Research Article

Journal of Orthoptera Research 2021, 30(2): 163-172

Establishing the nutritional landscape and macronuirient preferences of a
major United States rangeland pest, Melanoplus sanguinipes, in field and

lab populations

DEANNA ZEMBRZUSKI', DEREK A. WOLLER2, LARRY JECH*?, LONNIE R. BLACK, K. CHRIS REUTER4, RICK OVERSON!4,

ARIANNE CEASE!*

1 School of Life Sciences, Arizona State University, Tempe, AZ, USA.

2 USDA APHIS PPQ Science & Technology Insect Management and Molecular Diagnostics Laboratory (Phoenix), Phoenix, AZ, USA.

3 Tempe, USA.

4 School of Sustainability, Arizona State University, Tempe, AZ, USA.

Corresponding author: Deanna Zembrzuski (dzembrzu@asu.edu)

Academic editor: Ludivina Barrientos-Lozano | Received 8 December 2020 | Accepted 31 August 2021 | Published 14 December 2021

http://zoobank.org/911 9B055-463 7-4E55-9DE1-8CB7BEAA047E

Citation: Zembrzuski D, Woller DA, Jech L, Black LR, Reuter KC, Overson R, Cease A (2021) Establishing the nutritional landscape and macronutrient
preferences of a major United States rangeland pest, Melanoplus sanguinipes, in field and lab populations. Journal of Orthoptera Research 30(2): 163-

172. https://doi.org/10.3897/jor.30.61605

Abstract

When given a choice, most animals will self-select an optimal blend
of nutrients that maximizes growth and reproduction (termed “intake
target” or IT). For example, several grasshopper and locust species se-
lect a carbohydrate-biased IT, consuming up to double the amount of
carbohydrate relative to protein, thereby increasing growth, survival,
and migratory capacity. ITs are not static, and there is some evidence
they can change through ontogeny, with activity, and in response to
environmental factors. However, little research has investigated how
these factors influence the relative need for different nutrients and how
subsequent shifts in ITs affect the capacity of animals to acquire an op-
timal diet in nature. In this study, we determined the ITs of 5" instar
(final juvenile stage) Melanoplus sanguinipes (Fabricius, 1798), a preva-
lent crop and rangeland grasshopper pest in the United States, using
two wild populations and one lab colony. We simultaneously collected
host plants to determine the nutritional landscapes available to the
wild populations and measured the performance of the lab colony on
restricted diets. Overall, we found that the diet of the wild populations
was more carbohydrate-biased than their lab counterparts, as has been
found in other grasshopper species, and that their ITs closely matched
their nutritional landscape. However, we also found that M. sanguinipes
had the lowest performance metrics when feeding on the highest car-
bohydrate diets, whereas more balanced diets or protein-rich diets had
higher performance metrics. This research may open avenues for study-
ing how management strategies coincide with nutritional physiology to
develop low-dose treatments specific to the nutritional landscape for
the pest of interest.

Keywords

geometric framework, macronutrient preference, nutritional ecology, nu-
tritional landscape, plant-insect interactions, rangeland grasshopper

Introduction

Rangelands in the western United States are important agri-
cultural and environmental resources, serving not only as grazing
lands for livestock, but also as habitats for wildlife (Havstad et
al. 2007). While the U.S. has not been home to a locust species
since the 1870s [the extinct Rocky Mountain locust, Melanoplus
spretus (Walsh, 1866) (Tt), originally described within Calopte-
nus by Walsh in 1866, see Lockwood 2004], the rangelands are
sometimes plagued by large grasshopper outbreaks (Capinera
and Sechrist 1982, Joern and Gaines 1990, Schell and Lockwood
1997). Grasshoppers represent a significant problem for ranchers
and farmers across the United States, but especially in the western
rangelands (Hewitt and Onsager 1983). Grasshopper outbreaks
can represent a significant economic hardship to ranchers, with
conservative estimates placing the economic damage of grasshop-
pers at $393 million in rangeland forage lost annually (Hewitt
and Onsager 1983). There is support for the use of fungal manage-
ment for rangeland grasshoppers (Streett 1996-2000, Bidochka
and Roberts 2000, Branson et al. 2006), and nutritional ecology
can be helpful when applying these management strategies. How-
ever, few studies have bridged lab and field research to understand
how the nutritional requirements of grasshoppers relate to the
host plants available to them in the field.

In rangelands, the migratory grasshopper M. sanguinipes (Fab-
ricius) is the most destructive grasshopper, causing more forage
loss than any other grasshopper species in the United States (Pfadt
2002). This grasshopper is not exceptionally large, with a body
length of approximately 16-23 mm for 5" instars, 20-26 mm
for adult males, and 20-29 mm for adult females (Pfadt 2002).

JOURNAL OF ORTHOPTERA RESEARCH 2021, 30(2)

164

Management of this species is particularly challenging because
populations that emerge in rangelands can then migrate to crop-
lands miles away. Due to their mixed (grasses and forbs) feeding
behavior, they will consume vegetables in addition to cereal crops
and grasses (Pfadt 2002, Murray 2016). Indeed, as described in
COPR (1982), this species is “decidedly ambivorous” and will
“devour and thrive on almost any available plant,” including
plants from grasslands and crops to hedge mustard and moss. This
grasshopper is especially problematic because of its large outbreak
potential, with outbreak populations able to reach 80 individuals/
yd? (Murray 2016). Due to its economic impact, M. sanguinipes
has often been the subject of population management research
(Pickford and Mukerji 1974, Hewitt 1977, Hewitt and Onsager
1983, Pfadt 2002), as well as nutritional and life history studies
(Behmer and Joern 2008, Fielding and Defoliart 2008). However,
there is still much unknown about this major rangeland pest spe-
cies’ nutrient preferences in field populations and how those com-
pare with long-term lab colonies.

