Precise localization of human beta-globin gene complex on chromosome 11

Isolation of polymorphic DNA fragments from human chromosome 4

We have identified and characterized 40 DNA probes detecting restriction fragment length polymorphism (RFLP) on human chromosome 4. Single copy human clones were isolated from a bacteriophage library enriched for chromosome 4 sequences. Each clone was hybridized to somatic cell hybrid DNAs for verification of its species and chromosomal origin and for regional localization. Sequences specific for chromosome 4 were tested for their ability to detect RFLPs in human DNA and their potential utility as genetic markers was assessed. Approximately 263,000 base pairs or 0.13% of the chromosome was screened for sequence variation. The estimate of heterozygosity calculated from this large body of data, H = 0.0021, indicates that the degree of sequence variation on chromosome 4 is comparable to other autosomes. The characterization of these 40 markers has tripled the number of polymorphic loci available for linkage studies on chromosome 4, making it feasible to begin construction of a detailed linkage map that will span the entire chromosome.

Overabundance of rare-cutting restriction endonuclease sites in the human genome

A human chromosome 3-specific cosmid library was constructed from a somatic cell hybrid containing human chromosome 3 as its only human component. This library was screened to identify 230 human recombinants which contained an average insert size of 37 kilobases. DNA prepared from 54 of these cosmids, representing 2000 kilobases of human DNA, was then tested for restriction endonuclease sites for EcoRI, HindIII, KpnI, XhoI, and DraI, as well as those of the rare-cutting restriction endonucleases NotI, SfiI, NruI, MluI, SacII, and BssHII. Sites for the latter enzymes were much more abundant than would be expected from theoretical calculations, reflecting non-random clustering of these sites. This has important implications for the use of these enzymes in the construction of physical maps of chromosomes. Some individual cosmids contained large numbers of rare sites, offering an alternative means of physically mapping chromosomes based upon identifying clusters of rare restriction sites. These clusters appear to be spaced an average of 1000 kb apart.

Regional localization of DNA probes on the short arm of chromosome 11 using aniridia-Wilms' tumor-associated deletions

We are interested in the precise localization of various DNA probes on the short arm of chromosome 11 for our research on the aniridia-Wilms' tumor association (AWTA), assigned to region 11p13 (Knudson and Strong 1972; Riccardi et al. 1978). For this purpose we have screened lymphocyte DNA and material derived from somatic cell hybrids from individuals with constitutional 11p deletions with a range of available probes: D11S12; calcitonin/CGRP (CALC1/CALC2); insulin (INS); Harvey ras 1 (HRAS 1); beta-globin gene cluster (HBBC); human insulin-like growth factor 2 (IGF-2); parathyroid hormone (PTH); human pepsinogen A (PGA). Using this material, it has been possible to map all probes used, except insulin, outside the region 11p111-p15.1, resulting in an SRO (same regional overlap) of 11p15.1-p15.5 for most probes. We found an SRO for PGA of 11p111-q12 and an SRO for CALC2 of 11p15.1-p15.5 or 11p111-q12. We have localised the insulin gene to band 11p15.1.

Epidermal growth factor receptor gene-amplified MDA-468 breast cancer cell line and its nonamplified variants

We have recently reported (J. Filmus, M. N. Pollak, R. Cailleau, and R. N. Buick, Biochem. Biophys. Res. Commun. 128:898-905, 1985) that MDA-468, a human breast cancer cell line with a high number of epidermal growth factor (EGF) receptors, has an amplified EGF receptor gene and is growth inhibited in vitro pharmacological doses of EGF. We have derived several MDA-468 clonal variants which are resistant to EGF-induced growth inhibition. These clones had a number of EGF receptors, similar to normal human fibroblasts, and had lost the EGF receptor gene amplification. Karyotype analysis showed that MDA-468 cells had an abnormally banded region (ABR) in chromosome 7p which was not present in the variants. It was shown by in situ hybridization that the amplified EGF receptor sequences were located in that chromosome, 7pABR. Five of the six variants studied were able to generate tumors in nude mice, but their growth rate was significantly lower than that of tumors derived from the parental cell line. The variant that was unable to produce tumors was found to be uniquely dependent on EGF for growth in soft agar.

Molecular and physical arrangements of human DNA in HRAS1-selected, chromosome-mediated transfectants

We used mitotic chromosomes isolated from a human EJ bladder carcinoma cell line for morphological transformation of mouse C127 cells. These chromosome-mediated transformants were analyzed for cotransfer of markers syntenic with c-Ha-ras-1 on human chromosome 11. We also used cloned, dispersed human DNA repeats, in a general mapping strategy, to quantitate the amounts and molecular state of human DNA transferred along with the activated c-Ha-ras-1 gene. In situ hybridization was used to visualize the physical state of the transfected human chromatin. The combined use of these various techniques revealed the occurrence of both chromosomal and DNA rearrangements. However, our analysis also demonstrated that, in general, very substantial lengths of DNA are transferred intact. Closely linked markers are likely to cosegregate. Therefore, these transformants should be invaluable sources for the complete molecular cloning of isolated fragments of the short arm of human chromosome 11.

