RNA-mediated gene duplication: the rat preproinsulin I gene is a functional retroposon

Evidence for retrotranscription of protein-coding genes in the Drosophila subobscura genome

Evidence is provided for the presence of retrosequences (also named retroposons) arising from Adh in the Drosophila subobscura genome. Restriction analysis and primary structure of two different retrosequence-containing clones, S812 and S135, are reported. The fact that these retrosequences lack introns and a recognizable promoter strongly supports their retrotranscriptional origin. Adjacent to the two retrosequences analyzed, a middle repetitive DNA element has been found which bears no clear similarity to any sequence reported to date in the GenBank/EMBL Data Library. A comparative analysis of these retrosequences with the functional Adh gene of D. subobscura is presented. In addition, a model concerning the origin, functionality, and propagation of these genome elements is discussed.

Structure and lens expression of the gene encoding chicken beta A3/A1-crystallin

The beta A1- and beta A3-crystallins are major polypeptides in the lenses of vertebrates. We present evidence that a single beta A3/A1 gene encodes these two proteins in the chicken. The beta A3/A1 gene has been sequenced and its functional promoter identified in transfection experiments. The chicken beta A3/A1 gene has the same structure as the human orthologue: six exons with standard splice sites and two alternative start codons from which the protein products are apparently translated. Northern analysis revealed an abundant 0.9-kb transcript in the lenses of 1-2-day-old chickens and no detectable transcripts in the rest of the eye, brain, heart, kidney, liver or skeletal muscle. The 5'-flanking sequence of the chicken beta A3/A1 gene is very similar to that of the human and mouse genes, suggesting conservation of important putative regulatory sequences in addition to the TATA box. A thymidine-rich element (bp -218 to -163) and a potential AP-1-binding site (bp -264 to -258) are present within the chicken 5'-flanking region. A DNA fragment from -382 to +22 of the chicken beta A3/A1 gene is sufficient to promote expression of the bacterial cat gene in transfected chicken primary lens epithelial cells, but not in transfected dermal fibroblasts.(ABSTRACT TRUNCATED AT 250 WORDS)

Chromosomal localization of the IL-6 receptor signal transducing subunit, gp130 (IL6ST)

Signal transduction in eukaryotic cells is a complex process mediated, normally, by the interaction of soluble extrinsic protein factors and their cognate receptors. One example of this phenomena is the inflammatory cytokine interleukin-6 and the IL-6 receptor. However, the IL-6 receptor, once its ligand is bound, associates with another membrane glycoprotein, gp130, to potentiate the cytokine response. To further understand the basis of this interaction, and its possible implications in cellular transforming events, the corresponding gene(s) must be studied. Here we find that the human gp130 gene product is homologous to two distinct chromosomal loci on chromosomes 5 and 17. Furthermore, the presence of two distinct gp130 gene sequences is restricted to primates and is not found in other vertebrates.

Localization of insulin-2 (Ins-2) and the obesity mutant tubby (tub) to distinct regions of mouse chromosome 7

A DNA mapping panel derived from an interspecific backcross was used to position the mouse insulin-2 locus (Ins-2) on Chromosome 7, near H19 (0/114 recombinants) and Th (1/114 recombinants). Ins-2 is part of a human-mouse conserved linkage group that includes Th, H19, and Igf-2. Analysis of segregation in the F2 generation from the cross C57BL/6J-tub/tub x CAST/Ei demonstrated that Ins-2 and the obesity mutant tubby (tub) are distinct loci, thus eliminating Ins-2 as a candidate gene for tub. These results also refine the estimated genetic distance between tub and Hbb to 2.4 +/- 1.4 cM. The predicted location for a human homolog of tubby is HSA 11p15.

The ratio of mouse insulin I:insulin II does not reflect that of the corresponding preproinsulin mRNAs

Rats and mice both express two, non-allelic, insulin genes. In the rat the ratio of the two preproinsulin mRNAs closely matches that of the mature insulin peptides. The experiments reported here demonstrate that this is not the case in the mouse. The relative amounts of the two murine proinsulin RNAs were measured by an S1 nuclease assay. The ratio of preproinsulin I mRNA to preproinsulin II mRNA was 4:1 in RNA extracted from the pancreas of mice fed ad libitum or fasted for 72 h. A similar value was found in mouse islets of Langerhans after maintenance in tissue culture for 48 h at either 2.8 or 16.7 mM glucose. The ratio of insulin I:insulin II peptides, assessed by separating the two insulins using reversed phase high-performance liquid chromatography, was approximately 1:3 in both pancreas and islets. Thus in the mouse, unlike the rat, the ratio of the two insulin peptides does not reflect that of the two preproinsulin mRNAs.

