Recovery of DNA fragments inserted by the "tailing" method: regeneration of PstI restriction sites

A general method has been developed for the recovery of any DNA fragment inserted into a cloning vehicle containing a single endonuclease PstI site. Endonuclease PstI sites are regenerated by the addition of one or more deoxyguanosine residues to the 3' termini of the PstI-cleaved vehicle by terminal deoxynucleotidyl transferase. Chain elongation by terminal deoxynucleotidyl transferase is then continued with dITP, dATP or dGTP. A plasmid vehicle, pAO1, containing a single PstI site has been constructed. Insertional (foreign) DNA fragments that were "tailed" with dCTP have been annealed to PstI-cleaved pAO1 that was "tailed" with dGTP. When the annealed fragments were used to transform competent Escherichia coli cells, the single-stranded DNA gaps in the recombinant plasmids were repaired. Plasmids recovered from transformed bacteria could be cleaved by PstI into the insertional DNA with dG:dC tracts and linear pAO1 molecules.     

Restriction cutting independent method for cloning genomic DNA segments outside the boundaries of known sequences

We present a simple method for cloning genomic DNA segments outside the boundaries of known sequences, which is not dependent on restriction cutting or mapping. In the first step of the method, a library of single-stranded flanking sequences is generated by linear amplification with one primer in the known region. A homooligomeric cytosine tail is added to each of the single-stranded fragments by a terminal transferase catalyzed reaction. The tailed fragments are then amplified by PCR with a nested primer in the known region and a poly-guanine primer complementary to the cytosine tail in the unknown region. Finally, the different fragments are separated by cloning and characterized by sequencing. The method was used to clone both the upstream (5') and the downstream (3') genomic regions of an intron-interrupted tRNA(Leu)(UAA) gene from three cyanobacteria belonging to the genus Microcystis.     

MOLECULAR ANALYSES OF LINEAR CHLOROPLAST PLASMIDS FROM ERNODESMIS VERTICILLATA

Ernodesmis verticillata contains novel, linear plasmid-like DNA molecules in its chloroplasts, whose function remains unclear. Their molecular architecture is putatively a "hairpin," wherein every molecule consists of a long inverted repeat folded back on itself. Thus, each molecule is composed of a terminal (telomeric) domain, a central inverted repeat, and a "loop" domain. Cloning strategies have been devised for characterizing the terminal and loop regions, since they might contain landmark features like replication origins. Polymerase chain reaction (PCR) was used to amplify loop domains of native molecules, and ligation of the PCR products with commercial cloning vectors initially yielded 11 clones. So far, no recognizable sequences have turned up in the loop domains of the molecules. Unlike what has been reported for most linear plasmids, we have been unable to verify that any proteins are associated with either the 5'- or 3'-ends of the Ernodesmis plasmids. In fact, the 5'-end of each molecule contains a terminal phosphate that is accessible to alkaline phosphatase and subsequently to T4 polynucleotide kinase in vitro. It is also possible to modify the 3'-end with terminal deoxynucleotidyl transferase (TdT) for homopolymeric tailing. Poly-(C) tailing of native molecules promotes their annealing to poly-(G) tailed vectors, for cloning of the terminal domains. An initial library of 14 TdT clones (10 unique) indicates that short (11–28 bp) direct repeats occur near the termini of the plasmids. Shorter (4–6 bp) inverted repeats at the very ends may lead to terminal foldbacks that might serve to protect the termini.     

Preparation of sensitive and specific oligonucleotide probes tailed using terminal transferase and dITP

An oligonucleotide probe tailed with deoxyadenosine-5'-triphosphate or deoxythymine-5'-triphosphate is detectable with high sensitivity, but has a major drawback--the tail co-hybridizes specifically to complementary sequences. This can be a problem when screening cDNA clones that contain poly(dA) sequences. While it is possible to mask the cDNA tail with unlabeled poly(dA) or poly(A) oligonucleotides, false-positive clones are still produced because complete masking of extremely long (dA) tails is difficult. As a result, only cDNA clones that have extremely long poly(dA) sequences are often obtained by hybridization screening using tailed probes. In this report, we describe an oligonucleotide probe tailed with DIG-labeled nucleotide in combination with deoxyinosine-5'-triphosphate that was highly specific and sensitive to cDNAs. Terminal deoxynucleotidyl transferase efficiently adds dI nucleotides to the 3'-end. The dI of the tails did not pair with any nucleotides under stringent hybridization so that the specificity of hybridization assays remained high without affecting the sensitivity of the test. Colony hybridization experiments demonstrated that there were very few (1 of 80 tested) false positives using this technique. Its use may increase the accuracy of cDNA screening.     

5''-Terminal sequences of eucaryotic mRNA can be cloned with high efficiency.

