Enhancing In-crop Diversity in Common Bean by Planting Cultivar Mixtures and Its Effect on Productivity

Reinprecht, Yarmilla; Schram, Lyndsay J.; Smith, Thomas H.; Pauls, K. Peter

doi:10.3389/fsufs.2020.00126

Cited by 7 publications

(8 citation statements)

References 98 publications

(119 reference statements)

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“…Germplasm exchange and repatriation based on climate analog tools are also very effective to obtain higher production and conservation of diversity in the fields. Multiple approaches might be good to use even in a single landrace for producing higher benefits as well as to accelerate their conservation on-farm [14,15]. For increasing diversity, farmers' practices are, relatively, better than modern agricultural practices.…”

Section: Approaches For Increasing Diversitymentioning

confidence: 99%

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Approaches and Advantages of Increased Crop Genetic Diversity in the Fields

et al. 2023

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Crop genetic diversity is the most important factor for a long-term sustainable production system. Breeding and production strategies for developing and growing uniform and homogenous varieties have created many problems. Such populations are static and very sensitive to unpredictable stresses. In Nepal, more than 80% of the seed system is informal, which has contributed greatly to creating and maintaining genetic diversity within the field. This paper aims to assess and present the approaches and advantages of increased crop genetic diversity in the fields, based on the experiences of implementing on-farm conservation activities carried out in Nepal for last two decades. Some of the evidence has been derived from an ongoing evolutionary plant breeding (EPB) project being implemented in Nepal. The information is supplemented with field assessments, focus group discussion, and a literature review. The major approaches to increase crop genetic diversity are evolutionary plant breeding, cultivar mixture, landrace enhancement, informal seed systems, the bulk method, diversifying the seed sources, participatory plant breeding, open pollination, etc. EPB and cultivar mixture are very simple and effective approaches to increase crop genetic diversity at field level. The involvement of farmers in these approaches helps to accelerate the population improvement, maintaining the higher degree of genetic diversity. The major advantages of increased crop genetic diversity are seed maintenance by farmers themselves, minimal risk of crop failure, resilience to unpredictable stresses, increased amount of diversified nutrition, production increment, ease of producing organically, etc. However, there are some issues and problems associated with mixtures and intra-varietal diversity; for example, not being able to harvest by machine, maturing at a different date, difficulty in maintaining seeds and registration, etc. Crop genetic diversity should be considered as a sustainable approach for a climate-resilient and self-dependent production system. The higher the genetic diversity in farming land, the more chance of receiving multiple benefits in the agriculture system.

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Section: Approaches For Increasing Diversitymentioning

confidence: 99%

“…Selection responses in such narrow genetic diversity are almost negligible. Because of the lack of buffering capacity, these varieties are vulnerable to both biotic and abiotic stresses [15,20] and there are many cases of a complete failure of production in many crops. In addition.…”

Section: Impact Of Narrow Genetic Diversitymentioning

confidence: 99%

Approaches and Advantages of Increased Crop Genetic Diversity in the Fields

et al. 2023

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show abstract

“…Germplasm exchange and repatriation based on climate analog tools are also very effective to get higher production and conservation of diversity in the fields. Multiple approaches might be good to use even in a single landrace for getting higher benefits as well as to accelerate their conservation on-farm (Hufnagel et al 2020, Reinprecht et al 2020.…”

Section: Approaches For Increasing Diversitymentioning

confidence: 99%

“…Selection response in such narrow genetic diversity is almost negligible. Because of the lack of buffering capacity, these varieties are vulnerable to both biotic and abiotic stresses (Lin 2011, Reinprecht et al 2020 and there are many cases of complete failure of production in many crops. Insect pollinators prefer to visit fields where diversity is high both at intra and inter-varietal levels.…”

