U1 small nuclear RNA genes are located on human chromosome 1 and are expressed in mouse-human hybrid cells

U1 snDNA chromosomal mapping in ten spittlebug species (Cercopidade, Auchenorrhyncha, Hemiptera)

Spittlebugs, which belong to the family Cercopidae (Auchenorrhyncha, Hemiptera), form a large group of xylem-feeding insects that are best known for causing damage to plantations and pasture grasses. The holocentric chromosomes of these insects remain poorly studied in regards to the organization of different classes of repetitive DNA. To improve chromosomal maps based on repetitive DNAs and to better understand the chromosomal organization and evolutionary dynamics of multigene families in spittlebugs, we physically mapped the U1 snRNA gene with fluorescence in situ hybridization (FISH) in 10 species of Cercopidae belonging to three different genera. All the U1 snDNA clusters were autosomal and located in interstitial position. In seven species, they were restricted to one autosome per haploid genome, while three species of the genus Mahanarva showed two clusters in two different autosomes. Although it was not possible to precisely define the ancestral location of this gene, it was possible to observe the presence of at least one cluster located in a small bivalent in all karyotypes. The karyotype stability observed in Cercopidae is also observed in respect to the distribution of U1 snDNA. Our data are discussed in light of possible mechanisms for U1 snDNA conservation and compared with the available data from other species.

U1 snDNA clusters in grasshoppers: chromosomal dynamics and genomic organization

The spliceosome, constituted by a protein set associated with small nuclear RNA (snRNA), is responsible for mRNA maturation through intron removal. Among snRNA genes, U1 is generally a conserved repetitive sequence. To unveil the chromosomal/genomic dynamics of this multigene family in grasshoppers, we mapped U1 genes by fluorescence in situ hybridization in 70 species belonging to the families Proscopiidae, Pyrgomorphidae, Ommexechidae, Romaleidae and Acrididae. Evident clusters were observed in all species, indicating that, at least, some U1 repeats are tandemly arrayed. High conservation was observed in the first four families, with most species carrying a single U1 cluster, frequently located in the third or fourth longest autosome. By contrast, extensive variation was observed among Acrididae, from a single chromosome pair carrying U1 to all chromosome pairs carrying it, with occasional occurrence of two or more clusters in the same chromosome. DNA sequence analysis in Eyprepocnemis plorans (species carrying U1 clusters on seven different chromosome pairs) and Locusta migratoria (carrying U1 in a single chromosome pair) supported the coexistence of functional and pseudogenic lineages. One of these pseudogenic lineages was truncated in the same nucleotide position in both species, suggesting that it was present in a common ancestor to both species. At least in E. plorans, this U1 snDNA pseudogenic lineage was associated with 5S rDNA and short interspersed elements (SINE)-like mobile elements. Given that we conclude in grasshoppers that the U1 snDNA had evolved under the birth-and-death model and that its intragenomic spread might be related with mobile elements.

Genetic characterization of Plectorhinchus mediterraneus yields important clues about genome organization and evolution of multigene families

Background

Molecular and cytogenetic markers are of great use for to fish characterization, identification, phylogenetics and evolution. Multigene families have proven to be good markers for a better understanding of the variability, organization and evolution of fish species. Three different tandemly-repeated gene families (45S rDNA, 5S rDNA and U2 snDNA) have been studied in Plectorhinchus mediterraneus (Teleostei: Haemulidae), at both molecular and cytogenetic level, to elucidate the taxonomy and evolution of these multigene families, as well as for comparative purposes with other species of the family.

Results

Four different types of 5S rDNA were obtained; two of them showed a high homology with that of Raja asterias, and the putative implication of a horizontal transfer event and its consequences for the organization and evolution of the 5S rDNA have been discussed. The other two types do not resemble any other species, but in one of them a putative tRNA-derived SINE was observed for the first time, which could have implications in the evolution of the 5S rDNA. The ITS-1 sequence was more related to a species of another different genus than to that of the same genus, therefore a revision of the Hamulidae family systematic has been proposed. In the analysis of the U2 snDNA, we were able to corroborate that U2 snDNA and U5 snDNA were linked in the same tandem array, and this has interest for tracing evolutionary lines. The karyotype of the species was composed of 2n = 48 acrocentric chromosomes, and each of the three multigene families were located in different chromosome pairs, thus providing three different chromosomal markers.

Conclusions

Novel data can be extracted from the results: a putative event of horizontal transfer, a possible tRNA-derived SINE linked to one of the four 5S rDNA types characterized, and a linkage between U2 and U5 snDNA. In addition, a revision of the taxonomy of the Haemulidae family has been suggested, and three cytogenetic markers have been obtained. Some of these results have not been described before in any other fish species. New clues about the genome organization and evolution of the multigene families are offered in this study.

