Room temperature DNA preservation of soft tissue for rapid DNA extraction: An addition to the disaster victim identification investigators toolkit?

Assessing the feasibility of free DNA for disaster victim identification and forensic applications

In tropical disaster victim identification (DVI) scenarios, challenging environmental conditions lead to accelerated DNA degradation in remains. To further enhance the utilization of leached DNA from tissue in the preservative solution (termed "free DNA") as an alternative source, we incorporated new results by assessing its integrity in postmortem and decomposing cadavers preserved in DNA/RNA Shield™ and modified TENT, with silica-based purification (QIAquick®) for faster processing. The psoas muscle tissues of one decomposed and ten cadavers were preserved in each solution at 25 °C and 35 °C for 3 months. Free DNA efficiency was compared with individual reference samples for reliable results in quantity, quality, and STR profiles. The findings revealed that DNA/RNA Shield™ effectively preserves free DNA integrity for extended storage, while modified TENT is more suitable for short-term storage due to higher degradation levels. Moreover, the use of free DNA samples with massive parallel sequencing displays potential for forensic DNA analysis. Successful amplification of the mtDNA control region enables variant calling and heteroplasmy analysis while also serving as quality control using ACTB and enabling differentiation within the 16S rRNA region for microbiome analysis. The simplicity of handling free DNA for PCR-based forensic analysis adds to its potential for various applications, including DVI and field-based analysis of biological evidence.

DNA Profiling in Forensic Science: A Review

DNA is present in most of the cells in our body, which is unique in each and every individual, and we leave a trail of it everywhere we go. This has become an advantage for forensic investigators who use DNA to draw conclusion in identification of victim and accused in crime scenes. This review described the use of genetic markers in forensic investigation and their limitations.

Collection and storage of DVI samples with microFLOQ® Direct swabs for direct amplification

The rapid identification of decomposing human remains is a crucial component of disaster victim identification (DVI), often occurring in remote areas without access to laboratory or storage facilities. Due to the ease of collection and amenability to storage in harsh conditions, swabs may be used to collect DNA from decomposing remains as an alternative to sampling tissue or bone. Direct amplification could further streamline the process and reduce costs. This study investigated the efficacy of direct amplification of DVI samples using microFLOQ® Direct swabs and the QIAGEN Investigator QS GO! Kit. A comparison of performance between direct amplification and traditional methods was made to assess whether direct amplification offered an improvement to traditional methods. DNA was collected by swabbing the muscle of a decomposing human cadaver using three swab types (ADS Genetics 4N6FLOQSwabs®, NADS Genetics 4N6FLOQSwabs®, and the microFLOQ® Direct swab). Traditional swabs (4N6FLOQSwabs®) were extracted and quantified, while a direct amplification strategy was used with the microFLOQ® Direct swabs coupled with the Investigator 24Plex GO! Kit. Processing of the microFLOQ® Direct swabs were optimized and a hybrid strategy that used 4N6FLOQSwabs® to collect and store DNA before swabbing or "subsampling" the 4N6FLOQSwabs® for processing with microFLOQ® Direct swabs was developed. This hybrid strategy allowed for rapid processing without the consumption of the original sample. Traditional and direct PCR methods were comparable up to day 10 of decomposition depending on the sample location and for up to 3 months of storage at room temperature. This research indicated that microFLOQ® Direct swabs in conjunction with the Investigator 24Plex GO! Kit can be used to facilitate rapid direct processing of DNA from decomposing human remains.

Evaluation of rapid DNA using ANDE™ in a technical exploitation Level 2 laboratory workflow

A trial of rapid DNA (rDNA), a fully automated DNA profiling system, within a technical exploitation (TE) workflow is an important endeavor. In the 2019 Ardent Defender (AD) exercise, the Deployable Technical Analysis Laboratory (DTAL), of the Canadian Department of National Defence (DND), evaluated the use of rDNA using ANDE™. Sixteen samples were processed during a pre-exercise "controlled" setting, 44 samples were from an "uncontrolled" environment during the exercise, and 22 samples were buccal swabs. The proportion of profiles suitable for upload to ANDE™ was 95.5% of buccal samples (21/22), 66.7% controlled samples, and 15.9% for uncontrolled samples. A considerable difference was observed in the proportions of complete DNA profiles obtained from all exploited items between the controlled (58.3%) and uncontrolled (15.9%) trials and in the proportions of samples where no DNA was detected (16.7% controlled trial vs. 56.8% uncontrolled trial). Overall, the trials highlighted the potential to gain identity intelligence using rDNA within a TE workflow and revealed the impact of operational constraints and the need to improve certain TE practices to gain the most benefit from rDNA. It also demonstrated the benefit of including an uncontrolled component for a more realistic indication of rDNA effectiveness in operational settings and highlighted operational practices impacting rDNA success. Mixture deconvolution was difficult as current guidelines do not consider some of the stochastic effects produced by the rDNA analysis; however, overall, the study demonstrated that rDNA using the ANDE™ instrument could be successfully incorporated into a TE workflow within a deployable laboratory.

