The questions of who we are and where we come from have been asked for throughout our history. Once we explained our origins with mythology and folklore but now we utilize modern science to answer them. Genetics help us tell the story of our origins from the beginning, through the formation of the human gene pools and to the last 2000 years of history. The test results you have just received, along with the following information, will help you understand your personal story, from the shared history of all humans to your unique family story. Read More
#1 Fennoscandia 19.3%
#2 Southern France 15.5%
#3 Orkney Islands 13.7%
/ / / #1 Fennoscandia
The area known as Fennoscandia encompasses the countries of Norway, Sweden, Finland
At the end of the last Ice Age, the glaciers retreated and hunter-gatherers arrived in northern Europe between 11,000 and 12,000 years ago.1 The presence of hunter-gatherers is known from archaeological evidence and likely came from populations similar to the early, small bands of hunter-gatherers that moved into Europe during the Paleolithic period.
Agriculture appeared in Scandinavia between 4,000 and 6,000 years ago.3-6 Archaeological evidence has shown that this farming culture originated in Central Europe and spread north into Fennoscandia.7 Similar to other regions in Europe, there has been a considerable debate as to whether this evidence for farming meant that immigrants arrived and pushed out the local ancient hunter-gatherers, or whether farming culture was adopted by the people already living in the area.
Recent genetic studies looking at samples of ancient DNA from preserved bones have found differences between prehistoric people and later farming populations,2 suggesting that immigrants may have replaced he locals. There are two major language groups in Scandinavia: the Germanic language of Norway, Sweden, and Denmark, and the Finno-Ugric languages of Finland. The division between the Germanic and Finno-Ugric speaking areas has been used as evidence to support the theory that the Baltic region may have been a refuge for earlier hunter-gatherers.2,8 Analysis of Y-chromosome ancestry from Finno-ugric speakers in Scandanavia and areas in north Eurasia points to a high level of diversity. The potential ancient origins of these people dates from 12,000 to 14,000 years ago, when they would have travelled on an ancient Paleolithic migration route that may have gone through Central Asia before turning west to Europe.9
The consensus among researchers today is that the genomes of the people of Fennoscandia are of a mixed ancestry, which is a combination of ancient hunter-gatherers and more recent Germanic farmers. In areas with more extreme cold climates, there remains more original hunter-gatherer influence, likely due to the marginal nature of farming under such conditions. In Finland, some genetic studies have noted potential historic population crashes as evidence for regional genetic distinctiveness, possibly occurring about 3,900 years ago.10 Surviving on farming alone was very difficult in such an extreme climate and there is evidence that farming and foraging cultures coexisted in Finland.1
Between 600 and 700 AD, social changes in Scandinavia marked the start of a migration event that saw the cultures of Scandinavia make their mark on the rest of Europe. It is thought that economic and political stress, as well as a rapid period of agricultural expansion, led people to seek resources and land further afield, catalyzing the start of the Viking Age.11 Various small kingdoms and chiefdoms invaded and colonized many countries within Europe. Vikings raided, and invaded much of Northern and Western Europe, taking over lands in England, Scotland, and France. They moved east into Russia and further to the west into Iceland, Greenland, and ultimately North America. They briefly settled in what is now Canada's province of Newfoundland.12,13 They often mixed in with the local populations, as shown by the mixed British Celtic and Norse origins of Iceland that have been identified both through historical and genetic research.14,15
Viking migration ended in the medieval era but the movement of people from Scandinavia has continued to the present day. In recent centuries there have been migrations to parts of the United States and Canada, with people often moving into the Mid-West, for example to Northern Michigan, where a distinct Finnish immigrant community is well established.16
In the future, we can envision genetic tests that will be able to distinguish between the ancient hunter-gatherer and more recent Germanic farming components. There may also be tests that can link individuals back to ancient DNA extracted from archaeological skeletal material. What may also prove fascinating for historical enthusiasts is the possibility of tests in the future that are able to distinguish specific migrations of Viking settlers to different areas of Europe.
1. Tallavaara M, Pesonen P, Oinonen M. 2010. Prehistoric population history in eastern Fennoscandia. J Archaeol Sci 37: 251-260.
2. Skoglund P, Malmström H, Raghavan M, Storå J, Hall P, Willerslev E, Gilbert MTP, Götherström A, Jakobsson M. 2012. Origins and genetic legacy of Neolithic farmers and hunter-gatherers in Europe. Science, 336: 466-469.
3. Taavitsainen JP, Simola H, Grönlund E. 1998. Cultivation history beyond the periphery: early agriculture in the North European Boreal forest. J World Prehist 12: 199-253.
4. Vuorela I. 1998. The transition to farming in Southern Finland. In: Zvelebil M, Dennell R, Domanska L. Eds. Harvesting the Sea, Farming the Forest: The Emergence of the Neolithic Societies in the Baltic Region. Sheffield Academic Press: Sheffield, pp. 175-180.
