A mitotically stable marker chromosome negative for whole chromosome libraries, centromere probes and chromosome specific telomere regions: a novel class of supernumerary marker chromosome?

A two year-old child presented with mild developmental delay. On karyotype analysis, a supernumerary small marker chromosome (SMC) was found in all cells examined. This SMC was approximately the size of an isochromosome 18p, being symmetrical with a central constriction. C-banding and silver staining were negative and FISH with all chromosome-specific paints, centromere probes and telomere probes showed no hybridization to the SMC; telomere repeat sequences were however present on both arms. Comparative genomic hybridization showed no amplification of any chromosome region. Flow sorting of the SMC and reverse painting onto normal metaphase spreads showed no hybridization to any chromosome, whereas reverse painting onto the patient's own metaphases showed hybridization to the SMC only. This SMC may thus represent either a complex amplicon of different genomic regions, or a multifold amplification of a very small region, with a neocentromere comprising an active kinetochore but no alphoid DNA. Prognostic implications for the proband were difficult to assess due to the absence of reports of similar marker chromosomes in the literature.     

Characteristics of βA chromosome haplotypes in Japanese

DNA polymorphism patterns linked to the ^A-globin gene were analyzed in healthy Japanese using four different restriction endonucleases. The chromosomes with the ^A-globin gene were mapped through an evaluation of the presence of seven different restriction sites (HincII 5 to ; HindIII in ^G and ^A; HincII in, and 3 to, ₁; AvaII in ; Bam-HI 3 to ). Among 36 chromosomes analyzed, 20 chromosomes had a haplotype of [+–––––+]. Among 55 individuals examined, 7 possessed a homozygous haplotye of [+–––––+]. All Japanese with the ^AT-globin gene had a subhaplotype of [–++–+] 5 to the -globin gene. Their major haplotypes were [–++–+–+] and [–++–++–]. It was expected that the presence of the ^AT-globin gene in Japanese may be deduced from subhaplotypes 5 to the -globin gene.     

Molecular characterization of “inverted” pericentromeric heterochromatin of chromosome 3

Summary Inversion of the pericentromeric region of human chromosome 3 [inv (3) (p11q11.2)] is a rare event. Initially, this inversion was identified with staining for Q-bands by fluorescence using quinacrine (QFQ) and later characterized with staining for C-bands by CBG technique. The molecular methods of fluorescence in situ hybridization (FISH) and AluI/Giemsa and TaqI/Giemsa techniques were utilized. The findings suggest that the variable band q11.2 on chromosome 3 contains alphoid DNA sequences, which appear to be similar to those identified by conventional methods in the centromeric region (band p11).     

Aberrations of chromosome 3. A marker of T-cell lymphomas?

Aberrations of chromosome occur in different malignancies, but they are more frequent in lymphoproliferative ones than in the others. In this study here four out of five T-zone lymphomas had abnormalities of chromosome 3. This lead to the question of whether aberrations of chromosome 3 might be a marker of T-cell lymphomas. The conclusion which can be drawn from the cases described in the literature, the own unpublished cases, and these four T-zone lymphomas is that abnormalities of chromosome 3 cannot be regarded as a discriminative marker of T-cell derived malignancies. It is suggested that the relationship between chromosome aberrations and type of disease is not necessarily a direct one. One possible model of the genesis of chromosome aberrations in malignant diseases is presented.     

cDNA sequence and chromosome localization of pig α1,3 galactosyltransferase

Human serum contains natural antibodies (NAb), which can bind to endothelial cell surface antigens of other mammals. This is believed to be the major initiating event in the process of hyperacute rejection of pig to primate xenografts. Recent work has implicated galoctosyl 1,3 galactosyl 1,4 N-acetyl-glucosaminyl carbohydrate epitopes, on the surface of pig endothelial cells as a major target of human natural antibodies. This epitope is made by a specific galactosyltransferase (1,3 GT) present in pigs but not in higher primates. We have now cloned and sequenced a full-length pig 1,3 GT cDNA. The predicted 371 amino acid protein sequence shares 85% and 76% identity with previously characterized cattle and mouse 1,3 GT protein sequences, respectively. By using fluorescence and isotopic in situ hybridization, the GGTA1 gene was mapped to the region q2.10–q2.11 of pig chromosome 1, providing further evidence of homology between the subterminal region of pig chromosome 1q and human chromosome 9q, which harbors the locus encoding the AB0 blood group system, as well as a human pseudogene homologous to the pig GGTA1 gene.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number L36152     

