Land Management Officer Land and Water Development Division

Land Management Officer Land and Water Development Division
Sustainable Use of Agricultural Biodiversity: An essential aspect of natural resources management in agricultural ecosystems Sally Bunning Land Management Officer Land and Water Development Division FAO of the UN

What is agricultural biodiversity?
It includes all components of biological diversity of relevance to food and agriculture: the variety and variability of plants, animals and micro-organisms at genetic, species and ecosystem level which are necessary to sustain key functions in the agro-ecosystem, its structures and processes. Local knowledge and cultural diversity can be considered an essential part of agrobiodiversity as it is the human activity of agriculture which conserves this biodiversity.

Importance (value) of biodiversity in agricultural ecosystems
In agricultural systems biodiversity is important for the production of food, fibre, fuel, fodder...(goods) to conserve the ecological foundations to sustain life (life support function) to allow adaptation to changing situations and to sustain rural peoples’ livelihoods (sustainable agriculture – food security, income, employment,...) Specificity: it has been developed through human intervention over generations and it requires human management to sustain it.

Human Management practices and decisions GENETIC and SPECIES DIVERSITY
Agricultural Biodiversity is complex Human Management practices and decisions GENETIC and SPECIES DIVERSITY wild and domesticated CULTURAL DIVERSITY Crop based systems: food/fibre crops, pasture, trees (planned + harvested spp.) Mixed systems and associated biodiversity: soil organisms, pollinators, predators Livestock based systems: pasture, rangelands, cattle, small ruminants, poultry... Case studies and experiences to be shared among countries and farming systems ECOSYSTEMS DIVERSITY varied production systems habitats and landscapes

Need to address all components of agrobiodiversity
Habitat diversity (mosaic of land uses varies with soil and terrain, hedges, borders, trees in the landscape; farm type) Inter-species diversity (plant, animal and microbial) Inter-species diversity (very important for agrobiodiversity) genetic resources, unique traits –resistance to drought, cold, disease, etc, rooting, aspect, taste, storage, etc. Harvested species and Associated species (pollinators, beneficial/harmful predators, soil organisms – health/ disease,…) as well as Cultural diversity (type of farmer and farm; regulations; common property resources/ownership) and to understand implication of agrobiodiversity on ecosystem functions/processes and the services provided (see adapted Table by J. Paruel, Environmental controls and effect of land use on ecosystem functioning in temperate Argentina)

Farmers managing … Farmers managing genes Farmers managing species
Farmers, even in the poorest and most food-insecure regions of the world, manage genes by their decisions on crop varieties, manage species by their decisions on farm animals and manage ecosystems by their decisions on soil or pollinators (Kenmore, 2002) A simple description of the linkages between the “managers” of natural resources and the different components of biodiversity; genes, species and ecosystems. Examples of specific situation can provide you an idea of the diverse needs of the natural resource management communities to be considered in observing and monitoring biodiversity The situations which I will be presenting are case studies highlighted during a satellite event on the occasion of the 9th Regular session of the commission on genetic resources for food and agriculture. (proceedings online and printed) The examples will cover agricultural, aquatic and forest biodiversity highlighting the need for a wide variety of data and information. Throughout this overview, reference will also be made to international framework and conventions Before I move onto the case studies; I would like to recall the MUTUAL BENEFITS EXCHANGED BETWEEN AGRICULTURE AND BIODIVERSITY (NEXT SLIDE) Farmers managing ecosystems

Managing Agro-ecosystem biodiversity
Pollinators Predators and Parasites Herbivores Non-crop Vegetation Earthworms Soil Mesofauna Microfauna Pollination Genetic introgression Population regulation Biological control Biomass consumption Nutrient cycling Competition Allelopathy Sources of natural enemies Crop wild relatives Soil structure Decomposition Predation Nutrient cycling Disease suppression AGROECOSYSTEM BIODIVERSITY FUNCTIONS COMPONENTS Agricultural biodiversity comprises a wide variety of components .. The two following case studies will concentrate on soil and pollinators Next slide on soil biodiversity- case study from Burkina Faso ENHANCEMENTS Intercropping Rotations No-Tillage Green manures Windbreaks Agroforestry Cover crops Composting OM inputs From Altieri, M.A. Biodiversity and pest management Agro-ecosystems, Haworth Press, New York, 1994)

