A peer-reviewed open-access journal

NeoBiota 71: 91-112 (2022)

doi: 10.3897/neobiota.7 1.7571 | &) NeoBiota

https:/ / neobi ota. pen soft. net Advancing research on alien species and biological invasions

Predatory ability and abundance forecast
the ecological impacts of two aquatic invasive species

Emma M. DeRoy', Steven Crookes’, Kyle Matheson?, Ryan Scott’,
Cynthia H. McKenzie’, Mhairi E. Alexander’,
Jaimie T. A. Dick®, Hugh J. MaclIsaac!’

| Great Lakes Institute for Environmental Research, University of Windsor, Windsor ON N9B 3P4, Canada
2 Precision Biomonitoring, 361 Southgate Drive, Guelph ON, NIG 3M5, Canada 3 Northwest Atlantic
Fisheries Centre, Fisheries and Oceans Canada, St. John’s, Newfoundland and Labrador, AIC 5X1, Canada
4 Institute for Diagnostic Imaging Research, University of Windsor, Windsor ON N9B 3P4, Canada § School
of Health and Life Sciences, University of West of Scotland, Paisley, PAI 2BE, Scotland 6 Institute for Global
Food Security, School of Biological Sciences, Queens University, Belfast, Northern Ireland, UK 1 School of Ecol-
ogy and Environmental Sciences, Yunnan University, Kunming, China

Corresponding author: Emma M. DeRoy (deroye@uwindsor.ca)

Academiceditor: Jonathan Jeschke | Received 29 September 2021 | Accepted22 December 2021 | Published27 January 2022

Citation: DeRoy EM, Crookes S, Matheson K, Scott R, McKenzie CH, Alexander ME, Dick JTA,Maclsaac HJ (2022)
Predatory ability and abundance forecast the ecological impacts of two aquatic invasive species. NeoBiota 71: 91-112.

https://doi.org/10.3897/neobiota.71.75711

Abstract

Characterising interspecific interaction strengths, combined with population abundances of prey and their
novel predators, is critical to develop predictive invasion ecology. This is especially true of aquatic invasive
species, which can pose a significant threat to the structure and stability of the ecosystems to which they
are introduced. Here, we investigated consumer-resource dynamics of two globally-established aquatic
invasive species, European green crab (Carcinus maenas) and brown trout (Salmo trutta). We explored the
mediating effect of prey density on predatory impact in these invaders relative to functionally analogous
native rock crab (Cancer irroratus) and Atlantic salmon (Salmo salar), respectively, feeding on shared prey
(Mytilus sp. and Tenebrio molitor, respectively). We subsequently combined feeding rates with each preda-
tor’s regional abundance to forecast relative ecological impacts. All predators demonstrated potentially
destabilising Type II functional responses towards prey, with native rock crab and invasive brown trout
exhibiting greater per capita impacts relative to their trophic analogues. Functional Response Ratios (attack
rates divided by handling times) were higher for both invasive species, reflecting greater overall per capita
effects compared to natives. Impact projections that incorporated predator abundances with per capita etf-
fects predicted severe impacts by European green crabs. However, brown trout, despite possessing higher

per capita effects than Atlantic salmon, are projected to have low impact owing to currently low abun-

Copyright Emma M. DeRoy et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC
BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

92 Emma M. DeRoy et al. / NeoBiota 71: 91-112 (2022)

dances in the sampled watershed. Should brown trout density increase sixfold, we predict it would exert
higher impact than Atlantic salmon. Such impact-forecasting metrics and methods are thus vital tools to

assist in the determination of current and future adverse impacts associated with aquatic invasive species.

Keywords
Aquatic invasive species, consumption rate, feeding, freshwater, functional response, Functional Response

Ratio, impact, invasion, marine, predation, Relative Impact Potential

Introduction

Invasive species exert measurable and often catastrophic changes in recipient com-
munities (Ricciardi et al. 2013; Gallardo et al. 2016; Flood et al. 2020). As invasion
rates continue to increase globally (Seebens et al. 2017), understanding and mitigat-
ing invasion impacts is pivotal. Freshwater and marine environments support diverse
assemblages of non-indigenous species (Strayer 2010). Many such species have had
demonstrable impacts on their recipient systems, with approximately one-fifth of the
100 world’s worst invasive species found in aquatic habitats (Kulhanek et al. 2011).
However, comparative trait analyses between native and non-indigenous species have
focused primarily on terrestrial ecosystems (Leffler et al. 2014). Evaluating the impacts
of aquatic invasive species is, therefore, paramount to manage their effects (Ojaveer et
al. 2015). However, the inherent difficulty associated with quantifying invasive species’
ecological impacts requires a more mechanistic approach that can also forecast ecologi-
cal impacts with readily available data, based on per capita effects and abundances of
the interacting species (Dick et al. 2014, 2017a).

