EBTJV

Joint Meeting Agenda and Discussion Summary: This documents contains the joint meeting agenda items and summary of discussions.
Located in About EBTJV / … / EBTJV Partnership Meetings / Joint Meeting of EBTJV's Conservation Strategy and Science & Data Committees - February 19, 2016
Joint Meeting of the EBTJV's Conservation Strategy and Science & Data Committees - December 5-7, 2016: This document contains the meeting agenda and a summary of the meeting discussions.
Located in About EBTJV / EBTJV Partners / EBTJV Partnership Meetings
March 2016 NFH Board Meeting: This document contains materials associated with the National Fish Habitat Board's March 7-9, 2016 in-person meeting.
Located in About EBTJV / National Fish Habitat Board Meetings / 2016 NFH Board Meetings
Notice of Cooperative Agreement Award #F15AC00861: This document describes the conditions for the EBTJV's FY15 Coordination and Operations project supported by FWS-NFHAP funds.
Located in Projects / EBTJV Operational Grants / FY15 EBTJV Coordination and Operations_FWS-NFHAP Funded Agreement
October 2016 NFH Board Meeting Book: This document contains materials associated with the National Fish Habitat Board's October 26-27, 2016 in-person meeting.
Located in About EBTJV / National Fish Habitat Board Meetings / 2016 NFH Board Meetings
Range-wide Assessment of Brook Trout at the Catchment Scale: A Summary of Findings (Revised): This report provides a revised summary the EBTJV's range-wide assessment of Brook Trout at the catchment scale.
Located in Science and Data / Data and Brook Trout Decision Support Tools / Brook Trout Catchment Assessment Summary Report and Appendix Tables
Response of fish assemblages to declining acidic deposition in Adirondack Mountain lakes, 1984-2012: Adverse effects of acidic deposition on the chemistry and fish communities were evident in Adirondack Mountain lakes during the 1980s and 1990s. Fish assemblages and water chemistry in 43 Adirondack Long-Term Monitoring (ALTM) lakes were sampled by the Adirondack Lakes Survey Corporation and the New York State Department of Environmental Conservation during three periods (1984-87, 1994-2005, and 2008-12) to document regional impacts and potential biological recovery associated with the 1990 amendments to the 1963 Clean Air Act (CAA). We assessed standardized data from 43 lakes sampled during the three periods to quantify the response of fish-community richness, total fish abundance, and brook trout (Salvelinus fontinalis) abundance to declining acidity that resulted from changes in U.S. airquality management between 1984 and 2012. During the 28-year period, mean acid neutralizing capacity (ANC) increased significantly from 3 to 30 meq/L and mean inorganic monomeric Al concentrations decreased significantly from 2.22 to 0.66 mmol/L, yet mean species richness, all species or total catch per net night (CPNN), and brook trout CPNN did not change significantly in the 43 lakes. Regression analyses indicate that fishery metrics were not directly related to the degree of chemical recovery and that brook trout CPNN may actually have declined with increasing ANC. While the richness of fish communities increased with increasing ANC as anticipated in several Adirondack lakes, observed improvements in water quality associated with the CAA have generally failed to produce detectable shifts in fish assemblages within a large number of ALTM lakes. Additional time may simply be needed for biological recovery to progress, or else more proactive efforts may be necessary to restore natural fish assemblages in Adirondack lakes in which water chemistry is steadily recovering from acidification.
Located in Science and Data / Brook Trout Related Publications
Restoring habitat connectivity in Machias and Saint Croix River tributary streams, ME_FY11 Project: Through this project, Downeast Lakes Land Trust (DLLT) continued its work with partners to restore brook trout habitat on priority streams within its 55,678-acre Downeast Lakes Community Forest by removing passage barriers. Of the four sites included in the original proposal (Billy Brown Brook/Shaw St., Amazon Brook/Amazon Rd., Grand Lake Brook/Fourth Lake Rd., and Fourth Lake Trib./Belden Brook Rd), two were completed using NRCS funding received after the initial proposal was submitted to USFWS. As a result, Eastern Brook Trout Joint Venture funding was used to restore fish passage at two additional sites at South Branch/Little River Rd and Towers Brook/Little River Rd.
Located in Projects / Project Completion Reports
Technical Guide for Field Practitioners: Understanding and Monitoring Aquatic Organism Passage at Road-Stream Crossings: Stream connectivity has become increasingly important for river restoration and fish-habitat improvement projects (Fullerton et al. 2010) amidst increasing evidence that it plays a vital role in supporting aquatic organism populations (Roni et al. 2002; Gibson et al. 2005) and species diversity (Nislow et al. 2011). Recent emphasis on identifying and removing barriers in order to restore aquatic organism passage (AOP) is based on well-documented negative effects of road-stream crossings on fish (Rieman et al. 1997; Hudy et al. 2005) and the potential for cost-effective restoration of aquatic habitat. However, challenges remain in identifying barriers and prioritizing road-stream crossings for remediation. The U.S. Department of Agriculture Forest Service (USFS) has been working to stream-line the process of identifying and remediating road-stream crossings that are inadequate for AOP.
Located in Science and Data / Brook Trout Related Publications
Understanding environmental DNA detection probabilities: A case study using a stream-dwelling char Salvelinus fontinalis: Environmental DNA sampling (eDNA) has emerged as a powerful tool for detecting aquatic animals. Previous research suggests that eDNA methods are substantially more sensitive than traditional sampling. However, the factors influencing eDNA detection and the resulting sampling costs are still not well understood. Here we use multiple experiments to derive independent estimates of eDNA production rates and downstream persistence from brook trout (Salvelinus fontinalis) in streams. We use these estimates to parameterize models comparing the false negative detection rates of eDNA sampling and traditional backpack electrofishing. We find that using the protocols in this study eDNA had reasonable detection probabilities at extremely low animal densities (e.g., probability of detection 0.18 at densities of one fish per stream kilometer) and very high detection probabilities at population-level densities (e.g., probability of detection N0.99 at densities of ≥3 fish per 100 m). This is substantially more sensitive than traditional electrofishing for determining the presence of brook trout and may translate into important cost savings when animals are rare. Our findings are consistent with a growing body of literature showing that eDNA sampling is a powerful tool for the detection of aquatic species, particularly those that are rare and difficult to sample using traditional methods.
Located in Science and Data / Brook Trout Related Publications

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