ECOSYSTEM SERVICES: FUNCTIONS (biodiversity related examples)
Food production The portion of gross primary production extractable as raw food. or for processing for food (Game, crops, nuts, fruits by hunting, gathering, subsistence or commercial farming) Raw materials The portion of gross primary production extractable as raw material (Production of wood, energy/fuel, fodder, ..) Genetic resources Sources of unique biological materials and products. (Plant varieties, animal races, medicinal extracts, products for materials science, genes for resistance to plant pathogens/crop pests, ornamental species, pets, Climate and Gas Regulation: of global temperature, precipitation, other biologically mediated climatic processes at global/local levels (GHG); of atmospheric chemical composition (CO2/O2 balance, C sequestration, CO3 for UVB protection) Resilience/Disturbance Regulation: ecosystem response to environmental fluctuation, mainly controlled by vegetation structure (storm protection, flood control, drought recovery, other aspects of habitat response). Water Regulation and Supply: of hydrological flow/regimes; water retention, storage, provisioning in the watershed: (Infiltration, soil water retention determined by vegetation cover/structure; water supply in aquifers, surface water bodies; availability for consumption, irrigated agriculture, industry, transport) Erosion control and Sediment retention: prevent loss of soil by wind, rain impact, runoff; storage of silt in ecosystem, in lakes and wetlands.

ECOSYSTEM SERVICES: FUNCTIONS (biodiversity related examples) 2
Soil formation Processes of weathering of rock; soil build up (Accumulation of organic material Nutrient cycling: storage, cycling, processing, input of nutrients (N fixation, nutrient cycles - N,P et al, breakdown of organic materials to soil OM- humus) Waste Detoxification recovery of mobile nutrients, removal /break down of excess or toxic nutrients/ compounds, pollutions control (detoxification by soil organisms). Pollination Movement of floral gametes. (Supply of pollinators for the reproduction of plant populations- insects, bats, birds) Biological control Trophic (food web) dynamic regulations of populations (pest-predator interactions e.g. IPM, control of disease transmissions) Refugia habitat for local/ transient populations (Nurseries, habitat for migratory species, for locally harvested species, over wintering grounds Recreation Providing opportunities (eco-tourism, outdoor recreational activities –hunting, fishing, birdwatching) Cultural Providing opportunities for non-commercial uses (Aesthetic, artistic, educational, spiritual, and/or scientific values of ecosystems).

Understanding Human Pressures on and threats to agricultural biodiversity
Increasing pressure on species and their environments: Population growth and poverty (increasing demand) Overexploitation, mismanagement Expansion into wetlands and fragile areas Intensification and Specialisation of agriculture – market forces Pollution Urbanisation, changing consumption patterns, globalisation Threats and risks loss of plant and animal species loss of plant varieties and animal races/breeds (loss of unique traits) also loss of essential natural processes pollination by insects, birds, bats etc. regeneration of soils by micro-organisms also reduced resilience. Need to increase resilience of agriculture and human capacity to adapt (to harsh periods, drought, climate change, pests, diseases) by maintaining a wide array of life forms with unique traits (e.g. trees that survive drought or cattle that reproduce in harsh conditions).

Wide range of case studies illustrate Sustainable Use of agrobiodiversity
Integrated agro-ecological approaches : IPM, soil biological management Community-based adaptive management – animal and plant genetic resources, diverse farming systems Local knowledge systems multiple uses of species (diet, nutrition, medicines; gender differentiated knowledge of agrobiodiversity community perspectives/strategies in managing crop and livestock and associated biodiversity; coping strategies for HIV/AIDS, climate change) Ecosystem approach: address all components, systems functioning and services and human management (cf. EA principles) Strengthening viability of farm-livelihood systems with under-utilized and under-valued biodiversity (opportunities; options) grasslands (grazing species preference, productivity; deep roots-below ground biomass) mountains (adaptation to altitude, cold; disease resilience, etc.) marketing (diverse products, niche markets, organic agriculture, etc. recognition of positive externalities (valuing ecological services provided by biodiversity associated with agricultural systems)

Need to use common Agricultural Definitions
Sustainable agriculture is ecologically sound, environmentally sustainable, economically viable, socially just and culturally appropriate … is based on a holistic scientific approach and productive over the long term. Farm System : the farm household, its resources, and the resource flows and interactions at this individual farm level Farming System: a population of individual farm systems that have broadly similar resource bases, enterprise patterns, household livelihoods and constraints Sustainable agricultural systems provide a range of goods (food, fuel, fibre, materials, etc.) and services (also considered as positive externalities) Need to select indicators for monitoring sustainability: soil (sustained health + productivity, prevent soil erosion, minimise off-site impacts, ... ); water (water retention, maintain water regime, flood protection, etc); vegetation (protective land cover, structure, biomass, C sequestration) biodiversity (resilience, adaptability, opportunities) conservation of wildlife and wild species; agricultural biodiversity: genetic resources inter- and intra- species, farmed and associated species, ecosystem functions, air quality (minimise greenhouse gas emissions) rural amenities (e.g. landscape, tourism).

