Use of a Plastic Rain Shield Reduces Fruit Decay and Need for Fungicides in Sweet Cherry

It has been shown previously that covering sweet cherry trees (Prunus avium L.) with rain shields made of polyethylene or other waterproof, light-transmitting material prior to harvest to prevent fruit cracking will reduce fruit decay by various fungi. In the present work, the effects of extending the covering period on fruit decay, fruit quality, and the potential reduction in number of fungicide applications were investigated. In six of eight trials, there were significant reductions in fruit decay in covered fruit compared with fruit that were not covered. The most prevalent fruit-decaying fungi were Monilinia laxa and Botrytis cinerea. Mucor piriformis and Colletotrichum gloeosporioides occurred in high amounts in one trial each. The treatments included covering during rain periods until harvest was over from (i) bloom (bloom-cover), (ii) 6 to 7 weeks prior to harvest (early-fruit-cover), (iii) 3 to 4 weeks prior to harvest (late-fruit-cover), and (iv) not covered. In two trials, the number of fungicide applications was similar between different covering times (bloom-cover not included), and in one trial no fungicides were applied at all (all treatments included). There was a significant effect of covering on fruit decay in all three trials, but there was no difference between covering 6 to 7 and 3 to 4 weeks prior to harvest. In the sprayed fields, the incidence of decay was 48% in fruit that were not covered compared with from 6 to 11% in covered fruit. In the unsprayed field, covering from bloom resulted in 14% fruit decay compared with 23 to 26% in the other two cover treatments. In five trials, all covering regimes were included, and the number of fungicide applications varied with time of covering. The number of fungicide applications for the different treatments were: bloom-cover, 0; early-fruit-cover, 1 to 4; late-fruit-cover, 2 to 5; uncovered, 3 to 6. The mean incidence of fruit decay at harvest for the five trials (range in parentheses) was 3.4 (2.0 to 4.3), 1.8 (0.4 to 4.0), 3.8 (1.8 to 7.7), and 16.5% (2.5 to 39.7), respectively, for the covering times listed. There were no significant differences in decay after storage (3 to 7 days at 4°C followed by 2 to 4 days at 20°C) among the different covering times in the six experiments where fruit were stored. The results indicate that fungicide applications were not needed if fruit were covered during rainy periods from bloom until the end of harvest, and it was possible to omit 1 fungicide application if the covering period was increased from 3 to 4 weeks to 6 to 7 weeks. The fruit quality was not reduced by increasing the covering period from the normal 3 to 4 weeks in any of the experiments.

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Influence of the Plastic Cover on the Protection of Sweet Cherry Fruit Against Cracking, on the Microclimate under Cover and Fruit Quality

Journal of Horticultural Research ◽

10.2478/johr-2019-0018 ◽

2019 ◽

Vol 27 (2) ◽

pp. 31-38

Author(s):

Augustyn Mika ◽

Zbigniew Buler ◽

Katarzyna Wójcik ◽

Dorota Konopacka

Keyword(s):

Fruit Quality ◽

Sweet Cherry ◽

Prunus Avium ◽

Fruit Weight ◽

Solar Irradiation ◽

Anthocyanin Content ◽

Total Anthocyanin ◽

Fruit Cracking ◽

Mean Temperature ◽

Tree Canopies

AbstractTo study possibility of protection of sweet cherry fruit against cracking several rows of ‘Lapins’ sweet cherry (Prunus avium L.) trees grafted on ‘Colt’ rootstock, spaced 5 × 2.5 m and trained to a central leader were covered with a plastic foil to a height of 5 m. Several rows were left uncovered as a control. In the years 2016 and 2018, sun irradiation, air temperature and fruit quality were evaluated. The plastic cover reduced solar irradiation under the tunnel roof by around 40%. Light distribution within tree canopies was depleted by roughly 50%, but in the lower parts of the tree canopies, it was reduced to 6%, which is below the critical level (20%) estimated for apple trees. These results indicate the necessity to remove the covers as soon as possible after harvesting. Mean daily temperature near the ground was lower under the covers than outside, but at the height of 4.0 m, daily mean temperature was 0.4 °C higher and mean temperature during midday hours was 1.5 °C higher. The plastic covering reduced the fruit cracking from about 20% to 2% in both seasons but did not affect the fruit yield. The plastic covering did not affect the firmness and antioxidant activity and total anthocyanin content, but in the year 2018, it reduced the mean fruit weight, soluble solid, titratable acidity, dry matter and total polyphenols content.