5. Shennan S, Edinborough K. 2007. Prehistoric population history: from the Late Glacial to the Late Neolithic in Central and Northern Europe. J Archaeol Sci 34: 1339-1345.
6. Taavitsainen JP, Vilkuna J, Forssell H, 2007. Suojoki at Keuruu - a mid-14th century site of wilderness culture in Central Finland. Suomalaisen Tiedeakatemian toimituksia Humaniora 346. Annales Academiae Scientiarum Fennicae: Finland.
7. Zvelebil M, Dolukhanov P. 1991. The transition to farming in eastern and northern Europe. J World Prehist 5: 233-278.
8. Malmström H, Gilbert MTP, Thomas MG, Brandström M, Storå J, Molnar P, Andersen PK, Benedixen C, Holmlund G, Götherström A, Willerslev, E. 2009. Ancient DNA reveals lack of continuity between neolithic hunter-gatherers and contemporary Scandinavians. Curr Biol 19: 1758-1762.
9. Siiri R, Zhivotovsky LA, Baldovi M, Kayser M, Kutuev IA, Khusainova R, Bermisheva MA, Gubina M, Fedorova SA, Ilumäe A, Khusnutdinova EK, Voevoda MI, Osipova LP, Stoneking M, Lin AA, Ferak V, Parik J, Kivisild T, Underhill PA, Villems R. 2007. ""A counter-clockwise northern route of the Y-chromosome haplogroup N from Southeast Asia towards Europe"". Eur J Hum Genet 15: 204-211.
10. Sajantila A, Salem AH, Savolainen P, Bauer K, Gierig C, Pääbo S. 1996. Paternal and maternal DNA lineages reveal a bottleneck in the founding of the Finnish population. Proc Natl Acad Sci USA 93: 12035-12039.
11. Myhre B. 2000. The early Viking Age in Norway. Acta Archaeologica 71: 35-47.
12. Ingstad H, Ingstad AS. 2000. The Viking Discovery of America: The Excavation of a Norse Settlement in L'Anse Aux Meadows, Newfoundland. Breakwater Books: St John.
13. Brink S, Price N. 2008. The Viking World. Routledge: London.
14. Helgason A, Sigurðardóttir S, Nicholson J, Sykes B, Hill EW, Bradley DG, Bosnes V, Gulcher JR, Ward R, Stefánsson K. 2000. Estimating Scandinavian and Gaelic ancestry in the male settlers of Iceland. Am J Hum Genet 67: 697-717.
15. Byock JL. 2001. Viking Age Iceland. Penguin UK: London.
Gedicks A. 1977. Ethnicity, Class Solidarity, and Labor Radicalism among Finnish Immigrants in Michigan Copper Country. Polit Soc 7: 127-156.
/ / / #2 Southern France
Southern France was a major crossroads of Europe with multiple waves of human migration. The people of
Southern France and much of the surrounding area was inhabited by Neanderthals during the Paleolithic era, who became extinct upon the arrival of modern humans between 35,000 to 50,000 years ago.1 The area was situated at the edge of the Paleolithic ice sheets and was a refuge for people pushed back by worsening climate conditions further north, creating constant movement in and out of the region. The earliest modern humans that arrived in Southern France were Ice Age hunter-gatherers. These people are famous for producing some of the earliest cave paintings known to exist - in the limestone caves of the Pyrenees.2
Hunter-gatherer migration persisted for thousands of years and population density remained low. The development of agriculture in the Middle East and its spread into Europe - which started about 12,000 years ago3 - brought major changes to the region, as large-scale migration of people occurred along the southern corridor of the Alps. These people brought with them their languages, which are believed to be part of the Indo-European language family which exists all over Europe today.4,5 Nearly all of the currently spoken languages in Europe are thought to relate to this expansion of early farmers. In Southern Europe, this migration south of the Alps links the Latin languages of Italy, Spain, and France, while Germanic languages are found north of the Alps.6 This suggests that the early farming cultures that arrived in France came through the south and proceeded north.
A Bronze Age culture developed by 1000 BC,7,8 with settlements throughout Southern France. Over the next thousand years, Iron Age societies began to appear throughout all of France, and became unified as a culture known as the Celts.9 These Celtic societies formed strong links throughout France and into other parts of Northern Europe. These societies were eventually overwhelmed by the Romans who conquered all of present day France, turning it into the Roman province of Gaul.10 After the breakup of the Roman Empire, the southern area of France has generally remained within the borders of the Kingdom of France, with economic practices firmly rooted in the cultures of the Mediterranean.
The diversity of languages in the region may hint at populations that were ethnically and culturally distinct from one another. Catalan, Aragonese, and Gascon are Indo-European languages related to the French that are spoken in other areas of the Pyrenees today.11 Aragonese and Gascon have been in decline in recent centuries. While it may not be possible to link these populations back to the earliest societies in the area, they do provide some grounds for investigating local genetic ancestry.
