Single nucleotide polymorphism genotyping by mini-primer allele-specific amplification with universal reporter primers for identification of degraded DNA

Single nucleotide polymorphism (SNP) is informative for human identification, and much shorter regions are targeted in analysis of biallelic SNP compared with highly polymorphic short tandem repeat (STR). Therefore, SNP genotyping is expected to be more sensitive than STR genotyping of degraded human DNA. To achieve simple, economical, and sensitive SNP genotyping for identification of degraded human DNA, we developed 18 loci for a SNP genotyping technique based on the mini-primer allele-specific amplification (ASA) combined with universal reporter primers (URP). The URP/ASA-based genotyping consisted of two amplifications followed by detection using capillary electrophoresis. The sizes of the target genome fragments ranged from 40 to 67 bp in length. In the Japanese population, the frequencies of minor alleles of 18 SNPs ranged from 0.36 to 0.50, and these SNPs are informative for identification. The success rate of SNP genotyping was much higher than that of STR genotyping of artificially degraded DNA. Moreover, we applied this genotyping method to case samples and showed successful SNP genotyping of severely degraded DNA from a 4-year buffered formalin-fixed tissue sample for human identification.     

应用改进的通用荧光PCR引物进行多重STR分型

通过设计通用荧光PCR引物并结合DNA测序系统建立了小鼠的多重STR分型方案.实验针对小鼠基因组设计了两对不同的通用引物序列,标记了FAM荧光的通用序列和"加尾"的位点特异性引物共同用于小鼠的多重PCR的STR基因分型.本研究优化了通用引物和特异性引物间的比例,优化了多重STR-PCR的反应条件,并最终利用该技术方案实现了五重STR分型.实验验证了该方案在多重STR分型中的可行性.与传统的荧光检测PCR产物方案相比,应用通用方案完成多重PCR反应大大节省了实验时间与经费.     

微卫星复杂结构对分型的影响：以熊UamD116 和UamB1 为例

目的:微卫星是基因组上的短串联重复序列,具有高度多态性,表现为核心序列中重复单位的重复次数的变化,这种变化造成不同等位基因核心序列的长度不同。因此,其基因型主要依靠PCR扩增片段长度来判定。在各类研究中,人们更倾向于使用4碱基重复的微卫星以减少2碱基微卫星的stutter等问题的影响。但是4碱基微卫星核心序列结构复杂时,就会对分型的正确性产生影响,从而影响到下游分析的正确性。在很多野生动物的研究中,这一问题常常被忽略。本文以亚洲黑熊(Ursus thibetanus)的2个四碱基微卫星位点UamD116和UamB1为例,揭示内部结构对分型的影响。方法:我们选用96份亚洲黑熊样品(包括血液、肌肉组织和毛发等样品)进行微卫星分型研究,通过荧光标记的PCR扩增和毛细管电泳分型,比较了基于扩增片段长度的分型和基于序列核心结构的分型效果的差异。结果:UamD116核心序列结构除了含有多种不同的重复单位外,还在重复单位之间有碱基插入,出现单碱基T、二碱基TC和三碱基AAG插入;并在一类等位基因下游侧翼序列有1个GA缺失。基于序列结构的分型中可以将不同的等位基因分开,而在基于片段长度的分型中,容易将不同的等位基因合并为1个等位基因。在位点UamB1共发现两种类型的等位基因,在一类等位基因中出现一个3bp的插入,使等位基因之间的差异不再是4bp,而是1bp。在仅依据片段长度分型时,相差1bp的等位基因被认定为1个。此外,还有不同等位基因核心序列不同,但是二者长度完全一致。依据片段长度分型共发现8个等位基因,而经过序列分型确定的等位基因数为12个,相应地基因频率及其他遗传学参数都发生相应的改变。结论:对于核心序列结构复杂的微卫星必须通过等位基因测序来矫正片段长度分型的结果,才能得到可靠的群体遗传学结论。     

