Direct Measurement of the Mutation Rate and Its Evolutionary Consequences in a Critically Endangered Mollusk

Overview

Journal Mol Biol Evol

Publisher Oxford University Press

Specialty Biology

Date 2025 Jan 8

PMID 39775835

Authors

T Brock Wooldridge

Sarah M Ford

Holland C Conwell

John Hyde

Kelley Harris

Beth Shapiro

Affiliations

Soon will be listed here.

Abstract

The rate at which mutations arise is a fundamental parameter of biology. Despite progress in measuring germline mutation rates across diverse taxa, such estimates are missing for much of Earth's biodiversity. Here, we present the first estimate of a germline mutation rate from the phylum Mollusca. We sequenced three pedigreed families of the white abalone Haliotis sorenseni, a long-lived, large-bodied, and critically endangered mollusk, and estimated a de novo mutation rate of 8.60 × 10-9 single nucleotide mutations per site per generation. This mutation rate is similar to rates measured in vertebrates with comparable generation times and longevity to abalone, and higher than mutation rates measured in faster-reproducing invertebrates. The spectrum of de novo mutations is also similar to that seen in vertebrate species, although an excess of rare C > A polymorphisms in wild individuals suggests that a modifier allele or environmental exposure may have once increased C > A mutation rates. We use our rate to infer baseline effective population sizes (Ne) across multiple Pacific abalone and find that abalone persisted over most of their evolutionary history as large and stable populations, in contrast to extreme fluctuations over recent history and small census sizes in the present day. We then use our mutation rate to infer the timing and pattern of evolution of the abalone genus Haliotis, which was previously unknown due to few fossil calibrations. Our findings are an important step toward understanding mutation rate evolution and they establish a key parameter for conservation and evolutionary genomics research in mollusks.

Citing Articles

Population size interacts with reproductive longevity to shape the germline mutation rate.

Zhu L, Beichman A, Harris K bioRxiv. 2024; .

PMID: 39574678 PMC: 11580940. DOI: 10.1101/2023.12.06.570457.

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