Localization of the LDHA gene to 11p14----11p15 by in situ hybridization of an LDHA cDNA probe to two translocations with breakpoints in 11p13

Lymphoblastoid cell lines established from two individuals with apparently balanced translocations involving 11p13 were used for LDHA regional localization. The karyotypes were 46,XY,t(4;11)(q21;p13) and 46,XY,t(1;11)(p22;p13). In situ hybridization of a human LDHA cDNA probe to chromosome preparations from these cell lines resulted in specific labeling over bands p14----p15 of the normal chromosomes 11 and over bands 11p14----11p15 of the derivative chromosomes 4 and 1. These results exclude LDHA from any region proximal to 11p13 and localize the gene to 11p14----11p15.

Parasexual approaches to the study of human genetic disease

We have used two different strategies to construct hybrid cells in which specific, individual human chromosomes or fragments thereof are maintained by direct selective pressure. Our first approach was to introduce a drug-resistance gene into human chromosomes using a retroviral vector, and to transfer the marked chromosomes via microcells into mouse cells. The second method was to fuse gamma-irradiated human cells with rodent cells to produce hybrids containing fragments of the human X chromosome. Such hybrid cell lines should greatly facilitate both human gene mapping and the isolation of human genes by molecular cloning. The gene-transfer technologies described here can also be used to construct cell lines in which the expression of genes involved in human diseases can be studied in vitro.

Investigation of gyrate atrophy using a cDNA clone for human ornithine aminotransferase

Gyrate atrophy of the choroid and retina is an autosomal recessive disease associated with reduced or absent ornithine aminotransferase (OAT) activity. To approach the defect in OAT at the molecular level, we have cloned a cDNA for the mRNA encoding the OAT precursor from human liver. The clone contains the complete coding region of 1317 nucleotides along with 44 nucleotides of 5' and 654 nucleotides of 3' untranslated sequences. When used to probe genomic DNA, the OAT cDNA did not detect any evidence of gene deletion or rearrangement in patients with gyrate atrophy. The cDNA hybridizes to a 2.15-kb RNA species in liver, fibroblasts, and lymphoblasts. The size and approximate amount of this mRNA is not altered in fibroblasts and/or lymphoblasts of seven gyrate atrophy patients who display a 25- to 100-fold reduction in OAT activity. Our results suggest the defect in these individuals may be caused by a subtle sequence alteration in the mRNA that does not affect its apparent size.

Chromosomal assignment of the human erythropoietin gene and its DNA polymorphism

Erythropoietin (EPO), a glycoprotein hormone, is the major physiological regulator of erythrocyte production in mammals. A cDNA clone containing the entire human EPO-coding region was used for Southern blot analysis of a series of human-Chinese hamster somatic cell hybrids containing different combinations of human chromosomes. Synteny analysis revealed 100% concordance between the EPO gene and human chromosome 7. Further localization to the region q11-q22 was accomplished by in situ hybridization of 3H-labeled human EPO cDNA to metaphase chromosomes prepared from both human lymphocytes and the cell hybrid 879-2a that contained human chromosomes 5, 7, 9, 12, and 21. In addition, restriction fragment length polymorphisms were detected at a frequency of approximately 20% in a Chinese population using restriction enzymes either HindIII or HinfI. These polymorphisms were inherited in a Mendelian fashion. Thus, the EPO marker is reasonably polymorphic and should be useful in linkage analysis with other genetic markers on chromosome 7, including the locus for cystic fibrosis.

Molecular and physical arrangements of human DNA in HRAS1-selected, chromosome-mediated transfectants

We used mitotic chromosomes isolated from a human EJ bladder carcinoma cell line for morphological transformation of mouse C127 cells. These chromosome-mediated transformants were analyzed for cotransfer of markers syntenic with c-Ha-ras-1 on human chromosome 11. We also used cloned, dispersed human DNA repeats, in a general mapping strategy, to quantitate the amounts and molecular state of human DNA transferred along with the activated c-Ha-ras-1 gene. In situ hybridization was used to visualize the physical state of the transfected human chromatin. The combined use of these various techniques revealed the occurrence of both chromosomal and DNA rearrangements. However, our analysis also demonstrated that, in general, very substantial lengths of DNA are transferred intact. Closely linked markers are likely to cosegregate. Therefore, these transformants should be invaluable sources for the complete molecular cloning of isolated fragments of the short arm of human chromosome 11.

Regional localization of DNA sequences on chromosome 21 using somatic cell hybrids

We have used a panel of Chinese hamster X human somatic cell hybrids, each containing various portions of chromosome 21 as the only detectable human chromosome component, for regional mapping of cloned, chromosome 21-derived DNA sequences. Thirty unique and very low-repeat sequences were mapped to the short arm and three sections of the long arm. Three unique sequences map to the proximal part of the terminal band 21q22.3, and five to the distal part of this band. Some of these may represent parts of gene sequences that may be relevant to the pathogenesis of Down syndrome, as 21q22 is the area required to be present in triplicate for the full clinical picture.

The human type II collagen gene (COL2A1) assigned to 12q14.3

A cosmid clone containing the entire human type II alpha 1 collagen gene (COL2A1) was used as probe in the Southern analysis of DNA from a panel of human/hamster somatic cell hybrids containing different portions of human chromosome 12. Two of the hybrids exhibited a similar terminal deletion q14.3----qter, but one was positive for the gene while the other was negative. Therefore, the gene must reside in the region q14.3.

