Genetic history of the British Isles


The genetic history of the British Isles is the subject of research within the larger field of human population genetics. It has developed in parallel with DNA testing technologies capable of identifying genetic similarities and differences between populations. The conclusions of population genetics regarding the British Isles in turn draw upon and contribute to the larger field of understanding the history of humanity in the British Isles generally, complementing work in linguistics, archaeology, history and genealogy.
Research concerning the most important routes of migration into the British Isles is the subject of debate. Apart from the most obvious route across the narrowest point of the English Channel into Kent, other routes may have been important over the millennia, including a land bridge in the Mesolithic period, and also maritime connections along the Atlantic coasts.
The periods of the most important migrations are contested. The Neolithic introduction of farming technologies from Europe is frequently proposed as a period of major population change in the British Isles. Such technology could either have been learned by locals from a small number of immigrants or by colonists who significantly changed the population.
Other potentially important historical periods of migration which have been subject to consideration in this field include the introduction of Celtic languages and technologies, the Roman era, the period of Gaelic influx, the period of Anglo-Saxon influx, the Viking era, the Norman invasion of 1066 and the era of the European wars of religion. There are also many potential eras of movement between different parts of the British Isles.

Analyses of nuclear DNA

Mesolithic population

Mesolithic Britons were closely related to other Mesolithic people throughout Western Europe. This population probably had pale-coloured eyes, lactose intolerance, dark curly or wavy hair and very dark or black skin.

Continental Neolithic farmers

Mesolithic Britons were closely related to other Mesolithic people throughout Europe, but Neolithic individuals are close to Iberian and Central European Middle Neolithic populations, modelled as having about 75% ancestry from Anatolian farmers with the rest coming from Western Hunter-Gatherers in continental Europe. Some British Neolithic individuals had slightly more WHG genes, suggesting that some members of the WHG population in Britain did pass on their genes. Neolithic individuals from Wales have no detectable local admixture of Western hunter-gatherer genes, those from South East England and Scotland show the highest admixture of WHG genes, and those from South-West and Central England are intermediate. This suggests that farming was brought to the British Isles by sea from north-west mainland Europe, by a population that was, or became in succeeding generations, relatively large.

Bronze Age European Bell Beaker People

According to a 2017 study by Olalde et al., the spread of the Bell Beaker culture to Britain from the lower Rhine area in the early Bronze Age introduced high levels of steppe-related ancestry, resulting in a near-complete transformation of the local gene pool within a few centuries, replacing about 90% of the local Neolithic-derived lineages between 2,400 BC and 2,000 BC. These people exhibiting the Beaker culture were likely an offshoot of the Corded Ware culture, as they had little genetic affinity to the Iberian Beaker people. In addition to the large steppe-derived component, they had a smaller proportion of continental Neolithic and Western Hunter Gatherer DNA. The Modern British and Irish likely derive most of their ancestry from this Beaker culture population. According to David Reich, Southern England saw some resurgence of Neolithic DNA around the Iron Age to Roman Period, this may be attributable a resurgence of the native Neolithic-derived population, or to Celtic Iron Age or Roman period migrations.
Haak et al., in their 2015 Nature paper, had estimated that the modern English population derived somewhat just over half of their ancestry from a combination of Neolithic and Western Hunter Gatherer ancestry, with the steppe-derived element making up the remainder. Scotland was found to have both more Steppe and more Western Hunter Gatherer ancestry than England. These proportions are similar to other Northwest European populations.

Anglo-Saxon Settlement

Two studies published in 2016, based on data collected from bodies found in Iron Age, Roman and Anglo-Saxon era burials, concluded that the ancestry of the modern English population contained large contributions from both Anglo-Saxon migrants and Romano-British natives.

Viking Influence

A study into the Norwegian Viking ancestry of British and Irish people found that there is evidence of particular concentrations in certain areas; especially the North Sea islands of Shetland and Orkney, but also to a lesser extent the Western Isles, Anglesey in Wales, the Isle of Man, and the Wirral, West Lancashire and Cumbria in England.
Another important Viking influence was the long standing connection between North Eastern England and Denmark, resulting in the Danelaw region during the Dark Ages. The Normans were partly descended from Vikings.

Early studies of protein polymorphisms in modern populations

Early studies by Cavalli-Sforza used polymorphisms from proteins found within human blood. One of the lasting proposals of this study with regards to Europe is that within most of the continent, the majority of genetic diversity may best be explained by immigration coming from the southeast towards the northwest or in other words from the Middle East towards Britain and Ireland. He proposed at the time that the invention of agriculture might be the best explanation for this.

