Influence of Cladophora sp. on the Composition and Spatial Distribution of Macroinvertebrate Communities in Streams. A THESIS SUBMITTED TO THE SCHOOL OF GRADUATE STUDIES of BLOOMSBURG UNIVERSITY OF PENNSYLVANIA IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF MASTER OF SCIENCE PROGRAM IN BIOLOGY DEPARTMENT OF BIOLOGICAL AND ALLIED HEALTH SCIENCES BY BENJAMIN R. PAUL BLOOMSBURG, PENNSYLVANIA 2020 ii ABSTRACT: Nitrogen and phosphorus from agricultural runoff cause blooms of the green alga, Cladophora. This alga provides surface area for epiphytes and invertebrates to colonize. However, Cladophora is not nutritious and hard to digest for many invertebrates, which could impact invertebrate communities around this alga. The purpose of this research was to determine how invertebrate communities differ between patches in streams where Cladophora is present and absent in the Susquehanna River watershed. To do this, 13 streams were sampled. Invertebrates were collected using a Surber sampler by collecting five composites and combining them into one sample per patch type. In streams where Cladophora was present, patches consisted of areas that either contained or did not contain Cladophora. In streams where Cladophora was not present, a single sample was collected. The samples were preserved in ethanol and macroinvertebrates were identified to the family level. The communities were compared between patch types from Cladophora streams using four metrics: percent Ephemeroptera, Plecoptera, and Trichoptera (%EPT), Hilsenhoff Biotic Index (HBI), Shannon-diversity index and percent Chironomidae (%Chironomidae). Densities were compared between patch types from Cladophora streams and non-Cladophora streams. Data loggers were left at sites to collect dissolved oxygen and temperature data every 15 minutes for a week. Percent Chironomidae was greater in Cladophora patches than nonCladophora patches (p<0.005) which decreased Shannon diversity in Cladophora patches (p<0.05). Densities of invertebrates per m2 were higher in Cladophora patches than non-Cladophora stream patches (p<0.05). Stream type and percent agriculture within the stream watershed both directly impacted invertebrate communities (p<0.05). iii Logistic regression supported the prediction of Cladophora presence or absence in streams using alkalinity as a predictor (p=0.0516). This research supports that agriculture and the alga, Cladophora affect invertebrate communities at both patch and stream-level spatial scales in the Susquehanna River watershed by increasing invertebrate densities and decreasing diversity. v ACKNOWLEDGEMENTS: Thank you to Dr. Steven Rier, for showing me how to use and providing access to research equipment, sharing his knowledge of stream ecology and statistical analyses, and being a great mentor, without his help and guidance this research project would not have been possible. Thank you to my thesis committee members, Dr. Lauri Green and Dr. Thomas Klinger for their input in this project. Thank you to all the individuals who helped sort macroinvertebrates, including Bobby Paul, Jacob Paul, Randall Paul, Sandra Paul, Mackenzie Pierce, and Victoria Roper. Thank you to Dr. Stefanie Kroll, Dr. Matthew McTammany and Dr. Robert (Bob) Smith for their advice during this research study. Thank you to the Pennsylvania Fish and Boat Commission for allowing me to collect macroinvertebrates for this project. Thank you to Bloomsburg University for providing funding for this research project through a 2019/2020 Thesis Research Grant. vi TABLE OF CONTENTS: INTRODUCTION: ............................................................................................................ 1 Hypotheses: .................................................................................................................... 6 MATERIALS AND METHODS:....................................................................................... 6 Stream selection: ............................................................................................................ 6 Macroinvertebrate Processing and Identification: ......................................................... 8 Macroinvertebrate Metrics: ............................................................................................ 9 Percent EPT Taxa: ............................................................................................................. 9 Shannon Diversity Index: ................................................................................................ 10 Hilsenhoff Biotic Index (HBI): ........................................................................................ 10 Percent Chironomidae:..................................................................................................... 11 Water Chemistry: ......................................................................................................... 11 Percent Agriculture Land Cover: ................................................................................. 12 Statistical analyses: ...................................................................................................... 13 RESULTS: ........................................................................................................................ 15 DISCUSSION: .................................................................................................................. 27 LITERATURE CITED: .................................................................................................... 27 APPENDICES: ................................................................................................................ 43 vii LIST OF TABLES: Table 1. Raw data collected from each site including the stream site, patch type, proportion of the total macroinvertebrate sample that was identified, date the samples were collected, TP (ug/L), TN (ug/L), total alkalinity (mg CaCO3/L), coordinates for each site, %Ag in each stream watershed, average diel change in dissolved oxygen (Average DDO) (mg/L), average diel change in water temperature in °C (Average DTemperature), and identified macroinvertebrate data for each stream. ................................................................................... 44 viii LIST OF FIGURES: Figure 1. Map of all sites categorized as Cladophora (yellow) and non-Cladophora (red) streams within the Susquehanna River watershed. Layers data were obtained from Pennsylvania Spatial Data Access (PASDA). ....................... 7 Figure 2. Total alkalinity in mg CaCO3/L from Cladophora streams and nonCladophora streams in central Pennsylvania. Cladophora streams contained patches of Cladophora that covered at least 50% of the area within a Surber sampler. Non-Cladophora streams had very little or no Cladophora present. ...................................................................................................................... 16 Figure 3. Macroinvertebrate densities in non-Cladophora streams and in nonCladophora and Cladophora patches within Cladophora dominated streams in central Pennsylvania. .............................................................................. 18 Figure 4. The %Chironomidae in Cladophora patches and non-Cladophora patches in Cladophora dominated streams in central Pennsylvania. ........................... 19 Figure 5. Shannon-Weaver diversity (H) scores for Cladophora patches and nonCladophora patches in Cladophora dominated streams in central Pennsylvania. .............................................................................................. 20 Figure 6. The %EPT taxa from non-Cladophora patches and Cladophora patches within Cladophora dominated streams in central Pennsylvania................. 21 Figure 7. Hilsenhoff Biotic Index (HBI) scores of Cladophora patches and nonCladophora patches within Cladophora dominated streams in central Pennsylvania ............................................................................................... 23 Figure 8. Nonmetric multidimensional scaling (NMDS) ordination comparing Cladophora patch communities (circles) to non-Cladophora patch communities (triangles) in six Cladophora dominated streams in central Pennsylvania (stress=0.10571). .................................................................. 24 Figure 9. Nonmetric multidimensional scaling (NMDS) ordination comparing Cladophora stream communities (circles) to non-Cladophora stream communities (triangles) from 12 streams in central Pennsylvania. Briar Creek was omitted from this NMDS due to low numbers of macroinvertebrates heavily weighting NMDS analysis (stress=0.14163). ................................ 26 Figure 10. Image serving as an example of a Cladophora patch sample taken within Penns Creek before a Surber sample from a patch containing Cladophora was collected. ..................................................................................................... 34 Figure B1. Briar Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 60 Figure B2. Chillisquaque Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 61 ix LIST OF FIGURES CONTINUED: Figure B3. Fishing Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 62 Figure B4. Green Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 63 Figure B5. Hemlock Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 64 Figure B6. Huntington Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 65 Figure B7. Little Fishing Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 66 Figure B8. Mahoning Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 67 Figure B9. Mauses Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 68 Figure B10. North Mahantango Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 69 x LIST OF FIGURES CONTINUED: Figure B11. Penns Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 70 Figure B12. Turtle Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 71 Figure B13. Warrior Run data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. ......................................................................... 