When given a choice, most animals will self-select the blend of
nutrients that maximizes growth and reproduction (termed “in-
take target” or IT), which arises from the Geometric Framework for
Nutrition, or GFN (Raubenheimer and Simpson 1997, Raubenhe-
imer et al. 2009, Simpson and Raubenheimer 2012). GFN research
spans many taxa and has demonstrated that numerous insect pop-
ulations, particularly lab colonies, exhibit a consistent IT. For ex-
ample, Plutella xylostella (Linnaeus, 1758) caterpillars select a ma-
cronutrient ratio similar to ancestral colony conditions (3.25 mg
protein: 3.00 mg carbohydrates), and that ratio corresponds with
a narrow and high peak in performance (Warbrick-Smith et al.
2009). Several migratory grasshopper and locust species select a
carbohydrate-biased IT, consuming up to double the amount of
carbohydrate relative to protein, which increases growth, survival,
and migratory capacity (Behmer and Joern 2008, Cease et al. 2012,
2017, Le Gall et al. 2019, Le Gall et al. 2020a, b, Talal et al. 2020).

ITs are dynamic, and there is some evidence they can shift
through ontogeny, with activity, and in response to environmental
factors (Raubenheimer and Simpson 1997, Simpson and Rauben-
heimer 2012, Lawton et al. 2020). There is also evidence that meet-
ing an IT not only maximizes growth performance under optimal
conditions, but also aids in survival when faced with toxins and
pathogens. Helicoverpa armiger (Hiibner, 1808) and Helicoverpa
punctigera (Wallengren, 1860) caterpillars fed on diets that match
their IT have lower susceptibility to several Bt toxins (Tessnow et al.
2018). Chortoicetes terminifera (Walker, 1870), the Australian plague
locust, adjusts its IT when faced with a pathogen challenge, and the
adjusted IT reduces the grasshopper’s susceptibility to the pathogen
(Graham et al. 2014). Given how important external factors are on
ITs, little research has investigated how these factors influence the
relative need for different nutrients and how subsequent shifts in ITs
affect the capacity of animals to acquire an optimal diet in nature.

The GFN has been used to analyze long-term and first-genera-
tion lab colonies of M. sanguinipes. For example, one lab study on
5" instar first-generation lab-reared grasshoppers collected from
Arapaho Prairie (Arthur Co., Nebraska) showed that M. sanguinipes
had a 1:0.96 preferred dietary ratio of protein to carbohydrate (p:c)
(Behmer and Joern 2008). Results from another study on two 2"
generation lab populations of grasshoppers from Alaska (1p:0.90c)
and Idaho (1p:0.95c) suggested that the ITs of both populations re-
mained similar, though the Alaska population regulated more tight-
ly than the Idaho grasshoppers (Fielding and Defoliart 2008). How-
ever, no studies have examined macronutrient preferences of M.
sanguinipes collected directly from field populations. Understanding

D. ZEMBRZUSKI, D.A. WOLLER, L. JECH, L.R. BLACK, K.C. REUTER, R. OVERSON AND A. CEASE

how an organism's nutritional requirements compare to their habi-
tat's macronutrient composition can aid in developing manage-
ment strategies based on nutrition (e.g., Cease et al. 2015, Le Gall
and Tooker 2017, Word et al. 2019, Le Gall et al. 2020a).

The primary goals of this study were to 1) compare the IT of
two field populations of M. sanguinipes to their given nutritional
landscape, 2) compare the IT of these two field populations to the
IT of a long-term lab colony, and 3) determine if the lab colony
IT maximized performance by restricting grasshoppers to one of
five diets varying in p:c ratio. Our null prediction was that a given
field population of grasshoppers would have an IT that roughly
matched the protein and carbohydrate ratios of plants available to
them. We predicted that, relative to the long-term lab colony, the
field populations would be more carbohydrate-biased, similar to
other field populations of migratory acridids (Cease et al. 2012,
Le Gall et al. 2020b, Lawton et al. 2021), perhaps due to increased
activity or stressors. Finally, we hypothesized that grasshoppers se-
lect a diet that provides optimal performance and, thus, predicted
that the p:c ratio of the diet on which the lab colony performed
the best in restricted diet experiments would be similar to the lab
colony IT.

Methods
Field population studies

Studied species and studied area.—M. sanguinipes is an abundant
rangeland grasshopper with a range that extends throughout most
of the United States and into Canada (Pfadt 2002, Otte 2013). This
grasshopper has 5-6 nymphal instars, and nymphal development
takes 35-55 days. The 5" instar is easily recognized by the wing
buds shifting from small buds on the side to larger buds along
the dorsal side of the grasshopper (Pfadt 2002). We consulted with
USDA surveyors in Idaho to determine locations with sufficient
populations of M. sanguinipes for this study. Based on their surveys,
we selected two locations. Location 1 was a 3.9 ha plot of Bureau
of Land Management (BLM) cattle grazing land in Bliss, Idaho (see
Table 1 and Suppl. material 1: Fig. S6 for specific locations) and
was mostly dry rangeland with forbs, some light woody vegetation,
and an abundance of grasses. Location 2 was a 1.2 ha plot of pri-
vate non-grazed property in Boise, Idaho (see Table 1 and Suppl.
material 1: Fig. S7 for specific locations). The vegetation was not
irrigated and had a similar plant community composition to Bliss.
Grasshoppers were collected from the field in 2018 on June 26 for
Bliss and July 2 for Boise.

Plant collection.—We sampled plants from each location concur-
rent with the sampling of grasshoppers. We randomly selected five
collection plots per site using a random number generator. Plots
were 5 m x 5 m, and we mapped the plots for each location using
Google Maps (2021a, b) (Suppl. material 1: Figs S6-S7). In each
plot, we visually estimated the percent ground cover at ground
level for grasses, forbs, and shrubs using the relevé method (Poore
1955, Minnesota Department of Natural Resources 2013). We
measured humidity, wind speed, and temperature at each plot
with a digital anmemometer (Ambient weather WM-4). To broadly
assess the nutrient contents of the plots, we collected living leaf
material (the part generally eaten by grasshoppers) eaten by the
most abundant species from each functional group. Some plant
species were completely dead in a plot and were not collected.
Plants were stored in paper bags, air-dried for three days, and then
further dried for another 24 hours in a 60°C oven.