Major Farming Systems: Sub-Saharan Africa
Common classes, characterisation and terminology

Need to build on ongoing global agro-biodiversity fora/intergovernmental processes
CBD Programme of Work on Agricultural Biodiversity: 4 components on Assessment, Adaptive Management, Capacity Building, Mainstreaming) International Initiative for the Conservation and Sustainable Use of Soil Biodiversity International Initiative for the Conservation and Sustainable Use of Pollinators International Treaty on Plant Genetic Resources for Food and Agriculture FAO IT-PGRFA International Plant Protection Convention (IPPC) Sec. hosted by FAO FAO Commission on Genetic Resources for Food and Agriculture CGRFA FAO Committee on Agriculture COAG These have resulted in: Assessment, Monitoring and Priority Actions: GPA-PGR, SOWAGR, Good Practices: SLM, Conservation agriculture, IPM, .... Guidelines: PGR, AGR, Pollinators, soil biodiversity, ecosystem approach, farmer rights, Panel of Experts… etc. The CODE OF CONDUCT sets out the principles and international standards of behaviour for responsible practices … It takes into account the biological characteristics of the resources and their environment and the interest of the consumers and other users.

The International Treaty on Plant Genetic resources for Food and Agriculture (IT)
This legally binding instrument is crucial for sustainable agriculture. It provides a framework for national, regional and international efforts to conserve and sustainably use plant genetic resources for food and agriculture - and for sharing the benefits equitably, in harmony with the Convention on Biological Diversity. IT-PGRFA was adopted by the 31st session of the FAO Conference (Resolution 3/2001) It entered into force on 29 June

Global Plan of Action for the Conservation and Sustainable Use of PGRFA
Priority Activity Areas In Situ Conservation and Development Activity 1. Surveying and Inventorying of PGRFA 2. Supporting On-farm Management and Improvement of PGRFA 3. Assisting Farmers in Disaster Situations to Restore Agricultural Systems 4. Promoting in situ Conservation of Wild Crop Relatives and Wild Plants for Food production (Sustainable) Utilization of Plant Genetic Resources Activity Activity 9 Expanding characterization, evaluation and core collection 10 Increasing genetic enhancement and base broadening 11 Promoting sustainable agriculture 12Promiting under-utilized crops and species 13 Supporting seed production and distribution 14. developing new markets for local varieties an diversity rich products also Ex situ conservation..... Capacity building and Institutions.....

Global Strategy for the Management of Farm Animal Genetic Resources
FAO is coordinating its development to guide international action for the sustainable use, development and conservation of domestic animal diversity supported by the Inter-governmental Technical Working Group on Animal Genetic Resources An essential element is the first State of the world's animal genetic resources - a comprehensive overview of farm animal biodiversity; country-driven process (as agreed by CGRFA-8 in 1999). First stage of reporting completed >170 Country Reports, reports by International organizations on relevant activities see DAD-IS. CGRFA-10 decided that the 1st Report, including the Report on Strategic Priorities for Action should be finalized at the First International Technical Conference on Animal Genetic Resources in 2007, hosted by the Government of Switzerland in 2007 in Interlaken Draft Report on Strategic Priorities for Action was reviewed by electronic Regional Consultations.

