Two cases of mosaic RhD blood-group phenotypes and paternal isodisomy for chromosome 1.

We encountered a 22-year-old man (case 1) and a 23-year-old woman (case 2), both unrelated and healthy. They were mosaic for the Rh blood group phenotype: one erythrocyte population was D-positive and the other was D-negative. Flow cytometric analysis of density profile of RhD antigen in their erythrocytes, and cytogenetic analysis including in situ hybridization using an RHD/RHCE-containing PAC clone, excluded a deletion of the RHD/RHCE gene complex, but suggested the presence of cells with uniparental disomy for chromosome 1 (UPD1). Microsatellite marker analysis was performed in both probands and their family members. In case 1, the analysis with markers spanning the chromosome 1 revealed both maternal and paternal alleles in his peripheral blood leukocytes (PBL), Epstein-Barr virus-transformed lymphoblastoid cells (EBL), and buccal mucosal cells. However, only paternal alleles were detected in all of 50 individual pieces of his hair or hair-roots and all of five monoclonal cell lines cloned from his established EBL. There was no direct evidence of heterozygous, biparental alleles in these two tissues. The presence of maternal isodisomy 1 was not absolutely ruled out in other tissues examined in case 1. Similar results were obtained in case 2, showing biparental, disomic patterns in her PBL and in 15 of 20 pieces of her hair roots, and showing monoallelic patterns in the remaining five pieces of hair roots. Analysis with markers for other autosomes confirmed their biparental inheritance. These findings indicated that both cases had at least two cell populations, one population having paternal UPD1 (isodisomy 1), and another heterozygous, biparental disomy 1. We emphasize that isodisomy for chromosome 1 is not infrequent and may cause unusual RhD phenotype, as seen in cases we described.

Isolation of novel heart-specific genes using the BodyMap database.

Two novel heart-specific genes, C3orf3 (chromosome 3 open reading frame 3) and MMGL (myomegalin-like), were isolated using BodyMap, a gene expression database based on site-directed 3' expressed sequence tags (3'-ESTs) which were collected from nonbiased cDNA libraries of various tissues. The cDNA of C3orf3 was 1667 bp and was composed of 12 exons within a 10-kb-long genomic sequence. MMGL consisted of 8 exons within a genomic sequence of over 70 kb, leading to four alternatively spliced transcripts. Both genes were strongly expressed in heart and also in skeletal muscle. C3orf3 and MMGL were mapped to 3p22 and 1q1, respectively. Subcellular localizations of their putative proteins were determined as being in the cytoplasm for C3orf3 and in the cytoplasm and nucleus for MMGL. This study showed that BodyMap is a useful database for the isolation of tissue-specific genes.

Hyperlipemia and early pancreatic injury induced by ethanol intake in rats.

The pathogenesis of alcoholic pancreatitis is unknown, and even though hyperlipemia has been hypothesized to be a risk factor for alcoholic pancreatitis, no studies directly investigating whether there is a relationship between the two have ever been reported. Therefore, to determine if a relationship exists between hyperlipemia and alcoholic pancreatitis, especially the early stage of alcoholic pancreatic injury, we administered a regular liquid Lieber-DeCarli diet, with and without ethanol as 35% of total calories, to rats for 2 wk. Thereafter we measured their plasma lipid concentrations, pancreatic zymogen granule fragility, and plasma lipase activity and subsequently investigated the correlations between these parameters. Significant increases in plasma triglyceride, total cholesterol, phospholipid, nonesterified fatty acid, pancreatic zymogen granule fragility, and plasma lipase activity were observed in the ethanol liquid diet group, compared with the values of the control liquid diet group, and pancreatic zymogen granule fragility was correlated with plasma triglyceride (r=0.62), total cholesterol (r=0.77), phospholipid (r=0.76), nonesterified fatty acid concentrations (r=0.62), and lipase activity (r=0.63). These results show a possible relationship between hyperlipemia and the early stage of alcoholic pancreatic injury, and they may support the hypothesis that hyperlipemia contributes to the etiology of alcoholic pancreatitis.

Isolation and localization of an IDDMK1,2-22-related human endogenous retroviral gene, and identification of a CA repeat marker at its locus.

We intended to confirm genetically the involvement of the IDDMK1,2-22 gene in the pathogenesis of insulin-dependent diabetes mellitus (IDDM). For this purpose, we isolated a human endogenous retrovirus gene, possibly corresponding to IDDMK1,2-22. The isolated gene showed 99.8% and 99.7% homologies in nucleotide sequences to a part of the env region and of the 3'-LTR region, respectively, compared to those of IDDMK1,2-22 deposited in GenBank. The gene also showed a close relation to HERV-K18, of which the 3'-LTR sequence gave 99.5% homology. It seemed likely that these genes represented the same single gene. The newly isolated gene was present in the first intron of the CD48 gene and was located on chromosome 1q21.2-q22. A CA repeat marker was found approximately 20 kb upstream from the 5'-end of the 5'-LTR of the gene.

