Review Article

Journal of Orthoptera Research 2018, 27(1): 53-60

The response of Orthoptera to grazing on flood defense embankments

in Europe

KIMBERLEY FARGEAUD!, TIM GARDINER?

1 Ecole Pratique des Hautes Etudes, Les Patios Saint-Jacques, 4-14 Rue Ferrus, 75014 Paris, France.
2 Environment Agency, Iceni House, Cobham Road, Ipswich, Suffolk IP3 9JD, UK.

Corresponding author: Tim Gardiner (tim.gardiner@environment-agency.gov.uk)

Academic editor: Corinna S. Bazelet | Received 22 March 2018 | Accepted 26 May 2018 | Published 12 June 2018

http://zoobank.org/5EBC8A90-C7F8-4776-B70F-3FB4C680E99B

Citation: Fargeaud K, Gardiner T (2018) The response of Orthoptera to grazing on flood defense embankments in Europe. Journal of Orthoptera

Research 27(1): 53-60. https://doi.org/10.3897/jor.27.25183

Abstract

European flood defense embankments form an excellent habitat for
Orthoptera. To be effective against storms, these vegetated earth embank-
ments have to be managed by grazing or mowing. However, grazing can
impact invertebrates such as grasshoppers and crickets (Orthoptera). This
management can lead to dispersal toward undisturbed grassland and re-
ductions in the quality of habitat, food resources and oviposition sites. In
most cases, orthopteran insects require heterogeneous vegetation patches
with swards of varying height. The impact of grazing depends on the type
of livestock; it is very important to choose appropriate animals, timing and
intensity. Sheep grazing in late summer (September-October) at a moder-
ate intensity seems to be favorable for Orthoptera. If grazing is carefully
monitored, it can promote Orthoptera conservation while maintaining
flood defense integrity.

Key words

biodiversity, bush-cricket, coast, conservation, dike, engineering, fluvial,
grasshopper, sea wall

Introduction

In Europe, coastlands are protected from tidal flooding by
vegetated earth embankments known as ‘dikes’ or ‘dykes’ (Verheij
et al. 1997, Sprangers 1999). In the UK, they are referred to as
‘sea walls’ (Gardiner et al. 2015). There are 259 km of dikes on
the Dutch coast (van Loon-Steensma 2015), 970 km in Germany
(Rohde 1988), and 900 km in Denmark (Danish Coastal Author-
ity 2015). In the UK, there are approximately 2100 km of sea wall
(450 km in the county of Essex alone; Gardiner et al. 2015), which
matches the total of the aforementioned three countries com-
bined. A fluvial flood defense can also be required in flood-prone
areas; alongside Hungarian rivers for example. In Hungary, 4000
km of dikes protect land from fluvial flooding (IUCN 1995). In
England and Wales, there are 35000 km of tidal and fluvial em-
bankments (Dyer 2004).

Significant changes have occurred in the way many vegetated
sea walls around the coasts and estuaries of England are managed,
not least through increasing efforts to meet common standards

with respect to flood prevention (Environment Agency 2012). The
main changes relate to increased removal of woody vegetation,
changes in the frequency of mowing, and a reduction in grazing
of sea walls. The growth of woody vegetation can undermine the
structural integrity of sea walls and promote the activity of bur-
rowing mammals such as badgers Meles meles L., 1758 (Carnivora:
Mustelidae; Gardiner 2014). Woody vegetation and tall, unmown
grassland make it difficult for engineers to inspect the condition
of sea walls as a defense against tidal flooding, which is their main
function (Environment Agency 2012). In the event of overtopping,
water pouring over the crest and down the landward face could
rip grass tussocks and trees out of the earth, leaving holes in the
surface and damaging the sea wall (Gardiner et al. 2015).

A sea wall, or dike, is typically composed of several distinct
habitats (Fig. 1). Sea walls have a complex mosaic of microhabi-
tats which Orthoptera utilize (Gardiner et al. 2015) along with
adjacent grazing marshes (Gardiner et al. 2017). When combined,
these habitats represent a corridor for the dispersal of orthopter-
oid insects such as bush-crickets (Tettigoniidae), crickets (Gryl-
lidae) and grasshoppers (Acrididae). Orthoptera are key species
in many trophic levels but can be influenced by environmental
stresses such as grazing (Gardiner et al. 2015). To be fully effective,
embankments need to be managed; grazing by livestock is one of
the solutions to maintain a healthy ecosystem and flood defense
(Davis et al. 2014). Grazing can also occur naturally, for example
where rabbits Oryctolagus cuniculus L., 1758 (Lagomorpha: Lepori-
dae) and hares Lepus europaeus Pallas, 1778 (Lagomorpha: Lepori-
dae) occur (Gardiner et al. 2015). According to Gardiner (2018),
‘grazing prevents succession of open grasslands to scrub and forest, cre-
ates heterogeneity in sward height, and provides patches of bare earth
through the action of livestock hooves breaking the vegetative cover.’