The U8 snoRNA gene family: identification and characterization of distinct, functional U8 genes in Xenopus

U8 snoRNA is the RNA component of a small nucleolar ribonucleoprotein (U8 snoRNP) required for accumulation of mature 5.8S and 28S rRNAs, components of the large ribosomal subunit. We have identified two putative U8 genes in Xenopus laevis. Sequence analysis of the coding regions of these two genes indicate that both differ at several positions from the previously characterized U8 RNA and that the two differ from each other. Functional analysis of these genes indicates that both are transcribed in vivo, produce stable U8 transcripts, and are capable of facilitating pre-rRNA processing in vivo. These data demonstrate that natural sequence variation exists among the U8 snoRNA genes in Xenopus. Alignment of these three Xenopus U8 sequences with the previously described mammalian U8 homologues in mouse, rat and human has provided information about evolutionarily conserved sequence and structural elements in U8 RNA. Identification and functional characterization of these naturally occurring variants in Xenopus has helped identify regions in U8 RNA that may be critical for function.

Evidence for a new tumour suppressor locus (DBM) in human B-cell neoplasia telomeric to the retinoblastoma gene

Roughly 25% of human B-cell chronic lymphocytic leukaemias (CLL) are characterized by a chromosomal lesion involving 13q14. This region contains the retinoblastoma gene (RB1). We have used a variety of techniques to determine whether RB1 or some other locus is the critical region in 11 cases of low grade B-cell malignancy (mainly CLL), all with deletions or translocations involving 13q14. In all cases, except the one with minimal disease, there was deletion or a structural lesion in the region of D13S25, with at least 4 cases showing homozygous disruption. We conclude that D13S25 lies close to a tumour suppressor locus whose inactivation contributes to the initiation or progression of low grade B-cell malignancy. This locus is located at least 530 kilobases telomeric to RB1.

Isolation and characterization of a candidate gene for Norrie disease

Previous analysis has refined the location of the gene for Norrie disease, a severe, X-linked, recessive neurodevelopmental disorder, to a yeast artificial chromosome subfragment of 160 kilobases (kb). This fragment was used to screen cDNA libraries from human fetal and adult retina. As a result, we have identified an evolutionarily conserved cDNA, which is expressed in fetal and adult brain and encodes a predicted protein of 133 amino acids. The cDNA detects genomic sequences which span a maximum of 50 kb, and which are partly deleted in several typical Norrie disease patients. An EcoRI polymorphism with a calculated heterozygosity value of 43% was observed. The locus identified is a strong candidate for the Norrie disease gene.

Contiguous localization of the genes encoding human insulin-like growth factor binding proteins 1(IGBP1) and 3(IGBP3) on chromosome 7

In extracellular fluids the insulin-like growth factors (IGFs) are bound to specific binding proteins (IGBPs). The genes for two members of this protein family have been mapped, the IGBP1 gene to human chromosomal region 7p14-p12 and the IGBP2 gene to region 2q33-q34. In this study, somatic cell hybrid analysis indicated that IGBP3 is also located on chromosome 7. Pulsed-field gel electrophoresis was used to demonstrate the close physical linkage between IGBP1 and IGBP3. Overlapping cosmid clones encompassing these genes were isolated, and restriction endonuclease mapping showed that the genes are arranged in a tail-to-tail fashion separated by 20 kb of DNA. Further characterization of the IGBP1 DNA sequence disclosed a duplication of the intron 3-exon 4 junction within the third intron. In addition, we report RFLPs for ApaLI and TaqI in the IGBP1 locus.

Structure of the Echinococcus multilocularis U1 snRNA gene repeat

The gene encoding U1 snRNA in Echinococcus multilocularis has been cloned and sequenced. This gene is contained within a 1300-bp sequence which is tandemly repeated in the E. multilocularis genome. E. multilocularis U1 snRNA is 50-70% homologous to U1 snRNAs of other species. E. multilocularis U1 snRNA could assume a predicted secondary structure similar to that proposed for other U1 snRNAs, and appears shorter (157 bases) than the U1 snRNAs of higher eukaryotes (163-166 bases).

The gene for insulin-like growth factor-binding protein-1 is localized to human chromosomal region 7p14-p12

Insulin-like growth factors (IGF) I and II are bound to high-affinity binding proteins in the blood circulation and other body fluids. These IGF-binding proteins are expressed at different concentrations in different tissues and are thought to regulate the activity of IGF I and II. Cloned cDNA for IGF-binding protein-1 (IGFBP1) has been used to verify the location of its gene to human chromosome 7 by Southern blotting to DNA from a human-mouse hybrid cell line. Further, by in situ hybridization the gene was regionally localized to 7p14-p12, and a Mendelian-inherited two-allele BglII restriction enzyme length polymorphism was identified, with the most frequent allele occurring in 53% of the chromosomes.

