A critique of avian CHD‐based molecular sexing protocols illustrated by a Z‐chromosome polymorphism detected in auklets

The sexes of non‐ratite birds can be determined routinely by PCR amplification of the CHD‐Z and CHD‐W genes. CHD‐based molecular sexing of four species of auklets revealed the presence of a polymorphism in the Z chromosome. No deviation from a 1:1 sex ratio was observed among the chicks, though the analyses were of limited power. Polymorphism in the CHD‐Z gene has not been reported previously in any bird, but if undetected it could lead to the incorrect assignment of sex. We discuss the potential difficulties caused by a polymorphism such as that identified in auklets and the merits of alternative CHD‐based sexing protocols and primers.     

Heteroduplex molecules cause sexing errors in a standard molecular protocol for avian sexing

Molecular methods are a necessary tool for sexing monomorphic birds. These molecular approaches are usually reliable, but sexing protocols should be evaluated carefully because biochemical interactions may lead to errors. We optimized laboratory protocols for genetic sexing of a monomorphic shorebird, the upland sandpiper (Bartramia longicauda), using two independent sets of primers, P2/P8 and 2550F/2718R, to amplify regions of the sex‐linked CHD‐Z and CHD‐W genes. We discovered polymorphisms in the region of the CHD‐Z intron amplified by the primers P2/P8 which caused four males to be misidentified as females (n = 90 mated pairs). We cloned and sequenced one CHD‐W allele (370 bp) and three CHD‐Z alleles in our population: Z° (335 bp), Z′ (331 bp) and Z″ (330 bp). Normal (Z°Z°) males showed one band in agarose gel analysis and were easily differentiated from females (Z°W), which showed two bands. However, males heterozygous for CHD‐Z alleles (Z′Z″) unexpectedly showed two bands in a pattern similar to females. While the Z′ and Z″ fragments contained only short deletions, they annealed together during the polymerase chain reaction (PCR) process and formed heteroduplex molecules that were similar in size to the W fragment. Errors previously reported for molecular sex‐assignment have usually been due to allelic dropout, causing females to be misidentified as males. Here, we report evidence that events in PCRs can lead to the opposite error, with males misidentified as females. We recommend use of multiple primer sets and large samples of known‐sex birds for validation when designing protocols for molecular sex analysis.     

Rapid sex determination of a wild passerine species using loop‐mediated isothermal amplification (LAMP)

Many bird species are sexually monomorphic and cannot be sexed based on phenotypic traits. Rapid sex determination is often a necessary component of avian studies focusing on behavior, ecology, evolution, and conservation. While PCR‐based methods are the most common technique for molecularly sexing birds in the laboratory, a simpler, faster, and cheaper method has emerged, which can be used in the laboratory, but importantly also in the field. Herein, we used loop‐mediated isothermal amplification (LAMP) for rapid sex determination of blood samples from juvenile European blackcaps, Sylvia atricapilla, sampled in the wild. We designed LAMP primers unique to S. atricapilla based on the sex chromosome‐specific gene, chromo‐helicase‐DNA‐binding protein (CHD), optimized the primers for laboratory and field application, and then used them to test a subset of wild‐caught juvenile blackcaps of unknown gender at the time of capture. Sex determination results were fast and accurate. The advantages of this technique are that it allows researchers to identify the sex of individual birds within hours of sampling and eliminates the need for direct access to a laboratory if implemented at a remote field site. This work adds to the increasing list of available LAMP primers for different bird species and is a new addition within the Passeriformes order.     