72 xi LIST OF APPENDICES: Appendix A. Raw data including the name of each stream site, the patch type, proportion of the total sample that was identified, date the macroinvertebrate samples were collected, total phosphorus (TP) in (ug/L), total nitrogen (TN) in (ug/L), total alkalinity in (mg CaCO3/L), Latitude and Longitude coordinates for each site, percent agriculture (%Ag) in each stream watershed, average diel change in dissolved oxygen (Average DDO) (mg/L), average diel change in water temperature in °C (Average DTemperature), and the identified macroinvertebrate data for each stream. ...................................................... 43 Appendix B. Dissolved oxygen and water temperature data for each site including the following variables: dissolved oxygen (a), water temperature (b), diel change in dissolved oxygen, labeled DDO (c), diel change in water temperature, labeled DTemperature (d). The figures for each stream are presented in the following order: Briar Creek (Fig. B1), Chillisquaque Creek (Fig. B2), Fishing Creek (Fig. B3), Green Creek (Fig. B4), Hemlock Creek (Fig. B5), Huntington Creek (Fig. B6), Little Fishing Creek (Fig. B7), Mahoning Creek (Fig. B8), Mauses Creek (Fig. B9), North Mahantango Creek (Fig. B10), Penns Creek (Fig. B11), Turtle Creek (Fig. B12), and Warrior Run (Fig. B13). All figures were created by the author using R statistical software (R Core Team, 2019). ............................................................................................... 59 1 INTRODUCTION: Nutrients such as nitrogen and phosphorus often enter waterways from anthropogenic sources like agriculture fields, lawns, septic systems and construction sites (Cole and Weihe, 2016). Nitrogen concentrations in waterways are often positively associated with the amount of agricultural land within watersheds (Castillo et al., 2000; Carpenter et al., 1998). However, phosphorus concentrations are more strongly associated with suspended particles, like sediment (Jordan et al., 1997). This is likely due to phosphorus binding to these sediment particles which can be transported into waterways during rainfall events (McDowell et al., 2001). The addition and overapplication of phosphorus in the form of fertilizers and manures increases the content of phosphorus in soil and creates a surplus of phosphorus in many agricultural areas (Sharpley et al., 1994). The greater the concentration of phosphorus in the soil, the more phosphorus enters waterways through surface water runoff (Carpenter et al., 1998). Stream periphyton communities are reactive to environmental variables including water chemistry, light availability and nutrients found within the watershed of the stream (Feminella and Hawkins, 1995). Stream periphyton communities are a mixture of autotrophic algae, heterotrophic microbes and detritus embedded in a matrix of exopolymeric substances (Cole and Weihe, 2016) covering boulders, cobble, gravel, sand, silt, and organic detritus (Lamberti and Steinman, 1997; Fairchild and Holomuzki, 2002). Periphytic algae in streams often includes diatoms, cyanobacteria, and filamentous green algae (Stevenson et al., 2006; Wellnitz and LeRoy Poff, 2012). Cultural eutrophication is the process of increasing primary productivity, like the abundance of periphytic algae, in waterways due to anthropogenic inputs of nitrogen and phosphorus 2 (Cole and Weihe, 2016). Whereas nitrogen is often associated with primary productivity, phosphorus is the limiting nutrient that regulates the biomass of periphytic algae in most streams (Francoeur, 2001). Therefore, when phosphorus is added to a lotic system, this can cause a shift in the periphytic algal community to contain predominantly filamentous, green algae which can grow to levels that can overtake streambeds and harm stream health (Stevenson et al., 2012). The genus of filamentous, green alga, Cladophora, is one of the most widespread taxon of algae on the planet (Higgins et al., 2008) and is a prominent member of periphytic algal communities (Blum, 1956). The ability to out-compete other algae and reproduce in massive quantities in nutrient-rich waters are what allow this alga to be so widely distributed (Whitton, 1970). Cladophora sp., hereafter referred to as Cladophora, can withstand the high shear stresses that are common in streams, allowing for the colonization of lentic and lotic systems (Dodds and Gudder 1992). This alga is also capable of using inorganic carbon sources from the water to undergo photosynthesis and therefore does not rely solely on carbon dioxide from cellular respiration to photosynthesize, allowing for large growths of Cladophora to continue to grow without creating competition for resources between individual filaments (Choo et al., 2002). Cladophora large biomasses through a variety of reproductive strategies can overtake nutrient-rich waterways (Dodds and Gudder, 1992; Van den Hoek, 1963; Zulkifly et al., 2013). In some Cladophora species there is no record of sexual reproduction (Dodds and Gudder, 1992). Cladophora can reproduce sexually, but the most common form of reproduction is through the asexual reproduction of biflagellated spores, called zoospores (Van den Hoek, 1963). The alga can also asexually reproduce 3 through a resting-dormant cell called an akinete (Zulkifly et al., 2013). These methods of reproduction can cause differences in algal blooms within a year. Cladophora typically blooms twice annually (Whitton, 1970). In Northern temperate streams and rivers, this filamentous alga blooms in mid-summer and then dies off in the late-summer months. The alga then re-blooms in early fall (Higgins et al., 2008; Whitton, 1970). There is some debate as to which nutrient limits the growth of Cladophora. Some studies provide evidence for nitrogen limitation (Penick et al., 2012; Lohman and Priscu, 1992), whereas others provide evidence for phosphorus limitation (Zulkifly et al., 2013; Dodds and Gudder, 1992). In many streams, the limiting nutrient is likely phosphorus, but it depends on the individual stream and which nutrient is in shorter supply (Francoeur, 2001). Cladophora are rarely found in waters below a pH of 7 and are most commonly found in waters between a pH of 7 and 10 (Whitton, 1970). Research suggested that Cladophora can withstand a pH of 10.4 and still photosynthesize (Wood, 1975). This alga is likely to proliferate in waterways with higher alkalinity including areas with limestone bedrock, rich in CaCO3 (Fairchild and Holomuzki, 2002). During a field experiment in Lake Erie, McMillan and Verduin (1953) documented Cladophora glomerata in waters with a total alkalinity of 90 mg CaCO3/L. In a laboratory experiment in an artificial stream, water alkalinity was controlled at 134 mg CaCO3/ L to study optimum growth rates of C. glomerata (Robinson and Hawkes, 1986). In Lake Michigan, Cladophora was collected in areas with total alkalinity between 152 and 179 mg/CaCO3/L (Cheney and Hough, 1983). 4 Cladophora can grow to levels that can alter stream communities and harm overall stream health (Stevenson et al., 2012) and has been associated with reductions in the diversity of macroinvertebrate communities (Ellsworth, 2000). A fish kill in the Illinois River was attributed to large growths of filamentous green algae, including Cladophora, which caused hypoxic dissolved oxygen concentrations (0.9mg/L) (Stevenson et al., 2012). Hypoxia is the depletion of oxygen content in the water to about 3 mg/L (Berezina et al., 2007). Decaying Cladophora has also been shown to decrease dissolved oxygen to hypoxic levels in littoral areas of the Baltic Sea (Berezina et al., 2007, Berezina, 2008). In the absence of light, cellular respiration by both heterotrophic and autotrophic organisms removes oxygen from the water. Some macroinvertebrates can tolerate changes in oxygen better than others and thrive in low oxygen conditions, e.g. Chironomidae can absorb oxygen directly through their cuticle (Baranov et al., 2016) and pump water through their cases for irrigation in low flow conditions (Walshe, 1951). Cladophora can be consumed by several species of macroinvertebrates, including the caddisfly Gumaga nigricula, Helicopsyche borealis (Feminella and Resh, 1991), Dicosmoecus gilvipes (Holomuzki et al., 2013), and the mayfly Ephemerella subvaria (Bird and Kaushik, 1984). However, this alga can be hard to digest for macroinvertebrates (Dodds and Gudder, 1992). The cell walls of Cladophora are thicker and the cellulose is more crystalline in structure than that of terrestrial plants (Zulkifly et al., 2013). There are few amino acids in Cladophora, which gives it a poor nutritional value (Dodds and Gudder, 1992). Cladophora grow in filamentous tufts (Blum, 1956), which create a microhabitat including epiphytes, like diatoms, and the organisms that feed on these epiphytes 5 (Higgins et al., 2008; Ólafsson et al., 2013; Power, 1991). Many macroinvertebrates are likely ingesting Cladophora for the epiphytes that colonize the surface of this macroalga, essentially acquiring nutrition from the diatoms and particulate matter collected on the thalli of Cladophora rather than from the Cladophora itself (Dodds and Gudder, 1992). Therefore, even with a poor nutritional value, this alga has been associated with increased densities of macroinvertebrates from the genera Baetis and Simulium and the family Chironomidae (Ellsworth, 2000). Dudley et al. (1986) found