In Situ Hybridization of Biotinylated Dna Probes to Cotton Meiotic Chromosomes

A modified procedure for in situ hybridization of biotinylated probes to meiotic chromosomes of cotton has been developed with high retention of squashed cells on slides, preservation of acid-fixed chromosome morphology, exceptionally low levels of background precipitate at nonspecific hybridization sites and improved photomicrographic recording. Salient features of the techniques include pretreatment of slides before squashing, cold storage of squash preparations, and use of interference Biters for distinguishing precipitate from chromatin. A cloned 18S/28S ribosomal DNA fragment from soybean was biotinylated via nick-translation and hybridized to microsporocyte meiotic chromosomes 6f cotton (Gostypium hirsutum L. and G. hirsutum L. X G. barbadense L.). Enzymatically formed precipitate from streptavidin-bound peroxidase marked the in situ hybridization.

In situ hybridization of biotinylated probes to cotton meiotic chromosomes adds the specificity and resolution of in situ hybridization to the chromosomal and genomic perspectives provided by meiotic cytogenetic analyses. Molecular cytogenetic analyses of meiotic cells offer certain inherent analytical advantages over analyses of somatic cells, e.g., in terms of mapping, and for studying fundamental biological and genetic problems, particularly for organisms that are not amenable to somatic karyotypic analysis.     

Completely distinguishing individual A-genome chromosomes and their karyotyping analysis by multiple bacterial artificial chromosome - fluorescence in situ hybridization

Twenty bacterial artificial chromosome (BAC) clones that could produce bright signals and no or very low fluorescence in situ hybridization (FISH) background were identified from Gossypium arboreum cv. JLZM, and G. hirsutum accession (acc.) TM-1 and 0-613-2R. Combining with 45S and 5S rDNA, a 22-probe cocktail that could identify all 13 G. arboreum chromosomes simultaneously was developed. According to their homology with tetraploid cotton, the G. arboreum chromosomes were designated as A1-A13, and a standard karyotype analysis of G. arboreum was presented. These results demonstrated an application for multiple BAC-FISH in cotton cytogenetic studies and a technique to overcome the problem of simultaneous chromosome recognition in mitotic cotton cells.     

Identification of a homeologous chromosome pair by in situ DNA hybridization to ribosomal RNA loci in meiotic chromosomes of cotton (Gossypium hirsutum).

In situ DNA hybridization with 18S-28S and 5S ribosomal DNA probes was used to map 18S-28S nucleolar organizers and tandem 5S repeats to meiotic chromosomes of cotton (Gossypium hirsutum L.). Mapping was performed by correlating hybridization sites to particular positions in translocation quadrivalents. Arm assignment required translocation quadrivalents with at least one interstitial chiasma and sufficient distance between the hybridization site and the centromere. We had previously localized a major 18S-28S site to the short arm of chromosome 9; here we mapped two additional major 18S-28S sites to the short arm of chromosome 16 and the left arm of chromosome 23. We also identified and mapped a minor 18S-28S site to the short arm of chromosome 7. Two 5S sites of unequal size were identified, the larger one near the centromere of chromosome 9 and the smaller one near the centromere of chromosome 23. Synteny of 5S and 18S-28S sites indicated homeology of chromosomes 9 and 23, while positions of the other two 18S-28S sites supplement genetic evidence that chromosomes 7 and 16 are homeologous.     

Establishment of a multi-color genomic in situ hybridization technique to simultaneously discriminate the three interspecific hybrid genomes in gossypium

To identify alien chromosomes in recipient progenies and to analyze genome components in polyploidy, a genomic in situ hybridization （GISH） technique that is suitable for cotton was developed using increased stringency conditions. The increased stringency conditions were a combination of the four factors in the following optimized state： 100：1 ratio of blocking DNA to probe, 60% formamide wash solution, 43 ℃ temperature wash and a 13 min wash. Under these specific conditions using gDNA from Gossypium sturtianum （C1 C1 ） as a probe, strong hybridization signals were only observed on chromosomes from the C1 genome in somatic cells of the hybrid F1 （G. hirsutum x G. sturtianum） （AtDtC1）. Therefore, GISH was able to discriminate parental chromosomes in the hybrid. Further, we developed a multi-color GISH to simultaneously discriminate the three genomes of the above hybrid. The results repeatedly displayed the three genomes, At, Dt, and C1, and each set of chromosomes with a unique color, making them easy to identify. The power of the multi-color GISH was proven by analysis of the hexaploid hybrid F1 （G. hirsutum x G. australe） （AtAtDtDtG2G2）. We believe that the powerful multi-color GISH technique could be applied extensively to analyze the genome component in polyploidy and to identify alien chromosomes in the recipient progenies.     

