Localization of a gene controlling the expression of the human transferrin receptor to the region q12 leads to qter of chromosome 3

A monoclonal antiserum, 66-IG10, raised against human thymocytes was found to be directed against the human transferrin receptor. A panel of human X Chinese hamster somatic cell hybrids, in conjunction with the 66-IG10 reagent, was used to assign the gene(s) coding for the transferrin receptor to the q12 leads to qter region of human chromosome 3.     

GM1-gangliosidosis: chromosome 3 assignment of the beta-galactosidase-A gene (beta GALA).

The structural gene (beta GALA) coding for lysosomal beta-galactosidase-A (EC 3.2.1.23) has been assigned to human chromosome 3 using man--mouse somatic cell hybrids. Human beta-galactosidase-A was identified in cell hybrids with a species-specific antiserum to human liver beta-galactosidase-A. The antiserum precipitates beta-galactosidase-A from human tissues, cultured cells, and cell hybrids, and recognizes cross-reacting material from a patient with GM1 gangliosidosis. We have analyzed 90 primary man--mouse hybrids derived from 12 separate fusion experiments utilizing cells from 9 individuals. Enzyme segregation analysis excluded all chromosomes for beta GALA assignment except chromosome 3. Concordant segregation of chromosomes and enzymes in 16 cell hybrids demonstrated assignment of beta GALA to chromosome 3; all other chromosomes were excluded. The evidence suggests that GM1 gangliosidosis is a consequence of mutation at this beta GALA locus on chromosome 3.     

The structural gene for transferrin (TF) maps to 3q21----3qter

A cloned human cDNA for transferrin (TF) was used as hybridization probe in analysing a series of rodent x human somatic cell hybrids for the presence of human TF sequences. The assignment to chromosome 3 was further refined to region 3q21----3qter using hybrids that carried a translocated chromosome 3 and fibroblasts from a patient trisomic for this region. The gene for TF therefore maps to the same region as the gene for transferrin receptor (TFR) thereby defining an iron transport region on 3q2 to which the transferrin-related tumor associated antigen p97 may also belong. It follows that the genes for pseudocholinesterase (CHE1), ceruleoplasmin (CP) and alpha-2HS-glycoprotein (A2HS) which belong to the, as yet unassigned, linkage group of TF, now also map to chromosome 3 in man.     

Levels of fos, ets2, and myb proto-oncogene RNAs correlate with segregation of chromosome 11 of normal cells and with suppression of tumorigenicity in human cell hybrids.

The tumorigenicity in nude mice of human carcinoma-derived D98AH2 (D98) cells is suppressed when cell hybrids are made by fusing these cells with normal human diploid cells. Selection for hybrids that have segregated chromosomes results in the recovery of tumorigenic segregants. These segregants have all lost at least one copy of chromosome 11 of the diploid cell parent. Earlier we found that the parental D98 cells had detectable levels of mRNA specific for 13 of 21 proto-oncogenes examined. To determine if transregulation of proto-oncogenes by genes of the normal cell occurs in such hybrids, the steady-state levels of mRNA specific to 22 proto-oncogenes in the parental cells were compared with those of nontumorigenic D98 X human diploid hybrids as well as with those of their tumorigenic segregants and with the cells of the resulting tumors. The only chromosome consistently segregated in the latter was chromosome 11 of the diploid cell. fos and ets2 RNA levels and the amount of fos protein were consistently elevated in the segregants compared with amounts in the original hybrids. An unexpected finding was the inverse relationship for myb RNA that was barely detected in the parental D98 cells but was at least 10-fold elevated in hybrids that did not have segregated chromosomes compared with those that did. These patterns were evident in RNAs prepared from both subconfluent and confluent cell cultures. The findings suggest that genes of the normal cell parent can affect proto-oncogene expression. Whether the genes affecting fos, ets2, and myb RNA levels are on chromosome 11 and whether these alterations are causally related to the tumorigenic phenotype of the hybrid remain to be determined.     

The transferrin receptor

The isolation and analysis of the transferrin receptor has been greatly aided by the use of monoclonal antibodies. The receptor is a disulphide-linked homo-dimer which spans the membrane and binds two molecules of transferrin. Controlling genes for this receptor in humans have been mapped to chromosome 3 using cell hybrids. The expression of transferrin receptors is related to the obligatory and ubiquitous iron requirements associated with cell proliferation or the special iron demand of haemoglobin synthesizing cells and trophoblasts. However, transferrin receptors may also be involved in cell interactions regulating cell growth.     

