Real-time PCR assay for quantitative mismatch detection

We describe here a quantitative real-time PCR assay for the detection of single-base-pair differences that does not require fluorescently labeled gene-specific probes or complicated primer combinations. Following PCR or RT-PCR of a gene segment that may contain allele-specific differences, 100 pg amplified product are used for a real-time PCR with allele-specific primers and SYBR Green. The use of HEPES buffer at a pH of 6.95 together with AmpliTaq DNA polymerase results in a threshold difference between the correct template and the mismatched template of as many as 20 cycles, depending on the mismatch. Correct matches can be detected in an excess of mismatched template at least at the 0.01 level for the six primer-template matches versus mismatches tested: GC vs. A.C, AT vs. G.T, GC vs. C.C, GC vs. G.G, AT vs. C.T, and GC vs. G.A. Because the initial amplification is separate from real-time detection, conditions can be independently optimized for each step, making the assay particularly suitable for the detection of allele-specific expression in single cells.

Use of terminal transferase-dependent antisense RNA amplification to determine the transcription start site of the Snrpn gene in individual neurons

We describe here a very sensitive technique for RNA structure analysis and the determination of transcription start sites and demonstrate its use for mapping the start site of the imprinted Snrpn gene in individual hippocampal neurons. The method is adapted from reverse transcription-terminal transferase-dependent PCR (RT-TDPCR) to include amplification of the antisense sequence by in vitro transcription just prior to the final PCR step. The method should be useful for analysis of all genes for which variation in promoter usage and/or differences in RNA secondary structure may be specific to a given cell type or developmental stage.

In vivo, high-resolution analysis of yeast and mammalian RNA-protein interactions, RNA structure, RNA splicing and ribozyme cleavage by use of terminal transferase-dependent PCR

We have investigated the analysis of RNA by use of terminal transferase-dependent PCR (TDPCR), a procedure previously used for the analysis of DNA and chromatin [J. Komura and A.D.Riggs, Nucleic Acids Res.,26, 1807-1811 (1998)]. When preceded by reverse transcription (RT), TDPCR provides an extremely sensitive, versatile, quantitative and nucleotide-level assay for detecting RNA lesions or structures that block primer extension during the RT step. The procedure is: (i) RT using a gene-specific oligonucleotide; (ii) ribo-tailing of the single-stranded cDNA product by use of terminal deoxy-nucleotidyl transferase; (iii) ligation of a DNA linker to the tailed cDNA by use of T4 DNA ligase; and (iv) PCR using a nested, gene-specific primer and a linker-specific primer. This procedure combines the versatility of a primer extension assay with nucleotide-level resolution, the specificity of nested primers and the sensitivity of PCR. Band patterns obtained are reproducible and quantifiable. We successfully used the technique for the study of yeast RNA structure, splicing intermediates and ribozyme cleavage. Also, in vivo footprint experiments, using mammalian cells and RNase T1, revealed the binding of iron-responsive element binding protein to iron responsive elements in the mRNAs of transferrin receptor and ferritin H-chain.

Methylation dynamics, epigenetic fidelity and X chromosome structure

DNA methylation of the X chromosome is reviewed and discussed, with emphasis on the partial methylation seen in the mouse X-linked Pgk1 promoter region. A new study of partial methylation is presented in which the methylation of CpG site H3 in the mouse Igf2 upstream region was quantitatively measured during growth of subcloned cells in tissue culture. Before subcloning the average methylation level was 50%. After subcloning, methylation was highly variable in early stage clones. With continued passage, clones initially having high methylation lost methylation, whereas clones initially having low methylation gained methylation. By about the 25th generation, all clones had returned to a steady-state methylation level of 50%. These findings are discussed in the context of epigenetic mechanisms and epigenetic fidelity. Interpretation of the results is made according to a model that assumes stochastic methylation and demethylation, with rate parameters influenced by local chromatin structure. A second type of study is reported in which we have measured chromatin accessibility differences between the active X chromosome (Xa) and the inactive X chromosome (Xi). We found that Xa/Xi differences in accessibility to DNase I are surprisingly labile. Relatively infrequent DNA nicks rapidly eliminate differential accessibility.

