DNA recovery and analysis from skeletal material in modern forensic contexts

Latham, Krista E.; Miller, Jessica J.

doi:10.1080/20961790.2018.1515594

Cited by 94 publications

(69 citation statements)

References 60 publications

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“…Teeth have been widely used for the study of aDNA 36 , 37 , though the 30-fold covered genome of an archaic hominin from Denisova Cave from a distal phalanx demonstrates molecular preservation in elements that are not typically considered for paleogenetics work 4 . Despite these successes, a systematic and extensive study of differential DNA preservation across multiple human skeletal elements, such as those done in the context of modern forensics 38 , 39 , has yet to be attempted on archaeological remains. Our limited understanding of DNA preservation across the human skeleton is a significant hurdle for the efficient, practical, and ethical study of aDNA, which has particular relevance to the field of ancient population genetics where large sample sizes are needed for robust analytical resolution.…”

Section: Introductionmentioning

confidence: 99%

A systematic investigation of human DNA preservation in medieval skeletons

Parker

Rohrlach

Friederich

et al. 2020

Sci Rep

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Ancient DNA (aDNA) analyses necessitate the destructive sampling of archaeological material. Currently, the cochlea, part of the osseous inner ear located inside the petrous pyramid, is the most sought after skeletal element for molecular analyses of ancient humans as it has been shown to yield high amounts of endogenous DNA. However, destructive sampling of the petrous pyramid may not always be possible, particularly in cases where preservation of skeletal morphology is of top priority. To investigate alternatives, we present a survey of human aDNA preservation for each of ten skeletal elements in a skeletal collection from Medieval Germany. Through comparison of human DNA content and quality we confirm best performance of the petrous pyramid and identify seven additional sampling locations across four skeletal elements that yield adequate aDNA for most applications in human palaeogenetics. Our study provides a better perspective on DNA preservation across the human skeleton and takes a further step toward the more responsible use of ancient materials in human aDNA studies.

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Section: Introductionmentioning

confidence: 99%

A systematic investigation of human DNA preservation in medieval skeletons

Parker

Rohrlach

Friederich

et al. 2020

Sci Rep

View full text Add to dashboard Cite

show abstract

“…Teeth have been widely used for the study of aDNA 33,34 , though the 30-fold covered genome of an archaic hominin from Denisova Cave from a distal phalanx demonstrates molecular preservation in elements that are not typically considered for paleogenetics work 4 . Despite these successes, a systematic and extensive study of differential DNA preservation across multiple human skeletal elements, such as those done in the context of modern forensics 35,36 , has yet to be attempted on archaeological remains. Our limited understanding of DNA preservation across the human skeleton is a significant hurdle for the efficient, practical, and ethical study of aDNA, which has particular relevance to the field of ancient population genetics where large sample sizes are needed for robust analytical resolution.DNA preservation can be influenced by many factors including burial practises and treatment of the deceased, geology, as well as environmental and climatic conditions 37 , where the chronological age of a sample is thought to play only a secondary role 38,39 .…”