Analysis of a predator’s density-dependent consumption rates [i.e. its functional re-
sponse (FR)] can provide insights into its per capita effect (Holling 1959). In addition,
experimentally-derived estimates of invasive species’ per capita effects relative to those
of native analogues are useful tools to forecast the former's potential ecological impact
(Dick et al. 2014). Invasive species often demonstrate higher and more efficient re-
source utilisation relative to ecologically similar native species across taxonomic groups
(Dick et al. 2014; Crookes et al. 2019; Dickey et al. 2021). Taking such per capita im-
pact prediction one step further, the Functional Response Ratio (FRR) is derived from
the FR’s constituent parameters (attack rate divided by handling time). By synthesising
its parameters into a single metric, the FRR provides greater mechanistic insight into
drivers of predator impact on affected prey species than use of either attack rate or han-
dling time variables in isolation (Cuthbert et al. 2019). As the FRR integrates predator
effects at both low and high prey densities, it may provide increased predictive power of
per capita type (i.e. FR) experiments (Cuthbert et al. 2019; Madzivanzira et al. 2021).

While species’ resource consumption can provide insights into their projected eco-
logical impacts (Dick et al. 2014), the magnitude of an effect is also determined by the
predator’s local abundance (Parker et al. 1999). Dick et al. (2017a) thus devised a new
metric, the Relative Impact Potential (RIP), that incorporates per capita feeding rates

Forecasting ecological impacts of aquatic invasive species 93

and local field abundances as proxies for functional and numerical responses, respec-
tively, to predict the ecological impact of an invasive species versus that of a compara-
tive native species. This method shows promise to screen potential invasive species and
perform rapid impact assessments of established (as well as potential) invaders on both
prey communities and relative to co-occurring native predators (Hoxha et al. 2018;
DeRoy et al. 2020; Dickey et al. 2020a). Indeed, the RIP metric was 100% successful
in its ability to predict the actual field impacts of a range of invasives across trophic and
taxonomic groups (Dick et al. 2017a).

The objective of our study was to discern whether per capita and overall impacts
differed between aquatic invasive species and respective native analogues, using two
globally-established invasive species. We utilised the aforementioned trio of metrics
(i.e. FR, FRR and RIP) to quantify the predatory impacts of two aquatic invasive
species — the marine European green crab (Carcinus maenas) (hereafter, green crab)
and the freshwater brown trout (Salmo trutta) — each of which are established in
Canada and other regions globally. Both are listed amongst the 100 of the worst
invasive species (Lowe et al. 2000), in part due to their strong observed effects on
recipient ecosystems. Given that differences in feeding behaviour may influence
competitive ability and ecological impact in the field (Dick et al. 2017a), we ex-
pected that the outcomes of these experiments would reflect the relative impact of
both invasive and native predators.

To accurately direct management efforts of invasive species, researchers must
understand their projected effect across and within regions to which the species has
spread, relative to native analogues. Such predictions provide essential information to
possible management interventions of invasive species.

Methods
Collection and maintenance

Brachyuran crabs

Invasive green crab (Carcinus maenas) and native rock crab (Cancer irroratus) (N = 30
each) were collected during the summer of 2015 using Fukui traps (baited with her-
ring) from the upper subtidal zone at North Harbour within Placentia Bay, Newfound-
land (NL). Green crab was first detected in this region in 2007 (Blakeslee et al. 2010)
and has since spread throughout Placentia Bay and Fortune Bay on the NL south
coast. In this and other regions, green crab has precipitated cascading, ecosystem-level
changes to fish communities and their habitat (Matheson et al. 2016) and has had de-
monstrable negative effects on indigenous decapods (MacDonald et al. 2007; Rayner
and McGaw 2019). Rock crab was selected given that it shares similar habitat and diet
with the invasive green crab (Bélair and Miron 2009; Matheson and Gagnon 2012a,
b). The former is also an economically and ecologically important species and serves

94 Emma M. DeRoy et al. / NeoBiota 71: 91-112 (2022)

as the primary prey for American lobster (Homarus americanus) (Sainte-Marie and
Chabot 2002).

Only male crabs with all appendages intact were selected to avoid potential
variation in foraging that could result from morphological or behavioural differ-
ences between the sexes (Elner and Hughes 1978; Abello et al. 1994). We also se-
lected only green crab with a green carapace and did not retain those with a slightly
orange or red carapace, which can indicate a stronger and thicker carapace and
potentially stronger chelae (Reid et al. 1997). Lastly, all crabs were hard-shelled to
minimise potential foraging variation that could result from the use of individuals
undergoing moulting.

Mytilus sp. mussel prey (25 + 3 mm) — on which both crab species are known
to feed (Matheson and Gagnon 2012a) — were collected by hand by divers within
Conception Bay, NL. This size of mussels was selected based on previous size selection
experiments with rock and green crabs (Matheson and Gagnon 2012a). Understand-
ing the impact on mussel prey is important, given the threat posed by green crab to
large-scale commercial shell-fisheries (Grosholz et al. 2011), including that of the blue
mussel (Mytilus edulis) (DFO 2011; Pickering and Quijén 2011).

Crabs and mussels were transported in containers with seawater to the Northwest
Atlantic Fisheries Centre in St. John’s, NL. Species were held separately in holding
tanks (275 1) equipped with a flow-through seawater system (11.8 + 1.5 °C) and fed
ad libitum mussels and scallops. The photoperiod (13 h light:11 h dark) was kept con-
stant throughout the experiment. Crabs and mussels were allowed to acclimatise to the
system and monitored at least one week prior to and post use in FR trials.

