Physical mapping of the 5S ribosomal RNA genes in Arabidopsis thaliana by multi-color fluorescence in situ hybridization with cosmid clones

The 5S ribosomal RNA genes were mapped to mitotic chromosomes of Arabidopsis thaliana by fluorescence in situ hybridization (FISH). In the ecotype Landsberg erecta, hybridization signals appeared on three pairs of chromosomes, two of which were metacentric and the other acrocentric. Hybridization signals on one pair of metacentric chromosomes were much stronger than those on the acrocentric and the other pair of metacentric chromosomes, probably reflecting the number of copies of the genes on the chromosomes. Other ecotypes, Columbia and Wassilewskija, had similar chromosomal distribution of the genes, but the hybridization signals on one pair of metacentric chromosomes were very weak, and detectable only in chromosomes prepared from young flower buds. The chromosomes and arms carrying the 5S rDNA were identified by multi-color FISH with cosmid clones and a centromeric 180 bp repeat as co-probes. The metacentric chromosome 5 and its L arm carries the largest cluster of the genes, and the short arm of acrocentric chromosome 4 carries a small cluster in all three ecotypes. Chromosome 3 had another small cluster of 5S rRNA genes on its L arm. Chromosomes 1 and 2 had no 5S rDNA cluster, but they are morphologically distinguishable; chromosome 1 is metacentric and 2 acrocentric. Using the 5S rDNA as a probe, therefore, all chromosomes of A. thaliana could be identified by FISH. Chromosome 1 is large and metacentric; chromosome 2 is acrocentric carrying 18S-5.8S-25S rDNA clusters on its short arm; chromosome 3 is metacentric carrying a small cluster of 5S rDNA genes on its L arm; chromosome 4 is acrocentric carrying both 18S-5.8S-25S and 5S rDNAs on its short (L) arm; and chromosome 5 is metacentric carrying a large cluster of 5S rDNA on its L arm.     

Studies of mammalian chromosome replication

Sister chromatids of metaphase chromosomes can be differentially stained if the cells have replicated their DNA semiconservatively for two cell cycles in a medium containing 5-bromodeoxyuridine (BrdU). When prematurely condensed chromosomes (PCC) are induced in cells during the second S phase after BrdU is added to the medium, the replicated chromosome segments show sister chromatid differential (SCD) staining. Employing this PCC-SCD system on synchronous and asynchronous Chinese hamster ovary (CHO) cells, we have demonstrated that the replication patterns of the CHO cells can be categorized into G₁/S, early, early-mid, mid-late, and late S phase patterns according to the amount of replicated chromosomes. During the first 4 h of the S phase, the replication patterns show SCD staining in chains of small chromosome segments. The amount of replicated chromosomes increase during the mid-late and late S categories (last 4 h). Significantly, small SCD segments are also present during these late intervals of the S phase. Measurements of these replicated segments indicate the presence of characteristic chromosome fragment sizes between 0.2 to 1.2 m in all S phase cells except those at G₁/S which contain no SCD fragments. These small segments are operationally defined as chromosome replicating units or chromosomal replicons. They are interpreted to be composed of clusters of molecular DNA replicons. The larger SCD segments in the late S cells may arise by the joining of adjacent chromosomal replicons. Further application of this PCC-SCD method to study the chromosome replication process of two other rodents, Peromyscus eremicus and Microtus agrestis, with peculiar chromosomal locations of heterochromatin has demonstrated an ordered sequence of chromosome replication. The euchromatin and heterochromatin of the two species undergo two separate sequences of decondensation, replication, and condensation during the early-mid and mid-late intervals respectively of the S phase. Similar-sized chromosomal replicons are present in both types of chromatin. These data suggest that mammalian chromosomes are replicated in groups of replicating units, or chromosomal replicons, along their lengths. The organization and structure of these chromosomal replicons with respect to those of the interphase nucleus and metaphase chromosomes are discussed.     

