High-Altitude Wild Species Solanum arcanum LA385—A Potential Source for Improvement of Plant Growth and Photosynthetic Performance at Suboptimal Temperatures

Dinh, Quy Dung; Dechesne, Annemarie; Furrer, Heleen; Taylor, G. A.; Visser, Richard G. F.; Harbinson, Jeremy; Trindade, Luisa M.

doi:10.3389/fpls.2019.01163

Cited by 9 publications

(9 citation statements)

References 46 publications

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“…Some species have fruit characteristics that are very different from commercial tomatoes and potatoes. Some wild species are self‐incompatible as S. arcanum , 55 which remains with green color at maturity stage, not producing lycopene or being highly pubescent like S. habrochaites . 56 , 57 Thus, methods such as marker‐assisted selection can accelerate the development of new cultivars resistant to Alternaria spp.…”

Section: Host–pathogen–environment Interactionmentioning

confidence: 99%

Review: Holistic pest management against early blight disease towards sustainable agriculture

Jindo

Evenhuis

Kempenaar

et al. 2021

Pest Management Science

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Alternaria species are well‐known aggressive pathogens that are widespread globally and warmer temperatures caused by climate change might increase their abundance more drastically. Early blight (EB) disease, caused mainly by Alternaria solani, and brown spot, caused by Alternaria alternata, are major concerns in potato, tomato and eggplant production. The development of EB is strongly linked to varieties, crop development stages, environmental factors, cultivation and field management. Several forecasting models for pesticide application to control EB were created in the last century and more recent scientific advances have included modern breeding technology to detect resistant genes and precision agriculture with hyperspectral sensors to pinpoint damage locations on plants. This paper presents an overview of the EB disease and provides an evaluation of recent scientific advances to control the disease. First of all, we describe the outline of this disease, encompassing biological cycles of the Alternaria genus, favorite climate and soil conditions as well as resistant plant species. Second, versatile management practices to minimize the effect of this pathogen at field level are discussed, covering their limitations and pitfalls. A better understanding of the underlying factors of this disease and the potential of novel research can contribute to implementing integrated pest management systems for an ecofriendly farming system. © 2021 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

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Section: Host–pathogen–environment Interactionmentioning

confidence: 99%

Review: Holistic pest management against early blight disease towards sustainable agriculture

Jindo

Evenhuis

Kempenaar

et al. 2021

Pest Management Science

View full text Add to dashboard Cite

show abstract

“…Among possible uses of this approach is the identification of the germplasm with tolerance to adverse biotic and abiotic factors ( Foolad and Lin., 2000 ; Mittova et al, 2004 ; Venema et al, 2005 ; Zhao et al, 2005 ; Ruiz-Corral et al, 2008 ; Chetelat et al, 2009 ; Arellano-Rodríguez et al, 2013 ; Ruiz-Corral et al, 2013 ; Cervantes-Moreno et al, 2014 ; Chen et al, 2015 ; Nosenko et al, 2016 ; Stam et al, 2017a ; Stam et al, 2017b ; Flores-Hernández et al, 2017 ; Razali et al, 2018 ; Dinh et al, 2019 ; Vilchez et al, 2019 ) with potential use for genetic breeding, identification of routes of germplasm accession, and areas of high and low diversity for use and conservation ( Vilchez et al, 2019 ). In the information contained in Table 3 , Table 4 , and Figures 4 , 5 , it is possible to identify species with extreme values that indicate tolerance or resistance to climatic and edaphic factors, with potential use as germplasm for genetic breeding.…”

Section: Discussionmentioning

confidence: 99%

“…By considering plant genetic resources as the biological foundation for maintaining and improving crop productivity ( Kantar et al, 2015 ), wild tomato species constitute an important gene pool due to the presence of genes with tolerance and resistance to biotic and abiotic factors ( Arellano-Rodríguez et al, 2013 ; Cervantes-Moreno et al, 2014 ; Nosenko et al, 2016 ; Razali et al, 2018 ; Dinh et al, 2019 ) with potential use for breeding programs. Additionally, several questions arise about these gene pools, such as current distribution, population dynamics in situ or ex situ , and how are they used directly or as sources of genes to generate new varieties that respond to current and future basic problems of tomato cultivation (for example, climate change, diseases, pests), including the contribution of genes capable of conferring a greater nutritional–nutraceutical quality to new varieties ( Chávez-Servia et al, 2011 ; Hernández-Bautista et al, 2014 ).…”

