Homology of single copy and repeated sequences in chicken, duck, Japanese quail, and ostrich DNA.

The extent of reassociation of 3H-labeled repetitive or single copy DNA sequences from the chicken with excess unlabeled DNA from the duck, the Japanese quail, and the ostrich, respectively, was measured by hydroxylapatite chromatography. Chicken repetitive DNA reassociated to an equal or greater extent than chicken single copy DNA with the DNA of each of the other birds. Using an isolated subfraction of chicken repetitive DNA representing those DNA sequences common to the chicken and ostrich genomes, we determined that many repetitive DNA sequences that occur at high repetition frequency in the chicken genome have a much lower repetition frequency in ostrich DNA. The data indicate that there has been a striking change in the number of copies of many repetitive DNA sequences during avian evolution.     

Construction, analysis, and application to 46,XY gonadal dysgenesis of a recombinant phage DNA library from flow-sorted human Y chromosomes

The analysis of a recombinant human Y-enriched Hind III total digest phage library prepared from the DNA of flow sorted human Y chromosomes is described. Out of 43 phage inserts from the library thus far mapped, 25 revealed hybridization with Y chromosomal DNA. These inserts may be divided into five groups according to their degree of Y specific hybridization: inserts that hybridize with one single copy or slightly repeated Y-specific DNA sequence, Y-specific repeated sequences of various restriction fragment lengths, Y-chromosomal DNA sequence(s) shared by a sequence on the X and/or on autosomes, Y-specific DNA sequences in addition to multiple X and/or autosomal sequences, or Y-specific repeated DNA in addition to multiple X and/or autosomal sequences. Application of probes from this library for diagnostic purposes is shown in two 46,XY patients with gonadal dysgenesis and small deletions of the Y short arm.     

Method to eliminate linear DNA from mixture containing nicked circular, supercoiled, and linear plasmid DNA

Preparations of circular plasmid DNA in either supercoiled or nicked circular form often are contaminated with undesired linear DNA fragments arising from shearing/degradation of chromosomal DNA or linearization of plasmid DNA itself. We report a simple enzymatic method, using a combination of λ exonuclease and RecJ_f, for the selective removal of linear DNA from such mixtures. λ exonuclease digests one strand of linear duplex DNA in the 5′ to 3′ direction, whereas RecJ_f, a single-strand-specific exonuclease, digests the remaining complementary single strand into mononucleotides. This combination of exonucleases can remove linear DNA from a mixture of linear and supercoiled DNA, leaving the supercoiled form intact. Furthermore, the inability of λ exonuclease to initiate digestion at nicks or gaps enables the removal of undesired linear DNA when nicked circular DNA has been enzymatically prepared from supercoiled DNA. This method can be useful in the preparation of homogeneous circular plasmid DNA required for therapeutic applications and biophysical studies.     

Functional recA, lexA, umuD, umuC, polA, and polB genes are not required for the Escherichia coli UVM response.

The Escherichia coli UVM response is a recently described phenomenon in which pretreatment of cells with DNA-damaging agents such as UV or alkylating agents significantly enhances mutation fixation at a model mutagenic lesion (3,N4-ethenocytosine; epsilon C) borne on a transfected M13 single-stranded DNA genome. Since UVM is observed in delta recA cells in which SOS induction should not occur, UVM may represent a novel, SOS-independent, inducible response. Here, we have addressed two specific hypothetical mechanisms for UVM: (i) UVM results from a recA-independent pathway for the induction of SOS genes thought to play a role in induced mutagenesis, and (ii) UVM results from a polymerase switch in which M13 replication in treated cells is carried out by DNA polymerase I (or DNA polymerase II) instead of DNA polymerase III. To address these hypotheses, E. coli cells with known defects in recA, lexA, umuDC, polA, or polB were treated with UV or 1-methyl-3-nitro-1-nitrosoguanidine before transfection of M13 single-stranded DNA bearing a site-specific ethenocytosine lesion. Survival of the transfected DNA was measured as transfection efficiency, and mutagenesis at the epsilon C residue was analyzed by a quantitative multiplex DNA sequencing technology. Our results show that UVM is observable in delta recA cells, in lexA3 (noninducible SOS repressor) cells, in LexA-overproducing cells, and in delta umuDC cells. Furthermore, our data show that UVM induction occurs in the absence of detectable induction of dinD, an SOS gene. These results make it unlikely that UVM results from a recA-independent alternative induction pathway for SOS gene.     

