- Technical Note
- Open Access
Genotyping of black grouse MHC class II B using reference Strand-Mediated Conformational Analysis (RSCA)
© Strand et al; licensee BioMed Central Ltd. 2011
Received: 21 February 2011
Accepted: 14 June 2011
Published: 14 June 2011
The Major Histocompatibility Complex (MHC) is a cluster of genes involved in the vertebrate immune system and includes loci with an extraordinary number of alleles. Due to the complex evolution of MHC genes, alleles from different loci within the same MHC class can be very similar and therefore difficult to assign to separate loci. Consequently, single locus amplification of MHC genes is hard to carry out in species with recently duplicated genes in the same MHC class, and multiple MHC loci have to be genotyped simultaneously. Since amplified alleles have the same length, accurate genotyping is difficult. Reference Strand-Mediated Conformational Analysis (RSCA), which is increasingly used in studies of natural populations with multiple MHC genes, is a genotyping method capable to provide high resolution and accuracy in such cases.
We adapted the RSCA method to genotype multiple MHC class II B (BLB) genes in black grouse (Tetrao tetrix), a non-model galliform bird species, using a 96-Capillary Array Electrophoresis, the MegaBACE™ 1000 DNA Analysing System (GE Healthcare). In this study we used fluorescently labelled reference strands from both black grouse and hazel grouse and observed good agreement between RSCA and cloning/sequencing since 71 alleles were observed by cloning/sequencing and 76 alleles by RSCA among the 24 individuals included in the comparison. At the individual level however, there was a trend towards more alleles scored with RSCA (1-6 per individual) than cloning/sequencing (1-4 per individual). In 63% of the pair-wise comparison, the identical allele was scored in RSCA as in cloning/sequencing. Nine out of 24 individuals had the same number of alleles in RSCA as in cloning/sequencing. Our RSCA protocol allows a faster RSCA genotyping than presented in many other RSCA studies.
In this study, we have developed the RSCA typing method further to work on a 96-Capillary Array Electrophoresis (MegaBACE™ 1000). Our RSCA protocol can be applied to fast and reliable screening of MHC class II B diversity of black grouse populations. This will facilitate future large-scale population studies of black grouse and other galliformes species with multiple inseparable MHC loci.
In vertebrates, MHC (Major Histocompatibility Complex) is a cluster of highly variable genes that plays an important role in the immune defence and which may evolve through different forms of balancing selection [1–4]. This multigene family is highly interesting from an evolutionary perspective. For example, MHC genes have been associated with individual fitness, population viability and evolutionary potential in changing environments . MHC genes are in fact among the most suitable candidates for studies of adaptive genetic diversity because of the numerous associations found between MHC genotypes and pathogen resistance e.g. [5–9]. In studies of both model and non-model species, the interest in MHC genes has remained high among evolutionary biologists over decades. However, large-scale studies of natural populations are hampered because of the complexity working with MHC genes.
MHC evolution is characterized by repeated gene duplication (birth) and gene loss (death), thereby loci evolve under a birth-and-death model . Supplementary to the birth-and-death model of MHC evolution is concerted evolution, observed particularly in birds [11, 12]. This is the result of frequent genetic exchange between duplicated genes by recombination or gene conversion (i.e. interlocus genetic exchange). Because of the complicated (and not fully understood) evolution of MHC genes there are pronounced differences in the genomic organization and number of the MHC loci between vertebrate lineages , especially between mammalian and non-mammalian species [12, 14]. For this reason it is a great challenge to accurately amplify MHC genes in non-model species. For example, the number of MHC loci can vary extensively between different species, even when the species compared are phylogenetically related and belong to the same taxonomic family, like chicken and quail . There are also known or assumed cases of MHC copy number variation within species [16–21]. Additionally, in non-mammalian species with multiple loci per MHC class, the loci belonging to the same MHC class are, in most species, too similar to tell apart [16, 22–25]. Designing primers that amplify a single MHC locus is therefore a difficult task. In combination with PCR artefacts  and the common presence of pseudogenes in MHC, this also makes single locus amplification of functional MHC alleles hard to accomplish. Consequently, many MHC studies in non-mammalian species are struggling with genotyping PCR products including more than two MHC alleles.
For PCR products from multiple MHC loci, existing genotyping methods, like cloning and Sanger sequencing, Reference Strand-Mediated Conformational Analysis (RSCA), Single Strand Conformation Polymorphism (SSCP), Denaturing Gradient Gel Electrophoresis (DGGE) and Next Generation amplicon sequencing, work with different levels of accuracy, precision and speed [27–29]. RSCA, DGGE and SSCP all are methods that have the potential to separate PCR products that have the same length but differ in DNA sequence. PAGE-SSCP (gel-based SSCP) is a widely used MHC typing method that can separate alleles that only differ in one base-pair because of the different conformation of the alleles . The method has earlier been modified for use on automated sequencers  and recently also for capillary electrophoresis, CE-SSCP . In contrast, DGGE has not, to our knowledge, been adapted to automated sequencers . This technique is based on the principle that double-stranded DNA molecules have unique denaturation rates that are based on the specific nucleotide composition.
Although time-consuming, RSCA methods where preparation of acrylamide gels are required, is still widely used for MHC genotyping such as ALFexpress [39–43] and on ABI377 [44–46]. RSCA has also been optimised to various Capillary Electrophoresis (CE) instruments, firstly to the one capillary instrument ABI PRISM 310 (Applied Biosystems) [47, 48]. Recently, besides CE instruments, also Capillary Array Electrophoresis (CAE) instruments, with several capillaries for faster genotyping, are used in RSCA typing, four capillaries in CAE ABI 3130 [28, 49] and 16 capillaries in CAE ABI 3100 [21, 28, 36, 50, 51]. To our knowledge, RSCA genotyping has not previously been optimised for a MegaBACE™ instrument (GE Healthcare). RSCA on MegaBACE™ may work differently than RSCA on ABI because of the many differences between the systems. The dissimilarities between MegaBACE™ and ABI includes "the mechanism by which sample DNA is introduced into the capillaries, the capillaries themselves, i.e., capillary diameter, length, and internal coating, the mechanism of excitation (although both use laser-induced fluorescence), where the DNA is detected and the method of detection itself" .
The black grouse (Tetrao tetrix) has a well-studied complex mating system where males defend territories at traditional leks (mating grounds) which females visit to mate (Höglund and Alatalo 1995). Also, the black grouse is a wide-spread bird with both viable and threatened populations and MHC studies can, for example, clarify the role and importance of MHC diversity in conservation. In an earlier study  we amplified and sequenced transcribed MHC class II B alleles in black grouse, but before we can continue with large-scale studies of MHC variation, we wanted to design an efficient and reliable MHC genotyping method suitable for black grouse.
