Clustering of cytokine genes on mouse chromosome 11.

The presence of positionally conserved amino acid residues suggests that the mouse proteins TCA3, P500, MIP1-alpha, MIP1-beta, and JE are members of a single gene family. These proteins are activation specific and can be expressed by both myeloid and lymphoid cells. MIP1-alpha/MIP1-beta and MCAF (the putative human homologue of JE) act as chemotactic and activating agents for neutrophils and macrophages, respectively. The functions of TCA3 and P500 are unknown. We have used interspecies somatic cell hybrids and recombinant inbred mouse strains to show that the genes encoding TCA3, MIP1-alpha, MIP1-beta, and JE (provisionally termed Tca3, Mip-1a, Mip-1b, and Sigje, respectively) map as a cluster on the distal portion of mouse chromosome 11 near the Hox-2 gene complex. DNA sequence analysis indicates that the P500 and TCA3 proteins are encoded by alternative splicing products of one genomic gene. Additionally, the genes encoding TCA3 and JE are found to be strikingly similar with respect to the positions of intron-exon boundaries. Together, these data support the model that the cytokines TCA3, P500, MIP1-alpha, MIP1-beta, and JE are encoded by a single cluster of related genes. The gene encoding IL-5 (Il-5), which acts as a T cell-replacing factor, a B cell growth factor, and an eosinophil differentiation factor, is also mapped to mouse chromosome 11.Il-5 maps approximately 25 cM proximal to the Tca-3 gene and appears tightly linked to a previously described gene cluster that includes Il-3, Il-4, and Csfgm. We discuss the potential relevance of the two cytokine gene clusters described here with particular attention to specific human hematologic malignancies associated with chromosomal aberrations at corresponding locations on human chromosomes 5 and 17.

Salivary proline-rich protein genes on chromosome 8 of mouse.

Endonuclease restriction (Hind III) fragments of DNA from Chinese hamster X mouse somatic cell hybrids hybridized with proline-rich protein complementary DNA clones only when the DNA was isolated from cells containing mouse chromosome 8, or a fragment of chromosome 8. The evidence suggests that proline-rich protein genes are located at the proximal portion of chromosome 8 toward the centromere.

Lysosomal Acid phosphatase deficiency: liver specific variant in the mouse.

The number and classes of genes responsible for the final expression of lysosomal acid phosphatase were investigated in the mouse (Mus musculus ). In mouse tissues, lysosomal acid phosphatase activity was separated by gel electrophoresis into two major zones of activity. The cathodal zone of activity in liver of the SM/J inbred strain was almost completely absent, while the anodal zone was increased in activity. Other tissues from SM/J were not affected, nor were livers and other tissues in 27 inbred mouse strains. Genetic studies indicated that this deficiency variant segregated as an autosomal codominant gene which has been designated Apl to symbolize the acid phosphatase liver phenotype. The Apl gene was not linked to markers on chromosomes 1, 2, 4, 5, 7, 8, or X. Electrophoretic, heat denaturation, neuraminidase treatment, tartrate inhibition studies and tissue mixing experiments suggested that the Apl gene was not a structural gene for acid phosphatase, but a separate gene that functions in liver and is responsible for controlling or modifying an acid phosphatase structural gene product.

Aryl hydrocarbon hydroxylase induction by benzo[a]anthracene: regulatory gene localized to the distal portion of mouse chromosome 17.