Domestic Animal Genetic Resources at Risk
Exotic genetic resources not sustainable Indiscriminate crossbreeding Genetic resources for future needs Desirable commitments by governments Include stakeholders in decision-making Identification of sources of funding Support breeder associations Strengthen extension services

FAO Commission on Genetic Resources for Food and Agriculture (CGRFA)
The CGRFA deals with policy, sectorial and cross sectorial matters related to the conservation and utilization of genetic resources for food and agriculture. It develops and monitors the Global Strategy for the Management of Farm Animal Genetic Resources and the Global System for Plant Genetic Resources – for food and agriculture. It has been addressing genetic resources in a stepwise manner (plant genetic resources  animal …..) but has agreed on the need for an ecosystem approach Hence the side event on its 20th anniversary (CGRFA 10): Mainstreaming agricultural biodiversity for food security (8-10 November 2004) and resulting in the publication on Biodiversity and the Ecosystem Approach (See website)

Options for technical support to countries in enhancing sustainable use of AGBIO
Enhance biodiversity through Sustainable agriculture Sustainable pastoralism Sustainable intensification (enhance productivity and function) livelihoods’ diversification Managing seed systems to promote the sustainable utilization of crop genetic resources Economic analysis: marketing, addressing and valuing the multiple roles of agriculture (See and externalities Integrate into poverty alleviation strategies

Case studies of Sustainable agriculture - enhancing agricultural biodiversity
Increased use of mixtures (intercropping, multistorey, agro-forestry, crop-livestock systems) Access to a wide range of good quality genetic material (plant and animal) Promote production of local germplasm and commercialization Promote decentralized and participatory breeding Improve use of genetic diversity as part of IPM strategies Monitor and identify underutilized species, support needs Develop sustainable management practices and post-harvest and marketing methods; Stimulate demand for diverse local products (niche markets, labelling, registration) Review and promote policies for development and use e.g. biodiversity conseravtion and coping with climate change

Soil biodiversity and its management
Managing termites and organic mulch for soil productivity by researchers in Burkina Faso: Surface mulch applied to crusted soils was used to stimulate termite feeding and burrowing. This lead to improved soil structures, better aggregate formation, and enhanced soil function. Mixing and burrowing of termites can be stimulated by applying organic mulch and their feeding can promote soil regenerative activities I would like to refer to a case study in the Sahel region, an in particular in Burkina Faso. ---Case study – Burkina Faso: « Managing termites and organic resources to improve soil productivit in the Sahel » This is a case study in response to the call of the CBD Sec as follow up to decision on agr-biod (FAO has assisted to compile such studies) The main purpose of this work was to evaluate the capacity of termites to improve their ability to reduce soil compaction, increase soil porosity and improve the water infiltration and retention capabalities of the soil. So as to encourage vegetative diversity and restoration of primary productivity (all important issue for food and livelihood security in teh Sahel) --- other comments---not for presentation .. « The capacity to enhance soil biological functions through a better understanding of soil biodiversity process and mechanims and improved land use systems and practices have been seriously neglected.» (Bennack et al., 2003) » However, an increasing number of case studies are showing these mechanims and showing the types of data and information from biodiversity observation with respect to soil within managed ecosystems. Where termites behaviour has prooved to be an important component of agricultural practices: Althrough agricultural pests, termites play and important role in recovering degraded ecosystes (and enhance agricultural production) Conserving termite populations (instead of eradicating them) and stimulating their soil mixing capacities would improved crusted soil. Photo 2. Termite-created voids on crusted soil after mulch application.

Soil Biodiversity From Micro-organisms e.g. bacteria + fungi Micro & meso-fauna protozoa, nematodes to acari & springtails ...Roots in the soil and their interactions with species above & below ground Macro-fauna e.g. ants, termites, earthworms

Managing Pollinators Management practice:
In Himachal Pradesh in Northwest Indian Himalayas farmers are using colonies of honeybees – Apis cerana and Apis mellifera for pollination of apple crop. Case study from the North Western Himalayas concerning pollination. It is important to highlight that the focus of agriculture in the Him-region is slowly shifting from traditional cereal crops for subsistence agriculture to high-value cash-crop farming … (fruits) Thus this shift poses new challenges related to the improving and maintaining productivity and quality … The study highlighted that a way to confront such challenge is through pollination … yet a decline in pollinators was noticeable … The causes of the decline are identified as related to * Habitat fragmentation agricultural and industrial chemicals Parasites / diseases Introduction of alien species Taxonomic information Economic values 5) A new management practice was then developed/applied: the hiring and renting bee colonies … ... Moreover some farmers are trying to save the population of existing pollinators by making judicious use of carefully selected less toxic pesticides and spraying outside the flowering period of the apple.  There are more than known pollinators (bees, butterflies, beetles, birds, flies and bats) Many important food crops rely on animal pollination, including fruits and vegetables and foodder. The decline in pollinators populations impact negatively on food production. In recent years there is a world wide decline in pollinator populations and diversitz (importance of monitoring population changes) Factors causing the decrease could be the decrease in their food (nectar and pollen) supplies as a result of decline in pristine areas, LUCs, increase in monoculture-dominated agricultural interventions (eg use of chemicals fertizers and pesticides) Changes in climate might also be affecting the insect numbers  An organized system of hiring and renting bee colonies for pollination exists

