Physiological and genetic control of vigour in a ‘Ramsey’ × ‘Riparia Gloire de Montpellier’ population

Hugalde, Inés; Riaz, Summaira; Agüero, Cecilia B.; Romero, N.; Barrios-Masias, Felipe H.; Nguyen, Andy Viet; Vila, Hernán; McElrone, Andrew J.; Talquenca, Sebastián Gómez; Arancibia, Celeste; Walker, Michael

doi:10.17660/actahortic.2017.1188.27

Cited by 3 publications

(9 citation statements)

References 18 publications

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“…Figure 3 shows vigor (canopy biomass, B) for the complete progeny and the parents, for 2014. Data for 2015 (not shown) showed similar results [25].…”

Section: Genetic Component Of Vigor: Qtl Mapping In a Grapevine Populsupporting

confidence: 61%

“…This clearly shows how LA, which depends on leaf biomass and the hydraulic situation (turgor that allows cell expansion), is so different between opposite genotypes. Big plants with higher total plant hydraulic conductance have more leaf area, with respect to their biomasses, than small plants [25].…”

Section: Physiological Component Of Vigormentioning

confidence: 99%

“…Specific leaf area (SLA: LA/leaf biomass) was calculated, and QTL mapping and detection were performed on both parental and consensus maps. A complete description of the techniques and methods used to measure and assess the variables studied is published by Hugalde et al [25].…”

Section: Physiological Component Of Vigormentioning

confidence: 99%

“…Hydraulic variables were not mapped, as they were measured in a smaller number of genotypes given the time-consuming nature of the methods that asses them. However, significant statistics evidenced an important role of root hydraulics in vigor definition [25].…”

Section: Physiological Component Of Vigormentioning

confidence: 99%

“…For the parental Ramsey map ( Table 3), during 2014, the first year of mapping, seven putative QTLs were found. LA/total biomass, SLA, and partitioning indices Vigor (canopy biomass) for the complete progeny and the parents for 2014 [25].…”

Section: Genetic Component Of Vigor: Qtl Mapping In a Grapevine Populmentioning

confidence: 99%

See 4 more Smart Citations

Studying Growth and Vigor as Quantitative Traits in Grapevine Populations

Hugalde¹,

Riaz²,

Agüero³

et al. 2019

Integrated View of Population Genetics

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Vigor is considered as a propensity to assimilate, store, and/or use nonstructural carbohydrates for producing large canopies, and it is associated with high metabolism and fast growth. Growth involves cell expansion and cell division. Cell division depends on hormonal and metabolic processes. Cell expansion occurs because cell walls are extensible, meaning they deform under the action of tensile forces, generally caused by turgor. There is increasing interest in understanding the genetic basis of vigor and biomass production. It is well established that growth and vigor are quantitative traits and their genetic architecture consists of a big number of genes with small individual effects. The search for groups of genes with small individual effects, which control a specific quantitative trait, is performed by QTL analysis and genetic mapping. Today, several linkage maps are available, like "Syrah" × "grenache," "Riesling" × "Cabernet Sauvignon," and "Ramsey" × Vitis riparia. This last progeny segregates for vigor and constituted an interesting tool for our genetic studies on growth.

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“…Figure 3 shows vigor (canopy biomass, B) for the complete progeny and the parents, for 2014. Data for 2015 (not shown) showed similar results [25].…”

Section: Genetic Component Of Vigor: Qtl Mapping In a Grapevine Populsupporting

confidence: 61%

Section: Physiological Component Of Vigormentioning

confidence: 99%

Section: Physiological Component Of Vigormentioning

confidence: 99%

Section: Physiological Component Of Vigormentioning

confidence: 99%

Section: Genetic Component Of Vigor: Qtl Mapping In a Grapevine Populmentioning

confidence: 99%

See 3 more Smart Citations

Studying Growth and Vigor as Quantitative Traits in Grapevine Populations

Hugalde¹,

Riaz²,

Agüero³

et al. 2019

Integrated View of Population Genetics

View full text Add to dashboard Cite

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Modeling vegetative vigour in grapevine: unraveling underlying mechanisms

Hugalde

Agüero

Barrios-Masias

et al. 2020

Heliyon

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Mechanistic modeling constitutes a powerful tool to unravel complex biological phenomena. This study describes the construction of a mechanistic, dynamic model for grapevine plant growth and canopy biomass (vigor). To parametrize and validate the model, the progeny from a cross of Ramsey ( Vitis champinii ) × Riparia Gloire ( V. riparia ) was evaluated. Plants with different vigor were grown in a greenhouse during the summer of 2014 and 2015. One set of plants was grafted with Cabernet Sauvignon. Shoot growth rate (b), leaf area (LA), dry biomass, whole plant and root specific hydraulic conductance (k H and L pr ), stomatal conductance (g s ), and water potential (Ψ) were measured. Partitioning indices and specific leaf area (SLA) were calculated. The model includes an empirical fit of a purported seasonal pattern of bioactive GAs based on published seasonal evolutionary levels and reference values. The model provided a good fit of the experimental data, with R = 0.85. Simulation of single trait variations defined the individual effect of each variable on vigor determination. The model predicts, with acceptable accuracy, the vigor of a young plant through the measurement of L pr and SLA. The model also permits further understanding of the functional traits that govern vigor, and, ultimately, could be considered useful for growers, breeders and those studying climate change.

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Seed treatments with salicylic acid and Azospirillum brasilense enhance growth and yield of maize plants (Zea mays L.) under field conditions

Larramendi¹,

Salas‐Marina²,

García³

et al. 2023

Rev. FCA UNCUYO

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Salicylic acid and Azospirillum brasilense stimulate plant growth and productivity. In some environments, plant physiology similarly responds to both bioactive products. Considering this, a field experiment was conducted to study the physiological effect of Salicilic acid and A. brasilense on growth and grain yield of maize plants. The experiment involved three treatments consisting of imbibed seeds in an aqueous solution of SA (0.01 mM), inoculated seeds with A. brasilense and a control treatment. Seed imbibition in SA and inoculation with A. brasilense improved vegetative growth in the early stages of crop ontogeny, increasing leaf growth, plant height, stem diameter and biomass accumulation. Spikelet length and weight were greater in plants first inoculated with A. brasilense and then treated with SA. Results indicated that SA stimulated biomass partitioning towards leaves, root and stem, while A. brasilense mainly affected leaf growth, plant height, ear dimensions and grain yield. Such results turn crucial for biological fertilization strategies aimed at reducing pollutant loads that accompany chemical fertilizers. Both products can be part of maize management practices given competitive economic advantages and sustainability. Highlights: Seed imbibition in SA and inoculation with brasilense improved vegetative growth in the early stages of crop ontogeny, increasing leaf growth, plant height, stem diameter and biomass accumulation. Salicylic Acid stimulated biomass partitioning towards leaves, root and stem in maize plants. Azospirillum brasilense stimulates leaf growth, plant height, as well as ear dimensions and grain yield in corn plants.

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Physiological and genetic control of vigour in a ‘Ramsey’ × ‘Riparia Gloire de Montpellier’ population

Cited by 3 publications

References 18 publications

Studying Growth and Vigor as Quantitative Traits in Grapevine Populations

Studying Growth and Vigor as Quantitative Traits in Grapevine Populations

Modeling vegetative vigour in grapevine: unraveling underlying mechanisms

Seed treatments with salicylic acid and Azospirillum brasilense enhance growth and yield of maize plants (Zea mays L.) under field conditions

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