Future genetic testing may be able to distinguish between early hunter-gatherer influences and later agriculturalists. There have been some studies that have found links between Southern France and its Mediterranean neighbors.12 Research has also found genetic contributions from other Semitic and North African migration events. In the future, we may be able to distinguish these genes as well. It may also be possible to determine which specific Southern France groups (Catalan, Aragonese, or Gascon) an individual may be related to and what languages their ancestors used to speak.
1. Bocquet-Appel JP, Demars PY. 2000. Neanderthal contraction and modern human colonization of Europe. Antiq 74: 544-552.
2. Chauvet JM, Brunel Deschamps E, Hillaire C. 1996. Dawn of art: the Chauvet Cave: the oldest known paintings in the world. HN Abrams: New York.
3. Zeder MA. 2008. Domestication and early agriculture in the Mediterranean Basin: Origins, diffusion, and impact. Proc Natl Acad Sci USA 105: 11597-11604.
4. Diamond J, Bellwood P. 2003. Farmers and their languages: the first expansions. Science 300: 597-603.
5. Bouckaert R, Lemey P, Dunn M, Greenhill SJ, Alekseyenko AV, Drummond AJ, Gray RD, Suchard MA, Atkinson QD. 2012. Mapping the origins and expansion of the Indo-European language family. Science 337: 957-960.
6. Renfrew C. 1990. Archaeology and language: the puzzle of Indo-European origins. Cambridge University Press Archive: Cambridge.
7. Bouby L, Leroy F, Carozza L. 1999. Food plants from late Bronze Age lagoon sites in Languedoc, southern France: reconstruction of farming economy and environment. Vegetation History and Archaeobotany, 8: 53-69.
8. Sandars NK. 2015. Bronze age cultures in France. Cambridge University Press: Cambridge.
9. Webster J. 1996. Ethnographic barbarity: colonial discourse and ‘Celtic warrior societies'. In Webster J, Cooper N. eds. Roman imperialism: post-colonial perspectives. Leicester Archaeology Monographs No. 3. School of Archaeological Studies: University of Leicester. pp. 111-123.
10. Woolf G. 2000. Becoming Roman: the origins of provincial civilization in Gaul. Cambridge University Press: Cambridge.
11. Calafell F, Bertranpetit J. 1994. Mountains and genes: population history of the Pyrenees. Hum Biol 66: 823-842.
12. Gibert M, Reviron D, Mercier P, Chiaroni J, Boetsch G. 2000. HLA-DRB1 and DQB1 polymorphisms in Southern France and genetic relationships with other Mediterranean populations. Hum Immunol 61: 930-936.
/ / / #3 Orkney Islands
The Orkney Islands are a small group of islands that lie off the North Coast of Scotland
The earliest evidence for human habitation of the Orkney Islands dates to the Neolithic period, around 6,000 years ago. This period is associated with many-chambered tombs and distinctive ceramics, which linked these people to mainland Scotland where they are thought to have originated.1,2 Evidence for prehistoric hunter-gatherer cultures in the north of the British Isles predates the arrival of agriculture and is limited to a few archaeological sites in the Hebrides and the Western Isles of Scotland. Dating of these sites places human habitation back as far as 8,500 years ago.3 Challenging environmental conditions at the end of the last Ice Age may have prevented earlier human occupation.
Early Neolithic societies appeared in Scotland about 5,000 years ago.4 The shift to agriculture is thought to have been slowed by the relatively cold climate and short growing season. In many areas of Northern Britain, archaeological evidence also suggests foraging for food remained long after the arrival of agriculture. The arrival of agriculture brought changes to buildings, which help us identify the transition from Neolithic to Iron Age between 2,500 and 2,000 years ago. Chambered tombs were replaced by circular tombs and drystone towers known as Brochs appeared.
Archaeological evidence - such as stone monuments of a similar style across the Orkneys and other parts of the British Isles - tells us that there was contact between Orkney and the rest of Scotland during the Neolithic and Iron Age. It also shows clear cultural continuities with the Picts, an ethnic group that inhabited a large part of northeast Scotland,9 during the Iron Age.8 The strong links between the Orkney Islands and the Scottish mainland would change when Scandinavian invaders, called the Norse, arrived around 800 AD.10 These invaders took over the islands and maintained control for several centuries. The Norse influx clearly had an impact on the population but archaeological evidence points towards cultural continuity and assimilation between the Norse and the local people.11,12 Migration to the islands from the Scottish mainland continued both during and after the period of Scandinavian colonization.