Physical mapping of rDNA genes establishes the karyotype of almond

The localisation of ribosomal RNA genes on chromosomes of almond (Prunus amygdalus, 2n = 16) was studied by fluorescence in situ hybridisation. Simultaneous double-colour hybridisation with both 18S–5.8S–25S and 5S rDNA probes demonstrated that all chromosomes can be identified. In spite of the small size, differences in length between chromosomes that hybridised with the same rDNA probe as well as between chromosomes without hybridisation signal are apparent. Chromosomes were ordered in the karyotype according to their length. The 18S-5.8S-25S rDNA genes were detected in subdistal positions of chromosomes 2, 3, and 8. Sites located on chromosomes 2 and 3 carry a higher number of repeats than the site of chromosome 8. The 5S rDNA genes were found proximally located on chromosomes 5 and 7, the signal on chromosome 5 showing higher intensity than the signal on chromosome 7. Chromosomes 1, 4, and 6 show no hybridisation signal.     

Chromosome numbers of some species of Salvia (Lamiaceae) from the Sichuan Province, China

The present study reports the chromosome number of 12 accessions belonging to 10 species of Salvia from the Sichuan Province in China. Most accessions have the chromosome number 2n=2x=16. However, three species ( S. evansiana, S. przewalskii and S. brevilabra ) are tetraploid with a chromosome number of 2n=4x=32. A B-chromosome was observed in S. tricuspis . The basic chromosome number x=8 was inferred for all accessions studied. The chromosome number of all the species was determined for the first time, except for S. evansiana, S. przewalskii , S. flava and S. miltiorrhiza . The chromosomes in this genus are mostly small (0.46–2.94 μm). The small size of the chromosomes, together with their unclear centromeres, has hampered a detailed karyotype analysis.     

Chromosome 18 replaced by two ring chromosomes of chromosome 18 origin

We here describe the first example of the replacement of an autosome by two ring chromosomes originating from the missing chromosome, presented in a patient with a single chromosome 18 and two additional ring chromosomes. Detailed fluorescence in situ hybridization (FISH) analysis revealed the chromosome 18 origin of both ring chromosomes and characterized the small and the large ring chromosome as derivatives of the short and long arm of chromosome 18, respectively. The loss of subtelomeric regions of the short and the long arm of chromosome 18 in the ring chromosomes was confirmed by FISH studies. Molecular studies showed the exclusive presence of the paternal alleles for microsatellite markers located distal to the short and long arm loci D18S843 and D18S474, respectively. This indicates the maternal origin of both rings and provides evidence for substantial deletions of the distal parts of both arms of chromosome 18 in the ring chromosomes. The dysmorphic features of the patient can be explained by these deletions in both chromosome arms, as the clinical findings partly overlap with observations in 18p- and 18q-syndrome and are similar to some cases of ring chromosome 18. Centromere misdivision is suggested as one mechanism involved in the formation of the ring chromosomes.     

DNA probes for identifying chromosomes 5, 6, and 7 of Schistosoma mansoni

Schistosoma mansoni has a genome of 270 Mb contained on 8 pairs of chromosomes. C-banding has been a useful technique in identifying the 7 autosomal and sex chromosomes. However, even with C-banding, S. mansoni chromosomes 5, 6, and 7 are difficult to discriminate from each other, because of their small sizes, morphological similarity, and poor banding patterns. We have identified probes that specifically paint chromosomes 5, 6, and 7 of S. mansoni with the use of chromosome microdissection and the degenerate oligonucleotide-primed polymerase chain reaction (DOP-PCR). Exact chromosome identification is required for accurate chromosome mapping of genomic clones and genetic elements, which is an essential component of the schistosome genome project.     

Is the doubly deleted alpha-thalassemia gene a "fugitive" allele?