Section: Impact Of Narrow Genetic Diversitymentioning

confidence: 99%

Approaches and Advantages of Increased Crop Genetic Diversity in the Fields

Joshi¹,

Ghimire²,

Neupane³

et al. 2023

Preprint

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Crop genetic diversity is most for the long-term sustainable production system. The breeding and production strategies of developing and growing uniform and homogenous varieties have created many different problems. Such populations are static and very sensitive to unpredictable stresses. In Nepal, more than 80% of seed system is informal s which has contributed greatly to creating and maintaining genetic diversity within the field particularly contributing to landrace diversity. This paper aims to assess and present the approaches and advantages of increased crop genetic diversity in the fields. The paper is developed based on experiences of implementing on-farm conservation activities carried out in Nepal since last two decades. Some of the evidences have been derived from on-going evolutionary plant breeding project being implemented in Nepal. The information is supplemented with field assessment, focus group discussion, and literature review. The major approaches to increase crop genetic diversity are evolutionary plant breeding, cultivar mixture, landrace enhancement, informal seed system, bulk method, diversifying the sources, participatory plant breeding, open pollination, etc. EPB and cultivar mixture are very simple and effective approaches to increase crop genetic diversity at field level. The involvement of farmers in these approaches helps to accelerate the population improvement particularly for landraces. The major advantages of increased crop genetic diversity are: seed maintenance by farmers themselves, minimal risk of crop failure, resilience to unpredictable stresses, increased amount of diversified nutrition, production increment each year, ease to produce organically, etc. However, there are some issues and problems associated with mixtures and diverse varieties, for example, not being able to harvest by machine, mature at a different date, difficulty in maintaining seeds and registration, etc. Crop genetic diversity should be considered for a climate-resilient and self-dependent production system. The higher the genetic diversity in farming land, the more chance of getting the multiple benefits in the agriculture system (Vernooy 2022).

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“…Successful crop production depends on many factors, such as crop type [ 1 ], variety [ 2 ], and environmental factors [ 3 ], including climatic conditions [ 4 ], soil [ 5 ], and water [ 6 ]. Biotic and abiotic stresses also affect yield [ 7 ].…”

Section: Introductionmentioning

confidence: 99%

Examination of Different Sporidium Numbers of Ustilago maydis Infection on Two Hungarian Sweet Corn Hybrids’ Characteristics at Vegetative and Generative Stages

Szőke

Moloi

Kaczur

et al. 2023

Life

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Corn smut is one of the major diseases in corn production. The cob infection causes high economic and quality loss. This research investigated the effects of three different concentrations of corn smut infection (2500, 5000, and 10,000 sporidia/mL) on two Hungarian sweet corn hybrids (Desszert 73 and Noa). Plants were infected at the vegetative (V4–V5) and the generative (V7) stages. The effects of the corn smut infection were evaluated at 7 and 14 days after the pathogen infection (DAPI) at vegetative and at 21 DAPI at generative stages. The photosynthetic pigments (relative chlorophyll, chlorophyll-a and b, and carotenoids), malondialdehyde (MDA), and proline concentration, activities of the antioxidant enzymes [ascorbate peroxidase (APX), guaiacol peroxidase (POX), and superoxide dismutase (SOD)], morphological characteristics (plant height, stem and cob diameter, cob length, cob and kernel weights), mineral contents (Al, B, Ca, Cr, Cu, Fe, K, Mg, Mn, Na, P, Pb, S, Sr, and Zn), and quality parameters (dry matter, fiber, fat, ash, nitrogen, and protein) were measured. At both sampling times (7 and 14 DAPI) in both hybrids, the corn smut infection reduced the photosynthetic pigments (relative chlorophyll, chlorophylls-a, and b, and carotenoids) irrespective of the spore concentration. Under the same conditions, the MDA and proline contents, as well as the activities of APX, POX, and SOD increased at both sampling times. The negative effects of the corn smut infection were also observed at the generative stage. Only the 10,000 sporidia/mL of corn smut caused symptoms (tumor growth) on the cobs of both hybrids at 21 DAPI. Similarly, this treatment impacted adversely the cob characteristics (reduced cob length, kernel weight, and 100 grains fresh and dry weight) for both hybrids. In addition, crude fat and protein content, Mg, and Mn concentration of grains also decreased in both hybrids while the concentration of Al and Ca increased. Based on these results, the sweet corn hybrids were more susceptible to corn smut at the vegetative stage than at the generative stage.

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Enhancing In-crop Diversity in Common Bean by Planting Cultivar Mixtures and Its Effect on Productivity

Cited by 7 publications

References 98 publications

Approaches and Advantages of Increased Crop Genetic Diversity in the Fields

Approaches and Advantages of Increased Crop Genetic Diversity in the Fields

Approaches and Advantages of Increased Crop Genetic Diversity in the Fields

Examination of Different Sporidium Numbers of Ustilago maydis Infection on Two Hungarian Sweet Corn Hybrids’ Characteristics at Vegetative and Generative Stages

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