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Impact of Potassium Pre-Harvest Applications on Fruit Quality and Condition of Sweet Cherry (Prunus avium L.) Cultivated under Plastic Covers in Southern Chile Orchards

Plants ◽

10.3390/plants10122778 ◽

2021 ◽

Vol 10 (12) ◽

pp. 2778

Author(s):

Marco Bustamante ◽

Ariel Muñoz ◽

Iverly Romero ◽

Pamela Osorio ◽

Sergio Mánquez ◽

...

Keyword(s):

Fruit Quality ◽

Sweet Cherry ◽

Prunus Avium ◽

Soluble Solids ◽

Soluble Solids Content ◽

Southern Chile ◽

Post Harvest ◽

Fruit Cracking ◽

Solids Content ◽

The Impact

In rainy locations, sweet cherry is cultivated under plastic covers, which are useful to prevent fruit cracking but decrease cherry quality such as firmness and acidity. Here we evaluate the impact of pre-harvest K foliar applications on harvest and post-harvest fruit quality and condition of sweet cherry cultivated under plastic covers in southern Chile orchards. The study was performed on two commercial orchards (cv. Regina), located in different regions, during two consecutive seasons. In all cases, a conventional K regime (four sprays) was compared to an intensive K regimen (seven sprays). Results showed that cherries from the most southern region revealed lower acidity but higher soluble solids content weight and size. The intensive K regime improved the firmness and acidity of fruits of covered trees at harvest and post-harvest. Moreover, we found that condition defects were higher in fruits from un-covered trees and that trees grown under intensive K regime showed lower levels of cracking at harvest and pitting at post-harvest compared to trees treated with the conventional K regime. Otherwise, pedicel browning was inconsistently affected by K sprays. Our results revealed that an intensive K regime could improve the quality and condition of fruits at harvest and post-harvest in covered orchards of sweet cherry cv. Regina; however, the impacts can significantly vary depending on season and locality.

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Multi-year analyses on three populations reveal the first stable QTLs for tolerance to rain-induced fruit cracking in sweet cherry (Prunus avium L.)

Horticulture Research ◽

10.1038/s41438-021-00571-6 ◽

2021 ◽

Vol 8 (1) ◽

Author(s):

José Quero-García ◽

Philippe Letourmy ◽

José Antonio Campoy ◽

Camille Branchereau ◽

Svetoslav Malchev ◽

...

Keyword(s):

Confidence Intervals ◽

Sweet Cherry ◽

Prunus Avium ◽

Linear Models ◽

Basic Research ◽

Fruit Weight ◽

Phenotypic Variance ◽

Fruit Cracking ◽

The Stability ◽

Sweet Cherry Cultivars

AbstractRain-induced fruit cracking is a major problem in sweet cherry cultivation. Basic research has been conducted to disentangle the physiological and mechanistic bases of this complex phenomenon, whereas genetic studies have lagged behind. The objective of this work was to disentangle the genetic determinism of rain-induced fruit cracking. We hypothesized that a large genetic variation would be revealed, by visual field observations conducted on mapping populations derived from well-contrasted cultivars for cracking tolerance. Three populations were evaluated over 7–8 years by estimating the proportion of cracked fruits for each genotype at maturity, at three different areas of the sweet cherry fruit: pistillar end, stem end, and fruit side. An original approach was adopted to integrate, within simple linear models, covariates potentially related to cracking, such as rainfall accumulation before harvest, fruit weight, and firmness. We found the first stable quantitative trait loci (QTLs) for cherry fruit cracking, explaining percentages of phenotypic variance above 20%, for each of these three types of cracking tolerance, in different linkage groups, confirming the high complexity of this trait. For these and other QTLs, further analyses suggested the existence of at least two-linked QTLs in each linkage group, some of which showed confidence intervals close to 5 cM. These promising results open the possibility of developing marker-assisted selection strategies to select cracking-tolerant sweet cherry cultivars. Further studies are needed to confirm the stability of the reported QTLs over different genetic backgrounds and environments and to narrow down the QTL confidence intervals, allowing the exploration of underlying candidate genes.

