Cloning the swamp buffalo SRY gene for embryo sexing with multiplex-nested PCR

The polymerase chain reaction (PCR) is an efficient method for sexing embryos. The objective of this study was to develop an accurate and reliable method for sexing swamp buffalo (Bubalus bubalis) embryos. The SRY gene from swamp buffalo genomic DNA was amplified by PCR, using primers based on the sequence of the Holstein SRY gene. This fragment was sequenced based on a BLAST search; the SRY gene was highly conserved. Using a Southern blot, there was a strong signal in genomic DNA only from male swamp buffalo. Two pairs of nested primers, targeted to amplify the swamp buffalo SRY conserved region, were designed for sex identification. Simultaneously, the G3PDH gene was co-amplified to serve as an internal control. A multiplex-nested PCR system was optimized by varying the following individually: concentrations of Mg(2+) and dNTPs, ratio of concentrations of primers and numbers of cycles. Biopsies of 27 IVF-derived embryos and 24 embryos fertilized with Y-chromosome-bearing sperm were examined. Using optimized procedures, clear signals following PCR amplification were obtained from all embryo samples; PCR amplification accuracy was further verified by comparing PCR and dot blots. We concluded that this PCR technique was highly reliable for sexing swamp buffalo embryos.     

The first sex-specific molecular marker discovered in the moss Pseudocalliergon trifarium

Most dioecious plants do not exhibit discernible sexual dimorphism before sexual maturity. Therefore, it is impossible to address any sex-related questions during the prereproductive phase unless a genetic sex marker is available for gender determination. The aim of the present study was to develop a genetic sex marker for the moss Pseudocalliergon trifarium to allow gender and sex ratio determination at any stage in the life cycle. A high proportion of P. trifarium populations do not express sex. The screening of genomic DNA with inter simple sequence repeat (ISSR) primers was used to discover sex-specific polymerase chain reaction (PCR) amplification products. A presumably female-specific band was found, excised from the gel, cloned, and sequenced. A sequence-walking method was used to characterize the same region in males. A primer pair was designed to allow the amplification of a 159-bp portion of the female-specific DNA region. All tested material, up to 16-year-old herbarium specimens, provided unambiguous amplification products. This study successfully provides, for the first time in a moss, a sex-specific DNA marker. It allows reliable determination of gender and sex ratios. The short length of the amplification product is an advantage as satisfactory PCR products are more likely when the targeted sequence is short. The amount of variation in the DNA region shared by both sexes was relatively high. If the male sequence can be better characterized, the sex-specific regions could possibly be used to evaluate sex-specific phylogeographic patterns.     

Efficient removal of PCR inhibitors using agarose-embedded DNA preparations.

The use of agarose blocks containing embedded DNA improves the PCR amplification from templates naturally contaminated with polysaccharides or humic acids, two powerful PCR inhibitors. Presumably, the difference in size between the DNA macromolecules and these contaminants allows their effective removal from the agarose blocks by diffusion during the washing steps, whereas genomic DNA remains trapped within them. In addition, agarose-embedded DNA can be directly used for PCR since low melting point agarose does not interfere with the reaction. This simple and inexpensive method is also convenient for genomic DNAs extracted by other procedures, and it is potentially useful for samples containing other kinds of soluble inhibitors, overcoming this important problem of current amplification techniques.     

Chlamydomonas (Chlorophyceae) colony PCR

The ease and effectiveness of colony polymerase chain reaction (PCR) has allowed rapid amplification of DNA fragments and screening of large number of colonies of interest including transformants and mutants with genetic manipulations. Here, we evaluated colony PCR in Chlamydomonas. Individual colonies were treated with 10 mM ethylenediaminetetraacetic acid (EDTA) or Chelex-100 and the resulting clear cell lysate was used for PCR reaction. Either genomic DNA or plasmid DNA incorporated into the genome was equally amplified. We found that the Chelex method is superior to EDTA method in certain cases. This colony PCR technique will bypass the tedious process of isolating genomic DNA for PCR reaction and will make it possible for rapid amplification of genomic DNA fragments as well as rapid large-scale screening of transformants.     