that the genera Baetis, Hydroptila, Ochrotrichia, and Euparyphus, along with the Chironomidae family, were positively associated with Cladophora growths in a second order stream in Southern California. Cladophora has also been positively associated with Hydropsyche, Rhyacophilla, and Microsema due to the increased surface area this alga provides for colonization (Dudley et al., 1986). Cladophora has been recorded by Power (1991) to be used by Chironomidae to make cases or refuges. Therefore, Cladophora is not only a source of food, but also a source of shelter and building materials for some macroinvertebrates (Dudley et al., 1986; Power, 1991). Despite all the research that has been conducted on Cladophora and macroinvertebrates, no studies have examined the differences in community composition of macroinvertebrates in relation to Cladophora distribution at varying spatial scales, both within streams at the patch level and between streams at the stream level. It is important to gain a better understanding of the interactions between this alga and its associated macroinvertebrate communities over varying spatial scales, both small and large. The objectives of this study are to firstly, see if Cladophora is influencing macroinvertebrate community composition in middle order streams at both a patch-level 6 spatial scale within the same streams, and a between-stream spatial scale; secondly, to determine the direct and indirect effects of Cladophora on macroinvertebrates as bioindicators of water quality and to determine what these numbers actually mean for ecosystem managers; thirdly, to examine the possible mechanisms that could explain the response of macroinvertebrates to Cladophora; and fourthly, what factors influence the distribution of Cladophora in streams within central Pennsylvania. Hypotheses: 1. Cladophora biomass will alter macroinvertebrate community membership at varying spatial scales both on a scale of patch distribution, within streams, and between streams. 2. Areas with Cladophora present will have different macroinvertebrate densities, percent Chironomidae (%Chironomidae), Shannon-diversity Index values, Hilsenhoff Biotic Index (HBI) values, and percent Ephemeroptera, Plecoptera, and Trichoptera taxa (%EPT taxa), when compared to areas without Cladophora. MATERIALS AND METHODS: Stream selection: I collected data from thirteen middle order (4-6) streams in the Susquehanna River watershed, including: Briar Creek, Chillisquaque Creek, Fishing Creek, Green Creek, Hemlock Creek, Huntington Creek, Little Fishing Creek, Mahoning Creek, Mauses Creek, North Mahantango Creek, Penns Creek, Turtle Creek, and Warrior Run (Fig. 1). Streams were selected according to their stream order (4-6), proximity to Bloomsburg University, and the previous knowledge of Cladophora presence or absence in the streams from previous field experiments. Streams that contained patches of Cladophora 7 large enough for five Surber samples with at least 50% Cladophora cover within each Surber sample were classified as Cladophora streams. If a stream did not contain patches of Cladophora large enough for five Surber samples with at least 50% Cladophora cover for each Surber sample, they were classified as non-Cladophora streams. Streams in this study had a pH of 7 or greater because Cladophora tends to be found in streams with higher pH (Whitton, 1970). A map of the collection sites was created using QGIS (Version 3.12) (QGIS Development Team, 2020) (see Fig. 1). Stream type Non-Cladophora Cladophora Figure 1. Map of all sites categorized as Cladophora (yellow) and non-Cladophora (red) streams within the Susquehanna River watershed. Layers data were obtained from Pennsylvania Spatial Data Access (PASDA). Macroinvertebrates were collected when weather conditions allowed for safe access to streams and when Cladophora was present. Therefore, the sampling dates fell between 8 mid-July and mid-August 2019. The summer months may exhibit decreased diversity values due to emergence of adult macroinvertebrates (Chalfont, 2015; PADEP, 2012). In streams where Cladophora was present (Cladophora streams), two macroinvertebrate collections were taken, one from Cladophora patches and another from non-Cladophora patches. For each patch type collection, five composites, or grabs, from the Surber sampler (0.096 m2), were collected and compiled into one composite sample for a given patch type. Therefore, the total surface area of streambed disturbed per patch type was 0.48 m2. This was be done by placing the Surber sampler in areas within riffles where at least 50% of the area within the Surber sampler was covered with Cladophora and disturbing the substrate for 30 seconds, making sure to fully disturb the total area within the Surber sampler. The same was done where Cladophora was totally absent, in the nonCladophora patches. The macroinvertebrates were temporarily stored in Ziplocâ bags along with a 95% ethanol solution and then transported to the laboratory to be identified under a dissecting microscope (Shull and Lookenbill, 2017; Johnson et al., 2013). The macroinvertebrates were permanently stored in 95% ethanol in scintillation vials in a repository at Bloomsburg University. Macroinvertebrate Processing and Identification: Macroinvertebrates were identified to the family level according to the protocol set forth by the Pennsylvania Department of Environmental Protection (PADEP, 2012). Macroinvertebrates were identified according to Merritt et al. (2008). Macroinvertebrates were identified to the family-level because a majority of individuals were early instar or immature and did not exhibit the necessary characteristics to confidently identify them to the genus-level. 9 A sub-sampling protocol was implemented to decrease the time for processing and identifying the collected macroinvertebrates. I developed this protocol by modifying the existing Pennsylvania Department of Environmental Protection Division of Water Quality’s protocol for wadeable freestone riffle-run streams of Pennsylvania (PADEP, 2012) by taking 350 ± 70 individuals from each sample. I recorded the proportion of macroinvertebrates taken from the whole sample as a fraction, which was modified from the procedures used by Frost (2006). Macroinvertebrate Metrics: After macroinvertebrates were identified to the family level, I calculated the density of macroinvertebrates per m2 (hereafter referred to as density). I also applied the taxonomic information to the following metrics: Percent EPT Taxa: Richness of Ephemeroptera, Plecoptera, and Trichoptera taxa, hereafter referred to as EPT taxa, was calculated by adding the total number of these taxa in a sample, modified from the method used by Chalfont (2015). Percent Ephemeroptera, Plecoptera, and Trichoptera taxa, hereafter referred to as %EPT taxa, was calculated from the EPT taxa richness scores (Equation 1). To calculate the %EPT taxa the total EPT richness is divided by the total number of individuals identified in the sample and multiplied by 100, to form a percent (Equation 2). The Ephemeroptera, Plecoptera, and Trichoptera are generally sensitive taxa that are not associated with polluted waterways (Barbour et al., 1992) and knowing the number of these taxa within a sample can provide insight into the level of pollution in a waterway. This is a common macroinvertebrate metric used by many agencies (Chalfont, 2015; PADEP, 2012). 10 Equation 1: !"# #%&% '()ℎ+,-- = / !0ℎ,1,2304,2% + "6,)304,2% + #2()ℎ304,2% Equation 2: %!"# #%&% = !"# #%&% '()ℎ+,-× 100 8 N= Total number of identified organisms in the sample. Shannon Diversity Index: Shannon diversity (1948) scores are a metric that takes into account the family-level richness and evenness within the sample (Chalfont, 2015). Shannon diversity scores were calculated for each sample from the community data, excluding the unknown individuals (Equation 3). I excluded pupa, and damaged individuals that could not be identified from this calculation. Shannon diversity scores were calculated using the Vegan Package (R Core Team, 2019; Oksanen, 2019). Equation 3: $ ! <ℎ%++3+ =(>,2-(4? @+A,& (C ) = − / 0" ln 0" "%& S= the taxa richness, or total number of taxa identified pi= proportion of taxon i Hilsenhoff Biotic Index (HBI): Hilsenhoff Biotic index (1988), hereafter referred to as HBI, was calculated for each sample according to pollution tolerance values for each family of macroinvertebrate according to the table provided by the Pennsylvania Department of Environmental Protection (2012) (Equation 4). The families without pollution tolerance values were 11 excluded from the calculation. The HBI is an index that depicts higher values for areas that are influenced by anthropogenic sources (Chalfont, 2015). The pollution tolerance values for each family were originally written to identify organic pollution of raw sewage and can provide insight into how hypoxic a waterway is due to this organic pollution (Hilsenhoff, 1988). Equation 4: &- C(6-,+ℎ3HH I(34() @+A,& = /[(( × +"'() *+, " )]/8 "%- n indv PTV i = number of individuals identified in a sample with PTV i N= total number of individuals identified in the sample Percent Chironomidae: The percent Chironomidae, hereafter referred to as %Chironomidae, is a metric that was calculated by taking the number of Chironomidae present in each sample and dividing by the total number of individuals identified in each sample and multiplying by 100 to get the percentage of individuals which belonged to the Chironomidae in each sample. The number of Chironomidae in samples can be useful to understand why diversity levels can be lower in some samples due to increased abundances of this taxon. The numbers of this tolerant taxon in a sample can provide