Methylation analysis by genomic sequencing of 5' region of mouse Pgk-1 gene and a cautionary note concerning the method

We have used genomic sequencing aided by ligation-mediated PCR (LMPCR) to assay for 5-methylcytosine in the CpG-rich promoter region of the mouse X-linked phosphoglycerate kinase gene (Pgk-1). Earlier studies showed that there was very heavy methylation of CpG dinucleotides in the CpG-rich promoter of the human PGK1 gene on the inactive X chromosome (the Xi), but that these same sites were completely unmethylated on the active X chromosome (the Xa). For mouse Pgk-1, previous restriction enzyme analysis had shown apparently complete methylation of only one cytosine in the promoter region on the Xi, at HpaII site H7, which is located in the untranslated region, 28 nucleotides upstream of the translation start site. We analyzed this potentially critical region by combining the use of HpaII with LMPCR, and find that the CpG dinucleotides near H7 are either unmethylated or only partially methylated on the Xi. LMPCR analysis of male and female DNA over a 490-bp sequence including the promoter and enhancer extend the finding of relative hypomethylation on the mouse Xi to include all CpG dinucleotides in this region. These results are relevant to the role of DNA methylation in stabilizing the inactive state of chromatin. In addition, we find that caution must be exercised in using LMPCR for methylation analysis of some sequences. A DNA concentration-dependent band-suppression artifact can incorrectly suggest methylation of both CpG and nonCpG dinucleotides.

Parental imprinting studied by allele-specific primer extension after PCR: paternal X chromosome-linked genes are transcribed prior to preferential paternal X chromosome inactivation

The preferential inactivation of the paternal X chromosome in extraembryonic cells during early mouse development is an example of parental imprinting, but it has not been studied at the transcriptional level because standard methods of measuring RNA levels do not allow detection of allele-specific RNAs in individual early embryos. We sought to determine whether the paternal allele of the X chromosome-linked gene for 3-phosphoglycerate kinase 1 (Pgk-1), which is located very near the center of X chromosome inactivation, is transcribed prior to differentiation of extraembryonic lineages. Previous reports indicated that in heterozygous embryos there is a delay in the appearance of the phosphoglycerate kinase 1 allozyme encoded by the paternal X chromosome until 2 days after the appearance of the corresponding maternal allozyme. We report results obtained by use of a reverse transcription/PCR-based method which allows the quantitative measurement of allele-specific RNA. The assay is sensitive enough for the quantitative analysis in single embryos of allele-specific transcripts differing by only one nucleotide. We have used this assay to analyze mouse embryos heterozygous at the Pgk-1 and Hprt [hypoxanthine (guanine) phosphoribosyltransferase] loci, and we find that individual 8-cell and blastocyst embryos express both Hprt and Pgk-1 paternal transcripts, as do pooled 2- to 4-cell embryos. These results are discussed in view of the apparent temporal delay in paternal expression of the Pgk-1 gene at the enzyme level.

A sensitive, quantitative assay for measurement of allele-specific transcripts differing by a single nucleotide

We have found that the single nucleotide primer extension assay, a PCR-based assay currently used qualitatively to measure allelic differences in DNA, can be used quantitatively to measure allele-specific transcripts differing by only a single nucleotide. We show that total RNA containing the Pgk-1a transcript can be specifically detected even in a 1000-fold excess of RNA containing the Pgk-1b transcript.

Use of a HpaII-polymerase chain reaction assay to study DNA methylation in the Pgk-1 CpG island of mouse embryos at the time of X-chromosome inactivation

A HpaII-PCR assay was used to study DNA methylation in individual mouse embryos. It was found that HpaII site H-7 in the CpG island of the X-chromosome-linked Pgk-1 gene is less than or equal to 10% methylated in oocytes and male embryos but becomes 40% methylated in female embryos at 6.5 days; about the time of X-chromosome inactivation of the inner cell mass.

A quantitative HpaII-PCR assay to measure methylation of DNA from a small number of cells

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DNA topoisomerase from Agrobacterium tumefaciens: purification and catalytic properties

The DNA topoisomerase from Agrobacterium tumefaciens has been purified to apparent homogeneity. The enzyme is a single polypeptide of about 100,000 in molecular weight. No apparent separation of the nicking and sealing activities could be obtained in attempts to separate the two activities by a variety of methods, including limited protease digestion, thermal denaturation, and differential inhibition. Monoclonal antibodies obtained from hybridomas likewise did not preferentially inhibit one of the two activities. These results suggest that the two catalytic functions are carried by the same essential residues of the active enzyme site.

DNA modifying enzymes of Agrobacterium tumefaciens: effect of DNA topoisomerase, restriction endonuclease, and unique DNA endonuclease on plasmid and plant DNA

Extracts from Agrobacterium tumefaciens strain ID135 contain three enzymes that have been characterized and partially purified. The first enzyme, a DNA topoisomerase, appeared to relax only negatively twisted DNA. The second enzyme, Atu I, a type II restriction endonuclease, generated the identical DNA digestion pattern as EcoRII when several DNAs were used. The third enzyme, endonuclease A, showed a preference for superhelical DNAs as substrates. When plasmid pCK135DNA, obtained from the virulent strain IDI135 of A. tumefaciens, or plant DNA was exposed to the three enzymes, changes in DNA patterns were observed due to either conformational changes or digestion of the DNAs. These enzymes may function in vivo in the processing and incorporation of bacterial DNA in plant cells.