Rock crabs were significantly larger [carapace width (notch to notch) + SE: rock
crab: 104.3 = 1.57 mm; green crab: 64.2 + 0.62 mm] and heavier (mass: rock crab:
201.4 + 7.55 g; green crab: 82.8 = 2.45 g) than green crab (Wilcoxon rank sum: W =
0, P < 0.0001). Cheliped size, which can be a proxy for crushing strength, for the rock
crab was also larger (22.9 + 0.36 mm) than the green crab crusher cheliped (19.1 +
0.37 mm) (Wilcoxon rank sum: W = 81, P < 0.0001). This difference resulted from the
intentional selection of typical full-sized adult rock and green crabs found in the same
habitats, which further allowed comparisons with other studies that used the same ap-
proach. Use of both invasive and native adult crabs, therefore, permitted us to discern
maximum potential impact of these species.

Salmonids

Experimental trials with invasive brown trout (Salmo trutta) (N = 31: mean + SE
wet weight: 49.4 + 2.1 g) and native Atlantic salmon (Salmo salar) (N = 18: 91.7 +
5.4 g) were conducted at the University of Windsor’s Freshwater Restoration Ecology
Centre (FREC, LaSalle, ON Canada). Brown trout were purchased from Kolapore
Springs Fish Hatchery (Thornbury, ON, Canada) in the summer of 2015 and trans-
ported to FREC in insulated tanks with continuously aerated water. Atlantic salmon

were reared at FREC.

Forecasting ecological impacts of aquatic invasive species 95

We selected brown trout as our focal invader given its cosmopolitan distribution
and long invasion history (Klemetsen et al. 2003). Its ecological impacts span multiple
trophic levels (reviewed in Well et al. 2017) and affect various ecosystem processes
(Townsend and Simon 2006). The species has been deliberately introduced into many
regions, including New Zealand (Townsend and Simon 2006) and sub-Saharan Africa
(Weyl et al. 2017). However, despite brown trout’s ubiquity, impact assessments in in-
vaded habitats are relatively recent (McIntosh et al. 2011). Atlantic salmon was chosen
based on its high niche overlap with our focal invader (Armstrong et al. 2003).

All fish were acclimatised for one week during which time they were fed mealworms
(Tenebrio molitor) ad libitum. Animals were housed in climate-controlled facilities prior
to and during experiments (15—17 °C air temperature; 10 h light: 14 h dark regime). Fish
from individual species were held communally in recirculating housing tanks (800 1; 5%
turnover per day), in accordance with University of Windsor’s Animal Care guidelines.

Experimental trials

Brachyuran crabs

FR trials were run across six circular opaque fibre-glass tanks (275 |; 100 cm diameter
and ~ 50 cm water depth) configured in rows of two. Each tank was set up with its own
individual light source and inflow to standardise environmental conditions (10.25 °C
+ 0.04; ~ 5-10 |/minute flow rate). All tanks were covered with mesh (1.3 cm open-
ing) to prevent potential escape. A random number generator allotted predators and
prey density treatments to individual trial tanks.

Trials were conducted between 7am and 3pm. Individual crabs were selected at
random and held in experimental tanks supplied with flow-through seawater 48 hours
prior to experimental trial to acclimatise and standardise hunger. To initiate a trial,
mussels (free of epibionts) were presented haphazardly throughout the tank at six den-
sities (2, 4, 8, 16, 32 and 64 mussels per tank). Each feeding trial lasted five hours, after
which we examined prey capture, defined as any crab-mussel interaction that resulted
in the crushing or opening the shells of a mussel. We conducted five replicates at each
prey density and one control trial for each prey density in the absence of a predator
to quantify background mortality rates. Each crab was only used once. We excluded
any trial in which the foraging crab moulted in the week following the experiment to
further minimise potential variation in crab behaviour during the feeding trial.

Fisheries and Oceans Canada provided regional abundance estimates (CPUE +
SE) for both green and rock crab in North Harbour, Placentia Bay, NL. An average
multi-year estimate (2015-2019) was used to account for spatiotemporal variability in
population densities. Each yearly estimate was based on 12 traps (four lines of three
traps set perpendicular to the shore in the shallow subtidal) set during each of five
monthly surveys (June through to October). Trapping estimates recorded the number
of crabs obtained per trap per day. The soak time during each deployment was approxi-
mately 24 hours with traps set at low tide.

96 Emma M. DeRoy etal. / NeoBiota 71: 91-112 (2022)

Salmonids

Fish were starved for 24 hours to standardise hunger levels and acclimatised to experi-
mental tanks prior to trial onset. Fish were randomly selected and assigned to one of
two flow-through 50 | trial tanks (Mean + SE: 10.24 °C + 0.16, flow rate: 1 1/ min-
ute) containing aquarium water. Species were alternated between trials. Tanks were
wrapped in black plastic to mitigate observer influences.