Linkage analysis in a family with dominantly inherited torsion dystonia: exclusion of the pro-opiomelanocortin and glutamic acid decarboxylase genes and other chromosomal regions using DNA polymorphisms

A search for the defective gene causing torsion dystonia has been carried out in a family manifesting an autosomal dominant mode of inheritance of this movement disorder. Complete neurologic examination and establishment of lymphoblast lines have been carried out for over 50 members. Linkage analysis, using cloned DNA sequences and restriction fragment length polymorphisms, was evaluated by the LOD score method with requisite assumptions for mode of inheritance, age-of-onset and incomplete gene penetrance. Genes for pro-opiomelanocortin and glutamic acid decarboxylase, which have been implicated in the etiology of the disease in rat models, were excluded as being responsible for the disease state in this family. Other regions of the genome were also excluded using DNA probes for other genes and random "unique" sequences.

Genetic counterselective procedure to isolate interspecific cell hybrids containing single human chromosomes: construction of cell hybrids and recombinant DNA libraries specific for human chromosomes 3 and 4

Counterselection against genes on human chromosome 5 was applied to interspecific human-Chinese hamster cell hybrids which retained this and one additional human chromosome in order to generate cell hybrids retaining single, nonselected human chromosomes. Using this procedure, stable cell hybrids which retain human chromosome 3 exclusively or human chromosome 4 exclusively were isolated. Complete recombinant genomic DNA libraries were prepared from each hybrid using the lambda cloning vector EMBL-4. These libraries represent sources of human DNA fragments derived specifically from chromosomes 3 and 4, respectively. Low-copy or unique human DNA fragments isolated from both libraries were analyzed to confirm their chromosomal origin and to determine the complexity of their hybridization patterns to total human DNA. These single human chromosome libraries represent a means to efficiently saturate chromosomes 3 and 4 with informative, polymorphic genetic markers. DNA fragments from the chromosome 4 library will be particularly useful in identifying additional genetic markers close to the Huntington's disease gene. The same genetic counterselective procedure can be utilized to derive several additional cell hybrids with single human chromosomes.

The use of restriction fragment polymorphisms to identify the cell line MCF-7

We have recently documented variations in the level of N-ras gene amplification in independently passaged MCF-7 cells. To establish if these differences are due to a lack of genetic identity between current MCF-7 passages and the original cell line, we have performed karyological and restriction fragment length polymorphism (RFLP) analyses. Documentation of a combination of restriction fragment patterns which are characteristic of MCF-7 has been facilitated by an analysis of DNA from an early-passage of MCF-7 from the Michigan Cancer Foundation (MCF). In addition, such early passage cells and other MCF-7 lines also share a unique amplification of the N-ras oncogene. Using these criteria and karyotypic analysis it can be shown that a sample of MCF-7 obtained from the American Type Culture Collection (ATCC) was derived from a different individual than was the original MCF-7 cell line. It is important that researchers verify the relationship of current cell lines to the original MCF-7. Furthermore, the techniques described here provide a powerful tool which may be used to assess the identity of cell stocks.

Gene order on the short arm of human chromosome 11: regional assignment of the LDH A gene distal to catalase in two translocations

Leukemic cells with reciprocal translocations involving 11p13 and 14q13 were obtained from two patients with T-cell acute lymphoblastic leukemia and fused with mouse Ltk- cells. DNA from independent hybrid clones was screened by Southern blot and hybridization to molecular probes for the human catalase and Ha-ras-1 genes. Several clones showed segregation of these two genes, indicating the presence of either the der11 or der14 human chromosomes. When DNA from these hybrid clones was examined for the presence of the human genes for calcitonin and gamma-globin, both genes were found to segregate with the Ha-ras-1 gene and the der14 chromosome indicating that they lie distal to catalase. When the hybrid clones were examined for the presence of human lactate dehydrogenase A (LDH A) activity, only those clones containing the der14 chromosome expressed activity indicating that the LDH A gene is also distal to catalase on the short arm of chromosome 11.

Translocation of c-myc in the hereditary renal cell carcinoma associated with a t(3;8)(p14.2;q24.13) chromosomal translocation

A translocation between chromosomes 3 and 8, t(3;8)(p14.2;q24.13), has been reported in a family with hereditary renal cell carcinoma. Using somatic cell hybrids, we have isolated, separately, both derivative chromosomes. We find that the c-myc oncogene (8q24.1) has been translocated to the derivative 3 [der(3)]. We have not detected a rearrangement within an approximately equal to 21-kilobase region around the c-myc gene using restriction enzyme digestion and Southern blot hybridization analysis. The translocated c-myc gene should provide a probe to the chromosome 3p14 region, which appears to be important not only in renal cell carcinoma but also in small cell carcinoma of the lung. These hybrids have also been useful for the regional mapping of the Chinese hamster ovary cell Gly-B defect to 8q22.1----q24.13 and support the regional assignment of acylase I to 3p21.

Nucleotide sequence, evolution, and expression of the fetal globin gene of the spider monkey Ateles geoffroyi

The single gamma-globin gene of the New World spider monkey Ateles geoffroyi is similar to other primate genes of the beta-globin gene cluster ("beta-like" globin genes). The number of nonsynonymous nucleotide substitutions between the coding regions of Ateles and other primate gamma-globin genes suggests that the Platyrrhine and Catarrhine evolutionary lines diverged approximately equal to 40 million years ago, an estimate reasonably consistent with the fossil record. However, the number of synonymous coding region and noncoding base differences is much smaller than predicted by various molecular "clocks." This suggests that the rate of synonymous coding and noncoding base substitution has not been constant per absolute time in primate lineages. Expression of the cloned Ateles gamma-globin gene in cultured monkey cells showed that the sequence AAUAAA near the mRNA 3' terminus is not sufficient to define the site of transcript polyadenylylation.

