Mobile dispersed genetic element MDG1 of Drosophila melanogaster: structural organization.

The whole-length mobile dispersed genetic element mdg1 has been cloned from D. melanogaster genome. It contains DNA fragments described earlier as Dm225 and Dm234, Mdg1 is 7.2 kb long and framed with two direct repeats of 300-400 base pairs each. Mdg1 family is represented by about 25 copies in the genome of flies and by 200 copies in the genome of cultured cell line 67J25D. Virtually all the copies in the genome of D. melanogaster have the same restriction map. Oligo(dA)-oligo(dT) regions were found within mdg1.     

Characterization and expression of collagen-like genes in Drosophila melanogaster

We have used a cloned chicken collagen cDNA sequence to help identify hypothetic members of the collagen gene family from Drosophila melanogaster. Several experimental evidences have been obtained which indicate that the Drosophila genome contains numerous collagen-like sequences. We have characterized in more detail ten distinct DNA sequences that hybridized strongly to the heterologous collagen probe. By in situ hybridization we have shown that these sequences are dispersed throughout the Drosophila genome. Two of them are shown to originate from the previously described DCg 1 and DCg 2 collagen genes. In other respects, we show that in addition to DCg 1 and DCg 2, at least five putative collagen genes are expressed during the Drosophila lifetime. These genes are unique, and some of them are seen to be transcribed into different size classes of mRNAs. Additionally, the data presented so far demonstrate that the expression of these genes is regulated temporally and/or quantitatively during the Drosophila life cycle.     

Amplification of CFTR Exon 9 Sequences to Multiple Locations in the Human Genome

Cloning and characterization of the cystic fibrosis transmembrane conductance regulator (CFTR) gene led to the identification and isolation of cDNA and genomic sequences that cross-hybridized to the first nucleotide binding fold of CFTR. DNA sequence analysis of these clones showed that the cross-hybridizing sequences corresponded to CFTR exon 9 and its flanking introns, juxtapositioned with two segments of LINE1 sequences. The CFTR sequence appeared to have been transcribed from the opposite direction of the gene, reversely transcribed, and co-integrated with the L1 sequences into a chromosome location distinct from that of the CFTR locus. Based on hybridization intensity and complexity of the restriction fragments, it was estimated that there were at least 10 copies of the “amplified” CFTR exon 9 sequences in the human genome. Furthermore, when DNA segments adjacent to the insertion site were used in genomic DNA blot hybridization analysis, multiple copies were also detected. The overall similarity between these CFTR exon 9-related sequences suggested that they were derived from a single retrotransposition event and subsequent sequence amplification. The amplification unit appeared to be greater than 30 kb. Physical mapping studies includingin situhybridization to human metaphase chromosomes showed that multiple copies of these amplified sequences (with and without the CFTR exon 9 insertion) were dispersed throughout the genome. These findings provide insight into the structure and evolution of the human genome.     

Actin gene expression is modulated by ecdysterone in a Drosophila cell line

The steroid hormone ecdysterone induced characteristic and specific changes of morphology, enzymatic activities and protein synthesis in a Kc 0% Drosophila melanogaster cell line. To study the ecdysterone action at a molecular level, a Drosophila genomic library was screened by differential hybridization to poly(A)+ RNA from control and ecdysterone-treated cells. Two recombinant phages were selected for hybridizing very intensively with poly(A)+ RNA of ecdysterone-treated cells and very weakly with poly(A)+ RNA of untreated ones. These two clones (lambda Dm 1632 and lambda Dm A5A1) mapped at the 5 C locus on polytene chromosomes; they overlap for a 9000 base-pair sequence that contains an abundantly transcribed region in ecdysterone-treated cells of about 2000 base-pairs. This region permits the selection of mRNA that gives, after translation in vitro, two polypeptides identified as cytoplasmic actin II and III. We demonstrated that these two recombinant phages, hybridizing preferentially with poly(A)+ RNA of ecdysterone-treated cells, contain the 5 C actin gene. Poly(A)+ RNA prepared from various times of treatment of cells were electrophoresed on agarose gels, transferred to nitrocellulose paper and then hybridized with the cloned actin probe. Results of these experiments indicate that there is a sharp increase in the level of RNA coding for actin after ecdysterone treatment of the cell, and that there are two forms of actin-specific RNA in the D. melanogaster cells. Using genomic blots with specific probes derived from lambda Dm 1632, we show that there are six actin genes per haploid Drosophila cell genome contained on six EcoRI fragments, as in Drosophila embryos, indicating that there is no rearrangement of these sequences in cultured cells. Our results suggest that the expression of actin genes in D. melanogaster Kc 0% cells is modulated by ecdysterone.     