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Pruning effects on vegetative growth and fruit quality of 'Bing'/'Gisela®5' and 'Bing'/'Gisela®6' sweet cherry trees (Prunus avium)

Ciencia e investigación agraria ◽

10.4067/s0718-16202012000100009 ◽

2012 ◽

Vol 39 (1) ◽

pp. 117-126 ◽

Cited By ~ 6

Author(s):

Macarena Villasante ◽

Soledad Godoy ◽

Juan Pablo Zoffoli ◽

Marlene Ayala

Keyword(s):

Fruit Quality ◽

Vegetative Growth ◽

Sweet Cherry ◽

Prunus Avium ◽

Cherry Trees

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Fruit ripening and harvest.

Sweet cherries ◽

10.1079/9781786398284.0282 ◽

2021 ◽

pp. 282-303

Author(s):

Lynn E. Long ◽

Gregory A. Lang ◽

Clive Kaiser

Keyword(s):

Fruit Quality ◽

Fruit Ripening ◽

Sweet Cherry ◽

Humidity Control ◽

Fruit Cracking ◽

Temperature And Humidity ◽

Harvesting Techniques ◽

Safe Transport

Abstract This chapter provides information on the processes that occur in the sweet cherry fruit during ripening prior to harvest. Some pre-harvest disorders, such as fruit cracking, and their management are presented. Some factors to consider during the harvesting of the fruits are also discussed, along with various harvesting techniques. Some postharvest fruit quality considerations are highlighted and the importance of postharvest temperature and humidity control and safe transport of fruits from the orchard to the packing house are pointed out.

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Interaction of Irrigation and Soil Management on Sweet Cherry Productivity and Fruit Quality at Different Crop Loads that Simulate Those Occurring by Environmental Extremes

HortScience ◽

10.21273/hortsci.49.2.215 ◽

2014 ◽

Vol 49 (2) ◽

pp. 215-220 ◽

Cited By ~ 12

Author(s):

Gerry H. Neilsen ◽

Denise Neilsen ◽

Frank Kappel ◽

T. Forge

Keyword(s):

Fruit Quality ◽

Sweet Cherry ◽

Prunus Avium ◽

Fruit Size ◽

Growth Yield ◽

Soil Management ◽

Cold Climate ◽

Soluble Solids ◽

Irrigation Frequency ◽

Cross Sectional

‘Cristalina’ and ‘Skeena’ sweet cherry cultivars (Prunus avium L.) on Gisela 6 (Prunus cerasus × Prunus canescens) rootstock planted in 2005 were maintained since 2006 in a randomly blocked split-split plot experimental design with six blocks of two irrigation frequency main plot treatments within which two cultivar subplots and three soil management sub-subplots were randomly applied. The focus of this study was the growth, yield, and fruit quality response of sweet cherry to water and soil management over three successive fruiting seasons, 2009–11, in a cold climate production area. The final 2 years of the study period were characterized by cool, wet springs resulting in low yield and yield efficiency across all treatments. Soil moisture content (0- to 20-cm depth) during the growing season was often higher in soils that received high-frequency irrigation (HFI) compared with low-frequency irrigation (LFI). HFI and LFI received the same amount of water, but water was applied four times daily in the HFI treatment but every other day in the LFI treatment. Consequently, larger trunk cross-sectional area (TCSA) and higher yield were found on HFI compared with LFI trees. Soil management strategies involving annual bloom time phosphorus (P) fertigation and wood waste mulching did not affect tree vigor and yield. Increased soluble solids concentration (SSC) occurred with LFI. Decreased SSC occurred with delayed harvest maturity in trees receiving P fertigation at bloom. The largest fruit size was correlated for both cultivars with low crop loads ranging from 100 to 200 g fruit/cm2 TCSA. Overall cool, wet spring weather strongly affected annual yield and fruit quality, often overriding cultivar and soil and water management effects.

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