Northern geometrids and climate change: from abiotic factors to trophic interactions.

Pistachio nuts are an important economic tree nut crop which is used directly or processed for many food-related activities. They can become colonized by mycotoxigenic spoilage fungi, especially Aspergillus flavus, mainly resulting in contamination with aflatoxins (AFs), especially aflatoxin B1 (AFB1). The prevailing climate in which these crops are grown changes as temperature and atmospheric CO2 levels increase, and episodes of extreme wet/dry cycles occur due to human industrial activity. The objectives of this study were to evaluate the effect of interacting Climate Change (CC)-related abiotic factors of temperature (35 vs. 37 °C), CO2 (400 vs. 1000 ppm), and water stress (0.98–0.93 water activity, aw) on (a) growth (b) aflD and aflR biosynthetic gene expression and (c) AFB1 production by two strains A. flavus (AB3, AB10) in vitro on milled pistachio-based media and when colonizing layers of shelled raw pistachio nuts. The A. flavus strains were resilient in terms of growth on pistachio-based media and the colonisation of pistachio nuts with no significant difference when exposed to the interacting three-way climate-related abiotic factors. However, in vitro studies showed that AFB1 production was significantly stimulated (p < 0.05), especially when exposed to 1000 ppm CO2 at 0.98–0.95 aw and 35 °C, and sometimes in the 37 °C treatment group at 0.98 aw. The relative expression of the structural aflD gene involved in AFB1 biosynthesis was decreased or only slightly increased, relative to the control conditions at elevated CO, regardless of the aw level examined. For the regulatory aflR gene expression, there was a significant (p < 0.05) increase in 1000 ppm CO2 and 37 °C for both strains, especially at 0.95 aw. The in situ colonization of pistachio nuts resulted in a significant (p < 0.05) stimulation of AFB1 production at 35 °C and 1000 ppm CO2 for both strains, especially at 0.98 aw. At 37 °C, AFB1 production was either decreased, in strain AB3, or remained similar, as in strain AB10, when exposed to 1000 ppm CO2. This suggests that CC factors may have a differential effect, depending on the interacting conditions of temperature, exposure to CO2 and the level of water stress on AFB1 production.

Download Full-text

Repeated surveying over 6 years reveals that fine-scale habitat variables are key to tropical mountain ant assemblage composition and functional diversity

Scientific Reports ◽

10.1038/s41598-020-80077-8 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Mulalo M. Muluvhahothe ◽

Grant S. Joseph ◽

Colleen L. Seymour ◽

Thinandavha C. Munyai ◽

Stefan H. Foord

Keyword(s):

Climate Change ◽

Species Composition ◽

High Altitude ◽

Functional Diversity ◽

Large Scale ◽

Climate Models ◽

Spatial Scales ◽

Abiotic Factors ◽

Composition Analysis ◽

Fine Scale

AbstractHigh-altitude-adapted ectotherms can escape competition from dominant species by tolerating low temperatures at cooler elevations, but climate change is eroding such advantages. Studies evaluating broad-scale impacts of global change for high-altitude organisms often overlook the mitigating role of biotic factors. Yet, at fine spatial-scales, vegetation-associated microclimates provide refuges from climatic extremes. Using one of the largest standardised data sets collected to date, we tested how ant species composition and functional diversity (i.e., the range and value of species traits found within assemblages) respond to large-scale abiotic factors (altitude, aspect), and fine-scale factors (vegetation, soil structure) along an elevational gradient in tropical Africa. Altitude emerged as the principal factor explaining species composition. Analysis of nestedness and turnover components of beta diversity indicated that ant assemblages are specific to each elevation, so species are not filtered out but replaced with new species as elevation increases. Similarity of assemblages over time (assessed using beta decay) did not change significantly at low and mid elevations but declined at the highest elevations. Assemblages also differed between northern and southern mountain aspects, although at highest elevations, composition was restricted to a set of species found on both aspects. Functional diversity was not explained by large scale variables like elevation, but by factors associated with elevation that operate at fine scales (i.e., temperature and habitat structure). Our findings highlight the significance of fine-scale variables in predicting organisms’ responses to changing temperature, offering management possibilities that might dilute climate change impacts, and caution when predicting assemblage responses using climate models, alone.

Download Full-text

The Effects of Biotic and Abiotic Factors on the Community Dynamics in a Mountain Subtropical Forest

Forests ◽

10.3390/f12040427 ◽

2021 ◽

Vol 12 (4) ◽

pp. 427

Author(s):

Tianyang Zhou ◽

Jiaxin Zhang ◽

Yunzhi Qin ◽

Mingxi Jiang ◽

Xiujuan Qiao

Keyword(s):