The alpha-thalassemias (particularly in Asia) can be considered as a three-allele system, with one "normal" allele (N) consisting of a pair of closely linked alpha-chain loci, a second "single" allele (S) in which one of the loci has been lost by deletion, and a third "double" allele (D) in which both have been lost. Representatives of all the sets of fitnesses leading to the maintenance of this condition by selection for malaria resistance have been explored, and after the discarding of unlikely sets of fitnesses, it is found that there will be three outcomes: (1) the S chromosome is fixed, (2) the S and N chromosomes form a stable polymorphism, and (3) the N and D chromosomes form a stable polymorphism, but this can be lost and the population forced to fixation by the introduction of sufficiently large number of S chromosomes. Some Melanesian populations appear to have reached outcome (1), while frequencies in African, Mediterranean, and Middle Eastern populations are not incompatible with outcome (2). Southeast Asian populations, however, which carry S and D chromosomes in high frequency, may be in a state of flux. The D chromosome may form a polymorphism with N locally, but it can be driven from the local population by the introduction of large numbers of S chromosomes. The D chromosome would thus be somewhat analogous to a fugitive species, which can only exist in certain transient environments and is displaced as the environment changes. The possibility that N, S, and D are coexisting as a stable polymorphism can almost certainly be ruled out by a consideration of fitness sets required.     

水稻45S rDNA和5S rDNA的染色体定位研究

45SrDNA和5SrDNA是水稻中与核糖体RNA合成有关的2个功能片段,有关这2个序列在水稻染色体上的位置,不同研究者的研究结果不尽相同,在获得水稻染色体清晰制片的基础上,通过FISH确定了45SrDNA序列位于水稻的第9号和第10号染色体的短臂末端,并且第9号染色体上的拷贝数多于第10号染色体,5SrDNA序列位于第11号染色体短臂靠近着丝点处。     

Quantitative chromosome map of the polyploid Saccharum spontaneum by multicolor fluorescence in situ hybridization and imaging methods

Somatic chromosomes of a wild relative of sugarcane (Saccharum spontaneum L.) anther culture-derived clone (AP 85-361, 2n=32) were identified and characterized by computer-aided imaging technology and molecular cytological methods. The presence of four satellite chromosomes and four nearly identical chromosome sets suggests that the clone is a tetrahaploid with the basic number x=8. A quantitative chromosome map, or idiogram, was developed using image analysis of the condensation pattern (CP) at the prometaphase stage of somatic chromosomes. The 45S and 5S ribosomal RNA gene (rDNA) loci were simultaneously visualized by multi-color fluorescence in situ hybridization (McFISH) and precisely localized to the regions of 3p3.1 and 6q1.3 on the idiogram. The simultaneous visualization of two sets of four ribosomal RNA genes confirms tetraploidy of this clone. This conclusion is consistent with results of molecular marker mapping. The quantitative chromosome map produced will become the foundation for genome analyses based on chromosome identity and structure. Previously impossible identification of small chromosomes and untestable hypotheses about the polyploid nature of plants can now be settled with these two approaches of quantitative karyotyping and FISH.     

Rearrangements between germ-line Limited and somatic chromosomes in Smittia parthenogenetica (Chironomidae,Diptera)

Among more than 700 chromosome rearrangements induced by X-rays in oocytes of newly hatched females of Smittia parthenogenetica two cases of insertion of heterochromatin into an S chromosome have been obtained. As the S chromosomes do not contain such heterochromatic sections, the insertions must be derived from K chromosomes. Whether all K chromosomes are completely heterochromatic or whether all or some contain euchromatic sections remains open, but for the two latter possibilities no proof has been obtained. Euchromatic insertions or translocations with a banding pattern non-homologous with S chromosome sections have not been observed with certainty. Homologous duplications could all be interpreted as being derived from S chromosomes. From the K chromosome cycle it can be inferred that the K complement consists of more or less identical elements and that genetic isolation has led to their heterochromatinization.To Sally Hughes-Schrader with affection and admiration.     

