Bale Mountains Research Articles

GIS and remote sensing-based wildlife habitat suitability analysis for mountain nyala (Tragelaphus buxtoni) species mapping at Bale Mountains National Park, Ethiopia

Ethiopia's Bale Mountains National Park protects the continent's largest remaining alpine environments. This park was first suggested in 1973 to safeguard its great biodiversity, including the endangered Mountain Nyala (Tragelaphus buxtoni) and Red Foxes. Despite these conservation measures, the lack of infrastructure and the enormous area projected have resulted in significant wildlife habitat fragmentation. The purpose of this study is to analyse the habitat appropriateness of the Mountain Nyala in Bale Mountains National Park using GIS and remote sensing technologies in order to inform conservation efforts and assist park managers in making decisions. To identify potential habitats for the Mountain Nyala, the study employed GIS spatial analyst techniques such as the Digital Elevation Model (DEM) and Landsat 9 (OLI/TIRS) data, as well as key environmental factors such as vegetation types, soil types, topographic factors (elevation and slope), climate factors (temperature), and proximity factors (distance to settlements, roads, and rivers). The Weights of these factors was calculated using IDRISI32 Multi-Criteria Evaluation (MCE) with the pair-wise comparison method. These weighted factor maps were then integrated through weighted overlay analysis to model wildlife habitat suitability. The analysis revealed five classes of habitat suitability; of the total land area studied, 1326.7 km2 (60%) was deemed suitable for the Mountain Nyala while 881.3 km2 (40%) was unsuitable. Specifically, 327.4 km2 (15%) was classified as highly suitable, 240.7 km2 (11%) as moderately suitable, 758.6 km2 (34%) as marginally suitable, 352.4 km2 (16%) as currently not suitable, and 528.9 km2 (24%) as permanently not suitable. The majority of suitable habitats are concentrated in the northern part of the park, along the western border, and in the Harrena forest area. This study provides vital insights into habitat suitability that are crucial for the conservation of the Mountain Nyala and the overall management of the park.

New species and record of oribatid mites (Acari, Oribatida) from highlands bamboo location in Ethiopia

The present study is based on oribatid mite material collected from litter in highlands bamboo location in Bale Mountains National Park, Southeastern Ethiopia. A list of 35 species belonging to 27 genera and 19 families is presented; of these, Nothrus berlesei and Dolicheremaeus capillatus neonominatus are recorded in Ethiopia for the first time. Two new species—Coronabelba pustulata Ermilov sp. nov. and Suctobelbila quattuor Ermilov sp. nov.—are described. Coronabelba pustulata differs from the other congeneric species by the presence of densely tuberculate dorsal part of the notogaster, bordered by two longitudinal ridges. Suctobelbila quattuor differs from the other congeneric species by the presence of four longitudinal cerotegumental bands represented by sparse granules connected by cerotegumental cords on the notogaster.

New faunistic and taxonomic data on oribatid mites (Acari, Oribatida) from Ethiopia: results of the Joint Russian-Ethiopian Biological Expedition in Bale Mountains National Park (2023)

The present study is based on oribatid mite materials collected from Bale Mountains National Park, Southeastern Ethiopia in 2023. A list of 71 species belonging to 44 genera and 29 families is presented; of these, nine species, three genera and two families are reported in Ethiopia for the first time. Two new species—Brachioppiella (Brachioppiella) sanettiensis Ermilov n. sp. and Drymobatoides harennaensis Ermilov n. sp.—are described.

Paleoclimate reconstruction using biomarker and stable isotope analyses of lake sediments in the Bale Mountains, Ethiopia

Paleoclimate reconstruction using biomarker and stable isotope analyses of lake sediments in the Bale Mountains, Ethiopia

Analyses of LULC dynamics in a socio-ecological system of the Bale Mountains Eco Region of Southeast Ethiopia.

