the equator to divide equationally, are also discussed. The latter seems improbable in view of the independent behaviour of univalents dividing reductionally. A correlation observed between the behaviour of chromosome 6B and the rest of wheat univalents is attributed to variation between cells due to external causes.     

小麦-黑麦代换系5A/5R与6A/6R杂交诱导同祖染色体配对与易位的研究

利用两个小麦-黑麦异源双代换系DS 5A/5R与DS 6A/6R杂交,探讨同祖染色体配对的可能性与创制小麦黑麦异源易位系.在方法上对杂种F1的减数分裂行为进行研究,观察5R与5A、6R与6A配对频率,探讨同祖染色体配对规律.实验结果看到杂交F1减数分裂中有22.91%的花粉母细胞有小麦染色体(ABD组)与黑麦染色体(R组)发生同祖配对.在F2及以后世代,通过染色体C分带、原位杂交检测,选择小麦-黑麦易位系.在F2代的45株中检测到9株有易位,易位频率为20%,是目前小麦-黑麦染色体易位频率最高的.染色体易位有的来源于同祖配对的交换,有的来源于单价体错分裂或断裂的重建.     

Meiotic pairing in hybrids between tetraploid Triticale and related species: new elements concerning the chromosome constitution of tetraploid Triticale

Summary Two F5 strains of tetraploid triticale (2n= 4x=28), obtained from 6x triticaleX2 rye progenies, were crossed with diploid and tetraploid rye, some durum and bread wheats, and various 8x and 6x triticale lines. Meiosis in the different hybrid combinations was studied. The results showed that the haploid complement of these triticales consists of seven chromosomes from rye and seven chromosomes from wheat. High frequencies of PMCs showing trivalents were observed in hybrids involving the reference genotypes of wheat and triticale. These findings proved that several chromosomes from the wheat component have chromosome segments coming from two parental wheat chromosomes. The origin of these heterogeneous chromosomes probably lies in homoeologous pairing occurring at meiosis in the 6x triticaleX2x rye hybrids from which 4x triticale lines were isolated. A comparison among different hybrids combinations indicated that the involvement of D-genome chromosomes in homoeologous pairing is quite limited. In contrast, meiotic patterns in 4x triticale X 2x rye hybrids showed a quite high pairing frequency between some R chromosomes and their A and B homoeologues.     

Mechanisms of Meiotic Restitution and Their Genetic Regulation in Wheat–Rye Polyhaploids

Meiosis has been studied in partially fertile wheat–rye F₁ hybrids yielded by crosses Triticum aestivum (Saratovskaya 29 variety) × Secale cereale L. (Onokhoiskaya variety) (4x =28). Hybrid self-fertility proved to be caused by formation of restituted nuclei, which appear after equational segregation of univalent chromosome in AI and sister chromatid non-separation in AII of meiosis, as well as after AI blockage in three different ways. Both types of meiotic restitution were found in each hybrid plant. Expression of the meiotic restitution trait varied significantly in polyhaploids of the same genotype (ears of the same plants, anthers of the same ear, microsporocytes of the same anther). Chromatin condensation in prophase proved to be related to the division type and univalent segregation in AI. During reduction segregation of univalents in AI, sister chromatid cohesion and chromosome supercondensation remained unchanged. The results obtained suggest that in the remote hybrids with haploid karyotype of the parental origin (polyhaploids), the program of two-stage meiosis may be fundamentally transformed to ensure one instead of two divisions. We propose that meiotic restitution is a result of special genetic regulation of the kinetochore organization (both structural and functional) and chromatin condensation, i.e. of major meiotic mechanisms.     

应用原位杂交技术对小麦—黑麦代换系间杂交的细胞遗传研究

应用原位杂交技术结合染色体组型分析方法,对两个小麦-黑麦异源双代换系5R/5A和6R/6A杂交后代的遗传进行了研究,探讨同祖染色体配对的可能性并获得小麦-黑麦易位系。实验中对杂种F1代植株减数分裂各时期的花粉母细胞染色体行为进行分析,结果发现有22.91%的花粉母细胞中黑麦染色体与小麦染色体发生同祖配对。F2代通过C-分带、原位杂交鉴定,在45株中检测到9株易位,易位频率为20%,是目前报道易位频率最高的。染色体易位有的来源于同祖配对交换,有的来源于单价体错分裂或断裂的重建。     

Identification and analysis of DYAD: a gene required for meiotic chromosome organisation and female meiotic progression in Arabidopsis

The dyad mutant of Arabidopsis was previously identified as being defective in female meiosis. We report here the analysis of the DYAD gene. In ovules and anthers DYAD RNA is detected specifically in female and male meiocytes respectively, in premeiotic interphase/meiotic prophase. Analysis of chromosome spreads in female meiocytes showed that in the mutant, chromosomes did not undergo synapsis and formed ten univalents instead of five bivalents. Unlike mutations in AtDMC1 and AtSPO11 which also affect bivalent formation as the univalent chromosomes segregate randomly, the dyad univalents formed an ordered metaphase plate and underwent an equational division. This suggests a requirement for DYAD for chromosome synapsis and centromere configuration in female meiosis. The dyad mutant showed increased and persistent expression of a meiosis-specific marker, pAtDMC1::GUS during female meiosis, indicative of defective meiotic progression. The sequence of the putative protein encoded by DYAD did not reveal strong similarity to other proteins. DYAD is therefore likely to encode a novel protein required for meiotic chromosome organisation and female meiotic progression.     