Aryl hydrocarbon (benzo[a]pyrene) hydroxylase inducibility by benzo[a]anthracene was studied in 29 somatic cell hybrid clones, developed by fusing mouse spleen or peritoneal cells from four different inbred strains with hypoxanthine phosphoribosyltransferase-deficient Chinese hamster E36 cells. Karyotype analysis plus 25 markers assigned to 16 autosomes and the X chromosome were examined. In 28 of the 29 clones, the presence or absence of inducibility is associated with the presence or absence, respectively, of mouse chromosome 17. Liver microsomal aryl hydrocarbon hydroxylase induction by 3-methylcholanthrene or benzo[a]anthracene was assessed in appropriate backcrosses with the Mus musculus molossinus, M. m. castaneus, MOR/Cv, PL/J, SM/J and DBA/2J inbred strains and in 13 NX8 recombinant inbred lines. Twenty-seven biochemical genetic markers representing all but four autosomes were tested for possible linkage with the hydroxylase inducibility, and no linkage was found. The hepatic Ah receptor was quantitated in 26 BXD recombinant inbred lines; the Ah phenotype did not match exactly any of the more than 70 genes with established strain distribution patterns representing 12 autosomes and at least five unlinked markers. It is concluded that a major gene controlling aryl hydrocarbon hydroxylase inducibility by benzo[a]anthracene is located on chromosome 17. Because there is no significant linkage with any of three biochemical markers in the upper third of the chromosome, we conclude that the inducibility gene is located in the distal 40% of mouse chromosome 17. Whether this trait represents the Ah locus, i.e., the gene encoding the cytosolic Ah receptor, will require further study.

Genetic markers in thyroid tumors.

Tissue from nine patients with malignant tumors and two with benign tumors was cultured briefly before cytogenetic analysis. The tumors included one goiter and one Hürthle cell adenoma, one lymphoma, one medullary carcinoma, two Hürthle cell cancers, and five papillary cancers, varying widely in clinical staging and histologic differentiation. When assessed, DNA content was aneuploid in two of six malignant tumors. Various culture conditions (oxygen levels, dissociation methods, and media) were evaluated; the end points were growth, cell differentiation, and time to first harvest. Clonal aberrations were detected in one of four successfully harvested papillary cancers: they consisted of trisomy 7 and a rearrangement of chromosome 10. The rea (10) seen in 22 of 27 cells involved bands q11-21. Two other papillary tumors and a medullary cancer (a family member with multiple endocrine neoplasia type IIA) showed tetraploidy and nonclonal numerically aberrant cells. A lymphoma and two benign lesions showed no cytogenetic abnormality. The tumor with rea (10) is of special interest because abnormalities of 10q have been reported repeatedly in thyroid tumors, including two cases of papillary thyroid tumors with a structural aberration similar to that of the presented case. This rearrangement could affect the ret-proto-oncogene, localized to 10q11.2 which is activated in some papillary thyroid carcinomas.

Significance of trisomy 7 in thyroid tumors.

Standard cytogenetic studies of a multifocal metastasizing papillary thyroid carcinoma revealed two clonal chromosome aberrations: rearranged 10q and trisomy 7. Trisomy 7 seemed to be restricted to tumor nodule A, whereas era (10q) was detected in tumor nodule B and in a metastatic lymph node. We applied fluorescent in situ hybridization to ask whether trisomy 7 was a feature of the original tumor nodule or an in vitro phenomenon changing quantitatively during early passages and to see whether trisomy 7 was restricted to tumor nodule A. We used the biotinylated chromosome 7 alpha-satellite probe D7Z1 on freshly dropped slides from metaphase harvests from tumor nodule A,B, and the lymph node and on touch preparations from the frozen specimen of tumor nodule A. Trisomy 7 was present in the original tumor nodule (6% of cells), as well as in early passages (P1-3) from both tumor nodules and the metastatic lymph node with a frequency of 10.7-13.2%. The detection of trisomy 7 as a stable component in short-term cell culture and its presence in the original tumor material indicates that this common numerical aberration is an in vivo phenomenon.

Chromosomal aberrations in two adrenocortical tumors, one with a rearrangement at 11p15.