Chromosome loss is responsible for segregation at the HPRT locus in Chinese hamster cell hybrids

The phenomenon of segregation of gene expression has been examined in intraspecific somatic cell hybrids. Specifically, segregation at the hypoxanthine guanine phosphoribosyltransferase (HPRT) locus has been studied in hybrids of Chinese hamster cell lines. The role of chromosome segregation, or other chromosomal events has been assessed by detailed comparison of karyotypes in the 6-thioguanine resistant segregants with those of the parental hybrid lines. The results clearly demonstrate that loss of an entire X chromosome is the primary event responsible for segregation at the HPRT locus, while deletion of a portion of the short arm of an X chromosome was also a frequent event. The results provide the first direct evidence for the assignment of the mapping of this locus to the distal region of the short arm. Analysis of chromosome number distributions in the hybrids and segregants suggests that in selecting chromosomal segregants one may also select for hybrid lines with reduced chromosome stability.     

Segregation of recessive phenotypes in somatic cell hybrids: role of mitotic recombination, gene inactivation, and chromosome nondisjunction.

Somatic cell hybrids heterozygous at the emetine resistance locus (emtr/emt+) or the chromate resistance locus (chrr/chr+) are known to segregate the recessive drug resistance phenotype at high frequency. We have examined mechanisms of segregation in Chinese hamster cell hybrids heterozygous at these two loci, both of which map to the long arm of Chinese hamster chromosome 2. To follow the fate of chromosomal arms through the segregation process, our hybrids were also heterozygous at the mtx (methotrexate resistance) locus on the short arm of chromosome 2 and carried cytogenetically marked chromosomes with either a short-arm deletion (2p-) or a long-arm addition (2q+). Karyotype and phenotype analysis of emetine- or chromate-resistant segregants from such hybrids allowed us to distinguish four potential segregation mechanisms: (i) loss of the emt+- or chr+-bearing chromosome; (ii) mitotic recombination between the centromere and the emt or chr loci, giving rise to homozygous resistant segregants; (iii) inactivation of the emt+ or chr+ alleles; and (iv) loss of the emt+- or chr+-bearing chromosome with duplication of the homologous chromosome carrying the emtr or chrr allele. Of 48 independent segregants examined, only 9 (20%) arose by simple chromosome loss. Two segregants (4%) were consistent with a gene inactivation mechanism, but because of their rarity, other mechanisms such as mutation or submicroscopic deletion could not be excluded. Twenty-one segregants (44%) arose by either mitotic recombination or chromosome loss and duplication; the two mechanisms were not distinguishable in that experiment. Finally, in hybrids allowing these two mechanisms to be distinguished, 15 segregants (31%) arose by chromosome loss and duplication, and none arose by mitotic recombination.     

The expression of human glycerol-3-phosphate dehydrogenase in human/rodent somatic-cell hybrids

Our previous studies using rodent/human somatic-cell hybrids suggested that the expression of human mitochondrial glycerol-3-phosphate dehydrogenase (GPDM) is dependent on the presence of human mitochondria. This has now been tested directly by analysis of GPDM activity in a series of nine hybrid-cell lines, four segregating human chromosomes and five losing rodent chromosomes (reverse segregants). The chromosome composition of the hybrids was deduced from analysis of biochemical markers and examination of G- and G11-banded metaphase spreads and the mitochondrial content was determined by Southern blot analysis, using cloned mouse and human mtDNA sequences as probes. We found that the mtDNA species present in these hybrids correlated exactly with the pattern of chromosome segregation such that the conventional hybrids contained rodent mtDNA and the reverse segregants human mtDNA. However, the pattern of GPDM expression was not directly correlated with the species of chromosomes or mitochondria present: all the hybrids showed strong rodem GPDM activity and two from each class of hybrid also showed human GPDM activity but the other hybrids were negative for human GPDM. We conclude that rodent GPDM readily integrates into human mitochondria, that the expression of rodent GPDM is not dependent on the presence of rodent mitochondria, and that GPDM is not coded by mtDNA. Human GPDM either is not capable of being inserted into the rodent mitochondrial membrane or is regulated in some way in the hybrid cells by an unidentified rodent factor.     