Distinguishing Anuran species by high‐resolution melting analysis of the COI barcode (COI‐HRM)

Taxonomic identification can be difficult when two or more species appear morphologically similar. DNA barcoding based on the sequence of the mitochondrial cytochrome c oxidase 1 gene (COI) is now widely used in identifying animal species. High‐resolution melting analysis (HRM) provides an alternative method for detecting sequence variations among amplicons without having to perform DNA sequencing. The purpose of this study was to determine whether HRM of the COI barcode can be used to distinguish animal species. Using anurans as a model, we found distinct COI melting profiles among three congeners of both Lithobates spp. and Hyla spp. Sequence variations within species shifted the melting temperature of one or more melting domains slightly but do not affect the distinctness of the melting profiles for each species. An NMDS ordination plot comparing melting peak profiles among eight Anuran species showed overlapping profiles for Lithobates sphenocephala and Gastrophryne carolinensis. The COI amplicon for both species contained two melting domains with melting temperatures that were similar between the two species. The two species belong to two different families, highlighting the fact that COI melting profiles do not reveal phylogenetic relationships but simply reflect DNA sequence differences among stretches of DNA within amplicons. This study suggests that high‐resolution melting analysis of COI barcodes (COI‐HRM) may be useful as a simple and rapid method to distinguish animal species that appear morphologically similar.     

A novel method of caenophidian snake sex identification using molecular markers based on two gametologous genes

Sex identification provides important information for ecological and evolutionary studies, as well as benefiting snake conservation management. Traditional methods such as cloacal probing or cloacal popping are counterproductive for sex identification concerning very small species, resulting in difficulties in the management of their breeding programs. In this study, the nucleotide sequences of gametologous genes (CTNNB1 and WAC genes) were used for the development of molecular sexing markers in caenophidian snakes. Two candidate markers were developed with the two primer sets, and successfully amplified by a single band on the agarose gel in male (ZZ) and two bands, differing in fragment sizes, in female (ZW) of 16 caenophidian snakes for CTNNB1 and 12 caenophidian snakes for WAC. Another candidate marker was developed with the primer set to amplify the specific sequence for CTNNB1W homolog, and the PCR products were successfully obtained in a female‐specific 250‐bp DNA bands. The three candidate PCR sexing markers provide a simple sex identification method based on the amplification of gametologous genes, and they can be used to facilitate effective caenophidian snake conservation and management programs.     

Rapid identification of chloroplast haplotypes using High Resolution Melting analysis

We have evaluated High Resolution Melting (HRM) analysis as a method for one‐step haplotype identification in phylogeographic analysis. Using two adjoined internal amplicons (c. 360 and 390 bp) at the chloroplast rps16 intron (c. 750 bp) we applied HRM to identify haplotypes in 21 populations of two European arctic‐alpine herb species Arenaria ciliata and Arenaria norvegica (Caryophyllaceae). From 446 accessions studied, 20 composite rps16 haplotypes were identified by the melting‐curve protocol, 18 of which could be identified uniquely. In a comparative sensitivity analysis with in silico PCR‐RFLP, only seven of these 20 haplotypes could be identified uniquely. Observed in vitro experimental HRM profiles were corroborated by in silico HRM analysis generated on uMelt^SM. In silico mutation analysis carried out on a 360 bp wild‐type rps16I amplicon determined that the expected rate of missed single‐nucleotide polymorphisms (SNP) detection in vitro was similar to existing evaluations of HRM sensitivity, with transversion SNPs being more likely to go undetected compared to transition SNPs. In vitro HRM successfully discriminated between all amplicon templates differing by two or more base changes (352 cases) and between 11 pairs of amplicons where the only difference was a single transition or transversion SNP. Only one pairwise comparison yielded no discernable HRM curve difference between haplotypes, and these samples differed by one transversion (C/G) SNP. HRM analysis represents an untapped resource in phylogeographic analysis, and with appropriate primer design any polymorphic locus is potentially amenable to this single‐reaction method for haplotype identification.     

