R-loop stability as a function of RNA structure and size.

The sequence-specific formation of R-loops can be assayed using RNAs which overlap a HindIII cleavage site in a 3.5 kb plasmid. Chemical modification of the displaced DNA strand has permitted stabilization of these R-loops and allowed a systematic investigation of the dependence of these triple-stranded structures on the chain length and structure of the input RNA. RNAs as short as 50 nt form stable R-loops if 5-allylamine uridines (Uaa-RNA) are used in place of normal uridines; normal RNAs must be 100 nt long to form R-loops quantitatively. Since acetic anhydride decreases the hybridization efficiency of Uaa-RNAs, the positive charge of the RNAs must diminish the electrostatic repulsion of the three negatively charged phosphodiester backbones. The dependence of R-loop stability on the length of RNA can be stimulated with a random walk model, which also applies to strand migration within Holiday junctions. R-loop hybridization provides a versatile method to generate single-stranded DNA in a sequence-selective manner.     

Improved methods for the formation and stabilization of R-loops

Improved methods for the formation and stabilization of R-loops for visualization in the electron microscope are presented. The two complementary strands of a duplex DNA are photochemically crosslinked once every 1 to 3 kb using 4, 5', 8 trimethylpsoralen. R-loops are then formed by incubation with RNA in 70% formamide at a temperature above the DNA melting temperature. Finally, the R-loops are stabilized by modifying the free single strand of DNA with glyoxal, thus minimizing the displacement of the hybridized RNA by branch migration. In this manner R-loops can be formed and visualized at a high frequency irrespective of the base composition of the nucleic acid of interest.     

Arrangement of the rRNA sequences in the rDNA of Lytechinus variegatus

The arrangement of the 26S RNA and 18S RNA sequences of the ribosomal DNA (rDNA) from the sea urchin Lytechinus variegatus was investigated by an electron microscopic analysis of R-loops formed between the ribosomal RNA genes and the mature ribosomal RNAs. Ninety-eight percent of observed molecules contained R-loops clearly seen as a three-stranded complex. The size of DNA complementary to mature cytoplasmic 18S and 26S ribosomal RNA (rRNA) was calculated by measuring the double-strand (ds) and single-strand (ss) part of the R-loops separately. The values for the 18S R-loop are 1.75±0.24 kb¹ (ss) and 1.56±0.23 kb (ds). The 26S R-loop is 3.34±0.39 kb (ss) and 3.33±0.33 kb (ds). These measurements agree fairly well with the rRNA sizes measured on denaturing sucrose density gradients: 3.23±0.22 kb for the 26S and 1.93±0.10 kb for 18S. The short spacer between the 18S and 26S R-loops is 1.03±0.24 kb and the longer spacer is 5.36±0.53 kb. In long molecules a repeating pattern was observed. The average length of an rDNA repeat unit is 11.33±0.64 kb when computed using double-strand R-loop measurements and 11.50±0.72 when computed using R-loop single-strand lengths.Abbreviations kb kilobases, 1000 bases of RNA or single-strand DNA, and kilobase pairs, 1000 base pairs of duplex DNA or DNA/RNA hybrid - EDTA ethylenediaminetetraacetate - SSC 0.15 M NaCl, 0.015 M sodium citrate - PIPES piperazine-N,N-bis (2-ethanesulfonic acid)-Na_1.4     

DNA sequence recognition by a eukaryotic sequence-specific endonuclease, Endo.SceI, from Saccharomyces cerevisiae

A eukaryotic sequence-specific endonuclease, Endo.SceI, causes sequence-specific double-stranded scission of double-stranded DNA to produce cohesive ends with four bases protruding at the 3' termini. Unlike in the case of restriction enzymes, an asymmetric 26-base pair consensus sequence was found around the cleavage site for Endo.SceI instead of a common sequence. We analyzed the base pairs that interacted with Endo.SceI on the recognition of its cleavage sites. A region comprising -10 through +16 base pairs from the center of the cleavage site was shown to be essential and sufficient for the sequence-specific cutting with Endo.SceI by experiments involving synthesized DNAs. Methylation interference experiments indicate that bases in the region comprising the +7 through +14 base pairs is involved in close contact with Endo.SceI in its recognition of the cleavage site. This +7 through +14-base pair region overlaps the most stringently conserved sequence in the consensus sequence for the cleavage site, suggesting that this region constitutes the core for the recognition by Endo.SceI.     