Genetic demonstration of mitotic recombination in cultured Chinese hamster cell hybrids

Chinese hamster ovary cell hybrids were constructed that are heterozygous for two markers, leuS and emtB, linked to the long arm of chromosome 2. In addition, the chromosome 2 carrying the wild-type leuS and emtB alleles contains, on its short arm, a homogeneously staining region (hsr) in which the gene encoding dihydrofolate reductase (dhfr) is amplified approximately 50-fold. This provides a convenient cytogenetic and biochemical means to distinguish the chromosome 2s from the different parents. Analysis of emetine-resistant segregants isolated from such hybrids identified three distinct classes of segregants. One rare class of segregants loses the wild-type leuS and emtB gene functions on the long arm of the hsr chromosome 2 (H-2) but retains the amplified dhfr genes on the opposite arm. Detailed genetic analysis of two such segregants that did not arise by chromosome loss or deletion revealed that new gene linkage relationships had been established on the H-2 chromosome in each, demonstrating that the segregation events in these cell lines involved mitotic recombination.     

Gene inactivation as a mechanism for the expression of recessive phenotypes.

A series of Chinese hamster ovary cell hybrids were constructed which were heterozygous at the emtB and chr loci. These loci encode two recessive drug-resistance genes (emetine resistance and chromate resistance, respectively) located on a structurally hemizygous region on the long arm of chromosome 2. These heterozygous hybrids therefore exhibit wild-type sensitivity to both emetine and chromate. Drug-resistant variants were then selected in medium containing either emetine or chromate, and the mechanism of reexpression of the recessive drug-resistant allele was determined by karyotypic analysis of the resultant colonies. In previous studies at these loci we have determined that segregation of the recessive phenotype occurs primarily by (1) the loss of the chromosome 2 carrying the wild-type, drug-sensitive, allele, (2) deletion of the long arm of chromosome 2, or (3) loss of one chromosome 2 followed by duplication of the remaining homologue. However, a small proportion of segregants have also been detected which may have arisen by the mechanisms of de novo gene inactivation or mutation. In this report, hybrids are described which were constructed to allow selection for the retention of the chromosome carrying the wild-type allele and which therefore optimize isolation of these rare segregants. We demonstrate by karyotypic analysis, mutation frequency analysis, and microcell-mediated chromosome transfer that these rare segregants occur primarily by gene inactivation. We also demonstrate a dramatic increase in the proportion of segregants occurring by gene inactivation in two of these hybrids as compared with those previously reported, indicating that this mechanism may be an important mode of phenotype segregation in diploid cells and, therefore, in the development of cancers--such as the childhood tumors retinoblastoma and Wilms tumor--resulting from recessive alleles     

Mapping of aminoacylase-1 and beta-galactosidase-A to homologous regions of human chromosome 3 and mouse chromosome 9 suggests location of additional genes.

Conserved linkage groups have been found on the X and autosomal chromosomes in several mammalian species. The identification of conserved chromosomal regions has potential for predicting gene location in mammals, particularly in humans. The genes for human aminoacylase-1 (ACY1, N-acylamino acid aminohydrolase, E.C.3.5.1.14), an enzyme in amino acid metabolism, and beta-galactosidase-A (GLB1, E.C.3.2.1.23), deficient in GM1-gangliosidosis, have been assigned to human chromosome 3. Using human-mouse somatic cell hybrids segregating translocations of human chromosome 3, expression of both ACY1 and GLB1 correlated with the presence of the p21 leads to q21 region of chromosome 3. In a previous study, assignment of these genes to mouse chromosome 9 used mouse-Chinese hamster somatic cell hybrids, eliminating mouse chromosomes. To approximate the size of the conserved region in the mouse, experiments were performed with recombinant inbred mouse strains. An electrophoretic variant of ACY-1 in mouse strains was used to map the Acy-1 gene 10.7 map U from the beta-galactosidase locus. These data suggest that there is a region of homology within the p21 leads to q21 region of human chromosome 3 and a segment of mouse chromosome 9. Since the mouse transferrin gene (Trf) is closely linked to the aminoacylase and beta-galactosidase loci, we predict that the human transferrin (TF) gene is on chromosome 3.     

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.     

The p97 antigen is mapped to the q24-qter region of chromosome 3; the same region as the transferrin receptor.

