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Home , Beraeidae, Glossosomatidae, Lepidostomatidae, Limnephilidae

SUNY College of Environmental Science and Forestry Digital Commons @ ESF

Cranberry Lake Biological Station Environmental and Forest Biology

6-19-2015

Session A, 2015 First Place: Whatever the Case May Be: Investigating Trichoptera Diversity in Three Adirondack Streams

Emily Artruc

Grace Gustke

Samantha Hollister

Johanna Little

Miranda Tanner

Follow this and additional works at: https://digitalcommons.esf.edu/clbs

Part of the Aquaculture and Fisheries Commons, Biodiversity Commons, Biology Commons, Ecology and Evolutionary Biology Commons, Entomology Commons, and the Forest Sciences Commons

Recommended Citation Artruc, Emily; Gustke, Grace; Hollister, Samantha; Little, Johanna; and Tanner, Miranda, "Session A, 2015 First Place: Whatever the Case May Be: Investigating Trichoptera Diversity in Three Adirondack Streams" (2015). Cranberry Lake Biological Station. 5. https://digitalcommons.esf.edu/clbs/5

This Presentation is brought to you for free and open access by the Environmental and Forest Biology at Digital Commons @ ESF. It has been accepted for inclusion in Cranberry Lake Biological Station by an authorized administrator of Digital Commons @ ESF. For more information, please contact [email protected], [email protected]. WHATEVER THE CASE MAY BE: Emily Artruc Miranda Tanner INVESTIGATING TRICHOPTERA Johanna Little Grace Gustke DIVERSITY IN THREE Samantha Hollister ADIRONDACK STREAMS

Holzenthal et al., 2010

INTRODUCTION

are members of the order Trichoptera. There are 45 families and about 12,000 species.

 They are the most diverse order that are exclusively aquatic. larvae belong to many functional feeding groups, from collectors to predators, though they are primarily detritivores.

 Larvae construct cases out of sand or organic matter, though some are free-living. Case construction is often family or -specific.

 They also produce silk from modified salivary glands, which places them in the superorder Amphiesmenoptera with Lepidopterans ( Tree of Life Project: Trichoptera, Caddisflies). INTRODUCTION

 They inhabit streams and rivers, which are the most severely impacted and threatened systems in the world due to mining, agriculture, acid rain, and sedimentation (Holzenthal et al., 2007).

 Anthropogenic development also threatens biodiversity and the value of caddisflies as an indicator species and as a functional component of stream systems (de Moor and Ivanov, 2008).

 They are apneusitc and rely on dissolved oxygen in the water for respiration, making them useful indicators of pollution (de Moor and Ivanov, 2008).

INTRODUCTION

 Caddisfly larvae are indicators of stream health . Important factors of the aquatic food web . Stream presence is critical to overall integrity and structure of the system

 High caddisfly diversity also reflects stream resilience to environmental disturbance. ( Collier and Smith, 1998).

 Can the diversity of caddisfly adults be used as an indicator of stream health? Emily Artruc (2015) HYPOTHESIS

 Ha: There is no significant difference between caddisfly larvae diversity and caddisfly adult diversity at all three sampled stream locations at the Cranberry Lake Biological Station, NY.

 Ho: There is a significant difference in caddisfly larvae diversity and caddisfly adult diversity at all three sampled stream locations at the Cranberry Lake Biological Station, NY.

Emily Artruc (2015) METHODS

 We collected caddisfly larvae along 10 sites 20 meters apart on three streams: Sucker Brook, North Shore Creek, and Beaver Pond Flow.

 We used two sampling methods: d-netting and forceps.

 We used the YSI multi-probe to record the temperature, pH, and dissolved oxygen at each site.

 Specimens were placed in glass

jars for laboratory analysis. Emily Artruc (2015)

MAP OF SAMPLING SITES

Sampling Unit Stream 2: North Shore Creek n= 33; 1/site

Experimental Unit n= 6; 3/factor

Stream 3: Beaver Pond Flow Factors: Aquatic and Terrestrial n= 2

Stream 1: Sucker Brook

SUNY ESF METHODS

 Adults were captured using a hanging sheet illuminated by a black light from 8:30-11:30 PM at one location at each stream. After 3 hours of exposure, adults were collected using forceps and placed in a kill jar for later identification and analysis.

Emily Artruc (2015) METHODS

 In the lab, specimens were identified using a dissecting scope and the Freshwater Macroinvertebrates of Northeastern North America and Kaufman Field Guide to of North America.