In European semi-natural grasslands, livestock grazing is a
common practice which maintains a high floristic species richness
(van Klink et al. 2016). However, grazing can alter habitat quality
and negatively affect invertebrates (Ma et al. 2017) by reducing
food abundance and influencing microclimate and oviposition
sites (O’Neill et al. 2003). Development of vegetation in grassland
varies in response to habitat factors and management (Sprangers
1999). It is therefore very important to choose the appropriate

JOURNAL OF ORTHOPTERA RESEARCH 2018, 27(1)

54

Borrow
DYKE

LaNDWaRD FoLpInG

SIDE FACE

SEAWARD CREST

SIDE FACE

SEA AND
SALTMARSH

Fig. 1. The typical composition of a sea wall (Brightlingsea, Essex);
credit K. Fargeaud.

kind of livestock for grazing dikes and sea walls (Gardiner et al.
2015). In this paper, we investigate how flood defense manage-
ment (dikes and sea walls) and Orthoptera conservation can be
balanced in Europe by collating the available literature and assess-
ing its implications.

Orthoptera on flood defense embankments

The English coastline can be rich in grasshoppers, bush-crickets
and groundhoppers (Gardiner et al. 2015). In the county of Essex,
as in the Wadden Sea (Netherlands and Germany) and Tisza Ba-
sin (Hungary), flood defense embankments provide an important
habitat for a range of common and scarce Orthoptera (Table 1).
The species richness of the tidal Essex (n = 13) and Wadden Sea (n
= 12) flood defense embankments was low in comparison to the
fluvial walls of the Tisza Basin (n = 31). The species assemblages
of the embankments were markedly different, with only four spe-
cies common to all three areas: lesser marsh grasshopper Chort-
hippus albomarginatus De Geer, 1773 (Orthoptera: Acrididae), field
grasshopper Chorthippus brunneus Thunberg, 1815 (Orthoptera:
Acrididae), short-winged conehead Conocephalus dorsalis Latreille,
1804 (Orthoptera: Tettigoniidae) and Tetrix subulata L., 1761 (Or-
thoptera: Tetrigidae). For the Essex sea walls, two species were lo-
cally scarce: grey bush-cricket Platycleis albopunctata Goeze, 1778
(Orthoptera: Tettigoniidae) and great green bush-cricket Tettigonia
viridissima L. 1758 (Orthoptera: Tettigoniidae), compared to four
scarce species on the Tisza Basin embankment: crested grasshop-
per Acrida ungarica Herbst, 1786 (Orthoptera: Acrididae), heath
bush-cricket Gampsocleis glabra Herbst, 1786 (Orthoptera: Tetti-
goniidae), Tesselana veyseli Kocak, 1984 (Orthoptera: Tettigonii-
dae) and large conehead Ruspolia nitidula Scopol, 1786 (Orthop-
tera: Tettigoniidae), and four scarce species on the Wadden Sea
embankment: bow-winged grasshopper Chorthippus biguttulus L.
1758 (Orthoptera: Acrididae), lesser grasshopper Chorthippus mol-
lis Charpentier, 1825 (Orthoptera: Acrididae), Cepero’s ground-
hopper Tetrix ceperoi Bolivar, 1887 (Orthoptera: Tetrigidae) and T:
subulata (Sprangers 1999, Verheij et al. 1997). The only embank-
ment species on the IUCN Red Data List for Europe was G. glabra
which is Near Threatened (Hochkirch et al. 2016) and found on
the Tisza Basin embankment.

From 1980 to 2009 in the UK, major changes occurred in cli-
mate and land use. Beckmann et al. (2015) studied the changes in
distribution of some grasshoppers and crickets. They concluded
that habitat generalism, southerly distribution and oviposition

K. FARGEAUD AND T. GARDINER

Table 1. Species of Orthoptera recorded from earth embankments
in three areas of Europe.