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D. ZEMBRZUSKI, D.A. WOLLER, L. JECH, L.R. BLACK, K.C. REUTER, R. OVERSON AND A. CEASE

Grasshopper collection.—We collected grasshoppers throughout the
field locations using sweep nets. All specimens were identified
to species by KCR, who has over 40 years of experience with the
identification of rangeland grasshopper species. We recorded the
sex and developmental stage of grasshoppers upon capture, and
early 5" (final) instar grasshoppers were kept for the experiment.
We separated grasshoppers by sex and kept them in separate cages
with a selection of plants wrapped in wet paper towels from the
collection site for 24 hours prior to starting experiments. All col-
lected specimens were then brought to a private ranch southeast of
Boise for the experiments.

Intake targets. —We started IT experiments for field populations on
June 27 for Bliss and July 3 for Boise. To determine self-selected
ITs, we used a restricted diet choice experiment that gave grass-
hoppers a choice between two complementary diets. We had two
treatment groups where one diet was kept constant between the
two treatments and the other diet had a variation in the protein
and carbohydrate ratio so we could ensure the ITs were not a re-
sult of random eating. Twelve male and 12 female grasshoppers
were placed into each treatment group for a total of 48 grasshop-
pers from each population. Both treatments received two comple-
mentary (high protein (p): low carbohydrate (c) and low p: high
c) isocaloric diets. By percentage of dry mass, Treatment A con-
tained 7p:35c and 28p:14c, while Treatment B contained 7p:35c
and 35p:7c. We selected these two different diet pairings so we
could determine if grasshoppers were regulating to a specific p:c
ratio; if so, grasshoppers from both treatment A and B would end
up selecting the same p:c ratio, regardless of their diet pairings.
This range of dietary p:c pairings encompassed all but a couple of
the most carbohydrate-biased plants, meaning that grasshoppers
could reach the same IT on the artificial diets as they could eating
field plants. Diets were made based on Dadd (1961) and as modi-
fied by Simpson and Abisgold (1985). The protein was a 3:1:1
mix of casein, peptone, and albumen; the digestible carbohydrate
(hereafter, carbohydrates) was a 1:1 mix of sucrose and dextrin.
All diets contained similar amounts of Wesson’s salt (2.4%), cho-
lesterol (0.5%), linoleic acid (0.5%), ascorbic acid (0.3%), and
vitamin mix (0.2%).

At the start of the experiments, we weighed the grasshop-
pers and placed them into individual plastic cages (17.5 x 11.8
x 4.3 cm), perforated for airflow and with a water tube and the
two diet dishes. Five extra cages without grasshoppers were set up
containing a dish of each of the three diets and a water tube to
record water mass gained by the diet during the experiment. The
grasshoppers were in their treatment for 48 hours in Bliss (ended
early due to high mortality) and 72 hours in Boise. We checked
the cages daily and recorded any mortality or molting, and ad-
ditional water was added as needed. Grasshoppers that died dur-
ing the experiment were not included in our final analyses. At the
conclusion of the experiment, we recorded grasshopper mass. We
weighed the diet dishes before and after the experiment and calcu-
lated the amount of protein and carbohydrate consumed by each
grasshopper, accounting for any water mass gain in the diets by
adjusting the initial weights of the diets based on the average pro-
portion change found in the diets kept in the extra five cages.

We recorded temperature and relative humidity in the cages
using iButtons (Thermochron, Maxim Integrated). Cages were
kept inside a garage on, approximately, a 15h/9h light/dark cy-
cle directly correlating to the natural light/dark cycle at the time
and at ambient shade temperature. For the Bliss experiments, the
average daytime (6:10 am-9:30 pm) temperature and humidity

165

+/- SEM were 24.18 +/- 0.26°C and 27.18% +/- 0.53% and average
nighttime (9:31 pm-6:09 am) values were 24.50 +/- 0.21°C and
27.64% +/- 0.40%. For the Boise experiments, daytime averages
were 25.87 +/- 0.22°C and 22.94% +/- 0.43%; nighttime averages
were 24.86 +/- 0.22°C and 28.37% +/- 0.66%.

Chemical analyses.—For each vegetation survey 5 m x 5 m plot,
we mixed leaves from plants of the same functional group (grass-
es and forbs) together and ground them into a fine powder us-
ing a ball mill (30 s at 30 Hz using a Retsch MM 400 ball mill)
for a total of 5 samples per functional group per field site. The
carbohydrate content of each sample was determined using the
phenol-sulfuric acid carbohydrate assay (DuBois et al. 1956), and
the protein content was determined using the Bradford protein
assay (Bradford 1976). Shrubs were excluded from the analyses, as
they do not typically make up the natural diet of this grasshopper
(Pfadt 2002).

Lab studies

Lab colony.—The Arizona State University M. sanguinipes lab col-
ony used in these experiments originally came from eggs from a
USDA ARS lab colony based in Sidney, MT. The USDA colony was
established in approximately 1970 from non-diapausing M. san-
guinipes from Arizona and maintained as such over the decades
mostly on an artificial diet, supplemented with head lettuce. Be-
tween 2000 and 2005, the colony was hybridized with individuals
from the Agriculture Agrifood colony in Saskatoon, Canada. In
approximately 2005 and 2013, genetic material was added to the
colony by mating with field-collected female non-diapausing M.
sanguinipes collected from Arizona. Starting in 2017, the colony
was moved to Arizona State University with funding from the
USDA's nearby Science and Technology Phoenix Laboratory for
the purpose of local lab experiments. The colony has been kept
at 32.2°C during the day and 25°C at night, and the humidity
fluctuates from 20-50% RH with a 14h:10h light/dark cycle. The
colony is reared on a combination of organic romaine lettuce,
wheatgrass, and wheat bran. Overall, the lab colony had access
to a wide range of protein and carbohydrates: two food sources
were carbohydrate-biased and the third was protein-biased. The
mature wheat grass available to the colony was analyzed using a
phenol-sulfuric acid carbohydrate assay (DuBois et al. 1956), and
the protein content was determined using the Bradford protein
assay (Bradford 1976) and found to be 27.62% + 6.467 protein
(Mean % + SEM) and 14.24% + 1.78 carbohydrate (Brosemann
et al. unpubl. data). Reviews of USDA databases show that the
romaine lettuce is approximately 1.24% protein and 3.24% carbo-
hydrate, and the wheat bran is approximately 15.6% protein and
64.5% carbohydrate (FoodData Central 2021b).