Y chromosomes and mitochondrial DNA from modern populations

With the advent of DNA analysis, modern populations were sampled for mitochondrial DNA to study the female line of descent, and Y chromosome DNA to study male descent. As opposed to large scale sampling within the autosomal DNA, Y DNA and mitochondrial DNA represent specific types of genetic descent and can therefore reflect only particular aspects of past human movement. Early usage of this technology has led to many theories that will be discussed in this section, including the proposed Basque origin of the modern British, in addition to the theory that the British gene pool has undergone very little change in the past 6,000 years.
For Britain, major research projects aimed at collecting more data include the Oxford Genetic Atlas Project, which was associated with Bryan Sykes of Oxford University and more recently the People of the British Isles, also associated with Oxford.
A 2010 DNA study published in PLOS Biology claimed that Neolithic farmers from the Middle East had a significant impact on the Y-DNA of European males, the majority of whom have paternal lineage tracing back to Middle-Eastern farmers during the Neolithic expansion. In contrast, the mtDNA of European females show the majority having maternal lineage tracing back to earlier hunter-gatherers predating the Neolithic expansion.
In 2006 Bryan Sykes produced an analysis of 6,000 samples from the OGAP project in his book Blood of the Isles. Stephen Oppenheimer in his 2006 book The Origins of the British used the data from, and for Europe. In opposition to Mesolithic origin theories, Sykes and Oppenheimer argued for significant immigration from the Iberian Peninsula into Britain and Ireland. Much of this argument depended on paternal Y chromosome DNA evidence Oppenheimer reviewed in the Weale and Capelli studies and suggested that correlations of gene frequency mean nothing without a knowledge of the genetic prehistory of the regions in question. His criticism of these studies is that they generated models based on the historical evidence of Gildas and Procopius, and then selected methodologies to test against these populations. Weale's transect spotlights that Belgium is further west in the genetic map than North Walsham, Asbourne and Friesland. In Oppenheimer's view, this is evidence that the Belgae and other continental people – and hence continental genetic markers indistinguishable from those ascribed to Anglo-Saxons – arrived earlier and were already strongly represented in the 5th century in particular regions or areas.
Oppenheimer, based on the Weale and Capelli studies, proposed that none of the invasions since the Romans have had a significant impact on the gene pool of the British Isles, and that the inhabitants from prehistoric times belong to an Iberian genetic grouping. He says that most people in Britain and Ireland are genetically similar to the Basque people of northern Spain and southwestern France, from 90% in Wales to 66% in East Anglia. Oppenheimer suggests that the division between the West and the East of England is not due to the Anglo-Saxon invasion but originates with two main routes of genetic flow – one up the Atlantic coast, the other from neighbouring areas of Continental Europe – which occurred just after the Last Glacial Maximum. He reports works on linguistics by Forster and Toth which suggest that the Indo-European languages began to fragment some 10,000 years ago, at the end of the last Ice Age. He claims that the Celtic languages split from Indo-European far earlier than the date generally asserted by most researchers of Indo-European linguistics, some 6000 years ago. He claims that the English language split from the other Germanic languages before the Roman period, and became the English that was spoken by the Belgae tribes of what is now southern and eastern England, northeastern France, and Belgium prior to their conquest by the Romans, and long before the arrival of the Anglo-Saxons.
Bryan Sykes, a former geneticist at Oxford University, came to fairly similar conclusions as Oppenheimer, which he set forth in his 2006 book called Blood of the Isles: Exploring the Genetic Roots of our Tribal History, published in the United States and Canada as Saxons, Vikings and Celts: The Genetic Roots of Britain and Ireland.
In 2012, from a highly enlarged whole-genome mitochondrial database published, the authors concluded that the most archaic maternal mtDNA lineages in Europe came from a Middle Eastern migration into Europe during the Late Glacial period, ~19–12 thousand years ago and not as late as the Neolithic as was previously proposed. They argued that this population came from a contracted European population refugium on the Anatolian Plateau which spread to three refugia, Franco-Cantabria, the Italian Peninsula and the East European Plain. From these three areas the lineages would then have repopulated Europe.
The work of Sykes and Oppenheimer regarding the British has recently been seriously challenged. More recent developments in genetic research demonstrate that R1b haplogroups came from the Steppe invaders from the east, rather than from Iberia or France. David Reich's Harvard laboratory found that over 90% of the British Neolithic population was overturned by the Bell Beaker People from the Lower Rhine, who had little genetic relation to the Iberian Bell Beaker people or South Europeans. Modern autosomal genetic clustering is testament to this fact, as the British and Irish cluster genetically very closely with other North European populations, rather than Iberians, Galicians, Basques or those from the south of France.
Invaders of Steppe origin brought R1b in significant proportions to the Iberian peninsula replacing 100% of Y-DNA lineages but only 40% of their total DNA. This in stark contrast to the 90% autosomal turnover in the British Isles. There is therefore significant haplogroup similarity between these populations, which led to early scholars proposing a Basque origin for the British, although there is little whole genome autosomal similarity.

