# Genetic Diversity and Inter‐Specific Phylogeny of Three Sympatric Cetacean Species (Stenella spp.) in Thai Territorial Waters Based on Mitochondrial and Nuclear DNA Markers

**Authors:** Promporn Piboon, Janine L. Brown, Patcharaporn Kaewmong, Kongkiat Kittiwattanawong, Sarisa Klinhom, Toshiaki Yamamoto, Korakot Nganvongpanit

PMC · DOI: 10.1002/ece3.72322 · Ecology and Evolution · 2025-10-12

## TL;DR

This study explores the genetic diversity and potential hybridization of three dolphin species in Thai waters using DNA markers, revealing high diversity and distinct genetic clusters.

## Contribution

The study provides new genetic data on three sympatric Stenella species in Thai waters, revealing high diversity and evidence of hybridization without shared mitochondrial haplotypes.

## Key findings

- High genetic diversity was observed across all three Stenella species in Thai waters.
- Bayesian clustering suggests three genetic clusters with admixture across species, indicating hybridization.
- Unique haplotypes were found in all three species, with no shared mitochondrial DNA haplotypes between them.

## Abstract

Three Stenella species, 
S. attenuata
, 
S. coeruleoalba
, and 
S. longirostris
, are widely distributed throughout the Indo‐Pacific region, but genetic information on each population remains scarce. This gap is particularly notable in Thai waters, where these species co‐occur in overlapping oceanic habitats. In contrast, previous studies in the Atlantic have revealed moderate to high mitochondrial genetic diversity and signs of ongoing hybridization among Stenella species. These findings raise the question of whether similar genetic patterns exist in other regions. To address this, we investigated genetic diversity, population structure, potential hybridization, and historical demographic change among three Stenella dolphin species in Thai waters. We analyzed 113 stranded specimens using 20 microsatellite loci and partial mitochondrial DNA (mtDNA) control region sequences. Results revealed high genetic diversity across all species, with expected heterozygosity highest in 
S. attenuata
 (He = 0.689), followed by 
S. longirostris
 (He = 0.651), and then 
S. coeruleoalba
 (He = 0.607). By contrast, 
S. longirostris
 exhibits the highest mtDNA diversity (haplotype diversity (H) = 0.988, nucleotide diversity (π) = 0.0194), followed by 
S. coeruleoalba
 (H = 0.986, π = 0.0173), and 
S. attenuata
 (H = 0.768, π = 0.0125). No population structure was detected within individual species by Bayesian clustering methods. However, analysis of the combined dataset for all three species suggests the presence of three genetic clusters (K = 3), with evidence of admixture across species but no shared mtDNA haplotypes, indicative of male‐mediated gene flow. Unique haplotypes were also found in all three species inhabiting Thai waters. Differing demographic histories likely reflect species‐specific responses to past environmental changes and recent anthropogenic impacts. These findings provide critical genetic insights for monitoring and informing conservation strategies in Thailand and surrounding regions.

This study investigated the genetic diversity, population structure, and hybridization among three Stenella dolphin species (
S. longirostris
, 
S. attenuata
, 
S. coeruleoalba
) in Thailand's Andaman Sea using microsatellite loci and mitochondrial DNA from 113 stranded specimens. High genetic diversity was observed in all species, with potential hybridization indicated by Bayesian clustering despite no shared mtDNA haplotypes across species. The findings highlight important genetic insights for monitoring and conserving these dolphin populations in Thai and adjacent waters.

## Linked entities

- **Species:** Stenella attenuata (taxon 9735), Stenella coeruleoalba (taxon 9737), Stenella longirostris (taxon 9736)

## Full-text entities

- **Species:** Stenella longirostris (pantropical spinner dolphin, species) [taxon 9736], Stenella (genus) [taxon 93481], Stenella coeruleoalba (striped dolphin, species) [taxon 9737]

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12516012/full.md

## References

91 references — full list in the complete paper: https://tomesphere.com/paper/PMC12516012/full.md

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Source: https://tomesphere.com/paper/PMC12516012