Analysis of land use and land cover (LULC) change and its drivers and impacts in the biodiversity hotspot of Bale Mountain's socio-ecological system is crucial for formulating plausible policies and strategies that can enhance sustainable development. The study aimed to analyze spatio-temporal LULC changes and their trends, extents, drives, and impacts over the last 48 years in the Bale Mountain social-ecological system. Landsat imagery data from the years 1973, 1986, 1996, 2014, and 2021 together with qualitative data were used. LULC classification scheme employed a supervised classification method with the application of the maximum likelihood algorithm technique. In the period between 1973 and 2021, agriculture, bare land, and settlement showed areal increment by 153.13%, 295.57%, and 49.03% with the corresponding increased annual rate of 1.93%, 2.86%, and 0.83%, respectively. On the contrary, forest, wood land, bushland, grass land, and water body decreased by 29.97%, 1.36%, 28.16%, 8.63%, and 84.36% during the study period, respectively. During the period, major LULC change dynamics were also observed; the majority of woodland was converted to agriculture (757.8 km2) and grassland (531.3 km2); and forests were converted to other LULC classes, namely woodland (766.5 km2), agriculture (706.1 km2), grassland (34.6 km2), bushland (31.9 km2), settlement (20.5 km2), and bare land (14.3 km2). LULC changes were caused by the expansion of agriculture, settlement, overgrazing, infrastructure development, and fire that were driven by population growth and climate change, and supplemented by inadequate policy and institutional factors. Social and environmental importance and values of land uses and land covers in the study area necessitate further assessment of potential natural resources' user groups and valuation of ecosystem services in the study area. Hence, we suggest the identification of potential natural resource-based user groups, and assessment of the influence of LULC changes on ecosystem services in Bale Mountains Eco Region (BMER) for the sustainable use and managements of land resources.

Giant root-rat engineering and livestock grazing activities regulate plant functional trait diversity of an Afroalpine vegetation community in the Bale Mountains, Ethiopia

Disturbances from rodent engineering and human activities profoundly impact ecosystem structure and functioning. Whilst we know that disturbances modulate plant communities, comprehending the mechanisms through which rodent and human disturbances influence the functional trait diversity and trait composition of plant communities is important to allow projecting future changes and to enable informed decisions in response to changing intensity of the disturbances. Here, we evaluated the changes in functional trait diversity and composition of Afroalpine plant communities in the Bale Mountains of Ethiopia along gradients of engineering disturbances of a subterranean endemic rodent, the giant root-rat (Tachyoryctes macrocephalus Rüppell 1842) and human activities (settlement establishment and livestock grazing). We conducted RLQ (co-inertia analysis) and fourth-corner analyses to test for trait-disturbance (rodent engineering/human activities) covariation. Overall, our results show an increase in plant functional trait diversity with increasing root-rat engineering and increasing human activities. We found disturbance specific association with traits. Specifically, we found strong positive association of larger seed mass with increasing root-rat fresh burrow density, rhizomatous vegetative propagation negatively associated with increasing root-rat old burrow, and stolonifereous vegetative propagation positively associated with presence of root-rat mima mound. Moreover, both leaf size and leaf nitrogen content were positively associated with livestock dung abundance but negatively with distance from settlement. Overall, our results suggest that disturbances by rodents filter plant traits related to survival and reproduction strategies, whereas human activities such as livestock grazing act as filters for traits related to leaf economics spectrum along acquisitive resource-use strategy.

Long-Term Impacts of Glacier Retreat on Downstream Water Availability in Ethiopia

Purpose: The aim of the study was to examine Long-Term Impacts of Glacier Retreat on Downstream Water Availability in Ethiopia. Methodology: This study adopted a desk methodology. A desk study research design is commonly known as secondary data collection. This is basically collecting data from existing resources preferably because of its low cost advantage as compared to a field research. Our current study looked into already published studies and reports as the data was easily accessed through online journals and libraries. Findings: The study revealed that as glaciers continue to shrink due to climate change, the hydrological systems in mountainous regions of Ethiopia, such as the Simien Mountains and Bale Mountains, face disruptions in water supply, affecting both local communities and downstream users. The reduction in glacial meltwater contributes to decreased streamflow, altered river regimes, and increased variability in water availability, exacerbating water stress in a country already prone to droughts and water scarcity. Moreover, glacier retreat affects ecosystems, biodiversity, and livelihoods dependent on freshwater resources, further amplifying socio-economic vulnerabilities in the region. Unique Contribution to Theory, Practice and Policy: Climate Change Theory, Hydrological Cycle Theory & Systems Theory may be used to anchor future studies on Long-Term Impacts of Glacier Retreat on Downstream Water Availability in Ethiopia. Implement cutting-edge technologies for real-time monitoring of glacier melt and downstream water flow. Use satellite imagery, remote sensing, and IoT sensors to gather data that can inform water management practices in real time. Develop and enforce policies that ensure sustainable water use and prioritize the maintenance of water quality and ecosystem health. This includes setting limits on water withdrawals based on sustainability criteria and enhancing the legal frameworks protecting water rights.