The objective of this study was to develop an RSCA approach further, for even higher throughput MHC genotyping on a 96-Capillary Array Electrophoresis (the MegaBACE™ 1000, an instrument not previously used for RSCA) in general, and more specifically, for MHC genotyping in black grouse. Such a method could facilitate large-scale surveys of MHC genetic polymorphism in both model and non-model species. To verify the method we compared the RSCA typing results with cloning and classic Sanger sequencing. In our study, we successfully genotyped black grouse MHC class II B alleles from expressed loci using RSCA. When we compared cloning/sequencing with RSCA, most black grouse alleles were detected with both methods. There is however a tendency for higher number of MHC alleles typed with RSCA than cloning/sequencing. We therefore suggest that our RSCA genotyping protocol is not primarily suitable for individual level studies of MHC diversity where allele-specific correlations are sought for, but it is appropriate for large-scale studies of MHC diversity on the population level.
Amplification of MHC BLB
The primer pair RNAF1a (5'GACAGCGAAGTGGGGAAATA-3') and RNAR1a (5'- CGCTCCTCTGCACCGTGA-3') was used to amplify a 125 bp fragment of the BLB exon 2 in all following PCR protocols. We designed these primers in conserved regions of the exon 2 for our previous study and have shown that they specifically amplify functional BLB but not YLB alleles . We assume that this primer pair is capable of amplifying a wide range of different BLB alleles, as it amplifies the BLB as well in two related grouse species, the hazel grouse and the willow grouse (Bonasa bonasia and Lagopus lagopus, unpublished data).
Ideally, the alleles chosen to be FLRs should neither be too different nor too similar to the alleles genotyped ("test alleles") in the study . If the FLR and the test allele are too different, they may not hybridise. On the other hand, if the FLR and the test allele are too similar, the homoduplex formation of the FLR and the heteroduplex formation between the FLR strand and the test allele strand will co-migrate in the gel and the test allele will therefore become undetected. Co-migration can also happen when a FLR strand is hybridised with a test allele strand, if the hybridisation produces a formation that has similar migration speed as another test allele. One way to avoid co-migration and therefore avoid undetected alleles is to use more than one FLR. The risk of co-migration with the homoduplex is also decreased if the FLRs are chosen from a related species instead of the same species, since shared alleles between different species are presumably rare.
In this study, we used one allele from black grouse and three alleles from a species from the same subfamily (Tetraoninae), the hazel grouse , giving a total of four FLRs. The first allele cloned and sequenced from our previous study , Tete BLB01, was assigned FLR-Tete1. We tested the remaining black grouse alleles, Tete BLB02-09, as FLRs and most of them resulted in distinguishable peaks in the electropherogram. However, we decided to use FLRs from the hazel grouse, to reduce the risk of undetected test-alleles identical to the allele that the FLR is based on. Using hazel grouse alleles minimizes this risk since black grouse and hazel grouse probably do not share alleles (although possible due to trans-species polymorphism). MHC class II B alleles were amplified from one hazel grouse individual (cloned twice) using the same primers (RNA F 1a and RNA R 1a), PCR-protocol and master cycler program as for the black grouse BLB (see ). The PCR-product was ligated into pCR4-TOPO vector using a Topo TA cloning kit (Invitrogen, Carlsbad, CA, USA) following the protocol by the manufacturer. Twenty colonies were both forward and reverse sequenced on MegaBACE™ 1000 DNA Analysis System (GE Healthcare, Uppsala, Sweden). The resulting three unique hazel grouse sequences were all chosen for FLRs. Allele Bobo BLB01 was assigned FLR-Bobo1, Bobo BLB02 FLR-Bobo2 and Bobo BLB03 FLR-Bobo3. GenBank accession numbers are GQ851943 for Bobo BLB01, GQ851944 for Bobo BLB02 and GQ851945 for Bobo BLB03.
We constructed a FAM-fluorescently labelled forward primer FAM RNAF1a and used the normal non-labelled reverse-primer RNAR1a for the FLR PCR on the above clones for FLR-Tete1, FLR-Bobo1, FLR-Bobo2 and FLR-Bobo3. We used ten times as much of the labelled primer than the non-labelled one, to increase the heights of the heteroduplex peaks in the electropherogram . Approximately 50 ng DNA, 0.5 μM of the FAM forward primer, 0.05 μM of the reverse primer, 0.6mM of dNTP, 3 mM MgCl2, 1 x buffer and 0.75 units BioTaq polymerase (DNA Technology, Aarhus, Denmark) were used in the 100 μl FLR PCR reaction. The reaction was initiated at 94°C for 1 minute and was then run for 35 cycles at 94ºC for 1 minute and 30 seconds at both 64.9ºC and 72ºC before a stop for 10 minutes on 72°C. The PCR products were purified with Montage PCR spin columns (Millipore Cooperation, MA, USA), dissolved in TE buffer of pH 7 and stored at -20°C.
Construction of RSCA library
We first constructed a preliminary RSCA library with eight unique BLB sequences from our previous study . The following PCR was performed on these eight clones. Approximately 50 ng DNA, 0.48 μM of each primer, 0.6mM of dNTP, 3 mM MgCl2, 1 x buffer and 0.75 units BioTaq polymerase (DNA Technology, Aarhus, Denmark) were used in a 25 μl PCR reaction. The reaction was initiated at 94°C for 1 minute and was then run for 30 cycles at 94ºC for 1 minute and 30 seconds at both 64.9ºC and 72ºC before a stop for 10 minutes on 72°C. The four FLRs were run with each of these original eight unique sequences (i.e. clones representing alleles Tete BLB01-BLB09 but not BLB08 since that allele may be an artefact) between four and nine times (mean 6.2 times) in independent runs, using different non-denatured polymer lots. Standard deviations (SD) for migrations values were calculated for each FLR using several runs. Between RSCA runs, the MegaBACE™ was run with denaturing polymer for microsatellite genotyping or sequencing using the same capillaries. The homoduplex FLR peak always had a migration value of about 161 bp, close to the size of the amplified part of exon 2 including primers. All RSCA peaks turned up to the right of the FLR peak (Figure 1). When we started to screen MHC alleles in a population study of black grouse (Strand et al. manuscript) using this RSCA library, we noticed new RSCA peaks so we cloned more individuals and increased the library with eight additional unique MHC class II B sequences. This updated RSCA library is based on 16 cloned MHC class II B sequences/alleles in total (additional file 1: RSCA library). One RSCA peak is visible for each unique allele in both FLR-Tete1 and FLR-Bobo1. FLR-Bobo2 shows two peaks (one additional or one alternative peak) instead of one peak for five alleles, and three peaks for one allele. One allele run with FLR-Bobo3 also shows an extra peak.
