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Plant of the Day. Isoetes andicola Lycophyte endemic to Peru at high elevations Restricted to the edges of bogs and lakes Leaves lack stomata and so CO 2 is obtained from sediment via the roots Carbon fixation occurs via the C 3 pathway by day, but via a CAM-like process at night
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Plant of the Day Isoetes andicola Lycophyte endemic to Peru at high elevations Restricted to the edges of bogs and lakes Leaves lack stomata and so CO2 is obtained from sediment via the roots Carbon fixation occurs via the C3 pathway by day, but via a CAM-like process at night Members of the quillwort family (Isoetaceae) are the nearest living relatives of the ancient “scale trees” (e.g. Lepidodendron)
Big Questions • Why is crop diversity/agrobiodiversity important? • What changes have occurred/are predicted to occur in global crop diversity? • What are the major threats to crop diversity? • What solutions do we have to these threats?
Crop diversity • Most crop species have lower genetic diversity than their wild progenitors due to the ‘domestication bottleneck’ • However, crop species commonly harbor many distinct varieties and landraces that arose as a result of artificial, diversifying selection.
Crop diversity • e.g. potatoes (Solanum tuberosum)
Major uses of crop diversity • Interspecific diversity (crop wild relatives) as well as intra-specific diversity are an important source for new alleles (such as disease resistance) in crop improvement efforts.
From last week: • Where does the cultivated gene pool come from? Sclerotinia resistance locus Wild Introgressions H. petiolaris H. argophyllus H. annuus landraces
Major uses of crop diversity • Interspecific diversity (crop wild relatives) as well as intra-specific diversity are an important source for new alleles (such as disease resistance) in crop improvement efforts. • Different landraces and varieties are often well adapted to their local/regional agro-ecological niche and are unique in many phenotypic traits, such as stress response/resistance.
Major uses of crop diversity • Interspecific diversity (crop wild relatives) as well as intra-specific diversity are an important source for new alleles (such as disease resistance) in crop improvement efforts. • Different landraces and varieties are often well adapted to their local/regional agro-ecological niche and are unique in many phenotypic traits, such as stress response/resistance. • Agro-biodiversity is thought to have the potential to play a major role in climate-change adaptations of agro-ecosystems
Global gridded crop models predict large reductions in yields of major crops (especially under nitrogen stress) Rozenweiget al. 2014
Major uses of crop diversity • Interspecific diversity (crop wild relatives) as well as intra-specific diversity are an important source for new alleles (such as disease resistance) in crop improvement efforts. • Different landraces and varieties are often well adapted to their local/regional agro-ecological niche and are unique in many phenotypic traits, such as stress response/resistance. • Agro-biodiversity is thought to have the potential to play a major role in climate-change adaptations of agro-ecosystems • Indigenous people who cultivate much of the world’s traditional crop diversity have often unique knowledge about uses of such diversity unknown to western society
Major uses of crop diversity Wild relatives of millet in Uganda (Global Crop Diversity Trust) Chuño, a variety of “freeze-dried” potato that can be stored long term
Major threats to crop diversity • Agricultural intensification and crop monocultures can lead to genetic erosion (loss of genetic diversity) in crops Van der Wouw et al. 2009
Uptake of modern varieties Van der Wouw et al. 2009
However, the evidence for a modernization bottleneck is equivocal From a meta-analysis of 24 wheat and 20 non-wheat studies of crop genetic diversity through time. Van der Wouw et al. 2010 wheat non-wheat
Major threats to crop diversity • Agricultural intensification and crop monocultures can lead to genetic erosion (loss of genetic diversity) in crops • Crop replacement as dictated by the global marketplace or as development strategy can lead to the loss of entire crop species
Changes in crop commodities worldwide Khoury et al. 2014 National food supplies contain more crop species (A & B), slightly increased evenness of crop contribution to calories (C & D), and reduced dominance by a single crop (E & F) over the last 50 years
Change in crop geographic spread in national diets, 1961–2009 All crops (except cottonseed oil) are contributing to food supply in an increasing number of countries Khouryet al. 2014
Change in crop abundance (calories) in national diets, 1961–2009 Which crops do you think have had the highest increase in abundance? The degree of increase in spread (see previous slide) predicts the abundance of crop species in national food supplies. Khouryet al. 2014
Increase in homogeneity among national diets (crop contribution to calories), 1961–2009 Khouryet al. 2014
Change in number of countries in which maize, rice and wheat are being eaten Khouryet al. unpublished
Major threats to crop diversity • Agricultural intensification and crop monocultures can lead to genetic erosion (loss of genetic diversity) in crops • Crop replacement as dictated by the global marketplace or as development strategy can lead to the loss of entire crop species • Transgene escape from GMOs to crop wild relatives and traditional landraces (has potentially already happened in maize in Mexico)
Interspecific crop Diversity in the Compositae Interspecific crop diversity in the Compositae
Crop diversity in the Compositae • Ornamental • Gerbera x hybrida • Zinnia sp. • Seed oil • Helianthus annuus • Guizotia abyssinica • Phytochemicals • Parthenium argentatum • Artemisia sp. • Edible leaves • Lactuca sativa • Cichorium endivia • Tubers and roots • Helianthus tuberosus • Smallanthus sonchifolius Dempewolfet al. 2008
Domestication is a process • The distinction ‘domesticated’ or ‘not domesticated’ is an over-simplification. • Some crops have moved along this process further than others… Why? • In order to be able to look at domestication at a broad scale (e.g. family wide), we need to be able to understand how this crop diversity is partitioned. • We can recognize different levels of domestication. • How can we decide which level?