Investigated the role of community based approaches for biodiversity conservation and socio-economic development in Bale Mountains National Park, Southeast Ethiopia

Community based conservation approaches are the holistic way to ensure appropriate biodiversity conservation and livelihood improvement in many protected areas across the world. However involvement of local community in conservation activities and benefit sharing in many protected areas are not well implemented. The purpose of this study is to investigate the role of community based conservation approaches for biodiversity conservation and socio-economic development. To address the stated objectives, required data were gathered from both primary and secondary sources. The result of the study revealed that parks provide various benefits for the local communities which are found in and adjacent to the park. Regarding perceived benefits from park, there was significant difference among community based association and non-community based association at (X2 = 92.071, df = 1, P < 0.05) while no significant difference was observed across kebeles. In spite of variation in perception among local community on park conservation, it was revealed that the communities contribute towards conservation of the park by controlling outbreak of fire and informing wildlife attack. Regarding strengths and weakness of community based conservation approaches as the finding indicated that internal factors out weight the external factors which imply that implementing the approaches is crucial for successful conservation of the park.

Multispectral analysis-ready satellite data for three East African mountain ecosystems

The East African mountain ecosystems are facing increasing threats due to global change, putting their unique socio-ecological systems at risk. To monitor and understand these changes, researchers and stakeholders require accessible analysis-ready remote sensing data. Although satellite data is available for many applications, it often lacks accurate geometric orientation and has extensive cloud cover. This can generate misleading results and make it unreliable for time-series analysis. Therefore, it needs comprehensive processing before usage, which encompasses multi-step operations, requiring large computational and storage capacities, as well as expert knowledge. Here, we provide high-quality, atmospherically corrected, and cloud-free analysis-ready Sentinel-2 imagery for the Bale Mountains (Ethiopia), Mounts Kilimanjaro and Meru (Tanzania) ecosystems in East Africa. Our dataset ranges from 2017 to 2021 and is provided as monthly and annual aggregated products together with 24 spectral indices. Our dataset enables researchers and stakeholders to conduct immediate and impactful analyses. These applications can include vegetation mapping, wildlife habitat assessment, land cover change detection, ecosystem monitoring, and climate change research.

Long-Term Volumetric Change Estimation of Red Ash Quarry Sites in the Afro-Alpine Ecosystem of Bale Mountains National Park in Ethiopia

The Bale Mountains National Park (BMNP) in Ethiopia comprises the largest fraction of the Afro-Alpine ecosystem in Africa, which provides vital mountain ecosystem services at local, regional, and global levels. However, the BMNP has been severely threatened by natural and anthropogenic disturbances in recent decades. In particular, landscape alteration due to human activities such as red ash quarrying has become a common practice in the BMNP, which poses a major environmental challenge by severely degrading the Afro-Alpine ecosystem. This study aims to quantify the long-term volumetric changes of two red ash quarry sites in the BMNP using historical aerial photographs and in situ data, and to assess their impact on the Afro-Alpine ecosystem. The Structure-from-Motion multi-view stereo photogrammetry algorithm was used to reconstruct the three-dimensional landscape for the year 1967 and 1984 while spatial interpolation techniques were applied to generate the current digital elevation models for 2023. To quantify the volumetric changes and landscape alteration of the quarry sites, differences in digital elevation models were computed. The result showed that the volume of resources extracted from the BMNP quarry sites increased significantly over the study period from 1984 to 2023 compared with the period from 1967 to 1984. In general, between 1967 and 2023, the total net surface volume of the quarry sites decreased by 503,721 ± 27,970 m3 and 368,523 ± 30,003 m3, respectively. The extent of the excavated area increased by 53,147 m2 and 45,297 m2 for Site 1 and 2, respectively. In terms of habitat loss, major gravel road construction inside the BMNP resulted in the reduction of Afro-Alpine vegetation by 476,860 m2, ericaceous vegetation by 403,806 m2 and Afromontane forest by 493,222 m2 with associated decline in species diversity and density. The excavation and gravel road construction have contributed to the degradation of the Afro-Alpine ecosystem, especially the endemic Lobelia rhynchopetalum on the quarry sites and roads. If excavation continues at the same rate as in the last half century, it can threaten the whole mountain ecosystem of the National Park and beyond, highlighting the importance of preventing these anthropogenic changes and conserving the remaining Afro-Alpine ecosystem.