Rat gene mapping using PCR-analyzed microsatellites

One hundred and seventy-four rat loci which contain short tandem repeat sequences were extracted from the GenBank or EMBL data bases and used to define primers for amplification by the polymerase chain reaction (PCR) of the microsatellite regions, creating PCR-formatted sequence-tagged microsatellite sites (STMSs). One hundred and thirty-four STMSs for 118 loci, including 6 randomly cloned STMSs, were characterized: (i) PCR-analyzed loci were assigned to specific chromosomes using a panel of rat x mouse somatic cell hybrid clones. (ii) Length variation of the STMSs among 8 inbred rat strains could be visualized at 85 of 107 loci examined (79.4%). (iii) A genetic map, integrating biochemical, coat color, mutant and restriction fragment length polymorphism loci, was constructed based on the segregation of 125 polymorphic markers in seven rat backcrosses and in two F2 crosses. Twenty four linkage groups were identified, all of which were assigned to a defined chromosome. As a reflection of the bias for coding sequences in the public data bases, the STMSs described herein are often associated with genes. Hence, the genetic map we report coincides with a gene map. The corresponding map locations of the homologous mouse and human genes are also listed for comparative mapping purposes.

Isolation and characterization of the CRIPTO autosomal gene and its X-linked related sequence

We have previously reported on the identification of a cDNA clone encoding a novel human growth factor, named "CRIPTO," that is abundantly expressed in undifferentiated human NTERA-2 clone D1 (NT2/D1) and mouse (F9) teratocarcinoma cells. We now report the organization and nucleotide sequence of two related genomic sequences. One (CR-1) corresponds to the structural gene encoding the human CRIPTO protein expressed in the undifferentiated human teratocarcinoma cells, and the other (CR-3) corresponds to a complete copy of the mRNA containing seven base substitutions in the coding region representing both silent and replacement substitutions. The 440 bp 5' to the CAP site of CR-1 are preserved in CR-3. CR-1 maps to chromosome 3, and CR-3 maps to Xq21-q22. Southern blot analysis reveals that multiple CRIPTO-related DNA sequences are present in the human as well as in the mouse genome.

RNA-mediated transfer of the gene coxII from the mitochondrion to the nucleus during flowering plant evolution

The gene coxII, normally present in the mitochondrion, was functionally transferred to the nucleus during flowering plant evolution. coxII transfer is estimated to have occurred between 60 and 200 million years ago, whereas loss of coxII from the mitochondrion occurred much more recently, being restricted to a single genus of legumes. Most legumes have coxII in both the nucleus and the mitochondrion; however, no evidence is found for simultaneous coxII expression in both compartments. The nuclear coxII sequence more closely resembles edited mitochondrial coxII transcripts than the genes encoding these RNAs. Hence, gene transfer appears to have involved reverse transcription of an edited RNA intermediate. The nuclear gene contains an intron at the junction of the transit peptide sequence and the mature protein-coding sequence; exon shuffling may have played a role in assembling a functional coxII gene in the nucleus.

Unique 3'-untranslated sequence of insulin-like growth factor-I isolated from human placenta

A cDNA clone of 525 bp corresponding to the 3'-untranslated region of insulin-like growth factor-I was isolated from a human placenta library. The sequence of this clone extended 200 nucleotides downstream from the previously reported 3'-end of IGF-IA cDNA, indicating the existence of IGF-IA transcripts having an even larger 3'-untranslated region. By using this clone for RNA transfer blot hybridization, it was shown that this longer 3'-untranslated region is included in the 7.5- and 5.0-kb transcripts, but not in the 1.1- and 0.9-kb transcripts. It is also apparent that transcripts bearing the extended 3'-untranslated sequence are highly expressed in human placenta.

