Basics of DNA
| Basics of Family History Research
This article is part of a series.
|Overview of Family History Research|
|Family History Collaboration|
|Basics of Family History and Technology|
|Basics of DNA|
|Evaluation and Goal Setting|
|Family History in Time and Place|
|Family History Etiquette, Ethics, Legalities|
|List of Useful Resources for Beginners|
This article originally appeared in "The Foundations of Family History Research" by Sandra Hargreaves Luebking, FUGA, and Loretto Dennis Szucs, FUGA in The Source: A Guidebook to American Genealogy This article was written by Donn Devine, CG, CGI.
One of the newest developments in genealogy is the use of DNA (deoxyribonucleic acid) as a source of genealogical information. DNA is the substance within every living cell that carries the code for passing on its exact makeup to new cells, and although DNA is uniquely different for each individual, it is similar in cells of related individuals. As applied to genealogical research, distinctive DNA patterns can be used to determine whether and how closely individuals are related to other individuals whose DNA patterns are known.
Genealogical DNA testing looks at the non-coding portions of the DNA strand (sometimes misleadingly called junk DNA) that have no known function. For the most part, these stretches of DNA remain unchanged from generation to generation. However, chance changes, called mutations or polymorphisms, do occur at infrequent intervals, and it is these changes that let us distinguish different lines of descent and determine how closely people may be related to each other from the closeness of their DNA matches. A DNA sequence that is passed on unchanged from one parent to a child is called a haplotype, and these are the distinctive patterns we use to establish genealogical links.
Two Types of DNA
Y chromosome DNA is found only in males and is the type most frequently used in genealogy because almost all of it passes as a single haplotype from father to son, essentially unchanged except for chance mutations. This type of DNA is used to identify a common male ancestor in all-male genealogical lines.
mtDNA is a haplotype that children inherit only from their mothers and can be used to identify all-female genealogical lines. Two people who share the same mtDNA haplotype have a common female ancestor in their all-female maternal lines. But, because mtDNA mutates much more slowly than Y-DNA, she may be too many generations back to identify or be of genealogical significance.
Genealogical Uses for DNA Tests
Additional Identity Item
For those ancestors at the head of an ancestral line, for whom we may know little more than a name and event date or place, a DNA sample from an appropriate descendant will provide the same pattern present in the ancestor, in the absence of any chance mutation along the way. For many family historians, a test of their own DNA is often their first step, providing a genetic signature for a distant paternal-line or maternal-line ancestor. Matching samples from two descendants through different lines provides assurance that the common ancestor’s DNA sequence descended unchanged, with no mutation in either line.
Verifying Probable or Suspected Relationships
Verifying relationships is perhaps the most frequent use being made of DNA, as tests can quickly determine whether any two men descend from a common ancestor through their the all-male surname line or whether any two people of either sex are related through their all-female maternal lines to a common female ancestor. However, the number of generations to the common ancestor, if not known from other sources, can be only estimated. A widely publicized example of this application was the Jefferson-Hemings study. There were no sons from President Thomas Jefferson’s marriage, but DNA tests showed that a male-line descendant of his slave Sally Hemings shared the same DNA as descendants in two male lines from the president’s Jefferson grandfather, proving that a Jefferson fathered at least one of Hemmings’s children.
Sorting Family Lines
People with the same surname frequently come from very different ancestral origins. DNA can show which share a common heritage, can show which are unrelated, and, with enough samples associated with ancestral localities of origin, can point modern descendants to their family’s geographic origin. For example, there were four families named Smolenyak living near each other in the tiny Slovak village of Osturma, but DNA tests on male Smolenyak descendants from each of the four families showed they were unrelated through the surname line.
Family and surname associations use DNA to confirm links in lines where records are ambiguous or less than convincing. Associations are also establishing previously unknown links of some members’ lines to known founder-ancestors. The Stidham Family Association sought proof that two lines, with problematic record links, truly descended from a seventeenth-century ancestor. DNA provided the assurance, but also revealed that another line, with clear documentary evidence of descent, was not biologically connected to the ancestor.
The rest of our DNA, called autosomal DNA, is widely used for forensic identification and for verifying paternity but so far has found only limited use in genealogy because individuals receive DNA from each of their parents, which combines to form the individual’s DNA. In each following generation, the genetic code is further diluted as DNA passes to a new generation. Most sections of our autosomal DNA represent small haplotype sequences inherited from a relatively small number of unknown ancestors among the thousands we had tens of generations back. Autosomal DNA is likely to find more uses in genealogy as a result of research now underway to identify inheritance patterns for haplotype segments in the DNA of the recombining chromosomes. The Sorenson Molecular Genealogy Foundation is testing sample donors from all over the world, comparing inherited DNA sequences on all their chromosomes with genealogies submitted by the donors (visit http://smgf.org for more information.)
Another worldwide research project, the National Geographic Society’s Genographic Project, is also searching for DNA markers that can be matched with geographic areas of ancestral origins.
Other laboratories are working on specific genealogical applications of data from autosomal chromosomes. One test of genealogical significance using autosomal DNA can help estimate deep roots. The results of this test are given in percentages, with rather wide confidence limits, and indicate how much of our genetic heritage comes from ancestral groups that originally lived in Sub-Saharan Africa, Europe (including western Asia and the Mediterranean fringe), East Asia, and the Americas. These tests may suggest avenues of research that might otherwise have been overlooked.
- E. A. Foster, et al., “Jefferson Fathered Slave’s Last Child,” Nature 396 (5 November 1998): 27–28.
- Family Tree DNA, “Spotlight: Smolenyak DNA Project,” Facts and Genes 2 (11 August 2003), downloaded 30 May 2004 from http://www.familytreedna.com/facts_genes.asp?act=show&nk=2.>.
- Richard L. Steadham, “The Saga of How Our Project Evolved,” with link to “Current Results of the Stidham DNA Study,” updated 24 February 2004, downloaded 4 June 2004 from http://homepages.rootsweb.com/~tstiddem/Pages/dna.html.