Haplotyping using a combination of polymerase chain reaction–single-strand conformational polymorphism analysis and haplotype-specific PCR amplification

A single nucleotide polymorphism (SNP) may have an impact on phenotype, but it may also be influenced by multiple SNPs within a gene; hence, the haplotype or phase of multiple SNPs needs to be known. Various methods for haplotyping SNPs have been proposed, but a simple and cost-effective method is currently unavailable. Here we describe a haplotyping approach using two simple techniques: polymerase chain reaction–single-strand conformational polymorphism (PCR–SSCP) and haplotype-specific PCR. In this approach, individual regions of a gene are analyzed by PCR–SSCP to identify variation that defines sub-haplotypes, and then extended haplotypes are assembled from the sub-haplotypes either directly or with the additional use of haplotype-specific PCR amplification. We demonstrate the utility of this approach by haplotyping ovine FABP4 across two variable regions that contain seven SNPs and one indel. The simplicity of this approach makes it suitable for large-scale studies and/or diagnostic screening.     

Clonal polymerase chain reaction-single-strand conformational polymorphism analysis: an effective approach for identifying cloned sequences

The amplification of target sequences from genomic DNA can result in more than one amplicon sequence being produced even when highly specific primers are used. Here we present a clonal polymerase chain reaction-single-strand conformational polymorphism (PCR-SSCP) approach for screening cloned amplicons and identifying particular clones prior to sequence determination. Comparison of the PCR-SSCP patterns of the cloned amplicons with the PCR-SSCP patterns observed for the DNA templates from which the clones were derived allows PCR artifacts, different alleles, and even different loci to be differentiated prior to sequencing. Using this approach, the number of clones required for reliable sequence determination is minimized, and complex “mixed” amplicons can be resolved easily, cost-effectively, and reliably.     

Allelic Variation in the Porcine MYF5 Gene Detected by PCR–SSCP

The MYF5 gene has been reported to be integral to muscle growth and development, and hence it has been considered as a candidate gene for meat selection programs in pig. To ascertain whether there was variation in the porcine MYF5 gene, we have developed a method of PCR–single-strand conformational polymorphism (PCR–SSCP) analysis. In this study, two coding regions of the MYF5 gene were investigated. Four unique SSCP patterns were detected in exon 1 and three patterns were identified in exon 3. Two SNPs detected in exon 1 led to a non-synonymous alanine/proline substitution. A nucleotide change in exon 3 did not affect the amino acid sequence. Five extended haplotypes were observed across the two regions. The variation detected in this study might underpin the development of gene markers for improved muscle growth in pig breeding.     

SNP exploring in the middle and terminal regions of the IGF-1 gene and association with production and reproduction traits in Holstein cattle

Five primer sets were designed in order to identify single nucleotide polymorphisms (SNPs) in middle and terminal exons (2 to 6) and in some flanking intronic regions of the bovine insulin-like growth factor 1 (IGF-1) gene. Sequencing results of PCR products for 10% of animals showed no variant in exons but a SNP at intron 4 was occurred. Both polymerase chain reaction–restriction fragment length polymorphism (PCR–RFLP) and high resolution melting (HRM) methods were developed to genotype samples. The PCR–RFLP results showed the presence of three fragments on agarose gel for the C allele due to two cleavage sites while two fragments for the T allele were observed. Melting curves of 123 bp fragments in HRM analysis showed a difference between temperature melting (T_m) of two homozygous genotypes as the CC genotypes had higher T_m than the TT genotypes. Melting curve of the CT genotype was different and crossed two parallel patterns of homozygous genotypes. The frequencies of the CC, CT and TT genotypes were 0.6, 0.37 and 0.03, respectively. Also, the estimated allele frequencies were 0.785 and 0.215 for the C and T alleles, respectively. Results showed higher accuracy of the HRM analysis compared to the PCR–RFLP method. Least square means (LSMs) comparison of the different genotypes in the SNP showed significant association with milk fat yield trait in the first lactation and open days after the second calving. The polymorphism did not have a significant effect on other milk production or reproduction traits. It seems that other variants or QTLs known in this region underlie genetic variation in the production and reproduction of dairy cattle.     