RSCA migration values
A peak was scored as a certain allele if it were present in the migration value range of that allele (additional file 1: RSCA library) in four out of the four FLRs.
It is enough to score an allele as present if it exists in three FLRs if that allele is single in one strong peak (this means that no other allele has the same migration value in that FLR, for an example see allele 5 in migration value 184.8 in FLR-Bobo3, Table 1).
Exceptions to these rules exist for allele BLB01 since this allele is the basis for FLR-Tete1 (they are identical). FLR-Tete1 can therefore not have a peak for BLB01. In case BLB01, three FLRs is therefore enough for scoring in the first rule, and two FLRs is enough for scoring in the second rule.
Comparison between cloning and RSCA in 24 individuals
Alleles by seq
A typical example of scoring is presented for individual Ref 26. The electropherograms for Ref 26 for all four FLRs is visible in Figure 1. The leftmost blue peak at migration value of approx. 161 is the homoduplex peak for the FLR so that peak is always disregarded. One FLR show three RSCA peaks, one show four RSCA peaks and two show five RSCA peaks. Each RSCA peak lays in a certain migration value range for a specific MHC allele, as reported in Table 1.
In certain cases there are two or even three RSCA peaks in the same FLR for the same allele (probably because more than one formation is stable between the FLR and the allele), resulting in two (or three) migration value ranges within the same FLR for one allele (additional file 1: RSCA library). In the example in Table 1, alleles with an apostrophe (') reflect a second or alternative RSCA peak. Following the scoring rules (in the paragraph above) on Table 1, Ref 26 has allele BLB22 according to rule 1, allele BLB05 according to both rule 1 and rule 2, and BLB01 according to rule 2 (and rule 1 applying the exception for BLB01). This individual thus has three MHC alleles, namely BLB01, BLB05 and BLB22 according to RSCA. Cloning and sequencing also revealed these MHC alleles (28 clones sequenced). There are peaks present in the electropherogram (Figure 1, Table 1) that were not scored as alleles (181.9 (FLR-Tete1), 170.6 (FLR-Bobo1) and 177.1 (FLR-Bobo2)). Two of these peaks (181.9 (FLR-Tete1) and 177.1 (FLR-Bobo2)) are actually peaks within much larger peaks and could therefore be artefacts. The other peak (170.6 (FLR-Bobo1)) could represent an additional folding structure that may appear for example when alleles are hybridised with the FLR (because the sequences can match in more than one way) or due to either non-optimal hybridisation temperatures or MegaBACE run temperatures. This peak could simply also represent an unknown allele.
Comparison between cloning/sequencing and RSCA
RSCA has been increasingly used as a MHC genotyping method in birds [35–37] and we have now further developed the RSCA typing method to operate on a 96-capillary array electrophoresis, providing a higher throughput. To our knowledge, this is the first time RSCA have been optimised to be run on the MegaBACE™ 1000 DNA Analysing System. We have now designed a genotyping method suitable for functional MHC class II B loci in black grouse. This method performs well on DNA extracted from both blood and moulted feathers. In the present study, when comparing cloning and classic Sanger sequencing with RSCA, most black grouse MHC class II B alleles are detected with both methods. Among the 24 individuals, 71 alleles were found by cloning/sequencing and 76 were found by RSCA. Some of the MHC class II B alleles are found only by cloning/sequencing but not with RSCA and vice versa. There is also a tendency for RSCA to score more alleles than cloning (1-4 alleles are observed per individual via cloning and 1-6 via RSCA) but whether RSCA overestimates or cloning underestimates number of alleles is not yet clarified. There are several possible reasons for the observed discrepancies between RSCA and cloning.
The first reason to the discrepancies at the individual level may be that not enough clones were sequenced in the cloning. Alleles that are not amplified to the same extent as other alleles in the PCR due to non-optimal primer binding will fail to be found in cloning if not very many clones are sequenced. To test this, many more clones per individual than we used need to be picked and sequenced. In our lab, fosmid sequencing across MHC genes in one black grouse individual has uncovered two MHC class II loci (BLB1 and BLB2) (B. Wang et al., in preparation), suggesting that a maximum of four MHC class II alleles can be present in black grouse. This is in line with the maximum of four alleles we observed in cloning. Our RSCA may thus overestimate number of alleles. However, at present we cannot rule out the possibility of copy number variations in MHC class II B in black grouse. Copy number variation in MHC has been observed in several species [18, 19], including chicken where some individuals possess two BLB (BLB1 and BLB2) loci and other individuals three BLB loci . BLB1 and BLB2 are possibly old duplications since they are positioned on either side of TAPB and are present also in turkey, which possesses a third BLB loci adjacent to BLB2[20, 54]. Copy number variation between one, two and three loci may explain the range of 1-6 RSCA alleles per individual. It is also possible that an individual can possess only one BLB allele in total even if black grouse possess between two and three BLB loci. It has been shown in other galliformes (red jungle fowl and pheasant) that identical MHC alleles can be present at different loci [36, 55], so one allele is possible for a bird homozygous at two loci. We are attempting to elucidate a possible presence of copy number variation in an on-going MHC study.
The second reason for the observed discrepancies between RSCA and cloning/sequencing at the individual level may be non-optimal RSCA conditions. To minimize alternative folding structures RSCA run temperatures and hybridisation temperatures could have been tested for each FLR individually. Also, more FLRs could have been added to providing better resolution of alleles, but at the price of being time- and resource consuming.
Our result of the comparison between cloning/sequencing and RSCA is almost identical to a study of the domestic cat . Using four FLRs we identified on average 2.96 alleles (range 1-4) via cloning and 3.17 alleles (range 1-6) via RSCA. In the feline study, using five FLRs, they found 3.0 alleles (range 1-4) by cloning and 3.9 (range 2-6) by RSCA. Copy number variation was found were some individuals carried two MHC class II DRB genes and some three, explaining the range from two to six DRB alleles per individuals (with RSCA). The allele range in black grouse could also be explained by similar copy number variation, as suggested above. Further, the feline study suggest that the deviations in allele number between the two methods could be the result of too strict rules for confirming an allele, (that were followed to disregard PCR artefacts) i. e. two independent PCR/cloning reactions. Paradoxically, another reason suggested for the deviations between the methods may be due to sequences that represent PCR artefacts. All this highlight the draw-backs of cloning and Sanger sequencing and the complexity of characterizing MHC variability.