Domestication index for Compositae crops Dempewolfet al. 2008
Level of domestication for major Compositae crops • Strongly domesticated: • sunflower (Helianthus annuus) • lettuce (Lactucasativa) • safflower (Carthamustinctorius) • endive (Cichoriumendivia) • chicory (Cichoriumintybus) • Semi-domesticated: • cardoon (Cynaracardunculusvar. altilis) • globe artichoke (Cynaracardunculusvar.scolymus) • noug (Guizotiaabyssinica) • Jerusalem artichoke (Helianthus tuberosus) • Yacon (Smallanthussonchifolius) • Weakly/not domesticated: • Stevia (Stevia rebaudiana) Dempewolfet al. 2008
Taxonomic diversity and number of strongly domesticated crops 20 - 18 - 16 - 14 - 12 - 10 - 8 - 6 - 4 - 2 - 0 - Fabaceae Poaceae Number of strongly domesticated crops Rosaceae Compositae Solanaceae Euphorbiaceae Rubiaceae Lamiaceae Melastomataceae Orchidaceae 5000 0 20000 10000 15000 25000 Number of species Dempewolfet al. 2008
Why are there so few strongly domesticated crops in the Compositae? • Secondary compounds: • sequiterpene lactones, alkaloids and terpenoids • affect the palatability of a species or act as allergens • Nutritional considerations: • produce inulin rather than starch as storage carbohydrate; inulin is indigestible by the human gut • oils from Compositae species are high in unsaturated fatty acids, which carries health benefits but also makes the oil go rancid faster Dempewolfet al. 2008
Why are there so few strongly domesticated crops in the Compositae? • Adaptive traits: • wind dispersal or dispersal by adhesion to animal fur is common; might limit seed and fruit size • Mating systems: • self-incompatible outcrossers; might reduce the probability of domestication • Preferences of early farmers: • defenses against herbivory (e.g. secondary compounds or spines/thorns) • early farmers probably focused on crops that could supply them with reliable sources of carbohydrates or proteins
What are neglected and underutilized species? • At present, only 150 plant species are used and commercialised on a significant global scale • Over 50% of the world's requirement for protein and calories are met by only three: rice, wheat and maize. • There are an estimated 7,000 species that play a crucial role in poor people's livelihood strategies and may have a significant potential for commercialisation. • Alongside their commercial potential, many of the underutilised plant species also provide important environmental services, as they are adapted to marginal soil and climate conditions.
Underutilized Species have the potential to contribute to livelihood improvement by: • increasing incomes • ensuring food security • improving nutrition • enhancing biodiversity • tolerating stress conditions • occupying important ecological niches • production with low external inputs • stabilizing ecosystems • creating new markets
Conserving Crop Genetic Diversity in – situ conservation vs. ex – situ conservation
Global ex situ conservation From Dulloo et al. 2010
An example of ex situ conservation The ‘Doomsday’ vault 60 minutes piece on the Svalbard Global Seed Vault: http://www.cbsnews.com/videos/saving-seeds-in-doomsday-vault/
Unanswered Questions • Will global diets continue to homogenize? • In highly developed countries, a diverse diet is often a signal of wealth. • Will our efforts to save genetic diversity of crops and wild relatives be enough? • To increase yield • To adapt to changing climates • What will be (or will there be) the next revolution in crop breeding?
“Adaptive drool in the gene pool” High starch human diets are associated with increased copy number of AMY1, the salivary amylase enzyme gene From Perry et al. 2007