Germanic genetics

Another subject in the literature which has been widely discussed is whether genetic evidence shows signs of large scale immigration of Germanic peoples, particularly into England. In a widely cited article, through DNA testing, Weale et al. argued that the Y DNA data showed signs of a mass Anglo-Saxon immigration from the European continent, affecting 50%–100% of the male genepool in Central England. This was based on the similarity of the DNA collected from the English towns to that found in Friesland.
Signatures of northern European influx to England are now widely accepted and have been shown in other early studies, such as. The Capelli study, with higher sample numbers mainly coming from larger towns, gave lower frequencies of "Germanic" genetic markers in England than did Weale. In their study, such markers typically ranged from 20% and 45% in southern England, with East Anglia, the east Midlands, and Yorkshire having over 50%. North German/Danish genetic frequencies were indistinguishable, thus precluding any ability to distinguish between the genetic influence of the Anglo-Saxon source populations and the later, and better documented, influx of Danish Vikings. The mean value of Anglo-Saxon genetic input in this study was calculated at 54 percent.
Schiffels and co-workers, in a 2016 study, calculated that a range of 25–40% of the ancestry of modern Britons is attributable to continental 'Anglo-Saxon' origins. Eastern England was ascribed 38% Anglo-Saxon ancestry on average, and the Welsh and Scottish samples given 30% Anglo-Saxon ancestry on average, with a large statistical spread. The study also found that there is a small but significant difference between the mean values in the three modern British sample groups, with East English samples sharing slightly more alleles with the Dutch, and Scottish samples looking more like the Iron Age samples.
Another 2016 study conducted using data from ancient burials found in northern England, primarily Yorkshire, found that a large genetic difference was present in bodies from the Iron Age and the Roman period on the one hand, and the Anglo-Saxon period on the other. Samples from modern-day Wales were found to be similar to those from the Iron Age and Roman burials, while samples from much of modern England, East Anglia in particular, were closer to the Anglo-Saxon-era burial. This was found to demonstrate a "profound impact" from the Anglo-Saxon migrations on the modern English gene pool, though no specific percentages were given in the study.
A study into the Norwegian Viking ancestry of British people found that there is evidence of particular concentrations in certain areas; especially the North Sea islands of Shetland and Orkney, but also to a lesser extent the Western Isles, including Skye, in Scotland, Anglesey in Wales, the Isle of Man, and the Wirral, Mid-Cheshire, West Lancashire and Cumbria in England.

Irish population

In Ireland, population genetic studies, including surname studies, have been undertaken by a team under Dan Bradley. Databases on Britain and Ireland, as well as on various surnames, are being built up from personal DNA tests, for example at FamilyTree DNA. A widely reported article in this area was, which provided Y DNA evidence that in some cases Irish surname groups were highly dominated by single male lines, presumed to be those of dynastic founders, such as Niall of the Nine Hostages.
Since 2010, use has been made of technologies which can test hundreds of thousands of possible mutation points in the rest of the human genome. The results of these large studies have shown that the main patterns of relatedness between European populations are simply geographical, meaning that the British and Irish are simply most genetically related to the people in neighbouring countries. This has not yet led to any new theories concerning migrations.
It has been proposed that Y chromosome diversity tends to change more quickly than the overall population, because at least sometimes, some male lines move more quickly than the general population, meaning that the most common Y chromosomes in areas will reflect relatively recent "waves" of human movement.
Two new genetic studies have recently been published on the Irish both showing that there is a large Northwestern French component to the Irish and a West Norwegian admixture event timed to the Viking era.

