Assignment of the human dihydrofolate reductase gene to the q11----q22 region of chromosome 5

Human rDNA: Evolutionary Patterns within the Genes and Tandem Arrays Derived from Multiple Chromosomes

Human rDNA forms arrays on five chromosome pairs and is homogenized by concerted evolution through recombination and gene conversion (loci RNR1, RNR2, RNR3, RNR4, RNR5, OMIM: 180450). Homogenization is not perfect, however, so that it becomes possible to study its efficiency within genes, within arrays, and between arrays by measuring and comparing DNA sequence variation. Previous studies with randomly cloned genomic DNA fragments showed that different parts of the gene evolve at different rates but did not allow comparison of rDNA sequences derived from specific chromosomes. We have now cloned and sequenced rDNA fragments from specific acrocentric chromosomes to (1) study homogenization along the rDNA and (2) compare homogenization within chromosomes and between homologous and nonhomologous chromosomes. Our results show high homogeneity among regulatory and coding regions of rDNA on all chromosomes, a surprising homogeneity among adjacent distal non-rDNA sequences, and the existence of one to three very divergent intergenic spacer classes within each array.

Isolation and characterization of a human heart cDNA encoding a new member of the small heat shock protein family--HSPL27

A novel cDNA clone was isolated from a human adult heart cDNA library. This cDNA clone is similar to the small heat shock protein (smhsp) in both DNA and amino acid sequences, especially in the conserved region. Sequence analysis has shown that the putative novel smhsp, named 27 kDa heat-shock-protein-like protein (HSPL27) is a protein of 241 amino acids with a deduced molecular mass of 26.7 kDa and a deduced pI of 8.0. We have expressed the HSPL27 in E. coli and the expressed protein was found to be present in the soluble fraction of the bacterial cell lysate. Chromosomal mapping data shows that the HSPL27 gene is located at human chromosome 5q11.2.

Natural resistance to infection with Legionella pneumophila: chromosomal localization of the Lgn1 susceptibility gene

Legionella pneumophila is a strict intracellular pathogen that replicates in the professional phagocytes of the human and guinea pig host. Although murine macrophages from most inbred strains are non-permissive to intracellular replication of L. pneumophila, inflammatory macrophages from the mouse strain A/J are completely permissive to intracellular replication of this bacterium. This genetic difference is controlled by the expression of a single autosomal gene designated Lgn1, with non-permissiveness behaving as completely dominant over permissiveness. We have used a total of 25 AXB/BXA recombinant inbred mouse strains and 182 (A/J x C57BL/6J) x A/J segregating backcross progeny (A/J, permissive; C57BL/6J, non-permissive) to map the Lgn1 gene. Animals were individually typed for tolerance to intracellular replication by in vitro infection of their inflammatory macrophages with L. pneumophila. All animals segregated into two nonoverlapping groups. Examination of the strain distribution pattern of the AXB/BXA strains for Lgn1 initially identified linkage to Chromosome (Chr) 13 markers. Genotyping of the 25 AXB/BXA strains and the 182 backcross progeny for 11 Chr 13 markers established that Lgn1 mapped to Chr 13, with the gene order and intergene distance D13Mit231-(5.5 +/- 1.5)-D13Mit193-(2.2 +/- 0.9)-D13Mit194- (1.1 +/- 0.6)-D13Mit128-(2.6 +/- 1.0)-Lgn1-(2.2 +/- 0.9)-D13Mit70-(3.9 +/- 1.3)- D13Mit73-(7.2 +/- 1.7)-D13Mit53-(0.7 +/- 0.5)-D13Mit32-(0.7 +/- 0.5)-D13Mit77- (0.7 +/- 0.5)-D13Mit78. This portion of Chr 13 is homologous to the distal portion of human Chr 5, 5q11-5q13, suggesting a possible location of a human LGN1 homolog. Understanding the molecular basis of the high permissiveness of A/J macrophage to L. pneumophila may shed light on the survival strategy of this bacterium in highly permissive human phagocytes. This may be achieved by positional cloning of Lgn1, and the identification of the Lgn1 subchromosomal region reported here is a first step towards that goal.

