Case Studies for Honeybee Breeding Research: Beekeeping Status in Kenya

INTRODUCTION

Beekeeping is the art of managing bees in order to produce honey and bee wax, among other products. It produces high-quality food, enhance seed production through pollination, and protects the natural environment (Klein et al., 2007). Beekeeping requires little capital, little space, and no good soil, making it feasible to practise alongside other farm activities. It can be done by both men and women, and it is an appropriate activity for women̓s and youth groups, among others. Beekeeping is emerging as a highly successful agricultural practice for rural areas in developing countries due to its numerous economic benefits (Kukonza, 2009).

The Kenyan government, in its strategy for development of apiculture and emerging livestock, has identified honey production as one of the few ways by which people in the Arid and semi-arid (ASAL) areas to earn an income and better adapt to climate change without damaging the environment on which they rely for survival. The beekeeping industry contributes to the overall rural economy through trade (Paterson, 2006). According to Kasina et al. (2009), honey bees and other pollinators provide ecosystem services worth US$3.2 million to several major vegetable, fruit, and nut crops in western Kenya alone. Kenya̓s livestock subsector, which includes bees, accounts for approximately 10% of the country̓s GDP. Beekeeping alone contributes approximately 1.89% of this amount (Muya, 2004). Traditional beekeeping in Kenya requires little financial or labour input. It is a versatile and gender-friendly business that does not compete for resources like land with other agricultural activities. Beekeeping is viable in Kenyan arid regions and areas where other crops have failed (Bradbear, 2002).

The effort to improve Kenyan apiculture began in 1967 through an Oxfam grant that funded their very first beekeeping development project. In 1970 the Kenyan government, with financial and technical assistance from the Canadian government, established a new agriculture sector (The National Beekeeping Station) within the Kenyan Ministry of Agriculture. The new branch would pursue the development of Kenyan beekeeping through extension services, research development and the professional training for Kenyan beekeepers (Kigatiira, 1976) where Kenyans were introduced to western beekeeping technology and knowledge. Current development trends emphasise on the improvement of hive technology and bee management training as the primary approach. The country is Africa̓s fourth-largest honey producer. Kenya̓s potential for apiculture development is estimated to be more than 100,000 tonnes of honey and 10,000 tonnes of beeswax annually. At the moment, only about a fifth of this potential is being realised. 80% of Kenya is made up of arid and semi-arid lands (ASALs), which have a high potential for honey production, and apiculture is a major occupation in these areas due to the abundance of bee flora. Non-ASAL regions also practise beekeeping. However, adoption of modern beekeeping equipment and practices has been slow, owing to the high cost. The document describes beekeepers̓ production systems, the honey value chain, the common bee species found in Kenya, and their characteristics, as well as the importance, prospects, and challenges of Kenyan apiculture.

LOCATION AND POPULATION OF KENYA

Kenya is located in the East African region of Africa. Kenya shares borders with five other countries: Tanzania in the south, Uganda in the west, South Sudan in the north west, Ethiopia in the north, and Somalia in the east. Kenya̓s land area includes a wide variety of ecological zones (Fig. 1). The country has been divided into seven major agro-climatic zones based on moisture and temperature regimes, with attempts to further subdivide these zones. Jaetzold and Schmidt (1982/83) classified the country into agro-ecological zones based primarily on altitude and rainfall, which included humid, sub-humid, semi-humid and semi-arid, semi-arid, and very arid. About 80% of Kenya̓s terrestrial land is classified as arid to semi-arid. Rainfall here ranges from 150 to 750 mm per year. Temperatures in the ASAL are always high, consistently exceeding 30 Celsius. The high-potential areas, which cover 20% of the country, house approximately 75~80% of the national population. Beekeeping is a major economic activity in Kenya̓s arid and semi-arid lands (ASALs) which account for 80% of honey production. Non-ASAL areas also practise beekeeping. ASALs have a greater potential for producing honey and other hive products.

Fig. 1.

Map of Kenya in Africa. Source google.

BEE FORAGE IN KENYA

Kenya has five agro-ecological zones, which are responsible for the wide variety of forage available. They are important in crop selection because they determine the crop̓s suitability in relation to the environmental conditions. Acacia species dominate bee foraging in Kenya̓s ASALS. The Kenyan highlands are distinguished by abundant rainfall, which supports a diverse range of crops and trees that serve as bee forage. This area produces multiflora honey (Table 1).

Table 1.