In situ localization of human fibronectin (FN) genes to chromosome regions 2p14----p16, 2q34----q36, and 11q12.1----q13.5 in germ line cells, but to chromosome 2 sites only in somatic cells

The locations of the genes for fibronectin (FN) on chromosomes of human germ line and somatic cells were determined by in situ molecular hybridization with two 3H-labeled DNA probes, one for the region encoding the cell attachment domain of human FN, the other for the 3' noncoding and part of the coding region. Pachytene chromosomes of two males and lymphocyte chromosomes of one of these males and a female were used. Two regions of hybridization on pachytene and somatic chromosome 2 (p14----p16 and q34----q36) were found, but not in all individuals. A third region of hybridization was found at 11q12.1----q13.5 in meiotic, but not with significant frequency in somatic chromosomes. It is not clear if these differences between meiotic and somatic chromosomes, and the large differences between individuals at some of the other hybridization sites, resulted solely from technical factors. The differences between the findings in meiotic and somatic preparations might be due to the presence of four strands in pachytene chromosomes versus only one per somatic chromatid. Individual differences in DNA sequences in the chromosome segment containing the gene, differences in gene locations among individuals, or between meiotic and mitotic chromosomes might account for the other findings. The results confirm some of the earlier studies with cell hybrids that mapped FN genes to chromosomes 2 or 11. The combined findings suggest that some of these loci may be coding for the plasma form of FN and others for the cellular form. The expression of the different FN types by differentiated cells might then depend on the loci that are activated.     

Identification of equine chromosomes in horse x mouse somatic cell hybrids.

Giemsa-11 (G-11) staining and in situ hybridization were used to identify the equine chromosome complement of horse x mouse somatic cell hybrids. The presence of horse chromosomes in somatic cell hybrids was determined by differential G-11 staining. The slides were then destained and hybridized with biotinylated total horse (Equus caballus) genomic DNA without suppression. Fluorescence detection permitted rapid confirmation of horse chromosomal DNA in the hybrid cells.     

Studying meiosis: a review of FISH and M-FISH techniques used in the analysis of meiotic processes in humans

It is well known that chromosome in situ hybridization allows the unequivocal identification of targeted human somatic chromosomes. Different fluorescent in situ hybridization (FISH) techniques have been developed throughout the years and, following the mitotic studies, meiotic analyses have been performed using these different techniques. The introduction of M-FISH techniques to the analysis of meiotic cells has allowed the study of meiotic processes for every individual human chromosome. In this paper, we review the different FISH and M-FISH techniques that have been used on human meiotic cells in both men and women.     

Simultaneous identification and banding of human chromosome material in somatic cell hybrids

We have developed a method that identifies human chromosomes in human x hamster somatic cell hybrids and simultaneously bands these same metaphases. Other methods generally require separate slides for banding and detection of human chromosome material, making the precise characterization of human material difficult. Our procedure involves denaturing metaphase chromosomes, followed by in situ hybridization of biotinylated whole human DNA. Fluoresceinated avidin is then bound to the biotinylated DNA, staining the human chromosomes yellow-green when excited with UV light. Chromosome banding is achieved by staining the slides with DAPI and actinomycin D. The fluorescein and DAPI excite maximally at 488 and 355 nm and emit at 520 and 450 nm, respectively. This permits identification of the human material at one excitation wavelength and visualization of the banding patterns at another wavelength. With this procedure, we have successfully identified both intact and broken human chromosomes, as well as human material involved in human x hamster translocations. The results indicate that this procedure is more accurate and considerably more rapid than previous methods and can be routinely employed for the cytogenetic analysis of human x rodent hybrids.     

Male meiotic segregation of gonosomes analysed by two colour FISH in human interphase spermatozoa

Human meiotic segregation of X and Y chromosomes was simultaneously analysed by dual fluorescence in situ hybridization (FISH) on 10638 interphase spermatozoa from the same donor. A modified method for sperm decondensation ensured access of both X and Y probes to the sperm chromatin and a 99% hybridization efficiency. Expected sex ratios were obtained (49.30% haploidy X and 49.22% haploidy Y). The frequencies of meiotic II non-disjunctions for X and Y chromosomes (0.05%) were similar to those observed in sperm karyotypes after heterospecific fertilization of hamster eggs. In contrast, the frequency of XY bearing cells was significantly higher (0.42%). However, XY cells detected by FISH could either be diploid somatic cells, diploid germinal cells or hyperhaploid XY spermatozoa, the latter resulting from meiotic I non-disjunctions.     

