Y-chromosome and Surname Analyses for Reconstructing Past Population Structures: The Sardinian Population As a Test Case

Overview

Journal Int J Mol Sci

Publisher MDPI

Specialties Biochemistry
Chemistry
Molecular Biology

Date 2019 Nov 21

PMID 31744094

Citations 3

Authors

Viola Grugni

Alessandro Raveane

Giulia Colombo

Carmen Nici

Francesca Crobu

Linda Ongaro

Vincenza Battaglia

Daria Sanna

Nadia Al-Zahery

Ornella Fiorani

Antonella Lisa

Luca Ferretti

Alessandro Achilli

Anna Olivieri

Paolo Francalacci

Alberto Piazza

Antonio Torroni

Ornella Semino

Affiliations

Soon will be listed here.

Abstract

Many anthropological, linguistic, genetic and genomic analyses have been carried out to evaluate the potential impact that evolutionary forces had in shaping the present-day Sardinian gene pool, the main outlier in the genetic landscape of Europe. However, due to the homogenizing effect of internal movements, which have intensified over the past fifty years, only partial information has been obtained about the main demographic events. To overcome this limitation, we analyzed the male-specific region of the Y chromosome in three population samples obtained by reallocating a large number of Sardinian subjects to the place of origin of their monophyletic surnames, which are paternally transmitted through generations in most of the populations, much like the Y chromosome. Three Y-chromosome founding lineages, G2-L91, I2-M26 and R1b-V88, were identified as strongly contributing to the definition of the outlying position of Sardinians in the European genetic context and marking a significant differentiation within the island. The present distribution of these lineages does not always mirror that detected in ancient DNAs. Our results show that the analysis of the Y-chromosome gene pool coupled with a sampling method based on the origin of the family name, is an efficient approach to unravelling past heterogeneity, often hidden by recent movements, in the gene pool of modern populations. Furthermore, the reconstruction and comparison of past genetic isolates represent a starting point to better assess the genetic information deriving from the increasing number of available ancient DNA samples.

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