Topographic barriers drive the pronounced genetic subdivision of a range-limited fossorial rodent.

Due to their limited dispersal ability, fossorial species with predominantly belowground activity usually show increased levels of population subdivision across relatively small spatial scales. This may be exacerbated in harsh mountain ecosystems, where landscape geomorphology limits species' dispersal ability and leads to small effective population sizes, making species relatively vulnerable to environmental change. To better understand the environmental drivers of species' population subdivision in remote mountain ecosystems, particularly in understudied high-elevation systems in Africa, we studied the giant root-rat (Tachyoryctes macrocephalus), a fossorial rodent confined to the afro-alpine ecosystem of the Bale Mountains in Ethiopia. Using mitochondrial and low-coverage nuclear genomes, we investigated 77 giant root-rat individuals sampled from nine localities across its entire ~1000 km2 range. Our data revealed a distinct division into a northern and southern group, with no signs of gene flow, and higher nuclear genetic diversity in the south. Landscape genetic analyses of the mitochondrial and nuclear genomes indicated that population subdivision was driven by slope and elevation differences of up to 500 m across escarpments separating the north and south, potentially reinforced by glaciation of the south during the Late Pleistocene (~42,000-16,000 years ago). Despite this landscape-scale subdivision between the north and south, weak geographic structuring of sampling localities within regions indicated gene flow across distances of at least 16 km at the local scale, suggesting high, aboveground mobility for relatively long distances. Our study highlights that despite the potential for local-scale gene flow in fossorial species, topographic barriers can result in pronounced genetic subdivision. These factors can reduce genetic variability, which should be considered when developing conservation strategies.

Helminth Parasite Prevalence in the Endangered Ethiopian Wolf (Canis simensis) in Web Valley, Bale Mountains National Park, Ethiopia.

Ethiopian wolves (EWs), Canis simensis, are the rarest canids in the world and Africa's most endangered carnivore, found in only six isolated habitat fragments in the highlands of Ethiopia. Previous reports on the prevalence of parasites in the EW in Bale Mountains National Park (BMNP) are limited, with little information on their helminth fauna. This study seeks to understand the prevalence of helminth parasites in the EW in BMNP, Ethiopia. In this study, fecal samples were collected from 43 EWs in Web Valley (WV), BMNP, from June to October 2020, and the presence of helminth eggs was assessed using fecal sedimentation and centrifugal floatation methods with microscopy. Forty-two out of 43 fecal samples from wolves (98%) contained eggs from two taxonomic groups of helminths. Eggs from Capillaria spp. and Trichuris vulpis were found most frequently, followed by Toxocara canis, Diphyllobothrium spp., Toxascaris leonina, and Capillaria aerophila. One EW (2%) was recorded for harboring the cestode Moniezia expansa. About 9 of the 43 EWs (21%) presented monospecific infection: 9 EWs (21%) harbored 2 parasite species, 9 EWs (21%) hosted 3 parasite species, 11 EWs (26%) had infection involving 4 parasite species, 2 EWs (5%) were infected with 5 parasite species, 1 EW (2%) presented 6 parasite species, 1 EW (2%) harbored 7 parasite species, and 1 EW (2%) was diagnosed without parasite species. Concurrent helminth infection was highly associated with female EW. Megeti 3 was associated with a low level of concurrent helminth infection. The prevalence of helminth parasites found in wolves in the study area suggests that the environment is highly contaminated with intestinal parasites. Regular control of parasite transmission in EW, domestic dogs, and humans in and around BMNP, public education, and further parasite epidemiological studies must be conducted.