Rapid differentiation of bacterial species by high resolution melting curve analysis

Molecular based differentiation of various bacterial species is important in phylogenetic studies, diagnostics and epidemiological surveillance, particularly where unusual phenotype makes the classical phenotypic identification of bacteria difficult. Molecular approach based on the sequence of 16S ribosomal RNA gene analysis can achieve fast and reliable identification of bacteria. High resolution melting (HRM) curve analysis has been developed as an attractive novel technique for DNA sequence discrimination but it’s application for bacteria differentiation has not been well studied yet. We have developed HRM assay for differentiation of sixteen pathogenic or opportunistic bacterial species. Amplified partial 16S ribosomal RNA gene region between 968 and 1401 positions (E. coli reference numbering) was subsequently used in high resolution melting curve analysis of PCR products for bacterial species differentiation. Sixteen bacterial species were simultaneously discerned by difference plot of normalized and temperatures shifted melting curves, without need for spiking of DNA, hetero-duplexing experiments or application of several primer pairs. High resolution melting curve analysis of duplex DNA is simple, fast and reliable tool for bacterial species differentiation and may efficiently complement phenotypic identification of bacteria.     

Sex Determination in 58 Bird Species and Evaluation of CHD Gene as a Universal Molecular Marker in Bird Sexing

The aim of this research was to test the CHD gene (Chromo Helicase DNA‐binding gene) as a universal molecular marker for sexing birds of relatively distant species. The CHD gene corresponds to the aim because of its high degree of conservation and different lengths in Z and W chromosomes due to different intron sizes. DNA was isolated from feathers and the amplification of the CHD gene was performed with the following sets of polymerase chain reaction (PCR) primers: 2550F/2718R and P2/P8. Sex determination was attempted in 284 samples of 58 bird species. It was successful in 50 bird species; in 16 of those (Alopochen aegyptiacus, Ara severus, Aratinga acuticaudata, Bucorvus leadbeateri, Cereopsis novaehollandiae, Columba arquatrix, Corvus corax, C. frugilegus, Cyanoliseus patagonus, Guttera plumifera, Lamprotornis superbus, Milvus milvus, Neophron percnopterus, Ocyphaps lophotes, Podiceps cristatus, and Poicephalus senegalus), it was carried out for the first time using molecular markers and PCR. It is reasonable to assume that extensive research is necessary to define the CHD gene as a universal molecular marker for successful sex determination in all bird species (with exception of ratites). The results of this study may largely contribute to the aim. Zoo Biol 32:269–276, 2013. © 2012 Wiley Periodicals, Inc.     

一种简单通用的鸟类性别分子鉴定技术（简报）

我国幅员辽阔,生物类型多种多样,是世界上拥有鸟类种类最多的国家之一。截至1999年底,已知有鸟类1253种948亚种,隶属于21目83科,其中有多种为我国特有或珍稀濒危的鸟类。近年来由于环境污染、植被破坏及非法捕猎等种种原因,许多鸟类尤其是珍稀鸟类正逐步濒临灭绝。为了加紧     

Molecular Differentiation of Schistosoma japonicum and Schistosoma mekongi by Real-Time PCR with High Resolution Melting Analysis

Human schistosomiasis caused by Schistosoma japonicum and Schistosoma mekongi is a chronic and debilitating helminthic disease still prevalent in several countries of Asia. Due to morphological similarities of cercariae and eggs of these 2 species, microscopic differentiation is difficult. High resolution melting (HRM) real-time PCR is developed as an alternative tool for the detection and differentiation of these 2 species. A primer pair was designed for targeting the 18S ribosomal RNA gene to generate PCR products of 156 base pairs for both species. The melting points of S. japonicum and S. mekongi PCR products were 84.5±0.07℃ and 85.7±0.07℃, respectively. The method permits amplification from a single cercaria or an egg. The HRM real-time PCR is a rapid and simple tool for differentiation of S. japonicum and S. mekongi in the intermediate and final hosts.     