Assignment of ecto-5′-nucleotidase to human chromosome 6

Summary Ecto-5-nucleotidase activity (5NT) was measured on whole cells of 26 human x Chinese hamster hybrids. Concordance analysis showed 100% correlation between enzyme activity and inheritance of human chromosome 6. This observation was confirmed by a segregation analysis in which cells of a hybrid containing chromosome 6 were stained by indirect immunofluorescence for HLA Class 1 antigen and sorted by a fluorescence-activated cell sorter (FACS). Cells in the HLA^- compartment were cloned and expression of HLA and 5NT was determined. Of nine clones, three were HLA^-, 5NT^- and six were HLA⁺, 5NT⁺, supporting the linkage of 5NT to chromosome 6.     

Organization of the variant domains of α satellite DNA on human chromosome 21

The de novo creation of long, homogeneous, satellite DNA domains was postulated previously to occur by saltatory amplification. In this paper, pulsed field gel electrophoresis analysis of the α satellite DNA block organization of the human chromosome 21 supports this hypothesis. Double-dimension electrophoresis indicated that the variant copies of the basic α satellite repeat of chromosome 21 are organized in a single 3,150 Kblong domain. It was also established that the other satellite DNAs found in man (β, II, and III) are organized independently of the α satellite DNA block of the same chromosome. Presented at the NATO Advanced Research Workshop onGenome Organization and Evolution, Spetsai, Greece, 16–22 September 1992     

Linkage of prostate cancer susceptibility loci to chromosome 1

Three prostate cancer susceptibility genes have been reported to be linked to different regions on chromosome 1: HPC1 at 1q24-25, PCAP at 1q42-43, and CAPB at 1p36. Replication studies analyzing each of these regions have yielded inconsistent results. To evaluate linkage across this chromosome systematically, we performed multipoint linkage analyses with 50 microsatellite markers spanning chromosome 1 in 159 hereditary prostate cancer families (HPC), including 79 families analyzed in the original report describing HPC1 linkage. The highest lod scores for the complete dataset of 159 families were observed at 1q24-25 at which the parametric lod score assuming heterogeneity (hlod) was 2.54 (P=0.0006) with an allele sharing lod of 2.34 (P=0.001) at marker D1S413, although only weak evidence was observed in the 80 families not previously analyzed for this region (hlod=0.44, P=0.14, and allele sharing lod=0.67, P=0.08). In the complete data set, the evidence for linkage across this region was very broad, with allele sharing lod scores greater than 0.5 extending approximately 100 cM from 1p13 to 1q32, possibly indicating the presence of multiple susceptibility genes. Elsewhere on chromosome 1, some evidence of linkage was observed at 1q42-43, with a peak allele sharing lod of 0.56 (P=0.11) and hlod of 0.24 (P=0.25) at D1S235. For analysis of the CAPB locus at 1p36, we focused on six HPC families in our collection with a history of primary brain cancer; four of these families had positive linkage results at 1p36, with a peak allele sharing lod of 0.61 (P=0.09) and hlod of 0.39 (P=0.16) at D1S407 in all six families. These results are consistent with the heterogeneous nature of hereditary prostate cancer, and the existence of multiple loci on chromosome 1 for this disease.     

Are rice chromosomes components of a holocentric chromosome ancestor?

Comparative genomics reveals that cereal genomes are composed of similar genomic building blocks (linkage blocks). By stacking these blocks in a unique order, it is possible to construct a single ancestral chromosome which can be cleaved to give the basic structure of the 56 different chromosomes found in wheat, rice, maize, sorghum, millet and sugarcane. The borders of linkage blocks are defined by cereal centromeric and telomeric sites. However, a number of studies have shown that telomeric heterochromatin has neocentromeric activity, implying that linkage blocks are in fact defined by centromeric-like sites with conserved sequences. The structure of the ancestral cereal genome thus resembles a holocentric chromosome, which is the chromosome structure shared by the closest relatives of the Gramineae, the Cypericeae and Juncaceae.     

