Machine learning dissection of human accelerated regions in primate neurodevelopment

Sean Whalen; Fumitaka Inoue; Hane Ryu; Tyler Fair; Eirene Markenscoff-Papadimitriou; Kathleen Keough; Martin Kircher; Beth Martin; Beatriz Alvarado; Orry Elor; Dianne Laboy Cintron; Alex Williams; Md Abul Hassan Samee; Sean Thomas; Robert Krencik; Erik M. Ullian; Arnold Kriegstein; John L. Rubenstein; Jay Shendure; Alex A. Pollen; Nadav Ahituv; Katherine S. Pollard

doi:10.1016/j.neuron.2022.12.026

Machine learning dissection of human accelerated regions in primate neurodevelopment

Sean Whalen, Fumitaka Inoue, Hane Ryu, Tyler Fair, Eirene Markenscoff-Papadimitriou, Kathleen Keough, Martin Kircher, Beth Martin, Beatriz Alvarado, Orry Elor, Dianne Laboy Cintron, Alex Williams, Md Abul Hassan Samee, Sean Thomas, Robert Krencik, Erik M. Ullian, Arnold Kriegstein, John L. Rubenstein, Jay Shendure, Alex A. PollenNadav Ahituv^*, Katherine S. Pollard^*

^*Corresponding author for this work

Institute of Human Genetics

Abstract

Using machine learning (ML), we interrogated the function of all human-chimpanzee variants in 2,645 human accelerated regions (HARs), finding 43% of HARs have variants with large opposing effects on chromatin state and 14% on neurodevelopmental enhancer activity. This pattern, consistent with compensatory evolution, was confirmed using massively parallel reporter assays in chimpanzee and human neural progenitor cells. The species-specific enhancer activity of HARs was accurately predicted from the presence and absence of transcription factor footprints in each species. Despite these striking cis effects, activity of a given HAR sequence was nearly identical in human and chimpanzee cells. This suggests that HARs did not evolve to compensate for changes in the trans environment but instead altered their ability to bind factors present in both species. Thus, ML prioritized variants with functional effects on human neurodevelopment and revealed an unexpected reason why HARs may have evolved so rapidly.

Original language	English
Journal	Neuron
Volume	111
Issue number	6
Pages (from-to)	857-873.e8
ISSN	0896-6273
DOIs	https://doi.org/10.1016/j.neuron.2022.12.026
Publication status	Published - 15.03.2023

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Whalen, S., Inoue, F., Ryu, H., Fair, T., Markenscoff-Papadimitriou, E., Keough, K., Kircher, M., Martin, B., Alvarado, B., Elor, O., Laboy Cintron, D., Williams, A., Hassan Samee, M. A., Thomas, S., Krencik, R., Ullian, E. M., Kriegstein, A., Rubenstein, J. L., Shendure, J., ... Pollard, K. S. (2023). Machine learning dissection of human accelerated regions in primate neurodevelopment. Neuron, 111(6), 857-873.e8. https://doi.org/10.1016/j.neuron.2022.12.026

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title = "Machine learning dissection of human accelerated regions in primate neurodevelopment",

abstract = "Using machine learning (ML), we interrogated the function of all human-chimpanzee variants in 2,645 human accelerated regions (HARs), finding 43% of HARs have variants with large opposing effects on chromatin state and 14% on neurodevelopmental enhancer activity. This pattern, consistent with compensatory evolution, was confirmed using massively parallel reporter assays in chimpanzee and human neural progenitor cells. The species-specific enhancer activity of HARs was accurately predicted from the presence and absence of transcription factor footprints in each species. Despite these striking cis effects, activity of a given HAR sequence was nearly identical in human and chimpanzee cells. This suggests that HARs did not evolve to compensate for changes in the trans environment but instead altered their ability to bind factors present in both species. Thus, ML prioritized variants with functional effects on human neurodevelopment and revealed an unexpected reason why HARs may have evolved so rapidly.",

author = "Sean Whalen and Fumitaka Inoue and Hane Ryu and Tyler Fair and Eirene Markenscoff-Papadimitriou and Kathleen Keough and Martin Kircher and Beth Martin and Beatriz Alvarado and Orry Elor and {Laboy Cintron}, Dianne and Alex Williams and {Hassan Samee}, {Md Abul} and Sean Thomas and Robert Krencik and Ullian, {Erik M.} and Arnold Kriegstein and Rubenstein, {John L.} and Jay Shendure and Pollen, {Alex A.} and Nadav Ahituv and Pollard, {Katherine S.}",

