Mapping the topography of DNA wrapped around gyrase by nucleolytic and chemical probing of complexes of unique DNA sequences

Complexes between DNA gyrase and DNA fragments of unique sequences were used to probe the topography of the DNA with nucleases and dimethyl sulfate. The results indicate that the flanking regions, each 50 bp in size, of a 145--155 bp DNA segment resistant to staphylococcal nuclease contain groups of pancreatic DNAase I-susceptible sites that are spaced 10--11 nucleotides apart. Pairs of adjacent DNAase I-sensitive sites on complementary strands are typically staggered by 2--4 bp. The binding of DNA to gyrase confers no protection against alkylation of the DNA by dimethyl sulfate. These properties of the gyrase-DNA complex are reminiscent of those of the nucleosome, and the common underlying structural feature appears to be wrapping of the DNA around a protein core. The gyrase-DNA complex differs from the nucleosome, however, in that it must possess features necessary for the catalysis of DNA chain breakage and the modulation of the DNA-enzyme interaction by ATP. We present evidence that the breakage and rejoining of the DNA by gyrase occur within a central region of the staphylococcal nuclease-resistant DNA segment. The relation of this observation to the mechanism of DNA supercoiling by gyrase is discussed. Addition of ATP or its beta, gamma-imido analog has essentially no effect on the patterns of susceptibilities to DNAase I, implying that the DNA-enzyme contacts mapped by the nuclease ae little affected by ATP-induced conformational changes.     

A protein binds to a satellite DNA repeat at three specific sites that would be brought into mutual proximity by DNA folding in the nucleosome

Using a generally applicable assay for specific DNA-binding proteins in crude extracts, we have detected and purified an HMG-like nuclear protein from African green monkey cells that preferentially binds to the 172 bp repeat of alpha-satellite DNA (alpha-DNA). DNAase I footprinting with the purified protein detects three specific binding sites (I-III) per alpha-DNA repeat. Site II is 145 bp (one core nucleosome length) from site III on the adjacent alpha-DNA repeat, while site I lies midway between sites II and III. In the alpha-nucleosome phasing frame corresponding with this arrangement, sites I-III would be brought into mutual proximity by DNA folding in the nucleosome. This phasing frame is identical with the preferred frame detected previously in isolated chromatin. Our results suggest that this new and abundant protein recognizes a family of short, related nucleotide sequences found not only in alpha-DNA but also throughout the genome, and that functions of this protein are mediated through its nucleosome-positioning activity. Such nucleosome-positioning proteins may underlie the sequence specificity of both nucleosome arrangements and higher order chromatin structures.     

Identification of Kaposi's Sarcoma-Associated Herpesvirus LANA Regions Important for Episome Segregation,Replication, and Persistence

Kaposi''s sarcoma-associated herpesvirus (KSHV) latency-associated nuclear antigen (LANA) is a 1,162-amino-acid protein that mediates the maintenance of episomal viral genomes in latently infected cells. The two central components of episome persistence are DNA replication with each cell division and the segregation of DNA to progeny nuclei. LANA self-associates to bind KSHV terminal-repeat (TR) DNA and to mediate its replication. LANA also simultaneously binds to TR DNA and mitotic chromosomes to mediate the segregation of episomes to daughter nuclei. The N-terminal region of LANA binds histones H2A and H2B to attach to mitotic chromosomes, while the C-terminal region binds TR DNA and also associates with chromosomes. Both the N- and C-terminal regions of LANA are essential for episome persistence. We recently showed that deletion of all internal LANA sequences results in highly deficient episome maintenance. Here we assess independent internal LANA regions for effects on episome persistence. We generated a panel of LANA mutants that included deletions in the large internal repeat region and in the unique internal sequence. All mutants contained the essential N- and C-terminal regions, and as expected, all maintained the ability to associate with mitotic chromosomes in a wild-type fashion and to bind TR DNA, as assessed by electrophoretic mobility shift assays (EMSA). Deletion of the internal regions did not reduce the half-life of LANA. Notably, deletions within either the repeat elements or the unique sequence resulted in deficiencies in DNA replication. However, only the unique internal sequence exerted effects on the ability of LANA to retain green fluorescent protein (GFP) expression from TR-containing episomes deficient in DNA replication, consistent with a role in episome segregation; this region did not independently associate with mitotic chromosomes. All mutants were deficient in episome persistence, and the deficiencies ranged from minor to severe. Mutants deficient in DNA replication that contained deletions within the unique internal sequence had the most-severe deficits. These data suggest that internal LANA regions exert critical roles in LANA-mediated DNA replication, segregation, and episome persistence, likely through interactions with key host cell factors.     