researchers with information of the water quality and can help identify polluted areas (Pinder, 1986). Water Chemistry: Along with collecting macroinvertebrates, water chemistry measurements were also taken at each site. Data loggers (MiniDOT, PME) were deployed to measure diel fluctuations in dissolved oxygen and temperature. These data loggers were deployed for 12 at least one week before or after macroinvertebrate samples were collected. Data loggers measured dissolved oxygen and water temperature every 15 minutes. The diel change in dissolved oxygen, was calculated by subtracting the minimum value of dissolved oxygen from the maximum value of dissolved oxygen for each day data were collected. The same calculation was used for the diel change in water temperature. The diel change in dissolved oxygen and diel change in water temperature were calculated for all full 24hour days within the dataset of each stream. The average diel change in dissolved oxygen and average diel change in water temperature were calculated for each stream. A Eureka Manta Sonde was used to record turbidity, dissolved oxygen, pH, temperature, and conductivity at the time of macroinvertebrate collection. Total alkalinity was measured in the field using a Hach digital titrator. Total alkalinity is a measure of the buffer capacity of the water and is a measure of inorganic carbon sources (Cole and Weihe, 2016). Total phosphorus, hereafter referred to as TP, and total nitrogen, hereafter referred to as TN, were analyzed in the laboratory from whole water samples using an alkaline persulfate oxidation followed by colorimetric determination on a Seal AQ1 Discrete Analyzer. The TP and TN are the amount of all forms of phosphorus and nitrogen, both organic and inorganic, respectively, found within the unfiltered water sample collected from a body of water (Cole and Weihe, 2016). Percent Agriculture Land Cover: Percent agriculture (%Ag) for each stream watershed was calculated by delineating each watershed at the site of field data collection using modelmywatershed.org (Stroud Research Center, 2020). To calculate the total %Ag land 13 cover the percent pasture/hay was added to the percent cultivated crops to get a total %Ag land cover within each stream watershed. Statistical analyses: All statistical analyses were performed using R statistical software (R Core Team, 2019). A logistic regression is a statistical analysis that can be used to test relationships between a dependent categorical variable and independent continuous predictor variables (Peng et al., 2002). A logistic regression was used to determine if environmental variables could predict the presence or absence of Cladophora in each stream sampled. The following environmental variables were analyzed in this model: %Ag, total alkalinity, and TP. These environmental variables were transformed using a log base 10 transformation to improve normality and homoscedasticity. An Akaike information criterion (AIC) is a way to compare multiple models to ensure the most parsimonious model is selected (Akaike, 1974 as cited by Akaike 1979). I performed a stepwise AIC test to select the most parsimonious categorical logistic regression. I carried out this categorical logistic regression using the generalized linear model (glm) function in base R (R Core Team, 2019). It is important to note, the non-Cladophora streams may have had Cladophora present in small amounts. I used a series of paired t-tests to compare % EPT taxa, Shannon diversity scores, HBI scores, and %Chironomidae values between Cladophora patches and nonCladophora patches from the same streams. These tests were performed using the t.test function in base R (R Core Team, 2019). I used a Kruskal-Wallis rank sum test as a nonparametric equivalent to a one-way analysis of variance (ANOVA) to compare the densities of macroinvertebrates by patch 14 type. This analysis compared densities from Cladophora patches, non-Cladophora patches and patches collected from non-Cladophora streams. When a Kruskal-Wallis rank sum test indicated a significant difference between one or more groups, I used a Dunn (1964) test as a nonparametric equivalent to a Tukey post hoc test. The KruskalWallis rank sum test was performed using the kruskal.test function in base R (R Core Team, 2019). The Dunn test was performed using the dunnTest function in the FSA Package version 0.8.27 in R (Ogle et al., 2020). Nonmetric multidimensional scaling (NMDS) ordination is a way to take multiple variables and arrange them in a multidimensional space according to the variable’s similarity or dissimilarity to each other and then plot them in a specified number of dimensions (Kruskal, 1964). In this case, macroinvertebrate communities (samples from different patch types) were the variables arranged according to Bray-Curtis dissimilarity. Bray-Curtis dissimilarity was calculated from Bray-Curtis similarity (Bray and Curtis, 1957) by the metaMDS function in the Vegan Package version 2.5-6 in R (Oksanen et al., 2019). This function also plotted the communities in a two-dimensional space, a biplot (Oksanen et al., 2019; R Core Team, 2019). The data were Wisconsin Double standardized and square root transformed for normality by the Vegan Package version 2.5-6 (Oksanen et al., 2007). Two NMDS biplots were created using the (ggplot) function in the ggplot2 package in R (Wickham, 2016). One biplot compared the macroinvertebrate communities from Cladophora patch samples to the non-Cladophora patch samples from the same streams. Another biplot compared the combined samples from Cladophora streams (Cladophora 15 patch samples and non-Cladophora patch samples from the same streams) to the samples from streams where Cladophora was absent. The permutational multivariate analysis of variance (PERMANOVA) is a nonparametric alternative to a multivariate analysis of variance, MANOVA (Anderson, 2001). PERMANOVA can be used to test the null hypothesis that the dependent variables, each taxon in the community, does not affect the community structure (Anderson, 2014). Two PERMANOVAs were performed using the macroinvertebrate community data. One PERMANOVA was used to test the hypothesis macroinvertebrate community structure was influenced by patch type, Cladophora patch or non-Cladophora patch within the same stream. Another PERMANOVA was used to test the hypothesis that macroinvertebrate community structure was influenced by stream type (Cladophora stream or non-Cladophora stream), %Ag, TP, average diel change in dissolved oxygen, or average diel change in water temperature. This statistical analysis was performed using the adonis function in the Vegan Package version 2.5-6 in R (Oksanen et al., 2007; R Core Team, 2019). RESULTS: Cladophora was generally found in streams with higher alkalinity values (see Fig. 2). The stepwise AIC test indicated the best model was one that used the log10 of total alkalinity values to predict the presence or absence of Cladophora in streams (AIC=14.73). The second-best model used the log10 of total alkalinity along with the log10 of TP (AIC=15.82). I used the log10 of total alkalinity values for each stream as the sole predictor variable for the categorical logistic regression to predict the presence or absence of Cladophora in streams (p=0.0516). 16 Figure 2. Total alkalinity in mg CaCO3/L from Cladophora streams and non-Cladophora streams in central Pennsylvania. Cladophora streams contained patches of Cladophora that covered at least 50% of the area within a Surber sampler. Non-Cladophora streams had very little or no Cladophora present. Samples collected from Cladophora patches contained greater numbers of macroinvertebrates compared to the samples collected from non-Cladophora patches. The lowest densities were found in samples collected from patches in non-Cladophora 17 streams, then samples from non-Cladophora patches within Cladophora streams had higher densities, and the highest densities were found in samples collected from Cladophora patches (see Fig. 3). The Kruskal-Wallis rank sum test indicated a difference (p<0.05) when comparing densities between all patch types. The Dunn test indicated the Cladophora patch densities were higher than the non-Cladophora stream densities (p<0.05). The non-Cladophora patch densities and the non-Cladophora stream densities exhibited less distinction (p=0.079). The differences in the densities for the Cladophora patches and the non-Cladophora patches from the same streams were similar (p=0.473). 18 Figure 3. Macroinvertebrate densities in non-Cladophora streams and in non-Cladophora and Cladophora patches within Cladophora dominated streams in central Pennsylvania. Samples collected from Cladophora patches contained greater numbers of Chironomidae and exhibited lower diversity than samples collected from nonCladophora patches (see Fig. 4 and Fig. 5). The %Chironomidae was greater in Cladophora patches compared to non-Cladophora patches (p<0.005). Therefore, Shannon diversity scores were lower in Cladophora patches compared to nonCladophora patches (p<0.05). 19 Figure 4. The %Chironomidae in Cladophora patches and non-Cladophora patches in Cladophora dominated streams in central Pennsylvania. 20 Figure 5. Shannon-Weaver diversity (H) scores for Cladophora patches and nonCladophora patches in Cladophora dominated streams in central Pennsylvania. Similar abundances of macroinvertebrate from the orders Ephemeroptera, Plecoptera, and Trichoptera were found in both Cladophora patches and non-Cladophora patches from the same streams. While the %EPT taxa for Cladophora patches were generally lower than that of the non-Cladophora patches (see Fig. 6) the differences were subtle (p=0.3508). 