The Human Hepatocyte Nuclear Factor 3/Fork Head Gene FKHL13: Genomic Structure and Pattern of Expression

We describe the isolation and characterization of the cDNA for FKHL13, the human homologue of the mouse hepatocyte nuclear factor 3/fork headhomologue 4 (HFH-4) gene, a member of the HNF-3/fork head(also called winged helix) gene family. Members of this gene family contain a conserved DNA binding region of approx. 110 amino acids and are thought to play an important role in cell-specific differentiation. Previous analysis of the mouse and rat HFH-4 cDNAs revealed a distinct pattern of expression for this gene, suggesting that the gene plays an important role in the differentiation of lung and oviduct/ampulla epithelial cells and testicular spermatids. Analysis of the human FKHL13 gene confirmed this pattern of expression. We also found expression in adult human brain cortex, which we were able to confirm for the mouse. The expression pattern of FKHL13/HFH-4, confined to cilia/flagella-producing cells, leads us to believe that the gene plays an important role in the regulation of axonemal structural proteins. We show that the human gene for FKHL13 lies on chromosome 17 (comparison with the chromosomal location of the mouse gene strongly suggests 17q22–q25) and that the gene, which is approx. 6 kb, contains a single intron disrupting thefork headDNA binding domain. Such a disruption of a functional unit provides strong evidence for the theory of intron insertion during gene evolution. The expression of the gene is probably controlled by the CpG island, which is located in the promoter region of the gene. We also demonstrate that the FKHL13 gene is highly conserved among a wide variety of species, including birds.     

Structure and Methylation-Based Silencing of a Gene (DBCCR1) within a Candidate Bladder Cancer Tumor Suppressor Region at 9q32–q33

Loss of heterozygosity (LOH) on chromosome 9q is the most frequent genetic alteration in transitional cell carcinoma (TCC) of the bladder, indicating the presence of one or more relevant tumor suppressor genes. We previously mapped one of these putative tumor suppressor loci to 9q32–q33 and localized the candidate region within a single YAC 840 kb in size. This locus has been designatedDBC1(for deleted in bladder cancer gene 1). We have identified a novel gene,DBCCR1,in this candidate region by searching for expressed sequence tags (ESTs) that map to YACs spanning the region. Database searching using the entireDBCCR1cDNA sequence identified several human ESTs and a few homologous mouse ESTs. However, the predicted 761-amino-acid sequence had no significant homology to known protein sequences. Mutation analysis of the coding region and Southern blot analysis detected neither somatic mutations nor gross genetic alterations in primary TCCs. AlthoughDBCCR1was expressed in multiple normal human tissues including urothelium, mRNA expression was absent in 5 of 10 (50%) bladder cancer cell lines. Methylation analysis of the CpG island at the 5′ region of the gene and the induction ofde novoexpression by a demethylating agent indicated that this island might be a frequent target for hypermethylation and that hypermethylation-based silencing of the gene occurs in TCC. These findings makeDBCCR1a good candidate forDBC1.     

Cloning, Mapping, and Expression of Two Novel Actin Genes, Actin-like-7A (ACTL7A) and Actin-like-7B (ACTL7B), from the Familial Dysautonomia Candidate Region on 9q31

Two novel human actin-like genes, ACTL7A and ACTL7B, were identified by cDNA selection and direct genomic sequencing from the familial dysautonomia candidate region on 9q31. ACTL7A encodes a 435-amino-acid protein (predicted molecular mass 48.6 kDa) and ACTL7B encodes a 415-amino-acid protein (predicted molecular mass 45.2 kDa) that show greater than 65% amino acid identity to each other. Genomic analysis revealed ACTL7A and ACTL7B to be intronless genes contained on a common 8-kb HindIII fragment in a “head-to-head” orientation. The murine homologues were cloned and mapped by linkage analysis to mouse chromosome 4 in a region of gene order conserved with human chromosome 9q31. No recombinants were observed between the two genes, indicating a close physical proximity in mouse. ACTL7A is expressed in a wide variety of adult tissues, while the ACTL7B message was detected only in the testis and, to a lesser extent, in the prostate. No coding sequence mutations, genomic rearrangements, or differences in expression were detected for either gene in familial dysautonomia patients.     