Essex Coast Wadden Sea _ Tisza Basin
(EC) (WS) (TB)
Acrida ungarica* X

Species

Adreppus nutans
Aiolopus thalassinus
Calliptamus italicus
Chorthippus albomarginatus xX xX
Chorthippus biguttulus*
Chorthippus brunneus X X
Chorthippus dichrous

Chorthippus dorsatus

Chorthippus mollis? X
Chorthippus oschei

Chorthippus parallelus xX

Conocephalus dorsalis

~<
x x Kx XK

x x XK

><
~<

Conocephalus fuscus X
Dociostaurus brevicollis

Euchorthippus declivus

Gampsocleis glabra?

Gryllus campestris

Leptophyes albovittata

Leptophyes boscii

Leptophyes punctatissima x Xx
Meconema meridionale

x KM KKK KK KK OX

><

Meconema thalassinum X X
Mecostethus parapleurus

Metrioptera bicolor

Metrioptera roeselii xX

Oecanthus pellucens

Omocestus haemorrhoidalis

Omocestus rufipes

xx KM KK XK XK

Pezotettix giornae
Phaneroptera falcata xX
Phaneroptera nana

><

Pholidoptera griseoaptera X
Platycleis affinis xX
Platycleis albopunctata' X
Ruspolia nitidula* X
Stenobothrus stigmaticus X
Tesselana veyseli* X
Tetrix ceperoi* xX
Tetrix subulata* X X X
Tetrix undulata X
Tettigonia viridissima' X X

Number of species 13 12 31

X indicates presence.
"Essex Red Data List species (Gardiner and Harvey 2004).

Wadden Sea Red Data Book species (Holst et al. 1996).
3Endangered or protected species in Tisza Basin (Torma and Bozs6 2016).

above ground in vegetation positively influenced range changes.
Two species commonly found on sea walls significantly increased:
C. fuscus and Roesel’s bush-cricket Metrioptera roeselii Hagenbach,
1822 (Orthoptera: Tettigoniidae) made use of these flood de-
fense corridors during their range expansions. A study in Hun-

JOURNAL OF ORTHOPTERA RESEARCH 2018, 27(1)

K. FARGEAUD AND T. GARDINER

gary showed that insect groups respond differently to habitat and
landscape characteristics and Orthoptera are generally influenced
by landscape more than habitat features (Torma and Bozs6 2016).
Krausz et al. (1995) found that the distance between habitats was
correlated with a difference in orthopteran assemblages. They
also highlighted the lack of knowledge in the role of population
isolation and of habitat corridors such as sea walls and dikes in
structuring Orthoptera assemblages. A small-scale study in Essex
suggested that the absence of intensive agriculture and livestock
grazing on an island with sea wall flood defenses created impor-
tant refuges for Orthoptera (Gardiner and Ringwood 2010).

Therefore, flood defense embankments seem to be an impor-
tant corridor habitat for Orthoptera across Europe and grazing
management should seek to enhance their value without compro-
mising flood risk.

General grazing effects

Timing.—Year-round grazing can be a useful tool for maintaining
the insect assemblages of large grassland areas (Fleischer and H6l-
zel 2013). This management can maintain the characteristic biodi-
versity of semi-natural heathlands and grasslands (WallisDeVries
et al. 2016). In lowland heathland in the Netherlands, grazing
seems more beneficial to early successional species than late suc-
cessional species which are negatively affected (WallisDeVries et
al. 2016). In grasslands in southwest Montana (USA), Davis et al.
(2014) showed that herbivory affected many plants and arthropod
characteristics in a similar manner: early grazing (June) can nega-
tively affect species which need forage in the early growing season.
Davis et al. (2014) suggest that the timing of grazing can have big
effects on the biodiversity of multiple trophic levels and effects
can depend on the grassland habitat type. However, they found
that Orthoptera were unaffected by grazing and that plant height
was greater with early grazing (late June) than late grazing (July
and August). In the Netherlands, a continuous pasturing lasts for
the entire grass growing season (mid-April to mid-October) with
a low density of livestock (Muijs 1999). In Essex, sea walls are
often grazed with sheep through September and October (Gar-
diner et al. 2015). Indeed, sheep grazing can be the best method
if it includes rest periods in areas where plants need to germinate.
The grassland should be mown twice a year to reduce the nutrient
content of the soil; if not, once a year in mid-July may be sufficient
(Sprangers 1999).