Isolation of polymorphic DNA segments from human chromosome 21

A somatic cell hybrid line containing only human chromosome 21 on a mouse background has been used as the source of DNA for construction of a recombinant phage library. Individual phages containing human inserts have been identified. Repeat-free human DNA subclones have been prepared and used to screen for restriction fragment length polymorphisms to provide genetic markers on chromosome 21. Nine independently isolated clones used as probes identified a total of 11 new RFLPs. Four of the DNA probes recovered from the library have been mapped unequivocally to chromosome 21 using a panel of somatic cell hybrid lines. A fifth probe detected an RFLP on chromosome 21 as well as sequences on other chromosomes. This set of RFLPs may now form the basis for construction of a genetic linkage map of human chromosome 21.

The E7-associated cell-surface antigen: a marker for the 11p13 chromosomal deletion associated with aniridia-Wilms tumor

Unbalanced interstitial deletions of the p13 region of human chromosome 11 have been associated with congenital hypoplasia or aplasia of the iris, mental retardation, ambiguous genitalia, and predisposition to Wilms tumor of the kidney. Utilizing somatic cell hybrids containing either the normal or abnormal chromosome 11 from a child with Wilms tumor and aniridia, we previously mapped the E7 cell-surface antigen to the 11p1300-to-11p15.1 region. To localize even further the site of this antigen on chromosome arm 11p, we have produced somatic cell hybrids from the fibroblasts of a second child with Wilms tumor and aniridia and a different deletion of 11p [46,XY, del (11)(pter----p14.1::p11.2----qter)]. Furthermore, the normal and deleted chromosome 11 could also be distinguished on the basis of a restriction fragment length polymorphism for the beta-globin gene. Hybrid cells containing the deleted chromosome were not killed in the presence of complement and the E7 monoclonal antibody (which recognizes E7 cell surface antigen), while hybrid cells containing the patient's normal chromosome 11 were killed. Thus, expression of the E7-associated cell-surface antigen can be mapped to the 11p13 region, and it appears to be a potential marker of the chromosome abnormality associated with aniridia-Wilms tumor.

Deletion mapping of human chromosome 5 using chromosome-specific DNA probes

A complete genomic DNA library was prepared from a Chinese hamster-human cell hybrid that contains human chromosome 5 as its only human DNA. Unique or low-copy DNA fragments, isolated form recombinant bacteriophage that contained human DNA inserts, were regionally mapped on chromosome 5 using Southern blot analysis of genomic DNA from a series of hybrid cell lines that were selected as having deletions of various portions of 5q. The chromosome 5-specific DNA library, together with a genetic selective procedure allowing the isolation of hybrid cell lines with deletions of virtually any portion of 5q, will provide a means to construct very accurate physical and recombinational maps of this human chromosome. This system represents an excellent opportunity to examine very precisely the relationship between physical and genetic distances for many loci along the length of this autosome.

Linkage map of the short arm of human chromosome 11: location of the genes for catalase, calcitonin, and insulin-like growth factor II

The following order of genes on the short arm of human chromosome 11 (11p) was determined previously: parathyroid hormone (PTH)-the beta-globin gene cluster (HBBC)-HRAS1/insulin. Although it is generally agreed that HRAS1 (formerly termed c-Ha-ras-1) and the insulin gene are close to each other [1-4 centimorgans (cM)], their order on chromosome 11p is still in question. We have now added three other genes, those for catalase, calcitonin, and insulin-like growth factor II (IGF-II), to this map of chromosome 11p by use of restriction site polymorphisms adjacent to these genes in classical linkage analysis. Most importantly, we find no evidence of linkage between the catalase and HBBC loci. In addition, our data indicate that the calcitonin gene is located between the catalase gene and the PTH gene. Our best estimate of the distance between the catalase and calcitonin gene is approximately 16 cM, while that between the calcitonin and PTH genes is approximately equal to 8 cM. In agreement, very loose linkage was found between the catalase and PTH loci (approximately 26 cM). Since the catalase locus has been mapped to 11p13, these data support the view that the PTH, HBBC, HRAS1, and insulin loci are located on the distal short arm of chromosome 11. The IGF-II gene is tightly linked to both the HRAS1 oncogene and the insulin gene since no recombinants were observed between the IGF-II and the HRAS1/insulin loci. Thus, based on our linkage analysis we propose that the most likely gene order for the short arm of chromosome 11 is centromere-catalase-calcitonin-PTH-HBBC-HRAS1/insulin-tel ome re and that the IGF-II gene is very close to both the HRAS1 and the insulin genes.

A mitotic recombination in Wilms tumor occurs between the parathyroid hormone locus and 11p13

Wilms tumor is believed to occur as the result of two mutations affecting both alleles of a critical gene located within the p13 band of chromosome 11 (Knudson and Strong 1972; Riccardi et al. 1978). Several mechanisms by which these mutations occur have already been determined in retinoblastoma (Cavenee et al. 1983) and Wilms tumor (Koufos et al. 1984; Orkin et al. 1984; Reeve et al. 1984; Fearon et al. 1984a; Eccles et al. 1984). Of the various mechanisms, however, no example of a mitotic recombination was demonstrated in Wilms tumor. An example is presented here which has been detected by the use of restriction fragment length polymorphisms (RFLPs) mapping to chromosome 11p. In addition the data presented are consistent with the mapping location of parathyroid hormone (PTH) being proximal to 11p13.