To initiate the start of a trial, mealworms (1 cm, cut using a razor) were introduced
to the water surface at one of six prey densities (8, 16, 32, 64, 128 and 175 prey per
tank). Due to limited stock of Atlantic salmon, three repetitions were conducted per
prey density with no re-use. Five replicates were performed per density for brown trout,
with the exception of the prey density of 175, for which six replicates were conducted.
Mealworms were launched via a weigh boat from the same point across trials. In this
regard, they mimicked drifting invertebrates on which salmonids commonly feed (Brid-
cut 2000). Following their addition, predators were left to feed for one hour, after which
they were removed and we counted the number of prey items remaining. Each predator
was only used once. After each trial, we euthanised fish via MS222 (300 mg I') and
recorded their wet weight. We verified the number of prey items consumed via stomach
contents. [he use of dried prey precluded use of control trials for prey mortality.

To compute an estimate of the relative impact for our study species, we procured
abundance estimates for Atlantic salmon and brown trout within the Credit River water-
shed (2015-2019) from Credit Valley Conservation Authority. The Credit River water-
shed is an important system for juvenile salmonids, including Atlantic salmon, of which
both naturally and hatchery-reared individuals are present. Atlantic salmon is native to
this region and is currently the subject of restoration efforts (Dimond and Smitka 2005).
Alongside other non-indigenous salmonids, brown trout has been introduced exten-
sively in this region to meet recreational demand (Stewart and Schaner 2002). Both spe-
cies are subject to stocking (Ontario Ministry of Natural Resources and Forestry 2016).

Abundance data were obtained using single pass electrofishing [see Credit Valley
Conservation Authority (2019) for a detailed overview of their methodology]. Abun-
dance estimates were procured in the summer, several months after stocking. Estimates
were calculated as the number of individual fish divided by stream area (m’).

Statistical analyses

Data analyses were performed in R, version 4.0.2 (R Core Team 2020). Data explora-
tion was performed according to Zuur et al. (2010). We verified the appropriateness of
GLMs by visually inspecting residuals (package DHARMa, Hartig 2020).

Brachyuran crabs

We tested for effects of species (factor, two levels), prey density (factor, six levels)
and their interaction on consumption rate (continuous) using a GLM (glmmTMB,

Forecasting ecological impacts of aquatic invasive species 97

Brooks et al. 2017) with a negative binomial error distribution with default param-
eterisation. Crusher cheliped size (continuous) was included as a covariate in the
GLM to control for its effects. A negative binomial distribution was selected after fit-
ting candidate distributions to consumption data via maximum likelihood estimation
to determine best fit (fitdistrplus, Delignette-Muller and Dutang 2015). We included
a dispersion formula for prey density in the GLM to account for heteroscedasticity.
Candidate models (with or without an interaction term between factors) were as-
sessed based on Akaike’s Information Criterion (AIC) and interpretation of scaled re-
siduals. Model assumptions were verified by plotting residuals versus fitted values and
inspecting residuals for goodness-of-fit patterns. We computed coefficients of the best
fitting model with analysis of deviance Type HI sums of squares, given the presence of
the interaction term (car, Fox and Weisberg 2019). Where a term was significant, we
used Tukey comparisons via estimated marginal means for pairwise testing (emmeans,
Lenth 2020).

We assessed differences in per capita feeding rates via FR curves. We fitted both
Type IJ and IIT FR models to consumption rate data, using maximum likelihood es-
timation (bbmle, Bolker and R Development Core Team 2016) and compared fit via
AIC. To account for prey depletion over the duration of the experiment, we modelled
the resultant Type II FRs using Rogers’ random predator equation (Rogers 1972):

N = N, (exp (a (NA-T))) (Eqn. 1)

where WV is the number of prey eaten, NV, is the initial density of prey, a is attack con-
stant, 4 is handling time and 7’is the total experimental period (5 hours).

Predator consumption rates — as well as consumer-resource interaction variables,
such as search rate, detection distance and handling time on which such rates depend —
often vary with individual mass (Kalinkat et al. 2013). In turn, this may implicate chang-
es in per capita interaction strength between predators and their prey and the resultant
FR. To account for size discrepancies between crabs, FR parameters were allometrically
scaled following Kalinkat et al. (2013). We used a fixed allometric-scaling exponent of
0.65 to account for body mass-metabolic rate scaling in brachyuran crabs (Griffen and
Sipos 2018), such that attack rate scaled positively with predator body mass:

Piet mine (Eqn. 2)
and handling time scaled negatively with predator body mass:
(UR aaa (Eqn. 3)
In both Eqns. 2 and 3, 4, and /, are constants and m is predator mass (g).
We fitted the allometrically-scaled FR models using all data for a given species to

obtain initial parameter estimates for bootstrapping. We then bootstrapped (V = 100)
the data to construct 95% confidence intervals around the fitted curves and extract

98 Emma M. DeRoy et al. / NeoBiota 71: 91-112 (2022)

median values for model parameters. Convergence in FR confidence intervals indi-
cated a lack of significant difference between species’ consumption rates.

We computed FRRs (attack rate a divided by handling time /, i.e. a/h) for each spe-
cies using median attack rate and handling time parameters. ‘The FRR is a novel metric
that has successfully differentiated ecologically-damaging invasive species (Cuthbert et
al. 2019). Higher values indicate greater inferred impact, since high values of a and low
values of / both predict high per capita effects across the FR curve and, hence, across
low and high prey densities (Cuthbert et al. 2019).

