climate change, nuisance mosquito populations, and coastal ...•end users/cooperators: •michael...
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Update MeetingJacques Cousteau Coastal Education Center
11/27/2018
Climate Change, Nuisance
Mosquito Populations, and
Coastal Marsh Resilience
Presenter: Rick Lathrop
Project Title: INVESTIGATING THE INTERCONNECTEDNESS OF CLIMATE CHANGE, NUISANCE MOSQUITO POPULATIONS, AND LONG-TERM RESILIENCE OF COASTAL SALT MARSH SYSTEMS
• Research Team• Project Lead: Richard G. Lathrop, Jr. , PhD., Department of Ecology, Evolution, and Natural Resources, Rutgers University,
• Science Lead: Michael J. Kennish, Ph.D., JC NERR, Department of Marine and Coastal Sciences, Rutgers University,
• Collaborative Lead: Lisa Auermuller, JC NERR,
• Education Coordinator: Kaitlin Gannon, JC NERR,
• Mosquito Research Lead: Dina M. Fonseca, Ph.D., Department of Entomology, Rutgers University,
• Brian Johnson, Postdoctoral Research Associate
• Mosquito Control Specialist: Scott Crans, M.S., NJDEP
• Technical Staff: Rachael Sacatelli, CRSSA, Rutgers University
• End Users/Cooperators:
• Michael Senyk and Joe Schmidt, Ocean County Mosquito Extermination Commission
• John Abdill, Jr., Atlantic County Office of Mosquito Control
• Erin Nooney, Burlington County Mosquito Control
• Victoria Thompson and Vince Poulsen, Monmouth County Mosquito Control Division
• Peter Bosak, Cape May Mosquito Control
• Martha Maxwell-Doyle, Barnegat Bay Partnership, NJ MidAtlanticCoast Wetlands Assessment(MACWA)
• Peter Winkler, NJ Division of Fish & Wildlife, Bureau of Land Management
Conceptual Model
How will a change in the location and
timing of mosquito breeding affect the
operations and planning by the
mosquito control agencies?
Based on round table discussions with the end-users, we developed 3 main objectives:
•High resolution habitat mapping/modelling to identify mosquito production hotspots under extreme flooding events;
•How restoration techniques designed to maintain marsh elevation (i.e., thin layer application) might affect mosquito production;
•Enhanced techniques for monitoring mosquito populations.
What types of information or tools do the end users need to make better decisions and/or be more effective in their work?
Identifying Salt Marsh Mosquito Population Hotspots
Develop strategies to effectively identify specific salt marsh mosquito productive hotspots.
•Soil-elevation-vegetation surveys to document marsh habitat characteristics.
• Soil cores to document presence of mosquito eggs/larvae or egg shells.
Allocation of Survey Sites
Field Survey Design
Mosquito Sampling
Each soil core was incubated
under a light:dark photoperiod
for 3 days to allow recently laid
eggs to mature or break
“diapause”, then flooded and
larvae counted.
Objective:
Delineate
species
oviposition
and relative
abundance
Summary of soil core results
No. of
Surveys
No. Soil
Cores
No. Positive
Soil Cores
# Larvae Percent
Soil Cores
Positive
All Sites 22 1929 94574
4.87
Sites with
>2
positive
soil cores
No. of
Surveys
No. Soil
Cores
No. Positive
Soil Cores
Percent
Soil Cores
Positive
3 389 87 536 22.37
2017
Summary of soil core results
No. of
SurveysNo. Soil Cores
No. Positive Soil
Cores# Larvae
Percent Soil
Cores
Positive
All Sites 21 1385 82 820 4.82
Sites with >2
positive soil
cores
No. of
SurveysNo. Soil Cores
No. Positive Soil
Cores# Larvae
Percent Soil
Cores
Positive
5 478 73 737 10.10
2018
No. of
SurveysNo. Soil Cores
No. Positive Soil
Cores
# Larvae Percent Soil
Cores
Positive
All Sites 22 1929 94574
4.87
Sites with >2
positive soil
cores
No. of
SurveysNo. Soil Cores
No. Positive Soil
Cores
Percent Soil
Cores
Positive
3 389 87
536
22.37
2017
Mosquito Abundance vs. Vegetation Composition
Thin Layer Application of Dredge Spoils
No observed
presence of breeding
mosquitoes in 2 yr
old TLD application.
Can an environmental DNA (eDNA) approach increase
sampling efficiency?
• Soil eDNA: Delineate species oviposition and relative abundance via the collection and analysis of small quantities of soil (<10g).
• Aquatic eDNA: Determine potential for nuisance by detection of larval stages even in difficult to sample/low density situations
OBJECTIVE OF DNA ANALYSIS SUBCOMPONENTS
EGG COUNTING
FROM SOIL SAMPLES
WHY? To develop a dataset of egg abundance.
QUANTITATING DNA
WITHIN SINGLE EGG
WHY? To determine how much variability exists between individual eggs. Understanding this variability will allow for a more informed estimates of egg abundance in a sample.
Paired samples collected to independently measure egg abundance to calibrate qPCR determination of egg abundance.
EGG COUNTING FROM SOIL SAMPLES
5421 3
QUANTITATING DNA / MOSQUITO EGG
FLUOROMETRIC ANALYSIS02
Avg. DNA/egg (ng/nL)
1.62
Stand.Dev.
0.33
Average DNA/egg (ng/nL)
1.67
Stand.Dev.
0.28
Meeker’s Method ‘Typical’ Hot-Shot
*HS4 in Zieritz et al. 2018 *HS3 in Zieritz et al. 2018
Both methods appear to be equally effective.
EXTRACTION01
SUMMARY OF DNA ANALYSIS SUBCOMPONENTS
EGG COUNTING
FROM SOIL SAMPLES
Finished.
QUANTITATING DNA
WITHIN SINGLE EGG
Quantitating results look promising.
Next step: statistical comparison with egg counts.
eDNA ASSAY
GENERATION
Why? To be able to identify mosquitoes down to the species level from both soil core and standing water.
In process.
● Locating site of mosquito egg laying is relatively hard
to find:
○ 3/22 sites sampled had more then 2 positive
samples in 2018;
○ 5/21 sites sampled had more then 2 positive
samples in 2017;
○ Less then 5% hit rate on the soil cores.
● Conundrum: How is ongoing management affecting
our ability to discern robust relationships between
habitat structure and mosquito breeding activity?
What Have We Learned?
Most of the marshes along the NJ coast are regularly treated with Bti.Light trapping data suggest a wholesale depression in numbers of adults.
● In 2017, Ae. sollicitans (89.79%) dominated the collections, followed by Ae. taeniorhynchus (9.64%) and Ae. cantator (0.67%).
○ What could be significant is that Ae. taeniorhynchus is a southern species that appears to be expanding its range northward.
● Common wisdom was that good breeding habitat for both species must not be flooded by more than 4 tides per month (e.g. 2 spring tides of 2 days each), which means these sites will be above the mean high water mark. This usually equates to “high marsh” dominated by Spartina patens and Distichlis spicata.
● However, in 2017, mosquitoes were observed primarily in Sp.
alterniflora, while in 2018 (when we surveyed more broadly) mosquitoes were found across all vegetation types.
● Suggesting that mosquitoes appear to be less discriminating in their breeding habitat choices than originally thought.
What Have We Learned?
Bermed areas that blocknormal high tides
Bermed areas that fill with rain water
Recent discussions with our Mosquito Agency collaborators have focused on using their local knowledge to identify microhabitat features that may serve as mosquito breeding habitat.
Questions? Comments?