One size fits all: How the “Ethiopian Highlands” made Bale Mountains National Park inscrutable

The categories we use to make sense of a place are never neutral. Scientific classifications can maintain ignorance about some aspects of a landscape, even as they create knowledge about others. This article considers this in the context of Ethiopia's Bale Mountains National Park, a landscape whose hydrologic and socio-cultural characteristics have been made inscrutable through the convergence of imperial legacies, processes of knowledge production, and complex biophysical properties. We use the example to conduct a genealogy of the notion of the “Ethiopian Highlands” and its associated metaphors, tracing the political-economic, biophysical, and epistemic factors by which this category came into use, and how these intersected to maintain a particular yet partial vision of the region. By critically analyzing bibliometric data, historical sources, and chains of reasoning in the scientific literature, we show how a small group of foreign experts erroneously conflated the landscapes, peoples, and environmental concerns of one area with those of another. Together these forces reify imperial gazes, perpetuate degraded wilderness narratives, and overlook significant geologic, (paleo)climatic, sociocultural, and land use differences. The result is a simplistic understanding of a distinct hydrosocial landscape, the perpetuation of conflict and resentment, and poorer conservation outcomes.

High-resolution digital elevation models and orthomosaics generated from historical aerial photographs (since the 1960s) of the Bale Mountains in Ethiopia

Abstract. The natural resources of Ethiopian high-altitude ecosystems are commonly perceived as increasingly threatened by devastating land-use practices owing to decreasing lowland resources. Quantified time-series data of the course of land-use cover changes are still needed. Very-high-resolution digital data on the historical landscape over recent decades are needed to determine the impacts of changes in afro-alpine ecosystems. However, digital elevation models (DEMs) and orthomosaics do not exist for most afro-alpine ecosystems of Africa. We processed the only available and oldest historical aerial photographs for Ethiopia and any afro-alpine ecosystem. Here, we provide a DEM and an orthomosaic image for the years 1967 and 1984 for the Bale Mountains in Ethiopia, which comprise the largest afro-alpine ecosystem in Africa. We used 298 historical aerial photographs captured in 1967 and 1984 for generating DEMs and orthomosaics with a structure-from-motion multi-view stereo photogrammetry workflow along an elevation gradient from 977 to 4377 m above sea level (a.s.l.) at very high spatial resolutions of 0.84 m and 0.98 m for the years 1967 and 1984, respectively. The structure-from-motion multi-view stereo photogrammetry workflow, employed with Agisoft Metashape, represents a modern approach that combines computer vision and photogrammetry. This method proves useful for reconstructing DEMs and orthomosaics from historical aerial photographs, with a focus on high spatial resolution. To validate the accuracy of the reconstructed DEMs, ground control points gathered through GPS measurements were used, resulting in root mean square error (RMSE) values of 3.55 m for the year 1967 and 3.44 m for the year 1984. Our datasets can be used by researchers and policymakers for watershed management, as the area provides water for more than 30 million people, landscape management, detailed mapping, and analysis of geological and archaeological features as well as natural resources, analyses of geomorphological processes, and biodiversity research. All the datasets are available online at https://doi.org/10.5281/zenodo.7271617 (Muhammed et al., 2022a) for all the inputs used and at https://doi.org/10.5281/zenodo.7269999 (Muhammed et al., 2022b) for the results obtained (very-high-resolution DEMs and orthomosaics) for both the years 1967 and 1984.

Seeing beyond the frames we inherit: A challenge to tenacious conservation narratives

Abstract Natural and social scientists everywhere are struggling to understand how to proceed in the face of continued biodiversity loss and the injustices brought upon people living in and around conservation landscapes. This has resulted in increasing calls for critical reflection on the narratives driving conservation research and practice. Narratives can be understood as part of a larger process of “framing” within an intellectual community, which includes the way studies are defined and discussed. Identifying, reflecting on and even destabilizing entrenched frames can be helpful for understanding when and where our diagnosis or understanding of a problem fails. However, we also need to understand the scholarly processes that create and reify some frames (and not others) over time. We address these needs by developing a mixed‐method approach that integrates qualitative frame analysis and quantitative science mapping to identify the origins of the dominant frame and trace its reproduction in the scientific literature over time. We demonstrate this approach using the case of the Bale Mountains, an internationally recognised centre of species endemism in Ethiopia. Our results show the enduring influence of the perceptions and values of a few early conservation scientists working with limited data. This led to erroneous assumptions and conclusions that, in some cases, were corrected by later research, but in many cases were not. This was a function of the social and intellectual structure of the scientific network, minor but consequential decisions in data interpretation and specific citational habits. Synthesizing these results, we identify several linked mechanisms that helped the dominant frame retain its tenacity and may also be at work in other contexts. We close with a discussion on how others might apply our approach and how future scientific research and conservation practice could proceed differently. Read the free Plain Language Summary for this article on the Journal blog.