Identification and localization of DNA alteration in Chinese hamster ovary cell mutants (Urd-) defective in the first three enzymes of de novo pyrimidine synthesis

In animals, the first three enzymatic steps of de novo pyrimidine synthesis, carbamyl phosphate synthetase, aspartate transcarbamylase, and dihydroorotase, comprise the multifunctional protein known as the CAD protein. Mutants of Chinese hamster ovary cells (CHO-K1, pro-) deficient in CAD protein activities require uridine for growth and are designated Urd-A mutants. To examine further the nature of the genetic alterations in Urd-A mutants and revertants, we have performed a detailed Southern blot hybridization analysis of DNA from wild-type, Urd-A, and revertant cells using as hybridization probes cDNAs complementary to CAD mRNA isolated from Syrian hamster. This has allowed us to identify an apparent alteration in the CAD gene in DNA from Urd-A cells. This alteration is in a region of the gene which appears to correspond to the region of the protein which is hypersensitive to proteases and which seems to be altered in the mutants. Only one of the two CAD alleles present appears to be altered in this way. Study of certain revertants of Urd-A strongly suggests that in some cases reversion has occurred by amplification of the mutant CAD allele.

The second human calcitonin/CGRP gene is located on chromosome 11

A second human calcitonin/calcitonin gene related peptide (hCT/CGRP) gene has been identified. This second hCT/CGRP gene has been shown to contain sequences highly homologous to exons 3, 5 (CGRP-encoding), and 6 of the first hCT/CGRP gene, but sequences closely related to exon 4 (CT-encoding) could not be demonstrated. Southern blot hybridization analysis of DNA from human-rodent somatic cell hybrids showed that the second hCT/CGRP gene is located in the q12-pter region of chromosome 11. The first hCT/CGRP gene has previously been assigned to the p13-p15 region of chromosome 11.

Expression of genes on human chromosome 21

Gene sequences were isolated from a lambda library containing inserts originating from human chromosome 21. One phage, CP21G1, had been selected on the basis of its lack of middle-repetitive sequences and its ability to hybridize with 32P-labeled cDNA synthesized from the cytoplasmic poly A+ RNA of cultured fibroblasts. Further experiments revealed that the human insert in this phage is unique-sequence DNA, maps to the long arm of chromosome 21, and is expressed in fibroblasts and T cells. A panel of 127 "unique-sequence" phage were also selected from the lambda library and were tested for hybridization to 32P-labeled cDNA synthesized from the cytoplasmic poly A+ RNA of CCRF-HSB-2, a T-blast leukemic line. Seventeen recombinants hybridized to the probe. One of these phages, CP8, contains a human unique-sequence DNA expressed in T cells and neuroblastoma cells. One phage (CP5) in the "unique-sequence" panel that had not hybridized to cDNA from T-cell RNA was found to carry a low-repeat sequence and to hybridize specifically to RNA from a neuroblastoma line. This phage appears to carry a brain-specific gene. Many of the genomic sequences related to the low-repeat sequence contained in CP5 map to the short arm of chromosome 21. The cloned genes described here represent new markers for the detailed mapping of human chromosome 21 and may prove valuable in studying tissue-specific gene regulation.

Assignment of the gene coding for the T3-delta subunit of the T3-T-cell receptor complex to the long arm of human chromosome 11 and to mouse chromosome 9

The gene encoding the 20-kDa glycoprotein of the T3-T-cell receptor complex (T3-delta chain) has been mapped to human chromosome 11 by hybridization of a T3-delta cDNA clone (pPGBC#9) to DNA from a panel of human-rodent somatic cell hybrids. In Southern blotting experiments with DNAs of somatic cell hybrids that contained segments of chromosome 11, we were able to assign the T3-delta gene to the distal portion of the long arm of human chromosome 11 (11q23-11qter). By use of a newly developed cDNA clone (pPEM-T3 delta) that codes for the murine T3-delta chain, the mouse T3-delta gene was mapped on chromosome 9. The importance of the T3-delta map position and its relationship to the other genes on the long arm of human chromosome 11 and to those on mouse chromosome 9 is discussed.

Molecular approach to analyzing the human 5p deletion syndrome, cri du chat

DNA unique or low-copy fragments were isolated from a genomic DNA library specific for the short (p) arm of human chromosome 5. These chromosome 5p-specific DNA fragments were used to analyze, by Southern blot experiments, somatic cell hybrids that retained either a normal chromosome 5 homolog or a homolog with a partial deletion of 5p, which was derived from either of two persons with the common human deletion syndrome, cri du chat or 5p- syndrome. In these studies, two classes of DNA fragments were identified, those located outside the region deleted in the persons with cri du chat and those located within the deleted region. This latter class of DNA probes will help to define, at the molecular level, a region of 5p that is critical in producing the phenotype associated with the cri du chat syndrome.

Mapping parathyroid hormone, beta-globin, insulin, and LDH-A genes within the human chromosome 11 short arm by spot blotting sorted chromosomes

Rearranged human chromosomes carrying segments of chromosome 11 were separated from the normal chromosome 11 by high-resolution chromosome sorting. Sorted chromosomes were tested with parathyroid hormone, beta-globin, insulin, and LDH-A gene-specific probes to determine the genes carried by each chromosome segment. Based on the gene content and karyotypes of these abnormal chromosomes, the parathyroid hormone, beta-globin, insulin, and LDH-A genes and the unique restriction fragment ADJ-762 are all located on the terminal band of the short arm of human chromosome 11 (band 11p15), with LDH-A proximal to the other loci.