Mitochondrial DNA

In 2007, Sykes broke mitochondrial results into twelve haplogroups for various regions of the isles. He has given maps and proposals concerning ancient migrations for Ireland, Scotland, Wales and England.
Sykes and Oppenheimer have each given nicknames to various haplogroups to allow easier recognition, including the principal ones in the isles. Below the normal scientific names are given, followed by the popularised "clan names" of Sykes, and in some cases also of Oppenheimer:-
mtDNA
...and within U...
Sykes found that the maternal clan pattern was similar throughout England but with a definite trend from east and north to the south and west. The minor clans are mainly found in the east of England. Sykes found Haplogroup H to be dominant in Ireland and Wales. A few differences were found between North, Mid and South Wales. There was a closer link between North and Mid Wales than either had with the South.
Sykes found that 10% of the Irish population were in Haplogroup U5 called Ursula. He calculated a date of 7,300 BC for the entry of this lineage into Ireland. Similar dates were proposed for the other mitochondrial haplogroups, implying that mitochondrial lines in Ireland are far older there than the arrival of Iron Age Celts. Little difference was found between the maternal clans in the four provinces.

Y chromosome DNA

In 2006, Sykes produced an analysis of 6,000 samples from the OGAP project in his book Blood of the Isles. designating five main Y-DNA haplogroups for various regions of the isles. As with mitochondrial haplogroups not only Sykes but also Stephen Oppenheimer chose to popularise the concept by giving them "clan names". The following gives their normal scientific names.
The larger Haplogroup R1b is dominant in Western Europe, not only Britain and Ireland. While it was once seen as a lineage connecting the Britain and Ireland to Iberia, opinions concerning its origins have changed. It is now known R1b and R1a entered Europe with Indo-European migrants likely originating around the Black Sea; R1 is now the most common haplotype in Europe. The second most common R1b subclade in England is R1b-S21, which is most common in North Sea areas such as eastern England, the Netherlands and Denmark. Ireland is dominated by R1b-L21, which is also found in north western France, the north coast of Spain, and western Norway on continental Europe. But R1B L21 is also common and dominates certain parts of England more so than other lineages.
There are various smaller and geographically well-defined Y-DNA Haplogroups under R1b in Western Europe.
Haplogroup R1a, a distant cousin of R1b, is most common in Eastern Europe. In Britain it is associated with Scandinavian immigration during periods of Viking settlement. 25% of men in Norway belong to this haplogroup; it is much more common in Norway than the rest of Scandinavia and are survivors of its original population predating the 5000 BCE invasion of haplogroup I. Around 9% of all Scottish men belong to the Norwegian R1a subclade, which peaks at over 30% in Shetland and Orkney. However, there is no conclusive evidence that all came with Vikings, and similarities could have arisen from similar pre-Viking settlement patterns. Current Scandinavians belong to a range of haplogroups.
Haplogroup I is a grouping of several quite distantly related lineages. Looking at the three main clusters, according to with up-dated nomenclature according to ISOGG:-
Haplogroups E1b1b and J in Europe are regarded as markers of Neolithic movements from the Middle East to Southern Europe and likely to Northern Europe from there. These haplogroups are found most often in Southern Europe and North Africa. Both are rare in Northern Europe; E1b1b is found in 1% of Norwegian men, 1.5% of Scottish, 2% of English, 2.5% of Danish, 3% of Swedish and 5.5% of German. It reaches its peak in Europe in Kosovo at 47.5% and Greece at 30%.

Uncommon Y haplogroups

Geneticists have found that seven men with the surname Revis, which originates in Yorkshire, carry a genetic signature previously found only in people of West African origin. All of the men belonged to Haplogroup A1a, a subclade of Haplogroup A which geneticists believe originated in Eastern or Southern Africa. The men are not regarded as phenotypically African and there are no documents, anecdotal evidence or oral traditions suggesting that the Revis family has African ancestry. It has been conjectured that the presence of this haplogroup may date from the Roman era, when both Africans and Romans of African descent are known to have settled in Britain. According to Bryan Sykes, "although the Romans ruled from AD 43 until 410, they left a tiny genetic footprint." The genetics of some visibly white people in England suggests that they are "descended from north African, Middle Eastern and Roman clans".
Geneticists have shown that former American president Thomas Jefferson, who might have been of Welsh descent, along with two other British men of the 85 British men with the surname Jefferson, carry the rare Y chromosome marker T. This is typically found in East Africa and the Middle East. It is also found in 4.5% of Greek men, 3.5% of Estonian, and 2.5% of Spanish and Italian men, also scattered across the Alps. There have been no other documented cases of Haplogroup T occurring in Northern Europe other than those two cases. The presence of scattered and diverse European haplotypes within the network is nonetheless consistent with Jefferson's patrilineage belonging to an ancient and rare indigenous European type.