Mechanisms of meiotic restitution and their genetic regulation in wheat-rye polyhaploids

Meiosis has been studied in partially fertile wheat-rye F1 hybrids yielded by crosses Triticum aestivum (Saratovskaya 29 variety) x Secale cereale L. (Onokhoiskaya variety) (4x = 28). Hybrid self-fertility proved to be caused by formation of restituted nuclei, which appear after equational segregation of univalent chromosome in AI and sister chromatid non-separation in AII of meiosis, as well as after AI blockage in three different ways. Both types of meiotic restitution were found in each hybrid plant. Expression of the "meiotic restitution" trait varied significantly in polyhaploids of the same genotype (ears of the same plants, anthers of the same ear, microsporocytes of the same anther). Chromatin condensation in prophase proved to be related to the division type and univalent segregation in AI. During reduction segregation of univalents in AI, sister chromatid cohesion and chromosome supercondensation remained unchanged. The results obtained suggest that in the remote hybrids with haploid karyotype of the parental origin (polyhaploids), the program of two-stage meiosis may be fundamentally transformed to ensure one instead of two divisions. We propose that meiotic restitution is a result of special genetic regulation of the kinetochore organization (both structural and functional) and chromatin condensation, i.e. of major meiotic mechanisms.     

Chromosome pairing in wheat-rye ABDR hybrids depends on the microsporogenesis pattern

The character of chromosome pairing in meiocytes was studied in F1 wheat-rye Triticum aestivum L. x Secale cereale L. (ABDR, 4x = 28) hybrids with three types of chromosome behavior: reductional, equational, and equational + reductional. A high variation of the frequencies of bivalents and ring univalents was observed in meiocytes with the reductional or equational + reductional type of chromosome behavior. The type of chromosome division was found to affect the bivalent and ring univalent frequencies. Chromosome pairing occurred in 10.28% of meiocytes with the reductional chromosome behavior, 0.93% of meiocytes with the equational chromosome behavior, and 10.81% of meiocytes with the equational + reductional chromosome behavior. On average, 0.13 bivalents per cell formed in meiocytes of the hybrid population. C-banding and genomic in situ hybridization (GISH) showed that both rye and wheat chromosomes produced ring univalents. The role of the Ph genes in regulating the bivalent formation in meiocytes with different types of chromosome behavior is discussed.     

Genetic collection of meiotic mutants of rye Secale cereale L

Genetic collection of meiotic mutants of winter rye Secale cereale L. (2n = 14) was created. Mutations were detected in inbred F2 generations after self-fertilization of the F1 hybrids, obtained by individual crossing of rye plants (cultivar Vyatka) or weedy rye with plants from autofertile lines. The mutations cause partial or complete plant sterility and are maintained in collection in a heterozygous state. Genetic analysis accompanied by cytogenetic study of meiosis has revealed six mutation types. (1) Nonallelic asynaptic mutations sy1 and sy9 caused the formation of only axial chromosome elements in prophase and anaphase. The synaptonemal complexes (SCs) were absent, the formation of the chromosome "bouquet" was impaired, and all chromosomes were univalent in meiotic metaphase I in 96% (sy1) and 67% (sy2) of cells. (2) Weak asynaptic mutation sy3, which hindered complete termination of synapsis in prophase II. Subterminal asynaptic segments were always observed in the SC, and at least one pair of univalents was present in metaphase I, but the number of cells with univalents did not exceed 2%. (3) Mutations sy2, sy6, sy7, sy8, sy10, and sy19, which caused partially nonhomologous synapsis: change in pairing partners and fold-back chromosome synapsis in prophase I. In metaphase I, the number of univalents varied and multivalents were observed. (4) Mutation mei6, which causes the formation of ultrastructural protrusions on the lateral SC elements, gaps and branching of these elements. (5) Allelic mutations mei8 and mei10, which caused irregular chromatin condensation along chromosomes in prophase I, sticking and fragmentation of chromosomes in metaphase I. (6) Allelic mutations mei5 and mei10, which caused chromosome hypercondensation, defects of the division spindle formation, and random arrest of cells at different meiotic stages. However, these mutations did not affect the formation of microspore envelopes even around the cells, whose development was blocked at prophase I. Analysis of cytological pictures of meiosis in double rye mutants reveled epistatic interaction in the mutation series sy9 > sy1 > sy3 > sy19, which reflects the order of switching these genes in the course of meiosis. The expression of genes sy2 and sy19 was shown to be controlled by modifier genes. Most meiotic mutations found in rye have analogs in other plant species.     

Behaviour of rye univalents in hybrids of 6x-triticale with Triticum turgidum (L.) ssp. turgidum conv. durum (Desf.)

In a cytological analysis of the meiotic behaviour in PMCs of five hybrids between hexaploid triticale and durum wheat, Triticum turgidum L., chromosome association at meiotic first metaphase and the behaviour of rye univalents at first anaphase were analyzed. The chromosomes of the B genome, chromosomes 4A and 7A (disomic condition), and the seven rye chromosomes, could be distinguished by their C-banding pattern. No wheat-rye paring was detected at metaphase I. Rye univalents were observed as laggards which disjoined either predominantly equationaly (2R, 3R, 4R, 5R and 7R) or predominantly reductionaly (1R and 6R). Misdivision occurred in up to 3% of rye univalents.