Results: Impact of Apis cerana pollination on fruit productivity
Also reduced premature fruit drop in apple, peach, plum, and citrus. Partap 2000b Misshapen fruit decreased by 50% 48 112 Strawberry Partap, 2000a 9/35 35 24 Citrus Partap et al, 2000 11/14 39 13 Plum 29/23 44 22 Peach Dulta and Verma, 1987 15/10 33 10 Apple Reference Increase in fruit size (length/ diameter) (%) Increase in fruit weight (%) Increase in fruit set (%) Crop These are some of the results highlighting the improvement in productivity and quality of the cash-crop (which then in turns is an improvement in terms of economic value) The study emphasised the need to conserve pollinators populations (and also the diversity) so as to ensure pollination ... By taking into consideration the factors behind the decline of pollinators …the study also highlighted the importance of biodiversity observations so as to maintain pollinators population and thus ensure pollination -MONITORING of the resources (cash crop yields and quality) of the pollinators (population and diversity) of the habitat / LUC Of chemical fertilizers and pesticides and their utilization … climate change Of the economic value of pollination … (free service vs hand-pollination like in the Maoxian county in China)

Targeting farmers: Increasing Farmer Access to Germplasm and Information
Information, and seed exchange between farmers slow Access to research generated germplasm poor Participatory breeding with farmers’ organizations Joint activities for improved information sharing Test new options for seed dissemination

Case studies/opportunities for Sustainable pastoralism
Controlled burning by pastoralists can improve forage quality and diversification of vegetation structure and species composition (trees, shrubs, perennials, annuals) Livestock grazing and crop-livestock integration can improve nutrient cycling and make better use of fragile resources/ ecosystems Livestock wildlife interaction: management of animal movements, stocking rates, control of incompatible cultivation by farmers; herders protect grazing wildlife from predators Settled herders creates long-lasting nutrient hotspots (kraals; fields) Intensification and fragmentation of rangelands seems to cause a LOSS in livestock production (may need to rethink ranching, sedentarisation) Challenges - control of livestock numbers: use of common property resources; prestige, savings, security, culture Improvement of pasture and rangelands

Minimizing impacts of farming practices on wild biodiversity- making best use of resources
Thatching, Busia District Gramminae Conservation through Sustainable management and Use Practices are part of the wider agricultural system. This takes two main forms: on-farm -strips of uncultivated land, ‘hedgerows’ of grass and bush, fallow land, fenced graminae-rich plots… off-farm - management of community grazing lands, seasonal wetlands, rocky outcrops and hillsides, sacred sites… - controlled burning traditional uses and skills Grass-strips between crops-Machakos District Kenya

Case studies/Opportunities for Sustainable intensification
Sustainable management practices: controlled burning and grazing, woodlots for energy and timber, field borders/hedges, crop-livestock-forestry interactions are key to maintaining diverse habitats and landscapes that support biodiversity Human management of ecosystems may increase species diversity semiarid savannas: managed pasture, control invasive forest and shrub species, harvesting, gathering and planting diversified agro-silvo-pastoral systems multi-layer farming systems: trees, perennials- banana, coffee, annuals) Planned settlements/roads: reduces lands with potential, avoid biodiversity hotspots, environmentally-friendly (green belt, trees, etc.) Protected areas, buffer zones, specific action to safeguard those groups and species that are more sensitive to human use than others, to allow hunting and gathering and in situ conservation of landraces/farmers varieties/breeds Land use planning by communities and sub-catchments to promote biodiversity. Vary land use type with soil type, terrain, microclimate, access to water. Patchwork of settlements, cropland, pasture, forestland, and protected areas. Regulations : stocking density, seasonality, quotas, user groups, etc.

