Isolation and structural analysis of ribosomal protein genes in Xenopus laevis. Homology between sequences present in the gene and in several different messenger RNAs

The ribosomal protein genes are present in two to four copies per haploid genome of Xenopus laevis. Using cloned complementary DNA probes, we have isolated, from a genomic library of X. laevis, several clones containing genes for two different ribosomal proteins (L1 and L14). These genes contain intervening sequences. In the case of the L1 gene, the exons are 100 to 200 base-pairs long and the introns, on average, 400 base-pairs. Along the genomic fragments, two different classes of repetitive DNA are present: highly and middle repetitive DNA. Both are evolutionarily unstable as shown by hybridization to Xenopus tropicalis DNA. Several introns of the gene coding for protein L1 contain middle repetitive sequences. Hybridization and hybrid-released translation experiments have shown that sequences inside the two genes hybridize to several poly(A) messenger RNAs. Some of the products encoded by these mRNA have electrophoretic properties of ribosomal proteins.     

One-step metal-affinity purification of histidine-tagged proteins by temperature-triggered precipitation

The feature of elastin-like proteins (ELPs) to reversibly precipitate above their transition temperature was exploited as a general method for the purification of histidine (His)-tagged proteins. The principle of the single-step metal-affinity method is based on coordinated ligand-bridging between the modified ELPs and the target proteins. ELPs with repeating sequences of [(VPGVG)(2)(VPGKG)(VPGVG)(2)](21) were synthesized and the free amino groups on the lysine residues were modified by reacting with imidazole-2-carboxyaldehyde to incorporate the metal-binding ligands into the ELP bio- polymers. Biopolymers charged with Ni(2+) were able to interact with a His tag on the target proteins based on metal coordination chemistry. Purifications of two His-tagged enzymes, beta-D-galactosidase and chloramphenicol acetyltransferase, were used to demonstrate the utility of this general method and over 85% recovery was observed in both cases. The bound enzymes were easily released by addition of either EDTA or imidazole. The recovered ELPs were reused four times with no observable decrease in the purification performance.     

CAC – the neglected repeat

It is becoming increasingly clear that repetitive DNA is of biological significance as well as experimental importance. Here we review the information available about one type of repetitive DNA, the trinucleotide repeat (CAC)_n, and briefly compare it with other trinucleotide repeats. Although much work has been done in analysing DNA fingerprinting patterns produced using the synthetic oligonucleotide (CAC)₅ as a probe, there is relatively little information about individual (CAC)_n-containing sequences and their abundance, organisation and distribution in mammalian DNA. From the data that is available, it is clear that there are at least two areas that should repay further study: (1) the organisation and generation of long sequences that contain (CAC)_n motifs as part of a larger repeating unit (minisatellites) and (2) the distribution of small (CAC)_n sequences (microsatellites), in particular their relationship to genes.     

Screening and cloning of antimicrobial DNA sequences using a vital staining method

A novel method for cloning of genes coding for cytotoxic molecules based on a cell viability assay is described. The working hypothesis is that expression of DNA sequences coding for cytotoxic molecules in bacterial cells will lead to cell death or impairment, and the isolation of the impaired or dead cells could lead to identification of DNA sequences responsible for debilitating the host cells. We verified this concept by isolating the well known antimicrobial Puroindoline b gene in Escherichia coli cells. We further demonstrated the feasibility to use this approach for isolating DNA encoding for antimicrobials from cDNA expression libraries. Sequence analysis and bioassay indicated that the isolated clones encoded previously characterized antimicrobial proteins (AMPs), proteins not previously characterized as AMPs, as well as novel antimicrobial peptides. In addition, clones harboring ribosomal protein encoding cDNA were also identified. Therefore, this method could also be used to identify host genes important in maintaining bacterial cell viability.     

