neuralized Encodes a peripheral membrane protein involved in delta signaling and endocytosis.

Activation of the Notch (N) receptor involves an intracellular proteolytic step triggered by shedding of the extracellular N domain (N-EC) upon ligand interaction. The ligand Dl has been proposed to effect this N-EC shedding by transendocytosing the latter into the signal-emitting cell. We find that Dl endocytosis and N signaling are greatly stimulated by expression of neuralized (neur). neur inactivation suppresses Dl endocytosis, while its overexpression enhances Dl endocytosis and Notch-dependent signaling. We show that neur encodes an intracellular peripheral membrane protein. Its C-terminal RING domain is necessary for Dl accumulation in endosomes, but may be dispensable for Dl signaling. The potent modulatory effect of Neur on Dl activity makes Neur a candidate for establishing signaling asymmetries within cellular equivalence groups.

Evolution of a multigene family of chorion proteins in silkmoths.

The evolution of the A family of chorion genes was examined by comparing new protein and DNA sequences from the silkmoths Antheraea pernyi and Bombyx mori with previously known sequences from Antheraea polyphemus. The comparisons indicated that the A family and its major subfamilies are ancient and revealed how parts of the genes corresponding to distinct regions of the protein structure have evolved, both by base substitutions and by segmental reduplications and deletions.

Molecular cloning, structure and expression analysis of a full-length mouse brain glutamate dehydrogenase cDNA.

We isolated and analysed a full-length mouse brain glutamate dehydrogenase (GLUD) cDNA as a preliminary step to use the mouse model for the investigation of GLUD function in neurotransmission and neurodegeneration. GLUD coding sequences were found highly conserved among mouse, human and rat. Northern blots revealed two transcripts with different ratios in different mouse organs implying some mechanism of tissue-specific expression. In contrast to human, mouse GLUD gene family appears not to contain an intronless member.

ZNF232: structure and expression analysis of a novel human C(2)H(2) zinc finger gene, member of the SCAN/LeR domain subfamily.

We have identified a novel zinc finger gene, ZNF232, mapped to human chromosome 17p12. The coding region of the gene is organized in three exons corresponding to a 417 amino acid long polypeptide containing a SCAN/LeR domain and five C(2)H(2)-type zinc fingers. ZNF232 is possibly a nuclear protein, as suggested by expression analysis of GFP/ZNF232 chimeric constructs. ZNF232 transcripts were detected in a wide collection of adult human tissues. The gene is possibly subjected to tissue-specific post-transcriptional regulation by means of alternative splicing.

Isolation and characterization of a third isoform of human hepatocyte nuclear factor 4.

Hepatocyte nuclear factor 4 (HNF-4) is an essential positive regulator of a large number of liver-specific genes. We report here the isolation of three HNF-4 isoforms from a human liver cDNA library. hHNF-4A and hHNF-4B, differing by the insertion of 10 amino acids in the C-terminal region, have been previously identified in mouse, rat and human liver. The novel isoform, hHNF-4C, is identical to hHNF-4A and B in the regions encompassing the DNA-binding and dimerization domains, but contains a different C-terminal domain. Similar to the other isoforms, hHNF-4C is produced in a limited number of tissues and represents 2.6-13% of the total hHNF-4 mRNA population, depending on the cell type. The chromosomal origin of all three isoforms has been localized to human chromosome 20. hHNF-4C can form heterodimers with hHNF-4A and B in vitro, and exhibits similar transactivation potential as hHNF-4A or B in transient transfection assays, suggesting that the divergent C-terminal region is not part of the transactivation domain.

Identification and characterization of a novel human brain-specific gene, homologous to S. scrofa tmp83.5, in the chromosome 10q24 critical region for temporal lobe epilepsy and spastic paraplegia.

We describe the structure, genomic organization, and some transcription features of a human brain-specific gene previously localized to the genomic region involved in temporal lobe epilepsy and spastic paraplegia on chromosome 10q24. The gene, which consists of six exons disseminated over 16 kb of genomic DNA, is highly homologous to the porcine tmp83.5 gene and encodes a putative transmembrane protein of 141 amino acids. Unlike its porcine homolog, from which two mRNAs with different 5'-sequences are transcribed, the human gene apparently encodes three mRNA species with 3'-untranslated regions of different sizes. Mutation analysis of its coding sequence in families affected with temporal lobe epilepsy or spastic paraplegia linked to 10q24 do not support the involvement of this gene in either diseases.

[A normalized cDNA library from human erythroleukemia cells]. / Normalizovannaia klonoteka kDNK iz éritroleikoznykh kletok cheloveka.

