Localization of human gene loci using spontaneous chromosome rearrangements in human-Chinese hamster somatic cell hybrids.

Analysis of human-Chinese hamster somatic cell hybrids with spontaneously derived chromosome structural changes has provided data for the regional and subregional localization of gene loci which have previously been assigned to human chromosomes 2, 12, and X. Correlation of the expression of human gene loci with the human chromosome complements present in somatic cell hybrids indicates that the cytoplasmic malate dehydrogenase (MDH1) locus is in the 2p23yields2pter region, and red cell acid phosphatase (AcP1) is at or adjacent to 2p23. The cytoplasmic isocitrate dehydrogenase (IDH1) locus is at or adjacent to 2q11, peptidase B (Pep B) is at or adjacent to 12q21, lactate dehydrogenase B (LDH B) is in the 12q21yiedls12pter region, glucose-6-phosphate dehydrogenase (G6PD) is in the Xq24yieldsXqter region, and the gene loci for phosphoglycerate kinase (PGK), alpha-galactosidase (alpha-gal), and hypoxanthine guanine phosphoribosyltransferase (GPRT) are in the Xp21yieldsXq24 region.     

Inherited pericentric inversion of chromosome no. 2 with Robertsonian translocation (13q 14q) resulting in trisomy for chromosome 13q

This report includes a patient with an inherited pericentric inversion of chromosome No. 2 in addition to a Robertsonian translocation resulting in trisomy for chromosome 13q. The chromosomal constitution of the proband was 46,XX,inv(2) (pter leads to p11 : : q14 leads to p11 : : q14 leads to qter); t(13,14) (13qter leads to 13p11 : : 14q11 leads to 14qter). Sequential QFQ, RFA and GTG banding techniques were employed on the chromosomes of all family members. The chromosomal constitutions of the father and his first child were normal while the mother had an inversion of chromosome No. 2 [46,XX,inv(2) (pter leads to p11 : : q14 leads to p11 : : q14 leads to qter)]. The proband inherited this abnormal chromosome. In addition, she had a de novo Robertsonian translocation involving chromosomes 13q and 14q resulting in trisomy of chromosome 13q.     

Introduction of new genetic markers on human chromosomes

The purpose of this study was to use DNA transfection and microcell chromosome transfer techniques to engineer a human chromosome containing multiple biochemical markers for which selectable growth conditions exist. The starting chromosome was a t(X;3)(3pter----3p12::Xq26----Xpter) chromosome from a reciprocal translocation in the normal human fibroblast cell line GM0439. This chromosome was transferred to a HPRT (hypoxanthine phosphoribosyltransferase)-deficient mouse A9 cell line by microcell fusion and selected under growth conditions (HAT medium) for the HPRT gene on the human t(X;3) chromosome. A resultant HAT-resistant cell line (A9(GM0439)-1) contained a single human t(X;3) chromosome. In order to introduce a second selectable genetic marker to the t(X;3) chromosome, A9(GM0439)-1 cells were transfected with pcDneo plasmid DNA. Colonies resistant to both G418 and HAT medium (G418r/HATr) were selected. To obtain A9 cells that contained a t(X;3) chromosome with an integrated neo gene, the microcell transfer step was repeated and doubly resistant cells were selected. G418r/HATr colonies arose at a frequently of 0.09 to 0.23 x 10(-6) per recipient cell. Of seven primary microcell hybrid clones, four yielded G418r/HATr clones at a detectable frequency (0.09 to 3.4 x 10(-6)) after a second round of microcell transfer. Doubly resistant cells were not observed after microcell chromosome transfers from three clones, presumably because the markers were on different chromosomes. The secondary G418r/HATr microcell hybrids contained at least one copy of the human t(X;3) chromosome and in situ hybridization with one of these clones confirmed the presence of a neo-tagged t(X;3) human chromosome. These results demonstrate that microcell chromosome transfer can be used to select chromosomes containing multiple markers.     

