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Secrets of Fish Population Changes

A tagged bicolor damselfish (note orange tattoo) and its artificial nest box on a coral reef in the Bahamas. Photo Credit: Nikita Rolle.

A tagged bicolor damselfish (note orange tattoo) and its artificial nest box on a coral reef in the Bahamas. Photo Credit: Nikita Rolle.

MEDIA RELEASE – Populations of fish in the ocean are notoriously variable, waxing and waning in often unpredictable ways.  Knowing what drives changes in fish population sizes is important for managing fisheries and conserving species.

For the first time, scientists have linked the ecology of adult fish populations inhabiting coral reefs with the dispersal of baby fish between reefs, reporting the dynamics of a living network called a “marine metapopulation.”

“It’s not like studying deer in a forest, where one need only count births and deaths to understand how population size changes, which is difficult enough,” says senior author Mark Hixon, professor at the University of Hawaii.

“The challenge of understanding changes in reef fish abundance in a metapopulation is to measure simultaneously egg production by adults on multiple reefs and the dispersal of baby fish among those reefs, as well as other factors,” explains first author Darren Johnson, professor at the California State University, Long Beach.

Challenge indeed.  Like many ocean species, most coral reef fishes cast their tiny babies (called “larvae”) into the ocean currents, where they may or may not eventually find a reef on which to settle.

“The larvae are like lottery tickets, some of which are lucky and most of which perish,” reports co-author Mark Christie, professor at Purdue University.  “The larvae that survive may return to the same reef as their parents or settle on a reef hundreds of miles away.”

But how can these tiny babies be tracked, let alone linked to their parents?

New genetic methods analyzing small samples of fin tissue from captured and released fish allowed the scientists to compare adult bicolor damselfish in the Bahamas with baby fish appearing on the same or other reefs over 3 years, thereby matching parents with their offspring.

“Such patterns of larval connectivity have now been documented many times using genetic methods,” says co-author Tim Pusack, professor at Williams College, “but we closed the population life-cycle loop by integrating larval dispersal with egg production by adults.”

Quantifying what they called “demographic connectivity,” the scientists calculated larval dispersal as a function of initial egg production by adding artificial nests to reefs in which the damselfish laid their eggs.

“We counted how many eggs each nest produced, thereby learning how many offspring were produced at each reef,” reports co-author Christopher Stallings, professor at the University of South Florida.  “Combining these data with the genetic parentage data, we were able to estimate how many of the larvae that leave a reef come home, and how many travel to other reefs.”

The most important reefs for replenishing the overall metapopulation showed high levels of successful larval dispersal relative to the number of eggs produced.

Studying either larval dispersal alone or egg production alone, both typical of previous studies, did not provide a clear picture of the drivers of fish abundance.

“This is the first field study to successfully measure both dispersal and egg production,” reports Oregon State University fisheries oceanographer J. Wilson White, who was not involved in the study.  “These results reinforce the need to link those two pieces to understand fish population changes.”

The integration of such difficult to measure information will allow scientists to identify the most valuable reefs to protect for conservation and management of coral reef fishes.

Funded by the National Science Foundation, this research was recently published in the peer-reviewed scientific journal Ecology.

Reference:  Johnson, D. W., M. R. Christie, T. J. Pusack, C. D. Stallings, and M. A. Hixon. 2018. Integrating larval connectivity with local demography reveals regional dynamics of a marine metapopulation. Ecology 99(6): 1419-1429.  DOI: 10.1002/ecy.2343

Online:  https://esajournals.onlinelibrary.wiley.com/doi/full/10.1002/ecy.2343

Fig. 1 caption:  Life cycle of the bicolor damselfish, showing that understanding how the population changes depends on simultaneously studying the juvenile and adult fish on the coral reef as well as the larvae that disperse back to the same reef or between reefs in a metapopulation.  Illustration credit:  Darren Johnson.

Fig. 1 caption: Life cycle of the bicolor damselfish, showing that understanding how the population changes depends on simultaneously studying the juvenile and adult fish on the coral reef as well as the larvae that disperse back to the same reef or between reefs in a metapopulation. Illustration credit: Darren Johnson.

Fig. 2 caption:  A tagged bicolor damselfish (note orange tattoo) and its artificial nest box on a coral reef in the Bahamas.  Photo credit:  Nikita Rolle.

Fig. 2 caption: A tagged bicolor damselfish (note orange tattoo) and its artificial nest box on a coral reef in the Bahamas. Photo credit: Nikita Rolle.

Fig. 3 caption:  Metapopulation connectivity of bicolor damselfish populations among 4 regions of coral reef in the Exuma Sound, Bahamas.  (A) Paths of larval dispersal detected by genetic parentage analysis.  Numbers indicate number of parent-offspring pairs detected for each pattern.  (B) Estimated egg production per adult fish during each larval dispersal event (mean plus standard error).  (C)  Patterns of estimated “demographic connectivity” that integrate larval dispersal (A) with egg production (B).  Demographic connectivity represents the proportion of eggs produced at each population that survived and dispersed as larvae to other populations (arrows connecting sites) or returned to their natal populations (circular arrows).  Arrow thickness reflects estimated rate of exchange.  Illustration credit:  Darren Johnson et al.

Fig. 3 caption: Metapopulation connectivity of bicolor damselfish populations among 4 regions of coral reef in the Exuma Sound, Bahamas. (A) Paths of larval dispersal detected by genetic parentage analysis. Numbers indicate number of parent-offspring pairs detected for each pattern. (B) Estimated egg production per adult fish during each larval dispersal event (mean plus standard error). (C) Patterns of estimated “demographic connectivity” that integrate larval dispersal (A) with egg production (B). Demographic connectivity represents the proportion of eggs produced at each population that survived and dispersed as larvae to other populations (arrows connecting sites) or returned to their natal populations (circular arrows). Arrow thickness reflects estimated rate of exchange. Illustration credit: Darren Johnson et al.

Senior Author:
Dr. Mark Hixon
Department of Biology
University of Hawai‘i at Mānoa
(808) 956-6427
hixonm@hawaii.edu
http://manoa.hawaii.edu/biology/people/mark-hixon

Lead Author:
Dr. Darren Johnson
Department of Biological Sciences
California State University at Long Beach
(562) 985-5602
darren.johnson@csulb.edu
http://darrenwjohnson.weebly.com/

Co-authors:
Dr. Mark Christie
Department of Biological Sciences
Purdue University
(765) 427-8435
markchristie@purdue.edu

Dr. Timothy Pusack
Williams-Mystic
Williams College
(860) 572-5359 ext. 5
tjp3@williams.edu

Dr. Christopher Stallings
College of Marine Science
University of South Florida
(727) 553-3371
stallings@usf.edu

Quoted scientist not involved in the study:

Dr. J. Wilson White
Department of Fisheries and Wildlife
Oregon State University
(541) 867-0385
will.white@oregonstate.edu

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