Adrenocortical tumors are detected with increasing frequency, but symptomatic cases with excessive hormone production are rare. We investigated cytogenetically one benign aldosterone-producing tumor (Conn Syndrome)(case 1) and one malignant cortisol-producing tumor (Cushing Syndrome)(case 2). Radioimmunoassay of cell culture supernatant of case 2 detected cortisol secretion during 2 months in culture. Flow cytometry of spill-out cells from case 2 showed a bimodal pattern (DNA Index 1.0, 1.4). Case 1 revealed a marker chromosome in 4/25 cells analyzed; the marker was a long acrocentric partially derived from chromosome 2,der(2q). In case 2, a cytogenetic harvest was achieved after prolonged culture time (6 weeks) and a marker chromosome, add(11)(p15), was detected in 16/22 cells. A breakpoint of 11p13, as well as loss of heterozygosity of alleles on 11p15, has been reported in the literature for other malignant adrenocortical cancers.

Double minutes in the papillary thyroid cancer cell line PTC-1113A.

The cell line PTC-1113A was established from a metastasizing recurrent papillary thyroid cancer. The cell line was growing as monolayer and showed a complex karyotype with chromosome numbers ranging from 30 to 140/metaphase. A proportion of metaphases contained double minutes and/or pulverized chromosomes. Extrachromosomal DNA seemed to originate from a B-group chromosome. A chromosome 4 painting probe hybridized to extrachromosomal material, representing double minutes (dmin) and possibly minutes. In addition, fluorescence in situ hybridization (FISH) with the chromosome 4 library detected a translocation chromosome and a pulverized chromosome originating from chromosome 4. PTC-1113A is, to our knowledge, the single papillary thyroid cancer cell line demonstrating evidence of gene amplification.

Chromosomal aberrations in two sporadic gastrinomas.

Results of cell culture and cytogenetic analysis (standard and fluorescent in situ hybridization, FISH) of two sporadic gastrinomas are reported. Maintenance of hormonal activity was assessed by detection of gastrin levels during the first 3 months in culture. Case 1 showed clonal aberrations consisting of two marker chromosomes: marker 1 is a large metacentric chromosome and marker 2 is a small acrocentric chromosome. Case 2 showed a constitutional polymorphism with chromosome 15p+ and a clone in the tumor cell culture with trisomy for chromosome 3. To our knowledge, this is the first cytogenetic report of sporadic gastrinomas (Zollinger-Ellison syndrome).

Assignment of the mouse alpha A-crystallin structural gene to chromosome 17.

alpha A2-crystallin is one of the major water-soluble proteins of the mammalian lens. Using a cloned cDNA probe coding for mouse alpha A2-crystallin and Southern blot hybridization, DNA isolated from a panel of somatic cell hybrids prepared from mouse fibroblasts or mouse spleen cells fused with Chinese hamster fibroblasts was probed to determine the chromosomal localization of the alpha A2-crystallin structural gene. We have located this gene on mouse chromosome 17.

New gene assignments and syntenic groups in the baboon (Papio papio).

MDH2, SOD2, PEPS, and ITPA were assigned to Papio papio chromosomes 3, 4, 5, and 10, respectively, by their concordant segregation with previously assigned gene markers in a set of baboon X mouse somatic cell hybrids. The linkage of NP, IDH2, SORD, MPI, and PKM2 was confirmed, and three other independently segregating markers (MDH1, ACY1, and PEPB) were identified. Syntenic groups described in the baboon are compared to those found in man and in the rhesus monkey.

I/Lyn mouse phosphorylase kinase deficiency: mutation disrupts expression of the alpha/alpha'-subunit mRNAs.

A cDNA encoding the alpha subunit of mouse skeletal muscle phosphorylase kinase was used to compare the expression of alpha mRNAs in normal and phosphorylase kinase-deficient tissues of the I/Lyn mouse. The results demonstrate that two different molecular weight species of poly(A)+ RNA in normal mouse heart and skeletal muscle hybridize to the alpha cDNA. These two mRNAs direct the synthesis of alpha protein and its isoform alpha' in a cell-free translation system. Thus, alpha and alpha' are encoded by two distinct mRNAs. The abundance of both of these mRNAs is reduced dramatically in the phosphorylase kinase-deficient skeletal muscle and heart tissues from the I/Lyn mouse strain. This result indicates that a mechanism common to both alpha and alpha' expression is disrupted by the I/Lyn mutation. The I/Lyn deficiency is inherited as an X chromosome trait. By Southern mapping of Chinese hamster-mouse cell hybrids the alpha gene was localized to the mouse X chromosome, supporting the possibility that the I/Lyn mutation is in the alpha gene. These results are discussed in terms of a cis or trans mutation influencing the expression of either a single alpha/alpha' gene or two genes encoding alpha and alpha'.