21 Figure 6. The %EPT taxa from non-Cladophora patches and Cladophora patches within Cladophora dominated streams in central Pennsylvania. Many of the same families of macroinvertebrates were found in both Cladophora patches and non-Cladophora patches within the same streams. Therefore, HBI scores between Cladophora patches and non-Cladophora patches from the same streams were comparable (p=0.1463) (see Fig. 7). When comparing macroinvertebrate community structures by patch type using a PERMANOVA, I did not find a clear difference between the macroinvertebrate community structures of Cladophora patches and non-Cladophora 22 patches within the same streams (p=0.296). It should be noted, in most cases, Cladophora patch samples (circles) were found to the left of the non-Cladophora patch samples (triangles) (see Fig. 8). This could indicate a trend that each Cladophora patch sample was separated from the non-Cladophora patch samples due to a difference in community structure in a similar direction, the negative direction on the NMDS1 axis. However, based on the results from the PERMANOVA, this trend is not strong enough to indicate clear differences in macroinvertebrate community structures between the two patch types. 23 Figure 7. Hilsenhoff Biotic Index (HBI) scores of Cladophora patches and nonCladophora patches within Cladophora dominated streams in central Pennsylvania. 24 Figure 8. Nonmetric multidimensional scaling (NMDS) ordination comparing Cladophora patch communities (circles) to non-Cladophora patch communities (triangles) in six Cladophora dominated streams in central Pennsylvania (stress=0.10571). Macroinvertebrate communities from Cladophora streams generally had greater numbers of macroinvertebrates and contained different families of macroinvertebrates when compared to non-Cladophora streams. Cladophora streams exhibited different community structure than non-Cladophora streams (p<0.05), indicated by closer grouping of Cladophora streams (circles) toward the middle of the biplot when compared 25 to non-Cladophora streams (triangles; see Fig. 9). This indicates many of the same taxa are found at similar abundances in Cladophora streams. Essentially, the Cladophora streams are more similar in community structure to each other than they are to the nonCladophora streams. The non-Cladophora streams show greater variation in their community structure and therefore do not group as tightly together as the Cladophora streams. It should be noted, when visually comparing Cladophora stream communities to non-Cladophora stream communities using NMDS ordination, an outlier was identified. This outlier was Briar Creek, which had far fewer individuals in the sample compared to all other samples. This caused a greater weight on the NMDS analysis and therefore, Briar Creek data were removed when making the NMDS biplot. Briar Creek data were not removed from the PERMANOVA test when comparing Cladophora stream and nonCladophora stream macroinvertebrate communities. 26 Figure 9. Nonmetric multidimensional scaling (NMDS) ordination comparing Cladophora stream communities (circles) to non-Cladophora stream communities (triangles) from 12 streams in central Pennsylvania. Briar Creek was omitted from this NMDS due to low numbers of macroinvertebrates heavily weighting NMDS analysis (stress=0.14163). The percent agriculture within stream watersheds impacted the macroinvertebrate community composition (p<0.05). However, my findings suggest that average diel change in dissolved oxygen (p=0.235), average diel change in water temperature (p=0.221), total phosphorus (p=0.094), and total alkalinity (p=0.191) along with an interaction between stream type : average diel change in dissolved oxygen (p=0.676) did 27 not seem to directly impact macroinvertebrate community composition between Cladophora streams and non-Cladophora streams. DISCUSSION: The findings of this study further support the large body of evidence that humans affect the communities of macroinvertebrates found in streams through agricultural land use and nutrient enrichment. The alga Cladophora is commonly associated with nutrient enrichment in streams (Stevenson et al., 2012; Whitton, 1970; Zulkifly et al., 2013). I found higher macroinvertebrate densities and decreased Shannon diversity in patches dominated by Cladophora due to higher Chironomidae abundances in these patches. These findings can help ecosystem managers by providing evidence for agricultural impact on macroinvertebrate communities, and potentially explain reasons for decreased diversity in nutrient-rich waters containing the filamentous, green alga, Cladophora. My findings support the hypothesis that agriculture land use impacts macroinvertebrate communities in streams. This means %Ag within the upstream watershed from the site of macroinvertebrate collection impacted the community structure of macroinvertebrates found within the streams. Hanna et al. (2020) found agriculture land use was associated with decreased ecosystem services and lower diversity of macroinvertebrates in streams. In a review by Weijters et al. (2009) many studies found significant negative relationships between the percent agriculture and macroinvertebrate diversity scores. It is important to note that the likely reason for seeing the percent agriculture directly influence macroinvertebrate community structure was likely due to phosphorus playing a role in Cladophora growth. Agriculture increases phosphorus content in soil (Sharpley et al., 1994) and phosphorus allows for large 28 growths of filamentous green algae, like Cladophora (Stevenson et al., 2012). Therefore, the percent agriculture indirectly influences Cladophora biomass which has a direct impact on macroinvertebrate community structure. I was unable to determine exactly how the percent agriculture specifically alters the community structure of macroinvertebrates. However, I suspect it is altering the community by increasing macroinvertebrate densities as well as the abundance of Chironomidae. In previous studies, macroinvertebrate densities have been shown to increase with Cladophora presence (Dudley et al., 1986; Ellsworth, 2000; Fairchild and Holomuzki, 2002; Feminella and Resh, 1991). My findings further support this trend. The higher densities of macroinvertebrates in Cladophora patches compared to samples from nonCladophora stream patches, suggested the Cladophora provided something to these macroinvertebrates, allowing for population sizes to increase. The macroinvertebrates could be benefitting from the increased surface area the Cladophora provides in streams, essentially providing a substrate for macroinvertebrate colonization (Dudley et al., 1986). Macroinvertebrates could also be feeding on epiphytic algae found on the Cladophora or potentially feeding on the Cladophora itself (Dudley et al., 1986; Feminella and Resh, 1991). The likely reason for increased macroinvertebrate densities is due to much higher abundances of Chironomidae in samples from Cladophora patches. The association of this dipteran larvae with Cladophora has been well documented (Berezina, 2008; Dudley et al., 1986; Higgins et al., 2008; Whitton, 1970). Chironomidae have been found to make their cases from filaments of this alga (Power, 1991). Though this study did not focus on what this alga provides for the Chironomidae, a higher %Chironomidae was found in 29 samples collected from patches containing Cladophora compared to patches without Cladophora from the same streams. Identification of Chironomidae past the family level would be necessary to determine the functional feeding groups present in this population. A potential future research project could be identifying the Chironomidae to the genus level to determine functional feeding groups present in each sample by taking a subsample of the Chironomidae and mounting head capsules for further identification. It is unknown exactly, what the Cladophora is providing the Chironomidae. However, research suggested the Chironomidae are likely feeding upon the diatoms and other epiphytes that typically colonize Cladophora and could also be using the Cladophora as a substrate to attach for filter feeding (Dudley et al., 1986; Furey et al., 2012; Pinder, 1986). Therefore, the Cladophora could be supplying the Chironomidae with both shelter and food, allowing for significant increases in Chironomidae populations in areas dominated by Cladophora compared to areas that lack this alga. The increase in Chironomidae in samples from Cladophora patches is likely the driving force for why Shannon diversity was lower for those samples. Essentially, the greater the abundance of one taxon in a sample, the lower the diversity for that sample. My research supports the findings of Ellsworth (2000), who found lower macroinvertebrate diversity associated with dense Cladophora growths in streams. However, Ellsworth (2000) attributed this decrease of diversity to increases of Baetis, Simulium and Chironomidae. My findings suggest Chironomidae are the dominant taxon in Cladophora patches and play a more significant role in the diversity of these patches than other taxa in central Pennsylvania. My research indicated macroinvertebrate community composition is likely determined at the stream-level spatial scale rather than patch-level spatial scale. This 30 claim is supported by finding distinct community composition separation between Cladophora streams and non-Cladophora streams, and not between Cladophora and nonCladophora patches within the same streams. However, this should be interpreted with caution. The distinction between macroinvertebrate communities in Cladophora streams and non-Cladophora streams could be due to geographic separation of these two stream types. Many of the Cladophora streams are