The gene map of the Norway rat (Rattus norvegicus) and comparative mapping with mouse and man

The current status of the rat gene map is presented. Mapping information is now available for a total of 214 loci and the number of mapped genes is increasing steadily. The corresponding number of loci quoted at HGM10 was 128. Genes have been assigned to 20 of the 22 chromosomes in the rat. Some aspects of comparative mapping with mouse and man are also discussed. It was found that there is a good correlation between the morphological homologies detectable in rat and mouse chromosomes, on the one hand, and homology at the gene level on the other. For 10 rat synteny groups all the genes so far mapped are syntenic also in the mouse. For the remaining rat synteny groups it appears that the majority of the genes will be syntenic on specific (homologous) mouse chromosomes, with only a few genes dispersed to other members of the mouse karyotype. Furthermore, the data indicate that mouse chromosome 1 genetically corresponds to two rat chromosomes, viz., 9 and 13, equalizing the difference in chromosome number between the two species. Further mappings will show whether the genetic homology will prove to be as extensive as these preliminary results indicate. As might be expected from evolutionary considerations, rat synteny groups are much more dispersed in the human genome. It is clear, however, that many groups of genes have remained syntenic during the period since man and rat shared a common ancestor. One further point was noted. In two cases groups of genes were syntenic in the mouse but dispersed to two chromosomes in rat and man, whereas in a third case a group of genes was syntenic in the rat but dispersed to two chromosomes in mouse and man. This finding argues in favor of the notion that the original gene groups were on separate ancestral chromosomes, which have fused in one rodent species but remained separate in the other and in man.

Parental imprinting of the mouse insulin-like growth factor II gene

We are studying mice that carry a targeted disruption of the gene encoding insulin-like growth factor II (IGF-II). Transmission of this mutation through the male germline results in heterozygous progeny that are growth deficient. In contrast, when the disrupted gene is transmitted maternally, the heterozygous offspring are phenotypically normal. Therefore, the difference in growth phenotypes depends on the type of gamete contributing the mutated allele. Homozygous mutants are indistinguishable in appearance from growth-deficient heterozygous siblings. Nuclease protection and in situ hybridization analyses of the transcripts from the wild-type and mutated alleles indicate that only the paternal allele is expressed in embryos, while the maternal allele is silent. An exception is the choroid plexus and leptomeninges, where both alleles are transcriptionally active. These results demonstrate that IGF-II is indispensable for normal embryonic growth and that the IGF-II gene is subject to tissue-specific parental imprinting.

IAPP/amylin gene transcriptional control region: evidence for negative regulation

Aberrant expression of the islet amyloid polypeptide (IAPP) gene might be involved in the pathogenesis of non-insulin-dependent diabetes mellitus (NIDDM). Here, we report that IAPP promoter-luciferase constructs revealed tissue-specific activity. This activity was not mediated by cAMP. Sequential 5' deletions of the IAPP promoter caused a progressive derepression of the IAPP gene promoter in IAPP-producing cells. Comparison of the nucleotide sequence of the IAPP promoter with that of the insulin promoter (both active in pancreatic beta-cells) reveals two sequence elements of putative importance: an insulin enhancer-like sequence and an element which corresponds to a protected domain in rat insulin I gene promoter footprint experiments.

Molecular structures of two human DNA topoisomerase I retrosequences

We have isolated recombinant lambda-phage clones that contain sequences complementary to the 3' half of the cDNA encoding human topoisomerase I (hTOP1). These lambda clones belong to three distinct classes: class-I clones contain sequences from the active gene located on human chromosome 20. Class-II and class-III clones contain sequences corresponding to the cDNA encoding hTOP1 from nucleotide (nt) 2208 to 3434 and from nt 1639 to 3434, respectively. These sequences exhibit the characteristic features of retroposons or retrosequences. They are most likely derived from truncated mRNA transcripts of the active gene. We propose to designate the truncated hTOP1 sequence located on chromosome 1 as the pseudogene 1 (psi 1-hTOP1) and the sequence on chromosome 22 as the pseudogene 2 (psi 2-hTOP1). Pseudogene psi 1-hTOP1 has two unique properties: it is flanked by upstream sequences which display promoter activity in transient expression assays, and it contains an open reading frame which could code for the 211 C-terminal amino acids of hTOP1. Pseudogene psi 2-hTOP1 is located within an AluI repetitive element and is flanked on one side by a (CA)21 stretch.