A human gene that restores the DNA-repair defect in SCID mice is located on 8p11.1→q11.1

In order to map the gene that is responsible for the DNA-repair defect in severe combined immune deficient (SCID) mice, a mixture of microcells independently isolated from mouse A9 cells containing pSV2neo-tagged human chromosomes 5, 7, 8, 9, 11, 15, 18 or 20 were fused with SCID fibroblast cell lines SCVA2 and SCVA4, which were originally established from lung tissue of the C.B.17-scid/scid mouse by SV40 virus transfection. After irradiation with ⁶⁰Co -rays and selection with antibiotic G418, 12 independent clones were obtained, of which 4 contained an intact chromosome 8, 3 clones contained a deleted chromosome 8 [del(8)q22qter or del(8)q23 qter] and remaining 5 had no detectable or specific human chromosome. We further independently transferred a single human chromosome 8 or 11 into the SCVA cells via microcell fusion, and examined the radiation sensitivity of the microcell hybrids. Complementation of the radiation sensitivity was correlated with the presence of human chromosome 8 in microcell hybirds, whereas no correlation was observed in clones following the transfer of human chromosome 11. Thus, the results indicate that human chromosome 8 restored high sensitivity to ionizing radiation. A number of subclones that were radiation resistant or sensitive were isolated from the microcell hybrids. The concordance of the radiation sensitivity with the presence or absence of specific DNA fragments on chromosome 8 indicates that the human gene is located on the centromeric region of chromosome 8, i.e., 8p11.1 q11.1.     

A new type of inversion of a human Y chromosome.

Using chromosome banding techniques, a phenotypically normal male was found to have an abnormal banding pattern of the Y chromosome. By the constitutive heterochromatin staining method, a darkly stained band was located on the short arm and the proximal region of the long arm. The quinacrine staining method also showed a similar abnormal banding pattern: a brightly fluorescing band was seen on the short arm and the proximal region of the long arm. By the conventional Giemsa staining method, however, no specific morphological abnormality was detected in the aberrant Y. On detailed karyotype analyses no recognizable abnormality of banding patterns of any other chromosome was found aside from the abnormal Y. The abnormality was determined to be a complex inversion of the Y chromosome, which is described as 46,X,inv(Y)(pter leads to p11::q11 leads to q12::cen::q12 leads to qter).     

Multiple cytogenetic methods used to identify a new structural rearrangement of the human X chromosome.

A woman with primary amenorrhea and pure gonadal dysgenesis had two cytogenetically abnormal cell lines. The karyotype was 45,X in 56--95% of mitosis from lymphocytes and skin fibroblasts. In the remaining 5--44% of the cells there was, in addition to a normal X, a structurally abnormal X chromosome interpretable as pter leads to q21::q11 leads to pter or pter leads to q21::q13 leads to pter. The abnormal X chromosome was heterocyclic and had a normal centromere plus an extra C band in the long arm. Detailed interpretation of the structural rearrangements of this chromosome required the use of both Q-, G-, and C-banding and the BrdU-Hoechst 33258 technique.     

Inactivation centers in the human X chromosome.

Reported cases with a structurally abnormal X chromosome were compiled. These included 17 balanced and 26 unbalanced X-autosome translocations, each with inactivation of either a derivative X or a derivative of any of the autosomes. A further 52 cases with various structural rearrangements were studied. The shortest late-replicating segment in each arm pter leads to p21 and q13 leads to qter. In both cases, they were detected in all or most metaphases, thus making the results convincing. In one case, the distal part of Xq, q25 or 26 leads to qter was probably inactivated in a small proportion of the cells. It appears reasonable to assume that the former two segments and probably also the third include an "inactivation center(s)." In a male with a 46,Y,dup(X)(q13q22), no part of dup X replicated late although it contained extra chromosome material.     

An expressed β-tubulin gene, TUBB, is located on the short arm of human chromosome 6 and two related sequences are dispersed on chromosomes 8 and 13

The chromosomal assignments of an expressed β-tubulin gene and two related sequences have been determined by Southern blot analysis of DNA from a panel of human X Chinese hamster somatic cell hybrids cleaved with Hind III or EcoR I. Probes containing the 3′ untranslated regions of the expressed gene M40 and of pseudogene 21β were used to localize the M40 sequence (gene symbol TUBB) to chromosome 6 region 6p21 → 6pter, the 21β pseudogene (TUBBP1) to chromosome 8 region 8q21 → 8pter and a third related sequence (TUBBP2) to chromosome 13. Asynteny of expressed genes and related processed pseudogenes has now been demonstrated for several gene families.     

Genetics of cell-surface antigens: regional mapping of three components of the human cell-surface antigen complex, AL, on chromosome 11

Cytogenetic analysis has been performed on a series of deletion mutations on human chromosome 11 of AL hybrid clones in which specific markers have been lost as a result of treatment with mutagenic agents. Such analysis has localized the three previously identified components of the AL cell-surface antigen complex to the indicated regions of chromosome 11: a1 and a3:11p13 leads to 11pter; a2:11q13 leads to 11qter. Using these methodologies human lactic dehydrogenase A localization on the short arm as reported by others has been confirmed. Evidence is presented provisionally assigning this gene to 11p13 leads to 11pter.     