The MHC study by Lenz et al. 2009  comparing RSCA and cloning/sequencing found an even stronger congruence than we found between the methods. It is difficult to disentangle the reason for this since our study differs from Lenz et al. in many ways, for example in the selection of FLRs, the DNA quality, the run temperature and in the use of different electrophoresis instrument.
Since we cannot rule out that our RSCA genotyping protocol may overestimate the number of alleles, it may not yet be optimal for individual level studies where allele-specific correlations are sought for. Nevertheless, we believe that our RSCA protocol is ideal for fast and cheap population level studies of MHC diversity in black grouse and related species.
A future possibility is to multiplex the RSCA, using unique dyes for each FLR so that the different FLRs can be run in the same capillary, increasing by a factor three the speed of throughput. In this study, we used one black grouse FLR and three hazel grouse FLRs to successfully genotype black grouse MHC class II B. This leads us to believe that the protocol presented in this paper can directly work to genotype MHC class II B in other galliform species. At present, we are testing this hypothesis by performing RSCA with black grouse FLRs in hazel grouse and willow grouse, and preliminary results are indeed positive. We want to point out that for these newer studies we use non-denaturing matrix (for the MegaBACE™) from Genomac International (Prague) successfully. The RSCA can be adapted to other loci but MHC and should be of great use since it has the potential of separating any complex same-length sequences.
In a number of recent studies, genotyping of MHC is still performed solely by cloning and Sanger sequencing e.g. [56–58]. Cloning and sequencing of MHC alleles does not need optimization once the primers amplify the right region, however, we see two major drawbacks with this method. First, different types of artefacts can lead to false identification of true alleles, namely PCR artefacts (Taq errors, chimeras and heteroduplex formation in the last PCR cycle) and mismatch repair during cloning . In RSCA, the number of artefacts is reduced since the PCR product is denatured before screening and thus heteroduplex formations are neutralized . The second drawback with cloning and Sanger sequencing is that alleles at low frequency in the PCR can fail to be observed. The reason for this is when amplifying several MHC alleles simultaneously, all alleles may not be amplified to an equal concentration if the primers amplify certain alleles better than others. If this is the case, alleles can be missed in cloning, because many clones have to be picked to certify that all alleles are identified. In RSCA, the lower concentration alleles may have a better chance of being identified than in cloning, since only the height of the RSCA peak is lower than the other peaks if concentration is lower. In a recent study using RSCA, RSCA was in fact not the main genotyping method but were used to confirm MHC alleles obtained from sequencing .
When alleles from multiple loci co-amplify in the PCR, as the case for this black grouse study and many other studies, accurate genotyping can be very challenging. The reason for this is because gels and chromatograms become difficult to interpret since bands or peaks representing various alleles may overlap due to similar mobility. This is the case for PAGE-SSCP, CE-SSCP and DGGE. This problem is solved in RSCA since each sample is hybridised with several FLRs, so that alleles migrate differently with different FLRs, leading to a higher resolution. Recently, CE-SSCP has also been modified to discriminate alleles better than before by the use of overlapping PCR amplicons . Other advantages in RSCA over PAGE-SSCP and DGGE are that the amount of toxic steps is greatly reduced as well as the labour since no handling of gels is needed. In theory, an advantage of both DGGE and PAGE-SSCP compared to RSCA, is the possibility of excising bands from the gels, reamplify and perform direct sequencing of new MHC alleles. For this to work, the bands have to be clearly separated in the gel. However, if sequences are needed in RSCA the procedure of classic cloning and sequencing can be greatly reduced by running RSCA on the clones. That is, samples that show new RSCA peaks can be cloned, and the clones can then be hybridised with an FLR and run through RSCA to identify the specific clone containing the new alleles. This procedure makes sequencing much cheaper since only clones including the new allele need to be sequenced. For further comparisons of the SSCP, DGGE and RSCA methods, see [27, 28].
Next generation amplicon sequencing techniques has been increasingly used for MHC typing [29, 61, 62]. 454 amplicon sequencing, with individual tagging of PCR primers, seem to be a reasonable choice for highly variable multilocus MHC genotyping when other, more widely used methods, are not successful . The major drawback with 454 amplicon sequencing seems to be the difficulties in distinguishing true alleles from artefact sequences, that exist in higher number than Sanger sequencing errors . However, the large number of reads from pyrosequencing would allow for correction of typing errors .
In the context of population genetics, the purpose of MHC genotyping can roughly be divided into two different groups based on the level of precision. The first group may be referred to as "sequence level MHC genotyping" and the other group as "population level MHC genotyping". "Sequence level MHC genotyping" is necessary when MHC sequences from individuals are studied, to test for various forms of selection using patterns of nucleotide and gene diversity or to find allele specific mate choice or disease associations. On the other hand, "population level MHC genotyping" is ideal for non-model species studies when a simpler MHC genotyping method is being sought for. This might be the case in conservation genetic studies of adaptive genetic diversity, for example to identify populations vulnerable to changes in the environment. In "population level MHC genotyping" there is no per se need to know the details about nucleotide differences among the present alleles so no sequencing needs to be performed in the screening process.
We believe that RSCA has a great potential for "population level MHC genotyping" and is of good value even for "sequence level MHC genotyping". RFLP (Restriction Fragment Length Polymorphism) is a solid technique but involves gel preparations and radioactive work and is not as accurate as RSCA. RFLP cannot be used for "sequence level MHC genotyping" at a later stage. We suggest therefore that RSCA is a great first step in MHC studies in non-model species, where the level of detail and precision can be easily turned from "population level MHC genotyping" to "sequence level MHC genotyping" with the same method.
In this study, we have developed a RSCA typing protocol for black grouse populations on a MegaBACE™ 1000 DNA Analysing System. We hybridised each PCR product with four different Fluorescently Labelled References in individual wells and separated them by electrophoresis. RSCA seems to be comparable at separating black grouse MHC class II B alleles as cloning and Sanger sequencing since we found 76 alleles by RSCA and 71 by cloning/sequencing among 24 individuals. There is however a tendency for RSCA to score more alleles than cloning at the individual level. Therefore, RSCA seems to be a promising method for studies when a simpler MHC genotyping method is being sought, for example, in conservation genetic studies for adaptive genetic diversity. Our study will also facilitate large scale MHC studies in species other than black grouse.