Genetic Alterations at Chromosome 6 Associated with Cervical Cancer Progression

Loss of heterozygosity (LOH) analysis on chromosome 6 was performed to define the genetic changes that occur in the development of squamous cell cervical cancer (SCC). Detailed analysis with 28 microsatellite markers revealed several loci with high frequency of deletions at the short (6p25, 6p22, 6p21.3) and long (6q14, 6q16–q21, 6q23–q24, 6q25, 6q27) arms of chromosome 6. Examination of microdissected 37 SCC and 22 cervical intraepithelial neoplasias (CIN) revealed allelic deletions in the HLA class I–III region (6p22–p21.3) and at subtelomeric locus 6p25-ter in more than 40% of CIN. By a combination of LOH and microdissection of multiple samples from the same tumor sections, we studied the intratumoral genetic heterogeneity of SCC, and identified clonal and subclonal allelic deletions. Half of SCC had clonal allelic deletion at D6S273, which is localized in intron of Ly6G6D (MEGT1) gene mapped in the HLA class III region. The LOH frequency at 6q in CIN cases did not exceed 20%. Allelic deletions at two loci, 6q14 and 6q16–q21, were for the first time associated with invasion and metastasis in SCC.     

The Mouse Pink-Eyed Dilution Gene: Association with Hypopigmentation in Prader-Willi and Angelman Syndromes and with Human OCA2

Mutations at the mouse pink-eyed dilution locus, p, cause hypopigmentation. We have cloned the mouse p gene cDNA and the cDNA of its human counterpart, P. The region of mouse chromosome 7 containing the p locus is syntenic with human chromosome 15q11-q13, a region associated with Prader-Willi syndrome (PWS) and Angelman syndrome (AS), both of which involve profound imprinting effects. PWS patients lack sequences of paternal origin from 15q, whereas AS patients lack a maternal copy of an essential region from 15q. However, the critical regions for these syndromes are much smaller than the chromosomal region commonly deleted that often includes the P gene. Hypopigmentation in PWS and AS patients is correlated with deletions of one copy of the human P gene that is highly homologous with its mouse counterpart. A subset of PWS and AS patients also have OCA2. These patients lack one copy of the P gene in the context of a PWS or AS deletion, with a mutation in the remaining chromosomal homologue of the P gene. Mutations in both homologues of the P gene of OCA2 patients who do not have PWS or AS have also been detected.     

Genomic structure and chromosomal localization of the mouse gene Punc

The mouse gene Punc encodes a member of the immunoglobulin superfamily of cell surface proteins. It is highly expressed in the developing embryo in nervous system and limb buds. At mid-gestation, however, expression levels of Punc decrease sharply. To allow investigation of such a regulatory mechanism, the genomic locus encompassing the Punc gene was cloned, characterized, and mapped. Fluorescent in situ hybridization was used to determine the chromosomal location of the Punc gene of mouse and human. Mouse Punc maps to Chromosome (Chr) 9 in the region D-E1, whereas the human PUNC gene is localized to Chr 15 at 15q22.3-23, a region known to be syntenic to mouse 9D-E1. The human PUNC gene therefore maps close to a genetic locus that is linked to Bardet-Biedl Syndrome, an autosomal recessive human disorder. Confirmation for the location of human PUNC was obtained through sequence relationships between mouse Punc cDNA, human PUNC cDNA, genomic sequence upstream of the murine Punc gene, and human STS markers that had been previously mapped on Chr 15. The STS sequence WI-14920 is in fact derived from the 3′-untranslated region of the human PUNC gene. WI-14920 had been placed at 228cR from the top of the Chr 15 linkage group, which provided positional information for the human PUNC gene at high resolution. Thus, this study identifies PUNC as the gene corresponding to a previously anonymous marker and serves as a basis to investigate its role in genetic disorders. Received: 8 July 1998 / Accepted: 14 October 1998     

Molecular cloning and characterization of a novel Dehydrogenase/reductase (SDR family) member 1 genea from human fetal brain

Short-chain dehydrogenases/reductases (SDR) constitute a large protein family of NAD(P)(H)-dependent oxidoreductase. They are defined by distinct, common sequence motifs and show a wide range of substrate specialisms. By large-scale sequencing analysis of a human fetal brain cDNA library, we isolated a novel human SDR-type dehydrogenase/reductase gene named Dehydrogenase/reductase (SDR family) member 1 (DHRS1). The DHRS1 cDNA is 1411 base pair in length, encoding a 314-amino-acid polypeptide which has a SDR motif. Northern blot reveals two bands, of about 0.9 and 1.4 kb in size. These two forms are expressed in many tissues. The DHRS1 gene is localized on chromosome 14q21.3. It has 9 exons and spans 9.2 kb of the genomic DNA.     

