Whole-genome amplification in double-digest RADseq results in adequate libraries but fewer sequenced loci

Whole-genome amplification by multiple displacement amplification (MDA) is a promising technique to enable the use of samples with only limited amount of DNA for the construction of RAD-seq libraries. Previous work has shown that, when the amount of DNA used in the MDA reaction is large, double-digest RAD-seq (ddRAD) libraries prepared with amplified genomic DNA result in data that are indistinguishable from libraries prepared directly from genomic DNA. Based on this observation, here we evaluate the quality of ddRAD libraries prepared from MDA-amplified genomic DNA when the amount of input genomic DNA and the coverage obtained for samples is variable. By simultaneously preparing libraries for five species of weevils (Coleoptera, Curculionidae), we also evaluate the likelihood that potential contaminants will be encountered in the assembled dataset. Overall, our results indicate that MDA may not be able to rescue all samples with small amounts of DNA, but it does produce ddRAD libraries adequate for studies of phylogeography and population genetics even when conditions are not optimal. We find that MDA makes it harder to predict the number of loci that will be obtained for a given sequencing effort, with some samples behaving like traditional libraries and others yielding fewer loci than expected. This seems to be caused both by stochastic and deterministic effects during amplification. Further, the reduction in loci is stronger in libraries with lower amounts of template DNA for the MDA reaction. Even though a few samples exhibit substantial levels of contamination in raw reads, the effect is very small in the final dataset, suggesting that filters imposed during dataset assembly are important in removing contamination. Importantly, samples with strong signs of contamination and biases in heterozygosity were also those with fewer loci shared in the final dataset, suggesting that stringent filtering of samples with significant amounts of missing data is important when assembling data derived from MDA-amplified genomic DNA. Overall, we find that the combination of MDA and ddRAD results in high-quality datasets for population genetics as long as the sequence data is properly filtered during assembly.

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Whole genome amplification of buccal cell DNA: genotyping concordance before and after multiple displacement amplification

Clinical Chemistry and Laboratory Medicine (CCLM) ◽

10.1515/cclm.2005.026 ◽

2005 ◽

Vol 43 (2) ◽

Cited By ~ 19

Author(s):

Miles D. Thompson ◽

Raffick A. R. Bowen ◽

Betty Y. L. Wong ◽

Joan Antal ◽

Zhanqin Liu ◽

...

Keyword(s):

Genomic Dna ◽

Whole Genome Amplification ◽

Multiple Displacement Amplification ◽

Buccal Cell ◽

Whole Genome ◽

Buccal Cells ◽

Genome Amplification ◽

Dna Yield ◽

Epidemiological Surveys ◽

Before And After

AbstractWhile buccal cells provide an easily accessible source of genomic DNA, the amount extracted may be insufficient for many studies. Whole genome amplification (WGA) using multiple displacement amplification (MDA) may optimize buccal cell genomic DNA yield. We compared the usefulness, in epidemiological surveys, of DNA derived from buccal cells collected by alcohol mouthwash and amplified by WGA protocol and standard protocols. Buccal cell collection kits were mailed to 300 randomly selected members of a large cohort study, and 189 subjects returned buccal cell samples. We determined: (i) which QIAamp

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Quantifying genome DNA during whole-genome amplification via quantitative real-time multiple displacement amplification

RSC Advances ◽

10.1039/d0ra09021b ◽

2021 ◽

Vol 11 (8) ◽

pp. 4617-4621

Author(s):

Jing Tu ◽

Yi Qiao ◽

Yuhan Luo ◽

Naiyun Long ◽

Zuhong Lu

Keyword(s):

Real Time ◽

Whole Genome Amplification ◽

Multiple Displacement Amplification ◽

Whole Genome ◽

Genome Amplification

Monitoring multiple displacement amplification by fluorescence signals.

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187 EMBRYO GENOTYPING FROM IN VIVO BIOPSIED BOVINE EMBRYOS AFTER WHOLE GENOME AMPLIFICATION

Reproduction Fertility and Development ◽

10.1071/rdv21n1ab187 ◽

2009 ◽

Vol 21 (1) ◽

pp. 192 ◽

Cited By ~ 3

Author(s):

D. Le Bourhis ◽

Y. Amigues ◽

F. Charreaux ◽

S. Lacaze ◽

M. Tissier ◽

...

Keyword(s):

Genomic Dna ◽

Detection Rate ◽

Whole Genome Amplification ◽

Field Conditions ◽

Bovine Embryo ◽

Whole Genome ◽

Bovine Embryos ◽

Genome Amplification ◽

Number Of Cells

Genomic tools are now available for most livestock species and used routinely for marker-assisted selection (MAS) in cattle. The detection of a large number of markers that are widespread over the genome is generally limited by the amount of genomic DNA available in an embryo biopsy of a small size not to be detrimental to embryonic survival. Amplification of DNA from such a biopsy is then necessary. In this study, the efficiency of embryo genotyping for 45 microsatellites (MS) following whole-genome amplification (WGA) was evaluated from samples of a variable number of cells isolated from cattle embryos. In a second part, this work aims to test the reliability of the MAS method for 45 MS and 13 single nucleotide polymorphisms (SNP) from bovine embryo biopsies under field conditions. In experiment 1, in vitro bovine morulae (n = 10) were produced, and 1, 5, and 10 embryonic cells were removed from each morula. Cells were dry frozen in tubes before further processing. Whole-genome amplification was performed using the commercial Qiagen REPLI-g® Mini Kit according to the manufacturer instructions (Qiagen, Valencia, CA, USA). WGA solution was then diluted, processed by PCR with 45 markers, and the resulting data were genotyped with GeneMapper software® (Applied Biosystems Europe). Accuracy and reliability of genotyping were assessed using different samples of cells from the same embryo. In experiment 2, after superovulation (10 cows), bovine embryos were in vivo-produced and collected at day 6 or day 7 of pregnancy. Only grade 1 embryos were washed and biopsied using a microblade. Biopsied embryos were either frozen or transferred back to synchronized recipients. Individual biopsies were transferred as dry samples to the laboratory. Genomic DNA was amplified using WGA, and embryos were genotyped. The results of experiment 1 clearly indicate that a conventional biopsy of 5 to 10 cells was sufficient for multi-markers detection after whole-genome amplification as 98% of the 45 markers were detected compared to 45% of marker detection using 1 cell (P < 0.01). In experiment 2, from 123 collected embryos, 79 were classified as grade I or II transferable embryos (64.2%) and 57 were biopsied (34 were classified as stage 4–5 and 23 as stage 5–6, according to the IETS criteria). Using the stereomicroscopic analysis, 44 biopsies had a number of cells ranging from 4 to 7 (5.6 ± 1.4) and 13 biopsies from 8 to 10 (8.4 ± 1.6). Overall, at least 95% of markers (MS + SNP) were detected in 49.1% of biopsies (28/57). The total detection rate for SNP was significantly higher than for MS; 70.2% (40/57) v. 31.6% (18/57), respectively, (chi-square, P < 0.01). The detection rate of the markers was not significantly affected by the embryo stage or the biopsy size. Our results confirm that genotyping a large number of markers from biopsy samples after whole-genome amplification is possible under field conditions. A larger number of biopsies is required to assess the reliability of this method that may allow the development of MAS from early embryo. This work has been performed through the programme TYPAGENAE (GENANIMAL 4-03) with the financial support of FRT/ANR and Apis-Genes.

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