Amplification of a long sequence that includes a processed pseudogene for elongation factor 2 in the mouse

Quantitative Southern blotting analysis has demonstrated that mouse cells contain about 70 copies per haploid genome of a DNA sequence related to the gene for elongation factor 2. The restriction maps of seven cosmids that each carry one copy of the EF2-related sequence (MER) and nucleotide sequences of MERs were highly conserved among the cosmids. Data obtained by such analyses suggest that MERs were produced by the integration of one copy of MER derived from poly(A)+ mRNA for EF2 into a specific site in the mouse genome, with subsequent amplification of MER together with its large flanking sequences during the evolution of the mouse. Furthermore, it appears that the size of each repeating unit is more than 60 kb. Analysis by pulse-field gel electrophoresis suggested that multiple copies of a repeating unit of more than 400 kb (or two units) are clustered at a specific site (or each specific site) in the mouse genome.

Complement genes C1r and C1s feature an intronless serine protease domain closely related to haptoglobin

The exon-intron structure of the human complement C1s gene displays a striking similarity with that of the gene encoding haptoglobin, a peculiar transport protein distantly related to the serine proteases. While the protease regions of the serine zymogens are typically encoded by multiple exons, the protease domains of C1s and of its genetically linked and functionally interacting homolog C1r are encoded as intronless domains, not unlike a region of haptoglobin, which in fact is devoid of proteolytic activity. The close similarity of the C1s gene with haptoglobin includes the precise conservation of exon-intron junctions and it extends to upstream exons encoding the short repeats typical of several complement components, but found also in other functionally unrelated proteins. Additional evidence of the common ancestry of C1r, C1s and haptoglobin is the presence, within the protease domain, of a set of sequence markers that distinguish these three proteins from all known serine proteases. The finding of vertebrate serine protease genes with an uninterrupted protease-encoding exon supports the definition of a novel evolutionary branch of this gene family and rules out the hypothesis that regards this unusual exon as an irrelevant byproduct of the extravagant functional divergence of haptoglobin.

Nucleotide sequence of the rat gamma-crystallin gene region and comparison with an orthologous human region

The sequences of a 51-kb region containing the cluster of five rat gamma-crystallin-coding genes (CRYG) and of a 7-kb region surrounding the sixth rat CRYG gene were determined. Approximately 78% of the total sequence represents intergenic DNA. We also sequenced 22 kb of DNA from the human CRYG gene cluster. All CRYG genes are associated with CpG-rich regions. The sequence similarity between the human and rat gene regions drops sharply (to 65%) in intronic and 3'-flanking regions but decreases only gradually in the 5'-flanking region. Highly conserved regions (greater than 80%) are found as far upstream as 1.5 kb. Overall intergenic distances are conserved. The human region contains much more repetitive DNA (24% vs. 10%) but less simple-sequence (sps) DNA (0.7% vs. 4%) than the rat region. Almost all repeats and spsDNA elements are located in the intergenic region. The location of repetitive and spsDNA differs between the orthologous regions and these elements were probably inserted after the evolutionary separation of rat and man. The Alu repeats in man and the B3 repeats in the rat are close copies of their respective consensus sequences and bordered by virtually perfect repeats. In contrast, the B1 and B2 repeats in the rat have diverged considerably from the consensus sequence and the surrounding direct repeats are usually imperfect. Thus the dispersion of the B1 and B2 repeats in the rat probably preceded that of the B3 repeats. Within the rat genomic region the spacing of Z-DNA elements is surprisingly regular, they are located about 12 kb apart. A search for putative matrix-associated regions suggests that the rat CRYG gene cluster is organized into two chromosomal domains.

Different evolution rates within the lens-specific beta-crystallin gene family

We have determined the sequence of a rat beta A3/A1-crystallin complementary DNA (cDNA) clone and the (partial) sequence of the human beta B3-crystallin gene. Calculation of the ratio of silent to nonsynonymous substitution between orthologous beta A3/A1-, beta B3-, and other beta- and gamma-crystallin sequences revealed that the region encoding the two globular domains of the beta A3/A1-crystallin sequence is the best conserved during evolution, much better than the corresponding region of the beta B1-, beta B3-, or the gamma-crystallin sequences, and even better (at least in the rodent/frog comparison) than the well-conserved alpha A-crystallin sequence. Remarkably, the rate of change of the beta A3/A1-crystallin coding sequence does not differ in the rodent and primate lineages, in contrast with previous findings concerning the evolution rates of the alpha A- or gamma-crystallin sequences in these two lineages. Comparison of the regions that encode the four motifs of the beta-crystallin between orthologous mammalian sequences showed that the extent of nonsynonymous substitution in each of these four homologous motif regions is the same. However, when the orthologous beta-crystallin genes of more distantly related species (mammals vs chicken or frog) are compared, the extent of non-synonymous substitution is higher in the regions encoding the external motifs I and III than in the regions encoding the internal motifs II and IV. This phenomenon is also observed when paralogous members of the beta/gamma-crystallin supergene family are compared.

