To sea or not to sea? Multiple lines of evidence reveal the contribution of non‐diadromous recruitment for supporting endemic fish populations within New Zealand's longest river

Otolith microchemistry was used to identify marine‐ versus freshwater‐derived recruitment of three native freshwater fish species belonging to the southern hemisphere family Galaxiidae, in New Zealand's longest river system, the Waikato River. Water chemistry data for trace elements and 87Sr/86...

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Bibliographic Details
Published inAquatic conservation Vol. 29; no. 9; pp. 1409 - 1423
Main Authors David, Bruno O., Jarvis, Matt, Özkundakci, Deniz, Collier, Kevin J., Hicks, Andy S., Reid, Malcolm
Format Journal Article
LanguageEnglish
Published Oxford Wiley Subscription Services, Inc 01.09.2019
Subjects
Ablation
Catchment area
Catchment scale
Depth profiling
Dispersal
Ecological monitoring
Endemic species
Fish
Fish populations
Floodplains
Freshwater
Freshwater fish
Galaxiidae
Indigenous species
Individual rearing
Inland water environment
Isotope ratios
Isotopes
Lakes
Larvae
Laser ablation
Lasers
LA‐ICPMS
Mass spectrometry
Mass spectroscopy
Microchemistry
Organic chemistry
otolith microchemistry
Otoliths
Outflow
Outlets
Populations
Ratios
Recruitment
Recruitment (fisheries)
recruitment source
restoration
River catchments
River discharge
Rivers
riverscape
Southern Hemisphere
Spawning
Strontium 87
Strontium isotopes
Trace elements
Water analysis
Water chemistry
Water outflow
New Zealand
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Summary:Otolith microchemistry was used to identify marine‐ versus freshwater‐derived recruitment of three native freshwater fish species belonging to the southern hemisphere family Galaxiidae, in New Zealand's longest river system, the Waikato River. Water chemistry data for trace elements and 87Sr/86Sr isotope ratios were collected from five lentic and 10 lotic water bodies throughout the lower river floodplain. Potential spawning sites for galaxiids were compared with values obtained by laser ablation inductively coupled mass spectrometry (LA‐ICPMS) depth profiling of young‐of‐the‐year otoliths sampled from fish in nine lower river catchment sites. Otolith chemical signatures from the larval rearing period indicated that catchment‐scale recruitment for two species, Galaxias argenteus (Gmelin, 1789) and Galaxias fasciatus Gray, 1842, was driven predominantly by non‐diadromous recruitment from one lake (Lake Waahi). In contrast, diadromous recruitment appeared to be more common for Galaxias maculatus (Jenyns, 1842); however, non‐diadromous specimens were also identified for the first time from a New Zealand river. Reversing lake outlet flows linked to river stage appears be important in facilitating the dispersal of rheotactic larvae out of lakes, suggesting that lake outflow management at key times could be used to sustain this ecologically important function. This study highlights that some water bodies can supply a disproportionately large number of recruits to support fish populations within the wider riverscape. Identifying these water bodies and managing them to sustain recruitment is key to the conservation of non‐diadromous Galaxiidae in this modified lowland environment
ISSN:1052-7613
1099-0755
DOI:10.1002/aqc.3022