[PDF] Impact Of Different Irrigation Strategies On Grapes And Wine Quality Of Four Grapevine Cultivars Vitis Sp In Cool Climate Conditions An Investigation Into The Relationships Among Aba Water Status Grape Cultivar And Wine Quality eBook

Author : Hernâni Gerós
Publisher : John Wiley & Sons
Page : 400 pages
File Size : 16,10 MB
Release : 2015-10-05
Category : Technology & Engineering
ISBN : 111873601X

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Grapes (Vitis spp.) are economically the most important fruit species in the world. Over the last decades many scientific advances have led to understand more deeply key physiological, biochemical, and molecular aspects of grape berry maturation. However, our knowledge on how grapevines respond to environmental stimuli and deal with biotic and abiotic stresses is still fragmented. Thus, this area of research is wide open for new scientific and technological advancements. Particularly, in the context of climate change, viticulture will have to adapt to higher temperatures, light intensity and atmospheric CO2 concentration, while water availability is expected to decrease in many viticultural regions, which poses new challenges to scientists and producers. With Grapevine in a Changing Environment, readers will benefit from a comprehensive and updated coverage on the intricate grapevine defense mechanisms against biotic and abiotic stress and on the new generation techniques that may be ultimately used to implement appropriate strategies aimed at the production and selection of more adapted genotypes. The book also provides valuable references in this research area and original data from several laboratories worldwide. Written by 63 international experts on grapevine ecophysiology, biochemistry and molecular biology, the book is a reference for a wide audience with different backgrounds, from plant physiologists, biochemists and graduate and post-graduate students, to viticulturists and enologists.

Author : Alexander David Levin
Publisher :
Page : pages
File Size : 43,47 MB
Release : 2016
Category :
ISBN : 9781369615692

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In recent years, deliveries of water for agricultural use in the San Joaquin Valley (SJV) of California have been reduced, or in some instances cut all together. Since 1980, the acreage of annual crops has decreased by 40%, while the acreage of perennial crops has increased by 77%. Recent research has shown that perennial crops have a higher potential for water conservation. Also, it has been shown that yields do not decrease significantly under some moderate levels of water stress. As trends in California agriculture shift away from traditional field crops, more detailed information is needed on the amount of water required to grow tree and vine crops. Vineyards now account for nearly half of the total acreage of woody perennial crops in California. Worldwide, approximately 10,000 grapevine cultivars are grown on over 8 million hectares of land covering a wide range of climates, from hot and dry to cold and wet. This apparent genetic diversity has led researchers to group different cultivars according to the drought responses of numerous vegetative and reproductive parameters. However, no studies have utilized an established cultivar trial to directly compare multiple cultivars grown at the same site and subjected to the same water stress. Growers in the SJV would have the most potential to conserve water if the more was known about how individual cultivars response to drought at different times of the growing season. Seventeen different red wine grape V. vinifera L. cultivars grafted on to the same rootstock (1103P) were grown in a replicated cultivar trial, and subjected to three different deficit irrigation regimes over four years in order to manipulate [psi][subscript l] at various times throughout the growing season. An early deficit treatment (ED) received no applied water from berry set until veraison, and then was irrigated at 50% of ET[subscript c] from veraison until harvest. A late deficit treatment (LD) was irrigated at 100% ET[subscript c] from berry set until veraison, and then received no applied water until harvest. The sustained deficit treatment (SD) was irrigated at 50% of ET[subscript c] from berry set until harvest. Previous work has categorized wine grape cultivars into ‘isohydric’ or ‘anisohydric’ groups based on the response of stomatal conductance (g[subscript s]) to plant water status (leaf water potential ([psi][subscript l])). Significant differences in l among cultivars were observed during both time periods, but the effects of the water deficits were consistent across growing seasons. There were no significant differences in maximum stomatal conductance (g[subscript max]) among cultivars. Cultivar-specific responses of g[subscript s] to [psi][subscript l] did not separate into two distinct groups, but were broadly distributed based on a negative relationship between the [psi][subscript l] threshold for the beginning of stomatal closure at 95% of g[subscript max] and the rate of stomatal closure. Cultivar mean [psi][subscript l] values were positively related to the [psi][subscript l] threshold for the end of stomatal closure at 25% of g[subscript max]. Potential mechanisms of stomatal closure related to vascular anatomy are discussed. The quantitative models of g[subscript s] response to [psi][subscript l] presented in this study provide baseline threshold [psi][subscript l] values from which to compare cultivars in future research. With increasing competition for water resources, accurate information regarding crop water requirements is needed for informed irrigation management decisions. Early (preveraison) water deficits (ED-treatment) consistently and significantly reduced yields compared to the control across all years and cultivars, but the late (post-veraison) deficit (LD) treatment vines were not different from the control. The reduction in yield with ED was primarily due to a significant reduction in berry fresh weight (FW), and clusters per vine, with little change in berries per cluster. The LD treatment had a limited effect on berry FW and did not affect other yield components. Variation in yield was mostly due to berries per vine rather than berry FW, although this depended on cultivar. There were also cultivar differences in the proportion of variation in berries per vine explained by either clusters per vine or berries per cluster. Irrigation treatment or applied water amounts did not have a consistent effect on the water footprint but it was strongly dependent on yield. Implications of the timing of water deficits on the productivity of wine grapes in the SJV are discussed with respect to cultivar differences in yield formation. Previous research has shown that berry size is the most important component in grapevine yield, and that the sensitivity of grape berry growth to water deficits depends on the timing of those deficits. Berry growth was significantly reduced in ED for every cultivar, and berry absolute and relative growth rates (AGR and RGR, respectively) were significantly lower at the first measurement date after imposition of irrigation treatments. RGR was consistently higher in ED compared to SD and LD postveraison, but lost growth was not made up for in ED berries at harvest. AGR and RGR were significantly more sensitive to vine water status preveraison compared to postveraison for all cultivars. Ripening rate was highly conserved across cultivars and years, and was only slightly (but significantly) reduced in ED compared to SD and LD. In comparison, sugar translocation rate varied widely among cultivars and years, and was significantly different among all irrigation treatments. Sugar translocation rate depended strongly on berry size at veraison, but ripening rate did not. Irrigation treatments and cultivars affected the timing of ripening events independently with no interaction, and the timing of events was more dependent on berry sugar concentration (TSS) than days after anthesis (DAA). The results of this study may provide growers with cultivar-specific pre- and postveraison vine water status targets for irrigation scheduling, as well as assist with the timing of vineyard operations through better understanding of the timing of ripening events near the end of the season.