Long-range physical mapping around the human steroid sulfatase locus

The region of the human X chromosome containing the steroid sulfatase locus was analyzed by pulsed-field gel electrophoresis. Restriction site maps were generated for the X chromosome in the blood of a normal male individual and that in the mouse-human hybrid cell line ThyB-X; these maps extend over approximately 4.3 Mb of DNA of the former, and 3.2 Mb of the latter. Physical linkage was defined between the STS locus and sequences detected by the probes GMGX9 (DXS237), GMGXY19 (DYS74), CRI-S232 (DXS278), and dic56 (DXS143), and the order telomere--(STS, DYS74)--DXS237--DXS278--DXS143--centromere was deduced. The pulsed-field maps were used to demonstrate a deletion of 180 kb of DNA from the X chromosome of an individual with X-linked ichthyosis. Also, possible locations for the Kallmann syndrome gene were revealed, and the distance between the steroid sulfatase locus and the pseudoautosomal region was estimated to be at least 4 Mb.

RNA synthesis and stability in UV-irradiated and nonirradiated mouse L cells

In mouse L cells, relatively low doses of UV light (e.g., about 35 J/m2) induced the rapid breakdown of the molecules of many RNA species transcribed shortly before irradiation. This included 28S, 18S, 5.8S, and 5S rRNA, U1, U2, U3, U4, and U5 small nuclear RNA, but not the main band of transfer RNAs or 7SL RNA. At higher UV doses, an RNA band that contains tRNAleu was also degraded rapidly after UV irradiation. RNA molecules synthesized long before irradiation (e.g., 22 h for small RNAs, 4 h for large rRNAs) were not affected. Our results suggest that the maturation and/or assembly into fully mature ribonucleoprotein particles of several small RNA species is not completed 4 h after transcription. The effect of UV radiation occurred in mouse L cells, but not in human HeLa or KB cells. In a previous report, L cells were transformed by DNA transfection with two mouse U1b RNA genes, named U1.1 and U1.2. We observed now that, in L cells transformed with the U1.2 gene, the ratio of radioactivity in the apparent U1b and U1a RNA precursors after 5 min of labeling was about 20 times higher than a) this ratio in briefly labeled L cells that had been transformed with the U1.1 gene, and b) the ratio of radioactive mature U1b and U1a RNA after 20 h of chase in L cells transformed with the U1.2 gene. These results suggest that very high levels of U1b RNA are transcribed from the exogenous U1.2 gene copies, followed by the rapid degradation of most of these transcripts.

Genomic organization of the human asparagine transfer RNA genes: localization to the U1 RNA gene and class I pseudogene repeat units

Previously isolated human DNA clones containing asparagine transfer RNA (tRNAAsn) genes have been used to determine the genomic organization of this multigene family in man. One clone also contained a gene for U1 RNA, and so the organization of the two multigene families could be directly compared. The majority, and perhaps all, of the human tRNAAsn genes map to the same chromosome bands as do the U1 RNA true genes and class I pseudogenes located on the short and long arms, respectively, of chromosome 1. These two gene clusters were independently isolated using a somatic-cell hybrid minipanel, and use of repeat-unit DNA polymorphisms showed that one tRNA gene clone maps to the short-arm gene cluster and the other to the long-arm gene cluster. Electron microscopy of heteroduplexes between these two clones showed duplex formation along the proposed region of overlap between them, indicating that the short- and long-arm gene clusters are structurally related. I suggest that the split into two distinct loci was facilitated by a pericentric chromosome inversion. This would have had the effect of positioning the genes currently on the long arm adjacent to the centromeric heterochromatin, perhaps resulting in a "position effect" on transcription of these genes. Restriction fragments of different sizes were found that were common to a majority of repeat units, depending on the restriction enzyme being used. Pulsed-field electrophoresis revealed that fragments of molecular weight of 180 kb were common to each unit (or multiples of units). These fragments also contained U1 RNA gene sequences. I therefore propose that these two gene families are closely linked on repeat units (or multiples of units) of 180 kb in size, which are probably organized in tandem arrays.

Genes for human U3 small nucleolar RNA contain highly conserved flanking sequences

Six human genomic clones containing sequences homologous to the U3 small nuclear RNA (snRNA) were isolated and characterized. Four of these clones were real U3 snRNA genes because they were transcribed in frog oocytes and the DNA sequences corresponding to the U3 snRNA were identical to the U3 snRNA of HeLa cells. The nucleotide sequences of four true U3 snRNA genes, 537 nucleotides on the 5'-flanking region and 340 nucleotides on the 3'-flanking region, were found to be identical. In addition, the restriction patterns, upto 2 kb on the 5' side and 2.2 kb on the 3' side, appeared to be same. All the isolated U3 clones, containing 15-20 kb of genomic DNA, contained only one U3 snRNA gene, indicating that the human U3 snRNA genes are several kilobases apart. One of the U3 clones contained a full-length U3 pseudogene. Southern blot analysis of genomic DNA with cloned U3 DNA as probe indicated that human DNA contains two families of U3 genes which differ in their flanking sequences. In the 5' flanking region of human U3 snRNA genes, homology to U-gene promoter element, an octamer motif, the 'U3 box', SP1 binding sites and a consensus 3' box in the 3' flanking region, were observed. These data show that the genomic organization and the sequence motifs that control transcription of human nucleolar U3 snRNA genes are similar to those of human U1 and U2 snRNA genes and suggest common mechanism(s) in the evolution of snRNA genes.