The Role of One Health Approach Research for the Conservation of Endemic Wild Animals and Mitigation of Future Public Health Threat in Bale Mountains National Park, Ethiopia.

One of the things that made the Bale mountains park attract international attention is the home of many endemic wild animal including the world rarest canid, Ethiopian wolf. However, the park's major issues, especially public health study, wildlife and environmental sanitation, have not been adequately researched. The main objectives of the review is to highlight the study needed for prevention of animal and human health threat at Bale mountains national park. The water (river) rises from the park is used for drinking by the people downstream. As human approach to new area of the park, there is a chance for infected with new pathogens which may cause for newly emerging outbreak of the disease. The endemic animal in the park is infected with many disease from different reservoirs such as another wild animal and environment they reside in. As an example the Ethiopian wolf which listed as critically endangered species of the animal is infected with many disease which are transmitted from the rodents, carcass, stray dogs, human and the environment specially water bodies. Due to that infectious disease in rodents, stray dogs, human lives in the park and presence of pathogenic agents in water bodies should be investigated for prevention and controlling of infectious disease which could be causes extinction of the Ethiopian wolf. Wildlife waste is major water pollutants which may excreted and released from large animals to rodents found in Bale mountains national park. The pathogen from wild animal and human can made contamination of water bodies rise from mountainous area of the Bale and flow to the downstream can easily made the pathogen transported to lowland area of Ethiopia and Somalia which results a health risk of livestock, wild animal and human. Thus integrated research related to identification of pathogens found in wild animal, human lives in surrounding the park, and presence of pathogen in environment of the park (water bodies, soil) should be performed.

Terrestrial versus aquatic source identification of sedimentary n-alkane and sugar biomarkers: a case study from the Bale Mountains, Ethiopia

Organic matter in sedimentary archives is abundantly used to reconstruct paleoenvironmental and climate histories. Thereby, distinguishing between the terrestrial and aquatic origin of sedimentary organic matter is often a prerequisite for robust interpretations. In this case study, we use published data for modern plants and topsoils to identify the terrestrial versus aquatic source of n-alkane and sugar biomarkers in two afro-alpine sediment archives (Lake Garba Guracha and Depression B4) in the Bale Mountains, Ethiopia. The results of our comparative approach show that the long-chain n-alkanes C29, C31, and C33 in the sedimentary archives yielded patterns similar to those typical for the potential terrestrial input. By contrast, the relative abundances of the sedimentary mid-chain n-alkanes C23 and C25, and at least partly C27, are significantly increased compared to the plants and topsoils. This suggests that they are primarily produced by aquatic macrophytes and micro-organisms. The Paq ratio (C23 + C25)/(C23 + C25 + C29 + C31) is validated as a suitable source identification proxy in our study area. The sugar biomarkers xylose (xyl) and arabinose (ara) are abundant in the plant and topsoil samples. By comparison, high relative abundances of fucose (fuc) and rhamnose (rham) are generally only observed in sediments. This indicates that these sugar biomarkers are primarily produced by aquatic macrophytes or micro-organisms. Therefore, the ratio (fuc + rham)/(ara + xyl) is a suitable sugar biomarker proxy for organic matter source identification. The relative abundances of galactose and mannose are systematically decreasing and increasing, respectively, from leaves over O-layers to Ah-horizons. Furthermore, they are not significantly different from the abundances found in the sediments. This hinders terrestrial versus aquatic source identification using galactose and mannose.

