Chemical sequencing of restriction fragments 3′-end-labeled with [S]dATPαS

Although the phosphorous radioisotope 32P is routinely used in Maxam-Gilbert sequencing, it presents disadvantages that adversely affect safety and ease of use, resolution, and DNA degradation rates. Here, we introduce a new protocol utilizing the alternative isotope 35S for 3'-end-labeling DNA restriction fragments. In our method, plasmid DNA is labeled with [35S]dATPalphaS and 7 Sequenase Version 2.0. We have shown that bands on Maxam-Gilbert sequencing gels are sharp with extremely low background. In addition, a single labeling reaction produces DNA sufficient for 80 sequencing lanes, and the labeled DNA can be utilized for prolonged periods of time without significant degradation. We have further demonstrated the utility of our 35S-end-labeling procedure by successfully mapping the sequence-specificity of DNA damage induced by photoexcited riboflavin. Overall, we have shown that 35S can be used as a safe and practical alternative to 32P in the 3'-end-labeling of DNA restriction fragments.     

Excision Repair of 2,5-Diaziridinyl-1,4-Benzoquinone (DZQ)-DNA Adduct by Bacterial and Mammalian 3-Methyladenine-DNA Glycosylases

The mechanisms of anticancer activity of 2,5-diaziridinyl-1,4-benzoquinone (DZQ) are believed to involve the alkylation of guanine and adenine bases. In this study, it has been investigated whether bacterial and mammalian 3-methyladenine-DNA glycosylases are able to excise DZQ-DNA adduct with a differential substrate specificity. DZQ-induced DNA adduct was first formed in the radiolabeled restriction enzyme DNA fragment, and excision of the DNA adduct was analyzed following treatment with homogeneous 3-methyladenine-DNA glycosylase from E. coli, rat, and human, respectively. Abasic sites generated by DNA glycosylases were cleaved by the associated lyase activity of the E. coli formamidopyrimidine-DNA glycosylase. Resolution of cleaved DNA on a sequencing gel with Maxam-Gilbert sequencing reactions showed that DZQ-induced adenine and guanine adducts were very good substrates for bacterial and mammalian enzymes. The E. coli enzyme excises DZQ-induced adenine and guanine adducts with similar efficiency. The rat and human enzymes, however, excise the adenine adduct more efficiently than the guanine adduct. These results suggest that the 3-methyladenine-DNA glycosylases from different origins have differential substrate specificity to release DZQ-DNA lesions. The use of 3-methyladenine-DNA glycosylase incision analysis could possibly be applied to quantify a variety of DNA adducts at the nucleotide level.     

Novel approach for the effective determination of DNA scission site using the Sanger method

This paper describes the effective determination of DNA scission site using a novel approach that is based on the Sanger method of nucleotide sequencing. The DNA scission site is determined by contrast with the nucleotide sequence of the DNA. Here, instead of the traditional Maxam-Gilbert method for the determination of the DNA sequence, we utilized the Sanger method and studied its effectiveness in the determination of DNA scission sites. Using this method, the determination of DNA scission site becomes more facile and exact. And the total time for the determination is reduced nearly by half in comparison to the Maxam-Gilbert method. Further advantages of this novel approach include the reduced risks of radiation exposure for researchers and contamination of the apparatus.     

Sequence of 1019 nucleotides encompassing one of the inverted repeats from the yeast 2 micrometer plasmid.

A sequence of 1019 nucleotides encompassing one of the 600 base inverted repeats and non-repeated flanking regions has been determined in the type A yeast 2 micrometers plasmid cloned in pMB9. Methods are described for applying the Maxam-Gilbert sequencing procedure to DNA fragments labelled at the 3'-end using a T4-polymerase exchange/repair reaction and for sequencing 5'-end labelled fragments using dideoxy-nucleotides as chain terminators in the presence of E. coli DNA polymerase (nach Klenow). A notable feature of the sequence is its unusual content of symmetry elements. In one region of 140 nucleotides, 137 are involved in a complex arrangement of direct and inverted repeats linked by palindromic sequences.     

Amplification of bacterial genomic DNA by the polymerase chain reaction and direct sequencing after asymmetric amplification: application to the study of periplasmic permeases.

The polymerase chain reaction (PCR) has been used to amplify DNA fragments by using eucaryotic genomic DNA as a template. We show that bacterial genomic DNA can be used as a template for PCR amplification. We demonstrate that DNA fragments at least as large as 4,400 base pairs can be amplified with fidelity and that the amplified DNA can be used as a substrate for most operations involving DNA. We discuss problems inherent in the direct sequencing of the amplified product, one of the important exploitations of this methodology. We have solved the problems by developing an "asymmetric amplification" method in which one of the oligonucleotide primers is used in limiting amounts, thus allowing the accumulation of single-stranded copies of only one of the DNA strands. As an illustration of the use of PCR in bacteria, we have amplified, sequenced, and subcloned several DNA fragments carrying mutations in genes of the histidine permease operon. These mutations are part of a preliminary approach to studying protein-protein interactions in transport, and their nature is discussed.     