Mapping the multiple self-healing squamous epithelioma (MSSE) gene and investigation of xeroderma pigmentosum group A (XPA) and PATCHED (PTCH) as candidate genes

The MSSE gene predisposes to the development of multiple invasive but self-healing skin tumours (multiple self-healing squamous epitheliomata, MSSE). MSSE (previously named ESS1) was mapped to chromosome 9q by linkage analysis; haplotype analysis in families then suggested a common founder mutation and indicated that the gene lies in the interval D9S1–D9S29 (9q22–q31). Squamous cell carcinomata also develop as one of the complications of xeroderma pigmentosum, and one of the xeroderma pigmentosum genes (XPA) maps within the MSSE interval. We have investigated the hypothesis that a novel dominant mutation in XPA is responsible for MSSE. We screened the entire coding region, 3′ untranslated region (UTR) and 5′UTR of XPA for germline mutations in MSSE families by single-stranded conformation polymorphism analysis and by direct DNA sequencing. No mutations were detected but a novel intragenic polymorphism was identified in the 5′UTR of XPA, in both MSSE-affected and unrelated normal individuals. This XPA polymorphism and nine new polymorphic markers that map in the MSSE region were typed in eleven MSSE families; XPA was excluded as the MSSE gene and the most likely location of MSSE was reduced to the interval between D9S197 and (D9S287, D9S1809). The Patched (PTCH) gene, which is mutated in naevoid basal cell carcinoma syndrome (NBCCS or Gorlin syndrome) lies in this interval and all MSSE families have been shown to share a common haplotype at three novel intragenic PTCH polymorphisms. Although no mutation has been detected in MSSE families, PTCH has not been excluded as the MSSE gene. Received: 6 May 1997 / Accepted: 3 September 1997     

A human gene similar to Drosophila melanogaster peanut maps to the DiGeorge syndrome region of 22q11

A Drosophila-related expressed sequence tag (DRES) with sequence similarity to the peanut gene has previously been localized to human chromosome 22q11. We have isolated the cDNA corresponding to this DRES and show that it is a novel member of the family of septin genes, which encode proteins with GTPase activity thought to interact during cytokinesis. The predicted protein has P-loop nucleotide binding and GTPase motifs. The gene, which we call PNUTL1, maps to the region of 22q11.2 frequently deleted in DiGeorge and velo-cardio-facial syndromes and is particularly highly expressed in the brain. The mouse homologue, Pnutl1, maps to MMU16 adding to the growing number of genes from the DiGeorge syndrome region that map to this chromosome.     

Polymorphisms in 9q32 and <Emphasis Type="Italic">TSCOT</Emphasis> are linked to cervical cancer in affected sib-pairs with high mean age at diagnosis

Cervical cancer is a multifactorial disease influenced by both environmental and genetic factors. We have previously found linkage to 9q32 in a genomewide scan of affected sib-pairs (ASPs) with cervical cancer and to the thymic stromal co-transporter (TSCOT), a candidate gene in this region. Here we examined the contribution of 9q32 and TSCOT to cervical cancer susceptibility using at larger material of 641 ASPs, 278 of which were included in the earlier genome-scan. Since heritable forms of cancer frequently show stronger genetic effects in families with early onset of disease, we stratified the ASPs into two groups based on mean age at diagnosis (MAAD) within sib-pairs. Surprisingly, ASPs with high MAAD (30.5–47.5 years) showed increased sharing at all microsatellite markers at 9q31.1–33.1 and linkage signals of up to MLS = 2.74 for TSCOT SNPs, while ASPs with low MAAD (19–30 years) showed no deviation from random genetic sharing (MLS = 0.00). The difference in allelic sharing between the two MAAD strata was significant (P < 0.005) and is not likely to be explained by the HLA haplotype, a previously known genetic susceptibility factor for cervical cancer. Our results indicate locus heterogeneity in the susceptibility to cervical cancer between the two strata, with polymorphisms in the 9q32 region mainly showing an effect in women with high MAAD.     