A genetic linkage map of human chromosome 5 with 60 RFLP loci

A genetic map of human chromosome 5 that contains 60 restriction fragment length polymorphism (RFLP) loci in one linkage group has been constructed. Segregation data using these markers and 40 large multigenerational families supplied by the Centre d'Etude du Polymorphisme Humain have been collected. Linkage analyses were performed with the program package CRI-MAP; using odds greater than 1000:1, 30 RFLP loci could be placed on the map. This genetic map spans 289 cM sex-equal, 353 cM in females, and 244 cM in males. While the relative rate of recombination for female meioses is nearly twice that of males over much of the chromosome, several instances of statistically significant excess male recombination were observed. The order of probes on the genetic map has been confirmed by their physical order as determined by somatic cell hybrid lines containing deletions of normal chromosome 5. There is concordance between the physical positions of markers and their genetic positions. Our most distal probes on the genetic map are cytologically localized to the most distal portions of the chromosome. This suggests that our genetic map spans most of chromosome 5.

Cystic fibrosis and Helicobacter pylori gastritis, megaloblastic anaemia, subnormal mentality and minor anomalies in two siblings: a new syndrome?

Two siblings of consanguineous Arab parents were found to have cystic fibrosis and gastritis associated with Helicobacter pylori, folate deficiency megaloblastic anaemia, subnormal mentality and minor anomalies. The association of H. pylori and megaloblastic anaemia has not been described in patients with cystic fibrosis. H. pylori infection and gastritis is probably more common in patients with cystic fibrosis than appreciated. We believe that the constellation of features in the two sibs represent a possible new autosomal recessive cystic fibrosis-like syndrome.

Chromosomal localization and racial distribution of the polymorphic human dihydrofolate reductase pseudogene (DHFRP1)

The human dihydrofolate reductase (DHFR) gene family comprises one functional gene and at least four intronless processed pseudogenes. The functional DHFR gene is on chromosome 5, and DHFRP4 is on chromosome 3. Using in situ hybridization, we have now localized the functional DHFR gene to the region q11.1-q13.3 on chromosome 5. By genomic DNA analysis of a panel of human X rodent somatic-cell hybrids, we determined the chromosomal assignment of the DHFRP1 pseudogene to chromosome 18 and that of the DHFRP2 pseudogene to chromosome 6. The DHFRP1 pseudogene exhibits a novel form of polymorphism in humans in that it is present in the DNA of some individuals and absent in that of others. We investigated the racial distribution of this pseudogene in five racial groups. The allelic frequency as defined by analysis of 180 chromosomes was found to be 94% in Mediterraneans, 77% in Asian Indians, 67% in Chinese, 57% in Southeast Asians, and 32% in American blacks. These data suggest that the transposition of this "perfect" pseudogene occurred prior to the inception of the human racial groups.

Regional assignment of the gene for diphtheria toxin sensitivity using subchromosomal fragments in microcell hybrids

Human x mouse microcell hybrids resistant to G418 were constructed between mouse hepatoma cells and human x mouse whole cell hybrids containing only intact human chromosome 5 and 22 with an integrated neor-gene. Among these, microcell hybrid BG15 produced four subclones, BG15-4, BG15-6, BG15-7 and BG15-9, which contained variously sized complements of human chromosome 5. BG15-6 contained an intact human chromosome 5, BG15-7 a deleted human chromosome 5 (5pter-q22) and BG15-4 and BG15-9 a translocation between parts of human chromosome 5 (pter-qter? and pter-q23, respectively) and a mouse chromosome. Southern DNA blot analysis showed that the human dihydrofolate reductase (DHFR) gene was present in all four subclones, whereas the human homolog of the v-fms gene was present in BG15-4 and 15-6, but absent from BG15-7 and 15-9. BG15-4, 15-6 and 15-9 were sensitive to diphtheria toxin, and only BG15-7 was resistant to the toxin. We used these microcell hybrids to restrict further the regional location of the gene for diphtheria toxin sensitivity to the q23 region of human chromosome 5.