Ultraviolet light-induced inhibition of small nuclear RNA synthesis

Two apparently distinct types of inhibition of the synthesis of U1, U2, U3, U4, and U5 small nuclear RNA, induced by ultraviolet (UV) radiation, have been described before: immediate and delayed. Our present observation can be summarized as follows: a) neither the immediate nor the delayed inhibition appear to be mediated by the formation of cyclobutane pyrimidine dimers, since they were not prevented by photoreactivating light, in ICR 2A frog cells; b) the inhibition of U1 RNA synthesis, monitored in HeLA cells within the first few minutes after irradiation, extrapolated to a substantial suppression at time zero of postirradiation cell incubation, providing further support for the proposal that the immediate inhibition is a reaction separate from the delayed UV light-induced inhibition of U1 RNA synthesis; c) the transition from the pattern of the immediate inhibition to that of the delayed inhibition (disappearance of the UV-resistant fraction of U1 RNA synthesis and increased rate of inhibition) occurred gradually, without an apparent threshold, within the first 2 hr of incubation after irradiation; and d) the incident UV dose that resulted in a 37% level of residual U1 RNA synthesis (D37) during the delayed inhibition was about 7 J/m2, with an apparent UV dose threshold, and was about 60 J/m2 for the immediate inhibition.

Adenovirus infection retards ribosomal RNA processing

Eight hours after infection of KB cells with adenovirus type 12, the rate of conversion from the 32S ribosomal RNA (rRNA) precursor to mature 28S and 5.8S rRNA decreased. An additional RNA species was detected, which appears to be novel, on the basis of its estimated size (about 6.5 kilobases) and its high level of radiolabeling early after infection at low multiplicity.

Metabolism of U6 RNA species in nonirradiated and UV-irradiated mammalian cells

We observed a series of rapidly labeled U6 RNA bands, which were hybrid selected with U6 DNA, in nonirradiated human cells. The electrophoretic mobility of these bands in denaturing gels was lower than that of the known mature U6 RNA species, and was equivalent to transcripts up to approximately 7 nucleotides longer. These multiple U6 RNA species lost their label during a chase without a proportional increase in radioactivity in the known mature U6 RNA, which suggests that a substantial fraction is not processed into the major mature U6 RNA. During a label chase, the multiple U6 RNA bands appeared first in the cytoplasmic fraction and later in nuclei. One of the major rapidly labeled U6 RNA bands had the electrophoretic mobility of an RNA species one nucleotide shorter than the known mature U6 RNA. UV light induced a UV dose-dependent, preferential disappearance of recently synthesized molecules of the U6 RNA species of higher gel electrophoretic mobility, including the known mature U6 RNA. Since this effect was seen in cells pulse-labeled immediately before or after irradiation, it suggests that UV radiation induces the specific degradation of the electrophoretically faster moving species of U6 RNA, which are apparently shorter chains. The effect of UV light was RNA species-specific, was not seen in molecules synthesized long (e.g., 22 hr) before irradiation, and occurred in human and mouse cells.

Effect of ultraviolet light on the expression of genes for human U1 RNA

Two types of UV-light-induced inhibitions of the synthesis of small nuclear RNA species U1, U2, U3, U4, and U5 were described previously: an immediate inhibition and a separate, delayed suppression that requires 1-2 hr of postirradiation cell incubation and UV doses that are about tenfold lower. In the present report, U1 RNA transcription in isolated nuclei from HeLa cells, assayed by RNAase T1 protection, reproduced the delayed inhibition. The sizes of the protected RNA fragments suggest that it is the initiation of U1 RNA transcription that is blocked during this inhibition. Transient expression of a marked human U1 RNA gene that contains 425 and 92 nucleotides of the 5' and 3' flanking sequences, respectively, showed delayed, but not immediate inhibition (while the endogenous U1 RNA genes exhibited immediate suppression). This indicates that continuity of the U1 gene flanking sequences beyond those segments and/or chromosomal integration of the U1 gene are not needed for the delayed inhibition, but may be required for the immediate inhibition. Irradiation of a U1 RNA gene, followed by its injection into Xenopus laevis oocyte nuclei, did not reproduce the immediate or delayed inhibitions. This suggests that direct UV radiation damage to DNA in the U1 RNA gene region is not the critical lesion in either the immediate or delayed UV-light-induced inhibitions of U1 RNA synthesis. In addition, the RNAase T1 protection pattern of transcripts synthesized in isolated nuclei from nonirradiated HeLa cells suggests that these cells may produce small amounts of U1 RNA molecules with variant nucleotide sequences in the mature region of the transcript.

