The gene for autosomal dominant craniometaphyseal dysplasia maps to chromosome 5p and is distinct from the growth hormone-receptor gene.

Craniometaphyseal dysplasia (CMD) is an osteochondrodysplasia of unknown etiology characterized by hyperostosis and sclerosis of the craniofacial bones associated with abnormal modeling of the metaphyses. Sclerosis of the skull may lead to asymmetry of the mandible, as well as to cranial nerve compression, that finally may result in hearing loss and facial palsy. We have analyzed a large German kindred with autosomal dominant (AD) CMD and found tight linkage between the disorder and microsatellite markers on chromosome 5p (maximum two-point LOD score 4.82; theta = 0). Our results clearly establish the existence of a locus for AD CMD on central chromosome 5p (5p15.2-p14.1). This region overlaps with the mapping interval of the growth hormone-receptor (GHR) gene (5p14-p12), which is known to be involved in the mitogenic activation of osteoblasts. Therefore, we tested the GHR gene as a candidate gene. However, recombination events between the CMD locus and the GHR gene identified in two members of this family clearly exclude this candidate.     

A high frequency of distinct ATM gene mutations in ataxia-telangiectasia.

The clinical features of the autosomal recessive disorder ataxia-telangiectasia (AT) include a progressive cerebellar ataxia, hypersensitivity to ionizing radiation, and an increased susceptibility to malignancies. Epidemiological studies have suggested that AT heterozygotes may also be at increased risk for malignancy, possibly as a consequence of radiation exposure. A gene mutated in AT patients (ATM) has recently been isolated, making mutation screening in both patients and the general population possible. Because of the relatively large size of the ATM gene, the design of screening programs will depend on the types and distribution of mutations in the general population. In this report, we describe 30 mutations identified in a panel of unrelated AT patients and controls. Twenty-five of the 30 were distinct, and most patients were compound heterozygotes. The most frequently detected mutation was found in three different families and had previously been reported in five others. This corresponds to a frequency of 8% of all reported ATM mutations. Twenty-two of the alterations observed would be predicted to lead to protein truncation at sites scattered throughout the molecule. Two fibroblast cell lines, which displayed normal responses to ionizing radiation, also proved to be heterozygous for truncation mutations of ATM. These observations suggest that the carrier frequency of ATM mutations may be sufficiently high to make population screening practical. However, such screening may need to be done prospectively, that is, by searching for new mutations rather than by screening for just those already identified in AT families.     

The human apolipoprotein A-II gene is located on chromosome 1

Apolipoprotein (apo) A-II is a major constituent of high density lipoproteins (HDL). The gene for apoA-II has been localized to the p21----qter region of chromosome 1 in man by Southern blot hybridization analysis of DNA from human-mouse cell hybrids using a cloned human apoA-II cDNA probe. The regional assignment was established using two hybrids carrying a reciprocal translocation involving chromosomes 1 and 2. Comparison with previously established gene loci on chromosomes 1 suggests that apoA-II may reside in a conserved linkage group with renin and peptidase C. On the other hand, apoA-II is not linked to the apoA-I gene, which has been localized previously to chromosome 11.     

The human liver-type pyruvate kinase (PKL) gene is on chromosome 1 at band q21

Pyruvate kinase (PK) is an important enzyme for ATP production in the glycolytic pathway. Deficiency of this enzyme in erythrocytes is characterized by hemolytic anemia. Using in situ hybridization, we have mapped the human liver-type pyruvate kinase gene (PKL) to band q21 of chromosome 1.     

Aurintricarboxylic acid (ATA) and DNA synthesis. II. Effect of ATA on structure and function of the crypts of the small intestine.

ATA affects only slightly DNA synthesis of continuously replicating cells. A single injection of the drug reduces the incorporation of (3H)-thymidine into DNA of crypt cells to only 62% of the control. The effect on DNA synthesis is preceded by a slight inhibition of protein synthesis, and by a partial decrease in the number of dividing cells. On the contrary, the incorporation of (3H)-uridine into RNA was enhanced. Electron microscopic studies revealed no cytologic abnormalities in ATA-treated animals. In view of the fact that ATA at the same concentration inhibits DNA synthesis of growth stimulated cells to 100% (Novi, 1976), it was suggested that the drug may become an useful tool in inducing a preferential inhibition of growth stimulation.     

The gene encoding human protective protein (PPGB) is on chromosome 20

Normal lymphocyte prometaphase chromosome spreads were hybridized in situ using single- and double-color fluorescence techniques. The results obtained with either the 1.8-kb protective protein cDNA or a 12-kb genomic fragment of the human protective protein gene as probe demonstrate that the PPGB gene is localized on the long arm of chromosome 20. This assignment was confirmed by hybridization with whole chromosome DNA libraries.     

The gene for the ataxia-telangiectasia variant,Nijmegen breakage syndrome,maps to a 1-cM interval on chromosome 8q21.