Patch formation.—Orthoptera are influenced by the formation of
grass patches in grazed habitats (Gardiner and Hill 2004). Heavy
grazing can create a homogeneous sward of consistently short veg-
etation with little cover from avian predation or inclement weather
(Fig. 2). In Germany, the interaction between fodder quality and
grazing intensity can lead to cattle adjusting their grazing pattern
according to the vegetation biomass, which leads to the establish-
ment of heterogeneous patches (Fleischer and Hélzel 2013). On
the Wadden Sea coastline, the choice of livestock type has smaller
effects on trophic levels than stocking intensity (van Klink et al.
2016). Invertebrates, such as C. brunneus, sometimes opt for patch-
es of short turf and bare ground as habitat because it provides ideal
oviposition and basking sites (Gardiner et al. 2015).

Soil disturbance.—Orthoptera may also be affected by the soil dis-
turbance associated with grazing. Grasshoppers, such as the mot-

95

Fig. 2. Sheep grazed sea wall with a homogeneous, short sward;
credit T. Gardiner.

tled grasshopper Myrmeleotettix maculatus Thunberg, 1815 (Or-
thoptera: Acrididae), require exposed soil and sparse grassland
(good egg-laying and basking conditions) which can be created by
associated cattle trampling of the vegetation. However, cattle graz-
ing can lead to a sward with uniformly short grass with reduced
grasshopper suitability overall (Gardiner 2012).

Applying livestock

Sea wall and dike vegetation is often maintained by grazing
animals. Herbivores grazing on grasslands stimulate grass produc-
tivity (Nolte et al. 2014). A study in the Netherlands found that
canopy height is affected by two variables: livestock species and
livestock density (Nolte et al. 2014). The livestock species (includ-
ing wild herbivores like rabbits) can also affect plant abundance
and assemblage diversity, which are correlated with Orthoptera
conservation and pest management (Gardiner 2018). Herbivore
species and densities should therefore be chosen depending on
their impacts.

Moderate intensity sheep grazing (c. 10 sheep/ha) in Essex can
create a high sward heterogeneity which is generally favorable for
Orthoptera (Figs 3, 4). Like rabbits, sheep can easily reach inacces-
sible areas, which can be desirable or undesirable depending on
the flood defense management objectives (Gardiner et al. 2015).

Less selective grazers such as cattle can create a relatively uni-
form sward height by removing long and coarse grass where many
invertebrates like M. roeselii or C. albomarginatus occur (Gardiner
et al. 2015). However, intense cattle grazing can damage the soil
surface (Fig. 5) and the flood defense requiring costly repairs. For
this reason, these grazers are not generally recommended for graz-
ing dikes or sea walls (Gardiner et al. 2015).

Horses can also be used to graze dikes and sea walls. If their
stocking intensity is heavy, a very homogeneous, short sward will
be created (Fig. 6). Nevertheless, low stocking densities of equines
in large areas can provide a varied mosaic with shortly grazed
lawns and taller undisturbed vegetation. Ungrazed latrines (dung-
ing areas) form an excellent tall-grass habitat for many species of
Orthoptera such as the bush-crickets C. fuscus and M. roeselii (Gar-
diner et al. 2015).

To create heterogeneous, small-scale vegetation mosaics, No-
Ite et al. (2014) recommended cattle rather than horses, but at a

JOURNAL OF ORTHOPTERA RESEARCH 2018, 27(1)

56

Fig. 3. Light sheep grazing on a sea wall creating a heterogeneous,
patchy sward favorable for Orthoptera (Little Oakley, Essex, UK);
credit T. Gardiner.

Fig. 4. Sheep grazing on a sea wall folding creating a heterogene-
ous, patchy sward favorable for Orthoptera (Brightlingsea, Essex,
UK); credit T. Gardiner.

low intensity. However, cattle and horses contribute to very poor
erosion-resistant revetments (Muijs 1999).

Of the Dutch dikes, 85% are grazed, and 15% have species-
poor grassland used for haymaking (Sprangers 1999). Sprangers
(1999) adds that the ‘Frysian system’ is very efficient. The princi-
ple of the system is that grazing a small dike parcel with a large
number of livestock during a short period is better than grazing a
large parcel with few livestock continuously. This results in peri-
odical heavy grazing of small areas with 35 to 40 ewes and lambs
per hectare, corresponding to 15 sheep per hectare per year. These
livestock numbers reflect the 60% of sea dikes which were tradi-
tionally heavily grazed and fertilized. Moreover, Sprangers (1999)
affirms that around 85% of the aforementioned heavily grazed
dikes are managed using sheep. This is exactly the opposite in Es-
sex where 86% of sea walls are mown and only 14% are grazed or
unmown (Gardiner et al. 2016). This results in a taller vegetation
on the Essex sea walls due to the late summer mowing in August
and September (Fig. 7).