A method for cloning mRNAs has been used which results in a high yield of recombinants containing complete 5'-terminal mRNA sequences. It is not dependent on self-priming to generate double-stranded DNA and therefore the S1 nuclease digestion step is not required. Instead, the cDNA is dCMP-tailed at its 3'-end with terminal deoxynucleotidyl transferase (TdT). The synthesis of the second strand is primed by oligo(dG) hybridized to the 3'-tail. Double-stranded cDNA is subsequently tailed with dCTP and annealed to dGMP-tailed vector DNA. This approach overcomes the loss of the 5'-terminal mRNA sequences and the problem of artifacts which may be introduced into cloned cDNA sequences. Chicken lysozyme cDNA was cloned into pBR322 by this procedure with a transformation efficiency of 5 x 10(3) recombinant clones per ng of ds-cDNA. Sequence analysis revealed that at least nine out of nineteen randomly isolated plasmids contained the entire 5'-untranslated mRNA sequence. The data strongly support the conclusion that the 5'-untranslated region of the lysozyme mRNA is heterogeneous in length.     

The effects of terminal heterologies on gene targeting by insertion vectors in embryonic stem cells.

We have examined the effects of placing nonhomologous DNA on the ends of an insertion-type gene targeting vector. The presence of terminal heterologies was found to be compatible with insertion targeting, and the terminal heterologies were efficiently removed. Terminal heterologies reduced the frequency of gene targeting to variable extents. The degree of inhibition of targeting was dependent on the length and the position of the heterology: 2.1kb heterologous sequences were more inhibitory than shorter regions of heterology, and heterology placed on the end of the long (4.8kb) arm of homology was more inhibitory than heterology positioned on the end of the short (0.8kb) arm. When heterology was placed on both arms of the targeting vector the targeting efficiencies were similar to or higher than when heterology was present on the long arm only. These results suggest that terminal sequences are removed simultaneously from both ends of targeting vectors. The removal of terminal sequences probably occurs by exonucleolytic degradation of both strands at each end, and removal of at least one of the strands is intimately coupled with the process of homologous recombination. These findings have implications for the design of gene targeting vectors.     

Modified T-RFLP methods for taxonomic interpretation of T-RF

Terminal restriction fragment length polymorphism (TRFLP) is a method that has been frequently used to survey the microbial diversity of environmental samples and to monitor changes in microbial communities. T-RFLP is a highly sensitive and reproducible procedure that combines a PCR with a labeled primer, restriction digestion of the amplified DNA, and separation of the terminal restriction fragment (T-RF). The reliable identification of T-RF requires the information of nucleotide sequences as well as the size of T-RF. However, it is difficult to obtain the information of nucleotide sequences because the T-RFs are fragmented and lack a priming site of 3'-end for efficient cloning and sequence analysis. Here, we improved on the T-RFLP method in order to analyze the nucleotide sequences of the distinct TRFs. The first method is to selectively amplify the portion of T-RF ligated with specific oligonucleotide adapters. In the second method, the termini of T-RFs were tailed with deoxynucleotides using terminal deoxynucleotidyl transferase (TdT) and amplified by a second round of PCR. The major T-RFs generated from reference strains and from T-RFLP profiles of activated sludge samples were efficiently isolated and identified by using two modified T-RFLP methods. These methods are less time consuming and labor-intensive when compared with other methods. The T-RFLP method using TdT has the advantages of being a simple process and having no limit of restriction enzymes. Our results suggest that these methods could be useful tools for the taxonomic interpretation of T-RFs.     

多等位基因PCR-SSO反相杂交法及其在HLA-DR_4亚型结构分析中的应用

本文介绍一种适合于多等位基因定型和结构分析的反相顺序特异性寡核苷酸探针杂交方法。将化学合成的多种探针分别经脱氧核苷末端转移酶(TdT)催化,于3′端加上100个以上碱基的Poly(dT)尾,然后将各探针分别以斑点固定于同一张尼龙膜上。用PCR法对该基因位点进行扩增,扩增的同时加入α-~(32)P-dCTP以直接参入放射标记,然后将PCR产物与膜固定探针杂交,以四甲基氯化铵根据探针长度统一洗涤温度。该方法克服了以往对同一份样品进行多个等位基因检测时需要进行多次探针标记和杂交的缺点。我们用该方法对中国人群MHC-Ⅱ类DR4多等位基因进行了研究。     

Use of 5-Nitroindole-2′-deoxyribose-5′-triphosphate for Labelling and Detection of Oligonucleotides†

Abstract

The 5′-triphosphate of 5-nitroindole-2′-deoxyriboside has been shown to be a good substrate for terminal deoxynucleotidyl transferase (TdT). An antibody has been prepared for the detection of 5-nitroindole and has been used for the detection of 5-nitroindole tailed DNA both in single-stranded form and after hybridisation to a template. This is therefore a new method for the detection of nucleic acid probes.