复杂染色体重排的女性携带者与她健康的女儿

一例新生复杂染色体重排的女性携带者（complex chromosome rearrangement ,CCR）,易位涉及1号、5号和12号染色体。病人因2次自然流产而要求进行外周血淋巴细胞G显带核型分析。最初G显带核型疑为46,XX,t(1;5;12)(1pter→1q25::12q24→12qter;5qter→5p11::1q25→1qter;12pter→12q24::5p11→5pter).经荧光原位杂交（FISH）技术检测,证实患者的核型为46,XX,t(1;5;12)(1pter→1q23::12q22→12qter;5qter→5p11::1q25→1qter;12pter→12q22::1q23→1q25::5p11→5pter).7年后病人再次妊娠,并拒绝产前诊断。女婴足月分娩,生长发育正常。核型为46,XX。比较以前报告的女性复杂易位携带者与我们报告的病例可以认为,CCR并不总是表现为自然流产或分娩畸形儿,仍有机会生出正常的孩子。Abstract: We reported in the paper one case of a de novo complex chromosomal rearrangement (CCR) involving three different chromosomes,1, 5 and 12. Two pregnancies of the female carrier over three years resulted in two spontaneous abortions. Initial cytogenetic analysis of her peripheral lymphocyte by G banding suspected a karyotype 46,XX,t(1;5;12)(1pter →1q25::12q24→12qter;5qter→ 5p11::1q25→1qter;12pter →12q24::5p11→5pter). Fluorescense in -situ hybridization (FISH) was used to confirm the karyotype 46,XX,t(1;5;12)(1pter→1q23::12q22→12qter;5qter→5p11::1q25→1qter;12pter→12q22::1q23→1q25::5p11→5pter). Seven years later she was pregnant again and refused to have prenatal diagnosis. The fetus is normal both in phenotype and karyotype。Comparing previously reported female CCR carriers with the case, we conclude that female CCR carriers may not always present spontaneous abortion or have offspring with congenital malformation and can have chance to get a healthy child.     

A complex mosaicism 45,X/46,X,del(Xq)/46,X,idic(Xq) in a patient with secondary amenorrhea

A complex mosaicism involving the X chromosome was found in a 35-year-old female affected by secondary amenorrhea and short stature. Her karyotype was: 45,X[20]/46,X,del(X)(pter-->q26::qter)[15]/46,X,idic(X)(pter-->q26::q26-->pter)[9]. No cell contained both abnormal X chromosomes. This observation would suggest a possible mechanism underlying the formation of isodicentric chromosomes.     

A de novo (1;2;3;15;18) chromosome rearrangement with six nonreciprocal translocations

A de novo complex chromosome rearrangement (CCR) found in a phenotypically abnormal boy was characterized by G-bands, FISH with subtelomere probes, and M-FISH. The G-banding analysis revealed involvement of chromosomes 1, 2, 3, 15, and 18 with (at least) eight breakpoints, five nonreciprocal translocations (1q --> 2q --> 8q --> 15q --> 2p --> 1q), and a 3p insertion into the der(2); there was also a presumptive deletion of 1q41. The 5 derivatives were described as follows: der(1)(1pter --> 1q32.3?::2p21--> 2pter),der(2)(1qter --> 1q42?::2q24.2 --> 2p21::3p13 --> 3p26::15q15 --> 15qter),der(3)(3qter --> 3p13:),der(15)(15pter --> 15q15::18q11 --> 18qter),der(18)(18pter --> 18q11::2q24.2 --> 2qter). The molecular assays confirmed the segmental composition of each derivative and documented the localization of most relevant telomeres. In addition to the novelty of the 1, 2, 3, 15 and 18 combination, this CCR may also be unique in the sense that it represents a cluster of 6 nonreciprocal transpositions regardless of the occurrence (or lack thereof) of secondary unbalances. Finally, there appears to be an excess of CCRs in fetuses conceived by intracytoplasmic sperm injection.     

