Saved in:
Bibliographic Details
Main Authors: Armstrong, Katrina C, Lippert, Marilla, Hanson, Erik, Nestor, Victor, Cornwell, Brendan, Walker, Nia S, Golbuu, Yimnang, Palumbi, Stephen R
Format: Artículo científico
Language:en
Published: Ecology and evolution 2024
Online Access:https://pubmed.ncbi.nlm.nih.gov/39691438/
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1868266265825509376
author Armstrong, Katrina C
Lippert, Marilla
Hanson, Erik
Nestor, Victor
Cornwell, Brendan
Walker, Nia S
Golbuu, Yimnang
Palumbi, Stephen R
author_facet Armstrong, Katrina C
Lippert, Marilla
Hanson, Erik
Nestor, Victor
Cornwell, Brendan
Walker, Nia S
Golbuu, Yimnang
Palumbi, Stephen R
Armstrong, Katrina C
Lippert, Marilla
Hanson, Erik
Nestor, Victor
Cornwell, Brendan
Walker, Nia S
Golbuu, Yimnang
Palumbi, Stephen R
collection PubMed - marine biology
contents Fine-Scale Geographic Variation of in Across the Palauan Archipelago. Armstrong, Katrina C Lippert, Marilla Hanson, Erik Nestor, Victor Cornwell, Brendan Walker, Nia S Golbuu, Yimnang Palumbi, Stephen R Symbiont genotype plays a vital role in the ability of a coral host to tolerate rising ocean temperatures, with some members of the family Symbiodiniaceae possessing more thermal tolerance than others. While existing studies on genetic structure in symbiont populations have focused on broader scales of 10-100 s of km, there is a noticeable gap in understanding the seascape genetics of coral symbionts at finer-yet ecologically and evolutionarily relevant-scales. Here, we mapped short reads from 271 holobiont genome libraries of individual colonies to protein coding genes from the chloroplast genome to identify patterns of symbiont population genetic structure. Utilizing this low-pass method, we assayed over 13,000 bases from every individual, enabling us to discern genetic variation at a finer geographic scale than previously reported at the population level. We identified five common chloroplast SNP profiles present across Palau, with symbiont structure varying between Northern, mid-lagoon, and Southern regions, and inshore-offshore gradients. Although symbiont populations within reefs typically contained significant genetic diversity, we also observed genetic structure between some nearby reefs. To explore whether coral hosts retain their symbionts post-transplantation, we experimentally moved 79 corals from their native reefs to transplant sites with both different and similar chloroplast SNP profiles. Over 12 months, we observed 12 instances where transplanted corals changed profiles, often transitioning to a profile present in adjacent corals. Symbiont genetic structure between reefs suggests either low dispersal of symbionts or environmental selection against dispersers, both resulting in the potential for significant adaptive differentiation across reef environments. The extent to which local corals and their symbionts are co-adapted to environments on a reef-by-reef scale is currently poorly known. Chloroplast sequences offer an additional tool for monitoring symbiont genetics and coral-symbiont interactions when assisted migration is used in restoration.
format Artículo científico
id pubmed_39691438
institution PubMed
language en
publishDate 2024
publisher Ecology and evolution
record_format pubmed
spellingShingle Fine-Scale Geographic Variation of in Across the Palauan Archipelago.
Armstrong, Katrina C
Lippert, Marilla
Hanson, Erik
Nestor, Victor
Cornwell, Brendan
Walker, Nia S
Golbuu, Yimnang
Palumbi, Stephen R
Fine-Scale Geographic Variation of in Across the Palauan Archipelago. Armstrong, Katrina C Lippert, Marilla Hanson, Erik Nestor, Victor Cornwell, Brendan Walker, Nia S Golbuu, Yimnang Palumbi, Stephen R Symbiont genotype plays a vital role in the ability of a coral host to tolerate rising ocean temperatures, with some members of the family Symbiodiniaceae possessing more thermal tolerance than others. While existing studies on genetic structure in symbiont populations have focused on broader scales of 10-100 s of km, there is a noticeable gap in understanding the seascape genetics of coral symbionts at finer-yet ecologically and evolutionarily relevant-scales. Here, we mapped short reads from 271 holobiont genome libraries of individual colonies to protein coding genes from the chloroplast genome to identify patterns of symbiont population genetic structure. Utilizing this low-pass method, we assayed over 13,000 bases from every individual, enabling us to discern genetic variation at a finer geographic scale than previously reported at the population level. We identified five common chloroplast SNP profiles present across Palau, with symbiont structure varying between Northern, mid-lagoon, and Southern regions, and inshore-offshore gradients. Although symbiont populations within reefs typically contained significant genetic diversity, we also observed genetic structure between some nearby reefs. To explore whether coral hosts retain their symbionts post-transplantation, we experimentally moved 79 corals from their native reefs to transplant sites with both different and similar chloroplast SNP profiles. Over 12 months, we observed 12 instances where transplanted corals changed profiles, often transitioning to a profile present in adjacent corals. Symbiont genetic structure between reefs suggests either low dispersal of symbionts or environmental selection against dispersers, both resulting in the potential for significant adaptive differentiation across reef environments. The extent to which local corals and their symbionts are co-adapted to environments on a reef-by-reef scale is currently poorly known. Chloroplast sequences offer an additional tool for monitoring symbiont genetics and coral-symbiont interactions when assisted migration is used in restoration.
title Fine-Scale Geographic Variation of in Across the Palauan Archipelago.
url https://pubmed.ncbi.nlm.nih.gov/39691438/