Finally, we determined the maximum feeding rate of each predator (1/h) and com-
bined these values with field abundance estimates to derive a Relative Impact Potential
(RIP) estimate according to Dick et al. (2017a):

oe -( FRinvader ( ABinvader
FRnative ABnative

This allowed us to discern the relative impact of introduced green crab to native rock crab.

Salmonids

Using the same methodology as described above, differences in overall prey consump-
tion amongst species (factor, two levels), prey density (factor, six levels) and wet weight
(continuous) were assessed using a GLM with negative binomial error distribution
(gimmTMB, Brooks et al. 2017). As there was no interaction found between the main
factors, interaction terms were removed to identify the most parsimonious model. We
incorporated a dispersion model to account for heteroscedasticity amongst prey densi-
ties and between species. We used Type II analysis of deviance to compute overall ef-
fects of GLMs (car, Fox and Weisberg 2019) and made post-hoc pairwise comparisons
using Tukey’s tests [package emmeans (Lenth 2020)].

FR type was confirmed following the protocol outlined above. We subsequently
incorporated allometric functions in FR models to account for size discrepancies be-
tween salmonids (Kalinkat et al. 2013). On average, metabolic rates in fish conform to
a 0.89 power-law scaling of maximum consumption with predator body mass (Jerde et
al. 2019). Handling time and attack rate parameters were scaled negatively and posi-
tively, respectively, using a fixed allometric exponent of 0.89.

Allometrically-scaled FR models were fitted following the aforementioned meth-
odology to obtain median estimates of attack rate and handling time. We then com-
puted FRRs (a/h) for each species as well as corresponding maximum feeding rates
(1/h). We subsequently used both species’ maximum feeding rates and abundances to
compute the RIP estimate. Stocking effort and abundance were both greater for the
native Atlantic salmon. Given field abundance disparities between our focal salmonid
predators, we projected impact potential of brown trout in increments of 0.01 ind/
m’ to determine the point at which RIP would exceed a value of 1. That is, we de-
termined when brown trout’s projected ecological impact may exceed that of native
Atlantic salmon.

Forecasting ecological impacts of aquatic invasive species 99

Results

Brachyuran crabs

In control trials, we experienced no prey mortality and thus ascribed all prey death
to predation, which was also directly observed. Predator consumption rates were best
described by Type II FRs (Fig. 1).

On average, rock crabs consumed more mussels than green crabs, though the dif-
ference was not significant (Wilcoxon: W = 415, P = 0.61). Analysis of species’ per
capita effects revealed more nuanced differences in consumptive impact. Rock crab
consumed more mussels than green crab, both with and without correcting for size
differences between crab species (Table 1; Suppl. material 1: Table $1). Differences in
consumption rates between species was contingent on prey density (species * prey den-
sity: X* = 29.04, df= 5, P < 0.0001). Rock crabs out-consumed their invasive analogues
at higher prey densities (32 prey: estimate + SE: -0.80 + 0.24, P = 0.002; 64 prey:
-0.44 + 0.25, P = 0.09) (Fig. 1). However, species’ consumption rates were not signifi-
cantly different at low prey densities, as evidenced by overlapping confidence intervals
(Fig. 1). Cheliped size — here used as a proxy for crushing strength — was significantly
and positively associated with consumption rate (X* = 6.28, df = 1, P = 0.01).

Green crab had a higher FRR, reflecting a steeper FR curve at low prey densities
(i.e. larger attack rate, 2) that compensated for a higher handling time (4; and, hence,
lower maximum feeding rate), indicating European green crab will potentially impact
prey populations more than rock crab. Further, green crab abundance (mean + SE:
29.44 + 6.91) was orders of magnitude greater than that of rock crab (0.17 = 0.12),
driving a large RIP value (Table 1, Fig. 2).

NS

—— Green Crab
---- Rock Crab

Ww
a

ey)
oO

24

Prey Consumed (+ 95% Cls)

Prey Density

Figure |. Functional responses of invasive green crab and native rock crab towards mussel prey. Lines
represent initial functional response fits from the random predator equation; shaded areas are 95% conf-

dence intervals (n = 100 non-parametric bootstraps).

100 Emma M. DeRoy et al. / NeoBiota 71: 91-112 (2022)

Table |. Relative Impact Potential (RIP) and Functional Response Ratio (FRR) scores, as well as mean
+ standard error (SE) estimates of maximum feeding rate, recorded for both invasive-native species pairs.

RIP > 1 are predicted to be high impact invaders, those < 1 are low impact relative to native predators.

System Species Maximum feeding rate (/h) (+ SE) RIP FRR (a/h) (+ SE)
Marine Green crab 0.82 (0.01) 71 0.17 (0.01)
Rock crab 2.02 (0.19) 0.12 (0.01)
Freshwater Brown trout 0.48 (0.01) 0.20 0.04 (0.002)
Atlantic salmon 0.41 (0.02) 0.001 (<0.001)
40

e Green crab
™® Rock crab

ie)
©

Abundance(CPUE)
= NO
© i=)

FR (maximum feeding rate)

Figure 2. RIP biplot comparing invasive green crab and rock crab feeding upon native mussel prey. Biplots
generated using mean + standard error (SE) estimates for FRs (allometrically-scaled maximum feeding

rate, prey/5 hour) and field abundances (CPUE). Ecological impact increases from bottom left to top right.
prey g Pp P tig.