Double autosomal aberration: trisomy 21 and familial reciprocal translocation t(10;12)(p14;q21)]

A child with the Down syndrome revealed besides a regular trisomy 21, an enlargment of the short arm of chromosome 10, and the deletion of the long arm of chromosome 12. The proband's mother, who was phenothypically normal woman, appeared to be a carrier of the reciprocal translocation, her karyotype being: 46, XX, rep (10;12) (10qter leads to leads to 10p14; 12q21 leads to 12qter; 12pter leads to 12q21 : 10p14 leads to 10pter). Hence, the proband had double chromosomal aberration 47, XX, +21, rcp (10; 12) (10qter leads to 10p14 : 12q21 leads to leads to 12qter; 12pter leads to 12q21 : 10p14 leads to 10pter) mat. There is no reason to relate hard manifistation of the Down syndrome with the detected translocation. The influence of the mathernal non-devision in the meiosis and the rise of the trisomy 21 is discussed. In the following pregnancies it is advisable to amniocentesis.     

Mapping of the human gene for epidermal growth factor receptor (EGFR) on the p13 leads to q22 region of chromosome 7

We previously reported that the structural gene for epidermal growth factor receptor (EGFR) can be mapped to the p22 leads to qter region of human chromosome 7 (Shimizu et al., 1979, 1980). In the present study, we produced two series of human-mouse cell hybrids by fusing mouse A9 cells that are deficient in EGFR with the human diploid fibroblast lines GM1356, 46,XX,t(1;7)(p34;p13), and GM2068, 46,XX,t(6;7)(q27;q22), both of which possess EGF receptors. Expression of EGF binding ability in the former series of cell hybrids was correlated with the retention of the human translocation chromosome containing the 7p13 leads to qter region, and in the latter series of cell hybrid it was correlated with the retention of the human translocation chromosome containing the 7pter leads to q22 region. Therefore, the EGFR gene can be localized in the p13 leads to q22 region of chromosome 7.     

Relationship of the human protooncogene CBL2 on 11q23 to the t(4;11), t(11;22), and t(11;14) breakpoints

A probe identifying CBL2, the human cellular homolog of the murine oncogene v-cbl and murine cellular protooncogene Cbl-2, and panels of rodent X human somatic cell hybrids were used to study the relationship of this protooncogene to translocations associated with acute leukemia, lymphoma, and Ewing sarcoma. CBL2 was mapped to 11q23 and found to translocate from chromosome 11 to 4 in an acute leukemia cell line possessing a t(4;11)(q21;q23) and from chromosome 11 to 14 in a B-cell lymphoma with a t(11;14)(q23;q32). In an Ewing sarcoma cell line with a t(11;22)(q23;q12), however, CBL2 remained on chromosome 11. Additional studies of other genes in the region of 11q23 allowed the following ordering of these genes and breakpoints: 11cen--q23--NCAM--CD3(E-D-G)--[t(11;14), t(4;11)]--(THY1, CBL2, ETS1)--t(11;22)--11qter. The gross structure of the CBL2 sequences examined was not altered by either of the flanking breakpoints. Given that the 5' and 3' ends of the CBL2 gene are not known and are probably not evaluated by the v-cbl probe, these results do not rule out the possibility of CBL2 involvement in the pathogenesis of a subset of acute leukemias possessing a t(4;11), B-cell lymphomas possessing a t(11;14), or Ewing sarcomas possessing a t(11;22).     

Isolation of a new cDNA clone encoding an Rh polypeptide associated with the Rh blood group system

We searched for a human chromosome that would restore the cholesterol metabolism in 3T3 cell lines (SPM-3T3) derived from homozygous sphingomyelinosis mice (spm/spm). Mouse A9 cells containing a single copy of pSV2neo-tagged chromosomes 9, 11, or 18 derived from normal human fibroblasts served as donor cells for transfer of human chromosomes. Purified A9 microcells were fused with SPM-3T3 cells, and the microcell hybrids were selected in medium containing G418 antibiotics. The microcell hybrids that contained human chromosomes 9, 11, or 18 in a majority of cells were examined. The accumulation of intracellular cholesterol in the microcell hybrids containing a chromosome 18 decreased markedly, whereas in the microcell hybrids containing either chromosomes 9 or 11 it was similar to that in SPM3T3 cells. The SPM-3T3 cells with an intact chromosome 18 were further passaged and subcloned. Clones which again accumulated intracellular cholesterol had concurrently lost the introduced chromosome 18. The abnormal accumulation was associated with a decrement in the esterification of exogenous cholesterol. These findings suggest that the gene responsible for the abnormal cholesterol metabolism in the spm/spm mice can be restored by a hu man chromosome 18. The gene was tentatively mapped on 18pter18p11.3 or 18q21.3qter that was lost during subcloning, thereby resulting in reaccumulation of the intracellular cholesterol.     