Chromosome maps of man and mouse, III

Data on loci whose positions are known in both man and mouse are presented in the form of chromosomal displays, a table, and autosomal and X-chromosomal grids. At least 40 conserved autosomal segments with two or more loci, as well as 17 homologous X-linked loci, are now known in the two species, in which mitochondrial DNA is also highly conserved. Apart from the Y, the only chromosome now lacking a conserved group is human 13. Human 17 has a single conserved group which includes both short and long arms, and so may have remained largely intact in mammalian evolution. Human and mouse chromosomal maps show the approximate locations of homologous genes while the mouse map also shows the positions of translocations used in gene location.

Localization of Chinese hamster dihydrofolate reductase gene to band p23 of chromosome 2

It has been shown that gamma irradiation causes extensive deletions at the dihydrofolate reductase (dhfr) locus in Chinese hamster ovary (CHO) cells. We have analyzed seventeen DHFR-negative (DHFR-) mutants of CHO cells for cytogenetic alterations involving the dhfr locus on chromosome 2. Five DHFR- mutants contained the same large deletion [del(2)(p16p23)] in the short arm of chromosome 2. This deletion comprised about 18% of the short arm and was estimated to be 41,000 kb in length. Four other DHFR- mutants contained smaller deletions of about 9200 kb. One of these mutants had a partial deletion of bands 2p22 and 2p23, whereas the others showed deletion of band 2p23. Inversions of chromosome 2 were seen in two other DHFR- mutants. An analysis of the breakpoints involved in these cytogenetic alterations indicates that the hamster dhfr gene resides in band p23 of chromosome number 2.

Assignment of genes encoding dihydrofolate reductase and hexosaminidase B to Mus musculus chromosome 13

The murine gene encoding dihydrofolate reductase (DHFR) has been localized to a particular mouse chromosome by complementation mapping. Microcells prepared from diploid mouse fibroblasts were fused with mutant hamster cells lacking the dihydrofolate reductase gene (Dhfr), and DHFR+ microcell hybrids were selected in medium lacking purines and pyrimidines. The complemented hybrids expressed wild-type levels of DHFR enzyme activity, and selectively retained a single mouse chromosome--chromosome 13. Genomic Southern blots of DNAs prepared from these hybrids and from an independently derived collection of clones isolated without selection on the DHFR phenotype confirmed the assignment of murine Dhfr gene sequences to chromosome 13. This assignment provides further evidence for the existence of genetic homology between regions of mouse chromosome 13 and human chromosome 5. In support of this view, we show that the gene encoding hexosamindase B, a chromosome 5 marker in man, also maps to mouse chromosome 13.

Expression of the human c-fms proto-oncogene in hematopoietic cells and its deletion in the 5q- syndrome

The c-fms proto-oncogene was shown to be expressed in human bone marrow and in differentiated blood mononuclear cells, suggesting that its gene product plays a role in hematopoietic maturation. The c-fms mRNA was not detected in HL-60 cells, an established promyelocytic line, whereas c-fms expression appeared 48 hr after induction when most cells had differentiated into macrophages. An acquired deletion of chromosome 5 (5q-) in bone marrow cells is associated with abnormalities in blood cell production. The normal 5 and 5q- chromosomes were segregated by construction of cell hybrids between bone marrow and rodent cells. A selective system was used that requires retention of the structural gene for dihydrofolate reductase, located on human chromosome 5. Analysis of DNA from individual hybrid clones revealed that the 5q- deletion had removed the c-fms gene. We postulate that hemizygosity at the c-fms locus leads to abnormalities in hematopoietic maturation.

Methotrexate resistant cells as targets for selective chemotherapy

Strategies that are selective for eradicating methotrexate resistant cells are described. These strategies have been developed based on knowledge of the mechanism of drug resistance encountered in experimental systems and in the clinic. Drug resistance to methotrexate in experimental tumors is commonly due to either gene amplification (dihydrofolate reductase) or to impaired transport of methotrexate. While no effective drugs or methods to prevent gene amplification have been described, the concept of developing "pro drugs", i.e. a drug that is selectively reduced by dihydrofolate reductase to an inhibitor of another critical folate enzyme (thymidylate synthase, methionine synthetase, folylpolyglutamate synthetase) remains worthwhile. Second generation antifolates such as trimetrexate which are effective vs methotrexate transport resistant cells have already been developed and are in clinical trial.