Whole Genome Amplification for Sequencing and Applications in Conservation Genetics

Abstract: We describe a method for rapidly amplifying whole genomes via a Phi29 DNA polymerase-mediated strand displacement reaction (SDR). Genomic amplification products derived from the SDR reaction resulted in high quantities of DNA suitable for polymerase chain reaction (PCR) amplification and sequencing of mitochondrial genomes. Control region sequences of DNA derived directly from PCR amplicons of extracted DNA were identical to those derived from PCR amplification of SDR genomic DNA. Effective SDR amplification and subsequent sequencing was successful across tissues sources ranging in age from 1 year to 19 years. Strand replacement reaction genomic amplification offers a means of obtaining large quantities of DNA from small amounts of tissue.     

Molecular detection of Marteilia sydneyi, pathogen of Sydney rock oysters

The life cycle of Marteilia sydneyi, the aetiological agent of QX disease in the Sydney rock oyster Saccostrea commercialis, is not known. We have developed and optimised 2 diagnostic assays, the polymerase chain reaction (PCR) and in situ hybridisation, for use in investigating the role of possible alternative hosts in the life cycle of this pathogen. PCR primers, designed within the ITS1 rDNA of M. sydneyi, amplified a 195 bp fragment. Sensitivity of the PCR assay was assessed using DNA extracted from known numbers of sporonts purified from infected oyster digestive gland. DNA equivalent to 0.01 sporonts was detectable following agarose gel electrophoresis. The potential inhibitory effect of the presence of host DNA on the PCR assay was tested by the addition of oyster genomic DNA during amplification. Concentrations of host DNA in excess of 50 ng per 20 microliters reaction reduced the sensitivity of the test. Environmental validation of the PCR assay was demonstrated by the amplification of M. sydneyi DNA from 50 ng of genomic DNA extracted from QX-infected oysters. A DNA probe was constructed using the M. sydneyi unique primers and was able to detect 10 pg of M. sydneyi PCR amplified DNA in dot-blot hybridisations. The probe hybridised with presporulating and sporulating M. sydneyi stages in paraffin sections of oyster digestive gland. No non-specific binding was observed. Hybridisation consistency and signal intensity decreased as sporonts matured. While the high sensitivity and specificity of the PCR test will allow rapid screening of large numbers of potential alternative hosts for the presence of parasite DNA, it does not actually identify infective stages. In situ hybridisation conducted on paraffin sections will determine the location of the parasite within the host for morphological characterisation.     

Biases for detecting arbuscular mycorrhizal fungal mixture by terminal restriction fragment length polymorphism (T-RFLP)

Terminal restriction fragment length polymorphism (T-RFLP) analysis of amplified ribosomal RNA genes is used for profiling microbial communities and sometimes for species richness and relative abundance estimation in environmental samples. However, the T-RFLP fingerprint may be subject to biases during the procedure, influencing the detection of real community structures in the environment. To investigate possible sources of T-RFLP bias, 18S rRNA gene clones derived from two arbuscular mycorrhizal fungal sequences were combined in simple pairwise mixes to assess the effects of polymerase chain reaction cycle number, plant genomic DNA purification method and varying template ratio on the template-to-product ratio as measured by relative T-RF peak area. Varying cycle numbers indicated that amplification was still in the exponential phase at the cycle numbers lower than 18, so these small cycle numbers were used for the comparison of template-to-product quantities. Relative abundance estimated from T-RF peak ratios varied with different purification procedures, but the best results, closest to input ratios, were obtained by using phenol–chloroform purification. The presence of an excess of unpurified non-target plant genomic DNA generated a bias towards lower or overestimation of relative abundance. We conclude that a low number of amplification cycles and stringent DNA purification are necessary for accurate mixed sample analysis by T-RFLP.     