Endonuclease from Escherichia coli that acts specifically upon duplex DNA damaged by ultraviolet light, osmium tetroxide, acid, or x-rays.

An endonuclease which is active upon DNA exposed to ultraviolet light at a photoproduct other than thymine dimers has been extensively purified from Escherichia coli. The small (2.7 S) enzyme is active in the presence of EDTA, has a neutral pH optimum, and is inhibited by tRNA and 1 M NaCl. It has no detectable exonuclease, DNA-N-glycosidase, or ribonuclease activities. The enzyme also nicks duplex DNA exposed to OsO4, x-rays, or acid, but it does not act upon undamaged DNA or irradiated single-stranded DNA. The majority of sites of action in DNA exposed to ultraviolet light or OsO4 appear to be alkali-stable, but those in DNA exposed to x-rays or acid are not. The incisions created by the endonuclease contain 5'-phosphate termini. The enzyme is possibly the same as E. coli endonuclease III described by Radman (Radman, M. (1976) J. Biol. Chem. 251, 1438-1445), but it is distinguishable from the other endodeoxyribonucleases described from that organism.     

A human-derived probe,p82H,hybridizes to the centromeres of gorilla,chimpanzee, and orangutan

A human-derived centromeric sequence, p82H, hybridizes to DNA from gorilla, chimpanzee, pygmy chimpanzee, and orangutan. On DNA blots, multimeric ladders based on 170 or 340 bp repeat units are seen. In metaphase chromosome preparations from these species, p82H hybridizes to the centromeric region of every chromosome. p82H forms less stable hybrids with DNA from the lion-tailed macaque and does not hybridize to DNA or chromosomes of the owl monkey or the mouse.     

DNA repair,recombination, and damage signaling

DNA must be accurately copied and propagated from one cell division to the next, and from one generation to the next. To ensure the faithful transmission of the genome, a plethora of distinct as well as overlapping DNA repair and recombination pathways have evolved. These pathways repair a large variety of lesions, including alterations to single nucleotides and DNA single and double-strand breaks, that are generated as a consequence of normal cellular function or by external DNA damaging agents. In addition to the proteins that mediate DNA repair, checkpoint pathways have also evolved to monitor the genome and coordinate the action of various repair pathways. Checkpoints facilitate repair by mediating a transient cell cycle arrest, or through initiation of cell suicide if DNA damage has overwhelmed repair capacity. In this chapter, we describe the attributes of Caenorhabditis elegans that facilitate analyses of DNA repair, recombination, and checkpoint signaling in the context of a whole animal. We review the current knowledge of C. elegans DNA repair, recombination, and DNA damage response pathways, and their role during development, growth, and in the germ line. We also discuss how the analysis of mutational signatures in C. elegans is helping to inform cancer mutational signatures in humans.     

Isolation of high-molecular-weight DNA from small samples of blood having nucleated erythrocytes,collected, transported,and stored at room temperature

Blood samples collected in the field for isolating DNA suitable for molecular analysis need special care in their storage and handling. In this article, we describe a simple method for the isolation of good-quality high-molecular-weight DNA that does not require low temperature conditions during collection, storage, and/or transportation of blood samples. This method involves smearing small aliquots of blood onto clean slides and air drying them at room temperature. The slides with blood smears can then be transported or stored at room temperature and still serve as a very good source of high-molecular-weight DNA. Genomic DNA from these samples can be extracted by organic phase separation (phenol-chloroform extraction) after lysis. The DNA thus obtained is of high quality and yields DNA fingerprints qualitatively similar to those prepared from corresponding control DNA isolated from frozen blood samples. Needing minimal facilities at field sites, the method is very convenient for conducting RFLP analysis of wild/field populations for demographic, behavioral, and ecologic studies.     

