Whole human blood DNA degradation associated with artificial ultraviolet and solar radiations as a function of exposure time.

Laboratory investigations were conducted to evaluate the effect of ultraviolet radiation components and solar radiation exposure as a function of time on the degradation of whole human blood DNA from the standpoint of forensic analysis. Ten µL of whole human male blood samples were exposed to UV-A, UV-B, UV-C, and solar radiation at 20 min intervals up to 120 min. Allele frequencies of 16 short tandem repeat (STR) markers were monitored by employing current forensic typing DNA techniques. The STR markers were grouped into high, medium, and low molecular weight categories. Results revealed that even 20 min exposure to 4.89 eV UV-C photons (ʎ = 254 nm) with radiation intensity of 1200 µW/cm2 would degrade whole human male blood DNA samples significantly, making them unfit for human identification due to the breakdown of high molecular weight STRs. Exposure of blood samples to 4.11 eV UV-B photons (ʎ = 302 nm) with radiation intensity of 900 µW/cm2 resulted in complete degradation of high molecular weight STRs after 60 min. Partial breakdown of medium and low molecular weight STRs started after 80 min exposure. The degradation index (DI) values appear to show that the degradation of the DNA template molecule was relatively less in the low molecular weight DNA fragments as compared with high molecular weight DNA fragments. This finding indicates that genetic profiles obtained from whole human male blood exposed to this radiation for 60 min will give inconclusive results. Samples exposed up to 120 min to 3.40 eV UV-A photons (ʎ = 365 nm) and 3.10-3.94 eV photons of solar radiation did not appear to produce appreciable degradation in any of three molecular weight STRs in the whole human blood DNA samples.

Degradation of nuclear and mitochondrial DNA after γ-irradiation and its effect on forensic genotyping.

Forensic genotyping can be impeded by γ-irradiation of biological evidence in the event of radiological crime; that is, criminal activity involving radioactive material. Oxidative effects within the mitochondria of living cells elicits greater damage to mitochondrial DNA (mtDNA) than nuclear DNA (nuDNA) at low doses. This study presents a novel approach for the assessment of nuDNA versus mtDNA damage from a comparison of genotype and quantity data, while exploring likely mechanisms for differential damage after high doses of γ-irradiation. Liquid (hydrated) and dried (dehydrated) whole blood samples were exposed to high doses of γ-radiation (1-50 kilogray, kGy). The GlobalFiler PCR Amplification Kit was used to evaluate short tandem repeat (STR) genotyping efficacy and nuDNA degradation; a comparison was made to mtDNA degradation measured using real-time PCR assays. Each assay was normalized before comparison by calculation of integrity indices relative to unirradiated controls. Full STR profiles were attainable up to the highest dose, although DNA degradation was noticeable after 10 and 25 kGy for hydrated and dehydrated blood, respectively. This was manifested by heterozygote imbalance more than allele dropout. Degradation was greater for mtDNA than nuDNA, as well as for hydrated than dehydrated cells, after equivalent doses. Oxidative effects due to water radiolysis and mitochondrial function are dominant mechanisms of differential damage to nuDNA versus mtDNA after high-dose γ-irradiation. While differential DNA damage was reduced by cell desiccation, its persistence after drying indicates innate differences between nuDNA and mtDNA radioresistance and/or continued oxidative effects within the mitochondria.

Investigation of single nucleotide polymorphism loci susceptible to degradation by ultraviolet light.

DNA in biological fluids is often degraded by environmental factors. Given that single nucleotide polymorphism (SNP) analyses require shorter amplicons than short tandem repeat (STR) analyses do, their use in human identification using degraded samples has recently attracted attention. Although various SNP loci are used to analyze degraded samples, it is unclear which ones are more appropriate. To characterize and identify SNP loci that are susceptible or resistant to degradation, we artificially degraded DNA, obtained from buccal swabs from 11 volunteers, by exposure to ultraviolet (UV) light for different durations (254 nm for 5, 15, 30, 60, or 120 min) and analyzed the resulting SNP loci. DNA degradation was assessed using gel electrophoresis, STR, and SNP profiling. DNA fragmentation occurred within 5 min of UV irradiation, and successful STR and SNP profiling decreased with increasing duration. However, 73% of SNP loci were still detected correctly in DNA samples irradiated for 120 min, a dose that rendered STR loci undetectable. The unsuccessful SNP typing and the base call failure of nucleotides neighboring the SNPs were traced to rs1031825, and we found that this SNP was susceptible to UV light. When comparing the detection efficiencies of STR and SNP loci, SNP typing was more successful than STR typing, making it effective when using degraded DNA. However, it is important to use rs1031825 with caution when interpreting SNP analyses of degraded DNA.