DNA degradation in fish: Practical solutions and guidelines to improve DNA preservation for genomic research

The more demanding requirements of DNA preservation for genomic research can be difficult to meet when field conditions limit the methodological approaches that can be used or cause samples to be stored in suboptimal conditions. Such limitations may increase rates of DNA degradation, potentially rendering samples unusable for applications such as genome-wide sequencing. Nonetheless, little is known about the impact of suboptimal sampling conditions. We evaluated the performance of two widely used preservation solutions (1. DESS: 20% DMSO, 0.25 M EDTA, NaCl saturated solution, and 2. Ethanol >99.5%) under a range of storage conditions over a three-month period (sampling at 1 day, 1 week, 2 weeks, 1 month, and 3 months) to provide practical guidelines for DNA preservation. DNA degradation was quantified as the reduction in average DNA fragment size over time (DNA fragmentation) because the size distribution of DNA segments plays a key role in generating genomic datasets. Tissues were collected from a marine teleost species, the Australasian snapper, Chrysophrys auratus. We found that the storage solution has a strong effect on DNA preservation. In DESS, DNA was only moderately degraded after three months of storage while DNA stored in ethanol showed high levels of DNA degradation already within 24 hr, making samples unsuitable for next-generation sequencing. Here, we conclude that DESS was the most promising solution when storing samples for genomic applications. We recognize that the best preservation protocol is highly dependent on the organism, tissue type, and study design. We highly recommend performing similar experiments before beginning a study. This study highlights the importance of testing sample preservation protocols and provides both practical and economical advice to improve DNA preservation when sampling for genome-wide applications.

Long-term room temperature preservation of corpse soft tissue: an approach for tissue sample storage

Background

Disaster victim identification (DVI) represents one of the most difficult challenges in forensic sciences, and subsequent DNA typing is essential. Collected samples for DNA-based human identification are usually stored at low temperature to halt the degradation processes of human remains. We have developed a simple and reliable procedure for soft tissue storage and preservation for DNA extraction. It ensures high quality DNA suitable for PCR-based DNA typing after at least 1 year of room temperature storage.

Methods

Fragments of human psoas muscle were exposed to three different environmental conditions for diverse time periods at room temperature. Storage conditions included: (a) a preserving medium consisting of solid sodium chloride (salt), (b) no additional substances and (c) garden soil. DNA was extracted with proteinase K/SDS followed by organic solvent treatment and concentration by centrifugal filter devices. Quantification was carried out by real-time PCR using commercial kits. Short tandem repeat (STR) typing profiles were analysed with 'expert software'.

Results

DNA quantities recovered from samples stored in salt were similar up to the complete storage time and underscored the effectiveness of the preservation method. It was possible to reliably and accurately type different genetic systems including autosomal STRs and mitochondrial and Y-chromosome haplogroups. Autosomal STR typing quality was evaluated by expert software, denoting high quality profiles from DNA samples obtained from corpse tissue stored in salt for up to 365 days.

Conclusions

The procedure proposed herein is a cost efficient alternative for storage of human remains in challenging environmental areas, such as mass disaster locations, mass graves and exhumations. This technique should be considered as an additional method for sample storage when preservation of DNA integrity is required for PCR-based DNA typing.

Simplified field preservation of tissues for subsequent DNA analyses

Successful DNA-based identification of mass disaster victims depends on acquiring tissues that are not highly degraded. In this study, multiple protocols for field preservation of tissues for later DNA analysis were tested. Skin and muscle samples were collected from decaying pig carcasses. Tissues were preserved using cold storage, desiccation, or room temperature storage in preservative solutions for up to 6 months. DNA quality was assessed through amplification of successively larger segments of nuclear DNA. Solution-based storage, including a DMSO/NaCl/EDTA mixture, alcohols, and RNAlater preserved DNA of the highest quality, refrigeration was intermediate, and desiccation was least effective. Tissue type and extent of decomposition significantly affected stored DNA quality. Overall, the results indicate that any tissue preservation attempt is far superior to delaying or forgoing preservation efforts, and that simple, inexpensive methods can be highly effective in preserving DNA, thus should be initiated as quickly as possible.

Genetic identification of decomposed cadavers using nails as DNA source

Blood or muscle can be used as a DNA source for the genetic identification of recently deceased persons. If the post mortem interval increases, bones and teeth are used. In this case, collection and DNA isolation will be more difficult and time consuming. The aim of this study was to evaluate the use of nails as an alternative DNA source for the genetic identification of decomposed cadavers. DNA extraction from 5mg of fingernails from 7 volunteers using 1h cell lysis in a standard buffer and a DNA purification on QIAamp DNA mini kit columns allowed to acquire a mean quantity of 100 ng DNA/mg nail. This was unexpected, as blood and muscle contain comparable amounts of DNA. Our protocol allowed to obtain full PowerPlex 16 DNA profiles from 10 cadavers characterized by post mortem intervals ranging from 5 days to more than 6 months. The good quality of these profiles indicated that DNA from nail is well preserved. In conclusion, nails are very easy to collect and contain large amounts of good quality DNA that can be extracted within a few hours. They may therefore represent an attractive DNA source not only for routine, but also for urgent genetic identification of decomposed cadavers.