Study animal, samples and DNA extraction
The black grouse
Black grouse belong to the same order, Galliformes, and family, Phasianidae, as chicken . The lekking black grouse is a species tied to taiga forest habitats. The females mate with only one male and the males do not provide any parental care . In an earlier study  we showed that MHC class II B (BLB) and Y (YLB) are orthologous in chicken and black grouse and this finding was one of first examples of orthology in the avian MHC . Black grouse and chicken possess approximately two to three BLB genes and two YLB genes. The BLB genes are more diverse and expressed than YLB genes . 17 of the individuals used in this study were captured between 1989 and 2004 at study sites around Jyväskylä in central Finland (see  for a description of the study area). Black grouse were caught in winter flocks or when lekking and c. 1 ml blood samples were drawn from the brachial wing vein with a syringe using a heparinized needle. Red blood cells were separated from plasma by centrifuging at 12000 rpm for 5 min, and stored at 75% alcohol at +4°C until DNA-extraction. Older blood samples (before 1990) were kept frozen until DNA was isolated. Feathers from six other individuals (named "Ref" and "Ne36" in Table 2) were collected in North Pennines (England) and Netherlands. The moulted feathers were stored dry at room temperature for 1-20 months until DNA extraction. One sample (10222) was sampled in Norway and the tissue type is muscle. For blood, genomic DNA was extracted mainly using a standard phenol-chloroform procedure , but salt extraction  was also used. Genomic DNA from feathers and muscle was extracted using DNeasy Tissue kit as described in . Birds that were caught, hunted or released were done so under the permission, legislation and guidance of the relevant authorities of the country of origin.
PCR were performed as described under the section "Construction of RSCA library". For production of FLRs, see the section "FLR amplification" in the result part. For individuals, 3.0 µl of PCR product was mixed with 2.0 µl of FLR and for clones 2.0 µl of PCR product was mixed with 2.0 µl FLR. The ratio between FLR and PCR product was optimised for each FLR, so FLRs were diluted individually. The hybridisation was performed using a PCR thermo cycler starting with denaturation at 95°C for 10 min, and then cooling by 1°C/s until 55, then heteroduplex formed for 15 min at 55°C until a cooling step at 4°C for 15 min. The heteroduplex product was then stored at 4°C.
Capillary array electrophoresis
The hybridisation product was mixed with 4.0 µl cold ddH2O. 2.0 µl of the diluted heteroduplex product was then mixed with 0.45 µl ET400R-Size standard (GE Healthcare) and 7.55 µl ddH2O. The capillary array electrophoresis was performed on MegaBACE™ 1000 DNA Analysing System (GE Healthcare). First, samples were preinjected to remove excess salt and next, the capillaries were rinsed. Thereafter, capillaries were filled with 3% non-denaturing Long-Read-Matrix (polymer) (GE Healthcare) under high pressure. Lastly, 96 samples were injected at 3 kV for 45 seconds and run for 60 min at 30°C and 10 kV. During the typing period, the capillaries were used either for sequencing or microsatellite genotyping when not used for RSCA, so we alternated between non-denaturing matrix and denaturing matrix.
MegaBACE fragment profiler™ version 1.2 was used to analyse the RSCA peaks. CodonCode Aligner version 2.06 was used to identify the new sequences. The difference in number of alleles in RSCA versus cloning and sequencing were tested in a paired Wilcoxon signed rank test in R v2.12.0.
Acknowledgements and Funding
We would first like to thank Yvonne Meyer-Lucht for many discussions, encouragement and thoughtful comments on the latest versions of the manuscript. We are grateful to Rauno Alatalo and Heli Siitari who run the field work which allowed taking blood samples from free living birds. For the black grouse feather samples, we thank David Baines and Hugh Jansman. Kindly, Xiao Lingyun assisted in the lab in the later stage of the study. Thanks to Iain Barr for helpful discussions about the RSCA method in the very beginning of this project. We would also like to thank Helena Westerdahl who provided support, RSCA discussions and comments on an earlier draft of this manuscript. We are grateful to two anonymous reviewers who helped us improve the manuscript substantially.
This work was supported by a grant from the Swedish Research Council (VR) to JH.
- Garrigan D, Hedrick PW: Perspective: Detecting adaptive molecular polymorphism: Lessons from the MHC. Evolution. 2003, 57 (8): 1707-1722.PubMedView ArticleGoogle Scholar
- Piertney SB, Oliver MK: The evolutionary ecology of the major histocompatibility complex. Heredity. 2006, 96 (1): 7-21.PubMedGoogle Scholar
- Apanius V, Penn D, Slev PR, Ruff LR, Potts WK: The nature of selection on the major histocompatibility complex. Crit Rev Immunol. 1997, 17 (2): 179-224.PubMedView ArticleGoogle Scholar
- Spurgin LG, Richardson DS: How pathogens drive genetic diversity: MHC, mechanisms and misunderstandings. Proc Roy Soc B. 2010, 277 (1684): 979-988. 10.1098/rspb.2009.2084.View ArticleGoogle Scholar
- Meyer-Lucht Y, Sommer S: MHC diversity and the association to nematode parasitism in the yellow-necked mouse (Apodemus flavicollis). Mol Ecol. 2005, 14 (7): 2233-2243. 10.1111/j.1365-294X.2005.02557.x.PubMedView ArticleGoogle Scholar