The Orkney Islands eventually rejoined Scotland and have been a permanent part of the country from the 15th century to the present day. While distinguishing between ancient and historic migration from Scotland is currently not possible, recent genetic data supports there is no more than a 40 per cent Nordic contribution in the genetic makeup of Shetland and the Orkney Islands as we know them now.13
Future testing may reveal Viking or Pictish ancestry, as well as genes from the more recent movement of people. Separate Y-chromosome and mitochondrial DNA lineages may also reveal mixed maternal and paternal ancestries. Genetic testing of ancient mummies found in the Orkneys may also lead to links with ancient DNA.
1. Richards CC. 1992. Doorways into another world: the Orkney-Cromarty chambered tombs. In Vessels for the Ancestors: Essays on the Neolithic of Britain and Ireland. Sharpie N, Sheridan A. eds. Edinburgh University Press: Edinburgh. pp. 62-77.
2. Ritchie A. 1983. Excavation of the Neolithic Farmstead at Knap of Howar, Papa Westray, Orkney. Proceedings of the Society of Antiquaries of Scotland 113:40-121.
3. Edwards KJ, Mithen S. 1995. The colonization of the Hebridean Islands of Western Scotland: evidence from the palynological and archaeological records. World Archaeol 26:348-365.
4. Schulting RJ, Richards MP. 2002. The Wet, the Wild and the Domesticated: the Mesolithic—Neolithic Transition On the West Coast of Scotland. Eur J Archaeol 5: 147-189.
5. Richards C. 1990. Postscript: the late Neolithic settlement complex at Barnhouse Farm, Stenness. In The Prehistory of Orkney. Renfrew C. ed. Edinburgh University Press: Edinburgh. pp. 306-316.
6. Sharples N. 1985. Individual and community: the changing role of megaliths in the Orcadian Neolithic. In Proceedings of the Prehistoric Society (Vol. 51, pp. 59-74). Cambridge University Press.
7. Pearson MP, Sharples N, Mulville J. 1996. Brochs and Iron Age society: a reappraisal. Antiq 70:57-67.
8. Smith B. 2001. The Picts and the martyrs or did Vikings kill the native population of Orkney and Shetland. North Stud 36:7-32.
9. Clarkson T. 2012. The Picts: a history. Birlinn: Edinburgh.
10. Wilson JF, Weiss DA, Richards M, Thomas MG, Bradman N, Goldstein DB. 2001. Genetic evidence for different male and female roles during cultural transitions in the British Isles. Proc Natl Acad Sci USA 98:5078-5083.
11. Ritchie A. 1993. Viking Scotland. Historic Scotland: London.
12. Morris CD. 1990. Viking Orkney: A Survey. In The Prehistory of Orkney, B.C. 4000-1000 A.D. Renfrew, C. ed. Edinburgh University Press: Edinburgh. pp. 210-242.
13. Sykes B. 2006. Blood of the Isles: Exploring the Genetic Roots of Our Tribal History. Bantam Press: London.
* The GPS Origins test is an Autosomal (SNP) test that is not gender specific. Although both Migration Patterns represent your Maternal and Paternal DNA route, we cannot differentiate which route is specifically your parents’ individual route at this time.
Origin: Peaks in the Iceland and Norway and declines in Finland, England, and France
Origin: Peaks in south France and declines in north France, England, Orkney islands, and Scandinavia
Origin: Peaks in the Orkney islands and declines in England, France, Germany, Belarus, and Poland
Origin: Peaks in Krasnoyarsk Krai and declines towards east Russia
Origin: Endemic to south eastern india with residues in Pakistan
Origin: Peaks in France and Spain Basque regions and declines in Spain, France, and Germany
Origin: Peaks in Sardinia and declines in Italy, Greece, Albania, and The Balkans
Origin: Peaks in south Siberia (Russians: Tuvinian) and declines in North Mongolia
Origin: Peaks in North India (Dharkars, Kanjars) and declines in Pakistan
Origin: Peaks in Algeria and declines in Morocco and Tunisia
Origin: Peaks in Peru, Mexico, and North America and declines in Eastern Russia
Origin: Peaks in Central-North America and declines towards Greenland and Eskimos
Origin: Endemic to Surui people (Brazil) and declines in Colombia
Origin: Peaks in Mexico and Central America with residues in Peru
The questions of who we are and where we come from have been asked for throughout our history. Once we explained our origins with mythology and folklore but now we utilize modern science to answer them.
Genetics help us tell the story of our origins from the beginning, through the formation of the human gene pools and to the last 2000 years of history.
The test results you have just received, along with the following information, will help you understand your personal story, from the shared history of all humans to your unique family story.
Our origins lie far beyond the first appearance of humans, with an evolutionary story common to many forms of life on earth. About 360 million years ago fish-like creatures ventured out of the Devonian Sea and became the first reptiles. After hundreds of millions years of evolution the mammals emerged after the extinction of the dinosaurs 65 million years ago thrust them into the evolutionary spotlight, and allowed them to expand into the world the dinosaurs left vacant.