Author : Xiaochi Ma
Publisher :
Page : 197 pages
File Size : 39,94 MB
Release : 2019
Category : Cabernet (Wine)
ISBN :

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Washington state is currently the second largest premium wine producer in the United States, with Vitis vinifera L. cv. Cabernet Sauvignon as one of the top produced varieties. Grape production in Washington not only depends on natural rainfall, but also on supplemental irrigation given the semi-arid climate. However, competition for agricultural water availability between grapes and other staple crops has become intense due to unstable climatic patterns and local policies, making efficient water management essential for sustainable viticulture and the development of the wine industry in Washington. Using Cabernet Sauvignon as a model variety, this project aimed to improve efficiency of water management by investigating the effects of novel irrigation strategies and watering regimes on grapevine physiology and grape production. Chapter one provides a comprehensive review of grapevine performance under water stress and discusses strategies to enhance water management in vineyards. Chapters two to four describe the implementation of a novel subsurface drip irrigation strategy named direct root-zone irrigation (DRZ) and summarize grapevine responses. Compared with traditional surface drip irrigation, DRZ increased leaf net CO2 assimilation rate and yield, reduced shallow root growth, and showed potential to save water and enhance crop water use efficiency without reducing grape quality. DRZ likely increased soil water availability but did not show significant effect on root growth in the deep soil profile. Finally, a greenhouse study described in chapter five investigated the responses of grapevine to four different watering regimes, which revealed that increasing watering rate after veraison did not improve grape yield and quality, but it helped improve carbon assimilation in leaves and relieved water stress in grapevines during later growing stages. Moreover, a negative correlation was found between peroxisome abundance in leaves and midday stem water potential, which provides a cellular readout to better understand grapevine growth under water deficit. Overall, this project provides new ways to improve water productivity and advances the understanding of physiological and molecular responses of grapevines to water stress.

Author : José Tomás Matus
Publisher : Frontiers Media SA
Page : 423 pages
File Size : 18,56 MB
Release : 2019-12-06
Category :
ISBN : 2889632113

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Fruits play a substantial role in the human diet as a source of vitamins, minerals, dietary fiber and a wide range of molecules relevant to health promotion and disease prevention. The characterization of genes involved in the accumulation of these molecules during fruit development and ripening, and in the overall plant’s response to the environment, constitutes a fundamental step for improving yield- and quality-related traits, and for predicting this crop’s behavior in the field. This is certainly the case for grapevine (Vitis vinifera L.), one of the most largely cultivated fruit crops in the world. The cultivation of this species is facing challenging scenarios driven by climate change – including increases in atmospheric carbon dioxide (CO2), solar radiation, and earth surface temperature, and decreases of water and nutrient availability. All these events will potentially affect the grapevine phenology, physiology, and metabolism in many growing regions and ultimately affect the quality of their fruits and of the most important derived product, the wine. The sequencing of the grapevine genome has given rise to a new era, characterized by the generation of large-scale data that requires complex computational analyses. Numerous transcriptomic and metabolomic studies have been performed in the past fifteen years, providing insights into the gene circuits that control the accumulation of all sorts of metabolites in grapevines. From now on, the integration of two or more ‘omics’ will allow depicting gene-transcript-metabolite networks from a more holistic (i.e. systems) perspective. This eBook attempts to support this new direction, by gathering innovative studies that assess the impact of genotypes, the environment, and agronomical practices on fruits at the ‘ome’-scale. The works hereby collected are part of a Research Topic covering the use of ‘omics’-driven strategies to understand how environmental factors and agronomical practices – including microclimate modification (e.g. sunlight incidence or temperature), water availability and irrigation, and postharvest management – affect fruit development and composition. These studies report well-settled transcriptomic and metabolomic methods, in addition to newly-developed techniques addressing proteome profiles, genome methylation landscapes and ionomic signatures, some of which attempt to tackle the influence of terroir, i.e. the synergic effect of (micro)climate, soil composition, grape genotype, and vineyard practices. A few reviews and opinions are included that focus on the advantages of applying network theory in grapevine research. Studies on vegetative organs in their relation to fruit development and on fruit-derived cell cultures are also considered.