Localization and expression of U1 RNA in early mouse embryo development

We have studied the accumulation and localization of U1 RNA during mouse embryo development by in situ hybridization with a U1 RNA probe and immunofluorescence microscopy using a mouse monoclonal antibody to U1 snRNP. There is a substantial amount of U1 RNA present in the oocyte that is present in both the germinal vesicle and the cytoplasm although the concentration is higher in the nuclear compartment. Following the germinal vesicle breakdown that accompanies ovulation and meiotic maturation, the U1 RNA is uniformly distributed throughout the unfertilized oocyte. In the fertilized egg, the silver grain density from in situ hybridization is higher over pronuclei and this enrichment is maintained at the two-cell and later stages. Similar results were obtained for the distribution of the U1 snRNP as assayed by immunofluorescence microscopy: U1 RNA is predominantly localized in all nuclei except polar body nuclei. The U1 RNA in the oocyte and two-cell embryo is predominantly (greater than 85%) U1a RNA. By the eight-cell stage there is a two to three-fold increase in the amount of total U1 RNA and the proportion of U1b RNA has increased to about 40%. The amount of U1 RNA continues to increase through the blastocyst stage and the proportion of the U1b RNA increases to 60%.

Mapping and gene order of U1 small nuclear RNA, endogenous viral env sequence, amylase, and alcohol dehydrogenase-3 on mouse chromosome 3

Linkage was established between a number of genes that map on chromosome 3 by studying the distribution patterns of DNA polymorphisms and protein electrophoretic mobility polymorphisms in recombinant inbred (RI) strains of mice. This analysis resulted in the following suggested gene order between the newly assigned genes and previously mapped genes: gamma-fibrinogen (Fgg), Xmmv-22 of mink cell focus-inducing (MCF) virus, U1b small nuclear RNA gene cluster (Rnu-1b), amylase (Amy-1,2), cadmium resistance (cdm), alcohol dehydrogenase-3 (Adh-3), alcohol dehydrogenase-1 (Adh-1). In situ hybridization to chromosome spreads confirmed the assignment of the Ulb small nuclear RNA (snRNA) gene cluster and the gamma-fibrinogen gene to the center of chromosome 3.

The embryonic and adult mouse U1 snRNA genes map to different chromosomal loci

The linkage relationships of mouse adult (mU1a) and embryonic (mU1b) U1 snRNA genes were determined by analysis of the strain distribution patterns of two polymorphic variant RNAs, mU1a2 and mU1b3, in several recombinant inbred strain systems. The locus for mU1b3 RNA maps to the U1 gene cluster, Rnu1b, located near the center of chromosome 3, whereas the locus for mU1a2 RNA, Rnu1a2, is located in the proximal region of chromosome 12, tightly linked to D12-1. Moreover, the lack of linkage between Rnu1a2 and the locus for mU1a1 genes on chromosome 11 demonstrates that the mouse genome contains at least three clusters of U1 snRNA genes.

Fragments of rDNA within the Chinese hamster genome

We report the isolation and partial characterization of distinct EcoRI fragments of the Chinese hamster genome which contain regions complementary to a 1-kb portion of the mature 18 S ribosomal RNA molecule. This previously undescribed 18 S rDNA-like region, which we have termed a "fragment of ribosomal DNA" (frDNA), has been shown by sequence analysis to correspond to a region extending 1 kb upstream from the 3' terminus of the mature 18 S rRNA. Within the five frDNA-containing clones described here, no other region of the ribosomal RNA cistron was detected, making it unlikely that these are polymorphic forms of the ribosomal DNA repeat. The 18 S rDNA-complementary region appears to be flanked by an imperfect direct repeat, which could have been the result of the retroinsertion of a fragment of ribosomal RNA. Directly adjacent to the 18 S rDNA-like region we have identified nonribosomal sequences which appear common to all of the frDNA-containing clones we examined. At least eight different-sized EcoRI fragments contain frDNAs and the abundance of the frDNAs appears to be of the order of 30 per genome. The occurrence of multiple copies of this ribosomal-nonribosomal chimera suggests that, once formed, the chimera was duplicated within the genome.

Human cytochrome P-450 PB-1: a multigene family involved in mephenytoin and steroid oxidations that maps to chromosome 10

The cytochrome P-450 monooxygenase system possesses catalytic activity toward many exogenous compounds (e.g., drugs, insecticides, and polycyclic aromatic hydrocarbons) and endogenous compounds (e.g., steroids, fatty acids, and prostaglandins). Multiple forms of cytochrome P-450 with different substrate specificities have been isolated. In the present paper we report the isolation and sequence of a cDNA clone for the human hepatic cytochrome P-450 responsible for mephenytoin (an anticonvulsant) oxidation. The mephenytoin cytochrome P-450 is analogous to the rat cytochrome P-450 form termed PB-1 (family P450C2C). We also report that human PB-1 is encoded by one of a small family of related genes all of which map to human chromosome 10q24.1-10q24.3. The endogenous role of this enzyme appears to be in steroid oxidations. This cytochrome P-450 family does not correspond to any of the hepatic cytochrome P-450 gene families previously mapped in humans.

