Automated sequencing and mapping of cosmid DNA with fluorescently-labeled dideoxynucleotide terminators.

We have established a method for directly sequencing cosmid DNA on an automated DNA sequencer. The major advantage of this method is that only small amounts of cosmid template DNA are needed for the sequencing reactions.     

A modified TnphoA useful for single-stranded DNA sequencing.

The TnphoA transposon constructed by Manoil and Beckwith [Proc. Natl. Acad. Sci. USA 82 (1985) 8129-8133] has been modified to permit easy isolation of single-stranded (ss) DNA of target plasmids. The intergenic region (IG) of filamentous phage f1, which consists of the phage origin of replication and packaging signal, was inserted into a nonessential region of TnphoA. This modified transposon should be useful for the analysis of genes cloned in plasmids that lack a filamentous phage IG. Transposition of TnphoA-IG into a plasmid carries the IG with it; subsequently, after infection with a filamentous helper phage, ss plasmid DNA suitable for sequence analysis and useful for oligodeoxyribonucleotide-mediated mutagenesis of TnphoA-generated fusions can be isolated. The utility of TnphoA-IG was confirmed by analysis of 'blue hops' into the bla (encoding beta-lactamase) and pspE (encoding phage shock protein) genes whose products are secreted into the Escherichia coli periplasm.     

A method for isolation of a large amount of a single-stranded DNA fragment

Single-stranded DNA inserts can be digested from recombinant phage DNA of M13mp7 with BamHI or EcoRI restriction endonucleases. The single-stranded DNA is satisfactory for DNA sequencing and nuclei acid hybridization.     

A method for sequencing single-stranded cloned DNA in both directions

A DNA sequencing method has been developed whereby DNA that has been cloned in a single-stranded bacteriophage vector can be sequenced from both ends. The method involves first making a minus-strand sense template from a single-stranded insert in the vector MJ3mp2 using a flanking primer, and then sequencing the synthesized template using the dideoxynucleotide termination method (Sangeret al., 1977, 1980) with a second primer. Special conditions are described under which the first primer is easily removed after making the templat% and sequencing in the opposite direction can be done in the normal way (Sangeret al., 1980) without separating the double strands. This method renders it possible to read up to twice the amount of sequence data from a long insert and also to check short inserts by producing complementary sequence patterns.     

Hybridization methods for DNA sequencing.

I have conducted a general analysis of the practicability of using oligonucleotide hybridization to sequence DNA. Any DNA sequence may be sequenced by hybridization with a complete panel of oligonucleotides. However, sequencing DNA segments over 2 kb long requires an unrealistic number of hybridization reactions. The optimal protocol is to hybridize 7-mer or 8-mer mixed oligonucleotide probes to immobilized DNA fragments 80 bp long: should this prove impractical, hybridization of labeled 270-bp fragments to immobilized mixed 10-mers is a potential alternative. Both protocols require no more experiments to sequence large regions of DNA than conventional m13-based sequencing and are much easier to automate, thus reducing the requirements for skilled personnel. In the ideal case, hybridization sequencing reduces the number of experiments required to sequence megabase DNA by 90%.     

High-throughput isolation of ultra-pure plasmid DNA by a robotic system

Background  

Short hairpin RNA (shRNA) encoded within an expression vector has proven an effective means of harnessing the RNA interference (RNAi) pathway in mammalian cells. A survey of the literature revealed that shRNA vector construction can be hindered by high mutation rates and the ensuing sequencing is often problematic. Current options for constructing shRNA vectors include the use of annealed complementary oligonucleotides (74 % of surveyed studies), a PCR approach using hairpin containing primers (22 %) and primer extension of hairpin templates (4 %).     

High-throughput isolation of ultra-pure plasmid DNA by a robotic system

Background  

With the availability of complete genomes, a systematic inventory of cellular processes becomes achievable. This requires assessing the function of all individual genes. Transfection of plasmid DNA into cell culture cells is an essential technique for this aim as it allows functional overexpression or downregulation of genes. While many robotic systems isolate plasmids for sequencing purposes, for more demanding applications such as transfections there is a shortage of robots for the high-throughput isolation of plasmid DNA.     

