Paleogenetics
Paleogenetics is the study of the past through the examination of preserved genetic material from the remains of ancient organisms. Emile Zuckerkandl and Linus Pauling introduced the term in 1963, long before the sequencing of DNA, in reference to the possible reconstruction of the corresponding polypeptide sequences of past organisms. The first sequence of ancient DNA, isolated from a museum specimen of the extinct quagga, was published in 1984 by a team led by Allan Wilson.
Paleogeneticists do not recreate actual organisms, but piece together ancient DNA sequences using various analytical methods. Fossils are "the only direct witnesses of extinct species and of evolutionary events" and finding DNA within those fossils exposes tremendously more information about these species, potentially their entire physiology and anatomy.
The oldest DNA yet sequenced dates to around two million years ago and was extracted from sediments in northern Greenland.
Applications
Evolution
Similar DNA sequences and their encoded proteins are found in different species. This similarity is directly linked to the sequence of the DNA. Due to the improbability of this being random chance, and its consistency too long to be attributed to convergence by natural selection, these similarities are best explained by common ancestry. This allows DNA sequences to be compared between species. Comparing an ancient genetic sequence to later or modern ones can be used to determine ancestral relations, while comparing two modern genetic sequences can determine, within error, the time since their last common ancestor.Ancient DNA research allows scientists to uncover how past organisms lived, including insights into their health, genetics, and interactions with their environment. A method used is called metagenomics which studies all the DNA in an environmental sample to identify different organisms
Human evolution
Genetic data can provide a new understanding for the evolution of human genes and how diseases are transmitted. Ancient archaeological human remains have been a way to see how human structure has changed over time.Using the thigh bone of a Neanderthal female, 63% of the Neanderthal genome, allowing comparison of billions of bases to the modern human genome. It showed that Homo neanderthalensis were the closest living relative of Homo sapiens, until the former lineage died out 30,000 years ago. The Neanderthal genome was shown to be within the range of variation of those of anatomically modern humans, although at the far periphery of that range of variation. Neanderthals and modern humans share more DNA with each other than either does with chimpanzees. It was also found that Neanderthals were less genetically diverse than modern humans, which indicates that Homo neanderthalensis grew from a group composed of relatively few individuals. DNA sequences suggest that Homo sapiens first appeared between about 130,000 and 250,000 years ago in Africa.
Paleogenetics opens up many new possibilities for the study of hominid evolution and dispersion. By analyzing the genomes of hominid remains, researchers can trace their lineage and estimate common ancestry. The Denisova hominid, a species of hominid found in Siberia from which DNA was able to be extracted, may show signs of having genes that are not found in any Neanderthal nor Homo sapiens genome, possibly representing a new lineage or species of hominid.
Evolution of culture
Looking at DNA can give insight into lifestyles of people of the past. Paleogenic research has linked genetic changes to cultural and behavioral development in early human life.Neandertal DNA shows that they lived in small temporary communities. DNA analysis can also show dietary restrictions and mutations, such as the fact that Homo neanderthalensis was lactose-intolerant. Studies of ancient farming communities have shown how the migration of agriculture and animal domestication in Europe during the Neolithic period was accompanied by genetic mixing between near eastern farmers and local hunters and gatherers. Such findings have made it easy to compare the genetic data with cultural transitions documented in archaeological records.Archaeology
Recovery and reconstruction of ancient DNA
Many advances have been made to studying archeological remains, such as the recovery of ancient DNA. DNA needs to be isolated in order for it to be recovered. Ancient material usually goes through dire environmental conditions, making it difficult to analyze. Therefore, researchers rely on a multitude of techniques in order to extract the DNA to get the most recovery possible. Polymerase chain reaction from the 1980s and 1990s came in handy. PCR is a technique used to take multiple copies of specific areas of DNA. Researchers used PCR to look for similarities in these copies and help solidify their findings of DNA. PCR is no longer the only vital technique for recovering ancient DNA. Specifically, library-based approaches and high-throughput sequencing have become prominent in recovering and analyzing DNA. Other ways of recovering DNA fragments include silica-based extraction protocols, light pre-digestion of calcified samples, and tissue selection and sampling methods.The areas prone for researchers to collect DNA include bone and teeth. After the extraction of DNA, it comes out fragmented, therefore, other techniques are needed to reconstruct it. Many techniques to reconstruct DNA, similar to the recovery techniques, include PCR, HTS pathways, library construction strategies, enrichment and target capture methods, data authentication and damage modeling, and epigenomic reconstruction.