Mitochondrial DNA polymorphisms in Phytophthora infestans: New haplotypes are identified and re-defined by PCR

Polymorphisms of mitochondrial DNA (mt-DNA) are particularly useful for monitoring specific pathogen populations like Phytophthora infestans. Basically type I and II of P. infestans mt-DNA were categorized by means of polymorphism lengths caused by an ~ 2 kb insertion, which can be detected via restriction enzyme digestion. In addition genome sequencing of haplotype Ib has been used as a simple Polymerase Chain Reaction–Restriction Fragment Length Polymorphism (PCR–RFLP) method to indirectly identify type I and II alterations through EcoR I restriction enzyme DNA fragment patterns of the genomic P4 area. However, with the common method, wrong mt-DNA typing occurs due to an EcoR I recognition site mutation in the P4 genomic area. Genome sequencing of the four haplotypes (Ia, Ib, IIa, and IIb) allowed us to thoroughly examine mt-DNA polymorphisms and we indentified two hypervariable regions (HVRs) named HVRi and HVRii. The HVRi length polymorphism caused by a 2 kb insertion/deletion was utilized to identify mt-DNA types I and II, while another length polymorphism in the HVRii region is caused by a variable number of tandem repeats (n = 1, 2, or 3) of a 36 bp sized DNA stretch and was further used to determine mt-DNA sub-types, which were described as R_{n=1, 2, or 3}. Finally, the P. infestans mt-DNA haplotypes were re-defined as IR₁ or IIR₂ according to PCR derived HVRi and HVRii length polymorphisms. Twenty-three isolates were chosen to verify the feasibility of our new approach for identifying mt-DNA haplotypes and a total of five haplotypes (IR₁, IR₂, IR₃, IIR₂ and IIR₃) were identified. Additionally, we found that six isolates determined as type I by our method were mistakenly identified as type II by the PCR–RFLP technique. In conclusion, we propose a simple and rapid PCR method for identification of mt-DNA haplotypes based on sequence analyses of the mitochondrial P. infestans genome.     

Identification of single-point mutations in mycobacterial 16S rRNA sequences by confocal single-molecule fluorescence spectroscopy

We demonstrate the specific identification of single nucleotide polymorphism (SNP) responsible for rifampicin resistance of Mycobacterium tuberculosis applying fluorescently labeled DNA-hairpin structures (smart probes) in combination with single-molecule fluorescence spectroscopy. Smart probes are singly labeled hairpin-shaped oligonucleotides bearing a fluorescent dye at the 5′ end that is quenched by guanosine residues in the complementary stem. Upon hybridization to target sequences, a conformational change occurs, reflected in a strong increase in fluorescence intensity. An excess of unlabeled (‘cold’) oligonucleotides was used to prevent the formation of secondary structures in the target sequence and thus facilitates hybridization of smart probes. Applying standard ensemble fluorescence spectroscopy we demonstrate the identification of SNPs in PCR amplicons of mycobacterial rpoB gene fragments with a detection sensitivity of 10⁻⁸ M. To increase the detection sensitivity, confocal fluorescence microscopy was used to observe fluorescence bursts of individual smart probes freely diffusing through the detection volume. By measuring burst size, burst duration and fluorescence lifetime for each fluorescence burst the discrimination accuracy between closed and open (hybridized) smart probes could be substantially increased. The developed technique enables the identification of SNPs in 10⁻¹¹ M solutions of PCR amplicons from M.tuberculosis in only 100 s.     

Post-amplification Klenow fragment treatment alleviates PCR bias caused by partially single-stranded amplicons

Partially single-stranded amplicons, formed during PCR amplification of single and mixed templates, are a potential source of bias in genetic diversity studies. The analysis of 16S rRNA gene diversity in mixed template samples by the fingerprinting technique terminal restriction fragment length polymorphism (T-RFLP) analysis can be biased by the occurrence of pseudo-T-RFs, i.e., restriction fragments occurring in addition to the expected terminal restriction fragments of single amplicons. This bias originates from PCR products, which are single-stranded at their terminal restriction site. Here we show that treatment of PCR amplicons with Klenow fragment prior to restriction digest and T-RFLP analysis minimized effectively the occurrence of pseudo-T-RFs. Klenow fragment activity filled in bases into the partially single-stranded amplicons and thereby restored the affected amplicons to complete double strands. Our method allowed to improve the assessment of genetic diversity and gene ratios from T-RFLP analysis of an original environmental sample. Since partially single-stranded amplicons might influence many PCR-based techniques, post-amplification treatment with Klenow fragment may be useful for a wide range of applications, which assess the composition of amplicon pools, e.g., the analysis of marker gene diversity in mixed template samples by fingerprinting techniques or the analysis of sequence diversity by cloning.     