K. FARGEAUD AND T. GARDINER

Fig. 6. Horse grazed area (left) vs. ungrazed area (right); credit T.
Gardiner.

Livestock effects on Orthoptera

Grazing by livestock affects vegetation, and therefore Orthop-
tera. Kruess and Tscharntke (2002) suggested that insect diversity
increases in the following order: ‘intensively grazed (5.5 cattle/ha)
> extensively grazed (1.4 cattle/ha) > short-term ungrazed (ungrazed
for 3 years) > long-term ungrazed (ungrazed for more than 5 years)’. In
Montana (USA), grazing and trampling encroach upon grasshop-
pers’ food and influence the physical structure of vegetation and
the soil surface which, in turn, impacts the thermal environment
and oviposition sites (O’Neill et al. 2003). O'Neill et al. (2003)
conclude that most grasshoppers are negatively influenced by
these stresses. Herbivores frequently disturb Orthoptera, leading
to dispersal of species such as the meadow grasshopper Chorthip-
pus parallelus Zetterstedt, 1821 (Orthoptera: Acrididae) to undis-
turbed grasslands (Gardiner et al. 2015). In the long-term, reduc-
ing sward height and increasing disturbance through heavy graz-
ing can lead to dispersal through undisturbed and infrequently cut

JOURNAL OF ORTHOPTERA RESEARCH 2018, 27(1)

K. FARGEAUD AND T. GARDINER

Fig. 7. Uncut grassland and scrub on a sea wall folding (Bright-
lingsea, Essex, UK); credit T. Gardiner.

areas (Fig. 8) (Gardiner et al. 2015). Moreover, the linear nature of
grassland dikes promotes migration (Krausz et al. 1995).

The response of Orthoptera to a physical disturbance is to
jump (Ben-Ari and Inbar 2013). However, this escape mechanism
leads to an important energy expense. In Israel, Ben-Ari and Inbar
(2013) studied the dropping mechanism of insects in response to
mammalian breath. They found a direct influence of mammalian
herbivores on plant-dwelling insects.

In the grasslands of the Eastern Eurasian steppe, Ma et al.
(2017) recommended avoiding continuous years of intense sheep
grazing. They found a significant cumulative effect; an increase in
sheep grazing intensity caused decreases in insect abundance, di-
versity and species richness. Regarding cattle, their presence on sea
walls can create very short, homogeneous grassland swards (uni-
formly <10 cm height) which reduces suitability for Orthoptera
(Gardiner et al. 2015). Eventually, modifying grassland ecosystems
with domestic livestock grazing can lead to a significant loss of
biodiversity (Evans et al. 2015). On Essex sea walls in Eastern Eng-
land, Orthoptera were recorded from 2 x 2 m quadrats (5 quad-
rats per plot) in cattle, sheep and rabbit grazed grassland plots
and compared to mown plots using a one-way analysis of variance
(ANOVA) after square-root transformation of count data to nor-
malize it. A post-hoc Tukey test was performed to determine the
differences between the plot means in the four differently-man-
aged grassland types.

The statistical analysis revealed that significantly higher densi-
ties of Orthoptera were recorded in sheep and rabbit grazed grass-
land compared to mown swards (Table 2). Densities of Orthop-
tera could exceed 3 adults/m* on some grazed sea walls. The great-
er heterogeneity in sward height on the sheep and rabbit grazed
sea walls was particularly favorable for grasshoppers such as C.
albomarginatus. The mosaic of grass heights provided patches of
short vegetation for basking and oviposition, and tall vegetation
for shelter from avian predation and excessively hot microclimatic
temperatures (Gardiner and Hassall 2009). Species richness did
not differ between the sea walls (Table 2).