Gene assignments and syntenic groups in the sacred baboon (Papio hamadryas).

Eighteen genes were assigned to chromosomes in the sacred baboon, Papio hamadryas, by their concordant segregation with the chromosomes in a set of baboon X Chinese hamster somatic cell hybrids. ACY1 was assigned to P. hamadryas chromosome 2 (PHA 2); SOD1 and MDH2 to PHA 3; ME1 and SOD2 to PHA 4; NP, MPI, PKM2, and HEXA to PHA 7; PP to PHA 9; ADA and ITPA to PHA 10; LDHB and TPI1 to PHA 11; MDH1 to PHA 13; ESD to PHA 17; and GPI and PEPD to PHA 20. Regional assignments were possible for ACY1 (PHA 2pter----q1) and MDH2 and SOD1 (PHA 3p). Five other independently segregating markers or syntenic groups (PGD, PGM1; and PEPC; PGM2 and PEPS; IDH1; LDHA and ACP2; and GSR) were also identified. Gene assignments and syntenic groups described in P. hamadryas are compared to those found in P. papio, the rhesus monkey, and man. A possible primate model for human lymphoid disease is discussed.

Human and mouse cellular myc protooncogenes reside on chromosomes involved in numerical and structural aberrations in cancer.

A molecular clone of viral myc (v-myc), the oncogene of avian myelocytomatosis virus, MC29, detected homologous human, mouse, and Chinese hamster cellular myc (c-myc) sequences by Southern filter hybridization. A v-myc probe, containing sequences from the 3' domain of the gene, hybridized to single human HindIII and mouse EcoRI genomic DNA fragments of the cellular myc genes whose segregation could be followed in interspecies somatic cell hybrids. Human c-myc segregated concordantly with the enzyme marker glutathione reductase and with a karyotypically normal chromosome 8. A rearrangement of human c-myc was observed in Burkitt's lymphoma cells possessing the t(8;14) translocation. These results suggest that human c-myc is located close to the breakpoint on chromosome 8 (q24) involved in the t(8;14) translocation. The mouse c-myc gene segregated concordantly with chromosome 15 in mouse-Chinese hamster cell hybrids. These gene assignments are noteworthy, as structural and numerical abnormalities of human chromosome 8 and mouse chromosome 15 are associated frequently with B-cell neoplasms.

Human salivary proline-rich protein genes on chromosome 12.

A DNA probe (PRP1) for the proline-rich protein (PRP) genes was used to analyze the segregation of human PRP genes in human X mouse somatic cell hybrids. Endonuclease restriction analysis of 22 independent hybrid clones segregating human chromosomes demonstrated that PRP genes segregate with human chromosome 12 only and were therefore assigned to that chromosome. The PRP1 probe should prove useful for further mapping studies of human chromosome 12.

Mouse immune interferon (IFN-gamma) gene is on chromosome 10.

A cDNA clone for mouse immune interferon has been used to map the mouse interferon gamma gene (Ifg) to a specific chromosome. This clone, which contains a 638-bp insert detects an 18-kb HindIII fragment of mouse DNA. The presence of the mouse Ifg gene in cel hybrids and its chromosomal location were determined by assaying cell hybrid DNA for the presence of the 18-kb HindIII fragment by Southern filter hybridization. Under the hybridization conditions used, Chinese hamster DNA did not hybridize to the cDNA probe. The segregation of mouse chromosomes in cell hybrids indicated that Ifg is located on chromosome 10. Previously, we have mapped immune interferon to the p12.05----qter region of chromosome 12 in humans (1). This region of chromosome 12 also contains the genes for peptidase B and citrate synthase. The homologous genes in mouse are also located on chromosome 10, suggesting that these genes comprise a conserved linkage group.