Climate Change ◽

Ecosystem Services ◽

Forest Dynamics ◽

Community Dynamics ◽

Abiotic Factors ◽

Subtropical Forest ◽

Above Ground Biomass ◽

Short Term ◽

Forest Ecosystem Services ◽

Number Of Individuals

From supporting wood production to mitigating climate change, forest ecosystem services are crucial to the well-being of humans. Understanding the mechanisms that drive forest dynamics can help us infer how to maintain forest ecosystem services and how to improve predictions of forest dynamics under climate change. Despite the growing number of studies exploring above ground biomass (AGB) dynamics, questions of dynamics in biodiversity and in number of individuals still remain unclear. Here, we first explored the patterns of community dynamics in different aspects (i.e., AGB, density and biodiversity) based on short-term (five years) data from a 25-ha permanent plot in a subtropical forest in central China. Second, we examined the relationships between community dynamics and biodiversity and functional traits. Third, we identified the key factors affecting different aspects of community dynamics and quantified their relative contributions. We found that in the short term (five years), net above ground biomass change (ΔAGB) and biodiversity increased, while the number of individuals decreased. Resource-conservation traits enhanced the ΔAGB and reduced the loss in individuals, while the resource-acquisition traits had the opposite effect. Furthermore, the community structure contributed the most to ΔAGB; topographic variables and soil nutrients contributed the most to the number of individuals; demographic process contributed the most to biodiversity. Our results indicate that biotic factors mostly affected the community dynamics of ΔAGB and biodiversity, while the number of individuals was mainly shaped by abiotic factors. Our work highlighted that the factors influencing different aspects of community dynamics vary. Therefore, forest management practices should be formulated according to a specific protective purpose.

Download Full-text

Evolutionary responses to environmental change: trophic interactions affect adaptation and persistence

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2014.1351 ◽

2015 ◽

Vol 282 (1805) ◽

pp. 20141351 ◽

Cited By ~ 14

Author(s):

Jarad P. Mellard ◽

Claire de Mazancourt ◽

Michel Loreau

Keyword(s):

Climate Change ◽

Head Start ◽

Trophic Interactions ◽

Evolutionary Dynamics ◽

Plant Interaction ◽

Persistence Time ◽

Plant Persistence ◽

Plant Herbivore Interaction ◽

Plant Herbivore ◽

Herbivore Interaction

According to recent reviews, the question of how trophic interactions may affect evolutionary responses to climate change remains unanswered. In this modelling study, we explore the evolutionary dynamics of thermal and plant–herbivore interaction traits in a warming environment. We find the herbivore usually reduces adaptation speed and persistence time of the plant by reducing biomass. However, if the plant interaction trait and thermal trait are correlated, herbivores can create different coevolutionary attractors. One attractor has a warmer plant thermal optimum, and the other a colder one compared with the environment. A warmer plant thermal strategy is given a head start under warming, the only case where herbivores can increase plant persistence under warming. Persistence time of the plant under warming is maximal at small or large thermal niche width. This study shows that considering trophic interactions is necessary and feasible for understanding how ecosystems respond to climate change.

Download Full-text

Trophic Interactions and Climate Change

Agroecosystems in a Changing Climate ◽

10.1201/9781420003826-16 ◽

2006 ◽

pp. 245-274

Keyword(s):

Climate Change ◽

Trophic Interactions

Download Full-text

Wood Ants: Important Components of the Forest "Immunity System"

10.21203/rs.3.rs-200088/v1 ◽

2021 ◽

Author(s):

Gema Trigos-Peral ◽

Orsolya Juhász ◽

Péter János Kiss ◽

Gábor Módra ◽

Anna Tenyér ◽

...

Keyword(s):

Climate Change ◽

Pest Control ◽

Bark Beetles ◽

Abiotic Factors ◽

Biological Pest Control ◽

European Forests ◽

Biotic And Abiotic Factors ◽

Red Wood Ants ◽

Wood Ants ◽

Wood Boring

Abstract Climate change is one of the major threats to biodiversity, but its impact varies among the species. Bark beetles (Ips spp.), as well as other wood-boring pests of European forests, show escalating numbers in response to the changes driven by climate change and seriously affect the survival of the forests through the massive killing of trees. Many methods were developed to control these wood-boring beetles, however, their implementation can be detrimental for other forest specialists. Ants are widely used for biological pest-control, so in our study, we aimed to test the effect of F. polyctena on the control of the wood-boring beetles. The results show that the proportion of infested trees is significantly reduced by the increase of the number of F. polyctena nests, with a strong effect on Ips species. We also show that the boring beetle community is shaped by different biotic and abiotic factors, including the presence of F. polyctena nests. However, the boring beetle infestation was not related to the latitude, altitude and age of the forests. Based on our results, we assert the effectiveness of the red wood ants as biological pest control and the importance of their conservation to keep the health of the forests.

Download Full-text

Impacts of climate change on trophic interactions in grasslands

Grasslands and Climate Change ◽

10.1017/9781108163941.013 ◽

2019 ◽

pp. 188-202 ◽

Cited By ~ 3

Author(s):

Sue E. Hartley ◽

Colin Beale

Keyword(s):

Climate Change ◽

Trophic Interactions ◽

Impacts Of Climate Change

Download Full-text

Invasion-mediated effects on marine trophic interactions in a changing climate: positive feedbacks favour kelp persistence

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2018.2866 ◽

2019 ◽

Vol 286 (1899) ◽

pp. 20182866 ◽

Cited By ~ 5

Author(s):

Ricardo J. Miranda ◽

Melinda A. Coleman ◽

Alejandro Tagliafico ◽

Maria S. Rangel ◽

Lea T. Mamo ◽

...