Complete assignment of the chromosomes of Gossypium hirsutum L. by translocation and fluorescence in situ hybridization mapping

Significant progress has been made in the construction of genetic maps in the tetraploid cotton Gossypium hirsutum. However, six linkage groups (LGs) have still not been assigned to specific chromosomes, which is a hindrance for integrated genetic map construction. In the present research, specific bacterial artificial chromosome (BAC) clones constructed in G. hirsutum acc. TM-1 for these six LGs were identified by screening the BAC library using linkage group-specific simple-sequence repeats markers. These BAC clones were hybridized to ten translocation heterozygotes of G. hirsutum. L as BAC-fluorescence in situ hybridization probes, which allowed us to assign these six LGs A01, A02, A03, D02, D03, and D08 to chromosomes 13, 8, 11, 21, 24, and 19, respectively. Therefore, the 13 homeologous chromosome pairs have been established, and we have proposed a new chromosome nomenclature for tetraploid cotton.     

Assignment of porcine cyclin-dependent kinase 4 (CDK4) and oncogene c-mos (MOS) by nonradioactive nonfluorescence in situ hybridization

Two pig genes, cyclin-dependent kinase 4 (CDK4) and the oncogene c-mos (MOS) were mapped by means of nonradioactive nonfluorescence in situ hybridization. Our approach was based on the detection of hybridized biotinylated probe by peroxidase conjugated extravidin and the reaction of peroxidase with its substrate diaminobenzidine (DAB) resulting in a dark precipitate. To increase the sensitivity of the method in single-copy gene mapping, two amplifications of the peroxidase signal were used: immunological amplification by biotinylated antiavidin, and peroxidase-catalysed deposition of biotinylated tyramide. Using this method, two 2-kb-long probes for the porcine genes CDK4 and MOS were mapped to pig chromosomes 5p12 and 4q14-15, respectively. Non-radioactive nonfluorescence in situ hybridization described here is a method of choice for gene mapping of short probes.     

ISH-facilitated analysis of meiotic bivalent pairing.

Chiasmata constitute one of the cornerstones of sexual reproduction in most eukaryotes. They mediate the reciprocal genetic exchange between homologues and are essential to the proper orientation of the homologous centromeres in meiosis I. As markers of recombination, they offer a cytological means of mapping. Rather than trying to accurately count individual chiasmata, we have examined properties of the mathematical relationship between frequencies of nonadorned disomic configurations in meiosis (ring, rods, and univalents) and the probabilities at which arms of the respective chromosomes are chiasmate (one or more chiasma per arm). Numerical analyses indicated that conventionally analyzed bivalents with nonidentified arms yield statistically biased estimates of chiasma probabilities under a broad range of circumstances. We subsequently analyzed estimators derived from adorned configurations with ISH-marked arms, which were found to be statistically far superior, and with no assumptions concerning interference across the centromere. We applied this methodology in the study of chromosomes 16 and 23 of cotton (Gossypium hirsutum), and estimated their arm lengths in centimorgans. The results for chromosome 23, the only one of the two chromosomes with a documented RFLP map, were consistent with the literature. Similar molecular-meiotic configuration analyses can be used for a wide variety of eukaryotic organisms and purposes: for example, providing far more powerful meiotic comparisons of genomes of chromosomes, and a rapid means of evaluating effects on recombination. Key words : meiotic configurations, chiasma frequencies, in situ hybridization, cotton.     

An approach for quantitative assessment of fluorescence in situ hybridization (FISH) signals for applied human molecular cytogenetics.

A number of applied molecular cytogenetic studies require the quantitative assessment of fluorescence in situ hybridization (FISH) signals (for example, interphase FISH analysis of aneuploidy by chromosome enumeration DNA probes; analysis of somatic pairing of homologous chromosomes in interphase nuclei; identification of chromosomal heteromorphism after FISH with satellite DNA probes for differentiation of parental origin of homologous chromosome, etc.). We have performed a pilot study to develop a simple technique for quantitative assessment of FISH signals by means of the digital capturing of microscopic images and the intensity measuring of hybridization signals using Scion Image software, commonly used for quantification of electrophoresis gels. We have tested this approach by quantitative analysis of FISH signals after application of chromosome-specific DNA probes for aneuploidy scoring in interphase nuclei in cells of different human tissues. This approach allowed us to exclude or confirm a low-level mosaic form of aneuploidy by quantification of FISH signals (for example, discrimination of pseudo-monosomy and artifact signals due to over-position of hybridization signals). Quantification of FISH signals was also used for analysis of somatic pairing of homologous chromosomes in nuclei of postmortem brain tissues after FISH with "classical" satellite DNA probes for chromosomes 1, 9, and 16. This approach has shown a relatively high efficiency for the quantitative registration of chromosomal heteromorphism due to variations of centromeric alphoid DNA in homologous parental chromosomes. We propose this approach to be efficient and to be considered as a useful tool in addition to visual FISH signal analysis for applied molecular cytogenetic studies.     