In search of polymorphic Alu insertions with restricted geographic distributions

Alu elements are transposable elements that have reached over one million copies in the human genome. Some Alu elements inserted in the genome so recently that they are still polymorphic for insertion presence or absence in human populations. Recently, there has been an increasing interest in using Alu variation for studies of human population genetic structure and inference of individual geographic origin. Currently, this requires a high number of Alu loci. Here, we used a linker-mediated polymerase chain reaction method to preferentially identify low-frequency Alu elements in various human DNA samples with different geographic origins. The candidate Alu loci were subsequently genotyped in 18 worldwide human populations (approximately 370 individuals), resulting in the identification of two new Alu insertions restricted to populations of African ancestry. Our results suggest that it may ultimately become possible to correctly infer the geographic affiliation of unknown samples with high levels of confidence without having to genotype as many as 100 Alu loci. This is desirable if Alu insertion polymorphisms are to be used for human evolution studies or forensic applications.     

Cloning and polymerase chain reaction-single-strand conformation polymorphism analysis of anonymous Alu repeats on chromosome 11.

We have shown that many of the Alu repeats found in the GenBank database are polymorphic and that this polymorphism can be detected by a simple technique, single-strand conformation polymorphism (SSCP) analysis, after polymerase chain reaction (PCR) amplification of each repeat from DNA of individuals. Here, we describe a method for collecting many anonymous Alu repeats and their flanks in a chromosome-specific phage library and cloning them into plasmids. The flanking single-copy sequences of each repeat in the plasmid were then determined, and 20mer to 30mer segments of these sequences were used as primers for the PCR-SSCP analysis. Many new polymorphic DNA markers on chromosome 11 were obtained with this method. These markers can also serve as sequence-tagged sites for physical mapping of the genome.     

毛细管电泳四色荧光检测法分析茶树SSR标记

将毛细管电泳四色荧光栓测技术应用于茶树SSR标记分析.该方法采用三引物PCR扩增SSR位点,三引物即在5'端加有M13尾巴序列(5'-CACGACGTTGTAAAACGAC-3')的特异正向引物、特异反向引物及带有荧光标记的通用型M13引物:为了运用四色荧光检测系统使通过一次毛细管电泳能同时检测3个以上的SSR位点,采用蓝、绿、黑3种不同颜色的荧光染料分别对3个M13引物进行标记. 应用该方法对42个茶树品种(系)的16个SSR位点进行遗传分析的结果表明:此法具有简便、可靠、低成本及高通量的优点;且随着所分析SSR位点数的增加,降低成本的效果更加显著.采用建立的方法,还筛选获得了11个多态性丰富的可应用于茶树遗传研究的SSR标记.     

TECHNICAL ADVANCES: Effects of genotyping protocols on success and errors in identifying individual river otters (Lontra canadensis) from their faeces

In noninvasive genetic sampling, when genotyping error rates are high and recapture rates are low, misidentification of individuals can lead to overestimation of population size. Thus, estimating genotyping errors is imperative. Nonetheless, conducting multiple polymerase chain reactions (PCRs) at multiple loci is time-consuming and costly. To address the controversy regarding the minimum number of PCRs required for obtaining a consensus genotype, we compared consumer-style the performance of two genotyping protocols (multiple-tubes and 'comparative method') in respect to genotyping success and error rates. Our results from 48 faecal samples of river otters (Lontra canadensis) collected in Wyoming in 2003, and from blood samples of five captive river otters amplified with four different primers, suggest that use of the comparative genotyping protocol can minimize the number of PCRs per locus. For all but five samples at one locus, the same consensus genotypes were reached with fewer PCRs and with reduced error rates with this protocol compared to the multiple-tubes method. This finding is reassuring because genotyping errors can occur at relatively high rates even in tissues such as blood and hair. In addition, we found that loci that amplify readily and yield consensus genotypes, may still exhibit high error rates (7-32%) and that amplification with different primers resulted in different types and rates of error. Thus, assigning a genotype based on a single PCR for several loci could result in misidentification of individuals. We recommend that programs designed to statistically assign consensus genotypes should be modified to allow the different treatment of heterozygotes and homozygotes intrinsic to the comparative method.     

