Post Archive:
Bloater/C. hoyi
Lake Superior Bloater Reproductive Biology
Development of eDNA markers for Coregonids in the Great Lakes
Impact of egg fatty acid signatures on embryo viability in wild and domesticated cisco
One of the major challenges in the aquaculture of bloater (Coregonus hoyi) and cisco (Coregonus artedi) is the low survival rate of larvae from hatchery-reared broodstock compared to wild broodstock. Percent eye-up of bloater eggs from parents fed different diets at...
Genetic Monitoring of Bloater Broodstock using a GTSeq (Genotypes by thousands sequencing) Panel
Hatchery production is a central component of coregonine restoration within the Great Lakes ecosystem, and active supplementation programs are currently underway in Lakes Ontario and Huron. As the development of coregonine broodstock lines and methods associated with...
Integrating historical records to compare historical and contemporary coregonine habitat use in the great lakes – Year 4
A methodology for the Gap Analysis (Box 2 of the Coregonine Restoration Template, or CRF; Bunnell et al. 2023) is published as a USGS Cooperator Publication. Our team has begun implementation of the Gap Methodology based on Joint Strategic Plan committee requests...
Implementation of Coregonine Population Viability Analysis within the Coregonine Restoration Framework – Year 4
The Coregonine Restoration Framework (CRF) provides an adaptive management structure to guide restoration of this suite of species in the Great Lakes Region. Initial steps in this effort established four science teams—Resolve Taxonomy, GAP Analysis, Population...
Hatchery production and research to support restoration of sutainable Coregonine populations in Lake Ontario and Lake Erie – Year 7
Coregonine species in the Great Lakes, such as Cisco and Bloaters, historically represented a substantial component of the forage base for native cold-water fish like Lake Trout and Atlantic Salmon. Extirpation or depletion of deepwater Bloater populations has left...
Evaluation of sequential chemical marking of Oxytetracycline, Alizarin Red S, and Calcein in calcified structures of bloaters (Coregonus hoyi)
This project will investigate the unique chemical marking patterns produced within the otoliths, lower jaw, and ribs of bloaters after sequential immersions of Oxytetracycline (OTC), Alizarin Red S (ARS), and calcein. This project is fully aligned with the Coregonine...
Implementing science planning methods within the Coregonine Restoration Framework via expert knowledge elicitation and workshop facilitation – Year 2
The Coregonine Restoration Framework (Bunnell et al. 2023) includes a Planning Phase that is divided into four elements: (1) resolving coregonine taxonomy using genetics and ecology and delineating spatial units for conservation and restoration, (2) describing and...
Hatchery production and research to support restoration of sustainable Coregonine populations in Lake Ontario (FY24)
Coregonine species in the Great Lakes, such as Cisco and Bloaters, historically represented a substantial component of the forage base for native cold-water fish like Lake Trout and Atlantic Salmon. Extirpation or depletion of deepwater Bloater populations has left...
Evaluating Bloater (Coregonus hoyi) natural reproduction in Lake Ontario
Evaluation of fisheries restoration actions such as the reestablishment of coregonine populations requires a life stage approach to evaluate program success and improve understanding on potential recruitment bottlenecks. Prior to their extirpation, Lake Ontario...
Defining bloater spawning habitat to inform potential impediments to Lake Ontario bloater reintroduction
Efforts to reintroduce bloater (Coregonus hoyi) in Lake Ontario have been ongoing for 11 years (Weidel et al. 2022). Although more than 1.1 million bloater have been released, the objective of a self-sustaining population has yet to be achieved. Reintroduction efforts...
Implementing science planning methods within the Coregonine Restoration Framework via expert knowledge elicitation and workshop facilitation
The Coregonine Restoration Framework includes a Planning Phase that is divided into four elements: (1) resolving coregonine taxonomy using genetics and ecology and delineating spatial units for conservation and restoration, (2) describing and mapping historical and...
Is handling and transport stress limiting post-stocking survival of yearling bloater C. hoyi in Lake Ontario?