DNA Extraction from small blood volumes and the processing of cellulose blood cards for use in polymerase chain reaction

This article describes two procedures for the purification of genomic DNA from small blood volumes of whole blood using DNAzol^®BD. In the first procedure, DNA is isolated from 1–20 μL of whole blood using a fast and simple protocol that is appropriate for the simultaneous extraction of a large number of samples. The isolated DNA is suitable for gel electrophoresis and polymerase chain reaction (PCR). In the second procedure, cellulose blood cards containing approx 5 μL of dried blood are treated with DNAzol BD in order to retain DNA on the cellulose matrix while removing other cellular components. The blood card with DNA subsequently serves as template in PCR. The blood card processing and amplification procedures are performed in the same PCR tube without any centrifugation steps, making the combined procedures amenable for automated DNA preparation and amplification in a single tube.     

Sequential DEXAS: a method for obtaining DNA sequences from genomic DNA and blood in one reaction

Sequential DEXAS (direct exponential amplification and sequencing), a one step amplification and sequencing procedure that allows accurate, inexpensive and rapid DNA sequence determination directly from genomic DNA, is described. This method relies on the simultaneous use of two DNA polymerases that differ both in their ability to incorporate dideoxynucleotides and in the time at which they are activated during the reaction. One enzyme, which incorporates deoxynucleotides and performs amplification of the target DNA sequence, is supplied in an active state whereas the other enzyme, which incorporates dideoxynucleotides and performs the sequencing reaction, is supplied in an inactive state but becomes activated by a temperature step during the thermocycling. Thus, in the initial stage of the reaction, target amplification occurs, while in the second stage the sequencing reaction takes place. We show that Sequential DEXAS yields high quality sequencing results directly from genomic DNA as well as directly from human blood without any prior isolation or purification of DNA.     

Sex determination in cattle based on simultaneous amplification of a new male-specific DNA sequence and an autosomal locus using the same primers

A PCR-based method for sex determination of bovine DNA samples and embryo biopsies is presented. Using only one primer pair both the male-specific sequence FBNY (127 bp) and a sex-independent control PCR-fragment, the microsatellite marker FBN17 (136-140 bp) are generated in the same PCR reaction. Synteny mapping assigned the male-specific sequence to bovine chromosome Y (BTA Y), whereas FBN17 was mapped to bovine chromosome 2. Localisation of FBNY on BTA Y was confirmed by fluorescence in hybridisation of two BAC clones containing the male-specific sequence. There was no amplification of the male-specific target sequence FBNY in sheep, pig, goat, mice, man, and several wild species of the tribe Bovini. The bovine male-specific fragment was detected in dilutions containing as little as 10 pg genomic DNA and in blastomeres from embryo biopsies. The PCR assay presented here does require neither restriction endonuclease digestion of the PCR product nor additional nested PCR steps. Owing to the advantage of parallel amplification of the autosomal locus FBN17 no additional control fragment is necessary to detect PCR failure. The results of sex determination in embryo biopsies using FBNY were in agreement with the outcome from a reference assay used in commercial breeding programs.     

A simple and rapid gene amplification from Arabidopsis leaves using AnyDirect system

Polymerase chain reaction (PCR) is a powerful technique in molecular biology and is widely used in various fields. By amplifying DNA fragments, PCR has facilitated gene cloning procedures, as well as molecular genotyping. However, the extraction of DNA from samples often acts as a limiting step of these reactions. In particular, the extraction of PCR-compatible genomic DNA from higher plants requires complicated processes and tedious work because plant cells have rigid cell walls and contain various endogenous PCR inhibitors, including polyphenolic compounds. We recently developed a novel solution, referred to as AnyDirect, which can amplify target DNA fragments directly from whole blood without the need for DNA extraction. Here, we developed a simple lysis system that could produce an appropriate template for direct PCR with AnyDirect PCR buffer, making possible the direct amplification of DNA fragments from plant leaves. Thus, our experimental procedure provides a simple, convenient, non-hazardous, inexpensive, and rapid process for the amplification of DNA from plant tissue.     

