Ring (15) chromosome

Summary Cytogenetic studies on lymphocytes from a girl aged 3 years and 10 months revealed a ring chromosome 15. Several banding methods showed the r(15) chromosome not to have any apparent deletion of the long arm. The silver staining technique for nucleolar organizer regions showed an NOR positive region (band p12). In only a few cells was a chromosome 15 missing. The size of the r(15) was found to be constant. Comparison with 11 previous reported cases in the literature shows that the clinical manifestations in the different patients with ring chromosome 15 are constant although not clinically identifiable and it appears likely to attribute them to a significantly retarded intrauterine and postnatal growth instead of presumed deficiency in the long arm and mosaic configurations.     

Analysis of banding patterns and mosaic configurations in a case of ring chromosome 15

Summary Cytogenetic studies on lymphocytes from a 14-year-old mentally retarded girl with somatic anomalies suggestive of a chromosomal abnormality revealed a ring chromosome 15. The long arm of the defective chromosome is broken at band q24 or q25. The silver staining technique for nucleolus organizer regions showed that the ring had lost the achromatic stalk and the satellite. The chromosomal mosaicism resulting from the structural instability of the ring chromosome was analyzed and compared with 6 cases reported in the literature. It is proposed that the clinical manifestations in the different patients with ring chromosome 15 result from both the deficiency in the long arm and the mosaic configurations.     

Molecular analysis of a ring chromosome X in a family with fragile X syndrome

The phenotypically normal sister of a patient affected by fragile X syndrome was referred for genetic counselling and was found to carry a mosaic karyotype 46,X,r(X)/45,X. Because the probability of the simultaneous chance occurrence of fragile X syndrome and a ring chromosome X in the same family is very low, we postulated that the breakpoint of the ring chromosome X originated in the cytogenetic break in Xq27.3 responsible for fragile X syndrome. In order to determine the relative positions of the breakpoint on the ring chromosome X and the (CGG)n unstable sequence responsible for the fragile X mutation, we used molecular markers to analyse the telomeric regions of chromosome X in this family. The results showed that the ring chromosome X was the maternal fragile X chromosome and that the telomeric deletion on the long arm encompassed the (CGG)n sequence. This suggests that the cytogenetic break in Xq27.3 is distinct from the unstable (CGG)n sequence, or that the break followed by the end-to-end fusion creating the ring chromosome was not completely conservative. Analysis of DNA markers on the short arm of chromosome X evidenced a deletion of a large part of the pseudoautosomal region, allowing us to position the genes involved in stature and in some syndromes associated with telomeric deletions of Xp on the proximal side of the pseudoautosomal region.     

A spontaneous derivative of abnormal chromosome 10 in maize

Summary A new type of abnormal chromosome 10 has been found among maize plants grown from seeds sent by Dr. Y. C. Ting of Harvard University. This chromosome deviates in its morphology from the orthodox abnormal chromosome 10 described by Rhoades (1952) and from the one described by Ting (1958b). It produces a low degree of neo-centric activity.Cytological observations of plants heterozygous for the new abnormal chromosome 10 and either an orthodox abnormal chromosome 10 or a normal one, have suggested that the new type was derived from an orthodox abnormal 10 through spontaneous breakage and loss of an important piece of its long arm. The delection involved the distal part of the long arm of orthodox abnormal chromosome 10, proximally limited by the third most distal dissimilar and prominent chromomere. This corresponds approximately to the extra segment at the end of orthodox abnormal chromosome 10 which remains unpaired in heterozygotes with the normal 10. It bears a large heterochromatic knob. The missing piece is a part of the larger fraction of the long arm of orthodox abnormal chromosome 10 that remains unaffected by crossingover in a heteromorphic bivalent having a normal chromosome 10 (telo-segment). The telo-segment has its proximal limit at the left of the most proximal of the 3 dissimilar chromomeres, probably between the R and Sr ₂ loci. It has been proposed that a factor or factors responsible for neo-centric activity are located in the portion of the telosegment between its proximal limit and the third most distal dissimilar chromomere (3 dissimilar chromomere region).Since the telo-segment of the orthodox abnormal 10 also bears a large knob in its distal half, it has been suggested that this segment has a dual role in neo-centric activity. The factor or factors located in the proximal piece of the telo-segment would stimulate over-abundance of fiber-forming substance, whereas local production of chromosomal fibers would depend ultimately on the knob's activity.If the large knob is absent, its role in neo-centric activity would be transferred to the next smaller and distally located hetero-chromatic mass, such as the knob-like body near the end of the new abnormal 10 which results from the fusion of the two most proximal prominent chromomeres of the telo-segment.This work has been partly done in the United States, under an I.C.A. — National Academy of Sciences fellowship.     