mentioning

confidence: 99%

A systematic investigation of human DNA preservation in medieval skeletons

Parker

Rohrlach

Friederich

et al. 2020

Preprint

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Ancient DNA (aDNA) analyses necessitate the destructive sampling of archaeological material.Currently the dense inner portion of the petrous pyramid, the location of the skull that houses the inner ear, is the most sought after skeletal element for molecular analyses of ancient humans as it has been shown to yield high amounts of endogenous DNA. Destructive sampling of the petrous pyramid, assuming its recovery, is often not recommended for highly valued specimens. To investigate alternatives, we present a survey of human aDNA preservation for each of ten skeletal elements in a skeletal collection from Medieval Germany. Through comparison of human DNA content and quality we confirm best performance of the petrous pyramid and identify seven additional sampling locations across four skeletal elements that yield adequate aDNA for most applications in human palaeogenetics. Our study provides a better perspective on DNA preservation across the human skeleton and takes a further step toward the more responsible use of ancient materials in human aDNA studies. 2 26 27 28 29 30 31 32 33 34 35 36 37 38Recent advances in minimally invasive sampling techniques 26 have led to a better balance between preservation of the anthropological record and the need for the production of reliable genetic data 27,28 ; however, the threat of damage to internal microstructures that form an important basis of morphological assessments 29-31 can still introduce hesitancy on the part of curators and physical anthropologists in making the petrous pyramid available for aDNA applications. These factors, in conjunction with the chance of incomplete recovery of crania at excavation 32 or restricted sampling of highly valued specimens, make the identification of alternative sampling locations based on quantitative evaluations of DNA preservation across the skeleton of clear benefit. Teeth have been widely used for the study of aDNA 33,34 , though the 30-fold covered genome of an archaic hominin from Denisova Cave from a distal phalanx demonstrates molecular preservation in elements that are not typically considered for paleogenetics work 4 . Despite these successes, a systematic and extensive study of differential DNA preservation across multiple human skeletal elements, such as those done in the context of modern forensics 35,36 , has yet to be attempted on archaeological remains. Our limited understanding of DNA preservation across the human skeleton is a significant hurdle for the efficient, practical, and ethical study of aDNA, which has particular relevance to the field of ancient population genetics where large sample sizes are needed for robust analytical resolution.DNA preservation can be influenced by many factors including burial practises and treatment of the deceased, geology, as well as environmental and climatic conditions 37 , where the chronological age of a sample is thought to play only a secondary role 38,39 . To serve as a baseline for future investigations seeking to incorporate and extrapolate the effects of these sources of v...

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“…With decomposition over time or damage from heat (such as fire), the laboratory may also be faced with processing more difficult samples such as teeth and bones. In such samples, the DNA is chemically linked to the hydroxyapatite mineral matrix keeping it well protected, but at the same time necessitating prolonged and intensive pre‐processing of samples prior to DNA extraction (Brundin, Figdor, Sundqvist, & Sjögren, 2013; Latham & Miller, 2019). With man‐made disasters, be it accidents or acts of terror, casework samples may be contaminated with chemical, biological, or radiological (CBR) agents.…”

Section: Dna Extraction From Human Remains and Non‐conventional Samplesmentioning

confidence: 99%

Recent trends and developments in forensic DNA extraction

Chong

Thong

Syn

2020

WIREs Forensic Science

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The extraction of DNA is a fairly standard procedure routinely undertaken in biological academic and research settings. In a forensic DNA context, DNA extraction is the crucial first step toward the generation of DNA profiles used to support convictions or exonerations in the criminal justice system. However, it is often complicated by the additional challenge of yielding sufficient quantities of clean DNA that is free from environmental inhibitors, from a wide spectrum of sample types which may contain limited quantities of biological material. While improvements in methods and technology over the decades have sped up and simplified the process of DNA extraction, several issues remain to be fully addressed—such as the incomplete separation of spermic DNA from sperm‐epithelial cell mixtures, increasing demands for ever‐faster DNA results, or even on‐scene DNA processing, and processing of difficult samples such as skeletal remains or samples contaminated by Chemical, Biological, or Radiological (CBR) agents. These challenges are often compounded by high work volumes and limited quantities of starting material. As such, this review focuses on recent trends and developments in four areas of forensic DNA extraction: (a) analysis of sexual assault evidence which often represents a significant portion of a forensic DNA laboratory's casework, (b) use of portable rapid DNA instruments which has gained much traction among law enforcement in recent times, (c) DNA extraction from difficult and CBR‐contaminated samples which, albeit rare, would be essential in a DNA laboratory's toolbox in the event of an incident, and (d) bypassing DNA extraction altogether. This article is categorized under: Forensic Biology > Forensic DNA Technologies

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DNA recovery and analysis from skeletal material in modern forensic contexts

Cited by 94 publications

References 60 publications

A systematic investigation of human DNA preservation in medieval skeletons

A systematic investigation of human DNA preservation in medieval skeletons

A systematic investigation of human DNA preservation in medieval skeletons

Recent trends and developments in forensic DNA extraction

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