Khoe-San Genomes Reveal Unique Variation and Confirm the Deepest Population Divergence in Homo sapiens

Schlebusch, Carina M.; Sjödin, Per; Breton, Gwenna; Günther, Torsten; Naidoo, Thijessen; Hollfelder, Nina; Sjöstrand, Agnès E.; Xu, Jingzi; Gattepaille, Lucie M.; Vicente, Mário; Scofield, Douglas G.; Malmström, Helena; Jongh, Michael De; Lombard, Marlize; Soodyall, Himla; Jakobsson, Mattias

doi:10.1093/molbev/msaa140

Cited by 73 publications

(93 citation statements)

References 48 publications

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“…The fact that the precuneus in its current form is, however, already visible in the palaeoneurological record from1 00 ka during the MSA, reveals a different scenario. Also, initial work on the genomes of living Khoe-San and ancient hunter-gatherer populations from southern Africa indicates selection for brain-selective gene regions associated with neuron connectivity at more than 300 ka (Schlebusch et al 2020). Based on what we presented here as part of our four-field co-evolutionary exploration, we suggest that the current evidence supports a scenario of long-term, incremental physiological, neurological, genetic, and socio-technical developments that gave rise to the sapient mind since the H. sapiens-Neanderthal split several hundred thousand years ago, instead of an abrupt appearance post-50 ka.…”

Section: Concluding Discussionmentioning

confidence: 99%

“…Some of the genes in their list affect neurons, brain growth and cognition, and one of them (ADSL) has recently been identified as selected for in H. sapiens after our divergence from Neanderthals (Stepanova et al 2020). Based on the genomes of living and ancient Khoe-San populations from southern Africa, Schlebusch et al (2020) found new variations in early H. sapiens subsequent to their split from the Neanderthals, but before their split from other African populations at more than 300 ka. These findings include a brainrelated region of the LPHN3 gene on chromosome 4, which plays an important role in determining the connectivity rates between the principal neurons of the cortex.…”

Section: Grade 7 Causal Network Cognitionmentioning

confidence: 99%

“…It is our take, however, that human cognitive evolution is a long, incremental, multi-faceted, and continuous process. The genetic and fossil records place the emergence of H. sapiens at~300 ka, with a focus on sub-Saharan Africa (see Mounier and Lahr 2019 for synthesis; also Schlebusch et al 2020). Work on the archaeological record over the last two decades and a re-assessment of the behavioural modernity thesis demonstrate that complex cognition can be traced back to at least 100 ka in H. sapiens populations from the region (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Four-Field Co-evolutionary Model for Human Cognition: Variation in the Middle Stone Age/Middle Palaeolithic

Lombard

Högberg

2021

J Archaeol Method Theory

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Here we explore variation and similarities in the two best-represented population groups who lived during the Middle Stone Age and Middle Palaeolithic—the Neanderthals and Homo sapiens. Building on approaches such as gene-culture co-evolution, we propose a four-field model to discuss relationships between human cognitive evolution, biology, technology, society, and ecology. We focus on the pre-50-ka phase, because we reason that later admixing between Neanderthals and Homo sapiens in Eurasia may make it difficult to separate them in terms of cognition, or any of the other fields discussed in this paper. Using our model enabled us to highlight similarities in cognition between the two populations in terms of symbolic behaviour and social learning and to identify differences in aspects of technical and social cognition. Dissimilarities in brain-selective gene variants and brain morphology strongly suggest differences in some evolutionary trajectories that would have affected cognition. We therefore suggest that rather than insisting that Neanderthals were cognitively ‘the same’ as Homo sapiens, it may be useful to focus future studies on Neanderthal-specific cognition that may have been well-developed within their specific context at the time.

