TY - JOUR A1 - Lasway, Julius V. A1 - Peters, Marcell K. A1 - Njovu, Henry K. A1 - Eardley, Connal A1 - Pauly, Alain A1 - Steffan‐Dewenter, Ingolf T1 - Agricultural intensification with seasonal fallow land promotes high bee diversity in Afrotropical drylands JF - Journal of Applied Ecology N2 - The exponential increase in the human population in tandem with increased food demand has caused agriculture to be the global‐dominant form of land use. Afrotropical drylands are currently facing the loss of natural savannah habitats and agricultural intensification with largely unknown consequences for bees. Here we investigate the effects of agricultural intensification on bee assemblages in the Afrotropical drylands of northern Tanzania. We disentangled the direct effects of agricultural intensification and temperature on bee richness from indirect effects mediated by changes in floral resources. We collected data from 24 study sites representing three levels of management intensity (natural savannah, moderate intensive and highly intensive agriculture) spanning an extensive gradient of mean annual temperature (MAT) in northern Tanzania. We used ordinary linear models and path analysis to test the effects of agricultural intensity and MAT on bee species richness, bee species composition and body‐size variation of bee communities. We found that bee species richness increased with agricultural intensity and with increasing temperature. The effects of agricultural intensity and temperature on bee species richness were mediated by the positive effects of agriculture and temperature on the richness of floral resources used by bees. During the off‐growing season, agricultural land was characterized by an extensive period of fallow land holding a very high density of flowering plants with unique bee species composition. The increase in bee diversity in agricultural habitats paralleled an increasing variation of bee body sizes with agricultural intensification that, however, diminished in environments with higher temperatures. Synthesis and applications. Our study reveals that bee assemblages in Afrotropical drylands benefit from agricultural intensification in the way it is currently practiced. However, further land‐use intensification, including year‐round irrigated crop monocultures and excessive use of agrochemicals, is likely to exert a negative impact on bee diversity and pollination services, as reported in temperate regions. Moreover, several bee species were restricted to natural savannah habitats. To conserve bee communities and guarantee pollination services in the region, a mixture of savannah and agriculture, with long periods of fallow land should be maintained. KW - bee abundance KW - bee body size KW - bee species richness KW - forage resources KW - inter‐tegular distance KW - mean annual temperature KW - northern Tanzania KW - species community composition Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-311877 VL - 59 IS - 12 SP - 3014 EP - 3026 ER - TY - JOUR A1 - Lasway, Julius V. A1 - Kinabo, Neema R. A1 - Mremi, Rudolf F. A1 - Martin, Emanuel H. A1 - Nyakunga, Oliver C. A1 - Sanya, John J. A1 - Rwegasira, Gration M. A1 - Lesio, Nicephor A1 - Gideon, Hulda A1 - Pauly, Alain A1 - Eardley, Connal A1 - Peters, Marcell K. A1 - Peterson, Andrew T. A1 - Steffan-Dewenter, Ingolf A1 - Njovu, Henry K. T1 - A synopsis of the Bee occurrence data of northern Tanzania JF - Biodiversity Data Journal N2 - Background Bees (Hymenoptera: Apoidea: Anthophila) are the most important group of pollinators with about 20,507 known species worldwide. Despite the critical role of bees in providing pollination services, studies aiming at understanding which species are present across disturbance gradients are scarce. Limited taxononomic information for the existing and unidentified bee species in Tanzania make their conservation haphazard. Here, we present a dataset of bee species records obtained from a survey in nothern Tanzania i.e. Kilimanjaro, Arusha and Manyara regions. Our findings serve as baseline data necessary for understanding the diversity and distribution of bees in the northern parts of the country, which is a critical step in devising robust conservation and monitoring strategies for their populations. New information In this paper, we present information on 45 bee species belonging to 20 genera and four families sampled using a combination of sweep-netting and pan trap methods. Most species (27, ~ 60%) belong to the family Halictidae followed by 16 species (35.5%) from the family Apidae. Megachilidae and Andrenidae were the least represented, each with only one species (2.2%). Additional species of Apidae and Megachilidae sampled during this survey are not yet published on Global Biodiversity Information Facility (GBIF), once they will be available on GBIF, they will be published in a subsequent paper. From a total of 953 occurrences, highest numbers were recorded in Kilimanjaro Region (n = 511), followed by Arusha (n = 410) and Manyara (n = 32), but this pattern reflects the sampling efforts of the research project rather than real bias in the distributions of bee species in northern Tanzania. KW - agriculture KW - bee pollinator KW - distribution KW - disturbance gradient KW - grazing KW - species diversity KW - Tanzania Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-265018 VL - 9 ER - TY - JOUR A1 - Njovu, Henry K. A1 - Steffan-Dewenter, Ingolf A1 - Gebert, Friederike A1 - Schellenberger Costa, David A1 - Kleyer, Michael A1 - Wagner, Thomas A1 - Peters, Marcell K. T1 - Plant traits mediate the effects of climate on phytophagous beetle diversity on Mt. Kilimanjaro JF - Ecology N2 - Patterns of insect diversity along elevational gradients are well described in ecology. However, it remains little tested how variation in the quantity, quality, and diversity of food resources influence these patterns. Here we analyzed the direct and indirect effects of climate, food quantity (estimated by net primary productivity), quality (variation in the specific leaf area index, leaf nitrogen to phosphorus and leaf carbon to nitrogen ratio), and food diversity (diversity of leaf traits) on the species richness of phytophagous beetles along the broad elevation and land use gradients of Mt. Kilimanjaro, Tanzania. We sampled beetles at 65 study sites located in both natural and anthropogenic habitats, ranging from 866 to 4,550 m asl. We used path analysis to unravel the direct and indirect effects of predictor variables on species richness. In total, 3,154 phytophagous beetles representing 19 families and 304 morphospecies were collected. We found that the species richness of phytophagous beetles was bimodally distributed along the elevation gradient with peaks at the lowest (˜866 m asl) and upper mid-elevations (˜3,200 m asl) and sharply declined at higher elevations. Path analysis revealed temperature- and climate-driven changes in primary productivity and leaf trait diversity to be the best predictors of changes in the species richness of phytophagous beetles. Species richness increased with increases in mean annual temperature, primary productivity, and with increases in the diversity of leaf traits of local ecosystems. Our study demonstrates that, apart from temperature, the quantity and diversity of food resources play a major role in shaping diversity gradients of phytophagous insects. Drivers of global change, leading to a change of leaf traits and causing reductions in plant diversity and productivity, may consequently reduce the diversity of herbivore assemblages. KW - plant functional traits KW - altitudinal gradient KW - Chrysomelidae KW - Curculionidae KW - diversity gradients KW - elevation gradient KW - functional diversity KW - herbivorous beetles KW - herbivory KW - more-individuals hypothesis KW - phytophagous beetles Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-257343 VL - 102 IS - 12 ER -