Defective repair of oxidative damage in mitochondrial DNA in Down''s syndrome

BACKGROUND: Synthetic homopyrimidine peptide nucleic acids (PNAs) can bind complementary targets in double-stranded DNA, generating strand-displacement complexes, and so offering an opportunity to modulate specific gene expression. Several issues remain to be addressed before these attributes can be exploited in vivo, however. RESULTS: The kinetics of the interaction between a homopyrimidine PNA and a complementary homopurine target on double-stranded DNA were analyzed in the presence or absence of a preformed strand-displacement complex proximal to the target. The complex was established under low salt conditions by the binding of a different homopyrimidine PNA to a target situated adjacent to the first PNA target. These two targets were placed next to each other on opposite strands at distances of 0, 2, 4 and 8 base pairs apart. The presence of a preformed strand-displacement complex near the target accelerates the binding of PNA to double-stranded DNA in a salt-dependent manner. The influence of salt on the binding rates was also examined. The binding rate is increased by a factor of 1 x exp(70[NaCl]), that is, 16-fold at 40 mM NaCl and more than 10(4)-fold if extrapolated to 140 mM NaCl. This effect is significantly reduced if the two targets are 2 base pairs apart and completely absent if the distance is 4 base pairs or more. CONCLUSIONS: The perturbation of the DNA helix imposed by a PNA strand-displacement complex only propagates a few base pairs. It is therefore possible to target sites in the immediate vicinity of strand invasion complexes specifically. The results presented have implications for the mechanism of strand displacement and for the application of PNA in a genomic context.     

DNA typing of human leukocyte antigen sequence polymorphisms by peptide nucleic acid probes and MALDI-TOF mass spectrometry

A novel analytical method using PNA probes detected by matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOFMS) was applied to type sequence polymorphisms within the human leukocyte antigen (HLA), DQA locus. Streptavidin-coated magnetic beads were used to immobilize biotinylated DNA. PNA probes representing possible alleles were then prepared for the immobilized DNA hybridization. The nonspecific PNA probes were removed with stringent washes. The PNA/DNA/beads conjugate was analyzed by MALDI-TOFMS. The genotype of the DNA was determined by the detected molecular masses of the released PNA probes. Reproducible and accurate genotyping was achieved by this analytical method.     

Detection of nucleic acids in the attomole range using polybiotinylated oligonucleotide probes

This article describes the optimization of the hybridization signal obtained with biotinylated oligonucleotides. Optimal number and positions of biotin moieties on a 33-base oligonucleotide probe were determined. The quality of avidin-peroxidase conjugate and the choice of chromogenic substrate influenced detection sensitivity. A signal amplification method was also developed for avidin enzymatic conjugates. These improvements allowed the detection of less than 0.02 fmol of target DNA.     

Naloxone-induced pituitary-adrenal activation does not differ in patients with depression, obsessive compulsive disorder, and healthy controls

Light-activated psoralens can covalently modify DNA and are widely used to study nucleic acid secondary structure and mutagenesis. Sequence specificity can be added to the photoaddition reaction by attaching the psoralen to an oligonucleotide designed to recognize a double-stranded DNA binding site through formation of a triple helix. We have previously used this strategy to study targeted psoralen modification of a triplex binding site within the bacterial supF gene carried in viral genomes. In the present work we report the targeting of psoralen photoadducts in vitro to a specific site in the genome of a transgenic mouse. Both 10 base and 16 base oligonucleotide-psoralen conjugates were capable of sequence-specific modification of genomic mouse DNA, while a truncated 8 base conjugate was not. Light activation was necessary, and a dose dependence was demonstrated for target site modification and mutagenesis. The 10 base conjugate rapidly found its target, with sequence-specific binding occurring after just 10 min incubation in the presence of mouse DNA. The ability to target psoralen photoadducts within mammalian genomes may prove useful in the study of chromatin structure and DNA repair. Moreover, this work may lead to potential in vivo applications of targeted psoralen modification.     

Peptide nucleic acids (PNA) and PNA-DNA chimeras: from high binding affinity towards biological function