A German study found a bottom-up effect in heavy cattle
grazing impacting plant-insect interactions (Kruess and Tscharn-
tke 2002). Increasing grazing intensity may affect trophic levels

57

Fig. 8. Sheep-grazed area (left) vs. undisturbed area (right); credit
T. Gardiner.

by negatively affecting both primary and secondary consumers
(Ma et al. 2017). Removal of vegetation biomass by grazing nega-
tively affects herbivorous arthropod abundance and consequent-
ly reduces predator numbers, especially of the field vole Microtus
agrestis L., 1761 (Rodentia: Cricetidae; Evans et al. 2015). In a
ten-year experiment, Evans et al. (2015) suggested that intense
long-term ungulate grazing can have an important impact on
trophic levels but not on plant diversity. Kruess and Tscharntke
(2002) found that decreasing grazing intensity improved insect
diversity but not plant diversity, which was low in intensively
grazed pastures and high in abandoned areas. In intensively
modified vegetation, even if the diversity is not impacted, Or-
thoptera and their predators are negatively impacted. Evans et
al. (2015) also detected a strong positive effect of vegetation bio-
mass on arthropod abundance.

The effect of grazing is usually species-specific because the re-
sponse of species and assemblages differs in accordance with the
region and the grassland type (Gardiner 2018). Both phytopha-
gous and entomophagous insects are affected by grazing inten-
sity (Kruess and Tscharntke 2002). However, not all groups are
negatively impacted, such as some larvae and soil-dwelling insects
(Evans et al. 2015). Kruess and Tscharntke (2002) consider that
grazing or abandoning of grassland does not affect habitat special-
ist or generalist insects.

Table 2. Density and species richness of Orthoptera on Essex sea
walls (UK) with differing management (Gardiner unpublished
data, 2011).

Management (n) Density/m? No. species/plot
Rabbits (4) 2.9+0.4 2.0 + 0.0
Sheep (4) 2.6 +0.8 2540.3
Cattle (4) 1.4+0.1 3.3+0.9
Mown (12) 0.7+0.2 2.4+0.4

One-way ANOVA:

Density: F = 9.05, d.f. 3, sheep vs. mown sig. P<0.05, rabbits vs. mown sig.
P<0.01.
Species: F = 0.74, d.f. 3, P=0.54.

JOURNAL OF ORTHOPTERA RESEARCH 2018, 27(1)

58 K. FARGEAUD AND T. GARDINER

Mixed management

Grazing can alternate with other kinds of management such
as mowing or occasional burning. Sometimes, mowing may be
the only solution in areas hardly accessible to domestic livestock
such as remote sea walls. A rotational management strategy pro-
duces complex effects on orthopteran assemblages and develops a
diverse range of vegetation structures (Gardiner 2018). A combi-
nation of grazing and mowing is possible on dikes and sea walls.
Alternate periods of grazing and mowing on a dike or sea wall
can increase biodiversity while ensuring flood defense integrity
is maintained (Gardiner et al. 2015). The use of rotational sheep
grazing on English sea walls develops suitable conditions for
large populations of grasshoppers, especially C. albomarginatus
(1.7 adults/m?’; Gardiner and Charlton 2012). In the Netherlands,
grassland needs to be managed by grazing and mowing to prevent
irregular grass (Muijs 1999). In Germany, some dikes were fre-
quently mown and grazed, so no impacts were found on already
impoverished grasshopper populations (Batdry et al. 2009). In
Hungary, grasshopper abundance was higher on extensive fields,
and all arthropods (including grasshoppers) were impacted in
their community structure (Batary et al. 2009). The relatively high
species richness on some Hungarian dike sides is probably due to
the infrequent mowing disturbance (Krausz et al. 1995).

Benefits of unmanaged sites

The structure of grassland provides an excellent habitat for Or-
thoptera when it is uncut (ungrazed and unmown,; Gardiner et al.
2015). In undisturbed patches on Essex sea walls (Fig. 9), locally
scarce species such as T: viridissima can be abundant. Ungrazed pas-
tures with tall grassland provide important refuges, like latrines,
for Orthoptera (Gardiner 2018). Indeed, an experiment showed
that C. parallelus nymphs and adults released in a heavily grazed
area dispersed to tall grass (Gardiner and Hill 2004). Gardiner and

Fig. 9. Undisturbed grassland on a sea wall folding; credit T. Gardiner.

Hill (2004) concluded that these directional movements reflected a
preference for ungrazed grass as a more favorable breeding habitat.