Localization of the Fanconi anemia complementation group D gene to a 200-kb region on chromosome 3p25.3

Fanconi anemia (FA) is a rare autosomal recessive disease manifested by bone-marrow failure and an elevated incidence of cancer. Cells taken from patients exhibit spontaneous chromosomal breaks and rearrangements. These breaks and rearrangements are greatly elevated by treatment of FA cells with the use of DNA cross-linking agents. The FA complementation group D gene (FANCD) has previously been localized to chromosome 3p22-26, by use of microcell-mediated chromosome transfer. Here we describe the use of noncomplemented microcell hybrids to identify small overlapping deletions that narrow the FANCD critical region. A 1.2-Mb bacterial-artificial-chromosome (BAC)/P1 contig was constructed, bounded by the marker D3S3691 distally and by the gene ATP2B2 proximally. The contig contains at least 36 genes, including the oxytocin receptor (OXTR), hOGG1, the von Hippel-Lindau tumor-suppressor gene (VHL), and IRAK-2. Both hOGG1 and IRAK-2 were excluded as candidates for FANCD. BACs were then used as probes for FISH analyses, to map the extent of the deletions in four of the noncomplemented microcell hybrid cell lines. A narrow region of common overlapping deletions limits the FANCD critical region to approximately 200 kb. The three candidate genes in this region are TIGR-A004X28, SGC34603, and AA609512.     

Introduction of Chromosome 7 Suppresses Telomerase with Shortening of Telomeres in a Human Mesothelial Cell Line

Introduction of human chromosome 7 by microcell-mediated chromosome transfer induced senescence in a telomerase-positive human mesothelial cell line, MeT5A. In microcell hybrids which underwent senescence, telomerase activity was decreased before entering senescence and telomeric sequences were shortened as cell division proceeded. Concomitantly, expression of the gene encoding telomerase catalytic subunit was abolished, whereas the genes encoding the RNA component of telomerase and its associated protein TEP1 were not affected. In revertants which arose from such microcell hybrids, telomerase activity was restored and the telomeric sequences were elongated. In microcell hybrids which showed no growth arrest, telomerase activity was unaltered. These results suggest that a putative mortality gene on chromosome 7 negatively regulates the telomere maintenance mechanism in MeT5A.     

Regional asssignments of the loci AK3, ACONS, and ASS on human chromosome 9.

Experiments are described in which human cells carrying balanced reciprocal translocations involving four different regions of chromosome 9 were fused with a Chinese hamster cell line and the resulting hybrids used to obtain subchromosomal assignments of the loci ASS, AK3, and ACONS. ASS was localized on the distal portion of the long arm of chromosome 9, in the region 9q34 leads to 9qter, and AK3 and ACONS on the short arm, in the region 9pter leads to 9p13.     

Human chromosome 11 complements ataxia-telangiectasia cells but does not complement the defect in AT-like Chinese hamster cell mutants

It has been shown that the X-ray-sensitive Chinese hamster V79 mutants (V-E5, V-C4 and V-G8) are similar to ataxia-telangiectasia (A-T) cells. To determine whether the AT-like rodent cell mutants are defective in the gene homologous to A-T (group A, C or D), human chromosome 11 was introduced to the V-E5 and V-G8 mutant cells by microcell-mediated chromosome transfer. Forty independent hybrid clones were obtained in which the presence of chromosome 11 was determined by in situ hybridization. The presence of the region of chromosome 11q22–23 was shown by molecular analysis using polymorphic DNA markers specific for the ATA, ATC and ATD loci. Seventeen of the obtained monochromosomal Chinese hamster hybrids contained a cytogenetically normal human chromosome 11, but only twelve hybrid cell lines were shown to contain an intact 11q22–23 region. Despite the complementation of the X-ray sensitivity by a normal chromosome 11 introduced to A-T cells (complementation group D), these twelve Chinese hamster hybrid clones showed lack of complementation of X-ray and streptonigrin hypersensitivity. The observed lack of complementation does not seem to be attributable to hypermethylation of the human chromosome 11 in the rodent cell background, since 5-azacytidine treatment had no effect on the streptonigrin hypersensitivity of the hybrid cell lines. These results indicate that the gene defective in the AT-like rodent cell mutants is not homologous to the ATA, ATC or ATD genes and that the human gene complementing the defect in the AT-like mutants seems not to be located on human chromosome 11.