Our human story really begins with the origin of primates, which split away from the other mammalian groups between 65 and 80 million years ago. It would be at least another 60 million years before the appearance of the species Ardipithecus, an ape that evolved from the Old World Monkeys and is regarded as the first fossil human ancestor.
Fossil finds from Ardipithecus in Ethiopia date it to between 4 and 6 million years ago.12 This species could walk on two legs like humans but shared other characteristics with chimpanzees. Ardipithecus further developed into a number of lineages found throughout East Africa and South Africa that are known as the Australopithecines.13
Over the next 3 million years, many Australopithecine species appeared in Africa but they evolved little; their brains remained roughly the same size as those of chimpanzees and they did not use tools. Around 3 million years ago, the subspecies Homo habilis14 began using stone tools, and by 1.5 million years ago the fire-mastering Homo erectus appeared. Fossils reveal that Homo erectus had a much bigger brain than its Australopithecine ancestors. This subspecies began spreading across much of Africa, Asia, and the Middle East, while the Australopithecines began to disappear.15
Next, a new human subspecies, the Neanderthals, appeared. They evolved from a Homo erectus relative outside of Africa and had spread widely throughout Europe and the Middle East 500,000 years ago.16 Neanderthals had stocky builds and thick limbs and were specially adapted to the Ice Age conditions. There is evidence that Neanderthals buried their dead, a practice once thought exclusive to modern humans,17,18 which raises questions about the nature of the Neanderthal’s genetic contribution to modern humans.19
It is thought that the ancestor of modern humans is one of the Homo erectus relatives, which appeared in East Africa sometime between 100,000 to 200,000 years ago.
Many different ancient human species also evolved outside Africa, and persisted for more than a million years of geologic time. Their fossils have been unearthed in Europe, Southeast Asia, and China. Yet this diversity had all but disappeared by 100,000 years ago, and human fossils became remarkably uniform across the globe.23
The theory that has become known as the Out of Africa model began with a study in the late 1980s, investigating small changes in the DNA carried by the mitochondria - the DNA passed down by the mother.24 The study analyzed DNA changes in the mitochondrial genome, and surmised that all humans diverged from a single ancestor living 200,000 years ago in Africa. While this does not indicate that there was just one mother, or ‘African Eve’, for all humanity, the results suggested that all humans alive today descended from a single population residing in Africa more recently than any of the previously mentioned early human species.
The Out of Africa model has also been applied to research on the Y chromosome.25,26 This chromosome is found only in male lineages and passed down through the generations, unchanged for the most part. A recent study estimates that the ‘African Adam’ lived 208,000 years ago27.
Mitochondrial and Y chromosomal DNA have been our primary tools for deciphering the human story because each person receives only one copy from each parent. Mitochondrial DNA is passed down from the mother and Y chromosomal DNA from the father, allowing scientists to track the ancestry of both the maternal and paternal lines. Perhaps one of the most interesting stories told by the mitochondrial and Y chromosomal DNA is how humans colonized the world.
The earliest human migrants appear to have reached Southern China some 80,000 years ago28, and DNA studies suggest they may have interbred with Neanderthals on their way through the Middle East.29 They then spread to the rest of Asia along a route that probably tracks south of the Himalayas and into East Asia between 50,000 and 60,000 years ago,30 possibly interbreeding with another subspecies known as the Denisovians.31
Archaeological and genetic evidence indicate that modern humans crossed the ocean from Southeast Asia and reached the islands near the tropical Pacific area of Oceania as far back as 50,000 years ago, probably in small water craft.32 At the same time, populations spread to Europe through Turkey and into Central Asia. Some of these Central Asian migrants subsequently moved westward from the Ural Mountains and may be represented today by the peoples of Northern Europe and of the Baltic region, such as the Sami people.
Climate and geography delayed further migrations of modern humans into other areas of the world. Much of northern Eurasia was extremely cold during the last Ice Age (11,000 to 12,000 years ago) and human populations remained small and isolated. A small group of people from Siberia, however, managed to reach North America around 18,000 years ago33 by way of a land bridge that existed when sea levels were lower. They moved south, and by 15,000 years ago, began to populate South America.
There were several more migratory waves to the Americas with the most recent being the Inuit, who colonized the Arctic of North America between 4,000 and 6,000 years ago.
Asian migration also continued eastwards to Oceania. The large islands of Oceania that are closest to Asia have been inhabited for at least 30,000 years, while the most isolated islands of Northeastern Oceania remained uninhabited until just 3,500 years ago.34,35 The people who made the first voyages into this region were Austronesians, a group that emigrated from an area around present day Taiwan and are today known as Polynesians.
But as the last Ice Age came to an end and the climate warmed, a human cultural revolution was about to start, and it began in the Middle East.