Rapid genotyping of the osteoporosis-associated polymorphic transcription factor Sp1 binding site in the COL1A1 gene by pyrosequencing

We describe a novel polymerase chain reaction (PCR) and deoxyribonucleic acid (DNA) sequencingbased assay for rapid genotyping of the polymorphic Sp1 binding site in the COL1A1 gene (1). A single nucleotide G-->T substitution polymorphism at this GC-rich site has recently been reported to be a predictive genetic marker for low bone mineral density (BMD). To simplify screening for this marker, we optimized PCR conditions and subjected the amplicons to pyrosequencing, which is a convenient high-throughput sequence analysis technique, readily amenable to automation. The analysis of 200 deidentified convenience DNA samples extracted from blood revealed genotype frequences in Hardy-Weinberg equilibrium (SS 68.0%, Ss 28.5%, and ss 3.5%) in agreement with other studies of European populations. This study demonstrates for the first time that pyrosequencing can be used for rapid identification of the osteoporosis-associated single nucleotide polymorphism (SNP) in the COL1A1 gene.     

Polymerase chain reaction–hybridization method using urease gene sequences for high-throughput Ureaplasma urealyticum and Ureaplasma parvum detection and differentiation

In this article, we discuss the polymerase chain reaction (PCR)–hybridization assay that we developed for high-throughput simultaneous detection and differentiation of Ureaplasma urealyticum and Ureaplasma parvum using one set of primers and two specific DNA probes based on urease gene nucleotide sequence differences. First, U. urealyticum and U. parvum DNA samples were specifically amplified using one set of biotin-labeled primers. Furthermore, amine-modified DNA probes, which can specifically react with U. urealyticum or U. parvum DNA, were covalently immobilized to a DNA–BIND plate surface. The plate was then incubated with the PCR products to facilitate sequence-specific DNA binding. Horseradish peroxidase–streptavidin conjugation and a colorimetric assay were used. Based on the results, the PCR–hybridization assay we developed can specifically differentiate U. urealyticum and U. parvum with high sensitivity (95%) compared with cultivation (72.5%). Hence, this study demonstrates a new method for high-throughput simultaneous differentiation and detection of U. urealyticum and U. parvum with high sensitivity. Based on these observations, the PCR–hybridization assay developed in this study is ideal for detecting and discriminating U. urealyticum and U. parvum in clinical applications.     

Low levels of DNA sequence variation among adapted genotypes of hexaploid wheat

 PCR products from regions corresponding to sequences hybridising to wheat RFLP probes were sequenced in order to establish the level of DNA sequence variation among adapted wheat genotypes. Hexaploid bread wheat shows a very low rate of nucleotide polymorphism, approximately 1 polymorphic nucleotide per 1000 basepairs. Differences in PCR product length can be exploited to design genome-specific amplicons, which may have use in gene tagging or in diagnostic applications. Interpretation of results may be complicated by the simultaneous amplification of orthologous and paralogous sequences. These findings have significant implications for the use of STS markers in wheat and other polyploid species. Received: 3 October 1998 / Accepted: 28 November 1998     

Detection and discrimination of Loa loa, Mansonella perstans and Wuchereria bancrofti by PCR–RFLP and nested-PCR of ribosomal DNA ITS1 region

The ribosomal deoxyribonucleic acid (DNA) internal transcribed spacer region (ITS1) of two filarial nematodes, Loa loa and Mansonella perstans, was amplified and further sequenced to develop an species-specific polymerase chain reaction–restriction fragment length polymorphism (PCR–RFLP) protocol for the differentiation of both species from Wuchereria bancrofti, three filarial nematodes with blood circulating microfilariae. The ITS1–PCR product digested with the restriction endonuclease Ase I generated an specific diagnostic pattern for each of the three species. Moreover, three new specific nested-PCRs, targeting the ITS1 region, for differential detection of L. loa, M. perstans and W. bancrofti were developed and used when the ITS1–PCR products were insufficient for the Ase I enzymatic digestion. These filarial species-specific molecular protocols were evaluated in forty blood samples from African adult immigrants attending in the Hospital Insular of Gran Canaria, Canarias, Spain.     