A hypervariable repeated sequence on human chromosome 1p36

When used to probe Southern blots of TaqI-digested DNAs from unrelated individuals, p1-79, a 900 bp subclone of a random human cosmid, revealed at least 50 fragments, many of which were polymorphic. Each of 27 unrelated individuals tested with p1-79 displayed a distinct band pattern. Similar variation was seen with several other enzymes, including HaeIII, MspI, PstI and PvuII, whereas other enzymes yielded primarily large fragments of greater than 40 kb. In situ hybridization of p1-79 showed that the loci of hybridization are clustered on human chromosome band 1p36; localization of all TaqI fragments to chromosome 1 was confirmed with a human-rodent somatic cell hybrid panel. DNA sequencing of p1-79 revealed several copies of a 39 bp repeat whose variation in copy number might be the basis of the observed length polymorphisms. Studies of 3-generation Utah families suggest that the numerous restriction fragments homologous to p1-79 are inherited as haplotypes, implying that recombination within this cluster of loci is rare and allowing the cluster to serve as a useful marker for human gene mapping.

Human interstitial retinol-binding protein (IRBP): cloning, partial sequence, and chromosomal localization

A cloned 2184-bp cDNA coding for human interstitial retinol-binding protein (IRBP) has been isolated and sequenced. The probe hybridized to a 5.2-kb poly(A) RNA from human retinas. Nineteen tryptic peptides (363 amino acids) sequenced and purified from bovine IRBP could be aligned with 86-88% homology to the translated sequence. Two segments approximately 200 amino acids long were found to have a 41% residue identity, suggesting an internal duplication event. This cloned cDNA was used to probe DNA samples from a panel of 29 rodent-human somatic cell hybrids, mapping the structural gene for IRBP to chromosome 10. In situ hybridization suggested a regional localization near the centromere (p11.2----q11.2), although a secondary site of hybridization at q24----25 was also observed.

Human U3 small nucleolar RNA genes are localized to the nucleoplasm

U3 RNA, an abundant, conserved, capped, small RNA localized to the nucleolar compartment of eukaryotic cells, its implicated in the processing of pre-ribosomal RNA. The genes for U1 and U2 snRNAs (small nuclear RNAs) are clustered and present in the nucleoplasmic DNA; however, the localization of U3 snRNA genes is not known. DNAs, isolated from HeLa cell nuclei and nucleoli, were hybridized with labeled probes corresponding to the 5'-flanking and the coding regions of the human U3 snRNA gene. The intensity of signals obtained with both the probes were 5-6 fold greater in nuclear DNA, compared to nucleolar DNA. With ribosomal gene probe, the nucleolar DNA had sixfold more intense signal than nuclear DNA. These results indicate that genes for U3 snRNA are in the nucleoplasm. Therefore, U3 snRNA, like 5S ribosomal RNA, appears to be synthesized in the nucleoplasm and transported to the nucleolus.

Reverse-transcribed pseudogenes of U1 small nuclear RNA presumably amplified in the rat genome together with the flanking region

We have examined 25 independent rat genomic clones each of which contains a U1 RNA gene or a pseudogene. We have found five clones whose restriction maps are identical with or overlapping one another. These clones contain sequences which are co-linear with that of U1 RNA except for one or two nucleotides (nt). They also contain 21-23-nt poly(A) stretches immediately after U1 RNA homology. In addition, the U1 RNA-poly(A) regions are surrounded by the same direct repeat sequences. Therefore, they seem to be pseudogenes which have been generated by the reverse transcription of poly(A)-tailed U1 RNA followed by the insertion of the transcript into the genome. Furthermore, conservation of the sequences extends over at least 18 kb of the flanking sequences. This suggests a family of conserved reverse-transcribed pseudogenes, which implies amplification of an original pseudogene. It is also suggested that the target sequence without insertion of a U1 RNA sequence has been amplified. The mechanisms for the amplification and sequence conservation are discussed.

Human DNA sequences isolated with an immunoglobulin switch region probe: sequence, chromosomal localization, and restriction fragment length polymorphisms

We have screened a human genomic DNA library with an immunoglobulin (Ig) derived switch (S) region specific probe for homologous sequences. Five Ig independent phage clones were isolated and characterized. The S sequence homologous DNA fragments are short compared to the S region sequences. Ig independent S sequences are flanked by highly repetitive DNA elements and perfect inverted repeats can be demonstrated in their close vicinity. Using subclones of S homologous sequences restriction fragment length polymorphisms were shown within DNA of different T cell leukemias, Burkitt lymphomas, lymphoblastoid cell lines, and DNA of healthy individuals. One of the five clones isolated with the S region probe was evidently localized to chromosome 2 and/or 10 and showed a complex hybridisation pattern with several different human DNAs. S homologous sequences of another clone are most likely localized on chromosome 1. It is possible that these Ig independent S sequences have arisen by amplification and transposition and that they are involved in genetic recombination.