An alternative view of mammalian DNA sequence organization: II. Short repetitive sequences are organized into scrambled tandem clusters in Syrian hamster DNA

Hyperchromicity, S₁ nuclease digestion, and reassociation studies of Syrian hamster repetitive DNA have led to novel conclusions about repetitive sequence organization. Re-evaluation of the hyperchromicity techniques commonly used to determine the average length of genomic repetitive DNA regions indicates that both the extent of reassociation, and the possibility of non-random elution of hyperpolymers from hydroxyapatite can radically affect the observed hyperchromicity. An alternative interpretation of hyperchromicity experiments, presented here, suggests that the average length of repetitive regions in Syrian hamster DNA must be greater than 4000 nucleotides.S₁ nuclease digestion of reassociated 3200 nucleotide Syrian hamster repetitive DNA, on the other hand, yields both long (>2000 nucleotides) and short (300 nucleotides) resistant DNA duplexes. Calculations indicate that the observed mass of short nuclease-resistant duplexes (>60%) is too large to have arisen only from independent short repetitive DNA sequences alternating with non-repetitive regions. Reassociation experiments using long and short S₁ nuclease-resistant duplexes as driver DNA indicate that all repetitive sequences are present in both fractions at approximately the same concentration. Isolated long S₁ nuclease-resistant duplexes, after denaturation, renaturation, and a second S₁ nuclease digestion, again produce both long and short DNA duplexes. Reassociation experiments indicate that all repetitive DNA sequences are still present in the “recycled” long S₁ nuclease-resistant duplexes. These experiments imply that many of the short S₁ nuclease-resistant repetitive DNA duplex regions present in reassociated Syrian hamster DNA were initially present in the genome as part of longer repetitive sequence blocks. This conclusion suggests that the majority of “short” repetitive regions in Syrian hamster DNA are organized into scrambled tandem clusters rather than being individually interspersed with non-repetitive regions.     

FastGroup: A program to dereplicate libraries of 16S rDNA sequences

Background

Ribosomal 16S DNA sequences are an essential tool for identifying and classifying microbes. High-throughput DNA sequencing now makes it economically possible to produce very large datasets of 16S rDNA sequences in short time periods, necessitating new computer tools for analyses. Here we describe FastGroup, a Java program designed to dereplicate libraries of 16S rDNA sequences. By dereplication we mean to: 1) compare all the sequences in a data set to each other, 2) group similar sequences together, and 3) output a representative sequence from each group. In this way, duplicate sequences are removed from a library.

Results

FastGroup was tested using a library of single-pass, bacterial 16S rDNA sequences cloned from coral-associated bacteria. We found that the optimal strategy for dereplicating these sequences was to: 1) trim ambiguous bases from the 5' end of the sequences and all sequence 3' of the conserved Bact517 site, 2) match the sequences from the 3' end, and 3) group sequences >=97% identical to each other.

Conclusions

The FastGroup program simplifies the dereplication of 16S rDNA sequence libraries and prepares the raw sequences for subsequent analyses.     

Discovery of active proteins directly from combinatorial randomized protein libraries without display, purification or sequencing: identification of novel zinc finger proteins

We have successfully linked protein library screening directly with the identification of active proteins, without the need for individual purification, display technologies or physical linkage between the protein and its encoding sequence. By using ‘MAX’ randomization we have rapidly constructed 60 overlapping gene libraries that encode zinc finger proteins, randomized variously at the three principal DNA-contacting residues. Expression and screening of the libraries against five possible target DNA sequences generated data points covering a potential 40000 individual interactions. Comparative analysis of the resulting data enabled direct identification of active proteins. Accuracy of this library analysis methodology was confirmed by both in vitro and in vivo analyses of identified proteins to yield novel zinc finger proteins that bind to their target sequences with high affinity, as indicated by low nanomolar apparent dissociation constants.     

DNA sequence organization in the genome of Petroselinum sativum (Umbelliferae)