Common bee forages in Kenya

BEE HIVE POPULATION AND HONEY PRODUCTION

FAO (2020), estimated as of 2018, Kenya had a population of 1, 533, 668 beehives. The number of hives in Kenya has reduced by 16.76% for the last ten years. The number of hives in Kenya has decreased by 16.76% over the last ten years. There are no official estimates for Kenya̓s beekeeper population (Sagwa, 2021). Musinguzi et al. (2018) stated that the average number of beehives per beekeeper in Kenya is 15 hives. Honey is the primary hive product in Kenya. According to Carroll and Kinsella (2013), 96.7% of farmers sell only honey, with only 3.3% trading in other hive products such as beeswax, royal jelly, and live bees. According to Asiko et al. (2019), the average annual honey production in Kenya is 27,000 tonnes, contributing KES 7.43 billion to the GDP (Table 2). Other estimates place national honey production at 27, 557.3 tonnes (Kiptarus et al., 2011; Kiptarus and Asiko, 2014). According to the FAO (2020), Kenya produces 20,525 tonnes of honey per year (Fig. 2). The average honey production per hive per year ranges from 3.77 kg to 13.38 kg, depending on the type of hive. The counties with the highest honey production in 2014 were as follows: Nyandarua recorded 11,449,500 kilogrammes, followed by Tharaka Nithi with 1,382,029 kilogrammes. Kitui County reported more than 800,000 kilogrammes, and Baringo over 500,000 kilogrammes (KIPPRA, 2014).

Table 2.

Amount of honey, beeswax production, and number of hives in the Eastern Africa Region

Fig. 2.

Honey production in Kenya from 2008 to 2022.

HONEY MARKET IN KENYA

Kenya̓s honey market is considered unrestricted. Marketing is carried out by farmer groups, organizations, and brokers. Most of these organizations complete the apiculture value chain by processing and adding value to hive products. They also provide farmers with hives and other beekeeping equipment (Sagwa, 2021). Seven years ago, the standard farm-gate price of processed honey was $2.36 (Carroll and Kinsella, 2013), but it is now $7 per kg. The price depends on the type of honey (comb honey, processed honey, or crude honey) and the source. The Kenya Bureau of Standards (KEBS) controls the quality of honey. Apiary products must meet KEBS specifications. African honey standards (KS EAS 36: 2000) apply to all honey produced by honey bees and cover all honey presentation styles available for direct consumption. The Beeswax Standards (KS 1279: 2013) specify the minimum requirements and methods of testing for beeswax. KEBS, in particular, is in charge of promoting standardisation in industry and trade through standards development, conformity assessment, testing, and metrology (Sagwa, 2021). Kenya has a high demand for honey and is a net importer of it. This suggests that the potential for honey production in Kenya has not been fully exploited (Table 3).

Table 3.

Honey imports and exports in Kenya from 2009 to 2018

Fig. 3.

Honey production and marketing channel in Kenya.

BEE KEEPING SYSTEMS IN KENYA

Honey hunting was the beginning of humanity̓s long relationship with honeybees. To reduce the hardship and unpredictability of harvesting from wild colonies, people discovered ways to gain more control over bees by owning and managing colonies kept in hives. Beekeeping in Kenya is primarily practiced in areas where agricultural cropping opportunities are limited and the natural vegetation contains a diverse range of plant species suitable for bee foraging (Nightingale and Crane, 1976).

1. Traditional beekeeping system

Traditional beekeeping has a long history in Kenya, with numerous practices documented (Nightingale and Crane, 1983). Kenya is primarily a traditional beekeeping country, with approximately 10 million people practicing in arid and semi-arid regions (KNBS, 2021). The majority of beekeepers in Kenya still use traditional production systems, which primarily consist of hollow log hives (Cramb, 2003). These hives account for the single largest number of hive types in the country, estimated at 1,273,000, with 73% concentrated in the country̓s east (Mwabu et al., 2000). Other traditional hives include bark hives, which are made of peeled bark from a tree̓s trunk (Figs. 5, 6). Honey is typically harvested at night by climbing the trees from which the hives hang (Porter and Stern, 2002). The improved log hive from the traditional log combines traditional and modern hive technologies. It is made from a hollow wooden log that has been split lengthwise into two parts. The internal framework has wax rings that serve as a foundation for the bees to begin building honeycombs. In arid and semi-arid regions, hive occupancy ranges between 75~79%. It protects the bee from adverse weather conditions, particularly in the asals.

Fig. 4.

log hive hanged on a tree.

Fig. 5.

Improved log hive.

Fig. 6.

Kenyan top bar hive.

3. Modern bee keeping

Modern beekeeping implies manipulating a bee colony based on some knowledge of the bees. This allows for much easier management and harvesting, resulting in higher yields and better honey quality. Langstroth hives are the most commonly used type (Fig. 7). Given the potential for beekeeping to generate income and alleviate poverty in rural areas, national governments, non-governmental organisations (NGOs), and international institutions have implemented apiculture development programs aimed at expanding the practice, modernising bee management, and increasing honey production. Despite the benefits described above, Langstroth is more expensive to purchase than log hives. Furthermore, much more technical and management expertise is required (Paterson, 2006). This has resulted in slow adoption of the technology among Kenyan beekeepers.