Self-selected IT and performance curves.—We determined the self-
selected IT and performance of the lab colony using choice and
no-choice diet experiments split into three consecutive blocks us-
ing three consecutive cohorts of fifth instar nymphs. Each block
contained all treatment groups for the choice and no-choice exper-
iments, with eight grasshoppers per treatment group (four males
and four females) for a total of 56 grasshoppers in each block anda
total of 168 grasshoppers for the full experiment (24 grasshoppers
in each treatment). Grasshoppers were removed from colony cages
during the 4" instar stage and provided the same food from the
colony cages until they molted into 5" instars. On the first day of
the 5" (final) instar, grasshoppers were placed into the experiment.

JOURNAL OF ORTHOPTERA RESEARCH 2021, 30(2)

166

The experiments were run in an environmental chamber kept at
32.2°C during the day and 25°C at night, and the humidity fluctu-
ated from 20-50% RH with a 14h:10h light/dark cycle.

For the lab choice diet experiments, we had two treatments:
Treatment A: 7p:35c and 28p:14c, and Treatment B: 7p:35c and
35p:7c. For the lab no-choice diet experiments, we restricted in-
dividual grasshoppers to one of the five isocaloric diets (7p:35c,
14p:28c, 21p:21c, 28p:14c, and 35p:7c). We weighed grasshoppers
and placed them in individual perforated plastic cages (18.891 cm
x 13.494 cm x 9.525 cm) with a similar set-up to that used to
measure the field population IT. The rest of the methods are iden-
tical to the field population IT, with the exception that the experi-
ments ran for 14 days, and food was changed every 3 days.

For the performance analyses, the specific growth rate (1)
was calculated for each grasshopper using the following formula:
= In (M,/M,)/dt, where M, is the initial mass of the grasshopper,
M, is the final mass of the grasshopper, and dt is the days between
weight measurements. Total days survived and total days spent in
the 5" instar prior to molting to an adult were calculated. The
proportion of grasshoppers surviving or molted was calculated for
each day of the experiment.

Statistical analyses. —We tested all data for assumptions of normal-
ity and homoscedasticity implicit in parametric tests. We trans-
formed any of the data that did not meet these requirements prior
to analyses, or non-parametric analyses were used. Outliers were
removed from the analyses. We performed analyses for ITs using
IBM SPSS Statistics 24 (2017), with all other analyses performed
using R 3.5.1 (2020). To determine IT differences among differ-
ent populations, we used generalized additive models to detect
nonlinear trends as discussed by Lawton et al. (2021), which ulti-
mately resulted in a generalized linear model (family: multivariate
normal distribution, link: identity).

Results
Field population studies

Plant collection.—The Bliss location was primarily composed of
dead vegetation cover, with some live vegetation in each sam-
ple plot. The average percent ground covered by dead and living
grasses was 57.4 + 12.137 (Mean % + SD), the average percent
ground covered by dead and living forbs was 0.6 + 0.548, and
2-15% ground covered by dead and living shrubs when shrubs
were present (Table 1). The Boise location consisted of more live

D. ZEMBRZUSKI, D.A. WOLLER, L. JECH, L.R. BLACK, K.C. REUTER, R. OVERSON AND A. CEASE

vegetation than the Bliss location. The average percent ground cov-
ered by dead and living grass was 39 + 12.942, the average percent
ground covered by dead and living forbs was 25 + 11.726 (Mean
% + SD), and there were no shrubs present at this site (Table 1).

Intake targets.—Both field populations (Bliss and Boise, ID) of
grasshoppers ate non-randomly from the two diet dishes. There
was a significant interactive effect of sex and treatment on carbo-
hydrate and protein consumption for the Bliss population, but no
significant effect on the Boise population. The Boise, population
tended to regulate its IT more tightly (Fig. 1, Table 2). The ITs of
both field populations were carbohydrate-biased, with popula-
tion 1 consuming 1p:3.5c and population 2 consuming 1p:2.1c
(Fig. 2A, B).

160 » 45p:159c
Bliss, ID
P20
@ Bliss, ID
£80 a, 77p:83¢ Hee ID
ge Lab Colony Lab Colony
8 + Standard
© Error (SE)
ee 4 16p:33c
Boise, ID

0 40 80
Protein (mg)

120 160

Fig. 1. Field populations and lab population ITs. Average intake
target (+/- SEM) for two field populations, Bliss and Boise, ID, and
the lab colony. The dashed line represents a 1:1 ratio of protein
and carbohydrates, and the crosses on the data points represent SE.

Chemical analyses.—The macronutrient ratios of the sampled
plants in the Bliss and Boise locations were close to the self-select-
ed ITs for both populations, as indicated by the small Euclidean
distances between the sampled plants’ p:c ratio and the IT (Aver-
age Euclidean distances of combined plants + SE: Population 1
= 0.021 + 0.006; Population 2 = 0.010 + 0.002). Using a Wilcox
rank-sum test, we found there was no significant difference in
the average Euclidean distances, calculated between the sampled

Table 1. Field sites. Habitat and environmental data from field plots in Idaho (see Suppl. material 1: Figs S6-S17 for maps and habitat

plots). Plot location coordinates are based on WGS84.