Swine in Biomedical Research: Creating the Building Blocks of Animal Models

Abstract

Sex of preimplantation porcine embryos was determined by DNA amplification using porcine male(Y chromosome)‐specific DNA primers in the polymerase chain reaction (PCR). In order to determine the sensitivity of this sexing method, single porcine embryos ranging from unfertilized ova to the blastocyst stage were amplified in the PCR using the Y‐specific primers, and analyzed by ethidium bromide‐staining of polyacrylamide gels. The 192 bp product which denotes the presence of the Y chromosome was seen in the embryos. The unfertilized ova which is of female origin gave no product. These results are representative of PCR analysis of a total of 34 swine embryos.

Results obtained using the PCR for sexing were validated by karyotyping and confirmed by in situ hybridization with the porcine Y‐chromosome‐specific probe. In order to confirm the sex of the embryos determined by PCR, 10 day‐old porcine preimplantation embryos were biopsied to produce a small number of cells for sex determination via PCR, while the remainder of the embryo was prepared for in situ hybridization using the biotinylated probe. In situ hybridization performed on embryos shown to be male by PCR, showed pinpoint fluorescence within the nuclei, similar to that obtained when male porcine lymphocytes were hybridized. No evidence of fluorescence was seen when in situ hybridization was performed in parallel on embryos determined to be female by the PCR.

The PCR was found to be a relatively fast, accurate and reproducible means of sex determination of swine preimplantation embryos. This capability could have significant impact on animal breeding and production programs by using PCR as a screening tool for traits of economic importance.     

Sex determination in the wild: a field application of loop‐mediated isothermal amplification successfully determines sex across three raptor species

PCR‐based methods are the most common technique for sex determination of birds. Although these methods are fast, easy and accurate, they still require special facilities that preclude their application outdoors. Consequently, there is a time lag between sampling and obtaining results that impedes researchers to take decisions in situ and in real time considering individuals’ sex. We present an outdoor technique for sex determination of birds based on the amplification of the duplicated sex‐chromosome‐specific gene Chromo‐Helicase‐DNA binding protein using a loop‐mediated isothermal amplification (LAMP). We tested our method on Griffon Vulture (Gyps fulvus), Egyptian Vulture (Neophron percnopterus) and Black Kite (Milvus migrans) (family Accipitridae). We introduce the first fieldwork procedure for sex determination of animals in the wild, successfully applied to raptor species of three different subfamilies using the same specific LAMP primers. This molecular technique can be deployed directly in sampling areas because it only needs a voltage inverter to adapt a thermo‐block to a car lighter and results can be obtained by the unaided eye based on colour change within the reaction tubes. Primers and reagents are prepared in advance to facilitate their storage at room temperature. We provide detailed guidelines how to implement this procedure, which is simpler (no electrophoresis required), cheaper and faster (results in c. 90 min) than PCR‐based laboratory methods. Our successful cross‐species application across three different raptor subfamilies posits our set of markers as a promising tool for molecular sexing of other raptor families and our field protocol extensible to all bird species.     

一种简单通用的鸟类性别分子鉴定技术(简报)

我国幅员辽阔,生物类型多种多样,是世界上拥有鸟类种类最多的国家之一。截至1999年底,已知有鸟类1253种948亚种,隶属于21目83科,其中有多种为我国特有或珍稀濒危的鸟类。近年来由于环境污染、植被破坏及非法捕猎等种种原因,许多鸟类尤其是珍稀鸟类正逐步濒临灭绝。为了加紧保护野生鸟类种群,我们对珍稀鸟类采用了人工饲养、交配等手段以提高繁殖率,并已经在部分鸟类中获得成功。但是,在全世界的鸟类中有50%是单态性鸟。他们的性别不论是在幼鸟还是在成鸟时期,都很难     

Use of high resolution melting analysis to genotype the avirulence AvrLm4‐7 gene of Leptosphaeria maculans,a fungal pathogen of Brassica napus