Normalized cDNA library from human erythroleukemia cells has been constructed. For equalizing frequencies of different cDNAs denaturation was carried out followed by partial reassociation. Single-stranded cDNAs separated by hydroxyapatite chromatography were transformed into double-stranded form by PCR and cloned in lambda gt11. Frequencies of 10 control nucleotide sequences were estimated. After normalization frequencies of the abundant sequences decreased. The normalized cDNA library may be used for search of the clones corresponding to the rare mRNAs and for human genome mapping.

Tetra-/di-nucleotide repeat polymorphism upstream of the human alpha 2-globin gene locus at 16p13.3.

A highly polymorphic tetra-/di-nucleotide repeat sequence was identified upstream of the human alpha 2/alpha 1-globin gene pair on chromosome 16p13.3. This microsatellite marker should be useful in alpha-thalassemia genotype-phenotype correlations and in respective population genetics studies.

Evolution of chorion structural genes and regulatory mechanisms in two wild silkmoths: a preliminary analysis.

We report a preliminary analysis of structural and regulatory evolution of the A and B chorion gene families in two wild silkmoths, Antheraea pernyi and Antheraea polyphemus. Homospecific and heterospecific dot hybridizations were performed between previously characterized A. polyphemus complementary DNA clones and total or stage-specific follicular mRNAs from the two species. The hybridization patterns indicated substantial interspecies changes in the abundance of corresponding mRNA sequences (heteroposic evolution) without substantial changes in their developmental specificities (heterochronic evolution). In addition, the proteins encoded in the two species by corresponding mRNAs were determined by hybrid-selected translation followed by electrophoretic analysis. The results suggested that the proteins evolve in size, presumably through internal deletions and duplications.

Locus assignment of human alpha-globin structural mutants by selective enzymatic amplification of alpha 1 and alpha 2-globin cDNAs.

We have used the powerful methodology of DNA enzymatic amplification in order to assign human alpha-globin structural mutants to one of the two highly homologous alpha-globin genes. Selectively amplified alpha 1 and alpha 2-globin cDNAs were dot-blotted and further hybridized to synthetic oligonucleotides encompassing either the normal or the mutated sequences. The generated signals corresponded specifically to one of the two alpha-globin genes. Using this approach the alpha-globin structural mutants J-Buda and G-Pest were found to be encoded by the alpha 2 and the alpha 1-globin genes, respectively. Furthermore, the exact nucleotide changes were determined. We propose this technique to serve as a simple and definitive method for assigning alpha-globin structural mutants.

Developmental and inducible patterns of human theta 1-globin gene expression in embryonic/fetal and adult erythroid cells.

Human theta (theta 1)-globin gene represents a member of the alpha-like globin gene family residing on chromosome 16. theta 1-Specific transcripts have been detected so far only in erythroid tissues and in erythroleukemia K562 cells. To investigate systematically its inducible expression and developmental specificity, we analyzed at the RNA level five additional human erythroleukemia cell lines with diverse developmental globin programs, two somatic cell hybrids between K562 and mouse erythroleukemia (MEL) cells, a human fetal liver x MEL somatic cell hybrid, and reticulocytes and bone marrow cells from normal adults. theta 1-Globin gene was expressed in all cell types. Inducible expression (two- to sixfold) was documented both in HEL and K562 erythroleukemia cells after 5-azacytidine treatment. Like K562 cells, HEL cells also displayed hemin-inducible theta 1-globin gene expression. Following transfer of human chromosome 16 from embryonic/fetal K562 to the adult MEL cells, theta 1-globin gene remained active but lost its potential for inducibility, suggesting probably a trans regulation mechanism. Higher levels of theta 1 mRNA were found in fetal liver cells compared with trace amounts in reticulocytes and normal adult bone marrow cells. These data clearly show that in contrast to the embryonic and adult patterns of expression of zeta and alpha-globin genes, respectively, theta 1-globin gene displays a different profile, being active predominantly during the early stages of ontogeny, switching to lower levels of expression in adulthood.

Chromosomal mapping of glutamate dehydrogenase gene sequences to mouse chromosomes 7 and 14.

Glutamate dehydrogenase (GLUD) plays an important role in mammalian neuronal transmission. In human, GLUD is encoded by a small gene family. To determine whether defects in Glud genes are associated with known neurological mutations in the mouse and to contribute to the comparative mapping of homologous genes in man and mouse, the chromosomal location of genes reactive with a mouse brain GLUD cDNA were determined. Genomic Southern analysis of a well-characterized panel of Chinese hamster x mouse somatic cell hybrids identified two GLUD-reactive loci, one residing on mouse Chromosome 14 and the other on Chromosome 7. Progeny of an intersubspecies backcross were used to map one of these genes, Glud, proximal to Np-1 on Chromosome 14, but no restriction fragment polymorphisms could be identified for the second locus, Glud-2.

The human glutamate dehydrogenase gene family: gene organization and structural characterization.