Multiplex SNP-SCALE: a cost-effective medium-throughput single nucleotide polymorphism genotyping method

We describe a convenient, cost-effective and flexible medium-throughput single nucleotide polymorphism (SNP) genotyping method, Multiplex SNP-SCALE, which enables the simultaneous amplification by polymerase chain reaction (PCR) of up to 25 (or potentially more) loci followed by electrophoresis in an automated DNA sequencer. We extended the original SNP-SCALE method to include (i) use of a commercial multiplex PCR kit, (ii) a four-dye system, (iii) much-reduced (2-μL) reaction volumes, (iv) drying down of template DNA before PCR, (v) use of pig-tailed primers, (vi) a PCR product weighting system, (vii) a standard optimized touchdown PCR thermocycling programme, and (viii) software (SNP-SCALE Primer Designer) that automatically designs suitable SNP-SCALE primers for a batch of loci. This new protocol was validated for different types of SNPs. The method is cost- and time-effective for medium-scale evolutionary and ecological projects involving 10s to 100s of loci.     

The Association Between HLA-A Alleles and Young Alu Dimorphisms Near the HLA-J, -H,and -F Genes in Workshop Cell Lines and Japanese and Australian Populations

At least two polymorphic Alu insertions have been previously identified and characterized within the class I region of the major histocompatibility complex (MHC). We have identified another two new polymorphic Alu insertions, AluyHJ and AluyHF, located near HLA-J and HLA-F, respectively, within the a block of the MHC. Here we report on (1) the haplotypic relationships between the Alu dimorphisms and the HLA-A locus within a panel of 51 IHW homozygous cell lines representing at least 36 HLA class I haplotypes, (2) the Alu genotype, allele, and haplotype frequencies present in the Australian Caucasians and Japanese populations, and (3) the frequency of association between the different Alu dimorphisms and the HLA-A alleles in 109 Australian Caucasians and 99 Japanese. PCR was used to detect the presence or absence of insertion for AluyHJ, AluyHG, and AluyHF within the DNA samples prepared from the cell lines and the two population groups that had been previously typed for HLA-A. In the homozygous cell lines, all three Alu insertions were found in only one HLA class I haplotype (HLA-A1, -B57, -Cw6), no Alu insertions were detected in six HLA class I haplotypes and one or more of the Alu insertions were found in 29 HLA class I haplotypes. At least one of the Alu insertions was found in about 86% of the Japanese and Australian individuals, with the AluyHJ generally related inversely to AluyHG and/or AluyHF. The gene frequency of the AluyHJ and AluyHF insertions was significantly different (p <0.05) BETWEEN JAPANESE AND AUSTRALIANS, WHEREAS THERE WAS NO DIFFERENCE (P > 0.05) between the frequencies of AluyHG in the two populations. The Alu haplotype frequencies were also significantly different between the Japanese and the Australians. In the cell lines and the population groups, the AluyHJ insertion was most frequently found associated with HLA-A1 or A24, AluyHG with HLA-A2, and AluyHF with HLA-A2, -A10, or -A26. This study suggests that the three polymorphic Alu elements have been inserted into the a block of the MHC in different progenitor groups and therefore will be useful lineage and linkage markers in human population studies and for elucidating the evolution of HLA class I haplotypes.     

A Perfect Marker for Fragrance Genotyping in Rice

Allele specific amplification (ASA) is a low-cost, robust technique that can be utilised to discriminate between alleles that differ by SNP's, insertions or deletions, within a single PCR tube. Fragrance in rice, a recessive trait, has been shown to be due to an eight bp deletion and three SNP's in a gene on chromosome 8 which encodes a putative betaine aldehyde dehydrogenase 2 (BAD2). Here we report a single tube ASA assay which allows discrimination between fragrant and non-fragrant rice varieties and identifies homozygous fragrant, homozygous non-fragrant and heterozygous non-fragrant individuals in a population segregating for fragrance. External primers generate a fragment of approximately 580 bp as a positive control for each sample. Internal and corresponding external primers produce a 355 bp fragment from a non-fragrant allele and a 257 bp fragment from a fragrant allele, allowing simple analysis on agarose gels.     