Localization of the beta-globin gene to 11p15 by in situ hybridization: utilization of chromosome 11 rearrangements

Chromosome preparations from four subjects, one normal 46,XY male and three patients with different rearrangements of chromosome 11: 46,XX,del(11)(p11.2----p15.1), 46,XY,inv(11)(p13q24.2), and 46,XY,rec(11)inv(11)(p13q24.2) pat, were utilized for in situ hybridization studies with a tritium-labeled cDNA probe containing a beta-globin insert. Using the hybridization technique described by Harper and Saunders (1981), there were 1-2 grains over each labeled metaphase. Of 360 cells scored, 88 were labeled over chromosome 11, band p15 (24%). Approximately half of the chromosome 11s labeled from the abnormal patients were the del(11) or inv(11). These results exclude the beta-globin locus from 11p11----p14, since these bands were not present in the deleted 11, and assign it to 11p15. This is in agreement with the recent exclusion data of de Martinville and Francke (1984) and Junien (1984), and suggestive assignment data of Morton et al. (1984).

Germ-line chromosomal localization of genes in chromosome 11p linkage: parathyroid hormone, beta-globin, c-Ha-ras-1, and insulin

The chromosomal localization of genes for parathyroid hormone (PTH), beta-globin cluster, c-Ha-ras-1, and insulin, all of which have previously been assigned to the short arm of chromosome 11, generated considerable interest because of their association with development of disease states. Furthermore, the availability of recombination data from family studies made the determination of their physical location on the chromosome necessary. Several investigators have attempted this; however, controversy has arisen concerning the location of beta-globin, insulin, and c-Ha-ras-1 genes. Thus, while the results of some investigators suggested that all three genes are situated in the 11p15 region, data of other investigators placed the beta-globin and insulin genes close to the centromere and c-Ha-ras-1 in a more proximal region than 11p15. The subchromosomal position of the PTH gene remains to be determined. We have performed in situ hybridization of meiotic pachytene bivalents with 3H-labeled cloned genomic probes of PTH, beta-globin, and insulin genes and find their germ-line positions to be the following: PTH at 11p11.21, beta-globin at 11p11.22, and insulin at 11p14.1. These data, when considered with our recent germ-line assignment of the c-Ha-ras-1 gene to 11p14.1, indicate the following relative order on 11p: cen-PTH-beta-globin-c-Ha-ras-insulin or cen-PTH-beta-globin-insulin-c-Ha-ras. The former order is consistent with genetic evidence from linkage analysis of DNA polymorphisms adjacent to these genes segregating in families.

Analysis of gene expression during hematopoiesis: present and future applications

Recombinant DNA technology now provides the strategies required to identify genes whose expression controls the development of normal and pathologic blood cells. Characterization of the gene families responsible for synthesis of hemoglobins, immunoglobulins, histocompatibility antigens, and cellular enzymes have already, or are about to, provide major insights into the mechanisms producing normal erythroid cells, immunocytes, and immune surface features. Hemoglobinopathies, leukemias, and autoimmune diseases of the bone marrow can now be examined to a degree of detail previously inaccessible to investigators. Oncogene translocation analysis is shedding new light on the pathogenesis of leukemias and lymphomas. Recent basic advances now permit direct cloning and identification of genes in host organisms which express their protein products, thus allowing isolation of genes coding for the hematopoietic surface markers and growth factors which characterize and regulate blood cell progenitors. This review summarizes the molecular genetic approach to analysis of normal and pathologic hematopoiesis, surveys major findings which have resulted, and examines the potential use of refined gene cloning strategies for improved understanding of blood cell development.

Isolation and analysis of the 21q+ chromosome in the acute myelogenous leukemia 8;21 translocation: evidence that c-mos is not translocated

Acute myelogenous leukemia (AML), subgroup M2, is associated with a nonrandom chromosomal translocation, t(8;21)(q22,q22). The oncogene c-mos also has been localized to the q22 band on chromosome 8. There is also evidence that genes on chromosome 21 may be important in the development of leukemia. To determine whether the c-mos oncogene has been translocated in AML-M2 with this translocation and to isolate DNA sequences and genes from these two chromosomes that may be important in malignancy, we constructed somatic cell hybrids between a Chinese hamster ovary cell (CHO) mutant defective in glycine metabolism and myeloblasts with an 8;21 translocation from a patient with AML. We isolated the 21q+ chromosome of this translocation in a somatic cell hybrid and showed that the c-mos oncogene had not been translocated to chromosome 21, ruling out the possibility that translocation of c-mos to chromosome 21 is necessary for development of AML-M2. In addition, there was no detectable rearrangement of the c-mos locus within a 12.4-kilobase region surrounding the gene, indicating that rearrangement of the coding region of the gene itself or alteration of proximal 5' or 3' flanking sequences is not involved. We used this hybrid to determine whether specific DNA sequences and biochemical markers from chromosomes 8 and 21 had been translocated in this case.