Glutamate dehydrogenase is a mitochondrially located, key metabolic enzyme. In addition to its general metabolic role, GLUD is important in neurotransmission. Significant alterations in GLUD enzymatic activity have been associated with certain neurodegenerative human disorders. Although a single species of human GLUD cDNA molecule has been identified so far, both genomic DNA Southern and cytogenetic analyses have indicated the presence of a GLUD gene family. Screening of a human genomic lambda-phage library with the GLUD cDNA, led us to the isolation of several clones divided into five structurally distinct contigs. We have confirmed the presence of all GLUD-specific sequences in the human genome by detailed genomic Southern analysis. This study allowed the identification of the entire functional GLUD gene, named GLUD1. The GLUD1 gene is about 45 kb long and it is organized into 13 exons. Its nucleotide sequence, exon-intron boundaries, and transcription start sites were determined. Potential binding sites for various regulatory factors such as Sp1, AP-1, and AP-2 were recognized at the promoter region of the gene. The members of the other contigs showed an organization clearly different from GLUD1. Two distinct GLUD-specific gene loci, termed GLUDP2 and GLUDP3, possibly represent truncated pseudogenes. Their high degree of similarity to GLUD1 is limited to the region surrounding exons 2, 3, and 4. Finally, two additional GLUD-specific genomic sequences, termed GLUDP4 and GLUDP5, are structurally similar with the 3' part of the GLUD cDNA sequence. These loci probably represent truncated GLUD pseudogenes generated by retrotransposition. The data presented here suggest that all human GLUD pseudogenes have diverged recently in evolution.

Human hepatocyte nuclear factor-4 (hHNF-4) gene maps to 20q12-q13.1 between PLCG1 and D20S17.

Human hepatocyte nuclear factor 4 (hHNF-4) is a member of the nuclear hormone receptor superfamily and an important transcription factor and developmental regulator of liver-specific genes. Distinct hHNF-4 cDNAs corresponding to various HNF-4 isoforms have been recently characterised. Three cDNAs, hHNF-4A, B and C, are considered splice variants of a single hHNF-4 gene. We have mapped hHNF-4 to 20q12-q13.1 between PLCG1 and D20S17 by genetic linkage analysis, taking advantage of an adjacent PstI restriction fragment length polymorphism, (RFLP), and by fluorescence in situ hybridisation. hHFN-4 maps to chromosome 20 in a region syntenic with mouse chromosome 2 where the hnf-4 homologue has been assigned.

The B multigene family of chorion proteins in saturniid silkmoths.

The main features of the B family of chorion proteins in saturniid moths were examined by partial sequencing of representative B proteins, seven from Antheraea polyphemus and two from A. pernyi. Comparisons were made to sequences derived from seven recombinant DNA clones representing three types of B family proteins of A. polyphemus. The central regions of the sequences are conservative, both within and between moth species, and differ largely by a few amino acid replacements, rather than deletions or insertions. By contrast, the amino-terminal third varies more substantially, in a manner which defines two protein subfamilies: within each subfamily sequences are similar, but the subfamilies differ by at least two multiresidue deletions as well as by amino acid replacements. These properties are analogous to features of the A family of chorion proteins.

Chromosomal mapping of two members of the human glutamate dehydrogenase (GLUD) gene family to chromosomes 10q22.3-q23 and Xq22-q23.

Glutamate dehydrogenase (GLUD) is an important mitochondrial enzyme that participates in neuronal transmission by catalyzing the deamination of L-glutamate, which serves as a potent excitatory neurotransmitter. The direct involvement of GLUD in the pathogenesis of certain human neurodegenerative disorders has been suggested recently. To investigate its possible role in the induction and progression of these disorders, we have initiated studies focusing on the chromosomal organization of the several members of the GLUD family and their functional status. In the present study using a panel of human x rodent somatic cell hybrids and in situ hybridization to metaphase chromosomes, we documented that the members of the GLUD gene family are dispersed in the human genome. The functional GLUD1 gene was mapped to chromosome 10q22.3-q23, and an intronless processed gene (GLUDP1) to chromosome Xq22-q23, while the truncated intron-containing GLUD pseudogene GLUDP2 was also assigned on chromosome 10, but not closely linked to the GLUD1 gene. These results provide novel information concerning the chromosomal organization of the human GLUD gene family.

Structure and expression analysis of a member of the human glutamate dehydrogenase (GLUD) gene family mapped to chromosome 10p11.2.

Glutamate dehydrogenase (GLUD) is a key metabolic enzyme of the mitochondrion, playing an important role in mammalian neuronal transmission. GLUD deficiency has been associated with certain forms of neurodegeneration in the human cerebellum. Genomic DNA blot hybridization analysis and identification of a large number of GLUD-specific genomic clones have suggested that human GLUD is encoded by a multigene family consisting of at least six members. A functional GLUD gene, GLUD1, has been mapped to chromosome 10q22.3-23 and a full-length "processed" GLUD gene, GLUDP1, to chromosome Xq22-23. In the context of studing the structure, the role, and the chromosomal organization of the other family members, we have analysed in detail, a cosmid clone solely reactive with the 3' region of the GLUD cDNA. Structure and expression analysis of its GLUD-specific region suggests that it represents a truncated "processed" GLUD pseudogene. Fluorescence in situ hybridization using the entire cosmid as a probe, mapped this GLUD gene locus, termed GLUDP5, to chromosome 10p11.2.