Sustainability - adaptation to change and enhancing systems’ resilience
Supporting the ability of farmers to remain agile in responding to new challenges, by adapting their production system Resilience or adaptive capacity are properties of the actors and the system in which they function Resilience may indicate a return to the status quo. Agility/adaptability refers to continuously moving targets/changing situations Need to sustain use and sustain adaptive capacity to increase probability of meeting future needs

FAO: Roles of Agriculture Project
Premise 1: Agriculture provides multiple non-commodity outputs that are not valued by market transactions  may be under-produced relative to what society desires. Premise 2: As income rises (socio-economic/agricultural development), the economic importance of the commodity outputs of agriculture decreases in relative terms, and willingness to pay for its other roles increases Policy challenge to Address Externalities (costs or benefits not valued in the market and not adequately taken into account by actor/decision maker) to Safeguard Common Resources/Public Goods (rules of access and use; mechanisms for collective action to prevent degradation, under / over use) to Integrate natural resources management /ecosystem approach (resources, and their products, are interlinked, management /policy measures for one resource/sector affects the others to Create resource/ecosystem friendly markets that generate growth and promote sustainable use/management of resources and ecosystems. Studies conducted in Ethiopia, Ghana, Mali, South Africa, Morocco

ENVIRONMENTAL EXTERNALITIES
Roles of Agriculture ENVIRONMENTAL EXTERNALITIES SOCIAL VIABILITY Equity; Stability FOOD SECURITY POVERTY ALLEVIATION CULTURAL ROLE Gender; Heritage; IK Global: Ecosystem resilience Climate change mitigation (C, land cover) Biodiversity Regional/National: Watershed mgmt (prevent soil erosion & off-site impacts) Water (stable regime; flood prevention) plant + animal genetic resources; services wild spp.+ wildlife conservation Air quality (reduce GHG) Local: farmed spp., associated spp., ecosystem functions NRM- soil+ water conservation Pollution control Global: Social stability Poverty Alleviation Regional/National: Rural-urban migration (social implications) Welfare systems substitute Social capital formation Biodiversity: diverse livelihoods Local: Social stability of rural community Rural employment Family values, gender impact. Bodiversity-coping strategies; risk mgmt Global: Economic Growth Poverty alleviation World Food Security Regional/National: Access to food National security Food safety support in times of crises (remittances, migration, fiscal support, food aid) Local: Local / household food security Biodiversity: nutrition; pest + disease control, options Sustainability Employment Income  services Global: Cultural Diversity Indigenous Knowledge Regional/ National: Cultural heritage Cultural identity Perception of roles of agriculture Local: Landscape, recreation, tourism Indigenous knowledge (disaster prevention, biodiversity, medicinal applications) Traditional technology.

Targeting Communities livelihoods and nutrition through local agrobiodiversity
Market opportunities Premium price for local products Increased productivity of landraces (improved seed quality; crop rotations; water harvesting Add-value products (fruit and milk processing) Production of herbs, medicinal plants, honey (bee keeping) Handicrafts and Ecotourism Nutrition /dietary diversity and opportunities Dietary energy supply can be satisfied without diversity but micro-nutrient supply cannot (e.g. essential fatty acids; amino acids) Wild and domesticated species and intra-species diversity play key roles in global food security Different species/varieties have very different nutrient contents

Understanding impacts/implications of HIV/AIDS on agro-biodiversity
HIV/AIDS impact on PGR? Less labour Loss of knowledge Reduction in land cultivated Less labour intensive crops Reduction in crop range and variety Loss of genetic diversity

Catchments: strengthen relation between ‘upland land users (as providers’ of ES) and lowland land + water users (beneficiaries)

Mainstreaming biodiversity for sustainable agriculture and food security
Programmes, Institutions and Capacity Building Multi-sectoral approaches: agricultural, environmental, land, water, community development, planning and finance (coordination; committees). Mainstreaming in national programmes (poverty alleviation, gender) Land use planning at community and watershed levels (landscape; habitat dimensions) Supporting on farm management Networks : e.g. plant genetic resources, research + development Participatory assessment, monitoring and early warning systems Information systems (threatened resources, threats etc) Training and education: curricula, adult education, extension, gender Raising awareness of importance (value) - public, private sector decision makers (local media, schools, etc)

BiodiversityAgriculture
Agriculture-environment collaboration – identify synergy, mutual benefits BiodiversityAgriculture Productivity Adaptation Maintenance of ecosystem functions Agriculture Biodiversity Delivery of ecosystem services Incentives Ecological knowledge It is an important issue in order to understand the needs of the natural resources management communities … Biodiversity benefits agricultural/managed ecosystems productivity: conservation management of broad-based genetic diversity within domesticated species has been improving agricultural production for years; Adaptation: a diverse range of organisms contributes to the resilience of agricultural ecosystems and their capacity to recover from environmental stress and to evolve. Maintenance of ecosystem functions: essential functions …. (text from folder) Agricultural/managed ecosystems benefits biodiversity