Studies on RNA in the Metaphase Chromosome of Zea mays by Electron Microscopy in Situ Hybridization

In situ hybridization using biotinylated cDNA probes of 18S rRNA, 5S rRNA, tRNAfMet, tRNAcys, tRNAAsn was performed on ultra-thin sections of K4M-embedded maize root tip. After hybridization, the biotinylated hybrids were detected with avidin coupled to 10 nm gold particles and then examined under the electron microscopy. The results showed that 18S rRNA, 5S rRNA and tRNA all existed in the metaphase chromosomes at random. They were distributed not only in the interior of the chromosomes, but also in the periphery of the chromosomes. Three tRNAs and 5S rRNA in the chromosomes were equal in amount to that in the cytoplasm, but the amount of 18S rRNA in the chromosomes was much higher than that in the cytoplasm. These results indicated that a part of the RNAs in the chromosomes came from the nucleolus, while others came from the nucleoplasm.     

Individual chromosome assignment and chromosomal collinearity in Gossypium thurberi, G. trilobum and D subgenome of G. barbadense revealed by BAC-FISH

The experiment on individual chromosome assignments and chromosomal diversity was conducted using a multi-probe fluorescence in situ hybridization (FISH) system in D subgenome of tetraploid Gossypium barbadense (D(b)), G. thurberi (D(1)) and G. trilobum (D(8)), which the later two were the possible subgenome donors of tetraploid cottons. The FISH probes contained a set of bacterial artificial chromosome (BAC) clones specific to 13 individual chromosomes from D subgenome of G. hirsutum (D(h)), a D genome centromere-specific BAC clone 150D24, 45S and 5S ribosomal DNA (rDNA) clones, respectively. All tested chromosome orientations were confirmed by the centromere-specific BAC probe. In D(1) and D(8), four 45S rDNA loci were found assigning at the end of the short arm of chromosomes 03, 07, 09 and 11, while one 5S rDNA locus was successfully marked at pericentromeric region of the short arm of chromosome 09. In D(b), three 45S rDNA loci and two 5S rDNA loci were found out. Among them, two 45S rDNA loci were located at the terminal of the short arm of chromosomes D(b)07 and D(b)09, whilst one 5S rDNA locus was found situating near centromeric region of the short arm of chromosome D(b)09. The positions of the BAC clones specific to the 13 individual chromosomes from D(h) were compared between D(1), D(8) and D(b). The result showed the existence of chromosomal collinearity within D(1) and D(8), and as well between them and D(b). The results will serve as a base for understanding chromosome structure of cotton and polyploidy evolution of cotton genome and will provide bio-information for assembling the sequences of finished and the on-going cotton whole genome sequencing projects.     

Karyotype of mitotic metaphase and meiotic diakinesis in non-heading Chinese cabbage

Non-heading Chinese cabbage [Brassica rapa L. ssp. chinensis (L.) Hanelt] is one of the most popular leafy vegetables. Despite the economic importance of non-heading Chinese cabbage, little attention has been given to its cytogenetic profile. This study reveals the karyotype of non-heading Chinese cabbage. Fluorescence in situ hybridization (FISH) with 45S and 5S rDNA probes was performed on mitotic metaphase complementary regions. We located 45S rDNA on the centromeric or adjacent region of chromosomes A1 and A2, with the largest on the satellite of chromosome A5. Meanwhile, 5S rDNA co-localized with 45S rDNA on chromosomes A2 and A5, and on the telomeric region of chromosome A10. We performed DAPI fluorescence banding on the same metaphase chromosomes to identify homologous chromosomes. The DAPI fluorescence pattern was observed mainly on the centromeric heterochromatin regions of each chromosome. However, the lengths of chromosomes A2 and A6 were completely stained, except for their telomeric regions. Meiotic diakinesis chromosomes as new substrates in FISH-developed karyotype were revealed for the first time. The karyotype of non-heading Chinese cabbage reveals that it contains eight submetacentric chromosomes, one subtelocentric chromosome (bearing satellite), and one telocentric chromosome. Diakinetic chromosome pairing can overcome the difficulty of unlabeled chromosome identification. This study provided valuable information for cytogenetic research and molecular breeding of non-heading Chinese cabbage by using the combination of FISH and DAPI fluorescence patterns on mitotic and meiotic chromosomes.     