These results corroborate two independent Ecological Impact Scores used by Lav-
erty et al. (2015) and Ricciardi and Cohen (2007). Both Scores are ordinal rankings
of impact, where higher scores demonstrate more negative effects. Maximum available
scores for each metric are 5 and 7, respectively. Using the regression equations in Figure
2 of Dick et al. (2017a) — the relationship between actual field impact and RIP value
— we predict green crab to have serious ecological impacts of 4.05 on the Laverty et al.

(2015) scale and 6.05 on the Ricciardi and Cohen (2007) scale.

Salmonids

Both salmonids exhibited Type II FRs (Fig. 3). While Atlantic salmon was significantly
heavier than brown trout (Wilcoxon: W = 528.5, P < 0.0001), the latter, on average,
consumed significantly more prey both in terms of raw consumption and per unit mass
(raw: Wilcoxon: W = 117, P = 0.001; per unit mass: Wilcoxon: W = 74, P < 0.0001).
Consumption rates increased significantly with increasing prey density (X* = 32.40,
df = 5, P < 0.0001) and by predator mass (X’= 16.60, df= 1, P < 0.0001). Brown trout
was more voracious than Atlantic salmon across all levels of prey availability (X* =
46.17, df= 1, P < 0.0001) (Fig. 3). However, consumption rates were not significantly

Forecasting ecological impacts of aquatic invasive species 101

different at the highest two prey densities, as evidenced by overlapping confidence
intervals. The observed FR relationship was unchanged when correcting for size differ-
ences between salmonids (Table 1; Suppl. material 1: Table S1).

Brown trout exhibited a higher maximum feeding rate and FRR relative to At-
lantic salmon (Table 1). However, their lower field abundance dampened the result-

ant RIP (Table 1, Fig. 4). Modelling of projected impact potential suggests that an

re GS
—— Brown Trout
90 4-7-7 Atlantic Salmon

=
Oo
|

co
|

Prey Consumed (+ 95% Cls)
tS NO
| |

25 50 75 100 125 150 175
Prey Density

Figure 3. Functional responses of invasive brown trout and native Atlantic salmon towards dried meal-
worm prey. Lines represent initial functional response fits from the random predator equation; shaded

areas are 95% confidence intervals (n = 100 non-parametric bootstraps).

0.1

Brown trout “sy Sy

*
“ Brown trout (x2) mae :
“ Brown trout (x3) |. % a5
_| © Brown trout (x4) |
fl 007) a Brown trout (x5) Se
“s 4“ Brown trout (x6) a
3 © Atlantic salmon RIP = 1.17.
= 7 io °e he we
g 0.05). : | d& RIP = 0.98
c ae ~
g A RIP = 0.78
= os SN
5 \
a A RIP = 0.59 |

0.0254 : id co
% i RIP = 0.39

— q RG
® \RIP = 0.20

0 0.2 0.4 0.6 0.8

FR (maximum feeding rate)

Figure 4. RIP biplot comparing invasive brown trout and Atlantic salmon feeding upon mealworm prey.
Biplots generated using mean + standard error (SE) estimates for FRs (allometrically-scaled maximum feed-
ing rate, prey/hour) and field abundances (ind/m*). Ecological impact increases from bottom left to top right.

102 Emma M. DeRoy etal. / NeoBiota 71: 91-112 (2022)

abundance of 0.06 ind/m?— equivalent to that of Atlantic salmon — would be required
to increase the RIP to a level where brown trout would exert a greater impact than

Atlantic salmon (Fig. 4).

Discussion

Understanding differences in resource consumption by invasive and native species can
provide meaningful insights into potential impacts of invaders in colonised ranges
(Dick et al. 2014). When combined with an invasive species’ abundance, meaningful
understanding of expected ecological impacts may become apparent (Dick et al. 2017;
Ricciardi et al. 2021). Here, we examined per capita effects of two notorious invasive
species using functional response (FR) methodology and the new Functional Response
Ratio (FRR) and, subsequently, examined how these effects were modified by each
species abundance using the Relative Impact Potential (RIP). This combined experi-
mental approach links per capita feeding rate with field abundance to provide best
estimates of invader impact relative to comparable native species (Dick et al. 2017a;
DeRoy et al. 2020).

Our study highlights strong density-dependence of both per capita and total es-
timated population effects. All species demonstrated inverse density-dependent prey
mortality and potentially destabilising Type II FRs for prey populations. While inva-
sive species often exhibit higher FR curves relative to functionally analogous native
species (Dick et al. 2014), we observed mixed results. FR results suggested a strong
per capita effect by brown trout and a much more muted one by green crabs, relative
to their native analogues. However, the FRR metric, which blends the parameters of
attack rate (a) and handling time (/), was a good predictor of both invasive species hav-
ing high impact on native prey compared to that of native predators (see Cuthbert et
al. 2019). Relative impact incorporating species’ numerical responses better captured
the full potential of each invader and suggested dominant impacts overall by each of
green crab and Atlantic salmon. We expect differences in projected impact reported
herein to correlate with field ecological impacts, as corroborated by past research (Dick
et al. 2014; Dick et al. 2017a).