RH Wind Live

Grasses % Forbs % Shrubs %

Ground ground = ground

Total Rock Litter Dung

Time . : Temp
Plot Date Latitude, Longitude

(PM) "°C %&%
Bliss, ID 1-1 26-Jun 12:00 42.981492, -114.9288965 26.1 26.1
Bliss, ID 1-2 26-Jun 12:25 42.9813708, -114.929146 26.3 22.9
Bliss, ID 1-3 26-Jun 12:50 42.9814282, -114.9310661 27.1 18.8
Bliss, ID 1-4 26-Jun 1:05 42,.9811249, -114.9307657 28.5 18.1
Bliss, ID 1-5 26-Jun 1:30 42.9799997, -114.9294353 28 17.8
Boise, ID 2-1 2-Jul 1:00 43.3943539, -115.9510955 22.7 28.7
Boise, ID 2-2 2-Jul 1:20 43.394394, -115.9512032 24 28.6
Boise, ID 2-3 2-Jul 1:40 43.3944951, -115.9512009 23.5 28.7
Boise, ID 2-4 2-Jul 2:00 43.3946555, -115.9525402 23.4 26.7
Boise, ID 2-5 2-Jul 2:15 43.3940407, -115.9512009 24.2 23.4

m/s Veg% Veg% % % %
Cover cover cover

4.8 <5 75-100 0 0) <5 74 1 0
55 <5 50-75 <5 0 <5 5D 1 0
6.0 <5 50-75 <5 0 0 55 0 2 (dead)
4.6 5-25 50-75 0 0 <5 40 0 15
Bad <5 50-75 0 0 <5 59 1 0

4 <5 50-75 O 0 0 53 5 0
4.6 25-50 75-100 0 0) 0 50 30 0
4.5 25-50 50-75 0 <5 0 30 30 0

6 25-50 50-75 0) <5 0 25 i) 0
5.3. 25-50 50-75 0 <5 0 35 25 0

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D. ZEMBRZUSKI, D.A. WOLLER, L. JECH, L.R. BLACK, K.C. REUTER, R. OVERSON AND A. CEASE

167

A 0.20 ,B 0.20 ,
Grasshopper IT , Grasshopper IT /
eg 1p:3.5¢ 4 Q 1p:2.1¢ ye
© ¢ ip:tce 6 , 1p:tc
= ; / => e /
S, Boise IT ra me e 4
i. 7 = 7
& 0-15 : ‘ 6 0-15 _
i) ig! p “ eS , ’
Cc 7 Cc 7
2 ’ 2 /
= ¢ = ¢
2.0.10 7 2.0.10 -
¢ f @
2 y, 2 :
ou Pa ae
oO 4 oO
2 a i
O Z
= —
& 0.05 $0.05
6 §
2 @ forbs a @ forbs
A 4 grass 5 & grass
Bliss, ID Boise, ID
0.0 0.0
8.00 0.05 0.10 0.15 0.2 8.00 0.05 0.10 0.15 0.2
C Protein (Proportion of Dry Mass) D Protein (Proportion of Dry Mass)
0.08 0.08

0.06

Euclidean Distance
(Perpendicular distance from a point to a line)
oO
=
B

S
2°
i)

S
2
ro)

Bliss, ID plants vs 1p:1c Bliss, ID plants vs IT
Bliss, ID

0.06

0.04

Euclidean Distance
(Perpendicular distance from a point to a line)

0.02

0.00
Boise, ID plants vs 1p:1c Boise, ID plants vs IT

Boise, ID

Fig. 2. Field IT compared to nutritional landscape. A, B. Grasshopper intake targets of the field populations (black solid line) alongside
the nutrient contents of grasses (triangles) and forbs (circles) collected from the same fields. The grey solid line represents the intake
target from the other field population. The dotted line represents a 1p:1c ratio. C, D. The average Euclidean distance between the plants
(triangles and circles in A and B) and either the grasshopper IT from each location or the 1p:1c line. * denotes a significant difference

between the Euclidean distances calculated from the IT and the Ip:

plants and the IT (Fig. 2A, B), between populations 1 and 2 (w =
53 p = 0.274). We found that when comparing the Euclidean dis-
tance of the plants calculated with the population IT versus calcu-
lations using the 1p:1c ratio, there was a significant difference in
the Euclidean distances. In this case, the Euclidean distance of the
plants was lower when calculated to the population IT than to a
1p:1c ratio for both Bliss (t = -4.0827 df = 14 p = 0.001) and Boise
(t = -9.464 df = 11.773 p = 7.536°”) field sites (Fig. 2C, D), sug-
gesting that the sampled plants macronutrient rations were closer
to the IT than to a balanced ratio.

Lab studies

Lab self-selected intake targets.—We calculated ITs for each of the
three blocks of the experiment, and t-tests were used to deter-
mine if both treatment groups were regulating consumption or
eating randomly and were compared to each other. Grasshop-
pers given Treatment A ate significantly different portions from
the high carbohydrate and high protein dishes, overall consuming

1c line.

slightly more from the high protein dish, and appeared to regulate
their consumption (Table 3). Grasshoppers given Treatment B ate
equally from both dishes, but grasshoppers from both treatments
arrived at similar p:c ratios (Table 3). We used a full MANCOVA
with sex and diet pairing as independent variables and total car-
bohydrates and protein eaten as separate dependent variables. We
included block as a random factor. There was a main effect of diet
treatment (group) and block (Table 2). For simplicity, we report
the overall ITs for males and females combined in Fig. 1, which
was 0.77 mg (+/-3) protein to 83 mg (+/-3) carbohydrates. We also
used generalized linear model methods to determine if the ITs of
our lab colony were significantly different from ITs of the Bliss and
Boise populations. Using the first three days of the lab colony IT
experiment, we found that our lab colony’s carbohydrate and pro-
tein consumption was significantly different from the Bliss popu-
lation, but not the Boise population (Suppl. material 1: Table $1).
We found that the Bliss population was consuming more carbo-
hydrates and protein than both the Boise population and our lab
colony (Suppl. material 1: Figs S$1-S4).