Cloning in a cosmid vector of complete 37 kb and 25 kb ribosomal DNA repeat units from the chicken

DNA fragments of up to 40 kb containing rRNA-coding sequences have been isolated from a chicken liver DNA library prepared in the cosmid pHC79. Characterization of the cloned DNA by R-loop and restriction mapping has shown that there are two size classes of repeat unit, one of 37 kb and one of 25 kb, the larger of which is a family of units which vary slightly in size. These two classes were shown to be present in the DNA of a single chicken. The size of the internal transcribed spacer in the chicken was measured to be 4.4 kb from analysis of R-loops and heteroduplexes between chicken and Xenopus laevis rDNAs. No introns were observed in either the 18 S or the 28 S coding sequences. The number of copies of the chicken rDNA unit was measured by titration against the cloned sequences to be 202±51 per haploid genome.     

R环的形成及对基因组稳定性的影响

R-环是由一个RNA:DNA杂交体和一条单链状态的DNA分子共同组成的三链核酸结构。其中, RNA:DNA杂交体的形成起因于基因转录所合成的RNA分子不能与模板分开, 或RNA分子重新与一段双链DNA分子中的一条链杂交。在基因转录过程中, 当转录泡遇到富含G碱基的非模板链区或位于某些与人类疾病有关的三核苷酸卫星DNA时, 转录泡后方累积的负超螺旋可促进R环形成。同时, 新生RNA分子未被及时加工、成熟或未被快速转运到细胞质等因素也会催生R环。研究表明, 细胞拥有多种管理R环的方法, 可以有效地管理R环的形成和处理已经形成的R环, 以尽量避免R环对DNA复制、基因突变和同源重组产生不利影响。文章重点分析了R-环的形成机制及R环对DNA复制、基因突变和同源重组的影响, 并针对R-环诱导的DNA复制在某些三核苷酸重复扩增有关的神经肌肉退行性疾病发生过程中的作用进行了分析和讨论。     

Molecular analysis of the human interferon-alpha gene family

Fifteen DNA clones containing sequences related to human interferon-alpha cDNA were isolated from a human chromosomal gene bank (Nagata et al., Nature 287 (1980) 401-408) and characterized by restriction mapping, R-loop and heteroduplex analysis. Nine distinct DNA segments hybridized strongly with interferon-alpha 1 cDNA and formed R-loops with poly(A) RNA from interferon-producing human leukocytes; most if not all of these segments represent functional interferon genes. Five segments hybridized weakly with the probe and did not form R-loops with the poly(A) RNA; one of these was characterized as an interferon-alpha pseudogene. Several DNA segments overlap and define a region of 36 kilobase pairs (kb) that contains three strongly and three weakly hybridizing sequences. From our data and those of Goeddel et al. (Nature 290 (1981) 20-25) we conclude that there exist at least 11 distinct genes of gene-like sequences of the interferon-alpha type in the human genome, of which most likely represents an allelic variant, and at least five pseudogenes distantly related to the interferon-alpha genes.     

The use of R-looping for structural gene identification and mRNA purification.

A method is presented for the purification of mRNAs and the identification of structural gene sequences in recombinant DNA molecules. RNA is hybridized to double-stranded linear DNA such that R-loops are formed between most DNAs and their complementary RNA sequences. These R-loops are purified from unhybridized RNAs by gel filtration chromatography in the presence of a high concentration of salt. The complementary RNAs are released from the R-loops by heating, and are assayed by gel electrophoresis or cell free translation to determine their purity and to identify the proteins for which they code. We have demonstrated that recombinant DNAs containing sequences for abundant or moderately abundant mRNAs of Saccharomyces cerevisiae can be identified by this means.     

