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.     

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.     

Conditions for rapid sex determination in 47 avian species by PCR of genomic DNA from blood,shell‐membrane blood vessels,and feathers

The ability to rapidly and reliably determine the sex of birds is very important for successful captive‐bird breeding programs, as well as for field research. Visual inspection of adult birds is sufficient for sexually dimorphic species, but nestlings and monomorphic species are difficult, if not impossible, to sex by sight only. A method for rapid extraction of gDNA from blood, shell‐membrane blood vessels, and fully grown feathers, using Chelex, and the PCR conditions for determination of sex‐specific bands in 47 species (39 genera, 21 families, and 10 orders) are described. The PCR primers used amplify a length of DNA spanning an intron in the CHD‐1 gene, which is present on both the W and Z chromosomes. The intron differs in size between the two sex chromosomes, resulting in PCR products that separate into two bands for females and a single band for males in most avian species (except ratites). Because this simple technique uses Chelex, a rapid gDNA isolation protocol, and sets of PCR primers independent of restriction enzyme digestion, birds can be accurately sexed within 5 hr of sample collection. Zoo Biol 22:561–571, 2003. © 2003 Wiley‐Liss, Inc.     

Molecular sexing and sources of CHD1‐Z/W sequence variation in Hawaiian birds

Sequence information from 28 CHD1 gene fragments reveals that a primary source of variability in CHD1‐W genes is a variable intron microsatellite; a single‐codon deletion was found in the 3′ exon in one species. Sequence variation of CHD1‐Z genes was detected in males that altered polymerase chain reaction (PCR) fragment length. Three sets of CHD1‐based primers were evaluated for sex determination in 12 endemic and 8 alien Hawaiian species, including one of the last po’o‐uli. Combined, these primers provide a reliable means of sex determination in most species (including the po’o‐uli), and have produced a valuable reference database for future expanded population‐level studies.     

Improving the reliability of molecular sexing of birds using a W-specific marker

Molecular techniques for identifying sex of birds utilize length differences between CHD-Z and CHD-W introns, but in some cases these methods can lead to sexing errors. Here we show that an additional W-specific primer can be used in conjunction with a pre-existing sexing primer pair to dramatically improve the reliability of molecular sexing methods. We illustrate the approach with American coots (Fulica americana), a species with CHD-Z polymorphism that could not be accurately sexed using traditional methods. We developed a reverse primer GWR2 designed to sit within the intron of the W chromosome and amplify a distinctively small DNA fragment that serves as a W-specific marker. Analysis of known-sex individuals indicates that this W-specific primer provides an efficient and reliable protocol to identify the sex of F. americana. The development of such sex-specific primers will likely increase the reliability of molecular sexing methods in other birds as well. Comparisons between CHD-Z alleles of coots and common moorhens (Gallinula chloropus) revealed that CHD-Z polymorphism evolved separately in these two closely related species. We discuss the implications of repeated evolution of CHD-Z polymorphisms among birds.     

DNA amplification in the field: move over PCR,here comes LAMP

It would not be an exaggeration to say that among molecular technologies, it is PCR (polymerase chain reaction) that underpins the discipline of molecular ecology as we know it today. With PCR, it has been possible to target the amplification of particular fragments of DNA, which can then be analysed in a multitude of ways. The capability of PCR to amplify DNA from a mere handful of copies further means that conservationists and ecologists are able to sample DNA unobtrusively and with minimal disturbance to the environment and the organisms of interest. However, a key disadvantage of PCR‐based methods has been the necessity for a generally non‐portable, laboratory setting to undertake the time‐consuming thermocycling protocols. LAMP (loop‐mediated isothermal amplification) offers a logistically simpler protocol: a relatively rapid DNA amplification reaction occurs at one temperature, and the products are visualized with a colour change within the reaction tubes. In the first field application of LAMP for an ecological study, Centeno‐Cuadros et al. ( 2016 ) demonstrates how LAMP can be used to determine the sex of three raptor species. By enabling DNA amplification in situ and in ‘real‐time’, LAMP promises to revolutionize how molecular ecology is practised in the field.     

High error rates for avian molecular sex identification primer sets applied to molted feathers

ABSTRACT Molted feathers are becoming increasingly important as a source of DNA for identifying the sex of individuals, and accurate methods for molecular sex identification are needed. Three molecular sex identification primer sets have been developed for use in nearly all nonratite birds, but performance of these primer sets has not been evaluated for molted feathers. For two species of birds, the Ring‐necked Pheasant (Phasianus colchicus) and the Scarlet Macaw (Ara macao), we evaluated success and error rates among primer sets using DNA from molted feathers and assessed the percentage of times an incorrect sex would be assigned when analyses are completed in duplicate. Amplification success rates differed among the primer sets for both species, ranging from 67.5% to 89.2% (P= 0.0002 and 0.009), and error rates were high, ranging from 1.9% to 24.2%. Success rates and error rates were not consistent between species and among primer sets. To improve the accuracy of molecular sex identification tests when using molted feathers, we suggest determining acceptable confidence levels in the accuracy of sex assignment, conducting pilot tests to evaluate the performance of different primer sets, and using high‐resolution electrophoresis systems to increase detection of errors.     