geographically closer together than the nonCladophora streams, potentially causing similar families of macroinvertebrates to be found due to geographic proximity. The reason for a lack of distinction between communities at the patch level could be due to lower taxonomic resolution resulting from family-level identification. Though family level identification can tell us a great deal about macroinvertebrate communities (Osborne et al, 1980), most agencies recommend genus-level identification (PADEP, 2012). This is because genus-level identification would allow for further separation of the communities. It is possible that with greater taxonomic resolution (i.e. genus-level identification) a difference in community composition at the patch level could be found. Total alkalinity did not have a direct impact on macroinvertebrate communities between streams. However, I found that alkalinity did impact the presence or absence of Cladophora in streams and that Cladophora can impact macroinvertebrate density and diversity. Therefore, alkalinity seems to indirectly impact the macroinvertebrate communities through the influence of Cladophora. Cladophora tends to be found in waters with alkalinity of at least 90 mg CaCO3/L or higher (McMillan and Verduin 1953; Cheney and Hough, 1983; Robinson and Hawkes, 1986). Choo et al. (2002) were able to identify the uptake of inorganic species of carbon, directly related to alkalinity, in the 31 Baltic Sea. It has also been documented that C. glomerata is capable of utilizing HCO3as a carbon source within streams (Raven et al., 1982; Raven et al., 1994). Therefore, it makes sense for this alga to be present in larger quantities in streams that have greater amounts of this inorganic carbon form, i.e. waters with higher alkalinity values. The likely reason %Ag and TP were not identified as key predictors of Cladophora presence in the streams within this study is due to the limited number of stream sites examined. Variation within the %Ag and TP of these 13 streams was likely causing these variables to be excluded as predictors. It is well-known that Cladophora has a close association with higher levels of phosphorus (Whitton, 1970; Stevenson et al., 2012; Zulkifly et al., 2013; Dodds and Gudder, 1992). Agriculture is linked to phosphorus by the application of fertilizers and manures to agricultural lands increasing concentrations of phosphorus in soil (Sharpley et al., 1994), ultimately increasing the amount of phosphorus in streams (Carpenter et al., 1998). Therefore, if more sites, of both Cladophora and non-Cladophora streams, were included in this study then %Ag and TP would likely be good predictors of Cladophora presence in streams. The reason for a lack of distinction between some macroinvertebrate metrics at the patch level could also be due to lower taxonomic resolution resulting from familylevel identification. Many of the same families of macroinvertebrates were found in both Cladophora and non-Cladophora patches in the same streams, likely influencing the %EPT taxa and causing it to be similar for both patch types. However, Cladophora patches generally exhibited lower %EPT taxa, which would suggest the alga is creating slightly unfavorable conditions for these sensitive taxa. The orders Ephemeroptera, Plecoptera, and Trichoptera are generally sensitive to environmental variables, 32 specifically lower dissolved oxygen (Connolly et al., 2004), and are often not found in abundance in waters with pollution (Barbour et al., 1992). Cladophora may be creating subtle changes in dissolved oxygen that these taxa do not prefer, causing them to be found less frequently in patches of Cladophora. A valuable future study could examine how subtle changes in dissolved oxygen could cause EPT taxa to avoid areas of Cladophora. To do this, a micro-sensor that collects dissolved oxygen data could be placed in patches of Cladophora before sampling for macroinvertebrates to see diel changes in dissolved oxygen at a smaller scale. Then the %EPT taxa could be calculated to determine how these small-scale diel changes in dissolved oxygen impact the EPT taxa found in Cladophora patches. If more sites were included in this study, a difference of %EPT taxa between Cladophora patches and non-Cladophora patches may be observed. The HBI metric was also calculated using family-level identified macroinvertebrates. Using family-level identified macroinvertebrates for HBI scores is a common practice (Hilsenhoff, 1988). However, HBI scores can also be calculated using the pollution tolerance values for macroinvertebrates identified to the genus level (Chalfont, 2015). Pollution tolerance values for macroinvertebrates identified to the genus level are more specific, whereas family level identified pollution tolerance values are more conservative and are typically higher than that of some of the genera within that particular family (PADEP, 2012). Therefore, if macroinvertebrates were identified to the genus level, a greater resolution could be found, further distinguishing any differences that may be found in the HBI values. Another explanation for the lack of difference between HBI values for Cladophora patches and non-Cladophora patches could be due to the limited number of sites to compare. In this comparison, six Cladophora patches were compared 33 to six non-Cladophora patches from the same streams. If more sites containing Cladophora were found and separate HBI scores were calculated to compare Cladophora patches to non-Cladophora patches, it is possible a difference could be observed. Large quantities of filamentous green algae, like Cladophora, can decrease dissolved oxygen to hypoxic levels in lotic systems, which harm fish and invertebrate communities (Stevenson et al., 2012). It was rare for any of the sites studied in this project to drop below dissolved oxygen concentrations of about 6 mg/L and so these sites were not in danger of becoming hypoxic. Hypoxia is when oxygen concentrations drop to around 3 mg/L (Berezina et al., 2007). Stevenson et al. (2012) reported a diel change in dissolved oxygen of around 7 mg/L that resulted in a fish kill. However, the reason for this fish kill was likely due to dissolved oxygen concentrations reaching as low as 0.9mg/L, not the actual diel change in dissolved oxygen. The highest average diel change in dissolved oxygen I found was from Penns Creek with an average diel change in dissolved oxygen of 5.45 mg/L. However, the lowest recorded dissolved oxygen for this site was 5.53 mg/L, well above hypoxic levels. Therefore, it is not surprising that the average diel change in dissolved oxygen did not have a direct impact on macroinvertebrate communities because these communities were likely receiving adequate dissolved oxygen, even at their lowest dissolved oxygen levels. I was unable to detect a change in the average diel change in dissolved oxygen due to the presence of Cladophora in streams. This is likely due to Cladophora growths not completely overtaking the streambeds. The site with the most Cladophora cover was Penns Creek (see Fig. 10). The Cladophora streams had Cladophora patches large enough to be considered Cladophora patches, greater than 50% Cladophora cover within a Surber 34 sample, but I would not consider any of the sites in this study to be completely overrun with Cladophora. Therefore, it is unlikely the Cladophora would be significantly impacting the average diel change in dissolved oxygen within the streams at a detectable level. To see significant changes in average diel change in dissolved oxygen due to Cladophora with this number of sites, the sites in this study would need to have larger amounts of Cladophora present in the stream, greater than that of Penns Creek. Figure 10. Image serving as an example of a Cladophora patch sample taken within Penns Creek before a Surber sample from a patch containing Cladophora was collected. Low macroinvertebrate diversity in streams has been attributed to large (13°C) diel changes in water temperature (Jacobsen and Marín, 2008). However, the highest average diel change in water temperature I found was 5.25°C in Briar Creek. Most of the 35 sites fell within a diel change in water temperature of around 3-4°C. Therefore, it is not surprising the diel change in water temperature did not have a direct impact on macroinvertebrate community structure at the stream. Nutrient enrichment, like phosphorus, can cause shifts in macroinvertebrate communities, and more specifically, indirectly increase the Chironomidae populations within macroinvertebrate stream communities (Gafner and Robinson, 2007; Friberg et al., 2010). My results indicate total phosphorus did not directly impact macroinvertebrate communities between streams. However, it has been well documented that TP influences the growth of Cladophora in streams (Whitton, 1970; Stevenson et al., 2012; Zulkifly et al., 2013; Dodds and Gudder, 1992). Therefore, TP is indirectly influencing macroinvertebrate communities, and more specifically Chironomidae populations, through the growth of Cladophora. My hypotheses were: (1) Cladophora biomass will alter macroinvertebrate community membership at varying spatial scales both on a scale of patch distribution, within streams, and between streams, and (2) areas with Cladophora present will have different macroinvertebrate densities, percent Chironomidae (%Chironomidae), Shannondiversity Index values, Hilsenhoff Biotic Index (HBI) values, and percent Ephemeroptera, Plecoptera, and Trichoptera taxa (%EPT taxa), when compared to areas without Cladophora. My first hypothesis is supported by my findings. Though the community composition may not clearly differ between patches where Cladophora was present and where it was absent