Since the p97 antigen, a membrane-associated iron-binding protein, has extensive amino acid sequence with homology with transferrin, is functionally related to the transferrin receptor, and has been previously mapped to chromosome 3, we have performed additional studies for regional mapping of the gene expressing p97 antigen. In these experiments, Chinese hamster-human cell lines were chosen that contained a large spectrum of autosomal human chromosomes, but mainly consisted of clones expressing all or a part of chromosome 3. These cell lines included a clone that previously allowed for mapping of human transferrin receptor to q22-qter region. Human p97 expression was assessed by specific binding of [125I]monoclonal antibody 96.5, and human transferrin receptor expression was tested by specific [125I]human transferrin binding and [125I]monoclonal antibody OKT-9 specific for human transferrin receptor. Based on these analyses, both human p97 antigenic expression and human transferrin receptor are mapped concordantly to the q24-qter region. These data and previous reports, therefore, suggest that the related iron-transport proteins are closely linked and may be under coordinate regulation. However, studies of several cell lines that exhibit up-regulation of human transferrin receptor expression with cellular proliferation, and down-regulation of receptor with increased transferrin-iron in the media, showed no change in expression of p97 antigen. p97 antigenic expression increased when melanocyte-stimulating hormone was added to a human melanoma cell line in tissue culture. These latter studies suggest that in mammalian cells the two proteins do not show coordinate regulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies of the binding of different iron donors to human serum transferrin and isolation of iron-binding fragments from the N- and C-terminal regions of the protein.

1. Trypsin digestion of human serum transferrin partially saturated with iron(III)-nitrilotriacetate at pH 5.5 or pH 8.5 produces a carbohydrate-containing iron-binding fragment of mol.wt. 43000. 2. When iron(III) citrate, FeCl3, iron (III) ascorabate and (NH4)2SO4,FeSO4 are used as iron donors to saturate the protein partially, at pH8.5, proteolytic digestion yields a fragment of mol.wt. 36000 that lacks carbohydrate. 3. The two fragments differ in their antigenic structures, amino acid compositions and peptide 'maps'. 4. The fragment with mol.wt. 36000 was assigned to the N-terminal region of the protein and the other to the C-terminal region. 5. The distribution of iron in human serum transferrin partially saturated with various iron donors was examined by electrophoresis in urea/polyacrylamide gels and the two possible monoferric forms were unequivocally identified. 6. The site designated A on human serum transferrin [Harris (1977) Biochemistry 16, 560--564] was assigned to the C-terminal region of the protein and the B site to the N-terminal region. 7. The distribution of iron on transferrin in human plasma was determined.     

Similarities between the transferrin receptor proteins on human reticulocytes and human placentae

The transferrin receptor of the human reticulocyte was isolated by two different immunoaffinity procedures. These included indirect immunoprecipitation with a transferrin/anti-transferrin complex and direct immunoprecipitation with antiserum to purified transferrin receptor from placentae. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the receptor isolated from reticulocytes reveals a polypeptide at Mr = 94,000 identical in molecular weight with that of the placenta. A radioimmunoassay using purified 125I-labeled transferrin receptor from placentae and antiserum to transferrin receptor fails to distinguish any immunological differences between the reticulocyte and placental forms of the protein. In addition, proteolytic digests of both of these polypeptides with Staphylococcus aureus protease show identical proteolytic patterns, indicating similar sequences.     

Isolation of two molecular weight variants of the mouse growth hormone receptor

GH receptors (GHRs) have been shown by affinity cross-linking to be present in late pregnant mouse liver microsomes in three forms with cross-linked mol wts of 125,000, 62,000, and 56,000. The two lower mol wt forms of the receptor were partially purified by bovine GH-affinity chromatography of 3-[(3-cholamidopropyl)dimethylammonio]-1-propane-sulfonate-solubilized extracts of late pregnant mouse hepatic microsomes. The GHRs were identified from the partially purified receptor preparation and isolated by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The isolated GHRs had mol wts of 40,700 and 37,500, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Enzymatic cleavage of N-linked glycosylation from the isolated GHRs reduced their apparent mol wts to 33,600 and 30,900, respectively. Sixteen of the amino-terminal 17 amino acid residues of the two isolated receptors were sequenced and determined to be identical. One amino acid residue in each of the proteins, at position 14, could not be identified. Rabbit polyclonal antiserum was produced against the isolated GHRs. The resulting antiserum precipitated the isolated 40,700 and 37,500 mol wt proteins as well as cross-linked mouse GHRs (including the high mol wt form of the receptor). However, the antiserum did not inhibit the binding of mouse GH to either membrane bound or 3-[(3-cholamidopropyl) dimethylammonio]-1-propanesulfonate-solubilized GHRs.     

Identification of a cell-surface antigen produced by a gene on human chromosome 3 (cen-q22) and not expressed by Rhnull cells.