Search for retroviral related DNA polymorphisms using RAPD PCR in schizophrenia

Random amplification of polymorphic DNA (RAPD) is widely used to detect polymorphisms in many organisms. Individual (or strain) specific amplified bands are generated with single or pairs of primers in PCR reactions and can serve as genetic markers. We have used this method to generate a large number of reproducible bands with single primers, random and retroviral related, on 92 human DNA samples. Theoretically, RAPD PCR presents a logical approach for assessing variability among individuals. We used ten retroviral related primers (12, 20 and 22 bp) and eight random primers (10 bp) to assess individual differences in the context of testing the retroviral hypothesis for schizophrenia. Three pairs of discordant monozygotic twins, four pairs of discordant full sibs and 53 schizophrenic individuals with 25 of their unrelated matched controls were analyzed. Ten of these primers resulted in a total of approx. 850 amplified bands (65-110 bands per primer). Almost all of these bands were identical among each individual analyzed. However, the results are inconclusive with respect to the retroviral hypothesis for schizophrenia. The general lack of RAPD polymorphism in this study may argue for mechanisms other than rearrangements such as inversions, associated with the evolution of the human genome.     

A refined panel of 42 microsatellite loci to universally genotype catarrhine primates

1. Microsatellite genotyping is an important genetic method for a number of research questions in biology. Given that the traditional fragment length analysis using polyacrylamide gel or capillary electrophoresis has several drawbacks, microsatellite genotyping‐by‐sequencing (GBS) has arisen as a promising alternative. Although GBS mitigates many of the problems of fragment length analysis, issues with allelic dropout and null alleles often remain due to mismatches in primer binding sites and unnecessarily long PCR products. This is also true for GBS in catarrhine primates where cross‐species amplification of loci (often human derived) is common.
2. We therefore redesigned primers for 45 microsatellite loci based on 17 available catarrhine reference genomes. Next, we tested them in singleplex and different multiplex settings in a panel of species representing all major lineages of Catarrhini and further validated them in wild Guinea baboons (Papio papio) using fecal samples.
3. The final panel of 42 microsatellite loci can efficiently be amplified with primers distributed into three amplification pools.
4. With our microsatellite panel, we provide a tool to universally genotype catarrhine primates via GBS from different sample sources in a cost‐ and time‐efficient way, with higher resolution, and comparability among laboratories and species.

     

Patterns of ancestral human diversity: an analysis of Alu-insertion and restriction-site polymorphisms

We have analyzed 35 widely distributed, polymorphic Alu loci in 715 individuals from 31 world populations. The average frequency of Alu insertions (the derived state) is lowest in Africa (.42) but is higher and similar in India (.55), Europe (.56), and Asia (.57). A comparison with 30 restriction-site polymorphisms (RSPs) for which the ancestral state has been determined shows that the frequency of derived RSP alleles is also lower in Africa (.35) than it is in Asia (.45) and in Europe (.46). Neighbor-joining networks based on Alu insertions or RSPs are rooted in Africa and show African populations as separate from other populations, with high statistical support. Correlations between genetic distances based on Alu and nuclear RSPs, short tandem-repeat polymorphisms, and mtDNA, in the same individuals, are high and significant. For the 35 loci, Alu gene diversity and the diversity attributable to population subdivision is highest in Africa but is lower and similar in Europe and Asia. The distribution of ancestral alleles is consistent with an origin of early modern human populations in sub-Saharan Africa, the isolation and preservation of ancestral alleles within Africa, and an expansion out of Africa into Eurasia. This expansion is characterized by increasing frequencies of Alu inserts and by derived RSP alleles with reduced genetic diversity in non-African populations.     