Comparative mitochondrial and nuclear quantitative PCR of historical marine mammal tissue,bone, baleen,and tooth samples

The use of historical and ancient tissue samples for genetic analysis is increasing, with ever greater numbers of samples proving to contain sufficient mitochondrial and even nuclear DNA for multilocus analysis. DNA yield, however, remains highly variable and largely unpredictable based solely on sample morphology or age. Quantification of DNA from historical and degraded samples can greatly improve efficiency of screening DNA extracts prior to attempting sequencing or genotyping, but requires sequence‐specific quantitative polymerase chain reaction (qPCR) based assays to detect such minute quantities of degraded DNA. We present two qPCR assays for marine mammal DNA quantification, and results from analysis of DNA extracted from preserved soft tissues, bone, baleen, and tooth from several cetacean species. These two assays have been shown to amplify DNA from 26 marine mammal species representing 12 families of pinnipeds and cetaceans. Our results indicate that different tissues retain different ratios of mitochondrial to nuclear DNA, and may be more or less suitable for analysis of nuclear loci. Specifically, historical bone and tooth samples average 60‐fold higher ratio of mitochondrial DNA to nuclear DNA than preserved fresh soft tissue, and the ratio is almost 8000‐fold higher in baleen.     

Synthesis of herpes simplex virus, vaccinia virus, and adenovirus DNA in isolated HeLa cell nuclei. I. Effect of viral-specific antisera and phosphonoacetic acid.

Purified nuclei, isolated from appropriately infected HeLa cells, are shown to synthesize large amounts of either herpes simplex virus (HSV) or vaccinia virus DNA in vitro. The rate of synthesis of DNA by nuclei from infected cells is up to 30 times higher than the synthesis of host DNA in vitro by nuclei isolated from uninfected HeLa cells. Thus HSV nuclei obtained from HSV-infected cells make DNA in vitro at a rate comparable to that seen in the intact, infected cell. Molecular hybridization studies showed that 80% of the DNA sequences synthesized in vitro by nuclei from herpesvirus-infected cells are herpesvirus specific. Vaccinia virus nuclei from vaccinia virus-infected cells, also produce comparable percentages of vaccinia virus-specific DNA sequences. Adenovirus nuclei from adenovirus 2-infected HeLa cells, which also synthesize viral DNA in vitro, have been included in this study. Synthesis of DNA by HSV or vaccinia virus nuclei is markedly inhibited by the corresponding viral-specific antisera. These antisera inhibit in a similar fashion the purified herpesvirus-induced or vaccinia virus-induced DNA polymerase isolated from infected cells. Phosphonoacetic acid, reported to be a specific inhibitor of herpesvirus formation and the herpesvirus-induced DNA polymerase, is equally effective as an inhibitor of HSV DNA synthesis in isolated nuclei in vitro. However, we also find phosphonoacetic acid to be an effective inhibitor of vaccinia virus nuclear DNA synthesis and the purified vaccinia virus-induced DNA polymerase. In addition, this compound shows significant inhibition of DNA synthesis in isolated nuclei obtained from adenovirus-infected or uninfected cells and is a potent inhibitor of HeLa cell DNA polymerase alpha.     

Mechanism of in vitro expansion of long DNA repeats: effect of temperature, repeat length, repeat sequence, and DNA polymerases.

Studies of sequence repeat expansions from duplexes consisting of DNA repeat sequences greater than three bases are currently lacking. These studies are needed in order to gain a better understanding of DNA expansions in general and as a first step in understanding expansions of longer sequence repeats that have been implicated in human diseases. We have undertaken an in vitro study of tetranucleotide, hexanucleotide, and octanucleotide repeat expansions from short DNA duplexes using Taq DNA polymerase. Expansions of hexanucleotide repeats were also studied with the Klenow fragment of DNA polymerase I and with T4 DNA polymerase. Studies with Taq DNA polymerase show that expansions occur more readily as the length of the repeat sequence decreases but are generally more efficient at reaction temperatures closer to the melting point of the starting duplex. A mechanism for the observed expansions with Taq DNA polymerase is proposed that does not invoke strand slippage or DNA structure. Studies at 37 degrees C with Klenow pol I and T4 DNA polymerase indicate that the template-switching and/or strand-displacement activities of the polymerases used can play a major role in the apparent in vitro expansions of short repetitive DNA duplexes.     

Methylation sequencing from limiting DNA: embryonic,fixed, and microdissected cells

It is frequently useful to determine the methylation state of samples containing limited amounts of DNA such as from embryos, or from fixed tissue samples in which DNA is degraded or difficult to isolate. By modification of the standard protocols for DNA preparation and bisulfite treatment, it is possible to obtain DNA methylation sequence data for such samples. We present methods for bisulfite treatment of embryos, fixed sections, and samples obtained by laser capture microdissection, and discuss the additional experimental considerations required when working with small numbers of cells or degraded DNA samples.     