Oligonucleotide analogs are of major interest as tools in molecular biology, as diagnostics, and as potential pharmaceuticals which bind in a predictable way to certain nucleic acid target sequences, aiming at the inhibition of expression of disease-causing genes. One of the most promising nucleic acid mimetics are the peptide - or polyamide- nucleic acids (PNA) which bind with higher affinity to DNA and RNA than natural oligonucleotides. In these non-ionic PNAs, the entire sugar-phosphate backbone is replaced by an N-aminoethylglycine-based polyamide structure. A unique property of PNA is its ability to displace one strand of a DNA double-helix. This strand displacement process, which is inefficient with DNA, is supported by the formation of an unusually stable internal (PNA)2 x DNA triple helix. The combination of PNA and DNA in one molecule results in PNA/DNA chimeras with new properties. They show improved aqueous solubility compared to pure PNAs due to their partially negatively charged structure. Furthermore, the cellular uptake of the chimeras is better than of pure PNAs. In contrast to PNA, the chimeras bind exclusively in the antiparallel orientation under physiological conditions. The binding affinity is generally stronger when the PNA/DNA chimeras are hybridized to RNAthan to DNA, whereby the strength of binding strongly depends on the PNA: DNA ratio. Most interestingly, PNA/DNA chimeras are recognized as substrates by various nucleic acid processing enzymes, and consequently can also assume biological functions, such as a primer function for DNA polymerases. Pure PNA cannot induce RNase H cleavage of target RNA, which is believed to support the biological efficacy of antisense agents. However, DNA-PNA chimeras are able to stimulate cleavage of the target RNA by RNase H upon formation of an RNA x chimera duplex.     

Human mesotheliomas contain the simian virus-40 regulatory region and large tumor antigen DNA sequences

BACKGROUND: A cohort (20%) of patients with mesothelioma will not have an exposure to asbestos. Recently, a DNA tumor virus (simian virus 40) has been shown to cause hamster mesotheliomas; we previously described simian virus 40-like DNA amino terminus sequences in 29 of 48 mesotheliomas. We analyzed an additional 42 mesotheliomas to determine (1) whether our initial observations were durable and (2) the extent to which the simian virus 40 genome is present in mesotheliomas. METHODS: Genomic DNA was extracted from snap frozen mesothelioma tumor samples and from the simian virus 40-induced hamster mesothelioma tumor H9A. Polymerase chain reaction primers were used to amplify various simian virus 40 large T-antigen regions including a 105-base pair amino terminus fragment, a 281-base pair carboxyl terminus fragment, and a 310-base pair fragment of the enhancer promoter region. Endonuclease digestions and Southern blotting were used to verify the expected product. RESULTS: Thirty of the 42 (71%) samples amplified T-antigen amino sequences, and specificity was verified by Southern hybridization. Sixteen of 42 samples (38%) amplified the appropriate size fragment for the carboxyl terminus, and digestion with BsaB1 matched that of H9A. Twenty-two of 42 samples (52%) amplified simian virus 40 regulatory sequences and Fok1 digestion matched that of the hamster control tumor. Sequence analysis (4 patients) revealed 100% homology with the regulatory region of simian virus 40 strain 776. CONCLUSIONS: These data suggest an association between the simian virus 40 virus and human mesothelioma that could be exploited for diagnostic/therapeutic options including early detection and potential vaccination strategies.     

The recombination hotspot Chi is recognized by the translocating RecBCD enzyme as the single strand of DNA containing the sequence 5'-GCTGGTGG-3'

The RecBCD enzyme of Escherichia coli functions in the seemingly disparate roles of homologous recombination and the degradation of DNA. Which of these two roles it assumes is regulated by the 8-base recombination hotspot, Chi. Using double-stranded DNA substrates that are heteroduplex at the Chi locus we have established the determinants for Chi recognition. Our results show that an actively translocating RecBCD enzyme requires only the sequence information in the 5'-GCTGGTGG-3'-containing strand to recognize and to be regulated by Chi. Furthermore, the RecBCD enzyme can translocate through DNA heteroduplex bubbles as large as 22 bases, and still recognize a Chi sequence embedded in this region. This implies that recognition of Chi occurs following the unwinding of the DNA.     

Functional analysis of coordinated cleavage in V(D)J recombination

V(D)J recombination in vivo requires a pair of signals with distinct spacer elements of 12 and 23 bp that separate conserved heptamer and nonamer motifs. Cleavage in vitro by the RAG1 and RAG2 proteins can occur at individual signals when the reaction buffer contains Mn2+, but cleavage is restricted to substrates containing two signals when Mg2+ is the divalent cation. By using a novel V(D)J cleavage substrate, we show that while the RAG proteins alone establish a moderate preference for a 12/23 pair versus a 12/12 pair, a much stricter dependence of cleavage on the 12/23 signal pair is produced by the inclusion of HMG1 and competitor double-stranded DNA. The competitor DNA serves to inhibit the cleavage of substrates carrying a 12/12 or 23/23 pair, as well as the cutting at individual signals in 12/23 substrates. We show that a 23/33 pair is more efficiently recombined than a 12/33 pair, suggesting that the 12/23 rule can be generalized to a requirement for spacers that differ from each other by a single helical turn. Furthermore, we suggest that a fixed spatial orientation of signals is required for cleavage. In general, the same signal variants that can be cleaved singly can function under conditions in which a signal pair is required. However, a chemically modified substrate with one noncleavable signal enables us to show that formation of a functional cleavage complex is mechanistically separable from the cleavage reaction itself and that although cleavage requires a pair of signals, cutting does not have to occur simultaneously at both. The implications of these results are discussed with respect to the mechanism of V(D)J recombination and the generation of chromosomal translocations.     