DNA analysis with multiplex microarray-enhanced PCR

We have developed a highly sensitive method for DNA analysis on 3D gel element microarrays, a technique we call multiplex microarray-enhanced PCR (MME-PCR). Two amplification strategies are carried out simultaneously in the reaction chamber: on or within gel elements, and in bulk solution over the gel element array. MME-PCR is initiated by multiple complex primers containing gene-specific, forward and reverse, sequences appended to the 3′ end of a universal amplification primer. The complex primer pair is covalently tethered through its 5′ end to the polyacryl- amide backbone. In the bulk solution above the gel element array, a single pair of unattached universal primers simultaneously directs pseudo-monoplex PCR of all targets according to normal solution-phase PCR. The presence of a single universal PCR primer pair in solution accelerates amplification within gel elements and eliminates the problem of primer interference that is common to conventional multiplex PCR. We show 10⁶-fold amplification of targeted DNA after 50 cycles with average amplification efficiency 1.34 per cycle, and demonstrate specific on-chip amplification of six genes in Bacillus subtilis. All six genes were detected at 4.5 pg of bacterial genomic DNA (equivalent to 10³ genomes) in 60 independent amplification reactions performed simultaneously in single reaction chamber.     

A strategy for single site PCR amplification of dsDNA: priming digested cloned or genomic DNA from an anchor-modified restriction site and a short internal sequence

Amplification of dsDNA by polymerase chain reaction (PCR) has been limited to those instances in which segments of known sequence flank the fragment to be amplified. A strategy for the PCR amplification of cloned or genomic dsDNA that necessitates sequence information from only a single short segment (single site PCR) has been devised. The region of known sequence may be located at any position within or adjacent to the segment to be amplified. The basic procedure for amplification consists of 1) digestion of dsDNA with one or more restriction enzymes, 2) ligation with a universal anchor adaptor and 3) PCR amplification using an anchor primer and the primer for the single site of known sequence. The anchor adaptor is designed in such a way as to facilitate the amplification of only those fragments containing the sequence of interest. We have demonstrated the utility of this technique by specifically amplifying and directly sequencing antibody variable region genes from cloned dsDNA and from genomic DNA.     

In situ monitoring of polymerase extension rate and adaptive feedback control of PCR by using fluorescence measurements

Real time PCR detection systems based on fluorescence detection from intercalating dyes (such as SYBR Green I) typically take only single point measurements during every cycle to quantify the amplification. In this process key information about enzymatic kinetics is lost. In this work we measure SYBR Green I fluorescence intensity every 0.5 s within a cycle during PCR in polypropylene tubes. We observe that the intensity during the extension cycle increases while the template is being extended. Results obtained for different lengths are used to estimate an in vitro polymerase activity rate of Thermus aquaticus and Thermus brockianus. An important practical consequence of this result is that the extension time of each PCR cycle can be individually optimized while the reaction is in progress. We demonstrate this idea of adaptive feedback control and show that the total number of cycles and total time required to reach maximum fluorescence is reduced as compared to conventional PCR.     

Incorporation of 7-deaza dGTP during the amplification step in the polymerase chain reaction procedure improves subsequent DNA sequencing

An improved method for sequencing human genomic DNA amplified by the polymerase chain reaction (PCR) procedure is described. The portion of the genome investigated is the 383 nucleotide-long exon 2 of the human antithrombin III gene. Incorporation of the analogue of dGTP, 7-deaza-2'-deoxyguanosine-5'-triphosphate, during the amplification of exon 2 by PCR allowed for the elimination of recurrent artifacts obtained during sequencing of the amplified DNA by the dideoxyribonucleotide chain termination method.     

Rapid amplification of genomic ends (RAGE) as a simple method to clone flanking genomic DNA

This report describes the amplification of upstream genomic sequences using the polymerase chain reaction (PCR) based solely on downstream DNA information from a cDNA clone. In this novel and rapid technique, genomic DNA (gDNA) is first incubated with a restriction enzyme that recognizes a site within the 5′ end of a gene, followed by denaturation and polyadenylation of its free 3′ ends with terminal transferase. The modified gDNA is then used as template for PCR using a gene-specific primer complementary to a sequence in the 3′ end of its cDNA and an anchored deoxyoligothymidine primer. A second round of PCR is then performed with a second, nested gene-specific primer and the anchor sequence primer. The resulting PCR product is cloned and its sequence determined. Three independent plant genomic clones were isolated using this method that exhibited complete sequence identity to their cDNAs and to the primers used in the amplification.     