DNA isolation by a rapid method from human blood samples: Effects of MgCl2, EDTA,storage time,and temperature on DNA yield and quality

The isolation of DNA from whole blood by a modified rapid method (RM) was tested using various detergents and buffer conditions. Extraction of DNA with either NP-40 or Triton X-100 gave a high yield of undegraded DNA in less than an hour. The concentration of magnesium ion in the buffers was critical to obtaining intact, high molecular weight (HMW) DNA. Greater than 10 mM MgCl₂ led to degradation. Addition of EDTA to the buffer inhibits this degradation. Preparation of DNA from blood stored at room temperature or incubated at 37°C for 24 hr resulted in the same amount and quality of DNA as from samples frozen at −70°C. DNA from blood samples that had undergone more than four freeze-thaw cycles was found to be partially degraded. The modified RM can be applied to extract DNA from as little as 10 μl of blood (340 ng of DNA) and from dried blood samples. DNA samples remained intact and undegraded for longer times when DNA was dissolved in higher concentrations of EDTA. This work was supported by grants from the Indiana Department of Mental Health and PHS RO1 AG10297.     

Relationships among cytotoxicity, lysosomal breakdown, chromosome aberrations, and DNA double-strand breaks

Certain chemicals that are either weak or non-carcinogens had been previously shown to induce DNA single-strand breaks in rat hepatocytes, but only at cytotoxic doses. In contrast, stronger carcinogens induced DNA single-strand breaks at non-toxic doses. This report shows that the strong carcinogens and mutagens cadmium sulfate, sodium dichromate, dimethyl sulfate, and N-methyl-N'-nitro-N-nitrosoguanidine all induce DNA single-strand breaks at non-toxic concentrations, but that they also induce DNA double-strand breaks at concentrations that are closely correlated with cytotoxicity. Some weak carcinogens produced DNA single- and double-strand breaks, but only at acutely cytotoxic concentrations. We suggest that the DNA double-strand breaks result from a cell-mediated process such as release of DNAase from lysosomes or other cellular compartments, that might occur during cellular response to acutely toxic damage. Experiments with N-dodecyl imidazole (NDI), a lysosomal detergent, show that lysosomal breakdown alone is only a weak inducer of DSBs, but that lysosomal breakdown in combination with prior chemical damage produced by MNNG synergistically induces DNA DSBs in BHK cells. N-Dodecyl imidazole also induces chromosomal aberrations in CHO cells at concentrations which cause cytotoxicity, cell cycle delay, and lysosomal breakdown. These results all suggest that chemical toxicity leads to limited lysosomal breakdown that induces DNA DSBs and chromosomal aberrations. Cells that have been sublethally damaged and that can repair these damages and survive could become transformed by the DNA-damaging mechanisms associated with carcinogenesis.     

A small-scale five-hour procedure for isolating multiple samples of CsCl-purified DNA: application to isolations from mammalian, insect, higher plant, algal, yeast, and bacterial sources

A rapid and simple procedure is described for obtaining CsCl-purified DNA from multiple small samples of cells or tissue. The DNA is recovered in a high-molecular-weight form (greater than or equal to 50 kb) that is readily cleaved with restriction enzymes. Sufficient quantities of DNA (10-50 micrograms) are recovered to allow multiple analyses by Southern blotting and most cloning procedures. The isolation procedure involves addition of intact cells or powders of frozen tissues directly to a simple lysis buffer containing detergent (sodium dodecyl sulfate or sodium sarcosinate) and high concentrations of EDTA. Ultra-high-speed centrifugation of CsCl gradients allows the isolation of DNA from 10 different samples in as little as 5 h. Applications are described for mammalian cells (HeLa cells), insect tissues (Drosophila melanogaster adults and pupa, Manduca sexta pupa, and Musca domestica pupa), higher plant tissues (Vicia faba leaves and meristems), algal cells (walled and wall-less Chlamydomonas reinhardi), yeast cells (Saccharomyces cerevisiae), and bacterial cells (Escherichia coli spheroplasts for preparation of both chromosomal and plasmid DNA). The procedure can be scaled up with larger sample sizes and longer centrifugation times to provide bulk quantities of DNA.     