Excision Repair of 2,5-Diaziridinyl-1,4-Benzoquinone (DZQ)-DNA Adduct by Bacterial and Mammalian 3-Methyladenine-DNA Glycosylases

The mechanisms of anticancer activity of 2,5-diaziridinyl-1,4-benzoquinone (DZQ) are believed to involve the alkylation of guanine and adenine bases. In this study, it has been investigated whether bacterial and mammalian 3-methyladenine-DNA glycosylases are able to excise DZQ-DNA adduct with a differential substrate specificity. DZQ-induced DNA adduct was first formed in the radiolabeled restriction enzyme DNA fragment, and excision of the DNA adduct was analyzed following treatment with homogeneous 3-methyladenine-DNA glycosylase from E. coli, rat, and human, respectively. Abasic sites generated by DNA glycosylases were cleaved by the associated lyase activity of the E. coli formami-dopyrimidine-DNA glycosylase. Resolution of cleaved DNA on a sequencing gel with Maxam-Gilbert sequencing reactions showed that DZQ-induced adenine and guanine adducts were very good substrates for bacterial and mammalian enzymes. The E. coli enzyme excises DZQ-induced adenine and guanine adducts with similar efficiency. The rat and human enzymes, however, excise the adenine adduct more efficiently than the guanine adduct. These results suggest that the 3-methyladenine-DNA glycosylases from different origins have differential substrate specificity to release DZQ-DNA lesions. The use of 3-methyladenine-DNA glycosylase incision analysis could possibly be applied to quantify a variety of DNA adducts at the nucleotide level.     

Resolution of sequencing ambiguities: a universal FokI adapter permits Maxam-Gilbert re-sequencing of single-stranded phagemid DNA

We propose a method to resolve ambiguities encountered when single-stranded (ss) phagemid DNA templates are sequenced by the dideoxy method. A single oligodeoxyribonucleotide (oligo) is synthesized with the following features: (i) the 20 nucleotides (nt) at the 5'-end form a double-stranded hairpin containing a FokI restriction site, exactly as previously described by Podhajska and Szybalski [Gene 40 (1985) 175-182]; (ii) the 23 nt at the 3'-end hybridize to the (+)strand of ss phagemid DNA in the region complementary to the M13 universal sequencing primer. In a simple one-tube set of reactions, ss phagemid DNA is annealed to this oligo, cleaved by FokI at a unique site outside the vector multiple cloning site and then labelled at this unique site by Klenow polymerase and [alpha-32P]dCTP. These reactions provide a convenient route by which Maxam-Gilbert chemical degradation sequencing methods can be used to resolve ambiguities encountered in the dideoxy-sequencing of a unidirectional deletion series already prepared in popular phagemid vectors. A single oligo allows labelling of all members of a deletion series. A second universal oligo allows the same set of reactions to be applied to inserts cloned into (-)strand phagemids.     

Isolation of circular yeast artificial chromosomes for synthetic biology and functional genomics studies

Circular yeast artificial chromosomes (YACs) provide significant advantages for cloning and manipulating large segments of genomic DNA in Saccharomyces cerevisiae. However, it has been difficult to exploit these advantages, because circular YACs are difficult to isolate and purify. Here we describe a method for purification of large circular YACs that is more reliable compared with previously described protocols. This method has been used to purify YACs up to 600 kb in size. The purified YAC DNA is suitable for restriction enzyme digestion, DNA sequencing and functional studies. For example, YACs carrying full-size genes can be purified from yeast and used for transfection into mammalian cells or for the construction of a synthetic genome that can be used to produce a synthetic cell. This method for isolating high-quality YAC DNA in microgram quantities should be valuable for functional and synthetic genomic studies. The entire protocol takes ～3 d to complete.     

Optimized genomic sequencing as a tool for the study of cytosine methylation in the regulatory region of the chicken vitellogenin II gene

Some critical parameters of genomic sequencing are described. As an example we show a 200-nucleotide (nt) sequence of the estradiol-regulated avian vitellogenin gene II upstream region containing four CpG nt pairs. The two CpG's at positions -612 and -618 are in the sequence binding estradiol-receptor complex. While all four CpG's are methylated in erythrocytes, they are hypomethylated in the DNA of estradiol-responsive organs of egg-laying hens. A simple electroblot DNA transfer system which gives no distortion of DNA bands and quantitative transfer of denatured DNA from the gel to the filter membrane is described. Using Gene Screen membranes, a maximal hybridization signal was obtained when 30-50% of the input DNA was stably bound to the filters. Hybridization background signal and exposure time could be largely reduced by using highly purified fractionated DNA. Using a 90-120 nt long homogeneous single-stranded DNA probe of high specific activity it was possible to read a genomic sequence of up to 200 nt. The resolution was further improved by reducing the extent of chemical modifications of the DNA during the Maxam-Gilbert sequencing reactions.     