Secondary structure mapping of an RNA ligand that has high affinity for the MetJ repressor protein and interference modification analysis of the protein-RNA complex

The secondary structure of an RNA aptamer, which has a high affinity for the Escherichia coli MetJ repressor protein, has been mapped using ribonucleases and with diethyl pyrocarbonate. The RNA ligand is composed of a stem-loop with a highly structured internal loop. Interference modification showed that the bases within the internal loop, and those directly adjacent to it, are important in the binding of the RNA ligand to MetJ. Most of the terminal stem-loop could be removed with little effect on the binding. Ethylation interference suggests that none of the phosphate groups are absolutely essential for tight binding. The data suggest that the MetJ binding site on the aptamer is distinct from that of the natural DNA target, the 8-base pair Met box.     

Discrete start sites for DNA synthesis in the yeast ARS1 origin

Sites of DNA synthesis initiation have been detected at the nucleotide level in a yeast origin of bidirectional replication with the use of replication initiation point mapping. The ARS1 origin of Saccharomyces cerevisiae showed a transition from discontinuous to continuous DNA synthesis in an 18-base pair region (nucleotides 828 to 845) from within element B1 toward B2, adjacent to the binding site for the origin recognition complex, the putative initiator protein.     

Purification, cloning, and preliminary characterization of a Spiroplasma citri ribosomal protein with DNA binding capacity

The rpsB-tsf-x operon of Spiroplasma citri encodes ribosomal protein S2 and elongation factor Ts, two components of the translational apparatus, and an unidentified X protein. A potential DNA-binding site (a 20-base pair (bp) inverted repeat sequence) is located at the 3' end of rpsB. Southwestern analysis of S. citri proteins, with a 30-bp double-stranded oligonucleotide probe (IRS), containing the 20-bp inverted repeat sequence and the genomic flanking sequences, detected an IRS-binding protein of 46 kDa (P46). P46 protein, which displays preferential affinity for the IRS, was purified from S. citri by a combination of affinity and gel filtration chromatographies. The native form of P46 seems to be homomultimeric as estimated by SDS-polyacrylamide gel electrophoresis analysis and gel filtration. A 3.5-kilobase pair S. citri DNA fragment comprising the P46 gene and flanking sequences was cloned and sequenced. Sequence analysis of this DNA fragment indicated that the P46 gene is located within the S10-spc operon of S. citri at the position of the gene coding for ribosomal protein L29 in the known S10-spc operons. The similarity between the N-terminal domain of P46 and the L29 ribosomal protein family and the presence of a 46-kDa IRS-binding protein in S. citri ribosomes indicated that P46 is the L29 ribosomal protein of S. citri. We suggest that P46 is a bifunctional protein with an L29 N-terminal domain and a C-terminal domain involved in IRS binding.     

Heterogeneous mutations in the gene encoding the alpha-subunit of the stimulatory G protein of adenylyl cyclase in Albright hereditary osteodystrophy

Albright hereditary osteodystrophy (AHO) is an inherited disorder associated with deficient activity of the alpha-subunit of the guanine nucleotide-binding regulatory protein (Gs alpha) that couples receptors to adenylyl cyclase. To identify mutations that lead to Gs alpha deficiency, we isolated genomic DNA from patients with AHO and used the polymerase chain reaction to amplify exons of the Gs alpha genes. DNA was amplified using intron-specific oligonucleotide primers flanking exons of the Gs alpha gene. To optimize our ability to detect mutations, one oligonucleotide from each primer pair was synthesized with a 5' GC-clamp. Amplified Gs alpha gene fragments were analyzed by denaturing gradient gel electrophoresis in order to detect mutations that alter the melting point of the double-stranded DNA fragment. Using this technique, we have identified and characterized three mutations and one neutral polymorphism. The polymorphism, located in exon 5, consisted of a T-->C substitution that conserves the isoleucine residue at codon 131 (ATT-->ATC). Two mutations were missense mutations, which in one family consisted of a nucleotide substitution (T-->C) in exon 4 that results in replacement of Leu by Pro at codon 99 of the Gs alpha molecule. Affected subjects in a second family had a single base (C-->T) mutation in exon 6 that resulted in replacement of Arg by Cys at codon 165. A 4-base pair deletion (GTGG) in exon 8 at position +214 was identified in one Gs alpha allele from each affected subject in the third family. This mutation causes a frameshift after the codon for Gln213 that results in a premature stop codon 81 base pair after the deletion. Immunoblot analysis of plasma membranes prepared from cultured fibroblasts or erythrocytes indicated that levels of immunoactive Gs alpha protein were decreased in all affected subjects. We conclude that heterogeneous mutations in the gene encoding Gs alpha, including deletions and single amino acid substitutions, are responsible for Gs alpha deficiency in AHO.     