The genome of parsley was studied by DNA/DNA reassociation to reveal its spectrum of DNA reiteration frequencies and sequence organization. The reassociation of 300 nucleotide DNA fragments indicates the presence of four classes of DNA differing in repetition frequency. These classes are: highly repetitive sequences, fast intermediate repetitive sequences, slow intermediate repetitive sequences, and unique sequences. The repeated classes are reiterated on average 136,000, 3000, and 42 times respectively. A minor part of the genome is made up of palindromes. — The organization of DNA sequences in the P. sativum genome was determined by the reassociation kinetics of DNA fragments of varying length. Further information was derived from S1 nuclease resistance and from hyperchromicity measurements on DNA fragments reassociated to defined C₀t values. — The portion of the genome organized in a short period interspersion pattern amounts to 47%, with the unique sequences on an average 1000 nucleotides long, and most of the repetitive sequences about 300 nucleotides in length, whereas the weight average length may be up to 600 nucleotides. — About 5% unique DNA and 11% slow intermediate repetitive DNA consist of sequences from 10³ up to 10⁴ nucleotides long; these are interspersed with repetitive sequences of unknown length. Long repetitive sequences constitute 33% of the genome, 13% are satellite-like organized, and 20% in long stretches of intermediate repetitive DNA in which highly divergent sequences alternate with sequences that show only minimal divergence. — The results presented indicate remarkable similarities with the genomes of most animal species on which information is available. The most intriguing pecularity of the plant genome derives from its high content of repetitive DNA and the presumed organization of the latter.     

The organization of DNA sequences in the mouse genome

Analysis of the organization of nucleotide sequences in mouse genome is carried out on total DNA at different fragment size, reannealed to intermediate value of Cot, by Ag⁺-Cs₂SO₄ density gradient centrifugation. — According to nuclease S-1 resistance and kinetic renaturation curves mouse genome appears to be made up of non-repetitive DNA (76% of total DNA), middle repetitive DNA (average repetition frequency 2×10⁴ copies, 15% of total DNA), highly repetitive DNA (8% of total DNA) and fold-back DNA (renatured density 1.701 g/ml, 1% of total DNA).— Non-repetitive sequences are intercalated with short middle repetitive sequences. One third of non-repetitive sequences is longer than 4500 nucleotides, another third is long between 1800 and 4500 nucleotides, and the remainder is shorter than 1800 nucleotides. —Middle repetitive sequences are transcribed in vivo. The majority of the transcribed repeated sequences appears to be not linked to the bulk of non-repeated sequences at a DNA size of 1800 nucleotides. — The organization of mouse genome analyzed by Ag⁺-Cs₂SO₄ density gradient of reannealed DNA appears to be substantially different than that previously observed in human genome using the same technique.     

Mechanism of Replicative DNA Polymerase Delta Pausing and a Potential Role for DNA Polymerase Kappa in Common Fragile Site Replication

Common fragile sites (CFSs) are hot spots of chromosomal breakage, and CFS breakage models involve perturbations of DNA replication. Here, we analyzed the contribution of specific repetitive DNA sequence elements within CFSs to the inhibition of DNA synthesis by replicative and specialized DNA polymerases (Pols). The efficiency of in vitro DNA synthesis was quantitated using templates corresponding to regions within FRA16D and FRA3B harboring AT-rich microsatellite and quasi-palindrome (QP) sequences. QPs were predicted to form stems of ~ 75–100% self-homology, separated by 3–9 bases of intervening sequences. Analysis of DNA synthesis progression by human Pol δ demonstrated significant synthesis perturbation both at [A]_n and [TA]_n repeats in a length-dependent manner and at short (< 40 base pairs) QP sequences. DNA synthesis by the Y-family polymerase κ was significantly more efficient than Pol δ through both types of repetitive elements. Using DNA trap experiments, we show that Pol δ pauses within CFS sequences are sites of enzyme dissociation, and dissociation was observed in the presence of RFC-loaded PCNA. We propose that enrichment of microsatellite and QP elements at CFS regions contributes to fragility by perturbing replication through multiple mechanisms, including replicative Pol pausing and dissociation. Our finding that Pol δ dissociates at specific CFS sequences is significant, since dissociation of the replication machinery and inability to efficiently recover the replication fork can lead to fork collapse and/or formation of double-strand breaks in vivo. Our biochemical studies also extend the potential involvement of Y-family polymerases in CFS maintenance to include polymerase κ.     