JOURNAL OF ORTHOPTERA RESEARCH 2021, 30(2)

168

Table 2. IT Statistics. MANCOVA statistics for field and lab intake
target (IT) studies testing the effects of sex, diet treatments, and
cohort (lab only) on the total amount of protein and carbohy-
drates consumed.

Pillai’s
Error
Population Effect trace df Sig.
Value

Intercept 0.972 364.1 21.000 0.000

Initial mass 0.146 1.792 21.000 0.191
Bliss, ID Sex 0.255 3.599 21.000 0.045
Diet pair 0.662 20.580 21.000 0.000

Sex * Diet pair 0.008 0.086 21.000 0.918
Intercept 0.037 0.774 40.000 0.468
Initial mass 0.341 10.330 40.000 0.000
Boise, ID Sex 0.008 0.155 40.000 0.857
Diet pair 0.126 2.890 40.000 0.067
Sex * Diet pair 0.005 0.108 40.000 0.898
Intercept 0.474 13.070 29.000 0.000
Initial mass (covariate) 0.029 0.438 29.000 0.649

Sex 0.152 2.606 29.000 0.091

Cohort 0.510 5.141 60.000 0.001
Lab Colony Diet pair 0.215 3.964 29.000 0.030
Sex * Cohort 0.029 0.220 60.000 0.926

Sex * Diet pair 0.033. 0.502 29.000 0.610
Cohort * Diet pair 0.074 0.578 60.000 0.680
Sex * Cohort * Diet Pair 0.212 1.783 60.000 0.144

Lab performance.—Using the no-choice experiments, we deter-
mined the specific growth rate (Fig. 3A) and absolute growth rate
(Suppl. material 1: Fig. S5), as well as the proportion of individu-
als surviving and successfully molting on diets that differed in
p:c ratio. Because the data did not meet the assumptions for an
ANOVA, we used the non-parametric Kruskal-Wallis test to deter-
mine if there was a significant effect of diet on specific growth rate
(2 = 32.41, df = 4, p = 1.576, e °°). We used the pairwise Mann-
Whitney non-parametric post hoc tests to determine that there
were no significant differences between all the treatment groups,
except 7p:35c, which was significantly lower than all other treat-
ments (Fig. 3A).

We analyzed the final proportion molted and proportion sur-
vived using Fisher's exact test of independence since grasshoppers
were removed from the experiment after they had either molted
or died. There was no significant difference in survival among the
treatment groups (p = 0.4298). However, there was a significant
difference among treatment groups regarding the final proportion
of grasshoppers successfully molted (p = 0.003), with the 7p:35c
treatment group being significantly different from all other diet
treatments. Overall, diet treatment 7p:35c had the lowest propor-
tion of grasshoppers survive and molt (Fig. 3B-C). All diet treat-
ments except 7p:35c had a large increase in molts by day 6 or 7,
whereas diet treatment 7p:35c delayed molting (Fig. 3C).

Discussion

Our long-term lab colony selected a balanced 1p:1c IT, which is
similar to previous studies using first (1p:0.96c; Behmer and Joern
2008) and second (1p:0.90c and 1p:0.95c; Fielding and Defoliart
2008) generation lab-reared M. sanguinipes. Our lab colony perfor-
mance experiments supported our hypothesis that M. sanguinipes
selects an IT range that aligns with high performance, similar to
Behmer and Joern (2008) and Fielding and Defoliart (2008). In
contrast with the lab populations, we found that M. sanguinipes

D. ZEMBRZUSKI, D.A. WOLLER, L. JECH, L.R. BLACK, K.C. REUTER, R. OVERSON AND A. CEASE

Table 3. IT paired t-tests to determine if there was equal consump-
tion from both diets in each treatment group.

Population Paired t test t p df
Bliss, ID a 7p:35c + 28p:14c 112.520 <0.001 12
Bliss, ID b 7p:35c+ 35p:7c 123.330- .<0:001 13
Boise, ID a 7p:35c + 28p:14c -20.384 <0.001 22
Boise, ID b 7p:35c+ 35p:7c -51.120 <0.001 22:
Lab a 7p:35c + 28p:14c -4.008 0.006 21
Lab b 7p:35c+ 35p:7c -0.008 0.994 20

collected directly from field populations had carbohydrate-biased
ITs (1p:2.1¢ and 1p:3.5c). The field populations may have shifted
their ITs to better match their nutritional landscape and/or in re-
sponse to disease, elevated activity, or other environmental factors
(Fig. 2). For example, the Boise landscape had a higher represen-
tation of forbs than Bliss, ID, which may have contributed to the
slightly less carbohydrate-biased IT of that population (Table 1);
further studies are needed to disentangle these potential hypothe-
ses. Understanding how these factors impact ITs will be key to pre-
dicting the nutritional physiology of these organisms in different
environments, which, in turn, may assist in the development of
novel management methods.

There is some evidence from lab-based experiments that pop-
ulations either adapt or acclimate to their nutritional environ-
ment by matching their IT and performance to their ancestral diet
(Raubenheimer et al. 2012). For instance, as mentioned briefly
earlier, P. xylostella moths reared on a single homogenous food
with a fixed nutrient composition for about 350 generations ex-
hibited a strong selection for the same nutrient balance as their
ancestral colony diet and had a sharp decline in performance
when they deviated from that macronutrient balance, showing an
extreme food specialization (Warbrick-Smith et al. 2009). A prior
study reared the same species for multiple generations on either
carbohydrate-rich or poor foods. The selected lines developed
the capacity to minimize or maximize body fat accumulation to
improve fitness when confined to their treatment diet (Warbrick-
Smith et al. 2006). The diets did impact host plant preference for
egg laying, but the authors did not test whether the selection ex-
periment shifted ITs.