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doi = "10.1016/j.neuron.2022.12.026",

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Whalen, S, Inoue, F, Ryu, H, Fair, T, Markenscoff-Papadimitriou, E, Keough, K, Kircher, M, Martin, B, Alvarado, B, Elor, O, Laboy Cintron, D, Williams, A, Hassan Samee, MA, Thomas, S, Krencik, R, Ullian, EM, Kriegstein, A, Rubenstein, JL, Shendure, J, Pollen, AA, Ahituv, N & Pollard, KS 2023, 'Machine learning dissection of human accelerated regions in primate neurodevelopment', Neuron, vol. 111, no. 6, pp. 857-873.e8. https://doi.org/10.1016/j.neuron.2022.12.026

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T1 - Machine learning dissection of human accelerated regions in primate neurodevelopment

AU - Whalen, Sean

AU - Inoue, Fumitaka

AU - Ryu, Hane

AU - Fair, Tyler

AU - Markenscoff-Papadimitriou, Eirene

AU - Keough, Kathleen

AU - Kircher, Martin

AU - Martin, Beth

AU - Alvarado, Beatriz

AU - Elor, Orry

AU - Laboy Cintron, Dianne

AU - Williams, Alex

AU - Hassan Samee, Md Abul

AU - Thomas, Sean

AU - Krencik, Robert

AU - Ullian, Erik M.

AU - Kriegstein, Arnold

AU - Rubenstein, John L.

AU - Shendure, Jay

AU - Pollen, Alex A.

AU - Ahituv, Nadav

AU - Pollard, Katherine S.

PY - 2023/3/15

Y1 - 2023/3/15

N2 - Using machine learning (ML), we interrogated the function of all human-chimpanzee variants in 2,645 human accelerated regions (HARs), finding 43% of HARs have variants with large opposing effects on chromatin state and 14% on neurodevelopmental enhancer activity. This pattern, consistent with compensatory evolution, was confirmed using massively parallel reporter assays in chimpanzee and human neural progenitor cells. The species-specific enhancer activity of HARs was accurately predicted from the presence and absence of transcription factor footprints in each species. Despite these striking cis effects, activity of a given HAR sequence was nearly identical in human and chimpanzee cells. This suggests that HARs did not evolve to compensate for changes in the trans environment but instead altered their ability to bind factors present in both species. Thus, ML prioritized variants with functional effects on human neurodevelopment and revealed an unexpected reason why HARs may have evolved so rapidly.

AB - Using machine learning (ML), we interrogated the function of all human-chimpanzee variants in 2,645 human accelerated regions (HARs), finding 43% of HARs have variants with large opposing effects on chromatin state and 14% on neurodevelopmental enhancer activity. This pattern, consistent with compensatory evolution, was confirmed using massively parallel reporter assays in chimpanzee and human neural progenitor cells. The species-specific enhancer activity of HARs was accurately predicted from the presence and absence of transcription factor footprints in each species. Despite these striking cis effects, activity of a given HAR sequence was nearly identical in human and chimpanzee cells. This suggests that HARs did not evolve to compensate for changes in the trans environment but instead altered their ability to bind factors present in both species. Thus, ML prioritized variants with functional effects on human neurodevelopment and revealed an unexpected reason why HARs may have evolved so rapidly.

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SN - 0896-6273

VL - 111

SP - 857-873.e8

JO - Neuron

JF - Neuron

IS - 6

ER -

Machine learning dissection of human accelerated regions in primate neurodevelopment

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