Identification of a recent recombination event within the human beta-globin gene cluster

In a detailed study of inheritance of DNA sequence polymorphism in a large reference pedigree, an individual was identified with an apparent genetic recombination event within the human beta-globin gene cluster. Analysis of the haplotypes of relevant individuals within this pedigree suggested that the meiotic crossing-over event is likely to have occurred within a 19.8-kilobase-pair region of the beta-globin gene cluster. Analysis of other DNA markers closely linked to the beta-globin gene cluster--segment 12 of chromosome 11 (D11S12) and loci for insulin, the cellular oncogene c-Ha-ras, and preproparathyroid hormone--confirmed that a crossover event must have occurred within the region of chromosome 11 between D11S12 and the beta-globin gene cluster. It is suggested that the event observed has occurred within a DNA region compatible with recombinational "hot spots" suggested by population studies.

Wilms' tumor-aniridia association: segregation of affected chromosome in somatic cell hybrids, identification of cell surface antigen associated with deleted area, and regional mapping of c-Ha-ras-1 oncogene, insulin gene, and beta-globin gene

Fusion of an auxotrophic mutant hamster cell with the skin fibroblasts of a child with the Wilms' tumor-aniridia association produced clones which, on the one hand, contained the child's normal chromosome 11 and, on the other, the chromosome 11 with the 11p13 deletion associated with the syndrome. Both hybrids were positive for human LDH-A by enzymatic assay. Clones containing the normal human chromosome 11 were killed by a cytotoxic monoclonal antibody to a cell surface antigen previously mapped to the 11p13----11pter region of chromosome 11. Clones with the abnormal 11 were not killed. Thus, we have produced hybrids from the same patient distinct from each other on the basis of their chromosome 11. These hybrids have been used to map the locus for a cell surface antigen to the deleted region on chromosome 11 of a patient with the Wilms tumor-aniridia association. The linkage between this antigen and the syndrome should be helpful in further study of the genetics of this disease. In addition, we have found that the c-Ha-ras-1 oncogene is distal to the p13 region of chromosome 11 and the position of insulin and beta-globin on the chromosome. Finally, by producing segregants of the hybrids containing the abnormal chromosome 11, we have provided evidence that chromosome 11-associated c-Ha-ras-1 is syntenic with chromosome 11 and not moved to a different portion of the genome.

Genetic mapping of the structural gene for antithrombin III to human chromosome 1

Using a purified cDNA probe of human antithrombin III (AT3) gene and a series of human/Chinese hamster cell hybrids, we established the chromosomal location of the structural gene for AT3 in human chromosome 1 by Southern blot analysis.

Development of homozygosity for chromosome 11p markers in Wilms' tumour

Somatic alterations in the genome are found in many human tumours. Chromosome rearrangements or base substitutions that activate cellular oncogenes appear to act dominantly. In contrast, recessive alleles apparently contribute to childhood retinoblastoma, as homozygosity (or hemizygosity ) for chromosome 13 is often established in tumours, by either mitotic nondisjunction or recombination. Parallels exist between retinoblastoma and childhood Wilms' tumour (WT). Retinoblastoma is often inherited and accompanied by a deletion of chromosome 13 (band q14), while WT is occasionally associated with aniridia and deletion of chromosome 11 band p13. Most Wilms' tumours are sporadic and not accompanied by these findings, although interstitial deletion of chromosome 11 in tumour, but not normal, cells has been reported. In view of these parallels, we compared constitutional and tumour DNAs from WT patients by using chromosome 11p DNA probes. We report here that although heterozygosity in constitutional DNAs was often preserved in tumour DNAs, one case developed homozygosity for chromosome 11p markers in tumour cells, implying the involvement of chromosomal events in revealing a recessive WT locus. This observation suggests the action of such general mechanisms in a tumour other than retinoblastoma.

Localization of the beta-globin gene by chromosomal in situ hybridization

A 3.7-kilobase (kb) genomic clone of the human beta-globin gene, including 1.5-kb upstream and approximately 0.5-kb downstream, was utilized in chromosomal in situ hybridization for precise mapping of the beta-globin locus on peripheral blood lymphocyte-derived metaphases from a normal male, and for further evaluation of a clonal t(7;11) (q22;p15) translocation on bone marrow-derived metaphases from a 46-year-old male with erythroleukemia. Analyses of 205 midmetaphases from a normal male hybridized with the tritium-labeled beta-globin probe and stained with quinacrine mustard dihydrochloride revealed approximately 12% of spreads to have silver-grain deposition over the p15 band of chromosome 11. Of the 365 silver grains observed to be located on or beside chromosomes, 25 (approximately 7%) grains were localized in band p15. Karyotype analysis of a bone marrow specimen from the patient with erythroleukemia revealed hypodiploidy with various unidentified marker chromosomes as well as a presumably balanced translocation between 7q and 11p . Chromosomal in situ hybridization showed localization of silver grains at the junction between chromosomes 7 and 11 as well as to the normal chromosome 11, indicating that the beta-globin locus had not been translocated in the chromosomal rearrangement. This case demonstrates the value of chromosomal in situ hybridization in the definition of chromosome rearrangements and provides further evidence for the localization of the beta-globin gene to 11p15 .