An efficient strategy for large-scale high-throughput transposon-mediated sequencing of cDNA clones

We describe an efficient high-throughput method for accurate DNA sequencing of entire cDNA clones. Developed as part of our involvement in the Mammalian Gene Collection full-length cDNA sequencing initiative, the method has been used and refined in our laboratory since September 2000. Amenable to large scale projects, we have used the method to generate >7 Mb of accurate sequence from 3695 candidate full-length cDNAs. Sequencing is accomplished through the insertion of Mu transposon into cDNAs, followed by sequencing reactions primed with Mu-specific sequencing primers. Transposon insertion reactions are not performed with individual cDNAs but rather on pools of up to 96 clones. This pooling strategy reduces the number of transposon insertion sequencing libraries that would otherwise be required, reducing the costs and enhancing the efficiency of the transposon library construction procedure. Sequences generated using transposon-specific sequencing primers are assembled to yield the full-length cDNA sequence, with sequence editing and other sequence finishing activities performed as required to resolve sequence ambiguities. Although analysis of the many thousands (22 785) of sequenced Mu transposon insertion events revealed a weak sequence preference for Mu insertion, we observed insertion of the Mu transposon into 1015 of the possible 1024 5mer candidate insertion sites.     

Genomic sequencing of single microbial cells from environmental samples

Recently developed techniques allow genomic DNA sequencing from single microbial cells [Lasken RS: Single-cell genomic sequencing using multiple displacement amplification. Curr Opin Microbiol 2007, 10:510-516]. Here, we focus on research strategies for putting these methods into practice in the laboratory setting. An immediate consequence of single-cell sequencing is that it provides an alternative to culturing organisms as a prerequisite for genomic sequencing. The microgram amounts of DNA required as template are amplified from a single bacterium by a method called multiple displacement amplification (MDA) avoiding the need to grow cells. The ability to sequence DNA from individual cells will likely have an immense impact on microbiology considering the vast numbers of novel organisms, which have been inaccessible unless culture-independent methods could be used. However, special approaches have been necessary to work with amplified DNA. MDA may not recover the entire genome from the single copy present in most bacteria. Also, some sequence rearrangements can occur during the DNA amplification reaction. Over the past two years many research groups have begun to use MDA, and some practical approaches to single-cell sequencing have been developed. We review the consensus that is emerging on optimum methods, reliability of amplified template, and the proper interpretation of 'composite' genomes which result from the necessity of combining data from several single-cell MDA reactions in order to complete the assembly. Preferred laboratory methods are considered on the basis of experience at several large sequencing centers where >70% of genomes are now often recovered from single cells. Methods are reviewed for preparation of bacterial fractions from environmental samples, single-cell isolation, DNA amplification by MDA, and DNA sequencing.     

Rapid and reliable fluorescent cycle sequencing of double-stranded templates.

Automated DNA sequencing is an extremely valuable technique which requires very high quality DNA templates to be carried out successfully. While it has been possible to readily produce large numbers of such templates from M13 or other single-stranded vectors for several years, the sequencing of double-stranded DNA templates using the ABI 373 DNA Sequencer has had a considerably lower success rate. We describe how the combination of a new fluorescent, dideoxy sequencing method, called cycle-sequencing, coupled with modifications to template isolation procedures based on Qiagen columns, makes fluorescent sequencing of double-stranded templates a reliable procedure. From a single five milliliter culture enough DNA can be isolated (up to 20 micrograms) to do 4-8 sequencing reactions, each of which yields 400-500 bases of high quality sequence data. These procedures make the routine use of double-stranded DNA templates a viable strategy in automated DNA sequencing projects.     

DNAse footprinting: a simple method for the detection of protein-DNA binding specificity.

A method for studying the sequence-specific binding of proteins to DBA is described. The technique is a simple conjoining of the Maxam-Gilbert DNA-sequencing method and the technique of DNAase-protected fragment isolation. Fragments of a 5' end-labelled, double-stranded DNA segment, partially degraded by DNAase in the presence and absence of the binding protein, are visualized by electrophoresis and autoradiography alongside the base-specific reaction products of the Maxam-Gilbert sequencing method. It is then possible to see the protective "footprint" of the binding protein on the DNA sequence. The binding of lac repressor to lac operator is visualized by "footprinting" as an example. Equillibrium estimates indicate that 10-fold sequence-specificity (differential binding constant) could be studied easily using this technique.     