Structure of the extrachromosomal ribosomal RNA chromatin of Physarum polycephalum

Isolated nucleoli from exponentially growing microplasmodia of Physarum polycephalum were digested with micrococcal nuclease or DNAase I, or were photoreacted with trimethyl psoralen. In the coding region for the precursor of the ribosomal RNA, micrococcal nuclease and DNAase I digestions show predominantly a smear, and treatment with psoralen leads to a fairly continuous crosslinking of the DNA. All three assays are compatible with the absence of a typical nucleosomal array in most of the gene copies. In contrast, in the central non-transcribed spacer, except in the immediate 5'-flanking region, micrococcal nuclease and DNAase I digestions yield fragments that are multiples of a basic repeat, compatible with a nucleosomal packing of this region. The crosslinking pattern with psoralen confirms this conclusion. In addition, there are three sites over 400 base-pairs long that are inaccessible for psoralen crosslinking. Two of these sites have been mapped to the putative origins of replication. In the terminal non-transcribed spacer, except in the immediate 3'-flanking region, digestions with micrococcal nuclease and DNAase I give a smeared repeat. The crosslinking pattern after treatment with psoralen suggests that this region is packed in nucleosomes, except for about 900 base-pairs constituting the telomere regions of the linear extrachromosomal palindromic rDNA. Micrococcal nuclease digestion of the immediate 5'-flanking region shows a complete absence of any nucleosomal repeat, but digestion with DNAase I leads to a faint ten base-pair repeat. In contrast, in the 3'-flanking regions both nuclease assays indicate a chromatin structure similar to the coding region. Both flanking regions are unusual with respect to psoralen crosslinking, in that crosslinking is reduced both in chromatin and deproteinized DNA. On the basis of the known sequence-dependent psoralen crosslinking and the established sequences in these regions, crosslinking should be expected to occur. However, it does not and we therefore propose the presence of an unusual DNA conformation in these regions.     

Effect of 27nt small RNA on endothelial nitric-oxide synthase expression

We have reported previously that the 27nt repeat polymorphism in endothelial nitric-oxide synthase (eNOS) intron 4-a source of 27nt small RNA-inhibits eNOS expression. In the current study, we have investigated how 27nt small RNA suppresses eNOS expression. Using a chromatin immunoprecipitation assay, we examined histone acetylation in the 27nt repeat element of eNOS intron 4, the promoter region up to -1486 bp, and the 5' enhancer region (-4583/-4223bp) in human aortic endothelial cells (HAECs) treated with 27nt RNA duplex. 27nt RNA duplex induced hyperacetylation in H3 (lysine8, 12, and 23) and H4 (lysine 9 and 12) at the 27nt repeat element, which then interacted with nuclear actin, histone deacetylase 3 (HDAC3), and NonO proteins. In contrast, the histone H3 and H4 became hypoacetylated at the eNOS core promoter. HAECs treated with 27nt RNA duplex had reduced eNOS expression, but treatment with either HDAC3 small interfering RNA or NonO siRNA significantly attenuated the 27nt small RNA-induced suppression. We further found that 27nt small RNA induced DNA methylation in a region approximately 750nt upstream of the intron 4 repeats, and a methyltransferase inhibitor reversed the effect on methylation and eNOS expression. Our study demonstrates that 27nt small RNA may suppress eNOS expression by altering histone acetylation and DNA methylation in regions adjacent to the 27nt repeat element and core promoter.     

Repetitive sequences of the tree shrew genome (Mammalia, Scandentia)

Copies of two repetitive elements of the genome of common tree shrew (Tupaia glis) were cloned and sequenced. The first element, Tu III, is a approximately 260 bp long short interspersed element (SINE) with the 5'-end derived from glycine RNA. Tu III carries long polypurine- and polypyrimidine-rich tracts, which may contribute to the specific secondary structure of Tu III RNA. This SINE was also found in the genome of smooth-tailed tree shrew of another genus (Dendrogale). Tu III seems to be confined to the order Scandentia (tree shrews) since it was not found in DNA of other tested mammals. The second element Tu-SAT1 is a tandem repeat with a monomer length of 365 bp. Some properties of its nucleotide sequence suggest that Tu-SAT1 is a centromeric satellite.     