Studies on early replication patterns in the marsupial Sminthopsis crassicaudata: no evidence for XY replication homologies

We present here the first detailed replication banding study of a marsupial species using the BrdU-replication technique. A comparison of the structural and replication bands of the chromosomes of Sminthopsis crassicaudata clearly demonstrates that the replication behavior is the same as the described for the chromosomes of eutherians. The early replicating segments correspond to R-bands, whereas the late-replicating regions tend to be situated within Q- and C-bands. Use of this technique clearly reveals an early and late replicating X chromosome. The very small Y chromosome can be subdivided into two replication segments, but no replication homologies can be demonstrated between the X and Y chromosomes of S. crassicaudata.     

Construction of a bacterial artificial chromosome (BAC) library for potato molecular cytogenetics research.

Lack of reliable techniques for chromosome identification is the major obstacle for cytogenetics research in plant species with large numbers of small chromosomes. To promote molecular cytogenetics research of potato (Solanum tuberosum, 2n = 4x = 48) we developed a bacterial artificial chromosome (BAC) library of a diploid potato species S. bulbocastanum. The library consists of 23,808 clones with an average insert size of 155 kb, and represents approximately 3.7 equivalents to the potato genome. The majority of the clones in the BAC library generated distinct signals on specific potato chromosomes using fluorescence in situ hybridization (FISH). The hybridization signals provide excellent cytological markers to tag individual potato chromosomes. We also demonstrated that the BAC clones can be mapped to specific positions on meiotic pachytene chromosomes. The excellent resolution of pachytene FISH can be used to construct a physical map of potato by mapping molecular marker-targeted BAC clones on pachytene chromosomes.     

Development and applications of a set of chromosome-specific cytogenetic DNA markers in potato

Reliable and easy to use techniques for chromosome identification are critical for many aspects of cytogenetic research. Unfortunately, such techniques are not available in many plant species, especially those with a large number of small chromosomes. Here we demonstrate that fluorescence in situ hybridization (FISH) signals derived from bacterial artificial chromosomes (BACs) can be used as chromosome-specific cytogenetic DNA markers for chromosome identification in potato. We screened a potato BAC library using genetically mapped restriction fragment length polymorphism markers as probes. The identified BAC clones were then labeled as probes for FISH analysis. A set of 12 chromosome-specific BAC clones were isolated and the FISH signals derived from these BAC clones serve as convenient and reliable cytological markers for potato chromosome identification. We mapped the 5S rRNA genes, the 45S rRNA genes, and a potato late blight resistance gene to three specific potato chromosomes using the chromosome-specific BAC clones. Received: 19 January 2000 / Accepted: 27 March 2000     

Use of the chromosomal co-location of the minor 5S and the major 28S rDNA as a cytogenetic marker within the genus Leuciscus (Pisces, Cyprinidae)

The chromosomes of three species from the genus Leuciscus (the ide L. idus, the European chub L. cephalus and the common dace L. leuciscus) were examined with the FISH technique for 5S and 28S rDNA probes. The analysis showed that among the three examined species, 5S rDNA signals were located on two large and four small subtelocentric chromosomes in L. leuciscus, on one large and five small subtelocentric chromosomes in L. idus, while in L. cephalus the probe signals were found on two metacentric chromosomes and one large and one small subtelocentric chromosome pairs. In all analysed species, the 28S rDNA probe signals were placed on only one chromosome pair, subtelocentric in the common dace and the European chub, and submetacentric in the ide. The three species differed in the number of sites in which both probe signals were present. In conclusion, the co-location of the 5S and 28S rDNA proved to be a useful cytogenetic marker among the studied fishes. Moreover, this marker could be adapted to other cyprinids.     

Nature and distribution of chromosomal intertwinings in Saccharomyces cerevisiae.