Preliminary development of a diagnostic test for Brucella using polymerase chain reaction

A highly sensitive and specific diagnostic test for Brucella based on polymerase chain reaction is under development in our laboratory. A commercially available PCR kit was used to create primers that allowed the amplification of a 635 bp fragment of a 43 kDa outer membrane protein gene from Brucella abortus strain 19. We successfully amplified the cloned gene present in the pMS64 plasmid and genomic Brucella S19 DNA. The amplified DNA was easily detected by agarose gel electrophoresis. Using both the pMS64 plasmid and Br. abortus S19 purified DNA as template each component of the PCR reaction was adjusted for the optimum amplification of the DNA sequence. Optimum specific amplification resulted when the primer annealing temperature was 60C. The gene fragment was amplifiable in 25 different Brucella species and strains. To test the specificity of the reaction, DNA extracted from 17 micro-organisms possibly associated with cattle were tested. No amplification was observed. The sensitivity of the reaction was determined with different concentrations of genomic Brucella strain 19 DNA. As little as 0.1 pg DNA (less than 100 brucella cells) could be detected. The specificity and sensitivity of PCR combined with its simplicity and speed suggests the potential of this technique for routine diagnosis of brucellosis.     

Advantages and disadvantages of using PCR techniques to characterize transgenic plants

The polymerase chain reaction (PCR) revolutionized molecular biology to a similar extent as the discovery of plasmids and restriction endonucleases. However, there are some limitations to the use of PCR. Transgenic plants containing potato spindle tuber viroid (PSTVd) cDNA constructs, demonstrated to become de novo methylated upon PSTVd infection, represent a good example to illustrate the advantages of PCR. PSTVd is a 359 nt long autonomously replicating plant pathogenic RNA where all of its enzymatic requirements are entirely provided by the host cell. In addition, viroids that propagate without a DNA intermediate barely tolerate nucleotide substitutions of their RNA genome without losing infectivity. PCR is the method of choice to characterize the sequence context of genome-integrated viroid cDNA or of reverse transcribed PSTVd RNA, and can hardly be replaced by any alternative procedure. Furthermore, the precise examination of DNA methylation patterns (genomic sequencing) is entirely dependent on PCR. In contrast, the use of PCR is critical for the determination of copy number and arrangement of transgene constructs. Here, the advantages and disadvantages of PCR are discussed and protocols for PCR amplification of cDNA, genomic DNA, and bisulfite-treated DNA from transgenic plants are presented.     

Rapid identification of Rhizobium strains by targeted PCR fingerprinting

Numerous polymerase chain reaction (PCR) based procedures are routinely used to produce genomic fingerprints of prokaryotes. Many of them have drawbacks however such as sensitivity to experimental variation, lack of reproducibility, poor resolution and the inability to distinguish between closely related strains. To overcome these difficulties, we developed an alternative procedure, Targeted PCR Fingerprinting (TPF) which is based upon the amplification of few but carefully selected markers, followed by high resolution RFLP analysis of the amplified DNA fragments. In contrast to most fingerprinting protocols that use low resolution agarose gels, TPF patterns are produced on denaturing polyacrylamide gels which allow the precise recording of the genomic fingerprints. TPF analysis, which can simultaneously process 96 samples in less than 12 h and remains unaffected by slight experimental variations, is particularly adapted for the rapid identification of target strains amongst many field isolates. Using PCR primers specific for the nifH and recA genes, this procedure was also sufficiently sensitive to discriminate between Rhizobium species NGR234 and R. fredii USDA257, two closely related bacteria in which the symbiotic loci are 98% homologous. Interestingly, comparison of several of their symbiotic genes as well as the partial DNA sequences of their 16S rDNA and recA genes suggest that chromosomes and symbiotic plasmids did not co-evolve, but that symbiotic functions were acquired by lateral gene transfer long after NGR234 and USDA257 diverged from their common ancestors. In this respect, TPF fingerprints produced with distinct chromosomal and plasmid born markers, such as the recA and the nifH genes in NGR234 and USDA257, are probably more likely to detect lateral transfer of genes in bacterial field-populations than procedures relying on the amplification of numerous fragments of unknown genomic position and biological function.