Invasive species’ impacts are often context-dependent, in part mediated by abun-
dance (but also per capita differences; see Howard et al. 2018). Reported abundance of
green crab in Placentia Bay exceeds that of the species elsewhere in the Canada’s eastern
provinces (DFO 2011) as well as in western United States and Canada (Yamada et al.
2020; Ens et al. 2021). Such differences may portend dissimilar ecological impacts.
Their high population abundance also highlights potential commercial impacts on
bivalve and lobster fisheries. Aquaculture is a growing economic driver for many lo-
cations, such as the Atlantic Canadian region, which is highly dependent on eastern
oyster (Crassostrea virginica) production (Bernier et al. 2020). Actual and potential
fisheries impacts of green crab have been well-documented throughout their invaded
range (Yamada 2001; Matheson and McKenzie 2014; Rayner and McGaw 2019),

Forecasting ecological impacts of aquatic invasive species 103

with economic losses projected to increase with their range expansion (Grosholz et al.
2011). Such inter-regional differences in ecological and economic impact of green crab
need further exploration globally.

The high attack rate of green crab at low prey densities can potentially drive mutual
prey species to become increasingly rare or even extinct (Dick et al. 2014) (Fig. 1).
These impacts on native prey populations could have negative spill-over implications
for native rock crab. Green crab’s abundance, in conjunction with their high attack
rate, could exclude rock crab from preferred resources like mussels. However, species’
prey consumption suggests that rock crab could co-exist with green crab in areas where
the latter is present at low abundance or when prey abundance is sufficiently high. As
a result, where green crab numbers are high, species’ co-existence could be facilitated
by numerical control of the invader. However, traditional population suppression is
complicated by the life history of green crabs, which demonstrate the potential for
density-dependent, stage-specific overcompensation (Grosholz et al. 2021). That is,
eradication efforts targeting adult green crabs may inadvertently facilitate enhanced
survival and growth of juveniles released from cannibalism (Grosholz et al. 2021). To
protect against such a scenario, functional eradication — suppressing populations below
the threshold that would cause significant ecological harm and a positive numerical
response by juveniles — may prove viable (Green and Grosholz 2021). Findings, pre-
sented herein, may provide a useful starting point to understand the species’ non-linear
population dynamics, on which the aforementioned management strategy is based.

Analysis of freshwater salmonids revealed greater levels of consumption by brown
trout across all levels of prey availability, despite their smaller size. These findings are
consistent with FRs of other high impact invasive species (Dick et al. 2014) and are in
accordance with strong negative effects of brown trout in invaded systems (reviewed in
McIntosh et al. 2011). Effects of brown trout may be most significant under resource
limitation owing to their high FR and heightened attack rate at low prey densities.

Field abundance provides an estimate or proxy of predator numerical response
(Dickey et al. 2020a and 2021) and, when combined with FR data, extends predic-
tive understanding of ecological impacts substantially (Dick et al. 2017a). Widespread
stocking of brown trout has traditionally supported its range expansion, often at the
expense of native fishes (McKenna Jr et al. 2013). Despite high reported abundances
of brown trout throughout its introduced range (for example, in excess of 1 ind/m’,
McIntosh et al. 2011) — which frequently exceeds that of sympatric natives (Jones and
Closs 2011; Al-Chokhachy et al. 2016) — native Atlantic salmon is purported to have a
greater ecological impact on prey within the sampled watershed as a consequence of its
high relative abundance (Fig. 4). These disparities in abundance are similar elsewhere
regionally where the species are sympatric (Larocque et al. 2020).

Abundance discrepancies may dampen the potential for interspecific competition
and produce limited, but strong interactions between the two species, as evidenced
by their overlapping isotopic niches (Larocque et al. 2020). Furthermore, resource
partitioning between Atlantic salmon and resident fish appears to reduce trophic inter-
actions (Larocque et al. 2020), which may further species’ co-existence. These results

104 Emma M. DeRoy et al. / NeoBiota 71: 91-112 (2022)

support the need to disentangle density-mediated effects from per capita effects to bet-
ter understand the processes driving impacts of individual invasive species.

The current risk of brown trout appears low, based on analyses of population-level
impact. However, numerical estimates of abundance, as reported herein, may not rep-
resent abundances of the focal species in other systems. It is possible that brown trout
impact could be far more substantial in areas where the numerical difference between
these species is lower (and in systems without external manipulation), as corroborated
by our model (Fig. 4).

Our findings have important implications. If left unchecked, they suggest that
burgeoning brown trout populations are likely to produce significant ecological im-
pacts, potentially to the detriment of both native Atlantic salmon and prey popu-
lations. Despite the invader’s high per capita effect, management interventions can
suppress its potential population-level impact on recipient systems by keeping relative
densities low. Sustaining native species’ populations while ensuring productive fisher-
ies — like that of brown trout — therefore depends on balanced management (Dettmers
et al. 2012). It also suggests a need to reconcile the paradox of brown trout as both an
important sport fish and a detrimental invader (Cowx et al. 2010).