- Bonneaud C, Perez-Tris J, Federici P, Chastel O, Sorci G: Major histocompatibility alleles associated with local resistance to malaria in a passerine. Evolution. 2006, 60 (2): 383-389.PubMedView ArticleGoogle Scholar
- Westerdahl H, Waldenström J, Hansson B, Hasselquist D, von Schantz T, Bensch S: Associations between malaria and MHC genes in a migratory songbird. Proc Roy Soc B. 2005, 272 (1571): 1511-1518. 10.1098/rspb.2005.3113.View ArticleGoogle Scholar
- Oppelt C, Starkloff A, Rausch P, Von Holst D, Rödel HG: Major histocompatibility complex variation and age-specific endoparasite load in subadult European rabbits. Mol Ecol. 2010, 19 (19): 4155-4167. 10.1111/j.1365-294X.2010.04766.x.PubMedView ArticleGoogle Scholar
- Burri R, Hirzel HN, Salamin N, Roulin A, Fumagalli L: Evolutionary patterns of MHC class IIB in owls and their implications for the understanding of avian MHC evolution. Mol Biol Evol. 2008, 25 (6): 1180-1191. 10.1093/molbev/msn065.PubMedView ArticleGoogle Scholar
- Nei M, Gu X, Sitnikova T: Evolution by the birth-and-death process in multigene families of the vertebrate immune system. Colloquium on Genetics and the Origin of Species: Jan 30-Feb 01 1997; Irvine, Ca: Natl Acad Sciences. 1997, 7799-7806.Google Scholar
- Nei M, Rooney AP: Concerted and birth-and-death evolution of multigene families. Ann Rev Gen. 2005, 39: 121-152. 10.1146/annurev.genet.39.073003.112240.View ArticleGoogle Scholar
- Hess CM, Edwards SV: The evolution of the major histocompatibility complex in birds. Bioscience. 2002, 52 (5): 423-431. 10.1641/0006-3568(2002)052[0423:TEOTMH]2.0.CO;2.View ArticleGoogle Scholar
- Kelley J, Walter L, Trowsdale J: Comparative genomics of major histocompatibility complexes. Immunogenetics. 2005, 56 (10): 683-695. 10.1007/s00251-004-0717-7.PubMedView ArticleGoogle Scholar
- Kulski JK, Shiina T, Anzai T, Kohara S, Inoko H: Comparative genomic analysis of the MHC: the evolution of class I duplication blocks, diversity and complexity from shark to man. Immunol Rev. 2002, 190 (1): 95-122. 10.1034/j.1600-065X.2002.19008.x.PubMedView ArticleGoogle Scholar
- Hosomichi K, Shiina T, Suzuki S, Tanaka M, Shimizu S, Iwamoto S, Hara H, Yoshida Y, Kulski JK, Inoko H, et al: The major histocompatibility complex (Mhc) class IIB region has greater genomic structural flexibility and diversity in the quail than the chicken. BMC Genomics. 2006, 7:Google Scholar
- Miller HC, Allendorf F, Daugherty CH: Genetic diversity and differentiation at MHC genes in island populations of tuatara (Sphenodon spp.). Mol Ecol. 2010, 19 (18): 3894-3908. 10.1111/j.1365-294X.2010.04771.x.PubMedView ArticleGoogle Scholar
- Ekblom R, Saether SA, Jacobsson P, Fiske P, Sahlman T, Grahn M, Kalas JA, Höglund J: Spatial pattern of MHC class II variation in the great snipe (Gallinago media). Mol Ecol. 2007, 16 (7): 1439-1451. 10.1111/j.1365-294X.2007.03281.x.PubMedView ArticleGoogle Scholar
- Siddle HV, Marzec J, Cheng YY, Jones M, Belov K: MHC gene copy number variation in Tasmanian devils: implications for the spread of a contagious cancer. Proc Roy Soc B. 2010, 277 (1690): 2001-2006. 10.1098/rspb.2009.2362.View ArticleGoogle Scholar
- Tanaka-Matsuda M, Ando A, Rogel-Gaillard C, Chardon P, Uenishi H: Difference in number of loci of swine leukocyte antigen classical class I genes among haplotypes. Genomics. 2009, 93 (3): 261-273. 10.1016/j.ygeno.2008.10.004.PubMedView ArticleGoogle Scholar
- Jacob JP, Milne S, Beck S, Kaufman J: The major and a minor class II beta-chain (B-LB) gene flank the Tapasin gene in the B-F/B-L region of the chicken major histocompatibility complex. Immunogenetics. 2000, 51 (2): 138-147. 10.1007/s002510050022.PubMedView ArticleGoogle Scholar
- Kennedy LJ, Ryvar R, Brown JJ, Ollier WER, Radford AD: Resolution of complex feline leukocyte antigen DRB loci by reference strand-mediated conformational analysis (RSCA). Tissue Antigens. 2003, 62 (4): 313-323. 10.1034/j.1399-0039.2003.00099.x.PubMedView ArticleGoogle Scholar
- Ekblom R, Grahn M, Höglund J: Patterns of polymorphism in the MHC class II of a non-passerine bird, the great snipe (Gallinago media). Immunogenetics. 2003, 54 (10): 734-741.PubMedGoogle Scholar
- Edwards SV, Gasper J, March M: Genomics and polymorphism of Agph-DAB1, an Mhc class II B gene in red-winged blackbirds (Agelaius phoeniceus). Mol Biol Evol. 1998, 15 (3): 236-250.PubMedView ArticleGoogle Scholar
- Westerdahl H, Wittzell H, von Schantz T: Polymorphism and transcription of Mhc class I genes in a passerine bird, the great reed warbler. Immunogenetics. 1999, 49 (3): 158-170. 10.1007/s002510050477.PubMedView ArticleGoogle Scholar
- Strand T, Westerdahl H, Höglund J, Alatalo RV, Siitari H: The Mhc class II of the Black grouse (Tetrao tetrix) consists of low numbers of B and Y genes with variable diversity and expression. Immunogenetics. 2007, 59 (9): 725-734. 10.1007/s00251-007-0234-6.PubMedView ArticleGoogle Scholar
- Lenz TL, Becker S: Simple approach to reduce PCR artefact formation leads to reliable genotyping of MHC and other highly polymorphic loci - Implications for evolutionary analysis. Gene. 2008, 427 (1-2): 117-123. 10.1016/j.gene.2008.09.013.PubMedView ArticleGoogle Scholar
- Babik W: Methods for MHC genotyping in non-model vertebrates. Mol Ecol Resour. 2010, 10 (2): 237-251. 10.1111/j.1755-0998.2009.02788.x.PubMedView ArticleGoogle Scholar
- Lenz TL, Eizaguirre C, Becker S, Reusch TBH: RSCA genotyping of MHC for high-throughput evolutionary studies in the model organism three-spined stickleback Gasterosteus aculeatus. BMC Evol Biol. 2009, 9 (57):Google Scholar