The use of cell surface antigens to characterize and select for fragments of human chromosomes retained by interspecies hybrids

We have used a mouse cell transformant generated by human chromosome-mediated gene transfer (CMGT) to explore the use of cell surface antigens in the identification of fragments of human chromosomes retained by somatic cell hybrids. The transformed line, 21-30b, contained an intact rear-ranged human chromosome, and could be shown by isozyme analysis to contain genetic material from chromosomes 9 and X. By using the transformant as an immunogen in mice, it was also possible to produce antiserum to human-specific surface antigens. Using genetically characterized human X rodent hybrid lines, the genes controlling expression of these antigens could be localized to 11per----11p13, segregating concordantly with surface antigen S3. These conclusions were possible despite the fact that the presence of chromosome 11 in the transformant was not detectable by the presence of chromosome specific isozyme LDH-A or surface antigens W6/34 and 4F2. Finally, the fluorescence-activated cell sorter (FACS) was used to fractionate the transformant cells into antigen positive and negative subpopulations. This resulted in the isolation and characterization of four additional chromosome rearrangements involving interspecies chromosome translocations. This work demonstrates the value of chromosome-specific surface antigens and the FACS in the evaluation of human chromosome fragments retained by interspecies hybrids.

Human apolipoprotein A-I--C-III gene complex is located on chromosome 11

The genes for two of the apolipoproteins, apo A-I and apo C-III, previously shown to be within 3kb in the genome, were localized to human chromosome 11 by Southern blot analysis of DNA from human-rodent somatic cell hybrids. These two genes were shown to exhibit polymorphisms associated with dyslipoproteinemia and premature atherosclerosis, and it will now be possible to examine the relationship of these genes to the many others that have been assigned to this chromosome.

c-Ha-ras-1 oncogene lies between beta-globin and insulin loci on human chromosome 11p

DNA sequence polymorphisms have been used to determine the linear order and recombinational distances separating the Harvey ras 1 oncogene (c-Ha-ras-1), beta-globin, insulin, and parathyroid hormone genes on the short arm of human chromosome 11. Our results indicate that c-Ha-ras-1 is closely linked to both the beta-globin locus (theta = .08 [8 centimorgans], lod score = 5.11) and the insulin locus (theta = .04 [4 centimorgans], lod score = 3.31). Furthermore, the probable order of these loci on chromosome 11p is centromere-parathyroid hormone-beta globin-c-Ha-ras-1-insulin.

Localization of the structural gene for human apolipoprotein A-I on the long arm of human chromosome 11

Apolipoprotein A-I (apo A-I), the major apolipoprotein in human high density lipoproteins, is involved in the disease atherosclerosis. Cloned apo A-I cDNA (pA1-3) was used as a probe in chromosome mapping studies to detect the human apo A-I structural gene sequence in human-Chinese hamster cell hybrids. Southern blot analysis of 13 hybrids localized the gene to human chromosome 11. Confirmation of the chromosomal assignment was obtained by analysis of a hybrid (J1) containing a single human chromosome, no. 11. Regional mapping was achieved by using deletion subclones of J1 that localized the human apo A-I structural gene to the region 11q13 leads to qter. Since the human apolipoprotein C-III (apo C-III) structural gene is closely linked to apo A-I, it can be assigned to the same region on the long arm of chromosome 11. By extension of methods previously described, it now appears possible to carry out fine-structure analysis of this and related gene regions on chromosome 11 and to study the biochemical concomitants of these genes and of genes on other chromosomes for analysis of their role in atherosclerosis.

Isolation of repetitive DNA sequences from human chromosome 21

We have developed a method for the isolation of phage from the human genomic library that carry repetitive DNA sequences highly represented on specific human chromosomes. We have used this technique to select recombinants carrying inserts concentrated on chromosome 21. Five clones, representing two families of sequences, have been characterized. Members of each family show cross-homology, but the two families show no homology with each other. In all but one case, the clones do not contain members of the human Alu repeat family. Single chromosome-concentrated repetitive sequences should prove to be useful in studies of the origin, evolution, and function of repetitive DNA and in regional chromosome mapping.

Molecular hybridization under conditions of high stringency permits cloned DNA segments containing reiterated DNA sequences to be assigned to specific chromosomal locations

Identifying the specific DNA sequences involved in the chromosomal abnormalities in developmental and neoplastic diseases may be essential to understanding the molecular biology of these disorders. The use of recombinant DNA techniques in conjunction with rodent-human hybrid cells makes it possible to assign chromosomal locations to specific DNA sequences. However, the ubiquitous presence of reiterated DNA species often complicates the application of straightforward molecular hybridization. To accelerate the mapping of cloned sequences to specific chromosomal locations, we investigated the possibility that cloned sequences containing reiterated DNA might be used without isolating unique sequences. By varying conditions of hybridization (specifically temperature) and using restricted DNA samples from human genomic DNA, Chinese hamster ovary-human chromosome 11 hybrids, and non-chromosome 11 hybrids, we have been able to assign cloned DNA sequences containing reiterated sequences to their chromosome of origin. By hybridization under the high-stringency condition of 55 degrees C, specific banding was produced with both human genomic DNA and the human-chromosome-containing hybrid from which the probe was prepared. Furthermore, using a panel of chromosome 11 deletion mutants, we have been able to assign a cloned sequence to a specific chromosomal location. We believe that this approach will accelerate gene mapping procedures and facilitate identification of DNA sequences involved in chromosomal abnormalities.

A polymorphic DNA marker genetically linked to Huntington's disease

Family studies show that the Huntington's disease gene is linked to a polymorphic DNA marker that maps to human chromosome 4. The chromosomal localization of the Huntington's disease gene is the first step in using recombinant DNA technology to identify the primary genetic defect in this disorder.