Presence of female-specific bent-repetitive DNA sequences in the genomes of turkey and pheasant and their interactions with W-protein of chicken

Two female-specific repetitive DNA units, the 0.4 kb PstI and 0.5 kb TaqI sequences, were detected in the genomic DNA of turkey and pheasant, respectively, by Southern blot hybridization under non-stringent conditions with the W chromosome-specific 0.7 kb XhoI repetitive unit of chicken as a probe. Cloning and sequencing of these two repetitive units revealed that they shared features with the XhoI family repetitive unit of chicken although the overall similarities of the nucleotide sequences were less than 60%. In common with the chicken XhoI family they consisted of tandem repeats of about 21 bp, the majority of which contained (A)_3–5 and (T)_3–5 clusters separated by six or seven relatively G+C-rich sequences, and they behaved as bent DNA molecules on polyacrylamide gel electrophoresis at room temperature. W-protein, purified from chicken liver nuclei and shown to bind with high affinity to the XhoI family repetitive unit, also bound with the cloned repetitive units from turkey and pheasant. DNase I footprint analysis suggested that the mode of interaction of W-protein with these units was similar to that with the 0.7 kb XhoI sequence. On the other hand, W-protein did not bind to the female-specific 0.4 kb BamHI repetitive unit from the Bobwhite quail. The 0.4 kb BamHI sequence contained some A and T clusters but these clusters did not appear in phase with the pitch of DNA helix and the repetitive unit did not show DNA bending.     

Characterization of Cold-Shock Protein A of Antarctic <Emphasis Type="Italic">Streptomyces</Emphasis> sp. AA8321

Abstact Polar organisms should have mechanisms to survive the extremely cold environment. Four genes encoding cold-shock proteins, which are small, cold-induced bacterial proteins, have been cloned from the Antarctic bacterium Streptomyces sp. AA8321. Since the specific functions of any polar bacterial or Streptomyces cold-shock proteins have not yet been determined, we examined the role of cold-shock protein A from Streptomyces sp. AA8321 (CspA_St). Gel filtration chromatography showed that purified CspA_St exists as a homodimer under physiological conditions, and gel shift assays showed that it binds to single-stranded, but not double-stranded, DNA. Overexpression of CspA_St in Escherichia coli severely impaired the ability of the host cells to form colonies, and the cells developed an elongated morphology. Incorporation of a deoxynucleoside analogue, 5-bromo-2′-deoxyuridine, into newly synthesized DNA was also drastically diminished in CspA_St-overexpressing cells. These results suggest that CspA_St play a role in inhibition of DNA replication during cold-adaptation.     

Screening for novel lipolytic enzymes from uncultured soil microorganisms

The construction and screening of metagenomic libraries constitute a valuable resource for obtaining novel biocatalysts. In this work, we present the construction of a metagenomic library in Escherichia coli using fosmid and microbial DNA directly isolated from forest topsoil and screened for lipolytic enzymes. The library consisted of 33,700 clones with an average DNA insert size of 35 kb. Eight unique lipolytic active clones were obtained from the metagenomic library on the basis of tributyrin hydrolysis. Subsequently, secondary libraries in a high-copy-number plasmid were generated to select lipolytic subclones and to characterize the individual genes responsible for the lipolytic activity. DNA sequence analysis of six genes revealed that the enzymes encoded by the metagenomic genes for lipolytic activity were novel with 34–48% similarity to known enzymes. They had conserved sequences similar to those in the hormone-sensitive lipase family. Based on their deduced amino acid similarity, the six genes encoding lipolytic enzymes were further divided into three subgroups, the identities among which ranged from 33% to 45%. The six predicted gene products were successfully expressed in E. coli and secreted into the culture broth. Most of the secreted enzymes showed a catalytic activity for hydrolysis of p-nitrophenyl butyrate (C₄) but not p-nitrophenyl palmitate (C₁₆).     

Structural requirements essential for elastin coacervation: favorable spatial arrangements of valine ridges on the three‐dimensional structure of elastin‐derived polypeptide (VPGVG)n

The elastin precursor tropoelastin possesses a number of polymeric peptides with repeating 3–9 mer sequences. One of these is the pentapeptide Val‐Pro‐Gly‐Val‐Gly (VPGVG) present in almost all animal species, and its polymer (VPGVG)n coacervates just as does tropoelastin. In the present study, in order to explore the structural requirements essential for coacervation, (VPGVG)n and its shortened repeat analogs (VPGV)n, (VPG)n, and (PGVG)n were synthesized and their structural properties were investigated. In our turbidity measurements, (VPGVG)n demonstrated complete reversible coacervation in agreement with previous findings. The Gly⁵‐deleted polymer (VPGV)n also achieved self‐association, though the onset of self‐association occurred at a lower temperature. However, the dissociation of (VPGV)n upon temperature lowering was found to occur in a three‐step process; the Val_i⁴‐Val_i+1¹ structure arising in the VPGV polypeptide appeared to perturb the dissociation. No self‐association was observed for (VPG)n or (PGVG)n repeats. Spectroscopic measurements by CD, FT‐IR, and ¹H‐NMR showed that the (VPGV)n and (VPG)n both assumed ordered structures similar to that of (VPGVG)n. These results demonstrated that VPGVG is a structural element essential to achieving the β‐spiral structure required for self‐association followed by coacervation, probably due to the ideal spatial arrangement of the hydrophobic Val residues. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