The transition from hunter-gathering to farming occurred in the Middle East between 10,000 and 12,000 years ago,36 and between 9,000 and 10,000 years ago in China37 and parts of the Americas.38,39 By 5,000 years ago agriculture had facilitated the rise of some of the first large civilizations such as Mesopotamia in West Asia,40 the Maya in Central America,41 and the earliest Chinese civilizations along the Yangtze.42
Early farming cultures then expanded into new areas. Farmers from the Middle East brought agriculture to Europe and rice farming travelled with groups across East Asia. This expansion was accompanied by a genetic reshuffling as different groups came into contact and reproduced. Such reshuffling has been a continuous process over the last 10,000 years.
Genetic research has played a key role in understanding the migrations that took place during this period. Mitochondrial DNA lineages have been used to confirm and enhance archaeological interpretations such as tracing the ancestry of Norse and Gaelic populations, and Y chromosomal studies have been used to track male lineages in studies of Oceania.
As humans traversed the globe and colonized different continents each group accumulated small differences in their DNA. Most of these differences or mutations occurred in the X chromosome and autosomal chromosomes that are inherited from both parents and allows us to follow the specific journeys made by each human group.
Some genetic roads diverged, not meeting again until modern times, while others led back to one another as genetically distinct groups. The accumulations of mutations in people from different areas of the world are what allow us today to distinguish different groups from one another.
DNA mutations may have been enhanced by the custom of marrying within an tribe, class, or social group, creating a group of people who were more similar to one another genetically than they were to their ancestors and neighboring groups - in other words, creating a new gene pool or genetic origin..
It is difficult to know exactly how many gene pools there are because every geneltic origin includes “gene puddles” where small, isolated groups of people married only within their local group, acquiring and maintaining unique mutations over time. At this time, scientists have identified about forty gene pools from all over the world. Over time, some of these gene pools spilled toward? each other, particularly those in Eurasia, whereas other pools remained more constant.
As ancient peoples traded, conquered, enslaved and fell in love, they spread their genes, along with their unique mutations, across larger areas at an increasingly rapid pace, interweaving previously distinct parts of the original gene pools. If, in the past, human groups diverged from one another and became genetically distinct, recent history has been characterized by populations coming together creating new genetic tapestries out of the original genetic origin. Today, every one of us is the product of these historical genetic exchanges: it is extremely rare to find individuals whose DNA belongs to a single gene pool.
Because the X and autosomal chromosomes contain the accumulated mutations that correspond with different gene pools, they provides a more nuanced picture of historical interactions in the past. Your genetic origin results will show you how your genome is linked to the human story of the populations who lived 60,000-15,000 years ago.
The past 2,000 years of human history have seen the rise and fall of empires that spanned entire continents, such as the Persian, Roman, Mongol, Arab Caliphate and most recently, the British Empire.
The expansion of European empires brought European DNA to many different parts of the world such as Australia, Asia and particularly the Americas, where the intermingling of Europeans and native tribes has led to many central and south Americans having mixed ancestry.
Pandemics, such as the Black Death in Europe and smallpox in the Americas caused widespread devastation. Conquests by Viking raiders reshaped entire cultures and identities. All of these events have left their mark in the DNA of present-day populations.
Countries such as the United States, which have experienced large waves of migration from different areas in the last two hundred years have facilitated the further mixing of many different gene pools.
Between the 17th and 19th centuries the slave trade brought up to 650,000 Africans to the United States. They were joined by 4.5 million Irish people who escaped famine and poverty between 1820 and 1930, Other groups to enter the United States between the mid-19th and early 20th centuries include about 5 million Germans, over 2 million European jews, 4 million Italians and up to 300,000 Chinese.
Consequently, these migrations merged gene pools that had, thus far, remained largely separate due to geographical barriers. Many Americans and British now share genetic origins with up to a dozen different gene pools, some of which have diverged more than 60,000 years ago, such as the European and Native American gene pools.
Your GPS Origins results reveal your genetic origins and the journey your DNA has made with end-points recorded each time the DNA has markedly changed through intermarriages.
For example, if you have Scottish ancestry your results could show that you are descended from the Viking ancestors who arrived in the Medieval era, but did not mix with Scots and retained their Danish origin. If you are African American, you may learn about connections to the Bantu peoples and the pre-colonial trading kingdoms in West Africa. If you are an Ashkenazic Jew, GPS Origins may trace your origin to the ancient Ashkenaz in northeastern Turkey.
Ongoing genetic research of archaeological remains could mean that, in the future, you may be able to match your background with a range of individuals - whether that is an ancient Mayan King found in a temple complex in Guatemala, a warrior from a Viking boat burial or a flint-knapping craftsman from Mesolithic Germany. The human story, as told through our genes, is only beginning.
Now, you are ready to see your results.