The structural organization of the human aldehyde reductase gene, AKR1A1, and mapping to chromosome 1p33-->p32.

Genomic DNA encoding for human aldehyde reductase (AKR1A1), a member of the aldo-keto reductase superfamily, was isolated and characterized. The genomic DNA is approximately 16 kb in length and contains eight exons which encode the entire coding region and the 3'-untranslated sequences. AKR1A1 was localized on chromosome 1p33-->p32 by fluorescence in situ hybridization.

Mapping of the alpha-1,6-fucosyltransferase gene, FUT8, to human chromosome 14q24.3.

Alpha-1,6-Fucosyltransferase (alpha1,6FucT) is involved in the biosynthesis of asparagine-linked glycoprotein oligosaccharides. In this study, we isolated a genomic clone for the human alpha1,6FucT gene (FUT8) and mapped it by fluorescence in situ hybridization to chromosome 14q24.3. This study suggests a distinct localization of FUT8 from genes for other human fucosyltransferases reported to date.

47,XX,UPD(7)mat,+r(7)pat/46,XX,UPD(7)mat mosaicism in a girl with Silver-Russell syndrome (SRS): possible exclusion of the putative SRS gene from a 7p13-q11 region.

Maternal uniparental disomy for chromosome 7 (UPD7) may present with a characteristic phenotype reminiscent of Silver-Russell syndrome (SRS). Previous studies have suggested that approximately 10% of SRS patients have maternal UPD7. We describe a girl with a mos47,XX,+mar/46,XX karyotype associated with the features of SRS. Chromosome painting using a chromosome 7 specific probe pool showed that the small marker was a ring chromosome 7 (r(7)). PCR based microsatellite marker analysis of the patient detected only one maternal allele at each of 16 telomeric loci examined on chromosome 7, but showed both paternal and maternal alleles at four centromeric loci. Considering her mosaic karyotype composed ofdiploid cells and cells with partial trisomy for 7p13-q11, the allele types obtained at the telomeric loci may reflect the transmission of one maternal allele in duplicate, that is, maternal UPD7 (complete isodisomy or homodisomy 7), whereas those at the centromeric loci were consistent with biparental contribution to the trisomic region. It is most likely that the patient originated in a 46,XX,r(7) zygote, followed by duplication of the maternally derived whole chromosome 7 in an early mitosis, and subsequent loss of the paternally derived ring chromosome 7 in a subset of somatic cells. The cell with 46,XX,r(7) did not survive thereafter because of the monosomy for most of chromosome 7. If the putative SRS gene is imprinted, it can be ruled out from the 7p11-q11 region, because biparental alleles contribute to the region in our patient.

Repeat-directed isolation of a novel gene preferentially expressed from the maternal allele in human placenta.

Using a repetitive sequence of tandemly arrayed pentanucleotides in the human H19 3'-flanking region, we isolated a phage clone (lambda PEN11) which localized to chromosome 11p15.5. The lambda PEN11 phage encodes a 2.3-kb cDNA consisting of seven exons at least. The gene was mainly expressed in brain and pancreas (and less abundantly in testis), and demonstrated differential allele usage, with maternal expression being predominant in placenta, which indicates the gene is an atypical imprinted gene. While the pentamer repeat might contribute to this effect, it is also possible that the differential allele usage might reflect the local chromosomal structure known as the imprinting domain.

Translocation t(X;21)(q13.3; p11.1) in a girl with Menkes disease.

A girl with a 46,X,t(X;21) (q13.3;p11.1) karyotype presented with skin redundancy, especially in the neck, prominent occiput and micrognathia, and later developed hypotonia, hypopigmentation, sparse scalp hair, and profound mental retardation characteristic of Menkes disease. Her serum copper (14 microg/dl) and ceruloplasmin (9 mg/dl) levels were extremely low. Fluorescent in situ hybridization analysis with a 100-kb P1-derived artificial chromosome probe containing the Menkes disease gene demonstrated three twin-signals, one on the normal X chromosome and one each on derivative chromosomes X and 21, indicating that the Xq13.3 breakpoint was located within the gene. Replication pattern analysis showed that the normal X chromosome was late replicating, whereas the derivative X chromosome was selectively early replicating. These results indicated that Menkes disease in our patient resulted from a de novo translocation that disrupts the disease gene.

Maternal uniparental disomy for chromosome 14 in a boy with intrauterine growth retardation.