Nucleic acid composition, codon usage, and the rate of synonymous substitution in protein-coding genes

Based on the rates of synonymous substitution in 42 protein-coding gene pairs from rat and human, a correlation is shown to exist between the frequency of the nucleotides in all positions of the codon and the synonymous substitution rate. The correlation coefficients were positive for A and T and negative for C and G. This means that AT-rich genes accumulate more synonymous substitutions than GC-rich genes. Biased patterns of mutation could not account for this phenomenon. Thus, the variation in synonymous substitution rates and the resulting unequal codon usage must be the consequence of selection against A and T in synonymous positions. Most of the variation in rates of synonymous substitution can be explained by the nucleotide composition in synonymous positions. Codon-anticodon interactions, dinucleotide frequencies, and contextual factors influence neither the rates of synonymous substitution nor codon usage. Interestingly, the nucleotide in the second position of codons (always a nonsynonymous position) was found to affect the rate of synonymous substitution. This finding links the rate of nonsynonymous substitution with the synonymous rate. Consequently, highly conservative proteins are expected to be encoded by genes that evolve slowly in terms of synonymous substitutions, and are consequently highly biased in their codon usage.

A proposal for a possible role of nucleosome positioning in the evolutionary adjustment of introns

1. Prokaryotes and yeast have mostly intronless genes, whereas the presence of a large number of extended introns are characteristic of the genes of of multicellular eukaryotic organisms which, however, as an exception also have a few intronless genes. 2. According to the current view, the lack of introns in prokaryotic organisms and yeast is due to the selective pressure of a short cell division time. On the other hand, the presence of introns in multicellular eukaryotic organisms is explained by the lack of selective forces against them. 3. In the present hypothesis it is proposed that introns were used as tools in the course of evolution for the organization of eukaryotic genes within the repeating units of nucleosomes, since the distinct DNA conformations of the nucleosome core particle and of the linker region, respectively, represent a constraint for the positioning of genes. 4. Recently it was shown that initiation of transcription is inhibited when the promoter sequence is within a nucleosome. 5. Since the nucleosomal organization of DNA leads to a severely deformed DNA helix and recognition of sequences by regulatory proteins is likely to depend on the conformation of the double helix, it is postulated that for the different sizes of eukaryotic genes which have to be organized within repeating units of nucleosomes, introns provided the flexibility of adjustment for the positioning of regulatory sequences, by drifting in length, sequence and position.

Organization and nucleotide sequence of two chromosomal genes for rat cytochrome c oxidase subunit VIc: a structural and a processed gene

A rat genomic library was screened with a cDNA probe coding for rat liver cytochrome c oxidase subunit VIc (COX-VIc). Out of 16 clones mapped, four inserts were different and did not overlap. Two inserts that gave strong hybridization signals were characterized by sequence analysis. These data show that we have cloned two different genes for rat COX-VIc. The rat COX-VIc-2 gene contains four exons and three introns. The 5' boundary of the first exon was mapped by primer extension experiments. The nucleotide sequence of the first three exons is identical to the sequence of the rat liver cDNA probe; thus, we can conclude that this gene is expressed in rat liver. The second gene (COX-VIc-1) is 88% homologous to the rat liver cDNA and contains an open reading frame of 228 nucleotides capable of coding for a full-length COX-VIc polypeptide of 76 amino acids. This predicted translation product is 79% homologous to the rat liver peptide. The absence of introns and other factors, such as the presence of a 13-bp direct repeat and a poly(A) addition signal, indicate that this locus is a processed gene which may have evolved from spliced mRNA intermediates.

Sequence-dependent gene conversion: can duplicated genes diverge fast enough to escape conversion?