A functional centromere lacking CentO sequences in a newly formed ring chromosome in rice

An awned rice(Oryza sativa) plant carrying a tiny extra chromosome was discovered among the progeny of a telotrisomic line 2nt4L. Fluorescence in situ hybridization(FISH) using chromosome specific BAC clones revealed that this extra chromosome was a ring chromosome derived from part of the long arm of chromosome 4. So the aneuploidy plant was accordingly named as 2nt4L ring. We did not detect any Cent O FISH signals on the ring chromosome, and found only the centromeric probe Centromeric Retrotransposon of Rice(CRR) was co-localized with the centromere-specific histone CENH3 as revealed by sequential FISH after immunodetection. The extra ring chromosome exhibited a unique segregation pattern during meiosis, including no pairing between the ring chromosome and normal chromosome 4during prophase I and pre-separation of sister chromatids at anaphase I.     

Deletions of the long arm of chromosome 10 in progression of follicular thyroid tumors

Previous studies of follicular thyroid tumors have shown loss of heterozygosity (LOH) on the short arm of chromosome 3 in carcinomas, and on chromosome 10 in atypical adenomas and carcinomas, but not in common adenomas. We studied LOH on these chromosomal arms in 15 follicular thyroid carcinomas, 19 atypical follicular adenomas and 6 anaplastic (undifferentiated) carcinomas. Deletion mapping of chromosome 10 using 15 polymorphic markers showed that 15 (37.5%) of the tumors displayed LOH somewhere along the long arm. Thirteen of these tumors showed deletions involving the telomeric part of chromosome 10q, distal to D1OS 187. LOH on chromosome 3p was found in 8 (20%) cases. Seven of these also showed LOH on chromosome 10q. In eight cases LOH was seen on chromosome 10q but not 3p. In comparison, the retinoblastoma gene locus at chromosome 13q showed LOH in 22% of the tumors. Most of these also had deletions on chromosome 10q. The results indicate that a region at the telomeric part of 10q may be involved in progression of follicular thyroid tumors.     

Molecular cloning and mapping of 10 new probes on the human Y chromosome

We have developed a novel positive cloning vector whose use precludes the cloning of any fragments less than 0.8 kb as well as 3.4-kb EcoRI fragments of DYZ1, the largest repeating-DNA family on the long arm of the human Y chromosome. Using this vector, we subcloned inserts of a Y-chromosome-specific phage library constructed from EcoRI-digested flow-sorted Y-chromosome DNA. Ten novel Y-specific fragments were obtained. Their localization on the Y chromosome was determined by deletion mapping using clinical samples with structurally abnormal Y chromosomes. The long arm of the Y chromosome was divided into 12 segments by the novel probes in combination with established probes. The amelogenin-like sequence, mapped on the long arm in Human Gene Mapping 10, has been mapped on the short arm.     

Assignment of the gene for cytoplasmic glutamic-oxaloacetic transaminase to the region q-24-qter of human chromosome 10.

Somatic cell hybrids between thymidine kinase-deficient mouse cells and human fibroblasts carrying a translocation of the distal third of the long arm of chromosome 10 to chromosome 17 were studied for the expression of cytoplasmic glutamic-oxaloacetic transaminase. A positive correlation between the expression of human cytoplasmic glutamic-oxaloacetic transaminase and the presence of the distal third of the long arm of chromosome 10 was established.     

Linkage mapping of human chromosome 10 microsatellite polymorphisms.

Ten microsatellite DNA polymorphisms located on human chromosome 10 were regionally mapped using subchromosomal somatic cell hybrids and linkage analysis. The resulting order of the markers from pter-qter was [D10S89, D10S111], D10S107, D10S109, [D10S91, D10S110, D10S108, D10S88, D10S168], and D10S169. Order of the markers within brackets was uncertain, although the order given was most likely. The microsatellites were distributed along the chromosome from the proximal p arm to near qter, with an unlinked gap between D10S168 and D10S169.     

Parental origin of a ring 13 chromosome in a female with multiple anomalies

Summary A ring chromosome No. 13 was found in a 21-year-old female with multiple anomalies suggestive of 13q-syndrome. Chromosomes of the girl and her parents, studied by quinacrine staining, revealed the ring to be of paternal origin. Detailed study of the quinacrine banding pattern of the ring indicated loss of the most distal band of the long arm (13q34) and possible partial loss of the next adjacent long arm band (13q33). The short arm (13q11) was present but the stalk (13p12) and satellite (13p13) regions appeared to be missing.This work was supported in part by NIH grants HD 07997; Maternal and Child Health Services 970; HD 08236; CA 16747; by grants from the Medical Research Foundation of Oregon and by a Basil O'Connor Starter Research Grant.     