Out of Africa Story References:
1. Nielsen PE, Engholm M, Berg RH, Buchardt O. 1991. Science 254: 1497–1500.
2. Mintmire JW, Dunlap BI. White CT. 1992. Phys Rev Lett 68: 631–634.
3. Zhu M, Ahlberg PE, Zhao W, Jia L. 2002. Palaeontology: First Devonian tetrapod from Asia. Nature 420: 760-761.
4. Rose KD. 1994. The earliest primates. Evol Anthropol 3: 159-173.
5. Clemens WA. 2004. Purgatorius (Plesiadapiformes, Primates?, Mammalia), a Paleocene immigrant into northeastern Montana: stratigraphic occurrences and incisor proportions. Bulletin of Carnegie Museum of Natural History: 36: 3-13.
6. Rose KD, Godinot M, Bown TM. 1994. The early radiation of Euprimates and the initial diversification of Omomyidae. In Fleagle JG, Kay RF. Eds. Anthropoid origins. Springer: United States. pp. 1-28.
7. Bajpai S, Kay RF, Williams BA, Das DP, Kapur VV, Tiwari BN. 2008. The oldest Asian record of Anthropoidea. Proc Natl Acad Sci USA 105: 11093-11098.
8. Zalmout IS, Sanders WJ, MacLatchy LM, Gunnell GF, Al-Mufarreh YA, Ali MA, Nasser AH, Al-Masari AM, Al-Sobhi SA, Nadhra AO, Matari AH, Wilson JA, Gingerich PD. 2010. New Oligocene primate from Saudi Arabia and the divergence of apes and Old World monkeys. Nature 466: 360-364.
9. Patterson N, Richter DJ, Gnerre S, Lander ES, Reich D. 2006. Genetic evidence for complex speciation of humans and chimpanzees. Nature 441: 1103-1108.
10. Langergraber KE, Prüfer K, Rowney C, Boesch C, Crockford C, Fawcett K, Inoue-Muruyama M, Mitano JC, Muller MN, Robbins MM, Schubert G, Stoinski TS, Viola B, Watts D, Wittig RM, Wrangham RW, Zuberbühler K, Pääbo S, Vigilant L. 2012. Generation times in wild chimpanzees and gorillas suggest earlier divergence times in great ape and human evolution. Proc Natl Acad Sci USA 109: 15716-15721.
11. Guy F, Lieberman DE, Pilbeam D, de León MP, Likius A, Mackaye HT, Vignaud P, Zollikofer C, Brunet M. 2005. Morphological affinities of the Sahelanthropus tchadensis (Late Miocene hominid from Chad) cranium. Proc Natl Acad Sci USA 102: 18836-18841.
12. White TD, Asfaw B, Beyene Y, Haile-Selassie Y, Lovejoy CO, Suwa G, WoldeGabriel G. 2009. Ardipithecus ramidus and the paleobiology of early hominids. Science 326: 64-86.
13. Reed KE. 1997. Early hominid evolution and ecological change through the African Plio-Pleistocene. J Hum Evol 32: 289-322.
14. Ungar PS, Grine FE, Teaford MF. 2006. Diet in early Homo: a review of the evidence and a new model of adaptive versatility. Ann Rev Anthropol 35: 209-228.
15. Antón SC. 2003. Natural history of Homo erectus. Am J Phys Anthropol 122(S37): 126-170.
16. de Castro JMB, Martinón-Torres M, Gómez-Robles A, Margvelashvili A, Arsuaga JL, Carretero JM, Martinex I, Sarmiento S. 2011. The Gran Dolina-TD6 human fossil remains and the origin of Neanderthals. In Condemi S, Weniger GC. Eds. Continuity and discontinuity in the peopling of Europe. Springer: Netherlands. pp. 67-75.
17. Pettitt P. 2002. The Neanderthal dead: exploring mortuary variability in Middle Palaeolithic Eurasia. Before Farming (1): 1-26.
18. Zilhao J. 2012. Personal ornaments and symbolism among the Neanderthals. Developments in Quaternary Science 16: 35-49.
19. Lowery RK, Uribe G, Jimenez EB, Weiss MA, Herrera KJ, Regueiro M, Herrera RJ. 2013. Neanderthal and Denisova genetic affinities with contemporary humans: Introgression versus common ancestral polymorphisms. Gene 530: 83-94.
20. Stringer C. 2003. Human evolution: out of Ethiopia. Nature 423: 692-695.
21. White TD, Asfaw B, DeGusta D, Gilbert H, Richards GD, Suwa G, Howell FC. 2003. Pleistocene Homo sapiens from Middle Awash, Ethiopia. Nature 423: 742-747.
22. Gunz P, Bookstein FL, Mitteroecker P, Stadlmayr A, Seidler H, Weber GW. 2009. Early modern human diversity suggests subdivided population structure and a complex out-of-Africa scenario. Proc Natl Acad Sci USA 106: 6094-6098.
