Effects of sample age on data quality from targeted sequencing of museum specimens: what are we capturing in time?

McGaughran, Angela

doi:10.1186/s12864-020-6594-0

Cited by 17 publications

(10 citation statements)

References 75 publications

(98 reference statements)

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“…Short-read next-generation sequencing methods require short fragments of DNA and can sequence DNA from old specimens. Thus, NGS has become a common alternative to PCR and Sanger sequencing, enabling incorporation of museum and herbarium samples in projects that require DNA sequencing (McGaughran, 2020;Mayer et al, 2021;Raxworthy and Smith, 2021). However, severe degradation that produces fragment lengths below the target length of the sequencing method will likely prevent a sample from being captured.…”

Section: Dna Concentrationmentioning

confidence: 99%

Predictors of sequence capture in a large-scale anchored phylogenomics project

et al. 2022

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Next-generation sequencing (NGS) technologies have revolutionized phylogenomics by decreasing the cost and time required to generate sequence data from multiple markers or whole genomes. Further, the fragmented DNA of biological specimens collected decades ago can be sequenced with NGS, reducing the need for collecting fresh specimens. Sequence capture, also known as anchored hybrid enrichment, is a method to produce reduced representation libraries for NGS sequencing. The technique uses single-stranded oligonucleotide probes that hybridize with pre-selected regions of the genome that are sequenced via NGS, culminating in a dataset of numerous orthologous loci from multiple taxa. Phylogenetic analyses using these sequences have the potential to resolve deep and shallow phylogenetic relationships. Identifying the factors that affect sequence capture success could save time, money, and valuable specimens that might be destructively sampled despite low likelihood of sequencing success. We investigated the impacts of specimen age, preservation method, and DNA concentration on sequence capture (number of captured sequences and sequence quality) while accounting for taxonomy and extracted tissue type in a large-scale butterfly phylogenomics project. This project used two probe sets to extract 391 loci or a subset of 13 loci from over 6,000 butterfly specimens. We found that sequence capture is a resilient method capable of amplifying loci in samples of varying age (0–111 years), preservation method (alcohol, papered, pinned), and DNA concentration (0.020 ng/μl - 316 ng/ul). Regression analyses demonstrate that sequence capture is positively correlated with DNA concentration. However, sequence capture and DNA concentration are negatively correlated with sample age and preservation method. Our findings suggest that sequence capture projects should prioritize the use of alcohol-preserved samples younger than 20 years old when available. In the absence of such specimens, dried samples of any age can yield sequence data, albeit with returns that diminish with increasing age.

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Section: Dna Concentrationmentioning

confidence: 99%

Predictors of sequence capture in a large-scale anchored phylogenomics project

et al. 2022

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“…However, without a framework to guide specimen selection, genomic work on formalin-preserved museum tissues will remain infeasible. It is probably impossible to fully know the numerous and interdependent factors driving sequencing success, for example, age of the specimen (McGaughran, 2020;Watanabe et al, 2017), method of preservation (Zimmermann et al, 2008), postmortem interval (Bär et al, 1988) and heat and light exposure during storage. However, identification of metrics with which to prescreen specimens for sequencing suitability will improve yield of genomic data while reducing unnecessary destruction of specimens.…”

Section: Introductionmentioning

confidence: 99%

Unlocking inaccessible historical genomes preserved in formalin

Hahn¹,

Alexander²,

Grealy³

et al. 2021

Molecular Ecology Resources

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Museum specimens represent an unparalleled record of historical genomic data.However, the widespread practice of formalin preservation has thus far impeded genomic analysis of a large proportion of specimens. Limited DNA sequencing from formalin-preserved specimens has yielded low genomic coverage with unpredictable success. We set out to refine sample processing methods and to identify specimen characteristics predictive of sequencing success. With a set of taxonomically diverse specimens collected between 1962 and 2006 and ranging in preservation quality, we compared the efficacy of several end-to-end whole genome sequencing workflows alongside a k-mer-based trimming-free read alignment approach to maximize mapping of endogenous sequence. We recovered complete mitochondrial genomes and up to 3× nuclear genome coverage from formalin-preserved tissues. Hot alkaline lysis coupled with phenol-chloroform extraction out-performed proteinase K digestion in recovering DNA, while library preparation method had little impact on sequencing success. The strongest predictor of DNA yield was overall specimen condition, which additively interacts with preservation conditions to accelerate DNA degradation. Here, we demonstrate a significant advance in capability beyond limited recovery of a small number of loci via PCR or target-capture sequencing. To facilitate strategic selection of suitable specimens for genomic sequencing, we present a decision-making framework that utilizes independent and nondestructive assessment criteria. Sequencing of formalin-preserved specimens will contribute to a greater understanding of temporal trends in genetic adaptation, including those associated with a changing climate. Our work enhances the value of museum collections worldwide by unlocking genomes of specimens that have been disregarded as a valid molecular resource.

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“…Our findings are unlikely to be the result of technical issues associated with the use of historical DNA (hDNA). In general, capture sequencing of hDNA has a lower sequencing depth and coverage leading to fewer mapped reads and thus more missing data with increasing sample age 47 , both of which could affect downstream population genomic inferences 48 – 50 . Although our historical samples presented fewer reads than the contemporary samples, the level of missing data was generally low, even for the oldest samples (maximum level of missing data allowed was 5% per SNP).…”

Section: Discussionmentioning

confidence: 99%

Retrospective genomics highlights changes in genetic composition of tiger sharks (Galeocerdo cuvier) and potential loss of a south-eastern Australia population

Manuzzi

Jiménez‐Mena

Henriques

et al. 2022

Sci Rep

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Over the last century, many shark populations have declined, primarily due to overexploitation in commercial, artisanal and recreational fisheries. In addition, in some locations the use of shark control programs also has had an impact on shark numbers. Still, there is a general perception that populations of large ocean predators cover wide areas and therefore their diversity is less susceptible to local anthropogenic disturbance. Here we report on temporal genomic analyses of tiger shark (Galeocerdo cuvier) DNA samples that were collected from eastern Australia over the past century. Using Single Nucleotide Polymorphism (SNP) loci, we documented a significant change in genetic composition of tiger sharks born between ~1939 and 2015. The change was most likely due to a shift over time in the relative contribution of two well-differentiated, but hitherto cryptic populations. Our data strongly indicate a dramatic shift in the relative contribution of these two populations to the overall tiger shark abundance on the east coast of Australia, possibly associated with differences in direct or indirect exploitation rates.

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Effects of sample age on data quality from targeted sequencing of museum specimens: what are we capturing in time?

Cited by 17 publications

References 75 publications

Predictors of sequence capture in a large-scale anchored phylogenomics project

Predictors of sequence capture in a large-scale anchored phylogenomics project

Unlocking inaccessible historical genomes preserved in formalin

Retrospective genomics highlights changes in genetic composition of tiger sharks (Galeocerdo cuvier) and potential loss of a south-eastern Australia population

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