# Genetic Population Structure of the Italian Wall Lizards Podarcis siculus (Squamata: Lacertidae): Insight From Nuclear DNA Markers

**Authors:** Gabriele Senczuk, Chiara Ripa, Paolo Colangelo, Riccardo Castiglia

PMC · DOI: 10.1002/ece3.72655 · Ecology and Evolution · 2026-01-15

## TL;DR

This study uses nuclear DNA markers to explore the genetic structure of Italian wall lizards and finds partial agreement with mitochondrial patterns, highlighting complex evolutionary history and gene flow.

## Contribution

The study reveals mito-nuclear discordance in Podarcis siculus using multilocus nuclear microsatellite data, offering new insights into Pleistocene-driven range dynamics.

## Key findings

- Eight genetic clusters were identified, partially aligning with mtDNA lineages.
- Mito-nuclear mismatches suggest asymmetric introgression and differential lineage sorting.
- Southern Italy and Sicily show significant discrepancies between mtDNA and nuclear data.

## Abstract

Since the Quaternary, recurrent climatic oscillations have profoundly shaped species distributions across the Mediterranean basin, generating complex phylogeographic patterns through repeated cycles of range contraction and expansion. The Italian Peninsula, characterized by a highly heterogeneous topography and a mosaic of glacial refugia, has emerged as a hotspot of intraspecific genetic diversity. The Italian wall lizard (Podarcis siculus), a widespread species across the Italian Peninsula and adjacent islands, represents an excellent model for exploring these dynamics. Previous phylogeographic studies based on mitochondrial (mtDNA) and nuclear (nuDNA) markers have revealed a highly structured matrilineal organization, with several parapatric lineages and subclades, but have also highlighted weak differentiation in nuDNA, suggesting possible mito‐nuclear discordance. In this study, we used multilocus nuclear microsatellite data to (i) evaluate whether the complex mtDNA phylogeographic structure is reflected in nuclear markers, or whether evidence of mito‐nuclear discordance is present, and (ii) quantify admixture and gene flow among mitochondrial lineages. Our results reveal partial congruence between mtDNA and nuclear patterns, with evidence of both historical isolation and secondary contact among major clades. However, several populations exhibit substantial mito‐nuclear mismatches, suggesting a history of asymmetric introgression and differential lineage sorting. These findings indicate that 
P. siculus
 experienced multiple phases of demographic expansion and secondary contact, consistent with Pleistocene‐driven range dynamics, and that mito‐nuclear discordance has played a significant role in shaping its current genetic landscape. This study underscores the importance of integrating multilocus nuclear data with mitochondrial evidence to disentangle the evolutionary processes driving complex phylogeographic patterns in Mediterranean taxa.

Microsatellite analysis of 294 Podarcis siculus specimens from 121 localities revealed eight genetic clusters that partially align with previously identified mtDNA lineages. However, notable mito‐nuclear discordance was observe, particularly in Southern Italy and Sicily, where microsatellite data indicated different contact zones and less genetic structure than mtDNA suggested. These discrepancies likely stem from factors including differential introgression, distinct dispersal patterns (e.g., sex‐biased philopatry), and varying evolutionary timescales captured by mitochondrial versus nuclear markers.

## Linked entities

- **Species:** Podarcis siculus (taxon 65484)

## Full-text entities

- **Species:** Podarcis muralis (Common wall lizard, species) [taxon 64176], Squamata (squamates, order) [taxon 8509], Podarcis siculus (Italian wall lizard, species) [taxon 65484]

## Full text

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## Figures

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## References

56 references — full list in the complete paper: https://tomesphere.com/paper/PMC12808333/full.md

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Source: https://tomesphere.com/paper/PMC12808333