     

Inverted terminal repetition in adeno-associated virus DNA: independence of the orientation at either end of the genome

Complementary strands of adeno-associated virus DNA labeled with 32P at the 5' ends were separated and then self-annealed to form single-stranded circles stabilized by hydrogen bonds between the complementary sequences in the inverted terminal repetitions. We have previously shown that there are two distinct sequences in the terminal repetition which represent an inversion of the first 125 nucleotides (E. Lusby et al., J. Virol. 34:402-409, 1980; I. S. Spear et al., Virology 24:627-634, 1977). Base pairing between terminal sequences of the same orientation leads to a normal double helical structure. If sequences of the opposite orientation pair, an aberrant secondary structure is formed. HpaII digestion of the self-annealed, single-stranded circles led to labeled terminal fragments that corresponded both to those generated from termini of a normal double helical structure and those generated from an aberrant terminal secondary structure. Thus, the orientation of the terminal repetition at one end of the genome is not influenced by the orientation at the other end.     

Initiator role of double stranded DNA in terminal transferase catalyzed polymerization reactions.

Binding of the 58 kDa monomer and 44 kDa alpha beta dimer forms of terminal deoxynucleotidyl transferase to double stranded DNA was demonstrated by gel retardation and tryptophan fluorescence quenching. The dissociation constants and cooperativity parameters were similar to those that have been determined for binding of these two forms of terminal transferase to single stranded DNA. However, the double stranded DNA binding site size of 10 nucleotides was half the size expected. The efficacy of blunt ended DNA as an initiator in the polymerization reaction catalyzed by terminal transferase was demonstrated by radiometric assays and product analyses on agarose gels. The initial reaction kinetics indicated that dGTP but not dATP was added efficiently to a blunt double stranded DNA 3' end. These results are correlated with current models for in vivo terminal transferase function.     

Expression and processing of recombinant human terminal transferase in the baculovirus system

Overproduction of human terminal transferase protein has now been accomplished by cloning the coding sequence of human terminal transferase into a baculovirus, where the expression of terminal transferase is under the control of the polyhedrin protein promoter. Two constructs were made, one producing a protein containing the entire terminal transferase fused to 12 amino acids from the NH2 terminus of the polyhedrin protein, and the other producing 58-kDa human terminal transferase. The terminal transferase levels expressed in cells infected with either recombinant baculovirus are around 10,000 units/10(7) cells at 48 h postinfection, about 200-fold greater than levels expressed in thymus and cultured lymphoblastoid cells. The chimeric polyhedrin/human terminal transferase protein produced in the infected insect cells has a molecular weight of about 60,000 while the nonfused recombinant human terminal transferase is identical in molecular weight to that present in human lymphoblastoid cells. Both forms of recombinant terminal transferase show immunological and enzymatic activity. When infected cells are pulse-labeled with [35S] methionine at 42-45 h postinfection, about 10% of newly synthesized protein is terminal transferase. Both forms of terminal transferase are phosphorylated in recombinant virus-infected cells as demonstrated by pulse-labeling infected cells with 32P-inorganic phosphate and isolation of labeled terminal transferase peptides by immunoprecipitation.     

Rapid amplification of genomic DNA ends bynla III partial digestion and polynucleotide tailing

We report a simple and efficient method, which combines restriction endonuclease digestion and deoxynucleotide tailing, for cloning unknown genomic sequences adjacent to a known sequence. Total genomic DNA is partially digested with the frequent-cutting restriction enzymeNla III. A homo-oligomeric cytosine tail is added by terminal transferase. The tailed DNA fragments are used as the template for cloning flanking regions from all sequences of interest. A first round PCR amplification is performed with a gene-specific primer and the selective (modified polyguanine) anchor primer complementary to the cytosine tail and theNla III recognition site, with a universal amplification primer sequence at its 5′ end. This is followed by another PCR amplification with a nested gene-specific primer and the universal amplification primer. Finally, the amplified products are fractionated, cloned, and sequenced. Using this method, we cloned the upstream region of a salt-induced gene based upon a partial cDNA clone (RSC5-U) obtained from sunflower (Helianthus annuus L.).     

Electron microscopic study of equine herpesvirus type 1 DNA.

Electron microscopic studies of equine herpesvirus DNA revealed that single strands that were allowed to reanneal formed single-stranded loops with double-stranded stems only at one end of the molecule. These observations support restriction enzyme analyses which indicate that the 92-megadalton DNA molecule exists as a long region of unique sequences covalently linked to a short region. The short region is comprised of an internal unique sequence, which forms the loop during reannealing of single strands, and two terminal inverted repeat sequences that bracket the unique sequence and form the double-stranded stem structure observed upon reannealing of single strands. Measurements of the unique sequence and terminal inverted repeat subgenomic sequences indicate a size of 6.4 megadaltons for each and thus fix the size of the short region at approximately 19.2 megadaltons.