Parallel Evolution of Skull Form in Three Rodent Genera Inhabiting Steep Elevational Gradients of Ethiopian Highlands

Several rodent genera radiated in Ethiopian highlands during Pleistocene, giving rise to species specialized to different elevation zones. The zonation is accompanied by vegetation change from savannahs or forests in lower elevations, through the mid-elevation belt of ericaceous shrublands to Afroalpine moorlands on the mountain tops. Such evolution on elevation gradient is expected to promote phenotypic adaptations and several genera are known to include highly distinctive high-elevation specialists. In this study, we systematically examined shape and size differentiation of skull and mandible in three genera, Lophuromys, Arvicanthis and Stenocephalemys, each including from six to eight species inhabiting different elevation zones on both sides of the Great Rift Valley. Employing computed tomography, three-dimensional virtual models, landmark-based geometric morphometrics and a powerful toolkit of partial least squares analysis, we demonstrated the elevation-related differentiation is a prominent feature of skull and mandible shape variation in all three genera. We identified the parts of skull and mandible which change most between the successive zones. These include, notably, orbits and insertion areas of masticatory muscles, which suggests adaptive shifts in visual perception and diet. We also showed that while the same parts are modified in all three genera, they are modified in different ways and to a different degree. The evidence for size differentiation was mixed despite the universal trend of larger size in higher elevations. Our study confirms the high-elevation specialists represent the most distinctive forms, which is especially true for the species from Bale and Arsi Mountains, East of the Great Rift Valley.

Human activities modulate reciprocal effects of a subterranean ecological engineer rodent, Tachyoryctes macrocephalus, on Afroalpine vegetation cover.

Human activities, directly and indirectly, impact ecological engineering activities of subterranean rodents. As engineering activities of burrowing rodents are affected by, and reciprocally affect vegetation cover via feeding, burrowing and mound building, human influence such as settlements and livestock grazing, could have cascading effects on biodiversity and ecosystem processes such as bioturbation. However, there is limited understanding of the relationship between human activities and burrowing rodents. The aim of this study was therefore to understand how human activities influence the ecological engineering activity of the giant root-rat (Tachyoryctes macrocephalus), a subterranean rodent species endemic to the Afroalpine ecosystem of the Bale Mountains of Ethiopia. We collected data on human impact, burrowing activity and vegetation during February and March of 2021. Using path analysis, we tested (1) direct effects of human settlement on the patterns of livestock grazing intensity, (2) direct and indirect impacts of humans and livestock grazing intensity on the root-rat burrow density and (3) whether human settlement and livestock grazing influence the effects of giant root-rat burrow density on vegetation and vice versa. We found lower levels of livestock grazing intensity further from human settlement than in its proximity. We also found a significantly increased giant root-rat burrow density with increasing livestock grazing intensity. Seasonal settlement and livestock grazing intensity had an indirect negative and positive effect on giant root-rat burrow density, respectively, both via vegetation cover. Analysing the reciprocal effects of giant root-rat on vegetation, we found a significantly decreased vegetation cover with increasing density of giant root-rat burrows, and indirectly with increasing livestock grazing intensity via giant root-rat burrow density. Our results demonstrate that giant root-rats play a synanthropic engineering role that affects vegetation structure and ecosystem processes.

Perception of local communities on protected areas: lessons drawn from the Bale Mountains National Park, Ethiopia

ABSTRACT A study targeting the Bale Mountains National Park in Ethiopia was conducted to gain a deeper understanding of local communities’ opinion on benefits and disbenefits of protected areas and existing benefit-sharing mechanisms and to suggest future research for development direction related to the management of protected areas. Household surveys, key informant interviews and focus group discussions were tools used to collect data. The results obtained through the analysis of the factors affecting the attitude of local communities on the park and its management demonstrated that efforts should be concentrated on improving communication with local communities and short-term economic benefits as well as identifying the reasons for the unhealthy relationships and addressing them. These issues can partly be addressed through creating and supporting effective and functioning multi-stakeholder platforms for dialogue and co-production of knowledge, continuous meetings and awareness-raising campaigns and integrating more income-generating activities. The results also suggested that park management and government authorities use their authority to decide how local communities should participate in Bale Mountains National Park management initiatives. Such a top-down approach affects the sustainability of the efforts to conserve protected areas because local stakeholders lack incentives to participate. This also leads to inadequate understanding of the complex relationships between people and protected areas they depend on and the inability to tailor management responses to specific needs and conditions. The study discussed the implications of the results for future planning and management of protected areas and forwarded recommendations for policy and future research for development directions.