Conversion between duplicated genes limits their independent evolution. Models in which conversion frequencies decrease as genes diverge are examined to determine conditions under which genes can "escape" further conversion and hence escape from a gene family. A review of results from various recombination systems suggests two classes of sequence-dependence models: (1) the "k-hit" model in which conversion is completely inactivated by a few (k) mutational events, such as the insertion of a mobile element, and (2) more general models where conversion frequency gradually declines as genes diverge through the accumulation of point mutants. Exact analysis of the k-hit model is given and an approximate analysis of a more general sequence-dependent model is developed and verified by computer simulation. If mu is the per nucleotide mutation rate, then neutral duplicated genes diverging through point mutants are likely to escape conversion provided 2 mu/lambda much greater than 0.1, where lambda is the conversion rate between identical genes. If 2 mu/lambda much less than 0.1, the expected number of conversions before escape increases exponentially so that, for biological purposes, the genes never escape conversion. For single mutational events sufficient to block further conversions, occurring at rate nu per copy per generation, many conversions are expected if 2 nu/lambda much less than 1, while the genes essentially evolve independently if 2 nu/lambda much greater than 1. Implications of these results for both models of concerted evolution and the evolution of new gene functions via gene duplication are discussed.

Tissue-specific binding of a nuclear factor to the insulin gene promoter

Using a DNA-binding gel mobility shift assay, a protein-DNA complex was detected using the rat II insulin promoter and a nuclear extract from rat insulinoma cells. This complex was detected using extracts from other insulin-producing cell lines but was not found using nuclear extracts from non-insulin-producing pancreatic cell lines or other cell types. Binding of the tissue-specific protein to the labelled promoter fragment was effectively competed by both rat and human insulin genes but not by the SV40 TATA box. This protein DNA interaction may be involved in tissue-specific regulation of insulin gene expression.

Structure and evolutionary origin of the gene encoding mouse NF-M, the middle-molecular-mass neurofilament protein

We describe the complete sequence of the gene encoding mouse NF-M, the middle-molecular-mass neurofilament protein. The coding sequence is interrupted by two intervening sequences which align perfectly with the first two intervening sequences in the gene encoding NF-L (the low-molecular-mass neurofilament protein); there is no intron in the gene encoding NF-M corresponding to the third intron in NF-L. Therefore, both the number of introns and their arrangement in the genes coding NF-L and NF-M contrast sharply with the number and arrangement of introns in the genes of known sequence, encoding other members of the intermediate filament multigene family (desmin, vimentin, glial fibrillary acidic protein and the acidic and basic keratins); with the exception of a single truncated keratin gene that lacks an encoded tailpiece, these genes all contain eight introns, of which at least six are placed at homologous locations. Assuming the existence of a primordial intermediate filament gene containing most (if not all) the introns found in contemporary non-neurofilament intermediate filament genes, it seems likely that an RNA-mediated transposition event was involved in the generation of an ancestral gene encoding the NF polypeptides. A combination of insertional transposition and gene-duplication events could then explain the anomalous number and placement of introns within these genes. Consistent with this notion, we show that the genes encoding NF-M and NF-L are linked.

Nucleotide sequence of the promoter region of a tissue-specific human retroposon: comparison with its housekeeping progenitor

The intronless autosomal phosphoglycerate kinase gene (Pgk-2) is a functional retroposon expressed in a tissue-specific manner in the meiotic and postmeiotic stages of mammalian spermatogenesis. The nucleotide sequence of the promoter region of this gene and its transcription start point are compared with those of Pgk-1, an intron-containing, X-linked, housekeeping gene expressed constitutively in all somatic cells and premeiotic germ cells. The location of flanking direct repeats and apparent conservation of specific regulatory sequences suggest the Pgk-2 retroposon arose from reverse transcriptase-mediated processing of an aberrant Pgk-1 transcript that included the endogenous Pgk-1 promoter elements. Specific sequences that may be involved in mediating differences observed in both the level and cell-type specificity of expression of these genes in spermatogenesis are identified.

Two bovine genes for cytochrome c oxidase subunit IV: a processed pseudogene and an expressed gene

We have isolated and analyzed 17 clones from a bovine genomic library in phage lambda Charon28 probed with a bovine liver cDNA for cytochrome c oxidase subunit IV. Restriction enzyme mapping and Southern analysis indicated that these clones represent only two genomic regions. One region was shown by nucleotide sequencing to contain a subunit IV pseudogene of the processed type. The other class of clones contained the 5' region of a putative expressed gene; the region consists of two exons and two introns, with one exon encoding exclusively the domain representing the presequence present on newly synthesized subunit-IV polypeptides. Genomic Southern analysis indicated that these two clones probably represent the only sequences in the bovine nucleus that share nucleotide sequence identity with the liver subunit IV cDNA when utilizing moderately stringent hybridization conditions.