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Section: Concluding Discussionmentioning

confidence: 99%

Section: Grade 7 Causal Network Cognitionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Four-Field Co-evolutionary Model for Human Cognition: Variation in the Middle Stone Age/Middle Palaeolithic

Lombard

Högberg

2021

J Archaeol Method Theory

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“…S8). This study also identifies a large set of old variants, well before 300kya, associated with genes belonging to putative positively-selected regions before the deepest divergence of Homo sapiens populations [34], such as LPHN3, FBXW7, and COG5 (figure S9).…”

Section: Variant Subset Distributionsmentioning

confidence: 90%

Fine-grained temporal mapping of derived high-frequency variants supports the mosaic nature of the evolution ofHomo sapiens

Andirkó

Moriano

Vitriolo

et al. 2021

Preprint

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As our knowledge about the history of the sapiens lineage becomes increasingly complex, large-scale estimations of the time of emergence of derived variants become essential to be able to offer more precise answers to time-sensitive hypotheses concerning human evolution. Using an open repository of genetic variant age estimations recently made available, we offer here a temporal evaluation of various evolutionarily relevant datasets, such as sapiens-specific variants, high-frequency variants found in genetic windows under positive selection, introgressed variants from extinct human species, as well as putative regulatory variants in various brain regions. We find a recurrent bimodal distribution of high-frequency variants, but also evidence for specific enrichments of gene categories in various time windows, which brings into prominence the 300-500k time slice. We also find evidence for very early mutations impacting the facial phenotype, and much more recent molecular events linked to specific brain regions such as the cerebellum or the precuneus. Additionally, we present a case study of an evolutionarily relevant gene, BAZ1B, and its targets, to emphasize the importance of applying temporal data to specific evolutionary questions. Overall, we present a unique resource that informs and complements our previous knowledge of sapiens evolution using publicly available data, and reinforce the case for the mosaic, temporally very extended nature of the evolutionary trajectory of our species.

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“…Such phenotypes include energy storage and enhanced use of metabolic water, reduced nonrenal water loss, low energy expenditure, ability to cope with high-salt diets without developing hypertension, adaptive tolerance to starvation and dehydration, and decreased renal water loss (Box 1 and Figure 1D). Some studies additionally identified functional categories of genes involved in stress responses (oxidative stress, DNA damage and repair, and heat stress) [13,18,32], response to radiation [32,56], dust ingestion [32], and toxic diets (perception of bitter taste [18] and xenobiotic metabolism [17,32,57]) as targets of natural selection, suggesting other biological adaptations that have not been explicitly targeted in phenotypic studies.…”

Section: Convergent Evolution At the Genetic Levelmentioning

confidence: 99%

Life in Deserts: The Genetic Basis of Mammalian Desert Adaptation

Rocha

Godinho

Brito

et al. 2021

Trends in Ecology & Evolution

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Deserts are among the harshest environments on Earth. The multiple ages of different deserts and their global distribution provide a unique opportunity to study repeated adaptation at different timescales. Here, we summarize recent genomic research on the genetic mechanisms underlying desert adaptations in mammals. Several studies on different desert mammals show large overlap in functional classes of genes and pathways, consistent with the complexity and variety of phenotypes associated with desert adaptation to water and food scarcity and extreme temperatures. However, studies of desert adaptation are also challenged by a lack of accurate genotype-phenotype-environment maps. We encourage development of systems that facilitate functional analyses, but also acknowledge the need for more studies on a wider variety of desert mammals. Deserts: Natural Laboratories for Studies of AdaptationDeserts (see Glossary) are the driest environments on the planet and cover at least 33% of the land surface on Earth [1]. Although mainly characterized by aridity and water scarcity, deserts also experience daily and annual extreme thermal amplitudes, and intense UV radiation [1]. Deserts have long been seen as natural laboratories for investigating how biological design is challenged by different aspects of the environment, and how organisms have adapted to these challenges [1,2]. They also offer unique opportunities to study convergent evolution at distinct points in time and space, given their well-documented geological age and diverse geographical origins [1,2].

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Khoe-San Genomes Reveal Unique Variation and Confirm the Deepest Population Divergence in Homo sapiens

Cited by 73 publications

References 48 publications

Four-Field Co-evolutionary Model for Human Cognition: Variation in the Middle Stone Age/Middle Palaeolithic

Four-Field Co-evolutionary Model for Human Cognition: Variation in the Middle Stone Age/Middle Palaeolithic

Fine-grained temporal mapping of derived high-frequency variants supports the mosaic nature of the evolution ofHomo sapiens

Life in Deserts: The Genetic Basis of Mammalian Desert Adaptation

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