Non-traditional Alu evolution and primate genomic diversity

Alu elements belonging to the previously identified "young" subfamilies are thought to have inserted in the human genome after the divergence of humans from non-human primates and therefore should not be present in non-human primate genomes. Polymerase chain reaction (PCR) based screening of over 500 Alu insertion loci resulted in the recovery of a few "young" Alu elements that also resided at orthologous positions in non-human primate genomes. Sequence analysis demonstrated these "young" Alu insertions represented gene conversion events of pre-existing ancient Alu elements or independent parallel insertions of older Alu elements in the same genomic region. The level of gene conversion between Alu elements suggests that it may have a significant influence on the single nucleotide diversity within the genome. All the instances of multiple independent Alu insertions within the same small genomic regions were recovered from the owl monkey genome, indicating a higher Alu amplification rate in owl monkeys relative to many other primates. This study suggests that the majority of Alu insertions in primate genomes are the products of unique evolutionary events.     

Direct and crossover PCR amplification to facilitate Tn5supF-based sequencing of lambda phage clones.

The 264 bp mini-transposon Tn5supF was constructed to sequence DNAs cloned in phage lambda without extensive shotgun subcloning or primer walking. Unique sequences near each transposon end serve as primer binding sites, and a supF gene is used to select transposition to lambda. We describe here PCR methods that facilitate Tn5supF-based sequencing. In a first pass, insertions are mapped relative to the ends of the cloned fragment using pairs of primers specific for vector DNA next to the cloning site and for a Tn5supF end. Most insertions not mapped in this step are near the center of the cloned fragment or in the vector arms, and are then mapped relative to the two innermost insertions by 'crossover' PCR. This involves amplification from primers on different DNA molecules, and generates hybrid DNA products whose lengths correspond to the distances between the two insertions. We routinely amplified more than 6 kb in direct PCR and 3 kb in crossover PCR; at the limit we amplified up to approximately 10 kb in direct PCR and approximately 6 kb in crossover PCR, but not reproducibly. Crossover PCR products were also obtained with insertions separated by only 200 bp, indicating that no rare sites are needed to switch templates. PCR products were purified by adsorption and then elution from glass slurry, and sequenced directly. Ladders of more than 400 bp were obtained from primer sites on each DNA strand; 2 kb was read from crossover PCR products, and showed that they were amplified with fidelity. In conclusion, direct and crossover PCR methods expedite transposon insertion mapping, and yield templates for accurate sequencing of both DNA strands.     

The Basques according to polymorphic Alu insertions

Polymorphic Alu insertions provide a set of DNA markers of interest in human population genetics. Approximately 1000-2000 of these insertions have not reached fixation within the human genome. Each one of these polymorphic loci most probably resulted from a unique insertional event, and therefore all individuals possessing the insertion are related by descent not just state. In addition, the direction of mutational change is toward the gain of the Alu element at a particular locus. Therefore, the improved knowledge of both the ancestral state and the direction of mutational change greatly facilitates the analysis of population relationships. As a result, Alu insertion polymorphisms represent a significant tool for population genetic studies. In this study, polymorphic Alu insertions have been employed to ascertain phylogenetic relationships among Basque groups and worldwide populations. The Basques are considered to be a geographic isolate with a unique language and customs. They may be direct descendants of Cro-Magnon enclaves from the upper Paleolithic (38,000 to 10,000 years). The Basques are distributed among narrow valleys in northeastern Spain with little migration between them until recently. This characteristic may have had an effect on allelic frequency distributions. With the aim of studying this possible effect, we have analyzed six autosomal polymorphic Alu loci from four different sites within the Spanish Basque region in order to ascertain any genetic heterogeneity among the Basques. The results are consistent with a lack of homogeneity among these four autochthonous Basque groups.     