Characterization and mapping of DNA sequence homologous to mouse U1a1 snRNA: localization on chromosome 11 near the Dlb-1 and Re loci

A phage clone which contained a functional U1a1 snRNA gene was isolated from a mouse genomic library. A single copy fragment was isolated from the 3' flanking region of the U1a1 gene and used as a hybridization probe for Southern blotted DNAs from recombinant inbred strains of mice, mouse-hamster hybrid cells, and the offspring from backcrosses between BALB/c mice and mice which were heterozygous for the Rex (Re) marker. The results of these experiments prove that the U1a1 gene is located on chromosome 11 near the Delb-1 and Re loci.

Chromosome-specific subfamilies within human alphoid repetitive DNA

Nucleotide sequence data of about 20 X 10(3) base-pairs of the human tandemly repeated alphoid DNA are presented. The DNA sequences were determined from 45 clones containing EcoRI fragments of alphoid DNA isolated from total genomic DNA. Thirty of the clones contained a complete 340 base-pair dimer unit of the repeat. The remaining clones contained alphoid DNA with fragment lengths of 311, 296, 232, 170 and 108 base-pairs. The sequences obtained were compared with an average alphoid DNA sequence determined by Wu & Manuelidis (1980). The divergences ranged from 0.6 to 24.6% nucleotide changes for the first monomer and from 0 to 17.8% for the second monomer of the repeat. On the basis of identical nucleotide changes at corresponding positions, the individual repeat units could be shown to belong to one of several distinct subfamilies. The number of nucleotide changes defining a subfamily generally constitutes the majority of nucleotide changes found in a member of that subfamily. From an evaluation of the proportion of the total amount of alphoid DNA, which is represented by the clones studied, it is estimated that the number of subfamilies of this repeat may be equal to or exceed the number of chromosomes. The expected presence of only one or a few distinct subfamilies on individual chromosomes is supported by the study, also presented, of the nucleotide sequence of 17 cloned fragments of alphoid repetitive DNA from chromosome 7. These chromosome-specific repeats all contain the characteristic pattern of 36 common nucleotide changes that defines one of the subfamilies described. A unique restriction endonuclease (NlaIII) cleavage site present in this subfamily may be useful as a genetic marker of this chromosome. A family member of the interspersed Alu repetitive DNA was also isolated and sequenced. This Alu repeat has been inserted into the human alphoid repetitive DNA, in the same way as the insertion of an Alu repeat into the African green monkey alphoid DNA.

Hypervariable telomeric sequences from the human sex chromosomes are pseudoautosomal

Pairing of human X and Y chromosomes during meiosis initiates within the so-called pairing region at the telomeres or the chromosome short arms. Using DNA from the Y chromosome we found sequence homology in the pairing region of the human X and Y chromosomes. This DNA is telomeric, contains repetitive sequences and is highly polymorphic in the population. The polymorphism has allowed family studies which show the sequences are not inherited as though linked to the sex chromosomes. This 'pseudoautosomal' pattern of inheritance points to an obligate recombination in the pairing region of the sex chromosomes during male meiosis.

A cloned sequence, p82H, of the alphoid repeated DNA family found at the centromeres of all human chromosomes

Clone p82H is a human DNA sequence which hybridises in situ exclusively to the centromeric regions of all human chromosomes. It is composed of approximately 14 tandemly repeated variants of a basic 172 bp sequence, and is related to the alphoid family. The organisation of the family of cross-hybridising sequences, detected by the clone p82H, is described both in the human genome and on certain chromosomes, and its relationship to known sequence families is discussed.

Selective expression of histone genes in mouse-human hybrid cells

Mouse-human hybrid cells preferentially segregating mouse chromosomes contain predominantly human histone mRNAs and synthesize human histone proteins. In contrast, hybrids segregating human chromosomes contain both human and murine histone mRNAs, yet synthesize only mouse histone proteins. These results suggest transcriptional control of histone gene expression in hybrids segregating mouse chromosomes and post-transcriptional regulation in hybrids segregating human chromosomes.

The gene cluster for human U2 RNA is located on chromosome 17q21

The gene cluster for human U2 RNA has been mapped to chromosome 17q21 by in situ hybridization and hybridization analysis of DNA from mouse/human somatic cell hybrids.

