Browsing by Person "Hailu, Teweldemedhn Gebretinsae"

Now showing 1 - 3 of 3

Classification and characterization of Ethiopian honey bees (Apis mellifera) based on morphometric, genetic and socio-economic analyses
(2022) Hailu, Teweldemedhn Gebretinsae; Hasselmann, Martin
Ethiopia is a major beekeeping country located in northeast Africa where several evolutionary lineages of Apis mellifera contact. A unique practice of honey bee colony marketing which involves broad agro-ecological zones (AEZs) is a developing trend in the northern part of the country such as Tigray region in association with apicultural development. Several studies based on classical morphometry on the Ethiopian honey bee subspecies classification debated from the unique Apis mellifera simensis to five others. Moreover, the genetic diversity, adaptation, gene flow and inter-relationships of the honey bees between AEZs were not disentangled – a challenge for planning sustainable apicultural development and conservation. Therefore, this study was conducted to elucidate the honey bees of Ethiopia in a context of apicultural transformation using integrated methods: morphometrics, genetics, colony market survey and metadata analyses on beekeeping development. The results of geometric morphometric analyses confirmed that Ethiopian honey bees represented by Apis mellifera simensis references belong to a separate lineage (Y) compared to A, O, M and C, and the present sample belonged to Y. This supported the hypothesis of five major honey bee lineages of the honey bee Apis mellifera. Similarly, a maximum likelihood phylogenetic tree analysis based on the mitochondrial COI-COII showed that most of the Ethiopian honey bees belong to lineage Y. However, a substantial proportion of the samples from the northern part of the country clustered with lineage O, which support the hypothesis that there is close contact between Y and O. Both geometric morphometry and classical morphometry differentiated the Ethiopian honey bees from all references including A. m. monticola, A. m. scutellata, A. m. jementica, A. m. adansonii but grouped with A. m. simensis. Genetically, five DraI haplotypes (COI-COII) were found to be randomly distributed across AEZs, indicating a substantial gene flow. Consequently, the level of genetic differentiation among the Ethiopian honey bee subpopulations defined by local areas and AEZs was generally low based on r7-frag nuclear marker, which is identified to be associated with adaptation to habitat elevation in East African honey bees. Similarly, nucleotide diversity consistently decreased with increasing elevation – indicating a reduced effective population size in the highlands. Results obtained from colony market survey showed that the honey bee swarms are reproduced in a few highlands and re-distributed throughout the region. Colony buyers have preferences of color and AEZ of origin of the honey bees, which led to a one-way flow and eroded the overall level of genetic differentiation. However, a marked differentiation was detected between the highland and lowland honey bees in relic communities where an allelic length polymorphism was observed as a signature of local adaptation. Altogether, Ethiopian honey bees belong to the lineage Y and subspecies A. m. simensis, and are characterized by a high level of gene flow enhanced by colony marketing; but a conserved signature of local adaptation to higher elevations was identified in less disturbed communities. Further studies based on genome-wide analyses and field experiments, focusing on undisturbed communities, can provide more insights into adaptation, admixture and management implications. Sustainable bee breeding and extension services that enable local beekeeping without colony trade and transportation will help to promote apiculture and genetic conservation.
High rates of honey bee colony losses and regional variability in Ethiopia based on the standardised COLOSS 2023 survey
(2024) Hailu, Teweldemedhn Gebretinsae; Atsbeha, Alem Tadesse; Wakjira, Kibebew; Gray, Alison
The COLOSS research association has been assessing honey bee colony losses, associated risk factors and management, focusing on Western countries but with a progressive international expansion. Here, we report the first survey on the loss rates of colonies in 2022/2023 in Ethiopia using COLOSS monitoring survey tools. A face-to-face interview questionnaire survey was conducted on 64 beekeepers selected from Oromia and Tigray regions. This covered 1713 honey bee colonies distributed in 68 apiaries. The percentages of colonies lost were significantly different between Oromia (24.1%) and Tigray (66.4%) regions. Colony losses were attributed as unsolvable queen problems (8% in Oromia; 10% in Tigray), natural disaster (32%; 82%), and empty hives or dead colonies (60%; 8%). The loss rate was significantly affected by queen replacement (p < 0.0001), use of natural comb (p < 0.0001), feed supplementation (p < 0.0001), region (p < 0.0001), varroa treatment (p < 0.0001), colony splitting (p < 0.01), and merging (p < 0.01). Beekeepers in Oromia managed more colonies and implemented improved practices compared to those in Tigray. However, all beekeepers in Oromia detected at least some bees with signs of deformed wing virus, compared to 76% of beekeepers in Tigray. In conclusion, the colony loss rate was significantly different between Oromia and Tigray regions due to differences in natural disasters, management, environment and health factors.
Projecting the impact of climate change on honey bee plant habitat distribution in Northern Ethiopia
(2024) Gebremedhn, Haftom; Gebrewahid, Yikunoamlak; Haile, Gebremedhin Gebremeskel; Hadgu, Gebre; Atsbha, Tesfay; Hailu, Teweldemedhn Gebretinsae; Bezabih, Gebreamlak
Climate change significantly affects the diversity, growth, and survival of indigenous plant species thereby influencing the nutrition, health and productivity of honey bees ( Apis mellifera ). Hypoestes forskaolii (Vahl) is one of the major honey bee plant species in Ethiopia’s Tigray region. It is rich in pollen and nectar that typically provides white honey, which fetches a premium price in both local and inter-national markets. Despite its socio-economic and apicultural significance, the distribution of H. forskaolii has been declining, raising concerns regarding its conservation efforts. However, there is limited knowledge on how environmental and climatic factors affect its current distribution and response to future climate change. The study investigates the current and projected (the 2030s, 2050s, 2070s, and 2090s) habitat distributions of H. forskaolii under three future climate change scenarios (ssp126, ssp245, and ssp585) using the Maximum Entropy Model (MaxEnt). The results show that land use (50.1%), agro-ecology (28%), precipitation during the Driest Quarter (11.2%) and soil texture (6.1%) predominantly influence the distribution of H. forskaolii, collectively explaining 95.4% of the model's predictive power. Habitats rich in evergreen trees and mosaic herbaceous with good vegetation cover are identified as the most suitable for H. forskaolii . The spatial distribution of H. forskaolii is concentrated in the highlands and mid-highlands of the eastern and southern parts of Tigray, characterized by a colder temperature. Across the three climate change scenarios, the size of suitable habitat for H. forskaolii is projected to decrease over the four time periods studied. Predictions under the ssp585 scenario reveal alarming results, indicating a substantial decrease in the suitable habitat for H. forskaolii from 4.26% in the 2030s to 19.09% in the 2090s. Therefore, given the challenges posed by climate change, research efforts should focus on identifying and evaluating new technologies that can help the H. forskaolii species in adapting and mitigating the effects of climate change.