Repetitive sequences of the tree shrew genome (Mammalia, Scandentia)

Copies of two repetitive elements of the common tree shrew (Tupaia glis) genome were cloned and sequenced. The first element, Tu III, is a ～260 bp long short interspersed element (SINE) with the 5′ end derived from glycine RNA. Tu III carries long polypurine-and polypyrimidine-rich tracts, which may contribute to the specific secondary structure of Tu III RNA. This SINE was also found in the genome of the smooth-tailed tree shrew of another genus (Dendrogale). Tu III appears to be confined to the order Scandentia since it was not found in the DNA of other tested mammals. The second element, Tu-SAT1, is a tandem repeat with a monomer length of 365 bp. Some properties of its nucleotide sequence suggest that Tu-SAT1 is a centromeric satellite.     

Nucleic acids in mummified plant seeds: biochemistry and molecular genetics of pre-Columbian maize.

Nucleic acids fractions were isolated from pre-Columbian maize seeds and characterized using different approaches such as polyacrylamide gel electrophoresis, anti-DNA antibody binding, HPLC fractionation, molecular hybridization with cloned genes, and DNA amplification by the polymerase chain reaction. The nucleic acids were found to be very depolymerized (less than or equal to 140 base pairs in length) and composed mainly of ribosomal RNA. Despite the very low amount and degree of polymerization of seed DNA, specific maize nuclear Mu1, Mu4, Mu8 and, possibly, Mu5 element components could be detected, thanks to the use of amplification systems as short as 90 bp. The results suggest that evaluation of the relative proportions of Mu-type element components and, possibly, other maize genomic components in single mummified kernels, may offer a new key to the study of ancient maize populations.     

Different repeat lengths in rat satellite I DNA containing chromatin and bulk chromatin.

The nucleosome repeat structure of a rat liver chromatin component containing the satellite I DNA (repeat length 370 bp) was investigated. Digestion experiments with micrococcal nuclease, DNAase II, and the Ca2+/Mg2+-dependent endogenous nuclease of rat liver nuclei revealed a repeat unit of 185 nucleotide pairs which is shorter by approximately 10 bp than the repeat unit of the bulk chromatin of this cell type. The difference seems not to be related to the histone composition which was found to be similar in the two types of chromatin.     

Identification and mapping of a 60 bp EcoRI fragment in the Dictyostelium discoideum ribosomal DNA

We have re-examined the organization of the transcribed sequences in the ribosomal DNA repeat unit of Dictyostelium discoideum. In addition to the four EcoRI fragments previously reported, we have identified and cloned a fifth fragment which defines a small portion of the 25S ribosomal RNA. The fragment is 60 bp long and is located between the 1.5 kbp and the 3 kbp EcoRI fragments of the ribosomal DNA repeat unit.     

A molecular basis for discrete size variation in human ribosomal DNA.

The tandemly repeated human ribosomal RNA (rRNA) genes contain a region of size heterogeneity that is present in the nontranscribed spacer of every individual examined. This heterogeneity has been previously examined by Southern analysis of BamHI-digested human DNA. Using a ribosomal DNA (rDNA) probe specific for the 3' end of the 28S rRNA gene, at least four discrete sizes of BamHI fragments were seen in human populations. Molecular analysis of the cloned DNA from this region reveals tandem duplication of a segment of spacer rDNA located 388 base pairs (bp) 3' to the end of the 28S ribosomal RNA gene. Five hundred fifty bp of DNA, flanked on either side by a 150-bp repeated element, is either duplicated or deleted to produce a series of spacers that differ in size by 850 bp. These duplications/deletions appear to be the product of unequal homologous exchange, mediated by the small repeated element. Thus, human rDNA fragments cloned in lambda vectors and propagated in E. coli generate the same apparent size variation seen in genomic DNA. This study suggests that unequal homologous exchange is the molecular basis for the observed length heterogeneity in the spacer rDNA and may be a common mechanism for the generation of human genetic diversity.