from the same streams, the % Chironomidae was significantly higher in the patches containing Cladophora. Therefore, at the patch scale, a greater number of Chironomidae can be found in areas containing Cladophora when 36 compared to areas the alga is absent. Macroinvertebrate communities differed more at the stream level, than the patch level. The basis for this statement is founded on the difference between macroinvertebrate community structure when comparing the macroinvertebrate communities by stream type. My second hypothesis was also supported by my findings. While not all the macroinvertebrate metrics would support this claim, both %Chironomidae and Shannon diversity differed between patch types within the same streams. The Shannon diversity scores were lower in samples from Cladophora patches, due to the %Chironomidae being greater in these patches. I found supporting evidence that alkalinity of streams can determine the distribution of Cladophora in streams of central Pennsylvania. My findings suggest that Cladophora growth in the streams I examined has not reached the nuisance levels reported by Stevenson et al. (2012) and is likely not strongly influencing diel changes in dissolved oxygen at a scale large enough for me perceive with the equipment I used. Cladophora seems to be influencing the macroinvertebrate community structure to be skewed with a dominant presence of Chironomidae. Future research could focus on the impacts of Cladophora on higher trophic levels. Beneficial questions which could be addressed include the following: What does the increased densities of macroinvertebrates mean for the organisms that feed on these macroinvertebrates? How does the presence or absence of Cladophora influence fish species and aquatic predators feeding on the aquatic life stages of macroinvertebrates? 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Photosynthesis of Cladophora in relation to light and CO2 limitation; CaCO3 Precipitation. Ecology. 56: 479-484. Zulkifly SB, Graham JM, Young EB, Mayer RJ, Piotrowski MJ, Smith I, Graham LE. 2013. The Genus Cladophora Kützing (Ulvophyceae) as a Globally Distributed Ecological Engineer. J. Phycol. 49: 1-17. 43 APPENDICES: Appendix A Raw data including the name of each stream site, the patch type, proportion of the total sample that was identified, date the macroinvertebrate samples were collected, total phosphorus (TP) in (ug/L), total nitrogen (TN) in (ug/L), total alkalinity in (mg CaCO3/L), Latitude and Longitude coordinates for each site, percent agriculture (%Ag) in each stream watershed, average diel change in dissolved oxygen (Average DDO) (mg/L), average diel change in water temperature in °C (Average DTemperature), and the identified macroinvertebrate data for each stream. 44 Table 1. Raw data collected from each site including the stream site, patch type, proportion of the total macroinvertebrate sample that was identified, date the samples were collected, TP (ug/L), TN (ug/L), total alkalinity (mg CaCO3/L), coordinates for each site, %Ag in each stream watershed, average diel change in dissolved oxygen (Average DDO) (mg/L), average diel change in water temperature in °C (Average DTemperature), and identified macroinvertebrate data for each stream. Stream Patch Type Proportion subsampled Date TP TN Total Alkalinity Briar Creek Non-Cladophora Stream 1 (N/A) 7/10/19 61.9779566 1815.336 60 Penns Creek Cladophora Patch 1/14 8/14/19 66.6792756 1174.874 96 Penns Creek Non-Cladophora Patch 3/28 8/14/19 66.6792756 1174.874 96 Fishing Creek Non-Cladophora Stream 3/28 7/16/19 30.0589682 1011.955 58 Green Creek Non-Cladophora Stream 9/28 7/15/19 15.5895266 2491.359 50 Mahoning Creek Cladophora Patch 1/28 8/20/19 62.3403174 1619.008 103 Mahoning Creek Non-Cladophora Patch 3/28 8/20/19 62.3403174 1619.008 103 Chillisquaque Creek Cladophora Patch 1/7 8/15/19 98.1796748 1982.938 101 Chillisquaque Creek Non-Cladophora Patch 3/28 8/15/19 98.1796748 1982.938 101 Mauses Creek Non-Cladophora Patch 3/28 8/20/19 43.3913466 1805.275 134 Mauses Creek Cladophora Patch 3/28 8/20/19 43.3913466 1805.275 134 Hemlock Creek Non-Cladophora Stream 9/28 7/15/19 22.580591 2650.922 68 Warrior Run Cladophora Patch 3/28 8/22/19 29.0968378 731.019 102 Warrior Run Non-Cladophora Patch 3/28 8/22/19 29.0968378 731.019 102 45 Table 1continued Stream Patch Type Proportion subsampled Little Fishing Creek Non-Cladophora Stream 3/28 7/17/19 33.3045964 1591.275 58 Huntington Creek Non-Cladophora Stream 1/7 7/16/19 26.8352066 720.604 47 Turtle Creek Cladophora Patch 1/56 8/18/19 46.0340814 5128.933 205 Turtle Creek Non-Cladophora Patch 1/28 8/18/19 46.0340814 5128.933 205 1/7 8/14/19 154 North Mahantango Creek Non-Cladophora Stream Date TP 51.553836 TN 1422.952 Total Alkalinity 46 Table 1 continued Stream Patch Type Latitude Longitude %Ag Briar Creek Non-Cladophora Stream 41.0679 -76.29013 34.39 Penns Creek Cladophora Patch 40.826213 -76.87228 Penns Creek Non-Cladophora Patch 40.826213 -76.87228 Average DDO Average DTemperature 1.702929 5.252929 27 5.45675 3.921875 27 5.45675 3.921875 Fishing Creek Non-Cladophora Stream 41.048969 -76.42997 28.08 2.199591 3.14 Green Creek Non-Cladophora Stream 41.109922 -76.41719 52.15 1.261667 2.960667 Mahoning Creek Cladophora Patch 40.977506 -76.62412 46.1 3.1626 2.908 Mahoning Creek Non-Cladophora Patch 40.977506 -76.62412 46.1 3.1626 2.908 Chillisquaque Creek Cladophora Patch 40.960146 -76.81623 65.71 1.433111 1.629444 Chillisquaque Creek Non-Cladophora Patch 40.960146 -76.81623 65.71 1.433111 1.629444 Mauses Creek Non-Cladophora Patch 40.984725 -76.63109 45.28 1.7227 2.4646 Mauses Creek Cladophora Patch 40.984725 -76.63109 45.28 1.7227 2.4646 54.39 1.263313 4.056313 Hemlock Creek Non-Cladophora Stream 40.995499 -76.4861 Warrior Run Cladophora Patch 41.101962 -76.79345 39.97 1.41225 1.78 Warrior Run Non-Cladophora Patch 41.101962 -76.79345 39.97 1.41225 1.78 39.1 1.599444 3.647833 Non-Cladophora Stream 41.113928 -76.33979 26.61 1.394375 3.0385 Little Fishing Creek Huntington Creek Non-Cladophora Stream 41.027598 -76.48027 Turtle Creek Cladophora Patch 40.928275 -76.88129 46.72 4.377 4.170333 Turtle Creek Non-Cladophora Patch 40.928275 -76.88129 46.72 4.377 4.170333 2.715944 3.301778 North Mahantango Creek Non-Cladophora Stream 40.6495 -76.96636 35.31 47 Table 1 continued Stream Patch Type Chironomidae Psephenidae Elmidae Oligochaeta Bivalvia Briar Creek Non-Cladophora Stream 665 2 12 20 4 Penns Creek Cladophora Patch 138 2 107 2 2 Penns Creek Non-Cladophora Patch 43 5 70 6 0 Fishing Creek Non-Cladophora Stream 151 0 2 3 0 Green Creek Non-Cladophora Stream 94 8 38 9 0 Mahoning Creek Cladophora Patch 172 2 15 3 0 Mahoning Creek Non-Cladophora Patch 96 6 47 21 0 Chillisquaque Creek Cladophora Patch 88 1 26 2 0 Chillisquaque Creek Non-Cladophora Patch 61 6 115 4 0 Mauses Creek Non-Cladophora Patch 54 2 13 45 0 Mauses Creek Cladophora Patch 173 3 18 19 0 Hemlock Creek Non-Cladophora Stream 32 2 12 5 0 Warrior Run Cladophora Patch 327 2 5 1 0 Warrior Run Non-Cladophora Patch 152 2 19 6 0 Little Fishing Creek Non-Cladophora Stream 48 2 37 65 0 Huntington Creek Non-Cladophora Stream 117 3 22 18 1 Turtle Creek Cladophora Patch 169 20 45 4 4 Turtle Creek Non-Cladophora Patch 111 9 82 5 2 160 10 106 5 5 North Mahantango Creek Non-Cladophora Stream 48 Table 1 continued Stream Patch Type Chloroperlidae Heptageniidae Limoniidae Tabanidae Julida Briar Creek Non-Cladophora Stream 1 1 5 1 1 Penns Creek Cladophora Patch 0 9 0 0 0 Penns Creek Non-Cladophora Patch 0 7 0 0 0 Fishing Creek Non-Cladophora Stream 0 8 0 0 0 Green Creek Non-Cladophora Stream 3 34 2 0 0 Mahoning Creek Cladophora Patch 0 15 0 0 0 Mahoning Creek Non-Cladophora Patch 0 17 0 0 0 Chillisquaque Creek Cladophora Patch 0 7 0 0 0 Chillisquaque Creek Non-Cladophora Patch 0 21 0 0 0 Mauses Creek Non-Cladophora Patch 0 11 7 0 0 Mauses Creek Cladophora Patch 0 10 12 0 0 Hemlock Creek Non-Cladophora Stream 0 11 2 0 0 Warrior Run Cladophora Patch 1 4 5 0 0 Warrior Run Non-Cladophora Patch 0 2 6 0 0 Little Fishing Creek Non-Cladophora Stream 1 35 1 0 0 Huntington Creek Non-Cladophora Stream 0 8 12 0 0 Turtle Creek Cladophora Patch 0 0 7 0 0 Turtle Creek Non-Cladophora Patch 0 0 8 0 0 0 2 3 0 0 North Mahantango Creek Non-Cladophora Stream 49 Table 1 continued Stream Patch Type Nematoda Isopoda Baetidae Hydropsychidae Arachnida Viviparidae Briar Creek Non-Cladophora Stream 2 1 3 1 1 0 Penns Creek Cladophora Patch 1 0 32 24 0 80 Penns Creek Non-Cladophora Patch 0 0 48 45 0 39 Fishing Creek Non-Cladophora Stream 5 0 70 57 0 0 Green Creek Non-Cladophora Stream 1 0 86 72 0 0 Mahoning Creek Cladophora Patch 1 0 31 82 0 0 Mahoning Creek Non-Cladophora Patch 10 0 32 103 0 0 Chillisquaque Creek Cladophora Patch 0 0 28 131 1 0 Chillisquaque Creek Non-Cladophora Patch 5 0 25 79 0 0 Mauses Creek Non-Cladophora Patch 4 0 84 76 0 0 Mauses Creek Cladophora Patch 0 0 66 55 0 0 Hemlock Creek Non-Cladophora Stream 6 0 80 103 0 0 Warrior Run Cladophora Patch 2 0 33 49 0 0 Warrior Run Non-Cladophora Patch 28 0 51 55 0 0 Little Fishing Creek Non-Cladophora Stream 16 0 124 67 0 0 Huntington Creek Non-Cladophora Stream 1 0 25 61 0 0 Turtle Creek Cladophora Patch 1 3 26 65 0 0 Turtle Creek Non-Cladophora Patch 7 0 26 46 0 0 8 0 7 62 0 0 North Mahantango Creek Non-Cladophora Stream 50 Table 1 continued Stream Patch Type Lepidostomatidae Perlidae Glossosomatidae Philopotamidae Briar Creek Non-Cladophora Stream 0 0 0 0 Penns Creek Cladophora Patch 1 5 32 1 Penns Creek Non-Cladophora Patch 0 4 13 2 Fishing Creek Non-Cladophora Stream 4 7 0 7 Green Creek Non-Cladophora Stream 0 2 0 3 Mahoning Creek Cladophora Patch 0 0 0 7 Mahoning Creek Non-Cladophora Patch 0 0 0 5 Chillisquaque Creek Cladophora Patch 0 0 0 9 Chillisquaque Creek Non-Cladophora