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.     

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.     

Universal primers for fluorescent labelling of PCR fragments--an efficient and cost-effective approach to genotyping by fluorescence

Directly labelling locus‐specific primers for microsatellite analysis is expensive and a common limitation to small‐budget molecular ecology projects. More cost‐effective end‐labelling of PCR products can be achieved through a three primer PCR approach, involving a fluorescently labelled universal primer in combination with modified locus‐specific primers with 5′ universal primer sequence tails. This technique has been widely used but has been limited largely due to a lack of available universal primers suitable for co‐amplifying large numbers of size overlapping loci and without requiring locus‐specific PCR conditions to be modified. In this study, we report a suite of four high‐performance universal primers that can be employed in a three primer PCR approach for efficient and cost‐effective fluorescent end‐labelling of PCR fragments. Amplification efficiency is maximized owing to high universal primer Tm values (approximately 60+ °C) that enhance primer versatility and enable higher annealing temperatures to be employed compared with commonly used universal primers such as M13. We demonstrate that these universal primers can be combined with multiple fluorophores to co‐amplify multiple loci efficiently via multiplex PCR. This method provides a level of multiplexing and PCR efficiency similar to microsatellite fluorescent detection assays using directly labelled primers while dramatically reducing project costs. Primer performance is tested using several alternative PCR strategies that involve both single and multiple fluorophores in single and multiplex PCR across a wide range of taxa.     

High‐resolution melting analysis for bird sexing: a successful approach to molecular sex identification using different biological samples

High‐resolution melting (HRM) analysis is a very attractive and flexible advanced post‐PCR method with high sensitivity/specificity for simple, fast and cost‐effective genotyping based on the detection of specific melting profiles of PCR products. Next generation real‐time PCR systems, along with improved saturating DNA‐binding dyes, enable the direct acquisition of HRM data after quantitative PCR. Melting behaviour is particularly influenced by the length, nucleotide sequence and GC content of the amplicons. This method is expanding rapidly in several research areas such as human genetics, reproductive biology, microbiology and ecology/conservation of wild populations. Here we have developed a successful HRM protocol for avian sex identification based on the amplification of sex‐specific CHD1 fragments. The melting curve patterns allowed efficient sexual differentiation of 111 samples analysed (plucked feathers, muscle tissues, blood and oral cavity epithelial cells) of 14 bird species. In addition, we sequenced the amplified regions of the CHD1 gene and demonstrated the usefulness of this strategy for the genotype discrimination of various amplicons (CHD1Z and CHD1W), which have small size differences, ranging from 2 bp to 44 bp. The established methodology clearly revealed the advantages (e.g. closed‐tube system, high sensitivity and rapidity) of a simple HRM assay for accurate sex differentiation of the species under study. The requirements, strengths and limitations of the method are addressed to provide a simple guide for its application in the field of molecular sexing of birds. The high sensitivity and resolution relative to previous real‐time PCR methods makes HRM analysis an excellent approach for improving advanced molecular methods for bird sexing.     

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.     

Development of novel polymerase chain reaction (PCR) based microsatellite markers in Armillaria gallica by cross‐species amplification and species‐specific cloning

Cross‐species PCR amplification of Armillaria mellea group taxa with previously reported A. ostoyae microsatellite markers, indicative of flanking sequence conservation, was exploited for the species‐specific isolation of simple sequence repeat (SSR) motifs from A. gallica. Six SSR motifs were sequence characterized from cloned PCR fragments generated with primers previously developed from A. ostoyae. Five novel primer pairs, designed from motif flanking regions, allowed for improved, efficient amplification in this species. One original A. ostoyae primer pair was used directly. Polymorphims were observed at wide geographical levels only. Relative cross‐species amplification intensities generally supported the currently accepted molecular phylogeny of this group.     

A DNA test to sex most birds

Birds are difficult to sex. Nestlings rarely show sex-linked morphology and we estimate that adult females appear identical to males in over 50% of the world's bird species. This problem can hinder both evolutionary studies and human-assisted breeding of birds. DNA-based sex identification provides a solution. We describe a test based on two conserved CHD (chromo-helicase-DNA-binding) genes that are located on the avian sex chromosomes of all birds, with the possible exception of the ratites (ostriches, etc.; Struthioniformes). The CHD-W gene is located on the W chromosome; therefore it is unique to females. The other gene, CHD-Z, is found on the Z chromosome and therefore occurs in both sexes (female, ZW; male, ZZ). The test employs PCR with a single set of primers. It amplifies homologous sections of both genes and incorporates introns whose lengths usually differ. When examined on a gel there is a single CHD-Z band in males but females have a second, distinctive CHD-W band.     

