Lake Ontario, bloater (Coregonus hoyi) populations declined from the late 1800s-1900s and ultimately were extirpated from the lake by 1983 (Weidel et al. 2022). Few records exist to document critical habitats used by bloater before their extirpation (Goodyear et al....
Post Archive:
Spawning Habitat Identification & Assessment
What physical conditions reduce Bloater embryo survival and development?
Conservation and restoration of Cisco (Coregonus artedi) and Bloater (C. hoyi) is ongoing across the Great Lakes (Bunnell et al. 2023). In Lake Ontario over 1,000,000 Bloater have been released from 2012 – 2020, with modest bottom trawl recaptures (n=24) and no...
Augmenting efforts to detect coregonine tributary spawning populations using eDNA
Coregonines historically spawned in tributaries throughout the Great Lakes basin (Goodyear et al. 1982), but tributary spawning declined due to overfishing, habitat degradation, and other factors (Honsey et al. 2024). Recent surveys have found river spawning runs of...
Defining bloater spawning habitat to inform potential impediments to Lake Ontario bloater reintroduction – Year 2
Bloater (Coregonus hoyi) reintroduction remains a priority for Lake Ontario management agencies. Since 2011, over 2 million bloater (age-0 through age-5) have been released into Lake Ontario without any evidence of natural reproduction by hatchery-origin individuals...
Chemical composition of incubation substrates and their effect on survival of cisco (Coregonus artedi) embryos
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...
Do hardened shoreline habitats help or hurt? Quantifying the extent of coregonine spawning and egg incubation suitability on human-modified habitats in Lake Ontario
Conserving and restoring Cisco (Coregonus artedi) and Lake Whitefish (C. clupeaformis) populations is a management objective within individual Great Lakes and at the basin scale. Similar to other fishes of conservation concern, anthropogenic changes to spawning...
Expanding efforts to document and understand Great Lakes coregonine river spawning – Year 2
Restoration and conservation efforts hinge on the identification of key habitats, such as fish spawning habitats (Lewis et al. 1996; Kondolf 2000), and the potentially distinct populations that use them. Knowledge of these habitats can help to ensure that conservation...
Expanding efforts to document and understand Great Lakes coregonine river spawning
Our project team sampled five Great Lakes tributaries in fall 2022 and spring 2023 to assess evidence of tributary spawning by coregonines, such as cisco Coregonus artedi and lake whitefish C. clupeaformis. Specifically, we sampled the Chaumont River, Niagara River,...
Testing habitat’s influence on Cisco reproductive success using egg translocation
Great Lakes Restoration Initiative studies from the Coordinated Science and Monitoring Initiative, Native Fish Restoration, and DOI Steering Committee from fiscal years 2018 - 2022 have rapidly improved our understanding of how habitat influences coregonine spawning...
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...
Supporting evaluation components of the Lake Huron Technical Committee’s Cisco reintroduction study for FY24
Cisco (Coregonus artedi) are functionally absent from the western main basin of Lake Huron and as such restoring Cisco “to a significant level” (DesJardine 1995) remains an unmet objective for Lake Huron management agencies (Riley and Ebener 2020). In 2007 the Lake...
How have changes to coregonine spawning habitat influenced reproductive success?
Lake Ontario’s Cisco, Coregonus artedi, and Lake Whitefish, Coregonus clupeaformis populations have declined for centuries and surveys suggest populations are impeded during early life stages. This project developed methods to quantify habitat specific coregonine egg...
Implementation of a gap analysis: comparing historical and contemporary coregonine habitat use in the Great Lakes
Understanding and comparing historic and contemporary habitat use and distributions of coregonines (Gap Analysis, Box 2) has been deemed essential to inform all boxes (Planning Phase) of the Great Lakes coregonine restoration framework (CRF). We are requesting support...
Integrating historical records to compare historical and contemporary coregonine habitat use in the great lakes
Understanding and comparing historic and contemporary habitat use and distributions of coregonines (Gap Analysis, Box 2) has been deemed essential to inform all boxes of the Great Lakes coregonine restoration framework; there are dependencies between planning boxes...
Identifying and characterizing coregonine spawning habitat in Lake Erie
During the fall of 2021 and 2022, Lake Whitefish egg deposition was assessed using egg mats and egg pumping along the southern shore of the central and eastern basins in Lake Erie. Sampling was conducted at 12 different locations with 111 individual sites sampled over...
Building an adaptive tool for mapping habitat and species to support the Great Lakes coregonine conservation and restoration framework
Coregonines have declined substantially over the past century throughout the Great Lakes. A basin-wide framework, adopted by the Council of Lake Committees, has been developed to conserve and restore these ecologically and economically important native fishes. We are...
Inventory and assessment of coregonine spawning locations in lakes Erie and Ontario, including connecting channels
This project involved two phases. First, to identify locations of key habitats for coregonines in lakes Erie and Ontario and their respective connecting channels, we conducted a literature review of historical spawning, nursery, and adult habitat sites where...
Site fidelity, depth-habitat use, and reproductive behavior of ciscoes in Grand Traverse Bay, Lake Michigan
Successful reintroduction of cisco (Coregonus artedi) to the Great Lakes requires that stocked individuals are suitably adapted to environmental conditions at stocking sites. Thus, understanding how cisco ecology, life history, and behavior varies among extant...
Movements and habitat use of cisco along a nearshore-offshore gradient in northern Lake Huron
Historically, the Great Lakes supported large and diverse cisco populations until overfishing, establishment of invasive species, and habitat loss resulted in large-scale extirpation during the mid 19th century. Managers have prioritized recovery of cisco in Lake...
Historical habitat use by Coregonus artedi in the upper Great Lakes and critical embayments
The restoration of the once abundant cisco (Coregonus artedi) is a management interest across the Laurentian Great Lakes. To inform restoration, we describe historical distributions of cisco in the upper Great Lakes (i.e., Lakes Superior, Michigan, and Huron) by...
Dedicated surveys to describe the distribution and abundance of a remnant cisco population in Green Bay
Contemporary spawning of cisco and lake whitefish is not known to occur in southern Green Bay but in recent years a small number (< 10 per year) of cisco adults have been recovered along the Door Peninsula, and lake whitefish larvae have been captured in drift...