Identification of cell type-dependent enhancer core element located in the 3'-downstream region of the human angiotensinogen gene

We previously demonstrated that the 3.8-kilobase DNA fragment containing exons 4 and 5 of the human angiotensinogen (hAG) gene enhances the expression of chloramphenicol acetyltransferase gene, under control of the hAG promoter, in human hepatoma HepG2 cells. In the present study, to define regulatory elements of the hAG gene, we have functionally dissected this downstream region and localized a cell type-dependent enhancer to the 832-base pair sequence containing the exon 5 and 3'-flanking region. Further deletion analyses revealed that the 24-base pair core DNA fragment present in the 3'-flanking region was responsible for this enhancement. Electrophoretic mobility shift assay demonstrated that the 3'-enhancer core element interacts specifically with two nuclear factors from the HepG2 cells, one of which is an uncharacterized factor (human angiotensinogen enhancer factor-1: hAEF-1), the other is an AP-3-related factor. Mutation analyses indicated that the disruption of hAEF-1 binding alone completely impaired the enhancer activity of the core element. These results suggested that the downstream enhancer core element interacting with hAEF-1 plays an important role in activating the angiotensinogen promoter in a cell type-dependent manner.     

Unique mode of GCC box recognition by the DNA-binding domain of ethylene-responsive element-binding factor (ERF domain) in plant

Ethylene-responsive element-binding proteins (EREBPs)have novel DNA-binding domains (ERF domains), which are widely conserved in plants, and interact specifically with sequences containing AGCCGCC motifs (GCC box). Deletion experiments show that some flanking region at the N terminus of the conserved 59-amino acid ERF domain is required for stable binding to the GCC box. Three ERF domain-containing fragments of EREBP2, EREBP4, and AtERF1 from tobacco and Arabidopsis, bind to the sequence containing the GCC box with a high binding affinity in the pM range. The high affinity binding is conferred by a monomeric ERF domain fragment, and DNA truncation experiments show that only 11-base pair DNA containing the GCC box is sufficient for stable ERF domain interaction. Systematic DNA mutation analyses demonstrate that the specific amino acid contacts are confined within the 6-base pair GCCGCC region of the GCC box, and the first G, the fourth G, and the sixth C exhibit highest binding specificity common in all three ERF domain-containing fragments studied. Other bases within the GCC box exhibit modulated binding specificity varying from protein to protein, implying that these positions are important for differential binding by different EREBPs. The conserved N-terminal half is likely responsible for formation of a stable complex with the GCC box and the divergent C-terminal half for modulating the specificity.     

The aging population: implications for the burden of neurologic disease

Two cDNA clones encoding ribonuclease F1 (EC 3.1.27.3) have been isolated using a probe prepared by polymerase chain reaction with primers designed on the basis of amino acid sequence of the enzyme. They derived probably from the same gene and contained 393-base pair open reading frame encoding 131 amino acid residues (Mr 13,606) including a putative 25-residue signal peptide. The sequences of 43-base pair 5'-untranslated region and 125-base pair 3'-untranslated region including a poly(A) tail of 25 nucleotides were also elucidated. Homology analyses showed that cDNA for ribonuclease F1 has 65% homology to that for ribonuclease T1 in the coding region. At the preprotein level, they share 53% homology.     

Role of DNA in the activation of the Cry1A insecticidal crystal protein from Bacillus thuringiensis

The Cry1A insecticidal crystal protein (protoxin) from six subspecies of Bacillus thuringiensis as well as the Cry1Aa, Cry1Ab, and Cry1Ac proteins cloned in Escherichia coli was found to contain 20-kilobase pair DNA. Only the N-terminal toxic moiety of the protoxin was found to interact with the DNA. Analysis of the crystal gave approximately 3 base pairs of DNA per molecule of protoxin, indicating that only a small region of the N-terminal toxic moiety interacts with the DNA. It is proposed that the DNA-protoxin complex is virus-like in structure with a central DNA core surrounded by protein interacting with the DNA with the peripheral ends of the C-terminal region extending outward. It is shown that this structure accounts for the unusual proteolysis observed in the generation of toxin in which it appears that peptides are removed by obligatory sequential cleavages starting from the C terminus of the protoxin. Activation of the protoxin by spruce budworm (Choristoneura fumiferana) gut juice is shown to proceed through intermediates consisting of protein-DNA complexes. Larval trypsin initially converts the 20-kilobase pair DNA-protoxin complex to a 20-kilobase pair DNA-toxin complex, which is subsequently converted to a 100-base pair DNA-toxin complex by a gut nuclease and ultimately to the DNA-free toxin.