Section: Introductionmentioning

confidence: 99%

Edaphoclimatic Descriptors of Wild Tomato Species (Solanum Sect. Lycopersicon) and Closely Related Species (Solanum Sect. Juglandifolia and Sect. Lycopersicoides) in South America

et al. 2021

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Wild species related to cultivated tomato are essential genetic resources in breeding programs focused on food security to face future challenges. The ecogeographic analysis allows identifying the species adaptive ranges and most relevant environmental variables explaining their patterns of actual distribution. The objective of this research was to identify the diversity, ecological descriptors, and statistical relationship of 35 edaphoclimatic variables (20 climatic, 1 geographic and 14 edaphic variables) from 4,649 accessions of 12 wild tomato species and 4 closely related species classified in Solanum sect. Lycopersicon and clustered into four phylogenetic groups, namely “Lycopersicon group” (S. pimpinellifolium, S. cheesmaniae, and S. galapagense), “Arcanum group” (S. arcanum, S. chmielewskii, and S. neorickii), “Eriopersicon group” (S. habrochaites, S. huaylasense, S. corneliomulleri, S. peruvianum, and S. chilense), “Neolycopersicon group” (S. pennellii); and two phylogenetically related groups in Solanum sect. Juglandifolia (S. juglandifolium and S. ochranthum), and section Lycopersicoides (S. lycopersicoides and S. sitiens). The relationship between the climate and edaphic variables were determined by the canonical correlation analysis, reaching 89.2% of variation with the first three canonical correlations. The most significant climatic variables were related to humidity (annual evapotranspiration, annual precipitation, and precipitation of driest month) and physicochemical soil characteristics (bulk density, pH, and base saturation percentage). In all groups, ecological descriptors and diversity patterns were consistent with previous reports. Regarding edaphoclimatic diversity, 12 climate types and 17 soil units were identified among all species. This approach has promissory applications for biodiversity conservation and uses valuable genetic resources related to a leading crop.

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“…Among possible uses of this approach is the identification of the germplasm with tolerance to adverse biotic and abiotic factors (Foolad and Lin., 2000;Mittova et al, 2004;Venema et al, 2005;Zhao et al, 2005;Ruiz-Corral et al, 2008;Chetelat et al, 2009;Arellano-Rodríguez et al, 2013;Ruiz-Corral et al, 2013;Cervantes-Moreno et al, 2014;Chen et al, 2015;Nosenko et al, 2016;Stam et al, 2017a;Stam et al, 2017b;Flores-Hernández et al, 2017;Razali et al, 2018;Dinh et al, 2019;Vilchez et al, 2019) with potential use for genetic breeding, identification of routes of germplasm accession, and areas of high and low diversity for use and conservation (Vilchez et al, 2019). In the information contained in Table 3 Finally, the hot spot analysis could satisfactorily identify regions with the greatest diversity of species.…”

Section: Discussionmentioning

confidence: 99%

“…By considering plant genetic resources as the biological foundation for maintaining and improving crop productivity (Kantar et al, 2015), wild tomato species constitute an important gene pool due to the presence of genes with tolerance and resistance to biotic and abiotic factors (Arellano-Rodríguez et al, 2013;Cervantes-Moreno et al, 2014;Nosenko et al, 2016;Razali et al, 2018;Dinh et al, 2019) with potential use for breeding programs. Additionally, several questions arise about these gene pools, such as current distribution, population dynamics in situ or ex situ, and how are they used directly or as sources of genes to generate new varieties that respond to current and future basic problems of tomato cultivation (for example, climate change, diseases, pests), including the contribution of genes capable of conferring a greater nutritional-nutraceutical quality to new varieties (Chávez-Servia et al, 2011;Hernández-Bautista et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

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High-Altitude Wild Species Solanum arcanum LA385—A Potential Source for Improvement of Plant Growth and Photosynthetic Performance at Suboptimal Temperatures

Cited by 9 publications

References 46 publications

Review: Holistic pest management against early blight disease towards sustainable agriculture

Review: Holistic pest management against early blight disease towards sustainable agriculture

Edaphoclimatic Descriptors of Wild Tomato Species (Solanum Sect. Lycopersicon) and Closely Related Species (Solanum Sect. Juglandifolia and Sect. Lycopersicoides) in South America

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