Fine-mapping the putative chromosome 17q21–22 prostate cancer susceptibility gene to a 10 cM region based on linkage analysis

Prostate cancer linkage studies have suggested the existence of a prostate cancer susceptibility gene on chromosome 17q21–22. We now report the results of an extended linkage analysis including 95 new multiplex prostate cancer families and 9 additional microsatellite markers resulting in a maximum LOD score of 2.99 at approximately 81–82 cM for all 453 pedigrees. Results from these 95 new pedigrees provide additional support for a chromosome 17q21–22 prostate cancer susceptibility gene. Inclusion of the 9 additional markers significantly reduced the size of the candidate region, as defined using a 1-LOD support interval, especially when focusing analyses on subsets of pedigrees with four or more confirmed affecteds or average age of diagnosis less than or equal to 65 years. A novel subset analysis of only those families (n = 147) that had four or more prostate cancer cases and an average age of prostate cancer diagnosis ≤ 65 years results in a maximum LOD score of 5.49 at 78 cM with a 1-LOD support interval of 10 cM. This large set of pedigrees with four more prostate cancer cases characterized by early-onset disease will serve as a useful resource for identifying the putative 17q21–22 prostate cancer susceptibility gene.     

The human aminopeptidase N gene: isolation,chromosome localization,and DNA polymorphism analysis

Summary DNA encoding the human aminopeptidase N (EC 3.4.11.2) gene (PEPN) was first isolated using rat cDNA probes and then used in Southern analysis of DNA from mouse-human somatic cell hybrids to assign this gene to the long-arm region (q11-qter) of human chromosome 15. This human genomic DNA probe detects a frequent DraIII polymorphism that is a useful marker for human chromosome 15.     

Cloning and tissue expression of cDNAs from chromosome 5q21–22 which is frequently deleted in advanced lung cancer

Previously, we have reported that the inactivation of putative tumor-suppressor gene(s) on chromosome 5q21–22 may play an important role in the progression of lung cancer. Here, we describe the establishment of a yeast artificial chromosome (YAC) contig that spans 8–10 Mb at the 5q21–22 region. Six cosmid contigs have also been established in this YAC contig. About 35 exon-like fragments have been detected by exon-amplification, direct screening, cross-species hybridization, and searches of a database. Thus far, 14 cDNAs have been isolated, and two of them coincide with known genes, viz., cysteine dioxygenase I and geranylgeranyltransferase I. The other 12 cDNAs are considered to be novel genes. Two of these novel cDNA show partial homology to known genes, viz., semaphorin CD100 and the 28S rRNA gene. In addition, four known genes, including APC (adenomatous polyposis coli), MCC (mutated in colorectal cancer), proto-oncogene tyrosine kinase FER, and genomic imprinted gene U2AF1-RS1, have also been mapped in this contig. This large contig and expression map should prove crucial in the identification of susceptibility gene(s) related to the progression of lung cancer. Received: 27 May 1997 / Accepted: 3 September 1997     

Structural Characterization and Chromosomal Location of the Mouse Macrophage Migration Inhibitory Factor Gene and Pseudogenes

Macrophage migration inhibitory factor, MIF, is a cytokine released by T-lymphocytes, macrophanges, and the pituitary gland that serves to integrate peripheral and central inflammatory responses. Ubiquitous expression and developmental regulation suggest that MIF may have additional roles outside of the immune system. Here we report the structure and chromosomal location of the mouse Mif gene and the partial characterization of five Mif pseudogenes. The mouse Mif gene spans less than 0.7 kb of chromosomal DNA and is composed of three exons. A comparison between the mouse and the human genes shows a similar gene structure and common regulatory elements in both promoter regions. The mouse Mif gene maps to the middle region of chromosome 10, between Bcr and S100b, which have been mapped to human chromosomes 22q11 and 21q22.3, respectively. The entire sequence of two pseudogenes demonstrates the absence of introns, the presence of the 5′ untranslated region of the cDNA, a 3′ poly(A) tail, and the lack of sequence similarity with untranscribed regions of the gene. The five pseudogenes are highly homologous to the cDNA, but contain a variable number of mutations that would produce mutated or truncated MIF-like proteins. Phylogenetic analyses of MIF genes and pseudogenes indicate several independent genetic events that can account for multiple genomic integrations. Three of the Mif pseudogenes were also mapped by interspecific backcross to chromosomes 1, 9, and 17. These results suggest that Mif pseudogenes originated by retrotransposition.