Human genes for U2 small nuclear RNA map to a major adenovirus 12 modification site on chromosome 17

U2 RNA is one of the abundant, highly conserved species of small nuclear RNA (snRNA) molecules implicated in RNA processing. As is typical of mammalian snRNAs, human U1 and U2 are each encoded by a multigene family. In the human genome, defective copies of the genes (pseudogenes) far outnumber the authentic genes. The majority or all of the 35 to 100 bona fide U1 genes have at least 20 kilobases (kb) of nearly perfect 5' and 3' flanking homology in common with each other; these U1 genes are clustered loosely in chromosome band 1p36 (refs 5, 7) with intergenic distances exceeding 44 kb. In contrast, the 10 to 20 U2 genes are clustered tightly in a virtually perfect tandem array which has a strict 6-kb repeating unit. We report here the assignment, by in situ hybridization, of the U2 gene cluster to chromosome 17, bands q21-q22. Surprisingly, this region is one of three major adenovirus 12 modification sites which undergo chromosome decondensation ('uncoiling') in permissive human cells infected by highly oncogenic strains of adenovirus. The two other major modification sites, 1p36 and 1q21, coincide with the locations of U1 genes and class I U1 pseudogenes, respectively. We suggest that snRNA genes are the major targets of viral chromosome modification.

An estimate of unique DNA sequence heterozygosity in the human genome

Fifteen different restriction fragment length polymorphisms (RFLPs) were detected in the human genome using 19 cloned DNA segments, derived from flow-sorted metaphase chromosomes or total genomic DNA, as hybridization probes. Since these clones were selected at random with respect to their coding potential, their analysis permitted an unbiased estimate of single-copy DNA sequence heterozygosity in the human genome. Since our estimate (h = 0.0037) is an order of magnitude higher than previous estimates derived from protein data, most of the polymorphic variation present in the genome must occur in non-coding sequences. In addition, it was confirmed that enzymes containing the dinucleotide CpG in their recognition sequence detect more polymorphic variation than those that do not contain CpG.

Expression of a mouse U1b gene in mouse L cells

A 6.9-kb DNA fragment containing two mouse U1b genes was introduced by cotransfection with the Herpes simplex virus (HSV) thymidine kinase (TK) gene into tk- mouse L cells. The parent Ltk- cells produce primarily U1a RNA and only small amounts of U1b RNA. However, after introduction of exogenous U1b genes by cotransfection these cells express large amounts of U1b RNA. Subcloned DNA fragments containing a single U1b gene and varying amounts of DNA flanking the 5' -end of the gene were introduced into Ltk- cells. All of the constructs containing 400 bp or more upstream of the U1b gene were efficiently expressed. By comparison, a subclone containing only 150 bp of DNA flanking the 5' -end of the U1b gene was not efficiently expressed. The U1b transcripts synthesized in transfected cells were identified by hybrid selection and by precipitation of ribonucleoproteins (RNP) containing U1 RNA with anti-RNP antibody.

DNA sequences complementary to human 7 SK RNA show structural similarities to the short mobile elements of the mammalian genome

A complementary DNA clone of 7 SK RNA from HeLa cells was used to study the genomic organization of 7 SK sequences in the human genome. Genomic hybridizations and genomic clones show that 7 SK is homologous to a family of disperse repeated sequences most of which lack the 3' end of the 7 SK RNA sequence. Only few of the genomic K sequences are homologous to both 3' and 5' 7 SK probes and presumably include the gene(s) for 7 SK RNA. The sequence of four genomic 7 SK clones confirms that they are in most cases pseudogenes. Although Alu sequences are frequently found near the 3' and 5' end of K DNA, the sequences immediately flanking the pseudogenes are different in all clones studied. However, direct repeats were found flanking directly the K DNA or the K-Alu unit, suggesting that the K sequences alone or in conjunction with Alu DNA might constitute a mobile element.

Differential expression of multiple U1 small nuclear RNAs in oocytes and embryos of Xenopus laevis

The small nuclear RNA, U1, is a highly conserved, 165 nucleotide long RNA which has been implicated in the processing of mRNA precursors. We present evidence that in the amphibian X. laevis there exist at least seven species of U1 RNA, which differ in sequence but not in length. Strikingly, these RNAs are not coordinately expressed. Two of the U1 RNAs are the predominant U1 species transcribed in the late blastula-early gastrula stages of Xenopus embryogenesis. These two RNAs, designated xU1a and xU1b, are not synthesized in significant amounts in stage 6 oocytes; a different set of U1 RNAs are expressed during late oogenesis. In a Xenopus cultured cell line, all of the U1 RNA species are expressed. Possible functions and developmental significance of these multiple U1 RNA species are discussed.

U1 small nuclear RNA-like sequences in human high molecular weight RNA

Human U1 small nuclear RNA synthesis was shown earlier to be very sensitive to UV radiation. This led us to test for the possible presence of U1 RNA-like sequences in large RNAs. Human RNA was analyzed in gel blots hybridized with U1 DNA probes. A high molecular weight, heterodisperse RNA population was detected, which hybridizes both to a U1 RNA-coding region single-stranded DNA probe, and to a U1 gene fragment that contains only 6 nucleotides of flanking sequence. These large RNAs can be hybrid selected using immobilized U1 DNA, and have an average size of several kilobases. Additional observations support the claims that the high molecular weight RNA hybridization signal is not an aggregation artifact and that it is sequence specific.