Localization of cytochrome P1-450 and P3-450 genes to mouse chromosome 9.

Treatment of mice with polycyclic aromatic hydrocarbons results in the induction of P1-450 and P3-450 forms of cytochrome P-450. The genes for both cytochromes have recently been cloned and shown to be coordinately regulated by the Ah receptor. The mouse analogues of P1-450 and P3-450 can be distinguished from their hamster counterparts by Southern blot analysis with Kpn I-digested DNA fragments. DNA from hamster-mouse somatic cell hybrids that have selectively lost mouse chromosomes was used in Southern blots to map the location of the two mouse genes. Chromosome segregation analysis of 12 hybrid clones demonstrated that the structural genes for both P1-450 and P3-450 can be assigned to mouse chromosome 9.

Chromosomal assignments of genes coding for components of the mixed-function oxidase system in mice. Genetic localization of the cytochrome P-450PCN and P-450PB gene families and the nadph-cytochrome P-450 oxidoreductase and epoxide hydratase genes.

Filter-hybridization studies show that major phenobarbital and pregnenolone-16alpha-carbonitrile-inducible cytochrome P-450 mRNAs in rats were encoded by members of separate, distinct gene families. These gene families are genetically divergent from each and show no cross-hybridization, even under low-stringency conditions. Furthermore, sequences contained in the P-450PB and P-450PCN gene families map to separate chromosomes of the mouse genome. Using mouse X Chinese hamster somatic cell hybrids (EBS cell lines), all distinguishable P-450PCN sequences were found to map to chromosome 6, whereas all P-450PB sequences were located on chromosome 7. Our data support the proposition that the region of the Coh locus on chromosome 7 is the site of the cytochrome P-450PB gene family. The presence of gene families for the cytochromes P-450 occurs in many mammalian species and is likely an important part of the mechanism by which the mixed-function oxidase system is capable of recognizing and metabolizing such a wide array of endogenous and foreign compounds. Conversely, NADPH-cytochrome P-450 oxidoreductase appears to be encoded in many vertebrate species by a single gene and is located on chromosome 6 of the mouse. Corroboratory data are presented to show that the Eph-1 locus on chromosome 1 is the site of at least one microsomal epoxide hydratase gene.

Comparative mapping using somatic cell hybrids.

Comparative mapping, or ascertaining the gene linkage relationships between different species, is rapidly developing. This is possible because new techniques in chromosome identification and somatic cell hybridization, such as the generation of hybrids preferentially segregating chromosomes of any desired species including rodents, and the development of gene transfer techniques have yielded new information about the human and rodent gene maps. In addition, the discovery and characterization of mouse subspecies has generated new mouse sexual genetic linkage data. The following picture is emerging. Several X-linked genes in man are X-linked in all mammalian species tested. The linkage relationships of several tightly linked genes, less than 1 map unit apart, are also conserved in all mammalian species tested. Ape autosomal genes are assigned to ape chromosomes homologous to their human counterparts indicating extensive conservation in the 12 million years (MYR) of evolution from apes to man. Similarly, mouse and rat, 10 MYR apart in evolution, have several large autosomal synteny groups conserved. In comparing the mouse and human gene maps we find that human genes assigned to different arms of the same human chromosome are unlinked in the mouse; mouse genes large map distances (20 to 45 cM) apart are very likely to be unlinked in the human. However, several autosomal synteny groups 10 to 20 cM apart, including the Pgd, Eno-1, Pgm-1 group on human chromosome arm 1p, are conserved in mice and man. This suggests that homology mapping, the superimposition of one species gene map on the homologous conserved portion of another species genome may be possible, and that ancestral autosomal synteny groups should be detectable.