Partitioning of Dry Matter into Fruit Explains Cultivar Differences in Vigor in Young Olive (Olea europaea L.) Trees

Rosati, A.; Paoletti, Andrea; Hariri, Raeed Al; Morelli, A. P.; Famiani, Franco

doi:10.21273/hortsci12739-17

Cited by 16 publications

(15 citation statements)

References 43 publications

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“…Increments in TCSA (and thus for whole-tree biomass) were lower for fruiting than non-fruiting treatments ( Figure 2 A and Figure 3 ), in line with previous findings in olive trees ( Fernández et al., 2015 ; Rosati et al., 2018a ). The TCSA of Arbequina NF was comparable to that of Frantoio NF up to the first three years of observation, confirming that the low vigor generally observed in Arbequina is due to its early and abundant fruiting (up to 159 g of fruit + flower dry matter per tree in the first and second year after transplanting Rosati et al., 2018a ; 2018b ). In the fourth year, however, the TCSA in Frantoio NF was significantly greater than that of Arbequina NF ( Figure 2 A).…”

Section: Discussionsupporting

confidence: 91%

“…Recently, it has been found that deflowering resulted in strong increments in vegetative growth also in young olive trees, and that this eliminated differences in vigor (i.e. vegetative growth) between plants of the cultivar Arbequina (low vigor) and those of the cultivar Frantoio (high vigor), suggesting that cultivar differences in vigor may be explained in terms of different dry matter partitioning towards fruit (Rosati et al, 2017(Rosati et al, , 2018a. This demonstrated that competition for resources plays a major role in determining tree growth in young olive trees, suggesting that tree growth is source limited (Rosati et al, 2018b).…”

Section: Introductionmentioning

confidence: 99%

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Effects of cultivar, fruit presence and tree age on whole-plant dry matter partitioning in young olive trees

Paoletti

Rosati

Famiani

2021

Heliyon

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This study investigated the effects of cultivar, fruit presence and tree age on whole-plant partitioning of dry matter and energy equivalents (i.e., glucose equivalents). Young trees of two cultivars characterized by different vigor (i.e., Arbequina, low vigor and Frantoio, high vigor) were either completely deflowered from 2014 to 2017 or never, providing two contrasting levels of cumulated reproductive growth over the following 4 years. Total vegetative dry matter growth over the 4 years was assessed by destructive samplings (whole tree). Plant growth was inversely correlated to reproductive efforts, with Arbequina producing more and growing less than Frantoio. Deflowered trees grew similarly across cultivars, although deflowered Arbequina grew statistically less than deflowered Frantoio by the fourth year, due to abundant flower production. Total reproductive (flowers þ fruit) and vegetative biomass production were the same for all cultivars and treatments. Arbequina had a greater distribution of dry matter in directly productive structures (current and one-year-old shoots) and in leaves. This allows it to increase the number of current and following-year production sites, and to save in the resources invested in non-productive sinks (roots, trunk and branches), thus liberating resources for reproductive growth. Greater investments in leaves allow it to intercept more light and thus to increase assimilation. Increased assimilation and increased partitioning towards productive structures, and decreased competition by nonproductive structures might contribute to explain the greater early bearing attitude of this cultivar.

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Section: Discussionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Effects of cultivar, fruit presence and tree age on whole-plant dry matter partitioning in young olive trees

Paoletti

Rosati

Famiani

2021

Heliyon

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“…The branching habit is one of the main factors affecting carbon partitioning between wood and leaves. Low-vigor and highbranching genotypes of the SILVOLIVE collection have a higher number of nodes and leaves (R 2 = 0.7), which means increased canopy density and may determine higher number of potential fruiting sites, becoming an important trait to be used to produce and export more assimilates toward fruits (Rosati et al, 2018). Otherwise, the hexaploid MAR1 and MAR3, together with most FRA and AMS genotypes show high apical growth with a low number of secondary stems.…”

Section: Phenotypic Diversity Of the Silvolive Collectionmentioning

confidence: 99%

“…Convincing evidence has been provided that these traits are genetically encoded by the root portion of the grafted plant, playing the rootstock genotype essential roles in shaping variation of these traits in the scion (Warschefsky et al, 2016). In addition, rootstocks can also affect the branching pattern of the scion (Costes et al, 2010) and promote early and more abundant bearing in young olive trees (Rosati et al, 2017(Rosati et al, , 2018. On the one hand, we have verified that all subspecies can be grafted with commercial olive varieties, including cuspidata, which has the maximum genetic distance with europaea ( Supplementary Table S9).…”

Section: Silvolive a Germplasm Collection For The Identification Of mentioning

confidence: 99%

SILVOLIVE, a Germplasm Collection of Wild Subspecies With High Genetic Variability as a Source of Rootstocks and Resistance Genes for Olive Breeding

et al. 2020

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Wild subspecies of Olea europaea constitute a source of genetic variability with huge potential for olive breeding to face global changes in Mediterranean-climate regions. We intend to identify wild olive genotypes with optimal adaptability to different environmental conditions to serve as a source of rootstocks and resistance genes for olive breeding. The SILVOLIVE collection includes 146 wild genotypes representative of the six O. europaea subspecies and early-generations hybrids. These genotypes came either from olive germplasm collections or from direct prospection in Spain, continental Africa and the Macaronesian archipelago. The collection was genotyped with plastid and nuclear markers, confirming the origin of the genotypes and their high genetic variability. Morphological and architectural parameters were quantified in 103 genotypes allowing the identification of three major groups of correlative traits including vigor, branching habits and the belowground-to-aboveground ratio. The occurrence of strong phenotypic variability in these traits within the germplasm collection has been shown. Furthermore, wild olive relatives are of great significance to be used as rootstocks for olive cultivation. Thus, as a proof of concept, different wild genotypes used as rootstocks were shown to regulate vigor parameters of the grafted cultivar "Picual" scion, which could improve the productivity of high-density hedgerow orchards.

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“…Notwithstanding, in stone fruit trees, the presence of an elevated number of fruits alters the source-sink balance, by increasing assimilate accumulation into the fruits and/or by inducing an intensification of competition among them and between vegetative and reproductive growth (Morandi et al, 2008;Costa et al, 2018). This is also the case in olive (Rosati et al, 2017(Rosati et al, , 2018b. As a rule, high crop loads cause a decrease in tree growth (Intrigliolo and Castel, 2009), mainly during the last phases of fruit development (Intrigliolo et al, 2014).…”

Section: Competition Among Sinksmentioning

confidence: 75%

Sugar Metabolism in Stone Fruit: Source-Sink Relationships and Environmental and Agronomical Effects

et al. 2020

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Partitioning of Dry Matter into Fruit Explains Cultivar Differences in Vigor in Young Olive (Olea europaea L.) Trees

Cited by 16 publications

References 43 publications

Effects of cultivar, fruit presence and tree age on whole-plant dry matter partitioning in young olive trees

Effects of cultivar, fruit presence and tree age on whole-plant dry matter partitioning in young olive trees

SILVOLIVE, a Germplasm Collection of Wild Subspecies With High Genetic Variability as a Source of Rootstocks and Resistance Genes for Olive Breeding

Sugar Metabolism in Stone Fruit: Source-Sink Relationships and Environmental and Agronomical Effects

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