Data from: How do freshwater prey respond to combinations of predation risk and salinity?
Data files
Dec 30, 2025 version files 280.46 KB
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PHYSA-SaltPred_MesocosmData.csv
1.74 KB
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PHYSA-SaltPred_Morphology.csv
276.46 KB
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README.md
2.26 KB
Abstract
Freshwater salinization is a growing problem worldwide and negatively affects many freshwater organisms. Many of the prior experiments studying the effects of salinity on freshwater organisms have examined the effects of salinity in isolation from natural stressors such as predation risk. However, stressors such as predation risk can synergistically interact with many pollutants to affect prey survival and growth, so it is important to determine if it interacts with salt pollution. In this experiment, we looked for interactive effects of salinity and predation risk on freshwater snails using a full-factorial mesocosm experiment that crossed four salt concentrations (no added salt, 250 mg Cl- /L, 500 mg Cl-/L, and 1000 mg Cl-/L) with three predator regimes (no predator, crayfish cues, and water bug cues). Snails were raised in the mesocosms from juveniles to reproductively mature adults, and we measured their survival, mass, reproduction, and shell morphology. We discovered a synergistic effect of salinity and predation risk on the survival of snails at the highest salt concentration. At the highest salinity, adding crayfish cues caused a 66% increase in snail mortality, whereas adding water bug cues caused a 143% increase in snail mortality. In contrast, the effects of predation risk and salinity on snail mass, reproduction, and shell morphology were additive. Our results suggest that experiments testing salinity in isolation from other stressors may underestimate the full impact of salt pollution in freshwater environments.
Description of the data and file structure
Freshwater salinization harms many organisms, and its effects can interact with natural stressors like predation risk. This experiment tested how salinity and predator cues together affect freshwater snails, finding that their combined impact greatly increased snail mortality at high salt levels. However, their effects on snail growth and reproduction were additive, highlighting the importance of studying multiple stressors together to understand salt pollution’s true impact.
File: PHYSA-SaltPred_Morphology.csv
Column Explanation:
- SnailID: Unique ID code for each snail
- Pool- Mesocosm of origin for this snail
- Pred - Predator treatment for this snail (Belostoma = water bug cue; Crayfish = crayfish/crushed snail cue; No Predator = no predator cue)
- Salt - Salt exposure for this snail (mgCl-/L)
- Mass- snail body/shell mass (g)
- Snail.Number- unique number of this snail
- Landmark.ID- name of shell morphological feature
- Measurement.mm- measurement of shell morphological feature (area = sq.mm; length/width = mm)
- Empty.Shell - if 1, this is the shell is empty
- Damage to.Shell - if 1, the shell is damaged
- Aperture. Unclear - if 1, the aperture in this photo is damaged or obscured
- Shell.Length.Width.Unclear - if 1, the shell length or width to be measured accurately
- Spire. Unclear - if 1, the spirecane to bis e measured accurately
- Scale.Bar.Unclear - if 1, the scale bar is missing or unable to be measured
- Comments - unique comments relating to the morphological photos
File: PHYSA-SaltPred_MesocosmData.csv
Column Explanation:
- Pool- Number designation of mesocosm
- Pred- Predator treatment of mesocosm (Bel = water bug; Cry = crayfish/crush; Nop = No predator)
- Salt -Salt addition treatment of mesocosm (mgCl-/L)
- T.Snails - Total # Snails found at the end of the experiment
- T.LiveSnails - Total # live snails found at the end of the experiment
- T.DeadSnails - Total # dead snails found at the end of the experiment
- EggMass - Number of egg masses found in mesocosm
- SnailMass -_End Mean snail mass at end of experiment