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DNA evidence has revolutionized forensic science in the past few years, cracking open cold cases and bringing both convictions and exonerations. The same techniques help archaeologists and anthropologists studying remains from ancient peoples or human ancestors. 

But DNA is a relatively fragile molecule that breaks down easily. That’s where proteomics, the new science of analyzing proteins, comes in. By reading the sequence of amino acids from fragments of protein, scientists can work backwards to infer the sequence of DNA that produced the protein. 

“It’s reading DNA when you don’t have any DNA to read,” said Glendon Parker, adjunct associate professor in the Department of Environmental Toxicology and graduate group in forensic science at the University of California, Davis. “Protein is much more stable than DNA, and protein detection technology is much better now.”

Parker’s laboratory at �������ϲʿ����������ͼ, with colleagues including Jelmer Eerkens, professor of anthropology, Robert Rice, professor of environmental toxicology and Brett Phinney, manager of the Proteomics Core Facility at the �������ϲʿ����������ͼ Genome Center, is working to establish proteomics as a new tool in forensics and anthropology.

Proteomics technology could be used where samples are old or degraded, and to back up results from DNA analysis, Parker said. Like genomics — the study of entire genomes and large amounts of DNA — it’s a new field enabled by rapid advances in protein sequencing technology and computing. 

Proteins are made up of chains of units called amino acids. There are 20 naturally occurring amino acids that are encoded by DNA. A three-letter sequence of DNA corresponds to a specific amino acid, so reading the sequence of DNA can give you the amino acid sequence of the corresponding protein. The DNA sequence can also be deduced by reading the amino acid sequence and comparing it against databases of known proteins and genes.    

The instruments like those at the �������ϲʿ����������ͼ Proteomics Core Facility can work with vanishingly small amounts of protein, as little as 50 nanograms. An inch of human hair contains 100 micrograms of protein. 

Hair is often found at crime scenes. Hair has very little DNA, but more than enough protein (mostly keratin) for analysis. By looking at variant amino acids in keratin, researchers can identify single-nucleotide polymorphisms, or SNPs, in the underlying DNA. That information can be used for both personal identification and to get information on ancestry. 

Hairs vary somewhat depending on where on the body they come from, but a recent paper led by graduate student Zachary Goecker from Parker’s team showed that the differences between scalp, beard, armpit and pubic hair are not great enough to affect identification. Changes such as graying, dyeing and peroxide treatments had no effect on the identifying information from peptides, Parker said. The study was published in March 2019 in .

Sex determination from teeth

For anthropologists, bones and teeth are a window to people of the past, but DNA may be in a very poor state. Working with Eerkens, Julia Yip, a graduate student in Parker’s laboratory, developed a method to determine the biological sex of an individual based on a single tooth. 

That’s possible because teeth contain a protein called amelogenin, which happens to be located on the X and Y chromosomes that determine biological sex. If a tooth has amelogenin-Y, then it must have come from an individual with XY chromosomes and therefore most likely a biological male. 

In side-by-side tests, the tooth protein analysis was more sensitive and reliable for sex determination than either DNA or looking at the anatomy of skeletons. The work was published last year in the  and is being followed up by postdoctoral researcher Tammy Buonasera. 

In a paper published in May 2019 in , the team has also shown that it is possible to get enough protein for personal identification from a fingermark. The issue is in finding and collecting the sample rather than the sensitivity of the machine, Parker said. 

Parker hopes that forensic proteomics can move out of the laboratory and into some real-world cases. The technique needs to be thoroughly validated before going into wide use, Parker said, but he expects those “boxes to be checked” within about a year. One possible starting point would be working on “cold case” sexual assault kits that are also being tested for DNA and other evidence. 

“We’re trying to get the interest of the forensics community in getting us involved in some of these cases,” Parker said. 

Parts of the laboratory’s work have been supported by grants from the National Institute of Justice, the National Institutes of Health and the National Science Foundation.