Characterisation of interstitial duplications and triplications of chromosome 15q11–q13

Chromosome 15 is frequently involved in the formation of structural rearrangements. We report the molecular characterisation of 16 independent interstitial duplications, including those of one individual who carried a duplication on both of her chromosomes 15, and three interstitial triplications of the Prader-Willi/Angelman syndrome critical region (PWACR). In all probands except one, the rearrangement was maternal in origin. In one family, the duplication was paternal in origin, yet appeared to segregate in a sibship of three with an abnormal phenotype that included developmental delay and a behavioural disorder. Ten duplications were familial, five de novo and one unknown. All 16 duplications, including two not visible by routine G-banding, were of an almost uniform size and shared the common deletion breakpoints of Prader-Willi syndrome and Angelman syndrome. Like deletions, the formation of duplications can occur in both male and female meiosis and involve both inter- and intrachromosomal events. This implies that at least some deletions and duplications are the reciprocal products of each other. We observed no instances of meiotic instability in the transmission of a duplication, although recombination within the PWACR occurred in two members of the same family between the normal and the duplicated chromosome 15 homologues. All three triplications arose de novo and included alleles from both maternal chromosomes 15. Triplication breakpoints were more variable and extended distally beyond the PWACR. The molecular characteristics of duplications and triplications suggest that they are formed by different mechanisms.     

Cosntruction of the physical map of yeast（Saccharomyces cerevisiae）chromosome V~1

There are about 17 chromosomes in yeast Saccharomycescerevisiae.A middle sized chromosome,chromosome V,waschosen in this work for studying and constructing the physi-cal maps.Chromosome V from strain A364a was isolatedby pulsed-field gradient gel electrophoresis(PFGE).Gelslices containing chromosome V DNA were digestedwith two rare cutting enzymes,NotⅠand SfiⅠ,and three6-Nt recognizing enzymes,SmaⅠ,SstⅡ and ApaⅠ.Several strategies-partial or complete digestions,digestion with different sets of two enzymes,and hybrid-ization with cloned genetically mapped probes(CAN1,URA3,CEN5,PRO3,CHO1,SUP19,RAD51,RAD3)——were used to align the restriction fragments.There are 9,9,15,17,and 20 sites for NotⅠ,SfiⅠ,SmaⅠ,SstⅡ and ApaⅠrespectively in the map of the A364a chromosome V.Itstotal length was calculated to be 620 Kb(Kilo-bases).Thedistributions of the cutting sites for these five enzymesthrough the whole chromosome are not uniform.A comp-arison between the physical map and the genetic map wasalso made.     

Genetic analysis of transgenome structure and size of chromosome—mediated gene transfer lines

The TK-selected chromosome-mediate gene transfer lines were analysed using DNA dot blot method G-11 banding and in situ hybridization.The results showed that CMGT can provide a wide variety of intermediate size of the transgenome from greater than 80,000kb to less than 2,000kb,Some of transfectants are intergrated into mouse chromosome which can be detected by G-11 banding and in situ hybridization.     

Chromosome-specific α-satellite DNA from the centromere of chimpanzee chromosome 4

The centromeric regions of human and primate chromosomes are characterized by diverged subsets of tandemly repeated α-satellite DNA. Comparison of the α-satellites on known homologous chromosomes in human and chimpanzee provides insight into the very rapid evolution of satellite DNA sequences and the mechanisms that shape complex genomes. By using oligonucleotide primers specific for a conserved region of human α-satellite DNA, we have amplified a chromosome-specific α-satellite subset from the chimpanzee genome by the polymerase chain reaction. Fluorescence in situ hybridization showed that clones pαPTR4N and pαPTR4H are homologous to sequences at the centromere of the chimpanzee chromosome 4. This α-satellite subset is organized as a series of pentameric (higher-order) repeats, operationally defined by digestion of genomic DNA with HaeIII, MboI, RsaI, SstI, and XbaI. The lengths of four independent centromeric arrays measured by pulsed-field gel electrophoresis varied between 800 and 3,500 kb (mean = 1,850 kb, SD = 1,000 kb). Nucleotide sequence analysis demonstrated that chimpanzee chromosome 4 α-satellite is most closely related to the suprachromosomal subfamily II, which is evolutionarily different from the subfamily I to which the α-satellite on the homologous human chromosome 5 belongs. This implies that the human-chimpanzee sequence divergence has not arisen from a common ancestral α-satellite repeat(s) but instead represents concerted evolution of distinct repeats on homologous chromosomes. Received: 21 February 1997; in revised form: 26 February 1997 / Accepted: 27 February 1997     