Fig. 7.

Apiary with Langstroth hives.

IDENTIFICATION AND CLASSIFICATION OF HONEYBEE SPECIES IN KENYA

In Kenya, honey bee identification is conducted through various field sampling methods. Proper preservation techniques, such as pinning and ethanol storage, are essential to maintain specimens for study. Curation of bee collections supports research on taxonomy and biodiversity, aiding in comparative analysis and species discovery (Reddy and Ronnanki, 2023). Africa and Madagascar are home to 11 bee subspecies of Apis mellifera (Engel, 1999; Franck et al., 2001). In Kenya, morphometric, allozyme, mitochondrial DNA and microsatellites methods have been used to identify bee subspecies. Three honey bee subspecies have been identified in Kenya: Apis mellifera monticola, Apis mellifera scutellata and Apis mellifera litorea (Smith, 1961; Engel, 1999; Wallberg et al., 2017; Christmas et al., 2019).

Fig. 8.

Demonstration on modern beekeeping.

SPECIES OF HONEY BEE IN KENYA AND THEIR CHARACTERISTICS

In Kenya, there are three subspecies of Apis mellifera: A. m. litorea, A. m. scutellata, and A. m. monticola. These sub species vary in terms of their size and the number of yellow bands on their abdomens. Their distribution across the country is influenced by geographical features and climate conditions. Factors such as the landscape and weather patterns play a key role in determining where each subspecies is found (Raina and Kimbu, 2005). Apis m. litorea is the smallest honey bee subspecies and is primarily found in low-altitude regions along the East African coast. Apis m. monticola, on the other hand, is larger, black in color, and inhabits mountainous forest areas. Meanwhile, Apis m. scutellata is yellowish in color and predominantly occupies the savanna grasslands (Smith, 1961; Engel, 1999; Raina and Kimbu, 2005).

OPPORTUNITIES OF BEEKEEPING IN KENYA

The Kenyan government and international agencies have promoted beekeeping as an important component of their rural development policies, with the goal of increasing productivity in the honey sector and facilitating the marketing of bee products through the establishment of producer cooperatives. Several initiatives encouraged the transition from traditional log hives to modern hives (first Kenyan Top Bar hives and then, since the early 2000s, Langstroth hives), as the former were deemed insufficient to meet market demand for honey in terms of quality and quantity. Several apiculture private companies are emerging, providing farmers with easy access to modern beekeeping equipment. Some go above and beyond by offering contract farming to beekeepers, ensuring a ready market for their honey. The arid and semi-arid areas in Kenya offers a huge potential for bee keeping in Kenya due to availability of bee forage and lees pressure on land due to less cultivation.

CONTRIBUTION OF BEE KEEPING INDUSTRY

CHALLENGES FACED BY BEEKEEPERS IN KENYA

CONCLUSION

Kenya adopted Vision 2030, with agriculture emerging as one of the major economic sectors requiring emphasis because it accounts for 80% of Kenya̓s GDP, of which apiculture is a component. The National Beekeeping Policy 2009 aims to improve honey production and raise awareness by providing farmers with extension services, research, and training. This will increase apiculture adoption, particularly in areas with extensive forests (Government of Kenya, 2010). Furthermore, most Kenyan land is Asals, making apiculture a viable economic venture due to the diverse forage available to beekeepers, whereas crop farming is unsuitable due to erratic rainfall patterns. Some of the most common challenges our beekeepers face include the use of agrochemicals, a lack of information and extension services, climate change, and pest and disease control. Currently, the primary focus is on the adoption of modern bee hives and improved management practices. Little attention has been paid to selection and breeding to develop superior bee varieties that are more productive, less swarming, and more docile, making them more acceptable to beekeepers. Furthermore, improved honeybee management practices such as queen rearing, requeening, and regular inspection should be implemented to make apiculture in the country an appealing and profitable enterprise for farmers to invest in.

Acknowledgments

This study is a part of the Korea-Africa Food and Agriculture Cooperation Initiative (KAFACI) 2024 young scientist research project of Rural development administration. I am deeply grateful to KAFACI and RDA for the financial support and entrusting me to with this opportunity. I also acknowledge the Kenyan government through the Kenyan Agricultural Livestock Research organization (KALRO) granting me opportunity to attend the training. This study was carried out with the support of the National Institute of Agricultural Sciences project (RS-2020-RD009411). I also thank Mr. Ndungu Maathai and KALRO oljoroorok fraternity for their input in developing the document.

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