The oilseed rape (Brassica napus) stem canker disease, due to the fungal pathogen Leptosphaeria maculans, is mainly controlled by host genetic resistance. Since 2004, the specific resistance gene Rlm7 is widely used in France. Specific resistance is effective when fungal populations are mainly composed of avirulent isolates. The development of molecular tools for the identification of virulent isolates towards Rlm7 was needed to undertake large‐scale surveys and to monitor the emergence of virulent populations in fields. Previous studies have described a large diversity of molecular events leading to virulence towards Rlm7, rendering conventional polymerase chain reaction (PCR) methods inapplicable to identify virulent isolates. Interestingly, a very limited nucleotide polymorphism was observed for avirulent, AvrLm7, alleles. Such characteristics were exploited here to develop a diagnostic method based on high resolution melting (HRM) analysis of the AvrLm4‐7 gene. High resolution melting analysis of a collection of 206 reference isolates revealed only four different profiles within 100 avirulent isolates and 87% of virulent isolates showed either no amplification or HRM curves distinct from those of avirulent isolates. The reliability of the method was confirmed using a second set of 119 unknown isolates, for which biological phenotyping and HRM genotyping were in agreement for 93% of the isolates. HRM combined with the PCR amplification of a larger fragment encompassing AvrLm4‐7 led to a correct diagnostic for 97.5% of the isolates.     

Arbovirus and insect‐specific virus discovery in Kenya by novel six genera multiplex high‐resolution melting analysis

A broad diversity of arthropod‐borne viruses (arboviruses) of global health concern are endemic to East Africa, yet most surveillance efforts are limited to just a few key viral pathogens. Additionally, estimates of arbovirus diversity in the tropics are likely to be underestimated as their discovery has lagged significantly over past decades due to limitations in fast and sensitive arbovirus identification methods. Here, we developed a nearly pan‐arbovirus detection assay that uses high‐resolution melting (HRM) analysis of RT–PCR products from highly multiplexed assays to differentiate broad diversities of arboviruses. We differentiated 15 viral culture controls and seven additional synthetic viral DNA sequence controls, within Flavivirus, Alphavirus, Nairovirus, Phlebovirus, Orthobunyavirus and Thogotovirus genera. Among Bunyamwera, sindbis, dengue and Thogoto virus serial dilutions, detection by multiplex RT–PCR‐HRM was comparable to the gold standard Vero cell plaque assays. We applied our low‐cost method for enhanced broad‐range pathogen surveillance from mosquito samples collected in Kenya and identified diverse insect‐specific viruses, including a new clade in anopheline mosquitoes, and Wesselsbron virus, an arbovirus that can cause viral haemorrhagic fever in humans and has not previously been isolated in Kenya, in Culex spp. and Anopheles coustani mosquitoes. Our findings demonstrate how multiplex RT–PCR‐HRM can identify novel viral diversities and potential disease threats that may not be included in pathogen detection panels of routine surveillance efforts. This approach can be adapted to other pathogens to enhance disease surveillance and pathogen discovery efforts, as well as the study of pathogen diversity and viral evolutionary ecology.     

Sex Identification of Four Penguin Species Using Locus‐Specific PCR

Traditional methods for sex identification are not applicable to sexually monomorphic species, leading to difficulties in the management of their breeding programs. To identify sex in sexually monomorphic birds, molecular methods have been established. Two established primer pairs (2550F/2718R and p8/p2) amplify the CHD1 gene region from both the Z and W chromosomes. Here, we evaluated the use of these primers for sex identification in four sexually monomorphic penguin species: king penguins (Aptenodytes patagonicus), rockhopper penguins (Eudyptes chrysocome), gentoo penguins (Pygoscelis papua), and Magellanic penguins (Spheniscus magellanicus). For all species except rockhopper penguins, primer pair 2550F/2718R resulted in two distinct CHD1Z and CHD1W PCR bands, allowing for sex identification. For rockhopper penguins, only primer pair p8/p2 yielded different CHD1Z and CHD1W bands, which were faint and similar in size making them difficult to distinguish. As a result, we designed a new primer pair (PL/PR) that efficiently determined the gender of individuals from all four penguin species. Sequencing of the PCR products confirmed that they were from the CHD1 gene region. Primer pair PL/PR can be evaluated for use in sexing other penguin species, which will be crucial for the management of new penguin breeding programs. Zoo Biol 32:257–261, 2013. © 2012 Wiley Periodicals, Inc.     