Base J, found in nuclear DNA of Trypanosoma brucei, is not a target for DNA glycosylases

Base excision repair (BER) is an evolutionarily conserved system which removes altered bases from DNA. The initial step in BER is carried out by DNA glycosylases which recognize altered bases and cut the N-glycosylic bond between the base and the DNA backbone. In kinetoplastid flagellates, such as Trypanosoma brucei, the modified base beta-D-glucosyl-hydroxymethyluracil (J) replaces a small percentage of thymine residues, predominantly in repetitive telomeric sequences. Base J is synthesized at the DNA level via the precursor 5-hydroxymethyluracil (5-HmU). We have investigated whether J in DNA can be recognized by DNA glycosylases from non-kinetoplastid origin, and whether the presence of J and 5-HmU in DNA has required modifications of the trypanosome BER system. We tested the ability of 15 different DNA glycosylases from various origins to excise J or 5-HmU paired to A from duplex oligonucleotides. No excision of J was found, but 5-HmU was excised by AlkA and Mug from Escherichia coli and by human SMUG1 and TDG, confirming previous reports. In a combination of database searches and biochemical assays we identified several DNA glycosylases in T. brucei, but in trypanosome extracts we detected no excision activity towards 5-HmU or ethenocytosine, a product of oxidative DNA damage and a substrate for Mug, TDG and SMUG1. Our results indicate that trypanosomes have a BER system similar to that of other organisms, but might be unable to excise certain forms of oxidatively damaged bases. The presence of J in DNA does not require a specific modification of the BER system, as this base is not recognized by any known DNA glycosylase.     

Sensing, signaling, and responding to DNA damage: organization of the checkpoint pathways in mammalian cells

The DNA damage and replication checkpoints are signaling mechanisms that regulate and coordinate cellular responses to genotoxic conditions. Unlike typical signal transduction mechanisms that respond to one or a few stimuli, checkpoints can be activated by a broad spectrum of extrinsically or intrinsically derived DNA damage or replication interference. Recent investigations have shed light on how the damage and replication checkpoints are able to respond to such diverse stimuli. The activation of checkpoints not only attenuates cell cycle progression but also facilitates DNA repair and recovery of faltered replication forks, thereby preventing DNA lesions from being converted to inheritable mutations. Recently, more checkpoint targets from the cell cycle and DNA replication apparatus have been identified, revealing the increasing complexity of the checkpoint control of the cell cycle. In this article, we discuss current models of the DNA damage and replication checkpoints and highlight recent advances in the field.     

DNA Damage Checkpoint, Damage Repair, and Genome Stability

Genomic DNA is under constant attack from both endogenous and exogenous sources of DNA damaging agents. Without proper care, the ensuing DNA damages would lead to alteration of genomic structure thus affecting the faithful transmission of genetic information. During the process of evolution, organisms have acquired a series of mechanisms responding to and repairing DNA damage, thus assuring the maintenance of genome stability and faithful transmission of genetic information. DNA damage checkpoint is one such important mechanism by which, in the face of DNA damage, a cell can respond to amplified damage signals, either by actively halting the cell cycle until it ensures that critical processes such as DNA replication or mitosis are complete or by initiating apoptosis as a last resort. Over the last decade, complex hierarchical interactions between the key components like ATM/ATR in the checkpoint pathway and various other mediators, effectors including DNA damage repair proteins have begun to emerge. In the meantime, an intimate relationship between mechanisms of damage checkpoint pathway, DNA damage repair, and genome stability was also uncovered. Reviewed hereinare the recent findings on both the mechanisms of activation of checkpoint pathways and their coordination with DNA damage repair machinery as well as their effect on genomic integrity.     

Deletion mapping of the testis determining locus with DNA probes in 46,XX males and in 46,XY and 46,X,dic(Y) females.

Eleven Y-specific DNA probes hybridizing with DNA from one or more 46,XX males were isolated from a recombinant phage DNA library constructed from flow sorted human Y chromosomes. Two probes hybridized with DNA from nine out of eleven, i.e. greater than 80% of these 46,XX males. The relative frequency of hybridization of the probes in the 46,XX males and in a 46,X,dic(Y) female, together with in situ hybridization data, allowed mapping of the probes on Yp in relation to a putative testis determining locus. Several of those probes were also absent in a 46,XY female, further refining a model for ordering the probes on Yp. The DNA of one XX male hybridized both with probes from Yp and probes from proximal Yq (excluding the pericentral region). This suggests that complex translocations may occur into the DNA of 46,XX males that involve not only parts of Yp but also parts of Yq.