Nijmegen breakage syndrome (NBS; Seemanová II syndrome) and Berlin breakage syndrome (BBS), also known as ataxia-telangiectasia variants, are two clinically indistinguishable autosomal recessive familial cancer syndromes that share with ataxia-telangiectasia similar cellular, immunological, and chromosomal but not clinical findings. Classification in NBS and BBS was based on complementation of their hypersensitivity to ionizing radiation in cell-fusion experiments. Recent investigations have questioned the former classification into two different disease entities, suggesting that NBS/BBS is caused by mutations in a single radiosensitivity gene. We now have performed a whole-genome screen in 14 NBS/BBS families and have localized the gene for NBS/BBS to a 1-cM interval on chromosome 8q21, between markers D8S271 and D8S270, with a peak LOD score of 6.86 at D8S1811. This marker also shows strong allelic association to both Slavic NBS and German BBS patients, suggesting the existence of one major mutation of Slavic origin. Since the same allele is seen in both former complementation groups, genetic homogeneity of NBS/BBS can be considered as proved.     

The pronatriodilatin gene is located on the distal short arm of human chromosome 1 and on mouse chromosome 4.

Atrial natriuretic factors (ANF) are polypeptides having natriuretic, diuretic, and smooth muscle-relaxing activities that are synthesized from a single larger precursor: pronatriodilatin. Chromosomal assignment of the gene coding for human pronatriodilatin was accomplished by in situ hybridization of a [3H]-labeled pronatriodilatin probe to human chromosome preparations and by Southern blot analysis of somatic cell hybrid DNAs with normal and rearranged chromosomes 1. The human pronatriodilatin gene was mapped to the distal short arm of chromosome 1, in band 1p36. Southern blot analysis of mouse X Chinese hamster somatic cell hybrids was used to assign the mouse pronatriodilatin gene to chromosome 4. This assignment adds another locus to the conserved syntenic group of homologous genes located on the distal half of the short arm of human chromosome 1 and on mouse chromosome 4.     

The sex chromosome association (Sxa) gene is located on the X-chromosome in mice

The genetic factor "Sxa" controlling the end-to-end association of the sex chromosome in mice is linked closely (R.V. = 4.6%) to Crm (cream), which is located near the distal end of the X chromosome.     

The gene for human liver arginase (ARG1) is assigned to chromosome band 6q23.

The human liver arginase gene, whose deficiency is responsible for argininemia (McKusick no. 20780), has been assigned to 6q23 through a combination of somatic cell hybrid analysis and in situ hybridization using a 1,550-base pair (bp) human DNA probe for this gene.     

The gene for human carbonic anhydrase II (CA2) is located at chromosome 8q22

The gene CA2 for the human carbonic anhydrase II isozyme is encoded in band q22 of chromosome 8. These data and supporting evidence predict that the genes for carbonic anhydrase I and III are also physically closely linked in this chromosomal region.     

The gene for human chromogranin A (CgA) is located on chromosome 14

Chromogranin A (CgA) is a protein that is present in most neuroendocrine tissues and is co-secreted with their resident hormones. We have assigned the CgA gene to human chromosome 14 by hybridization of a CgA cDNA probe cloned from a cDNA library of human medullary thyroid carcinoma cells to spots of individual human chromosomes flow-sorted onto nitrocellulose filters. Southern analysis of human genomic DNA with the same probe revealed only 1-3 restriction bands. These studies indicate that the CgA gene is probably single copy and not a member of a dispersed, multigene family. The CgA gene is not co-localized with the genes of any of the CgA-associated hormones.     

The gene for aromatase (P450arom) in the chicken is located on the long arm of chromosome 1

An 125I-labeled partial cDNA for the chicken aromatase P450 was used for in situ hybridization to chromosomes from primary chicken embryo fibroblast cultures. The results indicate that the gene that encodes aromatase is located on the long arm of chromosome 1 at approximately position 0.16.     

The axon degeneration gene SARM1 is evolutionarily distinct from other TIR domain-containing proteins

Many forms of neurodegenerative disease are characterized by Wallerian degeneration, an active program of axonal destruction. Recently, the important player which enacts Wallerian degeneration was discovered, the multidomain protein SARM1. Since the SARM1 protein has classically been thought of as an innate immune molecule, its role in Wallerian degeneration has raised questions on the evolutionary forces acting on it. Here, we synthesize a picture of SARM1’s evolution through various organisms by examining the molecular and genetic changes of SARM1 and the genes around it. Using proteins that possess domains homologous to SARM1, we established distances and Ka/Ks values through 5671 pairwise species–species comparisons. We demonstrate that SARM1 diverged across species in a pattern similar to other SAM domain-containing proteins. This is surprising, because it was expected that SARM1 would behave more like its TIR domain relatives. Going along with this divorce from TIR, we also noted that SARM1’s TIR is under stronger purifying selection than the rest of the TIR domain-containing proteins (remaining highly conserved). In addition, SARM1’s synteny analysis reveals that the surrounding gene cluster is highly conserved, functioning as a potential nexus of gene functionality across species. Taken together, SARM1 demonstrates a unique evolutionary pattern, separate from the TIR domain protein family.     

The human neurofilament gene (NEFL) is located on the short arm of chromosome 8

We have localized the gene coding for the human neurofilament light chain (NEFL) to chromosome band 8p2.1 by Southern blotting of DNA from hybrid cell panels and in situ hybridization to metaphase chromosomes.