Cargando…
The evolution and population diversity of human-specific segmental duplications
Segmental duplications contribute to human evolution, adaptation and genomic instability but are often poorly characterized. We investigate the evolution, genetic variation and coding potential of human-specific segmental duplications (HSDs). We identify 218 HSDs based on analysis of 322 deeply sequ...
| Autores principales: | , , , , , , , , , , , , , , , , , , , , |
|---|---|
| Formato: | Online Artículo Texto |
| Lenguaje: | English |
| Publicado: |
2017
|
| Materias: | |
| Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5450946/ https://www.ncbi.nlm.nih.gov/pubmed/28580430 http://dx.doi.org/10.1038/s41559-016-0069 |
| _version_ | 1783240080861691904 |
|---|---|
| author | Dennis, Megan Y. Harshman, Lana Nelson, Bradley J. Penn, Osnat Cantsilieris, Stuart Huddleston, John Antonacci, Francesca Penewit, Kelsi Denman, Laura Raja, Archana Baker, Carl Mark, Kenneth Malig, Maika Janke, Nicolette Espinoza, Claudia Stessman, Holly A.F. Nuttle, Xander Hoekzema, Kendra Lindsay-Graves, Tina A. Wilson, Richard K. Eichler, Evan E. |
| author_facet | Dennis, Megan Y. Harshman, Lana Nelson, Bradley J. Penn, Osnat Cantsilieris, Stuart Huddleston, John Antonacci, Francesca Penewit, Kelsi Denman, Laura Raja, Archana Baker, Carl Mark, Kenneth Malig, Maika Janke, Nicolette Espinoza, Claudia Stessman, Holly A.F. Nuttle, Xander Hoekzema, Kendra Lindsay-Graves, Tina A. Wilson, Richard K. Eichler, Evan E. |
| author_sort | Dennis, Megan Y. |
| collection | PubMed |
| description | Segmental duplications contribute to human evolution, adaptation and genomic instability but are often poorly characterized. We investigate the evolution, genetic variation and coding potential of human-specific segmental duplications (HSDs). We identify 218 HSDs based on analysis of 322 deeply sequenced archaic and contemporary hominid genomes. We sequence 550 human and nonhuman primate genomic clones to reconstruct the evolution of the largest, most complex regions with protein-coding potential (n=80 genes/33 gene families). We show that HSDs are non-randomly organized, associate preferentially with ancestral ape duplications termed “core duplicons”, and evolved primarily in an interspersed inverted orientation. In addition to Homo sapiens-specific gene expansions (e.g., TCAF1/2), we highlight ten gene families (e.g., ARHGAP11B and SRGAP2C) where copy number never returns to the ancestral state, there is evidence of mRNA splicing, and no common gene-disruptive mutations are observed in the general population. Such duplicates are candidates for the evolution of human-specific adaptive traits. |
| format | Online Article Text |
| id | pubmed-5450946 |
| institution | National Center for Biotechnology Information |
| language | English |
| publishDate | 2017 |
| record_format | MEDLINE/PubMed |
| spelling | pubmed-54509462017-08-17 The evolution and population diversity of human-specific segmental duplications Dennis, Megan Y. Harshman, Lana Nelson, Bradley J. Penn, Osnat Cantsilieris, Stuart Huddleston, John Antonacci, Francesca Penewit, Kelsi Denman, Laura Raja, Archana Baker, Carl Mark, Kenneth Malig, Maika Janke, Nicolette Espinoza, Claudia Stessman, Holly A.F. Nuttle, Xander Hoekzema, Kendra Lindsay-Graves, Tina A. Wilson, Richard K. Eichler, Evan E. Nat Ecol Evol Article Segmental duplications contribute to human evolution, adaptation and genomic instability but are often poorly characterized. We investigate the evolution, genetic variation and coding potential of human-specific segmental duplications (HSDs). We identify 218 HSDs based on analysis of 322 deeply sequenced archaic and contemporary hominid genomes. We sequence 550 human and nonhuman primate genomic clones to reconstruct the evolution of the largest, most complex regions with protein-coding potential (n=80 genes/33 gene families). We show that HSDs are non-randomly organized, associate preferentially with ancestral ape duplications termed “core duplicons”, and evolved primarily in an interspersed inverted orientation. In addition to Homo sapiens-specific gene expansions (e.g., TCAF1/2), we highlight ten gene families (e.g., ARHGAP11B and SRGAP2C) where copy number never returns to the ancestral state, there is evidence of mRNA splicing, and no common gene-disruptive mutations are observed in the general population. Such duplicates are candidates for the evolution of human-specific adaptive traits. 2017-02-17 2017 /pmc/articles/PMC5450946/ /pubmed/28580430 http://dx.doi.org/10.1038/s41559-016-0069 Text en Users may view, print, copy, and download text and data-mine the content in such documents, for the purposes of academic research, subject always to the full Conditions of use: http://www.nature.com/authors/editorial_policies/license.html#terms |
| spellingShingle | Article Dennis, Megan Y. Harshman, Lana Nelson, Bradley J. Penn, Osnat Cantsilieris, Stuart Huddleston, John Antonacci, Francesca Penewit, Kelsi Denman, Laura Raja, Archana Baker, Carl Mark, Kenneth Malig, Maika Janke, Nicolette Espinoza, Claudia Stessman, Holly A.F. Nuttle, Xander Hoekzema, Kendra Lindsay-Graves, Tina A. Wilson, Richard K. Eichler, Evan E. The evolution and population diversity of human-specific segmental duplications |
| title | The evolution and population diversity of human-specific segmental duplications |
| title_full | The evolution and population diversity of human-specific segmental duplications |
| title_fullStr | The evolution and population diversity of human-specific segmental duplications |
| title_full_unstemmed | The evolution and population diversity of human-specific segmental duplications |
| title_short | The evolution and population diversity of human-specific segmental duplications |
| title_sort | evolution and population diversity of human-specific segmental duplications |
| topic | Article |
| url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5450946/ https://www.ncbi.nlm.nih.gov/pubmed/28580430 http://dx.doi.org/10.1038/s41559-016-0069 |
| work_keys_str_mv | AT dennismegany theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT harshmanlana theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT nelsonbradleyj theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT pennosnat theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT cantsilierisstuart theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT huddlestonjohn theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT antonaccifrancesca theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT penewitkelsi theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT denmanlaura theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT rajaarchana theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT bakercarl theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT markkenneth theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT maligmaika theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT jankenicolette theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT espinozaclaudia theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT stessmanhollyaf theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT nuttlexander theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT hoekzemakendra theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT lindsaygravestinaa theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT wilsonrichardk theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT eichlerevane theevolutionandpopulationdiversityofhumanspecificsegmentalduplications AT dennismegany evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT harshmanlana evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT nelsonbradleyj evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT pennosnat evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT cantsilierisstuart evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT huddlestonjohn evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT antonaccifrancesca evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT penewitkelsi evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT denmanlaura evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT rajaarchana evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT bakercarl evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT markkenneth evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT maligmaika evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT jankenicolette evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT espinozaclaudia evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT stessmanhollyaf evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT nuttlexander evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT hoekzemakendra evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT lindsaygravestinaa evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT wilsonrichardk evolutionandpopulationdiversityofhumanspecificsegmentalduplications AT eichlerevane evolutionandpopulationdiversityofhumanspecificsegmentalduplications |