Grassland undisturbed for many years provided an impor-
tant habitat for large populations of Orthoptera, especially for
M. roeselii (Gardiner et al. 2015). On a sea wall, the uncut and
ungrazed folding next to the borrowdyke is the most important
habitat in terms of Orthoptera distribution (Fig. 9, Table 3).
Bush-crickets (Conocephalus spp. and M. roeselii) preferred tall
vegetation patches on the uncut folding and the landward slope.
Grasshoppers (especially C. brunneus and C. parallelus) preferred
the track disturbed by vehicle wheels because of the frequent
patches of bare earth probably used as basking and oviposition
sites. Soil disturbance is a key consideration in the conservation
of flood defense embankment Orthoptera, with trampling live-

Table 3. Orthoptera abundances recorded from five sections of a seawall (Brightlingsea, UK) using quadrat sampling (Gardiner et al. 2015).

Orthoptera species Folding (uncut) Folding (track) Landward Slope Crest Seaward slope TOTAL (%)
Conocephalus spp. 52: 0 35 0 wh 94 (13)
Pholidoptera griseoaptera 6 0 0 0 0 6 (1)
Chorthippus brunneus 1 31 EZ 3) 10 63 (9)
Chorthippus parallelus 15 32 15 0 3 65 (9)
Chorthippus albomarginatus 5 4 35 6 41 91 (12)
Metrioptera roeselii 236 170 il “ 415 (57)

TOTAL 315 68 267 16 68 734 (100)

Table 4. Advantages and disadvantages of three different grazing animals for grassland Orthoptera conservation and maintaining flood

defense integrity.

Advantages

Disadvantages

Sheep

Heterogeneous sward height'
Control scrub

Homogeneous, short sward?
Limited poaching

‘At low-medium stocking intensity.
°At high stocking intensity.

Cattle

Heterogeneous sward height!
Poaching creates bare ground
Control scrub

Homogeneous, short sward?
Damage to flood defense from poaching

JOURNAL OF ORTHOPTERA RESEARCH 2018, 27(1)

Horses
Heterogeneous sward height!
Poaching creates bare ground
Latrine areas
Control scrub
Homogeneous, short sward?
Damage to flood defense from poaching

K. FARGEAUD AND T. GARDINER

stock hooves providing the necessary disturbance in the absence
of vehicles (Table 4).

Dike habitats provide diverse resources, completely or incom-
pletely fulfilling resource requirements depending on the species
of Orthoptera (Gardiner et al. 2015). The main grazing animal on
European sea walls is sheep, which can be favorable for Orthoptera
when the stocking intensity is light-moderate establishing a hetero-
geneous sward (Table 4). However, Orthoptera may also be nega-
tively impacted at high stocking intensities due to the creation of a
uniformly short sward with few tall grass refuges (Table 4). It is ad-
visable to alternate grazing with mowing and to prefer sheep over
cattle and horses to minimize soil damage on the flood defense.

Conclusion

Flood defense embankments in Europe are commonly rich
in Orthoptera. In some cases, grazing can promote plant species
richness and favorable habitat for Orthoptera, including scarce
species such as G. glabra and T. ceperoi. Where high flood risk ex-
ists, dikes and sea walls are sometimes over-managed by heavy
grazing and/or mowing. Controlled management should aim to
establish a heterogeneous sward with varying grass heights. The
main criteria when deciding on the appropriate flood defense
embankment management for Orthoptera are: grazing duration,
stocking intensity (numbers of animals per hectare) and type of
livestock (Table 5). Without compromising the effectiveness of the
defense, a balance can be applied between management intensity
and conservation of the Orthoptera. Further research is needed
into the precise influence of sheep grazing on sea wall Orthoptera
throughout Europe, but particularly where there is a high propor-
tion of scarce and endangered species such as the Wadden Sea.

Table 5. Matrix to enable appropriate grazing and mowing regimes
to be chosen in relation to Orthoptera abundance and maintain-
ing flood defense integrity.

Low flood risk High flood risk
(farmland) (properties)
Low Orthoptera Oe Sheep+
abundance (<3/m7’) See Mowing+
Mowing-
High Orthoptera Rabbits* Sheep+
abundance (>3/m7) Sheep-

Key: - low intensity grazing (<10 sheep/ha) or mowing (1-2 cuts/yr)
+ high intensity grazing (>10 sheep/ha) or mowing (>2 cuts/yr)
* naturally occurring rabbits, not stocked

Acknowledgements

The authors wish to thank Roy Kleukers (EIS Kenniscentrum
Insecten en andere ongewervelden, Naturalis Biodiversity Center,
The Netherlands) for very useful discussions.

59

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