Results from field-based research, on the other hand, suggest
that aligning ITs and performance to match the nutritional land-
scape is uncommon in the absence of long-term specialization
and that physiological status is a better predictor of IT than ambi-
ent plant nutrient contents. For example, in West Africa, Oedaleus
senegalensis (Krauss, 1877), the Senegalese grasshopper, did not
shift its IT to match seasonal shifts in plant p:c; instead, ITs cor-
related poorly with plant nutrients and varied with age and sex (Le
Gall et al. 2021). In Australia, a comparison of a non-migratory
and two migratory grasshopper species through space and time
revealed that populations of the non-migratory grasshopper had
different ITs through space, but it was likely to redress nutrient im-
balances from the local environment rather than to match them
(Lawton et al. 2021). The migratory species largely maintained the
same IT, even when there was a mismatch between their IT and
their nutritional landscape, similar to Senegalese grasshoppers
(also a migratory species).

In Paraguay, field populations of Schistocerca cancellata (Ser-
ville, 1838), the South American locust, maintained a carbohy-
drate-biased IT and only gained mass when fed the most carbo-
hydrate-biased plants, despite being in a quite protein-biased
landscape (Talal et al. 2020). This result corroborates earlier re-

JOURNAL OF ORTHOPTERA RESEARCH 2021, 30(2)

D. ZEMBRZUSKI, D.A. WOLLER, L. JECH, L.R. BLACK, K.C. REUTER, R. OVERSON AND A. CEASE

bebe

0.154

>

0.104

In (M1/M2)/dt)

0.054

0.004

-0.054

Specific Growth Rate (yu

-0.10

7p:35c¢ 14p:28c

B Diet — O7p:35c — 14p:28c — 21p:2ic 28p:14c¢

0 5 10
Days in Experiment

21p:21¢
Artificial Diet (Yop:%c)

35p:7c Cc

169

28p:14¢ 35p:7c

Diet — O7p:35c — 14p:28c¢ — 21p:21c 28p:14c 35p:7c

1.00

0.75

0.50

Molting to Adult (Proportion)

10

5
Day in 5th Instar

Fig. 3. Performance experiments. Survival and specific growth rates of grasshoppers from the long-term lab colony no-choice diet
experiments. A. The specific growth rates for each diet treatment. Diamonds indicate the mean and bolded lines indicate the median.
Boxes are +/- 25%, lines represent minimum and maximum values excluding extreme values, and dots indicate data points > 1.5 far-
ther from the box edge than the interquartile range. Lower case letters indicate differences from Mann-Whitney post-hoc analyses. B.
The proportion of grasshoppers surviving through time on each diet treatment. Most diet treatments did not have individuals die until
the 5" day of the experiment, and most treatments except 7p:35c had minimal deaths (although there were no significant differences
among treatments). C. Proportion of grasshoppers molting to adults over time. Most of the diets saw increases in molting from days
5-7, except diet treatment 7p:35c, which was delayed and had the least number of grasshoppers successfully molt (significantly differ-

ent from all other treatments).

search indicating that locusts and migratory grasshoppers require
a carbohydrate-biased diet to undergo long-distance migration
(Cease et al. 2017) and that low p: high c environments support
population growth (Cease et al. 2012, Word et al. 2019, Le Gall et
al. 2020a, b). In the face of shifting environments, organisms and
populations will acclimate, evolve, move, or perish. Collectively,
these studies suggest that migratory species may rely on migration
or post-ingestive mechanisms to regulate nutrient balance in the
face of environmental change and that physiological constraints
in nature limit matching a population’s IT to its nutritional land-
scape except when under strong selection.

The current study using the migratory grasshopper provides
some support for both non-mutually exclusive hypotheses: that
population IT is shaped by local nutritional landscape and by
physiological status. Under standard rearing conditions, the colo-
ny has ad libitum access to foods encompassing a broad macronu-
trient range: wheat seedlings (1.9p:1c), romaine lettuce (1p:2.6c),
and wheat bran (1p:4.1c) (Brosemann et al. unpubl.; FoodData
Central 2021a). Therefore, it is unlikely that there was strong selec-
tive pressure to develop a narrow IT based on the lab diet, in con-

trast to the long-term moth colony reared on a single food choice
(Warbrick-Smith et al. 2009). The lab colony likely arrived at a
1p:1c IT (Fig. 1) because it maximizes performance in a lab col-
ony. While there was not a narrow performance peak, the IT was
within the range where the lab colony maintained a high growth
rate and fast development time across the 1:1, 1:2, 2:1, and 5:1 p:c
diets (Fig. 3).

The field populations both had carbohydrate-biased ITs that
matched their local environments. Although the 1p:2c Boise pop-
ulation IT could have been reached based on the plants available
in both field environments, the 1p:3c IT that the Bliss population
selected could only have readily been reached in the Bliss loca-
tion (Fig. 2). Furthermore, neither field environment would have
supported populations to select for the 1p:1c IT that the lab popu-
lation selected. The Boise location had an average of 25% forb
ground cover, and the Bliss location had <1% (Table 1), indicating
that the few forbs closer to 1p:1c were sparse in the landscape
and that the Bliss population was in an extremely carbohydrate-bi-
ased landscape. Therefore, it is possible that the grasshopper field
populations, particularly for Bliss, were under some selective pres-

JOURNAL OF ORTHOPTERA RESEARCH 2021, 30(2)

170

sure to have carbohydrate-biased ITs to align with their nutritional
landscape. However, all tests of lab colony ITs of M. sanguinipes
nymphs performed to date resulted in a narrow range (1p:0.90c
to 1p:1c) regardless of being first or second generation, being in
a colony since 1970, or being originally collected from Alaska,
Idaho, Nebraska, or Arizona (Behmer and Joern 2008, Fielding
and Defoliart 2008; Fig. 1). Therefore, it is unlikely that the align-
ment between IT and local plant nutrients that we measured in
this study represents local adaptation, though it could be evidence
of an evolved ability to plastically respond to a restricted diet.