Keyword(s):

Climate Change ◽

Trophic Interactions ◽

Multiple Stressors ◽

Grazing Intensity ◽

Ocean Warming ◽

Interactive Effects ◽

Ecological Change ◽

Climate Change Scenarios ◽

Ecological Consequences ◽

Management Actions

The interactive effects of ocean warming and invasive species are complex and remain a source of uncertainty for projecting future ecological change. Climate-mediated change to trophic interactions can have pervasive ecological consequences, but the role of invasion in mediating trophic effects is largely unstudied. Using manipulative experiments in replicated outdoor mesocosms, we reveal how near-future ocean warming and macrophyte invasion scenarios interactively impact gastropod grazing intensity and preference for consumption of foundation macroalgae ( Ecklonia radiata and Sargassum vestitum ). Elevated water temperature increased the consumption of both macroalgae through greater grazing intensity. Given the documented decline of kelp ( E. radiata ) growth at higher water temperatures, enhanced grazing could contribute to the shift from kelp-dominated to Sargassum -dominated reefs that is occurring at the low-latitude margins of kelp distribution. However, the presence of a native invader ( Caulerpa filiformis ) was related to low consumption by the herbivores on dominant kelp at warmer temperatures. Thus, antagonistic effects between climate change and a range expanding species can favour kelp persistence in a warmer future. Introduction of species should, therefore, not automatically be considered unfavourable under climate change scenarios. Climatic changes are increasing the need for effective management actions to address the interactive effects of multiple stressors and their ecological consequences, rather than single threats in isolation.

Download Full-text

CLIMATE CHANGE UNCOUPLES TROPHIC INTERACTIONS IN AN AQUATIC ECOSYSTEM

Ecology ◽

10.1890/04-0151 ◽

2004 ◽

Vol 85 (8) ◽

pp. 2100-2106 ◽

Cited By ~ 492

Author(s):

Monika Winder ◽

Daniel E. Schindler

Keyword(s):

Climate Change ◽

Trophic Interactions ◽

Aquatic Ecosystem

Download Full-text

Nitrogen fixation beyond leguminous plants: characterising overlooked plant-bacteria associations in the light of climate change

10.5194/egusphere-egu2020-103 ◽

2020 ◽

Author(s):

Kathrin Rousk

Keyword(s):

Climate Change ◽

Nitrogen Fixation ◽

Community Composition ◽

Abiotic Factors ◽

Arctic Tundra ◽

The Arctic ◽

Mean Annual Precipitation ◽

Precipitation Gradient ◽

Cyanobacterial Community ◽

Moss Species

Nitrogen (N2) fixation performed by moss-associated cyanobacteria is one of the main sources of new N in pristine, high latitude ecosystems like boreal forests and arctic tundra. Here, mosses and associated cyanobacteria can contribute more than 50% to total ecosystem N input. However, N2 fixation in mosses is strongly influenced by abiotic factors, in particular moisture and temperature. Hence, climate change will significantly affect this key ecosystem process in pristine ecosystems. Here,&#160;I will present a synthesis of several field and laboratory assessments of moss-associated N2 fixation in response to climate change by manipulating moisture and temperature in subarctic and arctic tundra.Both in a long-term climate warming experiment in the arctic, and along a continental climate gradient, spanning arctic, subarctic and temperate ecosystems, increased temperatures (up to 30 &#176;C) lead to either no effect or decreased N2 fixation rates in different moss species. Yet, N2 fixation rates were strongly dependent on moss-moisture, which seems to be a more important driver of N2 fixation in mosses than temperature.In another set of studies, two dominant moss species (Hylocomium splendens, Pleurozium schreberi) were collected from a steep precipitation gradient (400-1200 mm mean annual precipitation, MAP) in the Subarctic close to Abisko, Northern Sweden, and were incubated at different moisture and temperature levels in the laboratory. Nitrogen fixation, cyanobacterial abundance (via qPCR) and cyanobacterial community composition (via sequencing) on the mosses were assessed. Moisture and temperature interacted strongly to control moss-associated N2 fixation rates, and the highest activity was found at the wet end of the precipitation gradient. Although cyanobacterial abundance was higher in one of the investigated mosses (H. splendens), translating into higher N2 fixation rates, cyanobacterial community composition did not differ between the two moss species. Nostoc was the most common cyanobacterial genera on both mosses, and hardly any methanotrophic N2 fixing bacteria were found on the mosses along the precipitation gradient. Increased temperatures lead to increased abundances of certain cyanobacterial genera (Cylindrospermum and Nostoc), while others declined in response to warming. Hence, cyanobacterial communities colonizing mosses will be dominated by a few cyanobacteria species in a warmer climate, and temperature and moisture interact strongly to affect their activity. Thus, these two major climate change factors should be considered in unison when estimating climate change effects on key ecosystem processes such as N2 fixation. Further, host identity determines cyanobacterial abundance, and thereby, N2 fixation rates.&#160;&#160;&#160;

Download Full-text