Bloater (C. hoyi) have been stocked in Lake Ontario for 11 years with limited success (15 total recaptures; Weidel et al., 2022). Short term (1-12 days) post-stocking survival has been estimated at 42% with 22% of the mortality occurring in the first hour post-release...
Hatchery production and research to support restoration of sustainable Coregonine populations in Lake Ontario (FY23)
This project focuses on the production of Coregonines at the USFWS-ANFH and NEFC hatcheries, working in partnership with USGSTLAS, NYSDEC, OMNRF, and USFS-LOBS to further progress towards fish community goals outlined by the GLFC Lake Ontario Committee (LOC) through...
Developing a high throughput method to genotype coregonines at a standardized panel of loci for genetic monitoring and parentage-based tagging applications
A central component of coregonine restoration in the Great Lakes is hatchery production, and active supplementation programs are underway in Lakes Ontario and Huron. Importantly, these efforts must consider the decades of work in other salmonids that demonstrate...
Implementation of Coregonine Population Viability Analysis within the Coregonine Restoration Framework – Year 3
The Coregonine Restoration Framework (CRF) provides an adaptive management structure to guide restoration of this suite of species in the Great Lakes Region. Initial steps in this effort established four science teams [Resolve Taxonomy, GAP Analysis, Population...
Hatchery production and research to support restoration of sustainable coregonine populations in Lake Ontario (FY21, FY22)
This project focuses on the production of Coregonines at the USFWS-ANFH and NEFC hatcheries, working in partnership with USGSTLAS, NYSDEC, OMNRF, and USFS-LOBS to further progress towards fish community goals outlined by the GLFC Lake Ontario Committee (LOC) through contributing to Coregonine reintroduction and restoration. Production requests originate from the LOC and the NYSDEC. Fish health monitoring is a required component of the production program to transfer fish, maintain optimal fish health in culture facilities, and facilitate the restoration of both the natural forage base and the predatory Lake Trout populations in the Great Lakes. Production of bloater (Coregonus hoyi) in FY22 is part of a multi-year restoration effort for Lake Ontario.
Can stocked Bloater (Coregonus hoyi) survival be increased with environmental conditioning?
Bloater (Coregonus hoyi) were historically an important component of the Lake Ontario fish community but the species was likely extirpated by the 1970’s. A binational restoration has stocked over one million Bloater into Lake Ontario since 2012, however, low...
Use of multi-gear sampling to improve abundance estimates of demersal Coregonines in the Great Lakes
Acoustic and mid-water trawl surveys have been used to estimate abundance and biomass of Great Lakes coregonines for decades. Acoustic sampling has potential to be an important tool in the assessment of future coregonine restoration efforts because new populations...
Region 3 wild coregonine brood stock collection activities for FY 2021 in support of restoration activities on Lake Huron and Lake Ontario
The U.S. Fish and Wildlife Services Midwest Region Fisheries Program carried out two projects in support of a multi-agency effort to restore coregonid populations in Lakes Huron and Ontario. The first project began in 2015 when USFWS began documenting the spawning...
A coordinated approach to monitoring of a coregonine brood and cultured progeny in the R3 FWS hatchery program
Broodstock management and monitoring programs are vital components of all types of stocking initiatives (e.g. Captive, Supportive, restorative, rescue). Broodstock collection and development should aim to preserve genetic diversity and minimize inbreeding and stocking...
Deep-water cisco captive broodstock developed from wild-caught juveniles: proof of concept with Lake Michigan bloater
Hatchery broodstocks (Coregonus artedi and C. hoyi) created via fertilizing eggs with sperm from wild spawning populations or captive brood stock fuel current restoration efforts for ciscoes in the Great Lakes. But, creating these broodstock involves hazards to access...
Implementation and testing of hatchery enhancements at Allegheny National Fish Hatchery to increase production and improve health and quality of juvenile bloater raised for restoration stocking in Lake Ontario
The proposed project will install 16 15-foot circular fiberglass tanks to replace 10 45-year-old concrete raceways (scalable down to 8 tank option). The project will also assess a side-by-side production level comparison of fish health, water use, fish growth,...