Genome reorganization in Nicotiana asymmetric somatic hybrids analysed by in situ hybridization

In situ hybridization was used to examine genome reorganization in asymmetric somatic hybrids between Nicotiana plumbaginifolia and Nicotiana sylvestris obtained by fusion of gamma-irradiated protoplasts from one of the parents (donor) with non-irradiated protoplasts from the other (recipient). Probing with biotinylated total genomic DNA from either the donor or the recipient species unequivocally identified genetic material from both parents in 31 regenerant plants, each originating from a different nuclear hybrid colony. This method, termed genomic in situ hybridization (GISH), allowed intergenomic translocations containing chromosome segments from both species to be recognized in four regenerants. A probe homologous to the consensus sequence of the Arabidopsis thaliana telomeric repeat (5'-TTTAGGG-3')n, identified telomeres on all chromosomes, including 'mini-chromosomes' originating from the irradiated donor genome. Genomic in situ hybridization to plant chromosomes provides a rapid and reliable means of screening for recombinant genotypes in asymmetric somatic hybrids. Used in combination with other DNA probes, it also contributes to a greater understanding of the events responsible for genomic recovery and restabilization following genetic manipulation in vitro.     

Identification of Alien Chromatin and Ribosomal DNA in Wheat by in Situ Hybridization

In situ hybridization was carried out to somatic cells of hexaploid Triticale “Badger”, lB/IR translocation line “Ning 8026” and IR(ID) substitution line “84056-1-36-1” using biotin-labelled total rye genomic DNA and wheat rDNA as probes, the results were as follows: 1. The probe containing the total genomic DNA from rye hybridized to the entire length of all rye chromosomes, as a result of the formation of a brown precipitate over the sites of hybridization, the rye chromosomes could be distinguished from wheat chromosomes counterstained by Wright’s solution, the distinguishable appearance of the wheat and rye chromosomes resulted in an efficient method of detecting rye chromosome or segments in wheat. 2. When the probe PTA 71 containing wheat ribosomal DNA was used to hybridize to somatic chromosomes of "Badger" and “84056-1-36-1”, six signals in “Badger” and eight in “84056-1-36-1” were observed on lB, 6B, 1R and SD, among which lB and 6B showed large in situ signals corresponding to many copies of the genes. 3. The expression behavior of wheat rDNA was found in interphase cells by in situ hybridization.     

Combined GTG-banding and nonradioactive in situ hybridization improves characterization of complex karyotypes

Nonradioactive in situ hybridization (ISH) using biotinylated centromere probes for chromosomes 1, 6, 7, 10, 16, 17, 18, and the X, respectively, was combined with GTG-banding to study cytogenetic changes in two different ovarian cancer cell lines. ISH was performed after GTG-banding on the same metaphase. The use of a low trypsin concentration (0.01%) in the banding procedure was essential for subsequent ISH. This combined approach allows the detection of subtle chromosomal rearrangements and appears to aid the identification of marker chromosomes.     

用电镜原位杂交技术对玉米中期染色体中RNA的研究

用生物素标记的玉米１８ＳｒＲＮＡ、小麦５ＳｒＲＮＡ 及ｔＲＮＡ 的ｃＤＮＡ 作为探针,在Ｋ４Ｍ 树脂包埋的玉米（Ｚｅａ ｍ ａｙｓ）根尖超薄切片上进行原位杂交。杂交后,用与１０ ｎｍ 金颗粒相连的亲和素对杂交子在电镜下进行检测。结果发现,在玉米中期染色体中存在有１８ＳｒＲＮＡ、５ＳｒＲＮＡ 和ｔＲＮＡ 分子,这些ＲＮＡ分子在染色体中的分布是随机的,即这些ＲＮＡ 分子在染色体的内部和周边均有分布。５ＳｒＲＮＡ 和ｔＲ－ＮＡ 在染色体中和细胞质中的含量基本相等,而１８ＳｒＲＮＡ 在染色体中的含量则明显高于细胞质。这一结果表明染色体中的ＲＮＡ 一部分来自于核仁,而另一部分则来自于核质