Three human glutamate dehydrogenase genes (GLUD1, GLUDP2, and GLUDP3) are located on chromosome 10q, but are not closely physically linked.

Yeast artificial chromosomes (YACs) of 340 and 370 kb that contain the functional human glutamate dehydrogenase gene (GLUD1) and the pseudogene GLUDP2, respectively, were isolated. These genes were not physically linked to each other nor to any other sequences homologous to the exons of GLUD1. No additional GLUD sequences were found within at least 70 kb of the 5' and 175 kb of the 3' end of GLUD1 or 150 kb of either end of GLUDP2. By in situ hybridization, GLUD1 was located at 10q23.3, GLUDP2 at 10q11.2, and another pseudogene of the GLUD gene family, GLUDP3, at 10q22.1. DNA fragments of these three genes showed cross-hybridization to the loci assigned to the other two genes, but not to any other chromosomal locus. Thus, these three genes are located at distinct positions on chromosome 10q.

Sequences located 3' to the breakpoint of the hereditary persistence of fetal hemoglobin-3 deletion exhibit enhancer activity and can modify the developmental expression of the human fetal A gamma-globin gene in transgenic mice.

Expression of fetal gamma-globin genes in individuals with the deletion forms of hereditary persistence of fetal hemoglobin (HPFH) has been attributed either to enhancement by 3' regulatory elements juxtaposed to gamma-globin genes or to deletion of gamma-gene silencers normally residing within the beta-globin gene cluster. In the present study, we tested the hypothesis of imported enhancers downstream of beta-globin gene using the HPFH-3 deletion as a model. The abnormal bridging fragment of 13.6 kilobases (kb) containing the A gamma-gene with its flanking sequences and 6.2 kb of the juxtaposed region was microinjected into fertilized mouse eggs. Twelve transgenic mice positive for the fragment were generated. Samples from 11.5-day yolk sacs, 16-day fetal liver, and adult blood were analyzed for A gamma-mRNA using RNase protection assays. Three mice lacked A gamma expression in the yolk sac indicating non-optimal integration site. Four expressed A gamma-mRNA at the embryonic stage only, while two expressed A gamma-mRNA in both embryonic and fetal liver erythroid cells. Since the A gamma-gene with its normal flanking sequences and in the absence of the locus control region is expressed only in embryonic cells of transgenic mice, these data suggest that the juxtaposed sequences have altered the developmental specificity of the fetal gamma-globin gene. These sequences were further tested for the presence of an enhancer element, by their ability to activate a fusion reporter gene consisting of the CAT gene linked to the gamma-globin gene promoter, in erythroid (K562) and non-erythroid (HeLa) cells. A 0.7-kb region located immediately 3' to the breakpoint, enhanced chloramphenicol acetyltransferase activity by 3-fold in erythroid cells. The enhancer also activated the embryonic epsilon-globin gene promoter by 2-fold but not the adult beta- or delta-globin gene promoters. The enhancer represents a region of previously known complex tandem repeats; in this study we have completed the sequencing of the region encompassing the 0.7-kb enhancer element. Multiple areas of the enhancer region exhibit homology to the core element of the simian virus 40 enhancer and to the sequences of the human 3' A gamma- and the chicken 3' beta-globin enhancers. A consensus binding site for the erythroid specific GATA-1 transcription factor and seven consensus sites for the ubiquitous CP1 transcription factor are also included within the enhancer. These data suggest that these sequences located immediately 3' to the breakpoint of the HPFH-3 deletion, exhibit both the structure and the function of an enhancer, and can modify the developmental specificity of the fetal gamma-globin genes, resulting in their continued expression during adult life.

PKU in Slovakia: mutation screening and haplotype analysis.

The restriction fragment length polymorphism haplotypes and seven common mutations in the phenylalanine hydroxylase gene were analysed in 49 unrelated Slovak phenylketonuria (PKU) families of Caucasian origin. The predominant mutation in this population sample is R408W, with a frequency of 45.9%. In addition, four other mutations have been identified at relatively high frequencies: IVS12nt1, 10.2%; R158Q, 7.1%; R261Q, 7.1%; R252W, 2.0%. The mutation-haplotype associations correspond to those described in other European populations. The high proportion of mutations (72.4%) amenable to simple rapid detection based on the polymerase chain reaction provides a good basis for direct DNA-diagnosis of PKU in the Slovak population.