The National Agricultural Biodiversity Programme in Lao
CROP AND CROP ASSOCIATED BIODIVERSITY LIVESTOCK DEVELOPMENT AND MANAGEMENT NON-TIMBER FOREST PRODUCTS AND OTHER TERRESTRIAL BIODIVERSITY SUSTAINABLE USE AND CONSERVATION OF AQUATIC BIODIVERSITY HOUSEHOLD-BASED INTEGRATED AGRICULTURE PRODUCTION SYSTEMS INTEGRATED PARTICIPATORY PLANNING APPROACHES MANAGEMENT ARRANGEMENTS

FAO Agro-biodiversity Publications
You are invited to look at display copies of Biodiversity Awareness Folder (series of flyers/fact sheets e.g. Why is Biodiversity Important for the Maintenance of Agro-ecosystem Functions? Publication Biodiversity and the Ecosystem Approach in Agriculture, Forestry and Fisheries, 2003, case studies developed with partners htttp:// Powerpoint presentations prepared forCGRFA-10 Side event Case studies of Mainstreaming agrobiodiversity for food security (November 2004) distributed Publications: Valuing crop biodiversity and Beyond the Gene Horizon (prepoared with IPGRI, now Bioversity)

Overview of the FAO - Government of Kenya Agrobiodiversity Programme FAO–Netherlands Partnership Programme (FNPP II – 2007) Collaboration for policy and strategic support for sustainable ecosystems, rural livelihoods and food security Linkages/synergies being developed among themes for integrated process Coordination for more effective programmes and actions (identify gaps, avoid duplication) Impact on policy: within 2 years contribute to harmonised policy (agro-environment, food and nutrition policy, agroforestry) In longer term improve programme synergy and resource allocations and improve situation for rural people through Inter-sectoral/disciplinarity Food Security Agrobiodiversity Forestry

Guiding principles of Kenya strategic integrated programme
People centred (gender equity) Inter-sectoral approach/ process Strengthening existing programme activities Policy impact in short/ medium term Ecosystem approach Opportunity for establishing synergies Integrating water

AGBD Programme framework and linkages
Policy dialogue- mainstreaming AGBD, enabling environment Harmonisation AGBD, FS, FO Integrated land use, resources and agrobiodiversity assessment Specific studies Specific databases Training institutes - information and communication Local community action in Dryland district -agropastoral communities Local community action in Lake Zone district - fishing communities Case studies and policy briefs

AGBD Issues respond to needs identified
Habitat management (beaches, user rights, pollination) Integrated resources management (agro-ecological approaches; river basin management, soil, water, biological resources) Alternative livelihoods (fishing communities) Invasiveness (e.g. Prosopis – other woody species. learning from fisheries) Responding to HIV/AIDS (labour saving CA approaches, nutrition, fisher-trader links) Drought resilience (local varieties/species, runoof management Markets - Seeds Networks (prices, organisation, farming as a business)

Link with drylands Sudan, Eritrea, Somalia
Agrobiodiversity Programme: Local level –FFS in diverse farming systems/AEZ Identifying and adapting agro-biodiversity management options + opportunities 1) Mwingi district, semi-arid agro-pastoral  drought resilient, mixed systems 2. Bondo district, Sub-humid Lake Zone sustainable, productive aquatic and terrestrial systems 3. Coastal zone: INRA pilot Link with drylands Sudan, Eritrea, Somalia 1 2 Link across Lake Victoria basin

1a)Targets farmer groups, extension/facilitators
PRA and AGBD study Identify issues for FFS Curriculum development FFS Conduct and evaluation Documenting process and lessons FFS Resource management systems, land & water, Diversification- species, habitat management Soil health, pollination, aquaculture + fishery LInKS Integrating AGBD in FFS activities in Bondo + Mwingi Community appraisal of AGBD situation and awareness CurricuIum development to improve understanding and know-how on AGBD conservation and sustainable use Farmer field schools for Promoting farmer innovations, use of Indigenous knowledge and Technology transfer on AGBD  to improve food and livelihood security Community Action - Research: Test and adapt improved management practices, study plots, demonstrations, innovation, experimentation, local knowledge Impact analysis on agro-ecosystems and livelihoods Impact of markets- response to / increase options