Future research

Future research should consider the ecological impact of our focal species across a
wider variety of prey types in field and laboratory settings. A growing body of literature
reinforces the resource-specific nature of invasive species’ per capita effects (e.g. Chu-
choll and Chucholl 2021). We encourage subsequent studies to consider ecological
impact under varying prey and resource identities to gain a more complete picture of
predator-resource dynamics, as differences or similarities in prey preference and related
competitive interactions can have cascading influences on overall ecological patterns
and impacts.

Additionally, investigation into non-consumptive effects of both green crab and
brown trout are needed to ascertain implications for native predators and ultimately
consequences to prey. For example, habitat use and depth distribution overlap in shal-
low waters in areas where our focal crab species co-occur (Tremblay et al. 2005; Mathe-
son and Gagnon 201 2a). Green crabs are also highly agonistic and territorially compet-
itive, often outcompeting other crustaceans in foraging and shelter contests (McDon-
ald et al. 2001; MacDonald et al. 2007; but see Jensen et al. 2002). These factors may
lead to exploitative and/or interference competition for food or habitat, which may in-
crease as green crab become more numerically dominant. Similarly, brown trout often
occupy preferred foraging positions which provide preferential access to food (Alanara
et al. 2001). Brown trout is also a better competitor relative to Atlantic salmon (Van
Zwol et al. 2012) and exhibits higher levels of aggression (Scott et al. 2005; Van Zwol
et al. 2012; Houde et al. 2015). These traits may hinder the growth, survival and con-
sumption rates of native species like Atlantic salmon (Van Zwol et al. 2012; Houde et
al. 2015). In turn, interactions between invasive and native predators may ultimately
influence each predator's per capita effects on prey populations. Whether these effects

Forecasting ecological impacts of aquatic invasive species 105

have the potential to subsequently mediate ecological impact remains unclear — and is
beyond the scope of this study — but demands further investigation.

Understanding the synergistic influence of co-occurring stressors on invasive species’
impacts is a priority area for invasion science (Ricciardi et al. 2021). Future changes in
environmental parameters, such as temperature and salinity, have the potential to medi-
ate feeding behaviour (Iacarella et al. 2015; Dickey et al. 2020b), as well as prey availabil-
ity, and should be incorporated into subsequent impact predictions. This area of research
is particularly important for aquatic invasive species, for which research investigating the
combined influence of temperature and salinity regimes is scant (Cuthbert and Briski
2021). Physiological tolerances of our focal invasive predators portend increased impacts
in light of a changing climate. Green crabs have broad physiological tolerance (Simonik
and Henry 2014) and predation rates are positively correlated with temperature (Mathe-
son and Gagnon 201 2a, b). Increases in water temperature are similarly likely to favour
brown trout at the expense of native salmonids (Al-Chokhachy et al. 2016; Hoxmeier
and Dieterman 2019). The potential for variations and potentially higher impact under
climate change thus warrants additional studies across taxonomic groups.

Conclusions

Functional and numerical response methodology provides meaningful insights into
assessing invader impact and has become especially robust when used in conjunction
with the FRR and RIP metrics. These results imply that, if the per capita impacts and
relative abundance of non-indigenous species are well-known, its potential relative im-
pact can be predicted and appropriate management actions devised, if needed. Our
findings further underscore the importance of population suppression to effectively
manage invasive species and promote co-existence with native analogues and prey
populations. While our results provide novel insights into the implications of our focal
predators, further work is required that incorporates environmental change scenarios.

Acknowledgements

This work was supported by a Natural Sciences and Engineering Research Council of
Canada Discovery Grant and a Canada Research Chair in Aquatic Invasive Species to
H.J.M and the Fisheries and Oceans Canada Aquatic Invasive Species Science Program
(NL Region) to C.H.M. Experiments were conducted and animals were handled in
accordance with the CCAC and the University of Windsor’s Animal Care Committee.
The authors thank Dr. Trevor Pitcher for use of FREC facilities. Rock and green crab
were procured under a DFO scientific collection licence. The authors thank the fol-
lowing individuals for their assistance in crab collections and laboratory experiments:
Terri Wells, Vanessa Reid and Haley Lambert. The authors thank Drs. James Dickey
and Ross Cuthbert for their modelling assistance. Abundance data for Lake Ontario
were used with permission of Credit Valley Conservation Authority (2020).

106 Emma M. DeRoy et al. / NeoBiota 71: 91-112 (2022)

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Supplementary material |

Table S1

Authors: Emma M. DeRoy, Steven Crookes, Kyle Matheson, Ryan Scott, Cynthia H.

McKenzie, Mhairi E. Alexander, Jaimie T-A. Dick, Hugh J. Maclsaac

Data type: docx file

Explanation note: Unscaled mean + standard error (SE) estimates of maximum feed-
ing rate and Functional Response Ratio (FRR) scores, recorded for both invasive-
native species pairs.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/neobiota.71.75711.suppl1