Author : António M. Jordão
Publisher : BoD – Books on Demand
Page : 386 pages
File Size : 44,12 MB
Release : 2018-02-28
Category : Technology & Engineering
ISBN : 9535138332

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The book "Grapes and Wines: Advances in Production, Processing, Analysis, and Valorization" intends to provide to the reader a comprehensive overview of the current state-of-the-art and different perspectives regarding the most recent knowledge related to grape and wine production. Thus, this book is composed of three different general sections: (1) Viticulture and Environmental Conditions, (2) Wine Production and Characterization, and (3) Economic Analysis and Valorization of Wine Products. Inside these 3 general sections, 16 different chapters provide current research on different topics of recent advances on production, processing, analysis, and valorization of grapes and wines. All chapters are written by a group of international researchers, in order to provide up-to-date reviews, overviews, and summaries of current research on the different dimensions of grape and wine production. This book is not only intended for technicians actively engaged in the field but also for students attending technical schools and/or universities and other professionals that might be interested in reading and learning about some fascinating areas of grape and wine research.

Author : Nafees A. Khan
Publisher : I K International Pvt Ltd
Page : 206 pages
File Size : 33,81 MB
Release : 2008-03-21
Category : Science
ISBN : 8189866958

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Abiotic stresses such as temperature, radiation, salinity, heavy metals and drought are the main factors that limit crop productivity. The anthropogenic activities and changed agricultural system, intense use of chemical fertilizers and artificial irrigation have increased temperature, UV-B radiation, drought, salinity and heavy metals stresses and caused yield losses annually to a greater extent. To overcome the yield losses due to abiotic stresses, plants need to possess mechanisms of avoidance and tolerance to stress. For sustainable agriculture development, future crops should have abiotic stress resistant traits and the mechanism for stress tolerance. The tolerance mechanisms can also be improved by the development of new techniques employing plant physiology and plant molecular biology tools. In this present book the advances in the area of abiotic stress responses and stress management have been included. The information may be useful in elucidating limits and tolerance of a plant to abiotic stress. The present volume, comprising seventeen chapters by outstanding and eminent specialists across the world, covers the information on abiotic stresses such as salinity, heavy metals, drought and herbicides.

Author : Jason Edward Stout
Publisher :
Page : pages
File Size : 29,4 MB
Release : 2015
Category : Grapes
ISBN :

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RDI significantly reduced soil water availability at veraison, but the deficit was replenished by the end of the season. Water use efficiency was maximized in 'Cabernet Sauvignon' when additional water was applied post-veraison. RDI in 'Concord' initially reduced yields, but the vines adapted over time.

Author : Wesley D. Lowrey
Publisher :
Page : pages
File Size : 43,45 MB
Release : 2004
Category :
ISBN :

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A study was devised to evaluate influences of irrigation and fertigation practices on Vitis vinifera and Vitis labruscana grapes in the Niagara Peninsula. A modified FAO Penman- Monteith evapotranspiration formula was used to calculate water budgets and schedule irrigations. Five deficit irrigation treatments (non-irrigated control; deficits imposed postbloom, lag phase, and veraison; fiiU season irrigation) were employed in a Chardonnay vineyard. Transpiration rate (4-7 /xg H20/cmVs) and soil moisture data demonstrated that the control and early deficit treatments were under water stress throughout the season. The fiiU season irrigation treatment showed an 18% (2001) and 19% (2002) increase in yield over control due to increased berry weight. Soluble solids and wine quality were not compromised, and the fiiU season treatment showed similar or higher °Brix than all other treatments. Berry titratable acidity andpH also fell within acceptable levels for all five treatments. Irrigation/fertigation timing trials were conducted on Concord and Niagara vines in 2001- 02. The six Concord treatments consisted of a non-irrigated control, irrigation fi^om Eichhom and Lorenz (EL) stage 12 to harvest, and four fertigation treatments which applied 70 kg/ha urea. The nine Niagara treatments included a non-irrigated control, two irrigated treatments (ceasing at veraison and harvest, respectively) and six fertigation treatments of various durations. Slight yield increases (ca. 10% in Concord; 29% in Niagara) were accompanied by small decreases in soluble solids (1.5°Brix), and methyl anthranilate concentrations. Transpiration rate and soil moisture (1 1.9-16.3%) data suggested that severe water stress was present in these Toledo clay based vineyards.