Design of a novel quantitative PCR (QPCR)-based protocol for genotyping mice carrying the neuroprotective Wallerian degeneration slow (Wld s ) gene

Background

The strain of MeCP2^tm1.1Bird mice is a broadly used model for Rett syndrome. Because males carrying the invalidated MeCP2 locus are sterile, this strain has to be maintained in a heterozygous state. All animals therefore have to be genotyped at every generation to discriminate those carrying the invalidated allele (+/- females and y/- males) from those that do not. This is conveniently carried out by PCR on tail genomic DNA but because the primer pairs described initially for this purpose yield very similar size DNA bands on the WT and the KO alleles, this requires to carry out two independent PCR reactions on tail DNA preparations from all animals.

Results

After cloning and sequencing the PCR fragment amplified on the KO allele, we tested several sets of primers that were designed to yield PCR fragments of different sizes on the KO and WT alleles.

Conclusion

We have thus identified a set of three primers that allows for efficient genotyping of the animals by a single PCR reaction. Furthermore, using of this set of primers also resolves a recurrent problem related to the tendency of one of the initial primers to give rise to a non specific band because of its capacity to anneal at both ends of a repeated genomic element which we have identified as MurvyLTR.     

A simple method for direct automated sequencing of PCR fragments.

A simple and rapid method for direct sequencing of PCR-generated fragments has been developed for use on Applied Biosystems 373A Automated DNA Sequencer utilizing the DyeDeoxy terminator chemistry. Standard PCR conditions are used to generate a DNA fragment, which is subsequently gel-purified to remove excess primers and unwanted PCR products. The sequencing reactions are carried out in a thermal cycler using the purified product as template DNA and the Dye-Deoxy terminators. The sequence of 500-bp region in the bacteriophage lambda genome and a 320-bp fragment of the human genomic erythropoietin gene were sequenced with greater than 99% accuracy using this method.     

Synthesis of a Gene Coding for Human Vasoactive Intestinal Peptide (VIP)

Abstract

A gene coding for human Vasoactive Intestinal Peptide (VIP) was designed as a double-stranded 99 base pair DNA sequence. The sixteen fragments of the gene were chemically synthesized using a solid-phase phosphoramidite triester coupling approach and enzymatically assembled using T4 DNA ligase. The resulting gene was cloned into pBR322 and sequenced using the Maxam-Gilbert sequencing procedure.     

A simplified variant of the Maxam-Gilbert method for determining the primary structure of oligonucleotides and DNA fragments

A modification to the Maxam-Gilbert method is proposed that involves precipitation of the nucleotide material with the acetone solution of lithium perchlorate after the completion of chemical reactions to remove the reagents. Modification of cytosine residues is carried out in the presence of lithium chloride. The new mode of precipitation simplifies and speeds up the analysis of oligonucleotides and DNA fragments.     

Sequencing of double-stranded PCR products

Very often the experimental step following PCR is sequencing of the amplified fragment. Two protocols that allow direct sequencing of a double-stranded PCR product are described. The first involves removal of one strand of the PCR product using an Ml3 single-stranded DNA clone, allowing the second strand to be sequenced. The second protocol involves Maxam-Gilbert chemical sequencing after PCR amplification with one labeled primer. The advantages and disadvantages of the two protocols are compared, but both yield DNA sequence without cloning of the PCR product.     

Identification and isolation of the yeast cytochrome c gene.

The iso-1-cytochrome c gene of yeast has been identified and cloned using a synthetic oligodeoxynucleotide as a hybridization probe. The oligomer d[pT-T-A-G-C-A-G-A-A--C-C-G-G] is complementary to a region near the N terminal coding region of the yeast cyc 1 gene. Of several yeast Eco RI fragments which hybridize to this probe, one is changed in size by a G leads to T mutation which eliminates an Eco RI site within the cyc 1 gene. Both the wild-type and the RI- mutant forms were cloned in lambda gt vectors. Maxam-Gilbert sequencing for 91 nucleotides into the coding region for iso-1-cytochrome c yielded a DNA sequence in perfect correspondence with the known protein sequence.     

Prediction of personalized drugs based on genetic variations provided by DNA sequencing technologies

Recent reports of death and illness caused by adverse drug reactions have boosted rational drug design research. It has been shown through sequencing of the entire human genome that human genetic variations play a key role in adverse reactions to drugs as well as in differences in the effectiveness of drug treatments. The advent of high-throughput DNA sequencing technologies with bioinformatics of system biology have allowed the easy identification of genetic variations and all other pharmacogenetic variants in a single assay, thus permitting truly personalized drug treatment. This would be particularly valuable for many patients with chronic diseases who must take many medications concurrently. In this review, we have focused on pharmacogenomics for the prediction of variable drug responses between individuals with relevant genetic variations through new DNA sequencing technologies and provided directions for personalized drug therapy in the future.