A linkage group of five DNA markers on human chromosome 10

Five chromosome 10 DNA markers (D10S1, D10S3, D10S4, D10S5, and RBP3) were typed in five large pedigrees with multiple endocrine neoplasia type 2A (MEN-2A) and in five non-MEN-2A pedigrees. Linkage analyses showed that these loci and the locus for MEN-2A (MEN2A) are in one linkage group spanning at least 70 cM. The order of the marker loci is RBP3-D10S5-D10S3-D10S1-D10S4, with interlocus recombination frequencies of 7, 13-19, 19, and 19%, respectively, all on the same side of MEN2A. Analyses of sex-specific recombination frequencies indicated no significant differences between males and females for any of the map intervals studied. Previous localization of D10S5 and RBP3 to the proximal region of the long arm and the pericentric region, respectively, comparison of results with other studies, and our preliminary results with other chromosome 10 markers suggest that the D10S4 end of the map extends into the long arm. Our linkage map has been constructed using only two- and three-locus analyses. It will be possible to combine our results with those of other groups to construct a more detailed and accurate genetic map of chromosome 10.     

Trisomy for the short arm of chromosome No. 10

To the authors knowledge there is a single previous report of confirmed trisomy for the short arm of chromosome No 10 (Hustinx et al., 1974). In this paper we present a further case of trisomy 10p, resulting from 3 : 1 segregation of maternal balanced translocation, t(3;10)(q;11), in a female infant aged 7 months and showing numerous somatic anomalies.     

The organisation of repetitive sequences in the pericentromeric region of human chromosome 10.

Three satellite DNA families are present in the pericentromeric region of chromosome 10; the alpha satellite and two 5 bp satellite families defined here as satellites 2 and 3. Pulsed field gel electrophoresis (PFGE) demonstrates that these sequences are organised into five discrete arrays which are linked within a region of approximately 5.3 Megabases (Mb) of DNA. The alpha satellite is largely confined to a 2.2 Mb array which is flanked on its p arm side by two 100-150 kb satellite 3 arrays and on its q arm side by a 900 kb satellite 2 array and a further 320 kb satellite 3 array. This linear order is corroborated by fluorescent in situ hybridisation analyses. In total, these arrays account for 3.6 Mb of DNA in the pericentromeric region of chromosome 10. These data provide both physical information on sequences which may be involved in centromere function and a map across the centromere which has the potential to link yeast artificial chromosome (YAC) contigs currently being developed on both arms of this chromosome.     

Interstitial deletion and ring chromosome derived from 19q. Proximal 19q trisomy phenotype.

A small supernumerary ring chromosome has been found in a boy with overweight, dysmorphic facies and mental retardation. His mother had an interstitial deletion of the long arm of chromosome 19 and the same ring chromosome. By means of fluorescence in situ hybridization the ring chromosome was shown to be derived from the deleted chromosome, after the occurrence of two breaks: one in the centromere region, the other in the q-arm of chromosome 19.     

High-resolution pachytene chromosome mapping of bacterial artificial chromosomes anchored by genetic markers reveals the centromere location and the distribution of genetic recombination along chromosome 10 of rice

Large-scale physical mapping has been a major challenge for plant geneticists due to the lack of techniques that are widely affordable and can be applied to different species. Here we present a physical map of rice chromosome 10 developed by fluorescence in situ hybridization (FISH) mapping of bacterial artificial chromosome (BAC) clones on meiotic pachytene chromosomes. This physical map is fully integrated with a genetic linkage map of rice chromosome 10 because each BAC clone is anchored by a genetically mapped restriction fragment length polymorphism marker. The pachytene chromosome-based FISH mapping shows a superior resolving power compared to the somatic metaphase chromosome-based methods. The telomere-centromere orientation of DNA clones separated by 40 kb can be resolved on early pachytene chromosomes. Genetic recombination is generally evenly distributed along rice chromosome 10. However, the highly heterochromatic short arm shows a lower recombination frequency than the largely euchromatic long arm. Suppression of recombination was found in the centromeric region, but the affected region is far smaller than those reported in wheat and barley. Our FISH mapping effort also revealed the precise genetic position of the centromere on chromosome 10.     