A series of repetitive DNA sequences are associated with human core and H1 histone genes

Summary Repetitive DNA sequences, derived from the human β-globin gene cluster, were mapped within a series of human genomic DNA segments containing core (H2A, H2B, H3 and H4) and H1 histone genes. Cloned recombinant λCH4A phage with human histone gene inserts were analyzed by Southern blot analysis using the following³²P-labeled (nick translated) repetitive sequences as probes:Alu I,Kpn I and LTR-like. A cloned DNA designated RS002-5′C6 containing (i)a (TG)₁₆ simple repeat, (ii) an (ATTTT)n repeat and (iii)a 52 base pair alternating purine and pyrimidine sequence was also used as a radiolabelled hybridization probe. Analysis of 12 recombinant phage, containing 6 arrangements of core histone genes, indicated the presence ofAlu I,Kpn and RS002-5′C6 repetitive sequences. In contrast, analysis of 4 human genomic DNA segments, containing both core and H1 histone genes, indicated the presence of onlyAlu I family sequences. LTR-like sequences were not detected in association with any of the core or H1 histone genes examined. These results suggest that human histone and β-globin genes share certain aspects of sequence organization in flanking regions despite marked differences in their overall structure and pattern of expression.     

The organization of the evolutionarily conserved GATA/GACA repeats in the mouse genome

Simple repeated GATA and GACA sequences which were originally isolated from sex-specific snake satellite DNA have been found subsequently in all eukaryotes studied. The organization of these sequences within the mouse genome was investigated here by using synthetic oligonucleotide probes as a novel tool in comparison with conventional hybridization probes. Southern blot hybridization showed sex-specific patterns with both the (GATA)₄ and (GACA)₄ oligonucleotide probes, as previously described with conventional probes. The quantitative analysis of two mouse DNA phage libraries and of 25 isolated GATA-positive phage clones revealed intensive interspersion of GATA sequences with GACA, and with other repetitive and single-copy sequences. Ubiquitous interspersion and homogeneous genomic distribution of GATA and GACA sequences were confirmed by hybridization in situ of the oligonucleotide probes to metaphase chromosomes. The lengths of the GATA and GACA stretches were found to vary considerably in the individual phage clones. DNA inserts from 20 phages were assigned to autosomes and sex chromosomes and three genomic fragments were found to be confined to the Y chromosome. The organization of GATA and GACA sequences is discussed in the context of their evolutionary potential and possible conservation mechanisms.     

Specific Ribosomal DNA Sequences from Diverse Environmental Settings Correlate with Experimental Contaminants

Phylogenetic analysis of 16S ribosomal DNA (rDNA) clones obtained by PCR from uncultured bacteria inhabiting a wide range of environments has increased our knowledge of bacterial diversity. One possible problem in the assessment of bacterial diversity based on sequence information is that PCR is exquisitely sensitive to contaminating 16S rDNA. This raises the possibility that some putative environmental rRNA sequences in fact correspond to contaminant sequences. To document potential contaminants, we cloned and sequenced PCR-amplified 16S rDNA fragments obtained at low levels in the absence of added template DNA. 16S rDNA sequences closely related to the genera Duganella (formerly Zoogloea), Acinetobacter, Stenotrophomonas, Escherichia, Leptothrix, and Herbaspirillum were identified in contaminant libraries and in clone libraries from diverse, generally low-biomass habitats. The rRNA sequences detected possibly are common contaminants in reagents used to prepare genomic DNA. Consequently, their detection in processed environmental samples may not reflect environmentally relevant organisms.