To elucidate yeast chromosome structure and behavior, we examined the breakage of entangled chromosomes in DNA topoisomerase II mutants by hybridization to chromosomal DNA resolved by pulsed-field gel electrophoresis. Our study reveals that large and small chromosomes differ in the nature and distribution of their intertwinings. Probes to large chromosomes (450 kb or larger) detect chromosome breakage, but probes to small chromosomes (380 kb or smaller) reveal no breakage products. Examination of chromosomes with one small arm and one large arm suggests that the two arms behave independently. The acrocentric chromosome XIV breaks only on the long arm, and its preferred region of breakage is approximately 200 kb from the centromere. When the centromere of chromosome XIV is relocated, the preferred region of breakage shifts accordingly. These results suggest that large chromosomes break because they have long arms and small chromosomes do not break because they have small arms. Indeed, a small metacentric chromosome can be made to break if it is rearranged to form a telocentric chromosome with one long arm or a ring with an "infinitely" long arm. These results suggest a model of chromosomal intertwining in which the length of the chromosome arm prevents intertwinings from passively resolving off the end of the arm during chromosome segregation.     

Molecular cytogenetic characterization of Ciona intestinalis chromosomes

The compact genome of the ascidian Ciona intestinalis has been sequenced. Chromosome karyotype and mapping of the genome sequence information on each of the 14 pairs of chromosomes are essential for genome-wide studies of gene expression and function in this basal chordate. Although the small chromosome size (most pairs measuring less than 2 mum) complicates accurate chromosome pairing based on morphology alone, the present results suggest that 20 chromosomes are metacentric and 8 are submetacentric or subtelocentric, and two pairs of large chromosomes (#1 and #2) were defined. The characterization of chromosomes by FISH and staining with propidium iodide indicated that 18S/28S ribosomal gene repeats are present in the short arms of three pairs of chromosomes and that the short arms of these pairs show remarkable size polymorphism. In addition, each chromosome was characterized molecular cytogenetically by mapping representative BAC clones with FISH. The present study is therefore a first step in expanding the karyotype analysis and entire physical mapping of the genome sequence of Ciona intestinalis.     

Contrasting rDNA evolution in lima bean (Phaseolus lunatus L.) and common bean (P. vulgaris L., Fabaceae)

Phaseolus vulgaris has two 5S rDNA sites in chromosomes 6 and 10 and from two up to nine 45S rDNA sites depending on the accession. The presence of three 45S rDNA sites, in chromosomes 6, 9 and 10, is considered the ancestral state for the species. For P. lunatus, only one 5S and one 45S rDNA sites in distinct chromosomes were known. In order to investigate the homeologies among these rDNA-bearing chromosomes and the stability of the rDNA sites in P. lunatus, rDNA and P. vulgaris chromosome-specific probes were hybridized in situ to P. lunatus. The chromosomes bearing the 5S and the 45S rDNA of P. lunatus are homeologous to chromosomes 10 and 6 of P. vulgaris, respectively. In contrast to the common bean, no variation in the number of rDNA loci was detected, except for a duplication of the 5S rDNA in the same chromosome in a small group of cultivars. These results suggest that the 5S rDNA site in chromosome 10 and the 45S rDNA site in chromosome 6 represent the ancestral loci in the genus. The 5S rDNA site in chromosome 10 of P. vulgaris is located in the long arm, while in P. lunatus it is present in the short arm, suggesting the occurrence of a transposition or a pericentric inversion after separation of both lineages.     