Y chromosome—a tool in infertility studies of Latvian population

Human Y chromosome is used as a tool in male infertility and population genetic studies. The aims of this research were to analyse the prevalence of Y chromosome microdeletions among infertile Latvian men, and to identify possible lineages of Y chromosome that may be at increased risk of developing infertility. A study encompassed 105 infertile men with different spermatogenic disturbances. Deletions on Y chromosome were detected in 5 out of 105 (∼5%) cases analysed in this study. Three of them carried deletion in AZFc region and two individuals had AZFa+b+c deletion. Study of Y chromosome haplogroups showed that N3a1 and R1a1 lineages were found less frequently in the infertile male group compared to ethnic Latvian group, however K* cluster was predominantly found in infertile male Y chromosomes. Conclusions: (1) Our study advocates running Y chromosome microdeletion analyses only in cases of severe form of infertility; (2) Ychromosome haplogroup analysis showed statistically significant tendencies that some haplogroups are more common in ethnic male group, but others are more common in infertile males.     

Assignment of the gene for carboxypeptidase A to human chromosome 7q22→qter and to mouse chromosome 6

Summary A rat cDNA probe for preprocarboxypeptidase A was used to follow the segregation of the human gene for carboxypeptidase A (CPA) in 49 human x mouse somatic cell hybrids using Southern filter hybridization techniques. CPA was assigned to human chromosome 7q22qter. Similarly, the probe was used to follow the segregation of the mouse gene for carboxypeptidase A (Cpa) in 19 mouse x Chinese hamster somatic cell hybrids. Cpa was assigned to mouse chromosome 6. The gene for carboxypeptidase A forms part of a syntenic group that is conserved in man and mouse.Preliminary chromosomal assignments of carboxypeptidase A in man and mouse have been made in abstract (Honey et al. 1983a, b)     

Meiosis in haploid barley — An interpretation of non-homologous chromosome associations

Detailed meiotic studies were conducted on ten haploid plants representing six different genotypes of barley (Hordeum vulgare, 2n=14). At pachytene stages the non-homologous chromosomes were observed to pair as intimately as homologous chromosomes in many cells. Foldback pairing, involving single chromosomes, and multivalent associations were common. At diplotene, up to 4 chiasmatalike structures were observed in paired chromosomes but it is not likely that they resulted from crossing over. At diakinesis the bivalent frequency mean was from 1 to 1.3 per cell whereas by metaphase I the paired associations were rare with a single rod bivalent being observed in 3 to 5% of the cells. The frequencies of various types of secondary associations at metaphase were also recorded. — The origin and significance of bivalents and secondary associations in haploids is reviewed and discussed. Caution is urged in the interpretation that low levels of chromosome pairing in haploids is evidence of homology. It is concluded that very little chromosome duplication is likely to be found within the haploid set of barley chromosomes and that the basic chromosome number is seven.     

Pericentric inversions of chromosome number 9: benign or harmful?

Pericentric inversions of chromosome number 9 have been studied in 4 different probands: a normal female with designation 46,XX,inv(9)(p12q13); a male with Down syndrome designated as 47,XY,+21,inv(9))p13q13); a premature infant with multiple, congenital malformations who was 46,XX,inv(9)(p12q21), and a Down syndrome proband with 47,XYqs,+21,inv(9)(p13q21). All 4 cases were shown to be inherited based on family studies. These families are discussed with reference to the literature as to what possible effect this structural change could have on the reproductive capability of a normal carrier and what guidelines are available for counseling such a carrier.