Proteomic Characterization of Damaged Single Hairs Recovered after an Explosion for Protein-Based Human Identification.

Evidence recovery is challenging where an explosion has occurred. Though hair evidence may be sufficiently robust to be recovered at the site, forensic analysis underutilizes the matrix by relying on morphological analysis. Where DNA is compromised, particularly in hair, protein-based human identification presents a promising alternative. Detection of amino acid polymorphisms in hair proteins as genetically variant peptides (GVPs) permits the inference of individualizing single nucleotide polymorphisms for identification. However, an explosive blast may damage hair proteins and compromise GVP identification. This work assesses effects of an explosive blast on the hair proteome and GVP identification, investigates microscopy as a predictor of proteome profiling success in recovered hairs to improve analysis throughput, and quantifies discriminative power in damaged hairs. The proteomics dataset has been deposited into the ProteomeXchange Consortium (PXD017427). With the exception of degradation in keratins K75, K80, K40, and keratin-associated protein KAP10-11 as markers of hair cuticular damage, corroborated by scanning electron microscopic analysis, minimal hair proteome degradation following explosion allowed successful proteome profiling of single hairs regardless of morphological damage. Finally, GVP identification remained independent of explosion conditions, permitting similar discriminative power between exploded and undamaged hairs. These findings lend greater confidence to GVP analysis in one-inch hairs for forensic identification and provide information about hair protein localization.

Proteomic genotyping: Using mass spectrometry to infer SNP genotypes in pigmented and non-pigmented hair.

Proteomic genotyping uses genetically variant peptides that contain single amino acid polymorphisms to infer the genotype of corresponding non-synonymous SNP alleles. We have focused on hair proteins as a source of protein-based genetic information in a forensic context. An optimized sample processing protocol for hair shafts has been developed for use on a single hair that allows us to conduct validation protocols on real world samples. This includes whether the inferred SNP genotypes are robust and not systematically affected by biological or chemical variation in hair proteomes that might be obtained from a crime scene. To this end we analyzed the hair of 4 mature individuals with a mixture of pigmented and non-pigmented hair. We demonstrate significant changes in the proteomes of grey versus pigmented hair. Vesicle specific proteins and lipid catabolism proteins were enriched in pigmented hair, and housekeeping proteins and lipid anabolic enzymes were enriched in grey, non-pigmented hair. The resulting profiles of genetically variant peptides, however, were more correlated with profiles from the same individuals regardless of pigmentation status. Together with other published evidence, this finding indicates that profiles of genetically variant peptides are robust and more correlated with other genetically variant peptide profiles from the same individual irrespective of changes occurring in the hair protein profile. Based on this small sample, investigators using profiles of genetically variant peptides to infer random match probabilities should not expect to observe differences based on the pigmentation of the hair shaft.