23. Templeton A. 2002. Out of Africa again and again. Nature 416: 45-51.
24. Cann RL, Rickards O, Lum JK. 1994. Mitochondrial DNA and human evolution: Our one lucky mother. In Nitecki MH, Nitecki DV eds. Origins of anatomically modern humans. Interdisciplinary Contributions to Archaeology. Springer: United States. pp. 135-148.
25. Underhill PA, Shen P, Lin AA, Jin L, Passarino G, Yang WH, Kauffman E, Bonné-Tamir B, Bertranpetit J, Francalacci P, Ibrahum M, Jenkins T, Kidd JR, Mehdi SQ, Seielstad MT, Wells RS, Piazza A, Davis RW, Feldman MW, Cavalli-Sforza LL, Oefner PJ. 2000. Y chromosome sequence variation and the history of human populations. Nature genet 26: 358-361.
26. Underhill PA, Passarino G, Lin AA, Shen P, Mirazon Lahr M, Foley RA, Oefner PJ, Cavalli-Sforza LL. 2001. The phylogeography of Y chromosome binary haplotypes and the origins of modern human populations. Ann Hum Genet 65: 43-62.
27. Elhaik E, Tatarinova TV, Klyosov AA, Graur D. 2014. The ‘extremely ancient’chromosome that isn’t: a forensic bioinformatic investigation of Albert Perry’s X-degenerate portion of the Y chromosome. Eur J Hum Genet 22: 1111-1116.
28. Dennell R. 2015. Palaeoanthropology: Homo sapiens in China 80,000 years ago. Nature 526: 647-648.
29. Sankararaman S, Patterson N, Li H, Pääbo S, Reich D. 2012. The date of interbreeding between Neandertals and modern humans. PLOS Genetics OI: 10.1371:1002947.
30. Armitage SJ, Jasim SA, Marks AE, Parker AG, Usik VI, Uerpmann HP. 2011. The southern route “Out of Africa”: evidence for an early expansion of modern humans into Arabia. Science 331: 453-456.
31. Gibbons A. 2011. Who were the Denisovans?. Science 333: 1084-1087.
32. Mellars P. 2006. Going east: new genetic and archaeological perspectives on the modern human colonization of Eurasia. Science 313: 796-800.
33. Meltzer DJ. 2009. First peoples in a new world: colonizing ice age America. Univ of California Press: Berkeley.
34. Bellwood P. 1985. Prehistory of the Indo-Malaysian Archipelago. University of Hawai’i Press; Honolulu.
35. Kirch PV. 2000. On the Road of the Winds: An Archaeological History of the Pacific Islands before European Contact. University of California Press: Berkeley.
36. Brown TA, Jones MK, Powell W, Allaby RG. 2009. The complex origins of domesticated crops in the Fertile Crescent. Trends in Ecology & Evolution 24: 103-109.
37. Zhao Z. 2011. New archaeobotanic data for the study of the origins of agriculture in China. Current Anthropology 52(S4): S295-S306.
38. Smith BD. 1994. The origins of agriculture in the Americas. Evolutionary Anthropology: Issues, News, and Reviews 3: 174-184.
39. Smith BD. 1997. The initial domestication of Cucurbita pepo in the Americas 10,000 years ago. Science 276: 932-934.
40. Postgate JN. 1992. Early Mesopotamia. Society and Economy at the Dawn of History, 52: 92-95.
41. Demarest A. 2004. Ancient Maya: The rise and fall of a rainforest civilization (Vol. 3). Cambridge University Press: Cambridge.
42. Yasuda Y, Fujiki T, Nasu H, Kato M, Morita Y, Mori Y, Kanehara M, Toyama S, Yano A, Okuno M, Jiejun H, Ishihara S, Kitagawa H, Fukusawa H, Narus T. 2004. Environmental archaeology at the Chengtoushan site, Hunan Province, China, and implications for environmental change and the rise and fall of the Yangtze River civilization. Quatern Int 123: 149-158.
43. Helgason A, Hickey E, Goodacre S, Bosnes V, Stefánsson K, Ward R, Sykes B. 2001. mtDNA and the islands of the North Atlantic: estimating the proportions of Norse and Gaelic ancestry. Am J Hum Genet 68: 723-737.
44. Kayser M, Choi Y, van Oven M, Mona S, Brauer S, Trent RJ, Suarkia D, Schiefenhövel W, Stoneking M. 2008. The impact of the Austronesian expansion: evidence from mtDNA and Y chromosome diversity in the Admiralty Islands of Melanesia. Mol Biol Evol 25: 1362-1374.
45. Herlihy D, Cohn SK. 1997. The Black Death and the transformation of the West. Harvard University Press: Cambridge.
46. Patterson KB, Runge T. 2002. Smallpox and the Native American. Am J Med Sci 323: 216-222.