Many environmental factors can influence herbivore physiol-
ogy and result in shifting the IT, such as activity level and patho-
gens. For example, Locust migratoria (Linnaeus, 1758), the migra-
tory locust, increased carbohydrate, but not protein, consumption
following 120 min of tethered flight (Raubenheimer and Simpson
1999). Nutrient balance affects insect immune function, and thus
their ability to survive sickness and infections (Ponton et al. 2011a,
b; Graham et al. 2014, Deans et al. 2017). Different immune com-
ponents may be heightened by diets with different macronutri-
ent contents, as was the case for Spodoptera littoralis (Boisduval,
1833) caterpillars (Cotter et al. 2011). Furthermore, Graham et
al. (2014) found that Australian plague locusts that selected more
carbohydrate-biased diets were better able to fight infections from
the fungal pathogen Metarhizium. ITs that are highly carbohydrate-
biased, such as we observed in our study’s Bliss, ID population,
could be indicative of grasshoppers selecting this diet to fight sick-
ness or infection. Indeed, we found that the Bliss population suf-
fered significant mortality during the experiment and prior to the
start of the experiment. When we completed the setup of the Bliss
population experiment, approximately 30% of the grasshoppers
we had collected the previous day were dead. The Bliss popula-
tion also had more cases of grasshoppers losing mass than the
Boise population. While not conclusive, these signs indicate that
the population may have been suffering from pathogens or para-
sites. Further studies on field populations are needed to determine
if the selected ITs maximize performance in those conditions, as
well as the potential mechanisms driving variation in population
ITs. However, our data suggest that, at least for these populations,
they could achieve their preferred p:c ratio locally.

Understanding the nutritional requirements of rangeland
grasshoppers is important not only for understanding what types
of vegetation grasshoppers will be most likely to eat but also for
developing novel management strategies. For example, the balance
of macronutrients is important for immune function in insects and
may be important to consider when biopesticides are used for man-
agement (Lee et al. 2008, Ponton et al. 2011a, b, Deans et al. 2017,
Tessnow et al. 2018). Insects that can meet their ITs in their nutri-
tional landscapes are likely to be less susceptible to biological con-
trol strategies—either less susceptible to pathogens or less suscepti-
ble to toxins produced by the biological control agent (Graham et
al. 2014, Deans et al. 2017, Tessnow et al. 2018). There is evidence
that for some insects, nutritional physiology differs between popu-
lations. Research on Spodoptera frugiperda (J.E. Smith, 1797), study-
ing its susceptibility to Bt toxins, showed that for one population,
meeting the IT actually increased that population's susceptibility
to the toxins. In the other two populations, eating at the IT did not
affect individuals’ susceptibility to the toxins (Tessnow et al. 2021).
This suggests that not only will there be differences in how IT re-
lates to performance and survival between species, but there could
also be differences among populations, so analyzing populations’
nutritional physiology and ecology is critical to any management
strategy. Understanding how the nutritional landscape interacts

D. ZEMBRZUSKI, D.A. WOLLER, L. JECH, L.R. BLACK, K.C. REUTER, R. OVERSON AND A. CEASE

with an organism's IT and macronutrient requirements is going to
be important, especially with more farmers and ranchers turning to
biopesticides as means of managing grasshopper outbreaks (Gard-
ner and Thomas 2002). Similar to how there are recommended
temperature ranges across which biopesticides are most effective
(McNeill and Hurst 2008, Rai et al. 2014, Kim et al. 2019), there
should be guidance as to what types of nutritional landscapes will
make pests most susceptible to biopesticides.

Another aspect to consider is how biopesticide treatment
might affect pest host plant preference, as it could cause the target
pests to consume crops and other plants it might not normally
otherwise. Biopesticides aside, knowing how pests respond to nu-
tritional landscapes can open pathways for population suppres-
sion through agricultural practices. For example, for locusts and
migratory grasshoppers that thrive in low nitrogen environments
(Cease et al. 2012, Word et al. 2019), the nutritional landscape
could be altered through soil amendments, crop rotations, or oth-
er practices that increase soil organic matter and nitrogen availa-
bility; this would, in turn, increase the plant protein: carbohydrate
ratio and suppress pest populations (Cease et al. 2015, Word et al.
2019). To support the development of sustainable management
options, future research should study how biopesticide challenges
affect the nutritional demands of M. sanguinipes and if this species
can alter its diet to decrease its susceptibility. As with the Austral-
ian plague locust, such research would add greater understanding
to the potential relationship between the nutritional physiology
of grasshoppers and biopesticide efficacy, leading to more diverse,
sustainable, and efficient management options.

Acknowledgements

Special acknowledgments to Lori Atkins in Boise, Idaho for
the use of her property for running the field experiments; Brad
Newbry of the United States Department of Agriculture’s Animal
and Plant Health Inspection Service (APHIS) Plant Protection and
Quarantine (PPQ) Field Operations in Idaho for grasshopper field
survey information; Dustin Grief, who helped with running some
experiments; the Cease Lab, Arizona State University; the Global
Locust Initiative; and Mark Tubbs of Tubbs Land and Cattle LLC in
South Dakota for graciously allowing us to use his ranch for a test
run of the field population studies. This material was made pos-
sible, in part, by a Cooperative Agreement (AP17PPQS&T00C180)
from USDA APHIS. It may not necessarily express APHIS’ views.

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Supplementary material 1

Author: Deanna Zembrzuski, Derek A. Woller, Larry Jech, Lonnie

R. Black, K. Chris Reuter, Rick Overson, Arianne Cease

Data type: Environmental data

Explanation note: Table S1. Field sites. Habitat and environmen-
tal data from grasshopper field study plots in Idaho. Plot lo-
cation coordinates are based on WGS84. Field Diet Choice
Data Set. Diet choice experimental data from Field locations
in Boise and Bliss Idaho. Lab Diet Experiment Data Set. Lab
Diet choice and restricted diet experimental data sets. Plant
Macronutrient Data. Data set with the carbohydrate and pro-
tein content of plants sampled from the field sites in Boise
and Bliss Idaho. Supplementary figures and tables covering
additional data.

Copyright notice: This dataset is made available under the Open
Database License (http://opendatacommons.org/licenses/
odbl/1.0/). The Open Database License (ODDbL) 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/jor.26.61605.suppl1

JOURNAL OF ORTHOPTERA RESEARCH 2021, 30(2)