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Dung beetles are coprophagous insects belonging to the families Scarabaeidae and
Geotrupidae. They are a very important insects’ group, acting as significant ecosystem
engineers through dung burial, decomposition, nutrient cycling, bioturbation and seed dispersal
in natural and human managed systems. Despite these benefits, most essential ecosystem
services are not economically quantified and as such, their roles as natural capital in natural
and human managed systems have largely been neglected. To date, the global climate change
and anthropogenic activities such as the widespread use of synthetic pesticides for livestock
endo- and ectoparasites, has largely led to loss of or shifts in some the biodiversity and richness
of this natural capital. It has been hypothesised that in order to determine a suitable time for
activity, insects may monitor environmental variables such as light, temperature and diel events
such as sunrise and sunset. However, information on how environmental stress resistance may
influence diel activity times and ecosystem services provision remains scant, especially on
dung beetles in arid, tropical environments such as Botswana that are more vulnerable to the
impacts of climate change and associated anthropogenic activities. This work is therefore
aimed at investigating i) the diversity and activity patterns of dung beetle species in Botswana
(ii) the effects of temperature (and adaptation mechanisms thereof) as an environmental
variable in influencing activity times and (iii) implications on ecological services provision.
This study found that Botswana is richly abundant with Scarabaeinae dung beetles belonging
to 8 tribes namely, Canthonini, Coprini, Dichotomini, Gymnopleurini, Oniticellini, Onitini,
Onthophagini and Carabaeini. Most of the species belong to the Onthophagini tribe, and this
tribe comprised the most abundant species. Coprini and Scarabaeini were however the least
abundant tribes. Furthermore, the study also found that small-bodied beetles from the
Gymopleurini tribe such as Allogymnopleurus indicageous, Gymnopleurus aenescens and
Gymnopleurus ignitus preferred diurnal activity, compared to large-bodied beetles from the
Coprini tribe (Copris elephenor and Catharsius calaharis), and the Scarabaeini tribe
(Scarabaeus zambezianus, Scarabaeus goryi) which preferred crepuscular/nocturnal activity
(Chapter 2). Second, an investigation between activity time and temperature tolerancefound
that day active dung beetle species generally had higher maximum temperatures for activity
measured as critical thermal maxima (CTmax) than crepuscular and nocturnal species. This
implies that heat may significantly play a role in choice of diel activity time in dung beetle
species by constraining some species to be active at specific period of the day corresponding
to their thermal limitations. However, there was no clear correlation between body mass and
CTmax suggesting complex associations across species, body mass and heat tolerance that
warrants further investigation (Chapter 3). Third, this study revealed that tropical dung beetles’
physiological and ecological activities were generally negatively affected by low temperatures.
Results showed that low temperature stress may offset dung beetles’ ecological services
through reduction in dung removal. Dung ball creation between diurnal and nocturnal species
interacted with temperature, with diurnal species producing significantly fewer balls at low
temperatures, whilst nocturnal beetles were not significantly affected (Chapter 4). Fourth,
based on the trade-off theory, plastic responses to variable high (VT-H) and variable low
temeperatures (VT-L) were investigated in a day active dung beetle, Allogymnopleurus
thalassinus. Results showed that effects of acclimation were significant for heat tolerance,
significantly increasing and reducing CTmax values for variable temperature high (VT-H) and
variable temperature low (VT-L) respectively. Similarly, effects of acclimation on HKDT were
significant, with variable temperature high significantly increasing HKDT, while variable
temperature low reduced HKDT. In addition, effects of acclimation on ecological traits showed
that beetles acclimated to variable high temperatures were ecologically more efficient in their
ecosystem function (dung removal) compared to those acclimated at variable low temperatures.
Allogymnopleurus thalassinus nevertheless, had low acclimation response ratios, signifying
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limited scope for complete plasticity for ULTs tested here. This result supports the 'trade-off'
theory, and that observed limited plasticity may unlikely buffer A. thalassinus against effects
of climate change, and by extension, albeit with caveats to other tropical ecological service
providing insect species (Chapter 5). Fifth, functional responses experiments were conducted
to help quantify the effects of increasing mean temperatures consequence of climate change
and dung beetle species density on dung removal, an essential ecosystem service on three
telecoprid species: Allogymnopleurus indigaceous, Scarabaeus zambezianus and Khepher
prodigiosus (Chapter 6). Results showed that K. prodigiosus, exhibited greatest dung utilisation
efficiency overall across dung masses, compared to the other two species. Nevertheless, both
S. zambezianus and A. indigaceous utilization increased with both warming and beetle density,
whereas K. prodigiosus performance was less temperature and density-dependent. Results on
dung ball number differed across species and correlated positively with temperature and
densities, with S. zambezianus producing significantly most balls overall. These results show
that temperature and competition largely have a significant effect on dung beetle species’
fitness and thus functional efficiency and ecosystem service delivery. This work provides
insights on the survival mechanisms of tropical species against environmental stress and
provides a framework for the conservation of these natural capital species that inhabit arid
environments under rapidly changing environmental climate. Such studies are critical in
serving as early warning systems for predicting the potential effects of climate change on
biodiversity and fore warning against threats to the integrity of ecosystems and their essential
services. Incorporation of such scientific information in conservation policies may help
safeguard this neglected but essential natural capital and consequently ecological services provision in the future. |
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