高保真酶特异性检测大鼠SNP基因型新方法

目的应用高保真酶（Pfu）和3’末端修饰引物在单管双向等位基因特异性扩增（SB-ASA）中区分SNP基因型,建立高保真酶特异性检测SNP基因型的新方法。方法选取近交系大鼠SNP位点,以RS8149053为例,设计两个外部引物和两个等位基因特异性引物,四引物3’末端进行硫代磷酸化修饰,应用高保真聚合酶（Pfu）进行特异性扩增,扩增结果测序验证其可靠性。结果在RS8149053 SNP位点（C/T）上,等位基因型CC扩增出179 bp目的片段,基因型TT扩增出597 bp目的片段,基因型不同则扩增出分子量不同的片段,目的条带测序结果与Rat Genome Database数据库基因型结果一致,高保真酶扩增结果稳定且特异性强。结论高保真酶等位基因特异性扩增技术能有效降低假阳性率,是一种快速、特异的SNP基因分型新方法。     

Evaluation of DNA pooling for the estimation of microsatellite allele frequencies: a case study using striped bass (Morone saxatilis)

Using striped bass (Morone saxatilis) and six multiplexed microsatellite markers, we evaluated procedures for estimating allele frequencies by pooling DNA from multiple individuals, a method suggested as cost-effective relative to individual genotyping. Using moment-based estimators, we estimated allele frequencies in experimental DNA pools and found that the three primary laboratory steps, DNA quantitation and pooling, PCR amplification, and electrophoresis, accounted for 23, 48, and 29%, respectively, of the technical variance of estimates in pools containing DNA from 2-24 individuals. Exact allele-frequency estimates could be made for pools of sizes 2-8, depending on the locus, by using an integer-valued estimator. Larger pools of size 12 and 24 tended to yield biased estimates; however, replicates of these estimates detected allele frequency differences among pools with different allelic compositions. We also derive an unbiased estimator of Hardy-Weinberg disequilibrium coefficients that uses multiple DNA pools and analyze the cost-efficiency of DNA pooling. DNA pooling yields the most potential cost savings when a large number of loci are employed using a large number of individuals, a situation becoming increasingly common as microsatellite loci are developed in increasing numbers of taxa.     

Identity by descent and DNA sequence variation of human SINE and LINE elements

To test the hypothesis that Alu and L1 elements are genetic characters that are essentially homoplasy-free, we sequenced a total of five human L1 elements and eleven recently integrated Alu elements from 160 chromosomes (80 individuals representing four diverse human populations). Analysis of worldwide samples at L1 loci revealed 292 segregating sites and a nucleotide diversity of 0.0050. For Ya5 Alu loci, there were 129 segregating sites and nucleotide diversity was estimated at 0.0045. The Alu and L1 sequence diversity varied element to element. No completely or partially deleted Alu or L1 alleles were identified during the analysis. These data suggest that mobile element insertions are identical by descent characters for the study of human population genetics.     

Microplate array diagonal gel electrophoresis for cohort studies of microsatellite loci

After PCR amplification, we have achieved precise sizing of trinucleotide and tetranucleotide microsatellite alleles on 96-well open-faced polyacrylamide microplate array diagonal gel electrophoresis (MADGE) gels: two tetranucleotide repeats, HUMTHOI (five alleles 248-263 bp) and DYS390 (eight alleles 200-228 bp), and DYS392, a trinucleotide repeat (eight alleles 210-231 bp). A gel matrix of Duracryl, a high mechanical strength polyacrylamide derivative, and appropriate ionic conditions provide the 1.3%-1.5% band resolution required. No end-labeling of primers is needed, as the sensitive Vistra Green intercalating dye is used for the visualization of bands. Co-run markers bracketing the PCR fragments ensure accurate sizing without inter-lane variability. Electrophoresis of multiple gels in a thermostatically controlled tank allows up to 1000 samples to be run in 90 min. Gel images were analyzed using a Fluorlmager 595 fluorescent scanning system, and alleles were identified using Phoretix software for band migration measurement and Microsoft Excel to compute fragment sizes. Estimated sizes were interpolated precisely to achieve accurate binning. Microsatellite-MADGE represents a utilitarian methodfor high-throughput genotyping in cohort studies, using standard laboratory equipment.