Cloning vectors that yield high levels of single-stranded DNA for rapid DNA sequencing

We have constructed chimeric plasmid vectors with the origin and intergenic region from M13 phage cloned into the PvuII ( pZ145 ) and AhaIII ( pZ150 , pZ152 ) sites of pBR322. In the absence of M13 phage, these plasmids replicate like any other ColE1-derived plasmid and confer both ampicillin and tetracycline resistance (Amp, Tet). Upon infection with M13 phage, the viral origin present on the plasmids permits phage-directed plasmid replication and results in high yields of single-stranded (ss) plasmid DNA in M13-like particles. This ssDNA, which represents only one of the plasmid strands, is useful as a substrate for rapid DNA sequence determination by the dideoxy sequencing method described by Sanger et al. (1977). Since these plasmids contain an intact pBR322, the intergenic region can be transferred onto most pBR322 derivatives to yield ss plasmid DNA without affecting the recipient plasmid for further studies. We also constructed a deletion derivative of pZ145 , plasmid pZ146 , that does not exhibit interference with the growth of the M13 helper, although this plasmid is encapsidated into phage particles. This result confirms the theory that the intergenic region consists of two domains: one domain being a segment involved in phage morphogenesis and the other being a region of functional origin which interferes with M13 replication.     

In vitro production of large single-stranded templates for DNA sequencing.

A method has been developed for the preparation of large single-stranded DNA sequencing templates from primary cloning plasmids or cosmids. The method utilizes the separate action of T7 Gene 6 exonuclease and exonuclease III to generate large quantities of single-stranded template for each strand of a large-cloned fragment. Since the procedure is intended for use on primary clones, it avoids the time-consuming subcloning steps associated with most sequencing programs. The procedure also has the advantage of avoiding clone instability problems associated with subcloning in M13.     

Production of single-stranded DNA for sequencing: an alternative approach.

We describe a simple procedure for the direct sequencing of single-stranded, PCR-amplified, target regions of human genomic DNA. At variance with previously reported procedures, purification of the desired double-stranded DNA was introduced. This additional step allowed the single-stranded amplification and sequencing of the target gene. This step is required for direct sequencing of some amplified regions of human genomic DNA. However, no individual technique seems suitable to generate and sequence all single-stranded DNA.     

Pyrimidine-specific chemical reactions useful for DNA sequencing.

Potassium permanganate reacts selectively with thymidine residues in DNA (1) while hydroxylamine hydrochloride at pH 6 specifically attacks cytosine (2). We have adopted these reactions for use with the chemical sequencing method developed by Maxam and Gilbert (3).     

DNA isolation methods for medicinal and aromatic plants

Several protocols described for plant DNA isolation fail to produce good quality DNA from medicinal herbs and aromatic plants. These plants contain exceptionally high amounts of secondary metabolites that interfere with DNA isolation. To address this problem, we developed 2 DNA isolation methods for sundew and tarragon that produce DNA suitable for molecular biological applications. One of the methods also is applicable for milfoil and Siberian ginseng.     

Automated DNA sequencing and analysis of the human genome

In the past few years, striking advances have been made in automating DNA sequence analysis. Currently, efforts are underway to automate and improve DNA purification, mapping, and data processing procedures. The predictable advances in these technologies should soon place us in a position to sequence the entire human genome. The information derived from this project will have profound implications for basic biology and clinical medicine alike.     

The production of single-stranded DNA suitable for sequencing using the polymerase chain reaction

A simple and reliable procedure for the amplification of single-stranded DNA suitable for sequencing is described. This procedure employs the polymerase chain reaction and implements modifications pertaining to the purification of the double-stranded DNA product prior to single-stranded DNA amplification. The most consistent sequencing reactions are obtained when the double-stranded DNA product is purified by centrifugation with a microconcentrator prior to single-stranded DNA amplification and the overall amount of specific primers and number of cycles used, in both single-stranded and double-stranded DNA polymerase chain reactions, are reduced.     

Affinity generation of single-stranded DNA for dideoxy sequencing following the polymerase chain reaction

A method to rapidly generate single stranded DNA for dideoxy sequencing following the polymerase chain reaction is described. By incorporating biotin in one of the amplification primers, we are able to physically separate the two DNA strands produced in the polymerase chain reaction. After amplification, the mixture is passed through a column containing streptavidin agarose. The strand produced by the biotinylated primer is bound in this matrix. The unbiotinylated strand is eluted with 0.2 N NaOH and sequenced by the dideoxy method. This method was utilized to sequence mitochondrial DNA from crude genomic DNA and to determine the sequences of four clones containing human mitochondrial DNA as a test of its accuracy. The use of biotin-facilitated separation permitted us to amplify and sequence DNA samples in a single day.