Comparative mapping of a region on chromosome 10 containing QTL for reproduction in swine

Several quantitative trait loci (QTL) for important reproductive traits (age of puberty, ovulation rate, nipple number and plasma FSH) have been identified on the long arm of porcine chromosome 10. Bi-directional chromosome painting has shown that this region is homologous to human chromosome 10p. Because few microsatellite or type I markers have been placed on SSC10, we wanted to increase the density of known ESTs mapped in this region of the porcine genome. Genes were chosen for their position on human chromosome 10, sequence availability from the TIGR pig gene indices, and their potential as a candidate gene. The PCR primers were designed to amplify across introns or 3'-UTR to maximize single nucleotide polymorphism (SNP) discovery. Parents of the mapping population (one sire and seven dams) were amplified and sequenced to find informative markers. The SNPs were genotyped using primer extension and mass spectrometry. These amplification products were also used to probe a BAC library (RPCI-44, Roswell Park Cancer Institute) for positive clones and screened for microsatellites. Six genes from human chromosome 10p (AKR1C2, PRKCQ, ITIH2, ATP5C1, PIP5K2A and GAD2) were mapped in the MARC swine mapping population. Gene order was conserved within these markers from centromere to telomere of porcine chromosome 10q, as compared with human chromosome 10p. Four of these genes (PIP5K2A, ITIH2, GAD2 and AKR1C2), which map under QTL, are potential candidate genes. Identification of porcine homologues near important QTL and development of a comparative map for this chromosome will allow further fine- mapping and positional cloning of candidate genes affecting reproductive traits.     

Analysis of complex Y chromosome aberrations using a single DNA probe (Y-367)

A specific cloned DNA sequence (Y-367) detects at least four loci in the euchromatic long arm and in the short arm of the human Y chromosome. Deletion mapping assigns one locus to the distal euchromatic long arm, another to a region close to the centromere on either Yq or Yp, and two additional loci to the Y short arm. Y-367 may thus be used for the rapid screening of even complex Y chromosome aberrations. This is exemplified in a 45,X male with Y chromosome material on the long arm of chromosome 10 by the detection of an inversion of a portion of Yp and by the confirmation of duplications and deletions in two individuals with duplications of part of the Y chromosome.     

Isolation of a new polymorphic TC maize microsatellite located on the long arm of chromosome 10

Simple sequence repeats (SSR), also called microsatellites, were previously proved to be an important class of DNA markers. The isolation, mapping and designing of primers to the flanking regions of a new maize SSR is reported. The new marker, with a core motif of (TC) 12, designated as MZETC34, was mapped to the long arm of chromosome 10.     

Retained heterodisomy for chromosome 12 in atypical lipomatous tumors: implications for ring chromosome formation

Atypical lipomatous tumor (ALT) is an intermediate malignant mesenchymal tumor that is characterized by supernumerary ring chromosomes and/or giant rod-shaped marker chromosomes (RGMC). Fluorescence in situ hybridization (FISH) and molecular genetic analyses have disclosed that the RGMCs always contain amplified sequences from the long arm of chromosome 12. Typically, RGMCs are the sole clonal changes and so far no deletions or other morphologic aberrations of the two normal-appearing chromosomes 12 that invariably are present have been detected. The mechanisms behind the formation of the RGMCs are unknown, but it could be hypothesized that RGMC formation is preceded by trisomy 12 or, alternatively, that ring formation of one chromosome 12 is followed by duplication of the remaining homolog. The latter scenario would always result in isodisomy for the two normal-appearing chromosomes 12, whereas the former would yield isodisomy in one-third of the cases. In order to investigate these possible mechanisms behind ring formation, we studied polymorphic loci on chromosome 12 in 14 cases of ALT showing one or more supernumerary ring chromosomes and few or no other clonal aberrations at cytogenetic analysis. The molecular genetic analyses showed that the tumor cells always retained both parental copies of chromosome 12, thus refuting the trisomy 12 and duplication hypotheses.     

The gene encoding human vimentin is located on the short arm of chromosome 10.

The gene for vimentin, an intermediate-filament protein, is growth regulated. We used Southern blot analysis and in situ chromosome hybridization to determine the location of the human vimentin gene. Our results show that there is only one copy of the vimentin gene and that it is located on the short arm of chromosome 10 (10pter-10q23) close to the interleukin-2 receptor gene, which is also growth regulated. In situ hybridization studies suggest that the most likely location of the vimentin gene is 10p13. Sequence similarities and homologies of human vimentin to other genes are presented.