The 5S RNA genes of Schizosaccharomyces pombe.

The genomic arrangement and sequences of S. pombe 5S RNA genes are reported here. The 5S gene sequences appear to be dispersed within the genome, and are found independently of other rRNA genes. The sequences of two 5S genes examined show identical coding regions of 119 base pairs but have widely varying flanking sequences. A tRNAAsp gene is found in the 3' flanking region of one of the 5S genes. The tRNAAsp gene is faithfully transcribed in an X. laevis in vitro system, while the 5S genes are not transcribed in this system. The phylogenetic position of S. pombe is examined through comparison of 5S RNA sequences.     

Evolution of human cytoplasmic actin gene sequences: chromosome mapping and structural characterizations of three cytoplasmic actin-like pseudogenes including one on the Y chromosome

Eight recombinant phage clones containing cytoplasmic actin-like gene sequences have been isolated from a human genomic library for structural characterization. Kpn I family repeat sequences flank six of these actin genes isolated, and Alu family repeats are scattered throughout the DNA inserts of all eight phage clones. Three of these genes are γ actin-like, and the other five are β actin-like. The complete nucleotide sequence analysis of one β and one γ actin-like genes and their flanking regions demonstrates that they both are processed pseudogenes. Using unique DNA sequences flanking these two pseudogenes as hybridization probes for human-mouse somatic cell hybrid DNAs, we have mapped the two actin pseudogenes on human chromosomes 8 and 3, respectively. We have also determined the DNA sequence of a human Y chromosome-linked, processed actin pseudogene. The different values of sequence divergence of these processed pseudogenes and their functional counterparts allow us to estimate the time of generation of the pseudogenes. The results suggest that the cDNA insertion events generating the human cytoplasmic actin-like pseudogenes have occurred at significantly different times during the evolution of primates, after their separation from other mammalian species.     

Localization of three DNA segments encompassing tRNA genes to human chromosomes 1, 5, and 16: proposed mechanism and significance of tRNA gene dispersion

The chromosomal locations of three cloned human DNA fragments encompassing tRNA genes have been determined by Southern analysis of human-rodent somatic cell hybrid DNAs with subfragments from these cloned genes and flanking sequences used as hybridization probes. These three DNA segments have been assigned to human chromosomes 1, 5, and 16, and homologous sequences are probably located on chromosome 14 and a separate locus on chromosome 1. These studies, combined with previous results, indicate that tRNA genes and pseudogenes are dispersed on at least seven different human chromosomes and suggest that these sequences will probably be found on most, if not all, human chromosomes. Short (8-12 nucleotide) direct terminal repeats flank many of the dispersed tRNA genes. The presence of these flanking repeats, combined with the dispersion of tRNA genes throughout the human genome, suggests that many of these genes may have arisen by an RNA-mediated retroposition mechanism. The possible functional significance of this gene dispersion is considered.     

Gene Conversion Drives Within Genic Sequences: Concerted Evolution of Ribosomal RNA Genes in Bacteria and Archaea

Multiple copies of a given ribosomal RNA gene family undergo concerted evolution such that sequences of all gene copies are virtually identical within a species although they diverge normally between species. In eukaryotes, gene conversion and unequal crossing over are the proposed mechanisms for concerted evolution of tandemly repeated sequences, whereas dispersed genes are homogenized by gene conversion. However, the homogenization mechanisms for multiple-copy, normally dispersed, prokaryotic rRNA genes are not well understood. Here we compared the sequences of multiple paralogous rRNA genes within a genome in 12 prokaryotic organisms that have multiple copies of the rRNA genes. Within a genome, putative sequence conversion tracts were found throughout the entire length of each individual rRNA genes and their immediate flanks. Individual conversion events convert only a short sequence tract, and the conversion partners can be any paralogous genes within the genome. Interestingly, the genic sequences undergo much slower divergence than their flanking sequences. Moreover, genomic context and operon organization do not affect rRNA gene homogenization. Thus, gene conversion underlies concerted evolution of bacterial rRNA genes, which normally occurs within genic sequences, and homogenization of flanking regions may result from co-conversion with the genic sequence. Received: 31 March 2000 / Accepted: 15 June 2000     

A new copia-like transposable element found in a Drosophila rDNA gene unit.

We have discovered a member of a new family of copia-like transposable elements inserted into the non-transcribed spacer between two ribosomal genes (rDNA). This family, which we call 3S18, consists of at least 15 elements which are scattered throughout the Drosophila melanogaster genome. The elements of this family are approximately 6.5 kb long and have 0.5 kb terminal direct repeats. All of the elements appear to have the same restriction sites. The element is mobile as the size pattern of homologous fragments varies among different strains. In situ hybridization results confirm the scattered location and transposable qualities of 3S18. The element is not transcribed into abundant RNA.     