A monoclonal antibody, 1D8, which recognizes a cell-surface antigen expressed by human chromosome 3 in Chinese hamster-human somatic-cell hybrids, has been produced. Testing of hybrids containing various deletions of chromosome 3 determines that the gene encoding the antigen is regionally localized to 3q (cen-22). This regional mapping is distinct from that elsewhere reported for two other cell-surface antigens assigned to chromosome 3--namely, the human transferrin receptor and the p97 melanoma-associated antigen. In addition, biochemical characterization is different from that elsewhere reported for other chromosome 3-encoded cell-surface antigens. When tested against a panel of rare-phenotype red blood cells, the only cells that failed to react were those of the Rhnull phenotype. The antibody reacts only weakly with homozygous -D- and fetal red cells, in contrast with a previously described antibody, R6A, which does not react with Rhnull cells. Furthermore, R6A does not recognize a cell-surface antigen expressed by chromosome 3 in Chinese hamster-human somatic-cell hybrids. Thus, the monoclonal antibody 1D8 recognizes a previously undescribed cell-surface antigen encoded by human chromosome 3 and not expressed on Rhnull cells. The gene on chromosome 3 regulating expression of this antigen may be that defective in Rhnull disease or may require the normal allele at an unlinked Rhnull locus for expression. Linkage studies will be required to further elucidate this matter.     

Hormonal regulation of TSE1-repressed genes: evidence for multiple genetic controls in extinction.

Somatic cell hybrids formed by fusing hepatoma cells with fibroblasts generally fail to express liver functions, a phenomenon termed extinction. Previous studies demonstrated that extinction of the genes encoding tyrosine aminotransferase, phosphoenolpyruvate carboxykinase, and argininosuccinate synthetase is mediated by a specific genetic locus (TSE1) that maps to mouse chromosome 11 and human chromosome 17. In this report, we show that full repression of these genes requires a genetic factor in addition to TSE1. This conclusion is based on the observation that residual gene activity was apparent in monochromosomal hybrids retaining human TSE1 but not in complex hybrids retaining many fibroblast chromosomes. Furthermore, TSE1-repressed genes were hormone inducible, whereas fully extinguished genes were not. Analysis of hybrid segregants indicated that genetic loci required for the complete repression phenotype were distinct from TSE1.     

Selective linkage disruption in human-Chinese hamster cell hybrids: deletion mapping of the leuS, hexB, emtB, and chr genes on human chromosome 5.

Chinese hamster-human interspecific hybrid cells, which contain human chromosome 5 and express four genes linked on that chromosome, were subjected to selective conditions requiring them to retain one of the four linked genes, leuS (encoding leucyl-tRNA synthetase), but lose another, either emtB (encoding ribosomal protein S14) or chr. Cytogenetic and biochemical analyses of spontaneous segregants isolated by using these unique selective pressures have enabled us to determine the order and regional location of the leuS, hexB, emtB, and chr genes on human chromosome 5. These segregants arise primarily by terminal deletions of various portions of the long arm of chromosome 5. Our results indicate that the order of at least three of these genes is the same on human chromosome 5 and Chinese hamster chromosome 2. Thus, there appears to be extensive homology between Chinese hamster chromosome 2 and human chromosome 5, which represents an extreme example of the conservation of gene organization between very divergent mammalian species. In addition, these hybrids and selective conditions provide a very simple and quantitative means to assess the potency of various agents suspected of inducing gross chromosomal damage.     

Loss of the transferrin receptor during the maturation of sheep reticulocytes in vitro. An immunological approach.

Sheep reticulocyte-specific antiserum absorbed with mature sheep red cells has been used to isolate and identify reticulocyte-specific plasma-membrane proteins and to monitor their loss during incubation in vitro. Specific precipitation of labelled plasma-membrane proteins is obtained when detergent-solubilized extracts of 125I-labelled reticulocyte plasma membranes are incubated with this antiserum and Staphyloccus aureus, but not when mature-cell plasma membranes are treated similarly. During maturation of reticulocytes in vitro (up to 4 days at 37 degrees C), there is a marked decrease in the immunoprecipitable material. The anti-reticulocyte-specific antibodies have been identified as anti-(transferrin receptor) antibodies. By using these antibodies as a probe, the transferrin receptor has been shown to have a subunit molecular weight of 93 000. The data are consistent with reported molecular weights of this receptor and with the proposal that the receptor may exist as a dimer, since [125I]iodotyrosyl-peptide maps of the 93 000- and 186 000-mol.wt. components isolated are shown to be identical. Evidence is presented for the transmembrane nature of the receptor and for the presence of different binding sites for transferrin and these antibodies on the receptor.