Maternal uniparental disomy (UPD) for chromosome 14 [upd(14)mat] may cause a characteristic phenotype with growth and developmental deficiency and precocious puberty. We report the case of a Japanese infant with an isochromosome 14 [i(14q)] and intrauterine growth retardation (IUGR). The infant is one of triplets comprising a boy (the patient) and two karyotypically normal girls. We analyzed parent-child transmission modes of alleles on the i(14q) at 17 CA-repeat marker loci along the entire length of chromosome 14. Genotypes at 4 proximal and 5 distal loci on the i(14q) were consistent with maternal isodisomy, whereas those at an intervening region indicated maternal heterodisomy. Thus, the derivative chromosome 14 had arisen through a translocation between maternal homologous chromosomes 14 [t(14;14)(p10;q10)] after at least two crossing-over events at the first meiosis. This result also suggests that there must be maternally imprinted gene(s) on 14q, and that loss of the functionally active, paternally derived allele in the same locus may lead to IUGR. Alternatively, IUGR may be an autosomal recessive trait. In the latter case, the mother would be a heterozygote and the putative disease locus would be either at the most proximal or most distal region of 14q.

Visible integration of the adenosine deaminase (ADA) gene into the recipient genome after gene therapy.

Gene therapy for patients with adenosine deaminase (ADA) deficiency has become practical in the 1990s, and the exogenous gene has been reported to survive for several years in the recipient genome. To evaluate the integration efficiency of the ADA gene (ADA) into peripheral blood lymphocytes (PBL) of a patient with ADA deficiency who is receiving gene therapy, we performed two-color interphase fluorescence in situ hybridization (FISH) analysis by using digoxigenin-labeled ADA-cDNA and the biotin-labeled lambda-genomic ADA clone as probes. After each of 9 sequential series of gene therapy, interphase nuclei of 100 mononuclear cells from the patient were analyzed, and those of a LASN-producing cell line were used as a control. FISH signals were detected with rhodamine and FITC for the cDNA and the genomic DNA, respectively. The number of PBL giving a transgene signal grew after the sequential gene therapies, and the proportion of signal-positive cells reached about 10%. Our results indicate that the two-color FISH system can be used as a potential aid to monitor the efficiency of the ADA gene therapy.

Identification, characterization and mapping of the human ZIS (zinc-finger, splicing) gene.

From a human fetal brain cDNA library, we isolated two transcripts (ZIS-1 and ZIS-2) corresponding to the human ZIS gene, an ortholog of the rat Zis (zinc finger, splicing). A comparison of base sequences of the cDNA and its corresponding genomic DNA (a P1-derived artificial chromosome clone) revealed that both transcripts have an ORF of 1011bp and encodes 337 amino acids, but ZIS-1 has 10 exons and ZIS-2 contains 11 exons. Although both transcripts share the first nine exons, exon 10 of ZIS-2 is lacking in ZIS-1, and instead, exon 11 (10th exon) of ZIS-1 is larger in size, leading to the longer 3'-UTR. Thus, the two transcripts result from differential splicing. A Northern blot analysis on various adult and fetal tissues revealed that 5.2- and 3.2-kb transcripts were ubiquitously expressed, and 3.9- and 1.9-kb transcripts were highly expressed in the fetal brain and kidney, respectively. There were several other transcripts that may be alternatively processed forms of the human ZIS. Considering the ZIS gene size, the 3.2-kb transcripts most likely corresponds to ZIS-1 and may act as a major transcript of ZIS. The human ZIS has a high homology to the rat Zis for the coding DNA sequence with 91% identity and for the amino acid sequence with 87% identity. ZIS and Zis contain the same numbers of exons and introns. Both genes have unusually long 3'-UTR, and their encoding proteins contain similar components, i.e. a zinc finger domain, a nuclear localization signal, an Asp-Glu region, and a Ser-Arg-rich region. Furthermore, the expression patterns of the two genes in tissues are similar each other. Thus, the human ZIS may act as a transcriptional factor to regulate transcription and/or splicing, as does the rat Zis.

Molecular mapping of a translocation breakpoint at 14q13 in a patient with mirror-image polydactyly of hands and feet.

Mirror hands and feet (MIM, 135750) is a rare congenital anomaly, and mirror-image polydactyly is considered to be a variant of mirror hands and feet. To our knowledge, seven patients with the disorder have been reported in the literature. Parent-to-child transmission was reported in two families, which may indicate a single-gene defect inherited in an autosomal dominant fashion. We had previously encountered a boy with mirror-image polydactyly whose karyotype showed 46,XY,t(2;14) (p23.3;q13) de novo. We hypothesized that at least one of the putative genes responsible for the determination of an anterior-posterior limb pattern is disrupted by a translocation breakpoint. In this study, we identified a yeast artificial chromosome clone spanning a translocation breakpoint at 14q13, and the breakpoint was confirmed to be located between two loci, AFM200ZH4 and D14S306, within a genetic distance of 0.6 cM.

The human gene encoding the heavy chain of the major histocompatibility complex class I-like Fc receptor (FCGRT) maps to 19q13.3.

FcRn is an Fc receptor that structurally resembles the major histocompatibility complex class I molecule. In this study, we isolated the human gene encoding the heavy chain of FcRn (FCGRT) and mapped it by fluorescence in situ hybridization to chromosome band 19q13.3. Thus, like its mouse counterpart, the human FCGRT gene is located outside the major histocompatibility complex.