Detection of alien chromatin introgression from Thinopyrum into wheat using S genomic DNA as a probe--a landmark approach for Thinopyrum genome research

The introduction of alien genetic variation from the genus Thinopyrum through chromosome engineering into wheat is a valuable and proven technique for wheat improvement. A number of economically important traits have been transferred into wheat as single genes, chromosome arms or entire chromosomes. Successful transfers can be greatly assisted by the precise identification of alien chromatin in the recipient progenies. Chromosome identification and characterization are useful for genetic manipulation and transfer in wheat breeding following chromosome engineering. Genomic in situ hybridization (GISH) using an S genomic DNA probe from the diploid species Pseudoroegneria has proven to be a powerful diagnostic cytogenetic tool for monitoring the transfer of many promising agronomic traits from Thinopyrum. This specific S genomic probe not only allows the direct determination of the chromosome composition in wheat-Thinopyrum hybrids, but also can separate the Th. intermedium chromosomes into the J, J(S) and S genomes. The J(S) genome, which consists of a modified J genome chromosome distinguished by S genomic sequences of Pseudoroegneria near the centromere and telomere, carries many disease and mite resistance genes. Utilization of this S genomic probe leads to a better understanding of genomic affinities between Thinopyrum and wheat, and provides a molecular cytogenetic marker for monitoring the transfer of alien Thinopyrum agronomic traits into wheat recipient lines.     

Fluorescent in situ identification of human marker chromosomes using flow sorting and Alu element-mediated PCR.

A novel approach to the identification of human chromosomes has been developed. Chromosomal in situ hybridization (or "chromosome painting") has been performed using Alu element-mediated PCR products from small quantities (250-500) of flow-sorted normal and abnormal chromosomes. Chromosome paints for various normal chromosomes, including 5, 6, 7, 14, 18, 19, 21, and 22, were generated and shown to be effective in the identification of the appropriate chromosomes. In addition, certain abnormal chromosomes, including a mental retardation-associated deletion chromosome 11 (q22-q23), the products of the constitutional translocation t(11;22), and the CML-associated t(9;22), were used to generate region-specific paints. In each case, the appropriate regions of the chromosomes were highlighted and this strategy is, therefore, well suited to the identification of previously unidentified marker chromosomes. A further direct consequence of this work is that chromosome paints specific for the common aberrant chromosomes, such as the Philadelphia chromosome, can be generated and made widely available. These may find particular use in the analysis of complex or masked chromosomal translocations.     

Refined molecular characterization of the breakpoints in small inv dup(15) chromosomes

Inv dup(15) is the most common supernumerary marker chromosome in humans. To investigate the mechanism responsible for this frequent chromosome rearrangement, we characterized the breakpoints in 18 individuals with small inv dup(15) chromosomes [i.e., negative for the Prader-Willi (PWS)/Angelman syndrome (AS) critical region]. Since two proximal breakpoint regions (“hotspots”) for PWS/AS deletions have been previously identified with the most proximal 15q markers D15S541/S542 and S543, we hypothesized that formation of the small inv dup(15) chromosomes may involve one or both of these breakpoint hotspots. By analysis with S542, both breakpoint regions were found to be involved in approximately equal frequencies. In ten cases, the inv dup(15) was negative for S542 (Class I), indicating the breakpoint is between the centromere and the most proximal marker on chromosome 15. For the other eight cases, S542 was positive by fluorescence in situ hybridization (5/5) and/or microsatellite analysis (7/7), but S543 was negative (Class II). These two breakpoint regions appear to be the same as the two proximal breakpoints reported in the common PWS/AS deletions. To initiate cloning and sequencing of the Class II breakpoint, the gap in the yeast artificial chromosome (YAC) contig between S541/S542 and S543 was filled by screening the CEPH YAC and mega-YAC libraries. YACs 705C2 and 368H3 were found to bridge this gap, and therefore contain the more distal breakpoint region. The finding of consistent breakpoints in small inv dup(15), like that found in PWS/AS deletions, provides strong evidence for hotspots for chromosome breakage in this region. In addition, our results show that two extra copies (tetrasomy) of the region from 15cen to the euchromatic region containing S542 are present in individuals with Class II breakpoints. Since most individuals carrying a small inv dup(15) are phenotypically normal, the euchromatin region included in the small inv dup(15) chromosomes does not appear to contain genes with clinically significant dosage effects. Received: 23 May 1996 / Revised: 7 August 1996