Formation of Pseudo-Terminal Restriction Fragments, a PCR-Related Bias Affecting Terminal Restriction Fragment Length Polymorphism Analysis of Microbial Community Structure

Terminal restriction fragment length polymorphism (T-RFLP) analysis of PCR-amplified genes is a widely used fingerprinting technique in molecular microbial ecology. In this study, we show that besides expected terminal restriction fragments (T-RFs), additional secondary T-RFs occur in T-RFLP analysis of amplicons from cloned 16S rRNA genes at high frequency. A total of 50% of 109 bacterial and 78% of 68 archaeal clones from the guts of cetoniid beetle larvae, using MspI and AluI as restriction enzymes, respectively, were affected by the presence of these additional T-RFs. These peaks were called “pseudo-T-RFs” since they can be detected as terminal fluorescently labeled fragments in T-RFLP analysis but do not represent the primary terminal restriction site as indicated by sequence data analysis. Pseudo-T-RFs were also identified in T-RFLP profiles of pure culture and environmental DNA extracts. Digestion of amplicons with the single-strand-specific mung bean nuclease prior to T-RFLP analysis completely eliminated pseudo-T-RFs. This clearly indicates that single-stranded amplicons are the reason for the formation of pseudo-T-RFs, most probably because single-stranded restriction sites cannot be cleaved by restriction enzymes. The strong dependence of pseudo-T-RF formation on the number of cycles used in PCR indicates that (partly) single-stranded amplicons can be formed during amplification of 16S rRNA genes. In a model, we explain how transiently formed secondary structures of single-stranded amplicons may render single-stranded amplicons accessible to restriction enzymes. The occurrence of pseudo-T-RFs has consequences for the interpretation of T-RFLP profiles from environmental samples, since pseudo-T-RFs may lead to an overestimation of microbial diversity. Therefore, it is advisable to establish 16S rRNA gene sequence clone libraries in parallel with T-RFLP analysis from the same sample and to check clones for their in vitro digestion T-RF pattern to facilitate the detection of pseudo-T-RFs.     

Identification of the ovine KAP11-1 gene (<Emphasis Type="Italic">KRTAP11</Emphasis>-<Emphasis Type="Italic">1</Emphasis>) and genetic variation in its coding sequence

Keratin-associated proteins (KAPs) are a structural component of the wool fibre and form the matrix between the keratin intermediate filaments (KIFs). The gene encoding high sulphur-protein KAP11-1 has been identified in human, cattle and mouse, but not yet in sheep, despite the economic importance of wool. In this study, PCR using primers based on the cattle KAP11-1 gene sequence produced an amplicon of the expected size with sheep DNA. Upon using PCR–Single Stranded Conformational Polymorphism (PCR–SSCP) analysis in 260 sheep, six different PCR–SSCP patterns were detected. Either one or a combination of two banding patterns was observed for each sheep, suggesting they were either homozygous or heterozygous for this gene. Sequencing of the amplicons confirmed the occurrence of six DNA sequences. All of these were unique, and the greatest homology was with KRTAP11-1 sequences from cattle, human and mouse, suggesting that they were derived from the ovine KAP11-1 gene and were allelic variants. The ovine KAP11-1 gene had an open reading frame of 477 nucleotides encoding 159 amino acids. The putative protein was rich in serine, cysteine, and threonine which account for 18.2–18.9, 12.6 and 12.0 mol%, respectively. Of these, approximately 20 of the serine and threonine residues might be phosphorylated. Five nucleotide substitutions were identified, and one was non-synonymous and would result in an amino acid change at a potential phosphorylation site. The genetic variation found in KRTAP11-1 may influence its expression, protein structure, and/or post-translational modifications, and consequently affect wool fibre structure and wool traits.     