Farming, fish farming and fisheries in Lake Victoria basin
Identified General topics for FFS process Community resources management + impacts (species, habitats, etc.) Changing customs and innovations (practices, by-laws, diet, recipes..) Local conservation strategies; individual and communal Effects of markets and market development Ecological services e.g. pollination, beekeeping; soil health, water Impact of cash crops (on systems, income, environment, security..) IPM, safe use and beneficial insect species Links with other actors (nutrition, health, business management etc.) Farming, fish farming and fisheries in Lake Victoria basin Local vegetables (income, nutrition, ..) Alien species 2 fisheries scenarios: river (aquaculture) and lake (catch) Upstream agric. and non-agricultural practices affecting aquatic area Changes in aquatic area (not only fish) Conservation and use – e.g. products of wild harvested spp.such as Papyrus Drought resilient agropastoral systems Genebank of local varieties Communal seed systems (storage) Effects of commercialised crops Drought resistant crops: sorghum varieties; green gram; pigeon pea Resilient, productive systems (water harvesting etc.)

1.b) Targets extension and technical staff
Curriculum development – integrate AGBD in training Training materials/ short courses Livelihood approaches- HIV/AIDS, gender, nutrition Exchange between extension and training Workshops with colleges Development of Case studies and Policy briefs FFS in Kenya seed fair Kenya 1.b Integrating agrobiodiversity in training institutions Assessment of training institutes to work with Coordination with Ministry of Education and KIE for teacher training, education, etc. - Identify gaps and opportunities in existing curricula of selected training institutes (e.g. Egerton + Baraka; Moi Uni. (fisheries, UJK- pollinators); Link with FFS for documentation, case studies and practical experiences Integrate human and biophysical systems dimensions

AGBD 2: Improving access to information & knowledge
2.a Integrated natural resources assessment INRA (builds on forest resources assessment) Assess available information and needs (status and trends - land use, habitat/species) Develop and pilot inter-sectoral methodology (AGBD, land use, land, water, other natural resources, ecosystem) Identify indicator and tools (field survey, transects, RRA-questionnaire) Capacity building (Participatory mapping and assessment; RS, sampling, Compatible data, database development and analysis) Targets technical capacity & informed decision making by policy makers/resource manager

Improving access to information & knowledge (cont.)
2.b) Information systems on alien species in fisheries and forestry 2c) Information on plant genetic resources for food an agriculture Assess status of genetic resources with FFS Train people to collect and analyse data Improve the quality of information about PGRFA status and dynamics Contribute to reporting commitment to State of World report on PGRFA link with over 26 key PGR institutions Targets: technical + extension level (Partners: Genebank, IPGRI..)

1. Using markets to promote sustainable use of CGR
2d) Research on Managing Seed Systems to promote the sustainable utilization of crop genetic resources: Two focus areas 1. Using markets to promote sustainable use of CGR How to manage seed systems to promote sustainable agriculture, improved farm welfare and in situ conservation of important crop genetic diversity. Methodology development Case studies: Mali, Kenya, India, Mexico, Bolivia 2. Economic analysis of seed system impacts on farm welfare and on farm diversity Assessing the links between seed systems and farm level use of crops and varieties and their implications for welfare and diversity Case studies: Ethiopia (Sorghum, Wheat); Mozambique (cowpea) India (Pearl Millet) Mexico (Maize) in partnership with IPGRI, ICRISAT, IFPRI, and CIMMYT

Encourage partnerships for institutional capacity building & integrated NR management.
Multiple Partners are identified for synergy and collaboration Ministries of Agriculture and Livestock Departments: Resource survey and remote sensing; Fisheries and forestry Ministry of Environment and Education technical bodies KARI, KEFRI, ICRAF,ITDG, JKU, ICRISAT, ILRI, KEMFRI... Community level: District, FFS, Extension, Universities (Egerton, Moi, Jomo Kenyatta) Training colleges- teacher training, agriculture and forestry Partner organisations: ICRISAT, Bioversity, ITDG, CIKSAP, etc.

Work together to achieve happy healthy farmers and ecosystems
Smallholders access market prices from rural info kiosks, c/o Pride africa, IDRC

thank you for your attention
Farmers’ studying ecology and biodiversity, Farmer Field School approaches thank you for your attention