Out of Balance: R-loops in Human Disease

R-loops are cellular structures composed of an RNA/DNA hybrid, which is formed when the RNA hybridises to a complementary DNA strand and a displaced single-stranded DNA. R-loops have been detected in various organisms from bacteria to mammals and play crucial roles in regulating gene expression, DNA and histone modifications, immunoglobulin class switch recombination, DNA replication, and genome stability. Recent evidence suggests that R-loops are also involved in molecular mechanisms of neurological diseases and cancer. In addition, mutations in factors implicated in R-loop biology, such as RNase H and SETX (senataxin), lead to devastating human neurodegenerative disorders, highlighting the importance of correctly regulating the level of R-loops in human cells. In this review we summarise current advances in this field, with a particular focus on diseases associated with dysregulation of R-loop structures. We also discuss potential therapeutic approaches for such diseases and highlight future research directions.     

Sequence-specific complex formation of DNA and a eukaryotic sequence-specific endonuclease, SceI.

Endo.SceI is a eukaryotic sequence-specific endonuclease of 120 kDa that causes sequence-specific double-stranded scission of DNA. Unlike results with restriction enzymes, we found a consensus sequence around the cleavage sites for Endo.SceI instead of a common sequence. We searched for conditions for studying the binding of Endo.SceI to DNA other than cutting. Under optimized conditions including gel mobility shift assay, Endo.SceI exhibited sequence-specific binding to a short double-stranded DNA (41 base pairs) containing a cleavage site and the DNA reisolated from the protein-DNA complex was not cleaved. The analysis of the complex of Endo.SceI and DNA isolated by the gel mobility shift experiments showed that the DNA-binding entity in the Endo.SceI preparation does have Endo.SceI activity and consists of an equal amount of 75-kDa and 50-kDa polypeptides. Based on this observation and those from previous studies, we conclude that Endo.SceI is a heterodimer of the 75-kDa and 50-kDa subunits. Under the present assay conditions, Endo.SceI did not show binding to single-stranded DNA having the same sequence of either plus or minus strand of the double-stranded DNA containing the cleavage site (the 41-bp DNA). Endo.SceI showed significantly higher affinity for the consensus sequence than the major cleavage site in pBR322 DNA. Unlike the cleavage of DNA by Endo.SceI which requires Mg2+, this sequence-specific binding is independent of but stimulated by Mg2+.     

Isolation and characterization of a genomic sequence of maize coding for a zein gene

Summary An EcoRI restriction endonuclease fragment of maize DNA coding for the 19,000 dalton zein protein was cloned in phage gt WES. The zein gene was identified by the electron microscopic analysis of RNA-DNA hybrids (R-loops) and DNA-DNA hybrids (D-loops). The R-loops were formed with poly(rA)-containing RNA isolated from 18 days post-pollination maize endosperm and showed no intervening non-hybridizing sequences (introns) within their 800 base length. A cDNA clone specific for the 19,000 dalton zein protein formed D-loops in the same position and orientation as the R-loops. The cloned fragment measured 4.4 kilobases (kb), the same size as an EcoRI fragment of maize DNA revealed by Southern analysis.     

Application of the avidin-biotin method of gene enrichment to the isolation of long double-stranded DNA containing specific gene sequences.

A method of enriching for long double-stranded segments of eukaryotic DNA carrying particular genes is described. A purified RNA coded for by the gene is covalently attached to biotin via the protein, cytochrome c. This modified RNA is hybridized to total nuclear, double-stranded DNA under conditions that allow the formation of R-loops. Avidin, which has a high affinity for biotin, is covalently attached to polymer spheres. The complexes of avidin-spheres with DNA:RNA-biotin R-loop hybrids band in CsCl at a much lower bouyant density than does free DNA. This density is a function of the length of DNA coupled per avidin-sphere. This method was used to prepare very long double-strands of DNA highly enriched in the coding sequences for the large rRNAs of D. melanogaster and L. donovani and the histone mRNAs of S. purpuratus.