Headloop suppression PCR and its application to selective amplification of methylated DNA sequences

Selective amplification in PCR is principally determined by the sequence of the primers and the temperature of the annealing step. We have developed a new PCR technique for distinguishing related sequences in which additional selectivity is dependent on sequences within the amplicon. A 5′ extension is included in one (or both) primer(s) that corresponds to sequences within one of the related amplicons. After copying and incorporation into the PCR product this sequence is then able to loop back, anneal to the internal sequences and prime to form a hairpin structure—this structure is then refractory to further amplification. Thus, amplification of sequences containing a perfect match to the 5′ extension is suppressed while amplification of sequences containing mismatches or lacking the sequence is unaffected. We have applied Headloop PCR to DNA that had been bisulphite-treated for the selective amplification of methylated sequences of the human GSTP1 gene in the presence of up to a 10⁵-fold excess of unmethylated sequences. Headloop PCR has a potential for clinical application in the detection of differently methylated DNAs following bisulphite treatment as well as for selective amplification of sequence variants or mutants in the presence of an excess of closely related DNA sequences.     

Formation of pseudo-terminal restriction fragments,a PCR-related bias affecting terminal restriction fragment length polymorphism analysis of microbial community structure

Terminal restriction fragment length polymorphism (T-RFLP) analysis of PCR-amplified genes is a widely used fingerprinting technique in molecular microbial ecology. In this study, we show that besides expected terminal restriction fragments (T-RFs), additional secondary T-RFs occur in T-RFLP analysis of amplicons from cloned 16S rRNA genes at high frequency. A total of 50% of 109 bacterial and 78% of 68 archaeal clones from the guts of cetoniid beetle larvae, using MspI and AluI as restriction enzymes, respectively, were affected by the presence of these additional T-RFs. These peaks were called "pseudo-T-RFs" since they can be detected as terminal fluorescently labeled fragments in T-RFLP analysis but do not represent the primary terminal restriction site as indicated by sequence data analysis. Pseudo-T-RFs were also identified in T-RFLP profiles of pure culture and environmental DNA extracts. Digestion of amplicons with the single-strand-specific mung bean nuclease prior to T-RFLP analysis completely eliminated pseudo-T-RFs. This clearly indicates that single-stranded amplicons are the reason for the formation of pseudo-T-RFs, most probably because single-stranded restriction sites cannot be cleaved by restriction enzymes. The strong dependence of pseudo-T-RF formation on the number of cycles used in PCR indicates that (partly) single-stranded amplicons can be formed during amplification of 16S rRNA genes. In a model, we explain how transiently formed secondary structures of single-stranded amplicons may render single-stranded amplicons accessible to restriction enzymes. The occurrence of pseudo-T-RFs has consequences for the interpretation of T-RFLP profiles from environmental samples, since pseudo-T-RFs may lead to an overestimation of microbial diversity. Therefore, it is advisable to establish 16S rRNA gene sequence clone libraries in parallel with T-RFLP analysis from the same sample and to check clones for their in vitro digestion T-RF pattern to facilitate the detection of pseudo-T-RFs.     

Identification of Allelic Polymorphism in the Ovine Leptin Gene

Leptin is an adipocyte-derived hormone/cytokine that influences the physiological control of numerous biological functions and links nutritional status with both neuroendocrine and immune functions. In livestock, variation in the leptin (LEP) gene has been characterized in cattle and pig, but it has not been reported in sheep. In this study, variation in the exon 3 coding sequence of the ovine LEP gene was investigated by polymerase chain reaction–single-strand conformational polymorphism (PCR–SSCP) analysis and DNA sequencing. Five novel SSCP patterns, representing five different sequences, were identified under a combination of two different electrophoresis conditions. Either one or two different sequences were detected in individual sheep and all the sequences identified shared high homology with the LEP sequences from a variety of species, suggesting that these sequences represent alleles of the ovine LEP gene. Four single nucleotide polymorphisms (SNPs) were detected, and three of these resulted in amino acid changes. Variation detected here might have an impact on leptin activity and function.     