Patch 0 0 0 19 Mauses Creek Non-Cladophora Patch 0 0 23 8 Mauses Creek Cladophora Patch 0 0 1 4 Hemlock Creek Non-Cladophora Stream 0 0 4 22 Warrior Run Cladophora Patch 0 0 2 7 Warrior Run Non-Cladophora Patch 0 0 1 20 Little Fishing Creek Non-Cladophora Stream 0 2 0 5 Huntington Creek Non-Cladophora Stream 0 3 0 0 Turtle Creek Cladophora Patch 0 0 0 17 Turtle Creek Non-Cladophora Patch 0 0 0 44 0 0 0 1 North Mahantango Creek Non-Cladophora Stream 51 Table 1 continued Stream Patch Type Briar Creek Non-Cladophora Stream 0 0 0 0 Penns Creek Cladophora Patch 22 10 9 1 Penns Creek Non-Cladophora Patch 24 12 15 0 Fishing Creek Non-Cladophora Stream 0 0 0 0 Green Creek Non-Cladophora Stream 0 0 0 0 Mahoning Creek Cladophora Patch 0 2 10 0 Mahoning Creek Non-Cladophora Patch 0 0 13 0 Chillisquaque Creek Cladophora Patch 0 4 75 0 Chillisquaque Creek Non-Cladophora Patch 0 0 30 0 Mauses Creek Non-Cladophora Patch 0 1 1 0 Mauses Creek Cladophora Patch 0 0 0 0 Hemlock Creek Non-Cladophora Stream 0 4 0 0 Warrior Run Cladophora Patch 0 4 6 0 Warrior Run Non-Cladophora Patch 0 0 0 0 Little Fishing Creek Non-Cladophora Stream 0 2 0 0 Huntington Creek Non-Cladophora Stream 0 0 3 0 Turtle Creek Cladophora Patch 0 4 22 1 Turtle Creek Non-Cladophora Patch 0 0 1 0 8 0 4 3 North Mahantango Creek Non-Cladophora Stream Potamanthidae Simuliidae Hydroptilidae Helicopsyche 52 Table 1 continued Stream Patch Type Briar Creek Non-Cladophora Stream 0 0 0 0 Penns Creek Cladophora Patch 7 57 1 1 Penns Creek Non-Cladophora Patch 5 23 1 0 Fishing Creek Non-Cladophora Stream 1 13 1 1 Green Creek Non-Cladophora Stream 0 2 0 0 Mahoning Creek Cladophora Patch 1 0 0 0 Mahoning Creek Non-Cladophora Patch 7 0 3 0 Chillisquaque Creek Cladophora Patch 8 2 0 0 Chillisquaque Creek Non-Cladophora Patch 9 0 0 0 Mauses Creek Non-Cladophora Patch 2 0 0 0 Mauses Creek Cladophora Patch 0 3 0 0 Hemlock Creek Non-Cladophora Stream 1 0 0 0 Warrior Run Cladophora Patch 9 0 0 0 Warrior Run Non-Cladophora Patch 8 0 0 0 Little Fishing Creek Non-Cladophora Stream 0 0 1 0 Huntington Creek Non-Cladophora Stream 0 3 0 0 Turtle Creek Cladophora Patch 22 0 0 0 Turtle Creek Non-Cladophora Patch 58 0 0 0 2 14 0 9 North Mahantango Creek Non-Cladophora Stream Turbellaria Ephemerellidae Caenidae Brachycentridae 53 Table 1 continued Stream Patch Type Briar Creek Non-Cladophora Stream 0 0 0 0 Penns Creek Cladophora Patch 1 0 0 0 Penns Creek Non-Cladophora Patch 0 1 1 0 Fishing Creek Non-Cladophora Stream 4 13 0 1 Green Creek Non-Cladophora Stream 15 1 0 2 Mahoning Creek Cladophora Patch 16 3 0 0 Mahoning Creek Non-Cladophora Patch 21 4 0 3 Chillisquaque Creek Cladophora Patch 20 3 0 4 Chillisquaque Creek Non-Cladophora Patch 13 2 0 6 Mauses Creek Non-Cladophora Patch 1 0 0 0 Mauses Creek Cladophora Patch 1 1 4 4 Hemlock Creek Non-Cladophora Stream 1 0 0 1 Warrior Run Cladophora Patch 1 0 0 1 Warrior Run Non-Cladophora Patch 0 0 1 1 Little Fishing Creek Non-Cladophora Stream 3 12 0 3 Huntington Creek Non-Cladophora Stream 0 0 1 2 Turtle Creek Cladophora Patch 2 0 1 1 Turtle Creek Non-Cladophora Patch 0 0 0 3 0 2 0 2 North Mahantango Creek Non-Cladophora Stream Athericidae Isonychiidae Ancylidae Hydrachnidia 54 Table 1 continued Stream Patch Type Capniidae Aeshnidae Ceratopogonidae Polycentropodidae Sialis Briar Creek Non-Cladophora Stream 6 0 0 0 0 Penns Creek Cladophora Patch 0 0 0 0 0 Penns Creek Non-Cladophora Patch 0 0 0 0 0 Fishing Creek Non-Cladophora Stream 2 0 0 0 0 Green Creek Non-Cladophora Stream 0 1 1 2 1 Mahoning Creek Cladophora Patch 0 0 1 3 0 Mahoning Creek Non-Cladophora Patch 0 0 0 4 1 Chillisquaque Creek Cladophora Patch 0 0 0 3 1 Chillisquaque Creek Non-Cladophora Patch 0 0 0 2 0 Mauses Creek Non-Cladophora Patch 0 0 0 0 0 Mauses Creek Cladophora Patch 0 0 0 0 0 Hemlock Creek Non-Cladophora Stream 0 0 0 2 0 Warrior Run Cladophora Patch 0 0 0 4 0 Warrior Run Non-Cladophora Patch 0 0 0 4 0 Little Fishing Creek Non-Cladophora Stream 1 0 1 1 0 Huntington Creek Non-Cladophora Stream 0 0 0 7 2 Turtle Creek Cladophora Patch 0 0 0 0 0 Turtle Creek Non-Cladophora Patch 0 0 0 4 0 0 0 0 0 0 North Mahantango Creek Non-Cladophora Stream 55 Table 1 continued Stream Patch Type Briar Creek Non-Cladophora Stream 0 0 0 0 Penns Creek Cladophora Patch 0 0 0 0 Penns Creek Non-Cladophora Patch 0 0 0 0 Fishing Creek Non-Cladophora Stream 0 0 0 0 Green Creek Non-Cladophora Stream 0 0 0 0 Mahoning Creek Cladophora Patch 0 0 0 0 Mahoning Creek Non-Cladophora Patch 4 1 1 0 Chillisquaque Creek Cladophora Patch 0 0 0 1 Chillisquaque Creek Non-Cladophora Patch 0 0 0 0 Mauses Creek Non-Cladophora Patch 0 0 0 0 Mauses Creek Cladophora Patch 0 0 0 0 Hemlock Creek Non-Cladophora Stream 0 0 0 0 Warrior Run Cladophora Patch 0 0 0 0 Warrior Run Non-Cladophora Patch 0 0 0 0 Little Fishing Creek Non-Cladophora Stream 0 0 0 0 Huntington Creek Non-Cladophora Stream 0 0 0 0 Turtle Creek Cladophora Patch 1 0 0 0 Turtle Creek Non-Cladophora Patch 2 0 0 0 0 0 0 0 North Mahantango Creek Non-Cladophora Stream Amphipoda Perlodidae Gerridae Formicidae 56 Table 1 continued Stream Patch Type Briar Creek Non-Cladophora Stream 0 0 0 0 Penns Creek Cladophora Patch 0 0 0 0 Penns Creek Non-Cladophora Patch 0 0 0 0 Fishing Creek Non-Cladophora Stream 0 0 0 0 Green Creek Non-Cladophora Stream 0 0 0 0 Mahoning Creek Cladophora Patch 0 0 0 0 Mahoning Creek Non-Cladophora Patch 0 0 0 0 Chillisquaque Creek Cladophora Patch 0 0 0 0 Chillisquaque Creek Non-Cladophora Patch 0 0 0 0 Mauses Creek Non-Cladophora Patch 0 0 0 0 Mauses Creek Cladophora Patch 1 0 0 0 Hemlock Creek Non-Cladophora Stream 0 4 1 0 Warrior Run Cladophora Patch 0 0 0 0 Warrior Run Non-Cladophora Patch 0 0 0 1 Little Fishing Creek Non-Cladophora Stream 0 0 0 0 Huntington Creek Non-Cladophora Stream 0 0 5 0 Turtle Creek Cladophora Patch 0 0 0 0 Turtle Creek Non-Cladophora Patch 0 0 0 0 0 0 0 0 North Mahantango Creek Non-Cladophora Stream Leptophlebiidae Leuctridae Limnephilidae Tipulidae 57 Table 1 continued Stream Patch Type Briar Creek Non-Cladophora Stream 0 0 0 0 Penns Creek Cladophora Patch 0 0 0 0 Penns Creek Non-Cladophora Patch 0 0 0 0 Fishing Creek Non-Cladophora Stream 0 0 0 0 Green Creek Non-Cladophora Stream 0 0 0 0 Mahoning Creek Cladophora Patch 0 0 0 0 Mahoning Creek Non-Cladophora Patch 0 0 0 0 Chillisquaque Creek Cladophora Patch 0 0 0 0 Chillisquaque Creek Non-Cladophora Patch 0 0 0 0 Mauses Creek Non-Cladophora Patch 0 0 0 0 Mauses Creek Cladophora Patch 0 0 0 0 Hemlock Creek Non-Cladophora Stream 0 0 0 0 Warrior Run Cladophora Patch 0 0 0 0 Warrior Run Non-Cladophora Patch 2 0 0 0 Little Fishing Creek Non-Cladophora Stream 0 0 0 0 Huntington Creek Non-Cladophora Stream 0 10 0 0 Turtle Creek Cladophora Patch 0 0 0 0 Turtle Creek Non-Cladophora Patch 0 0 1 0 1 0 6 2 North Mahantango Creek Non-Cladophora Stream Corydalidae Psychomyiidae Pediciidae Gomphidae 58 Table 1 continued Stream Patch Type Briar Creek Non-Cladophora Stream 0 4 730 Penns Creek Cladophora Patch 1 22 568 Penns Creek Non-Cladophora Patch 0 10 374 Fishing Creek Non-Cladophora Stream 0 34 384 Green Creek Non-Cladophora Stream 0 27 404 Mahoning Creek Cladophora Patch 0 9 373 Mahoning Creek Non-Cladophora Patch 0 14 413 Chillisquaque Creek Cladophora Patch 0 15 429 Chillisquaque Creek Non-Cladophora Patch 0 19 416 Mauses Creek Non-Cladophora Patch 0 25 357 Mauses Creek Cladophora Patch 0 30 405 Hemlock Creek Non-Cladophora Stream 0 15 308 Warrior Run Cladophora Patch 0 15 478 Warrior Run Non-Cladophora Patch 0 28 387 Little Fishing Creek Non-Cladophora Stream 0 17 444 Huntington Creek Non-Cladophora Stream 0 15 319 Turtle Creek Cladophora Patch 0 19 434 Turtle Creek Non-Cladophora Patch 0 15 424 0 12 434 North Mahantango Creek Non-Cladophora Stream Polymitarcyidae Unknowns Totals 59 Appendix B Dissolved oxygen and water temperature data for each site including the following variables: dissolved oxygen (a), water temperature (b), diel change in dissolved oxygen, labeled DDO (c), diel change in water temperature, labeled DTemperature (d). The figures for each stream are presented in the following order: Briar Creek (Fig. B1), Chillisquaque Creek (Fig. B2), Fishing Creek (Fig. B3), Green Creek (Fig. B4), Hemlock Creek (Fig. B5), Huntington Creek (Fig. B6), Little Fishing Creek (Fig. B7), Mahoning Creek (Fig. B8), Mauses Creek (Fig. B9), North Mahantango Creek (Fig. B10), Penns Creek (Fig. B11), Turtle Creek (Fig. B12), and Warrior Run (Fig. B13). All figures were created by the author using R statistical software (R Core Team, 2019). 60 Figure B1. Briar Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 61 Figure B2. Chillisquaque Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 62 Figure B3. Fishing Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 63 Figure B4. Green Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 64 Figure B5. Hemlock Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 65 Figure B6. Huntington Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 66 Figure B7. Little Fishing Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 67 Figure B8. Mahoning Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 68 Figure B9. Mauses Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 69 Figure B10. North Mahantango Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 70 Figure B11. Penns Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 71 Figure B12. Turtle Creek data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed. 72 Figure B13. Warrior Run data including dissolved oxygen data (a) and water temperature data (b) collected every 15 minutes for the total amount of time the data loggers were deployed. The diel change in dissolved oxygen (c) and diel change in water temperature (d) for each day while data loggers were deployed is also displayed.