Emily Artruc (2015)  Data were analyzed using . ANOVA/Tukey’s Test . Sorenson’s Coefficient . Shannon-Wiener Index . Paired t-test RESULTS

 Stream 1 - 8 families: . Larvae - , . Adult - , Limnephilidae,  Stream 2 - 4 families: . Larvae - Linmephilidae, Glossosomatidae . Adult - Linmephilidae, Glossosomatidae, Lepidostomatidae  Stream 3 - 7 families: . Larvae - Linmephilidae, Glossosomatidae, Lepidostomatidae . Adults - Linmephilidae, Lepidostomatidae

© 2011 Robert G Henricks © 2009 tom murray

http://www.ispotnature.org/node/301750 Beraeidae Lepidostomatidae Limnephilidae Glossosomatidae

RESULTS

 ANOVA and Tukey’s Test . The caddisfly larvae family diversity between the three streams is not significant RESULTS

 Sorensen’s Coefficient of Similarity  Regression analysis . There is a relationship between temperature and dissolved oxygen, and temperature and Sorensen’s Coefficient RESULTS

 We determined with the Shannon-Wiener Index that the evenness of the larvae was greater than the evenness of adults at every stream. . There may be periods of adult emergence during which different families or genera emerge at different times during the year. RESULTS

 However, the paired t-test showed there is no significant difference in caddisfly adult diversity and caddisfly larvae diversity . Therefore we can assume that adults could be used to assess stream quality

Paired T-Tests

95% Confidence T-Value P-Value Interval

Stream 1 (-0.1615, 0.1612) 0.000 0.999

Stream 2 (-0.2125, 0.2125) 0.000 1.000

Stream 3 (-0.0827, 0.847) 0.000 1.000 DISCUSSION

 Based on the analysis of the data, we reject the null hypothesis that the diversity of caddisfly larvae is different than the diversity of the adults.

Emily Artruc (2015) DISCUSSION

 Most abundance of Adult Trichopterans found within 30 m of stream (Collier and Smith, 1998).

 In a study performed by Stanić-Koštroman et al. 2012, UV light traps were set 1 meter from a stream for 2 hours. After a year of experimentation, they determined that the adults stay close to the water and can be used to assess water quality. . Diversity of adults differed from the headwaters to mid- waters as well . The flight peaks were observed during warm spring and summer months, June had the highest species count and May had the highest individual count. DISCUSSION

 Due to many constraints, we feel we have insufficient data that does not reflect the true caddisfly diversity of the streams.

 Therefore, if we were to repeat the study, we would make the following changes: . More adult and larvae sampling to determine diversity . Time, weather, and equipment . Sample different streams off campus

CONCLUSION

 We found no significant difference in caddisfly larvae diversity between each stream.

 Similarity between adult and larval families varied due to temperature and dissolved oxygen concentration.

 Ultimately, we reject our null hypothesis, and conclude that caddisfly adult diversity can be indicative of larval diversity, and therefore of stream health. ACKNOWLEDGEMENTS AND REFERENCES

A big thank you to: Dr. Fiene and the CLBS staff Ben Amos Dr. Fierke Jake Erle Chris Foelker Clifford Peterson

 References

 C ollier, K.J. & Smith, Brian J. (1998). Dispersal of adult caddisflies (Trichoptera) into forests alongside three New Zealand streams. Hydrobiologia. 361: 53-65.

 Holzenthal, R., Blahnik, R., Prather, A., Kjer, K. (2007). Order Trichoptera Kirby, 1813 (Insecta), Caddisflies. Zootaxa 1668: 639–698.

 Holzenthal, R. W., Blahnik, R.J., Prather, A., and Kjer, K. (2010, July 20). Trichoptera. Retrieved from http://tolweb.org/Trichoptera.

 Holzenthal, R., Blahnik, R., Prather, A., Kjer, K. Tree of Life Project: Trichoptera, Caddisflies. Retrieved June 17, 2015, from http://tolweb.org/Trichoptera

 Ivanov, V.S., & DeMoor, F.C. (2008). Global Diversity of Caddisflies (Trichoptera: Insecta) in freshwater. Hydrobiologia, 595: 393-407.

 Stanić-Koštroman, S., Kučinić, M., Kolobara, A., Škobić, D., Knezović, L., & Durbešić, P. (2012). Light-Trapped Caddisflies (Insecta: Trichoptera) as Indicators of the Ecological Integrity of the Lištica River, Bosnia and Herzegovina. Entamologia Croatia, 16(1-4): 21-36. QUESTION?

http://unews.utah.edu/wp-content/uploads/caddisfly_larva_face_on.jpg