Single-strand conformation polymorphism (SSCP) for the analysis of genetic variation

The accurate analysis of genetic variation has major implications in many areas of biomedical research, including the identification of infectious agents (such as parasites), the diagnosis of infections, and the detection of unknown or known disease-causing mutations. Mutation scanning methods, including PCR-coupled single-strand conformation polymorphism (SSCP), have significant advantages over many other nucleic acid techniques for the accurate analysis of allelic and mutational sequence variation. The present protocol describes the SSCP method of analysis, including all steps from the small-scale isolation of genomic DNA and PCR amplification of target sequences, through to the gel-based separation of amplicons and scanning for mutations by SSCP (either by the analysis of radiolabeled amplicons in mutation detection enhancement (MDE) gels or by non-isotopic SSCP using precast GMA gels). The subsequent sequence analysis of polymorphic bands isolated from gels is also detailed. The SSCP protocol can readily detect point mutations for amplicon sizes of up to 450-500 bp, and usually takes 1-2 days to carry out. This user-friendly, low-cost, potentially high-throughput platform has demonstrated the utility to study a wide range of pathogens and diseases, and has the potential to be applied to any gene of any organism.     

Consensus multiplex PCR–restriction fragment length polymorphism (RFLP) for rapid detection of plant mitochondrial DNA polymorphism

A fast, simple, and efficient approach, termed consensus multiplex PCR–RFLP, was developed and employed to detect mitochondrial (mt)DNA variation in three orchid species, Spiranthes hongkongensis, S. sinensis , and S. spiralis . Using multiplex PCR, three pairs of consensus mitchondrial primers were added simultaneously into each reaction tube to amplify three nonoverlapping introns located in the NADH dehydrogenase genes. Fragment length differences in the multiplex PCR amplicons were directly detectable between S. spiralis and the other two species. Further restriction analysis of the multiplex PCR amplicons revealed sufficient mtDNA polymorphism, suitable for phylogenetic studies at the interspecific level. This approach is well suited for large-scale population surveys of mitochondrial genome diversity in plants. Additionally, the maternal mode of inheritance of organelle genomes renders this approach valuable for rapid identification of the origin and specific parentage of hybrid or allopolyploid species.     

Analysis of the BglI restriction fragment length polymorphism in the human factor VIII gene using “virtual PCR”– a novel approach employing the polymerase chain reaction in the absence of sequence information for the locus

The BglI restriction fragment length polymorphism (RFLP) of the human factor VIII (FVIII) gene is potentially useful in linkage studies in haemophilia A. The sequence at the RFLP locus is not known, therefore it is not amenable to analysis by the polymerase chain reaction (PCR) and Southern blotting is required. We present a novel approach for analysis of the BglI RFLP using the PCR targeted to known sequence downstream in exon 26 of the FVIII gene. Briefly, the size of the genomic restriction fragment carrying the PCR target depends upon whether the RFLP site is present or absent. If fragments of the required size are isolated from a genomic digest and used as substrates in the exon 26 PCR, the generation of a product in one or other fraction indicates the upstream RFLP status. We have called this approach “virtual PCR”, since PCR is used to obtain information about the RFLP without amplifying the locus itself. Received: 23 January 1996 / Revised: 18 March 1996     

Utilization of a set of high-polymorphism DAMD markers for genetic analysis of a cucumber germplasm collection

Eighteen minisatellite core sequences, derived from rice, human and phage M13, were used as primers in a PCR technique, known as directed amplification of minisatellite-region DNA (DAMD), to genotype 19 cucumber (Cucumis sativus L.) accessions from a wide collection. All the primers amplified polymorphic bands across the accessions. Out of 165 bands scored, 129 were polymorphic with 78.2% polymorphism. The average of polymorphism information content of the primers was 0.844, revealing a high discrimination power in cucumber. Based on Jaccard’s similarity indices and matrix generated by the DAMD markers, a dendrogram was constructed using the unweighted pair group method using arithmetic averages and allowed for separation of the 19 accessions into four distinct groups which demonstrated genetic relationship among the different types of germplasms. Sequencing of six polymorphic amplicons resulted in the identification of only one minisatellite locus, which indicated that variation in minisatellite number was not always the factor underlying DAMD polymorphism.