Evaluation of High Resolution Melting for MTHFR C677T Genotyping in Congenital Heart Disease

Background

High resolution melting (HRM) is a simple, flexible and low-cost mutation screening technique. The methylenetetrahydrofolate reductase (MTHFR) gene encoding a critical enzyme, potentially affects susceptibility to some congenital defects like congenital heart disease (CHD). We evaluate the performance of HRM for genotyping of the MTHFR gene C677T locus in CHD cases and healthy controls of Chinese Han population.

Methods

A total of 315 blood samples from 147 CHD patients (male72, female 75) and 168 healthy controls (male 92, female 76) were enrolled in the study. HRM was utilized to genotype MTHFR C677T locus of all the samples. The results were compared to that of PCR-RFLP and Sanger sequencing. The association of the MTHFR C677T genotypes and the risk of CHD was analyzed using odds ratio with their 95% confidence interval (CIs) from unconditional logistic regression.

Results

All the samples were successfully genotyped by HRM within 1 hour and 30 minutes while at least 6 hours were needed for PCR-RFLP and sequencing. The genotypes of MTHFR C677T CC, CT, and TT were 9.52%, 49.66%, and 40.82% in CHD group but 29.17%, 50% and 20.83% in control group, which were identical using both methods of HRM and PCR-RFLP, demonstrating the sensitivity and specificity of HRM were all 100%.

Conclusion

MTHFR C677T is a potential risk factor for CHD in our local residents of Shandong province in China. HRM is a fast, sensitive, specific and reliable method for clinical application of genotyping.     

A multiplex PCR assay for molecular sexing of the naked mole-rat (Heterocephalus glaber)

For molecular sexing of the naked mole-rat (Heterocephalus glaber), we designed a PCR primer set to amplify part of the Y-linked DBY gene. When this primer set was applied to the samples of known sex with the 16S rRNA gene (16S rDNA) primers as control, PCR products were successfully obtained as two DNA bands in males, a male-specific 163 bp DBY band and a 446 bp band of 16S rDNA shared with females, whereas females showed only the common band. This result shows that this multiplex PCR assay is useful for sex identification of H. glaber.     

Molecular Differentiation of Opisthorchis viverrini and Clonorchis sinensis Eggs by Multiplex Real-Time PCR with High Resolution Melting Analysis

Opisthorchis viverrini and Clonorchis sinensis are parasites known to be carcinogenic and causative agents of cholangiocarcinoma in Asia. The standard method for diagnosis for those parasite infections is stool examination to detect parasite eggs. However, the method has low sensitivity, and eggs of O. viverrini and C. sinensis are difficult to distinguish from each other and from those of some other trematodes. Here, we report a multiplex real-time PCR coupled with high resolution melting (HRM) analysis for the differentiation of O. viverrini and C. sinensis eggs in fecal samples. Using 2 pairs of species-specific primers, DNA sequences from a portion of the mitochondrial NADH dehydrogenase subunit 2 (nad 2) gene, were amplified to generate 209 and 165 bp products for O. viverrini and C. sinensis, respectively. The distinct characteristics of HRM patterns were analyzed, and the melting temperatures peaked at 82.4±0.09℃ and 85.9±0.08℃ for O. viverrini and C. sinensis, respectively. This technique was able to detect as few as 1 egg of O. viverrini and 2 eggs of C. sinensis in a 150 mg fecal sample, which is equivalent to 7 and 14 eggs per gram of feces, respectively. The method is species-specific, rapid, simple, and does not require fluorescent probes or post-PCR processing for discrimination of eggs of the 2 species. It offers a new tool for differentiation and detection of Asian liver fluke infections in stool specimens.