Cut feather containing rachis as a sampling way for avian sexing

Sex determination of birds is important to ensure successful breeding strategies, especially for endangered species. Most birds are vulnerable to stress during handling, however, so obtaining a sufficient amount of genomic DNA (gDNA) while causing the least amount of harm is a critical issue. Avian gender can be determined based on different CHD1 gene intron sizes in W and Z sex chromosomes. We have compared various specimen sources and have found that the rachis segment of a feather is a good DNA source for determining sex. This indicates that plucking the whole feather is not necessary; a cut feather including the rachis is a superior method because it decreases stress on the examined birds and is accomplished easily. Zoo Biol. 0:1–5, 2006. © 2006 Wiley‐Liss, Inc.     

Species and sex identification of Formosa landlocked salmon using loop-mediated isothermal amplification

Species and sex identification are among the most important parameters for conservation management. However, it is extremely difficult to perform such identification in Formosa landlocked salmon (Oncorhynchus masou formosanus). Both sexual dimorphism in landlocked dwarf form Formosa landlocked salmon and morphological difference among cherry salmon complex are minimal. We developed a simple, rapid and noninvasive method for identifying sex and species of this critically endangered species using a loop-mediated isothermal amplification (LAMP) technique. The LAMP assay showed the advantage of simple detection (evaluated by visual inspection), rapid reaction time (< 1 h), isothermal condition (less equipment required) and high efficiency (only 0.5-5 pg of DNA was required in the reaction mixture). Therefore, the method is more economical and practical than PCR. The LAMP assay can be easily performed in the field and is a valuable tool for detecting sex ratios in wild populations and identifying species in commercial imports. This is the first application of LAMP in identifying species and sex of salmonids as far as we know and clearly shows the potential application of LAMP in molecular ecology and conservation efforts.     

SP‐Designer: a user‐friendly program for designing species‐specific primer pairs from DNA sequence alignments

SP‐Designer is an open‐source program providing a user‐friendly tool for the design of specific PCR primer pairs from a DNA sequence alignment containing sequences from various taxa. SP‐Designer selects PCR primer pairs for the amplification of DNA from a target species on the basis of several criteria: (i) primer specificity, as assessed by interspecific sequence polymorphism in the annealing regions, (ii) the biochemical characteristics of the primers and (iii) the intended PCR conditions. SP‐Designer generates tables, detailing the primer pair and PCR characteristics, and a FASTA file locating the primer sequences in the original sequence alignment. SP‐Designer is Windows‐compatible and freely available from http://www2.sophia.inra.fr/urih/sophia_mart/sp_designer/info_sp_designer.php .     

A smörgåsbord of markers for avian ecology and evolution

The polymerase chain reaction has been a boon to the study of molecular ecology and population genetics of birds. But the nagging truth is that for many bird species, the number of polymerase chain reaction (PCR) primer pairs that one can pick off the shelf and expect to amplify their target loci with ease is frustratingly small. Now, studying DNA sequence variation in natural populations of birds just got a whole lot easier. This issue of Molecular Ecology reports a large-scale bioinformatics search for exonic sequences conserved between the chicken and zebra finch genomes and flanking polymorphic introns that has generated a staggering 242 PCR primer pairs that readily amplify their single-copy target loci in five avian species spanning ~100 million years of avian evolution ( Backström et al . 2008 ). As proof of principle, these primers have also been used to survey the genomic landscape in over 110 kb of intronic sequence in the collared flycatcher, a model species in ecology and evolution. These resources pave the way for easy multilocus study of evolving populations and lineages of birds, and bring the goal of quickly turning nonmodel species in to ecological genomic models tantalizingly close.     

Development of species-specific polymerase chain reaction primers for detection of Fusobacterium periodonticum

The purpose of this study was to develop species-specific PCR primers for detection of Fusobacterium periodonticum. The specificity data showed that two sets of PCR primers, Fp-F3/Fp-R2 and Fp-F1/Fp-R2 PCR, produced amplicons from all the F. periodonticum, but not from the other species tested, which included 12 Fusobacterium species or subspecies and representative oral bacteria. The sensitivity of the primer sets was 4 or 40 pg of the chromosomal DNA from F. periodonticum ATCC 33693(T) . These results suggest that these two sets of PCR primers are quite sensitive in detection of F. periodonticum in molecular epidemiological studies of periodontitis.