Characterization of mouse H3.3-like histone genes

We designed a strategy to select genomic clones of mouse replication-independent H3.3 histone genes. We obtained three clones which met our selection criteria for being H3.3 genes. Upon sequencing two of these clones we found that they were unlike previously isolated chicken H3.3 clones: they code for several unpredicted amino acid substitutions and contain no introns in the coding regions. We showed by S1 nuclease assays that these genes are protected by mRNAs that have expression characteristics of H3.3 mRNA. The protection data and nucleotide sequence analysis show that the H3.3 transcripts can be processed at one of four cleavage/polyadenylation sites. We show that these genes probably evolved through reverse transcription intermediates, and are processed pseudogenes which are no longer under selective pressure. The 5' and 3' transcribed, nontranslated sequences show extensive homology to those of a human cDNA clone, and we suggest that these sequences may be required for appropriate regulation of expression of H3.3 genes.

Rat insulin-like growth factor II gene. A single gene with two promoters expressing a multitranscript family

We have characterized the single-copy rat gene encoding the protein precursor of insulin-like growth factor II (pre-pro-rIGF-II) that is located downstream from and in the same transcriptional orientation as the homologous insulin II gene (5'-insulin-IGF-II-3'). This gene consists of at least three coding exons and utilizes two promoters that generate alternate 5' non-coding exons. Multiple transcripts from both promoters appear primarily in fetal or neonatal tissues (in all of the developmental stages and tissues that we have examined), but they are extremely rare or undetectable in adult tissues, with the exception of the brain and the spinal cord. These transcripts, which exhibit characteristic developmental profiles in various tissues, differ both in the presence of one of the alternate 5' non-coding exons and in the length of their fourth exon. The possible occurrence of differential splicing or differential polyadenylation (or both) in this region is discussed.

Characterization of the two nonallelic genes encoding mouse preproinsulin

We have cloned and sequenced the two mouse preproinsulin genes. The deduced amino acid sequences of the mature mouse insulins are identical to the published protein sequences. However, the nucleotide sequence indicates that the mouse I C-peptide has a deletion of two amino acids compared with the mouse II C-peptide. We used an S1 nuclease assay to confirm the presence of the deletion and to measure the ratio of transcripts from gene I to transcripts from gene II. The mouse preproinsulin I gene, like the rat gene I, is missing the second intervening sequence that normally interrupts the C-peptide region in other insulin genes. Comparison of the 5' flanking sequences of the mouse and rat genes II indicates that they are homologous for at least 1000 base pairs. The preproinsulin I genes also share homology in their 5' flanking DNAs; however, their homology to the preproinsulin II genes extends for only about 500 base pairs.

Human insulin-related DNA sequences map to chromosomes 2 and 11

The insulin-related hormone family consists of four known peptides: insulin, the insulin-like growth factors I and II, and relaxin. To investigate the hypothesis that the family contains additional members, we have isolated a series of human genomic clones using the insulin gene as a hybridization probe. Two of these single copy DNA sequences, hIr1 and hIr2, have been localized to chromosome 2 and 11p11----q13, respectively, by Southern blot analysis of mouse-human somatic cell hybrids, a result consistent with other evidence supporting the dispersal of the insulin gene family throughout the genome. Although a biological function for these DNA sequences has not yet been established, hIr1 and hIr2 are potentially useful as molecular probes for mapping, by analysis of restriction fragment length polymorphisms (RFLP), genetic disorders linked to chromosomes 2 or 11.

Rat LINE1: the origin and evolution of a family of long interspersed middle repetitive DNA elements

We present approximately 7.0 kb of composite DNA sequence of a long interspersed middle repetitive element (LINE1) present in high copy number in the rat genome. The family of these repeats, which includes transcribing members, is the rat homologue of the mouse MIF-Bam-R and human Kpn I LINEs. Sequence alignments between specimens from these three species define the length of a putative unidentified open reading frame, and document extensive recombination events that, in conjunction with retroposition, have generated this large family of pseudogenes and pseudogene fragments. Comparative mapping of truncated elements indicates that a specific endonucleolytic activity might be involved in illegitimate (nonhomologous) recombination events. Sequence divergence analyses provide insights into the origin and molecular evolution of these elements.