Human tRNA genes function as chromatin insulators

Insulators help separate active chromatin domains from silenced ones. In yeast, gene promoters act as insulators to block the spread of Sir and HP1 mediated silencing while in metazoans most insulators are multipartite autonomous entities. tDNAs are repetitive sequences dispersed throughout the human genome and we now show that some of these tDNAs can function as insulators in human cells. Using computational methods, we identified putative human tDNA insulators. Using silencer blocking, transgene protection and repressor blocking assays we show that some of these tDNA-containing fragments can function as barrier insulators in human cells. We find that these elements also have the ability to block enhancers from activating RNA pol II transcribed promoters. Characterization of a putative tDNA insulator in human cells reveals that the site possesses chromatin signatures similar to those observed at other better-characterized eukaryotic insulators. Enhanced 4C analysis demonstrates that the tDNA insulator makes long-range chromatin contacts with other tDNAs and ETC sites but not with intervening or flanking RNA pol II transcribed genes.     

Isolation of three novel Drosophila melanogaster genes containing repetitive sequences rich in GCN triplets.

Several cDNA and genomic clones were isolated from Drosophila melanogaster gene libraries by hybridization with a region of a mammalian gene that contains a simple repetitive sequence of six GCN repeats. One of the cDNA clones, E6, was completely sequenced and it was shown that it contains a region of 16 GCN repeats; these repeats encode a polyalanine stretch within a long open reading frame. The sequencing of three different genomic clones (A, B, and D) revealed that all the isolated Drosophila clones are similar to one another in a short region containing variable numbers of the GCN repeat. The genomic clone B was found to be the genomic counterpart of the cDNA clone E6. The other genomic clones, A and D, also hybridize with Drosophila cDNA clones at high stringency. These results indicate that the short GCN repetitive sequences, which we have named ala, are found within transcribed regions of the Drosophila genome. These Drosophila genes containing the ala repeat do not show significant sequence similarity to any presently known gene; we have named these novel genes ala-A, ala-B, and ala-D. The cDNA clone from gene ala-B was named ala-E6.     

A repetitive and apparently transposable DNA sequence in Dictyostelium discoideum associated with developmentally regulated RNAs.

Dictyostelium discoideum AX3 genomic DNA contains about 40 copies of a 4.5 Kb sequence. Each has the same restriction map, suggesting that they are all very similar. The sequences are scattered throughout the genome, and each of the six representative copies we cloned have different flanking sequences. Partial fragments of the 4.5 Kb sequence also are scattered throughout the genome. The DNA sequences flanking the 4.5 Kb repetitive sequences are different in different strains of Dictyostelium suggesting that the 4.5 Kb sequence is a transposable element. Each sub-region of this 4.5 Kb sequence is associated with a large number of mRNAs, all of which are developmentally regulated, but whose function is not known.     

Applications of retrotransposons as genetic tools in plant biology

Retrotransposons are mobile genetic elements that accomplish transposition via an RNA intermediate that is reverse transcribed before integration into a new location within the host genome. They are ubiquitous in eukaryotic organisms and constitute a major portion of the nuclear genome (often more than half of the total DNA) in plants. Furthermore, they are dispersed as interspersed repetitive sequences throughout most of the length of all host chromosomes. These unique properties of retrotransposons have been exploited as genetic tools for plant genome analysis. Major applications are in determining phylogeny and genetic diversity and in the functional analyses of genes in plants. Here, recent advances in molecular markers, gene tagging and functional genomics technologies using plant retrotransposons are described.     

Conserved sequences in both coding and 5'' flanking regions of mammalian opal suppressor tRNA genes.

The rabbit genome encodes an opal suppressor tRNA gene. The coding region is strictly conserved between the rabbit gene and the corresponding gene in the human genome. The rabbit opal suppressor gene contains the consensus sequence in the 3' internal control region but like the human and chicken genes, the rabbit 5' internal control region contains two additional nucleotides. The 5' flanking sequences of the rabbit and the human opal suppressor genes contain extensive regions of homology. A subset of these homologies is also present 5' to the chicken opal suppressor gene. Both the rabbit and the human genomes also encode a pseudogene. That of the rabbit lacks the 3' half of the coding region. Neither pseudogene has homologous regions to the 5' flanking regions of the genes. The presence of 5' homologies flanking only the transcribed genes and not the pseudogenes suggests that these regions may be regulatory control elements specifically involved in the expression of the eukaryotic opal suppressor gene. Moreover the strict conservation of coding sequences indicates functional importance for the opal suppressor tRNA genes.