- Babik W, Taberlet P, Ejsmond MJ, Radwan J: New generation sequencers as a tool for genotyping of highly polymorphic multilocus MHC system. Mol Ecol Resour. 2009, 9 (3): 713-719. 10.1111/j.1755-0998.2009.02622.x.PubMedView ArticleGoogle Scholar
- Orita M, Iwahana H, Kanazawa H, Hayashi K, Sekiya T: Detection of Polymorphisms of Human DNA by Gel-Electrophoresis as Single-Strand Conformation Polymorphisms. PNAS. 1989, 86 (8): 2766-2770. 10.1073/pnas.86.8.2766.PubMedPubMed CentralView ArticleGoogle Scholar
- Makino R, Yazyu H, Kishimoto Y, Sekiya T, Hayashi K: F-SSCP: Fluorescence-based polymerase chain reaction-single-strand conformation polymorphism (PCR-SSCP) analysis. Genome Res. 1992, 2 (1): 10-13. 10.1101/gr.2.1.10.View ArticleGoogle Scholar
- Bryja J, Galan M, Charbonnel N, Cosson JF: Analysis of major histocompatibility complex class II gene in water voles using capillary electrophoresis-single stranded conformation polymorphism. Mol Ecol Notes. 2005, 5 (1): 173-176. 10.1111/j.1471-8286.2004.00855.x.View ArticleGoogle Scholar
- Miller KM, Ming TJ, Schulze AD, Withler RE: Denaturing gradient gel electrophoresis (DGGE): A rapid and sensitive technique to screen nucleotide sequence variation in populations. Biotechniques. 1999, 27 (5): 1016-1030.PubMedGoogle Scholar
- Arguello JR, Little AM, Pay AL, Gallardo D, Rojas I, Marsh SGE, Goldman JM, Madrigal JA: Mutation detection and typing of polymorphic loci through double-strand conformation analysis. Nature Genetics. 1998, 18 (2): 192-194. 10.1038/ng0298-192.PubMedView ArticleGoogle Scholar
- Brouwer L, Barr I, van de Pol M, Burke T, Komdeur J, Richardson DS: MHC-dependent survival in a wild population: evidence for hidden genetic benefits gained through extra-pair fertilizations. Mol Ecol. 2010, 19 (16): 3444-3455. 10.1111/j.1365-294X.2010.04750.x.PubMedView ArticleGoogle Scholar
- Worley K, Gillingham M, Jensen P, Kennedy LJ, Pizzari T, Kaufman J, Richardson DS: Single locus typing of MHC class I and class IIB loci in a population of red jungle fowl. Immunogenetics. 2008, 60 (5): 233-247. 10.1007/s00251-008-0288-0.PubMedView ArticleGoogle Scholar
- Hale ML, Verduijn MH, Moller AP, Wolff K, Petrie M: Is the peacock's train an honest signal of genetic quality at the major histocompatibility complex?. J Evol Biol. 2009, 22 (6): 1284-1294. 10.1111/j.1420-9101.2009.01746.x.PubMedView ArticleGoogle Scholar
- Noakes MA, Reimer T, Phillips RB: Genotypic characterization of an MHC class II locus in lake trout (Salvelinus namaycush) from Lake Superior by single-stranded conformational polymorphism analysis and reference strand-mediated conformational analysis. Mar Biotechnol. 2003, 5 (3): 270-278. 10.1007/s10126-002-0079-9.PubMedView ArticleGoogle Scholar
- Baquero JE, Miranda S, Murillo O, Mateus H, Trujillo E, Suarez C, Patarroyo ME, Parra-Lopez C: Reference strand conformational analysis (RSCA) is a valuable tool in identifying MHC-DRB sequences in three species of Aotus monkeys. Immunogenetics. 2006, 58 (7): 590-597. 10.1007/s00251-006-0101-x.PubMedView ArticleGoogle Scholar
- Sun YY, Zhao DD, Jin L, Liu N, Liang F, Kong FH, Xi YZ: Human leukocyte antigens A and B loci genotyping by reference strand-mediated conformation analysis in hematopoietic stem cell transplantation donor selection. Int J Hemat. 2007, 86 (1): 77-83. 10.1532/IJH97.A10611.View ArticleGoogle Scholar
- Ramon DS, Arguello JR, Cox ST, McWhinnie A, Little AM, Marsh SGE, Madrigal JA: Application of RSCA for the typing of HLA-DPB1. Human Immunology. 1998, 59 (11): 734-747. 10.1016/S0198-8859(98)00079-2.PubMedView ArticleGoogle Scholar
- Tanaka-Takahashi Y, Yasunami M, Naruse T, Hinohara K, Matano T, Mori K, Miyazawa M, Honda M, Yasutomi Y, Nagai Y, et al: Reference strand-mediated conformation analysis-based typing of multiple alleles in the rhesus macaque MHC class I Mamu-A and Mamu-B loci. Electrophoresis. 2007, 28 (6): 918-924. 10.1002/elps.200600586.PubMedView ArticleGoogle Scholar
- Garcia-Ortiz JE, Sandoval-Ramirez L, Rangel-Villalobos H, Maldonado-Torres H, Cox S, Garcia-Sepulveda CA, Figuera LE, Marsh SGE, Little AM, Madrigal JA, et al: High-resolution molecular characterization of the HLA class I and class II in the Tarahumara Amerindian population. Tissue Antigens. 2006, 68 (2): 135-146. 10.1111/j.1399-0039.2006.00636.x.PubMedView ArticleGoogle Scholar
- Pratt BF, O'Connor DH, Lafont BAP, Mankowski JL, Fernandez CS, Triastuti R, Brooks AG, Kent SJ, Smith MZ: MHC class I allele frequencies in pigtail macaques of diverse origin. Immunogenetics. 2006, 58 (12): 995-1001. 10.1007/s00251-006-0164-8.PubMedView ArticleGoogle Scholar
- Feichtlbauer-Huber P, Stear MJ, Fries R, Buitkamp J: Reference-strand-mediated conformation analysis of MHC alleles: a new method for high-resolution typing of the Ovar-DQB genes. Immunogenetics. 2000, 51 (1): 65-68. 10.1007/s002510050010.PubMedView ArticleGoogle Scholar
- Krebs KC, Jin ZY, Rudersdorf R, Hughes AL, O'Connor DH: Unusually high frequency MHC class I alleles in Mauritian origin Cynomolgus macaques. J Immunol. 2005, 175 (8): 5230-5239.PubMedView ArticleGoogle Scholar
- Turner D, Akpe S, Brown J, Brown C, McWhinnie A, Madrigal A, Navarrete C: HLA-B typing by reference strand mediated conformation analysis using a capillary-based semiautomated genetic analyzer. Human Immunology. 2001, 62 (4): 414-418. 10.1016/S0198-8859(01)00213-0.PubMedView ArticleGoogle Scholar
- Turner DM, Poles A, Brown J, Arguello JR, Madrigal JA, Navarrete CV: HLA-A typing by reference strand-mediated conformation analysis (RSCA) using a capillary-based semi-automated genetic analyser. Tissue Antigens. 1999, 54 (4): 400-404. 10.1034/j.1399-0039.1999.540410.x.PubMedView ArticleGoogle Scholar
- Blasky AJ, Karl JA, Wiseman RW, Read DS, O'Connor DH: Rapid high-resolution MHC class I genotyping of Chinese rhesus macaques by capillary reference strand-mediated conformational analysis. Immunogenetics. 2008, 60 (10): 575-584. 10.1007/s00251-008-0315-1.PubMedPubMed CentralView ArticleGoogle Scholar
- Drake GJC, Kennedy LJ, Auty HK, Ryvar R, Ollier WER, Kitchener AC, Freeman AR, Radford AD: The use of reference strand-mediated conformational analysis for the study of cheetah (Acinonyx jubatus) feline leucocyte antigen class II DRB polymorphisms. Mol Ecol. 2004, 13 (1): 221-229. 10.1046/j.1365-294X.2003.02027.x.PubMedView ArticleGoogle Scholar
- Kennedy LJ, Quarmby S, Fretwell N, Martin AJ, Jones PG, Jones CA, Ollier WER: High-resolution characterization of the canine DLA-DRB1 locus using reference strand-mediated conformational analysis. 2nd International Conference on the Advances in Canine and Feline Genomics: Oct 14-16 2004; Utrecht, NETHERLANDS. 2004, 836-842.Google Scholar
- Koumi P, Green HE, Hartley S, Jordan D, Lahec S, Livett RJ, Tsang KW, Ward DM: Evaluation and validation of the ABI 3700, ABI 3100 and the MegaBACE 1000 capillary array electrophoresis instruments for use with short tandem repeat microsatellite typing in a forensic environment. Electrophoresis. 2004, 25 (14): 2227-2241. 10.1002/elps.200305976.PubMedView ArticleGoogle Scholar
- Crowe TM, Bowie RCK, Bloomer P, Mandiwana TG, Hedderson TAJ, Randi E, Pereira SL, Wakeling J: Phylogenetics, biogeography and classification of, and character evolution in, gamebirds (Aves: Galliformes): effects of character exclusion, data partitioning and missing data. Cladistics. 2006, 22 (6): 495-532. 10.1111/j.1096-0031.2006.00120.x.View ArticleGoogle Scholar
- Chaves LD, Faile GM, Krueth SB, Hendrickson JA, Reed KM: Haplotype variation, recombination, and gene conversion within the turkey MHC-B locus. Immunogenetics. 2010, 62 (7): 465-477. 10.1007/s00251-010-0451-2.PubMedView ArticleGoogle Scholar
- Wittzell H, Bernot A, Auffray C, Zoorob R: Concerted evolution of two Mhc class II B loci in pheasants and domestic chickens. Mol Biol Evol. 1999, 16 (4): 479-490.PubMedView ArticleGoogle Scholar
- Anmarkrud JA, Johnsen A, Bachmann L, Lifjeld JT: Ancestral polymorphism in exon 2 of bluethroat (Luscinia svecica) MHC class II B genes. J of Evol Biol. 2010, 23 (6): 1206-1217. 10.1111/j.1420-9101.2010.01999.x.View ArticleGoogle Scholar
- Bollmer JL, Dunn PO, Whittingham LA, Wimpee C: Extensive MHC Class II B Gene Duplication in a Passerine, the Common Yellowthroat (Geothlypis trichas). J Heredity. 2010, 101 (4): 448-460. 10.1093/jhered/esq018.View ArticleGoogle Scholar
- Castillo S, Srithayakumar V, Meunier V, Kyle CJ: Characterization of Major Histocompatibility Complex (MHC) DRB Exon 2 and DRA Exon 3 Fragments in a Primary Terrestrial Rabies Vector (Procyon lotor). PLoS ONE. 2010, 5 (8): e12066-10.1371/journal.pone.0012066.PubMedPubMed CentralView ArticleGoogle Scholar
- Kennedy LJ, Modrell A, Groves P, Wei Z, Single RM, Happ GM: Genetic diversity of the major histocompatibility complex class II in Alaskan caribou herds. Intl J Immunogenet. 2011, 38 (2): 109-119. 10.1111/j.1744-313X.2010.00973.x.View ArticleGoogle Scholar
- Alcaide M, Lopez L, Tanferna A, Blas J, Sergio F, Hiraldo F: Simultaneous analysis of multiple PCR amplicons enhances capillary SSCP discrimination of MHC alleles. Electrophoresis. 2010, 31 (8): 1353-1356. 10.1002/elps.200900709.PubMedView ArticleGoogle Scholar
- Kloch A, Babik W, Bajer A, SiNSki E, Radwan J: Effects of an MHC-DRB genotype and allele number on the load of gut parasites in the bank vole Myodes glareolus. Mol Ecol. 2010, 19: 255-265.PubMedView ArticleGoogle Scholar
- Zagalska-Neubauer M, Babik W, Stuglik M, Gustafsson L, Cichon M, Radwan J: 454 sequencing reveals extreme complexity of the class II Major Histocompatibility Complex in the collared flycatcher. BMC Evol Biol. 2010, 10 (1): 395-10.1186/1471-2148-10-395.PubMedPubMed CentralView ArticleGoogle Scholar
- Lebigre C, Alatalo RV, Siitari H, Parri S: Restrictive mating by females on black grouse leks. Mol Ecol. 2007, 16 (20): 4380-4389. 10.1111/j.1365-294X.2007.03502.x.PubMedView ArticleGoogle Scholar
- Höglund J, Alatalo RV, Lundberg A, Rintamaki PT, Lindell J: Microsatellite markers reveal the potential for kin selection on black grouse leks. Proc Roy Soc B. 1999, 266 (1421): 813-816. 10.1098/rspb.1999.0710.View ArticleGoogle Scholar
- Sambrook J, Frotsch E, Maniatis T: Molecular cloning: a laboratory manual. 1989, NY: Cold Spring Harbour Laboratory, Press, Cold Springs Harbour, 2Google Scholar
- Paxton RJ, Thoren PA, Tengo J, Estoup A, Pamilo P: Mating structure and nestmate relatedness in a communal bee, Andrena jacobi (Hymenoptera, Andrenidae), using microsatellites. Mol Ecol. 1996, 5 (4): 511-519. 10.1111/j.1365-294X.1996.tb00343.x.PubMedView ArticleGoogle Scholar
- Höglund J, Larsson JK, Corrales C, Santafé G, Baines D, Segelbacher G: Genetic structure among black grouse in Britain: implications for designing conservation units. Anim Cons. 2011, 14: 10.1111/j.1469-1795.2011.00436.x.Google Scholar
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