Tree performances of eight rootstocks grafted with ‘Šumadinka’ sour cherry

Plant material and trial layout

In spring 2015, the sour cherry cv. ‘Šumadinka’ was budded onto seven clonal rootstocks [Colt, MaxMa 14 (syn.: Brokforest, MaxMa Delbard 14), Krymsk 6, Adara, Cigančica (syn.: CigányMeggy), Gisela 5 and Gisela 6] and one generative selection of Myrobalan (seedlings), which were then planted in the field in Spring 2016. ‘Šumadinka’ was chosen for this experiment due to its large fruits, good cropping and commercial importance in the Serbian sour cherry industry. It was named and released by the Fruit Research Institute, Čačak (Serbia).

The sour cherry trial was located at Prislonica (near Čačak city, western Serbia, 43°33’N and 16°21’E, 300 m above sea level) on heavy, shallow and acidic soil. In this area (moderate climate), the average annual temperature from 2016 to 2020 was 12.9°C and the total annual rainfall was 810.9 mm. The orchard had a clay-loam soil texture with 1.62% organic matter and low soil pH (4.86) in 0-30 cm soil depth. Contents of total N, available P₂O₅ and K₂O, CaO and MgO were 0.16%, 178 mg g^-1, 220 mg g^-1, 0.39% and 6.2 mg g^-1 on a dry matter basis, respectively.

Horticultural management practices such as fertilization, training, pruning and weed control were conducted as in a commercial orchard. Fungicides and insecticides were applied as necessary for pest and disease control, following industry standards. Irrigation was not applied.

The experiment was established in a randomized block design with five trees for each rootstock-scion combination in four replicates (n = 20). Guard rows were used to avoid edge effects. Trees were trained to a high-density central leader system - modified Brunner-spindle (4.0 m × 2.0 m or 1,250 trees ha^-1).

Measurements

Tree growth, precocity, yield, leaf and stem properties and the primary fruit quality attributes were all observed during the research period.

Data analysis

All data obtained in the present study were subjected to analysis of variance (ANOVA) using the Microsoft Office Excel software (Microsoft Corporation, Redmond, WA, USA) and means were separated by the LSD test at p ≤ 0.05.

Tree growth, precocity and productivity

In the environmental conditions of the Čačak region, tree growth, as assessed by TCSA, was significantly influenced by rootstock starting from the third year after planting, with different increasing rates of TCSA (Fig. 1). Other authors also reported that rootstocks significantly influenced tree vigour of sour cherries (Hrotkó et al., 1996Hrotkó K, Nádosy F, Végvári G, Füzesséry A, 1996. Growth and productivity of sour cherry varieties grafted on different Mahaleb rootstocks. Acta Hortic 410: 499-502. https://doi.org/10.17660/ActaHortic.1996.410.81; Bujdosó et al., 2004Bujdosó G, Hrotkó K, Stehr R, 2004. Evaluation of sweet and sour cherry cultivars on German dwarfing rootstocks in Hungary. J Fruit Ornam Plant Res 12: 233-244.). By the fifth (final) year after planting, trees on Adara exhibited the highest TCSA value. In contrast, the lowest TCSA was observed on Myrobalan, although no significant differences were found with the semi-dwarfing Gisela 6 and Krymsk 6 rootstocks. Adara’s increased vigour is consistent with findings by Moreno et al. (1995Moreno MA, Tabuenca MC, Cambra R (1995) Adara, a plum rootstock for cherries and other stone fruit species. HortScience 30(6): 1316-1317. https://doi.org/10.21273/HORTSCI.30.6.1316, 1996Moreno MA, Montañés L, Tabuenca MC, Cambra R (1996) The performance of Adara as a cherry rootstock. Sci Hortic 65(1): 85-91. https://doi.org/10.1016/0304-4238(95)00862-4). Adara was initially selected as a rootstock for sweet cherries, but Moreno et al. (1995)Moreno MA, Tabuenca MC, Cambra R (1995) Adara, a plum rootstock for cherries and other stone fruit species. HortScience 30(6): 1316-1317. https://doi.org/10.21273/HORTSCI.30.6.1316 reported good graft compatibility with some sour cherry cultivars both in nursery and orchard conditions. Moreover, in the present trial, this rootstock demonstrated good adaptation capacity to growing conditions, particularly shallow, heavy and acidic soil. As previously suggested by Sorce et al. (2002)Sorce C, Massai R, Picciarelli P, Lorenzi R, 2002. Hormonal relationships in xylem sap of grafted and ungrafted Prunus rootstocks. Sci Hortic 93(3-4): 333-342. https://doi.org/10.1016/S0304-4238(01)00338-7 in Prunus rootstocks, greater growth features may lead to higher TCSA in the ‘Šumadinka’ scion by enhancing the availability of specific cytokinins (e.g. zeatin riboside) to the shoot.

Currently, the selection and breeding of Myrobalan as rootstock for cherries is the main target of research in some countries (Moreno, 2004Moreno MA (2004) Breeding and selection of Prunus rootstocks at the Aula Dei Experimental Station, Zaragoza, Spain. Acta Hortic 658: 519-528. https://doi.org/10.17660/ActaHortic.2004.658.79; De Salvador et al., 2019De Salvador FR, Fideghelli C, Engel P, Frattarelli A, Caboni E, 2019. Selection of myrobalan rootstocks for sweet cherry. Acta Hortic 1235: 213-218. https://doi.org/10.17660/ActaHortic.2019.1235.28). However, in the present experiment, Myrobalan seedlings caused the smallest tree vigour. The trees of cv. ‘Šumadinka’ on Myrobalan seedlings exhibited visual symptoms such as small, pale or yellow leaves and a large thickening at the graft union, indicating potential graft incompatibility with the ‘Šumadinka’ sour cherry. Consequently, Myrobalan seedling should not be recommended for production practice. On Gisela 6, the trees also displayed low vigour and unexpectedly smaller size compared to those on Gisela 5. These results contradicted the findings of Bujdosó et al. (2004)Bujdosó G, Hrotkó K, Stehr R, 2004. Evaluation of sweet and sour cherry cultivars on German dwarfing rootstocks in Hungary. J Fruit Ornam Plant Res 12: 233-244., who stated that the Gisela 5 rootstock appeared to induce excessive dwarfing. It is possible that Gisela 6 and Krymsk 6 require a longer period of adaptation to shallow, heavy and acidic soils. Similarly, Wociór (2008)Wociór S (2008) The effect of rootstocks on the growth and yielding of sour cherry cv. ‘Łutowka’. Acta Agrobot 61(1): 123-127. https://doi.org/10.5586/aa.2008.016 reported that trees of ‘Łutówka’ sour cherry grafted on Colt rootstock exhibited stronger growth than those on Mazzard seedlings in the first years after planting, despite Colt being considered a less vigorous rootstock. However, on fertile soils with vigorous scion cultivars, a reduction in tree size is often desirable for reduced pruning, thinning and picking costs. Additionally, lower vigour and increased tree density in the orchard allow the possibility of establishing pedestrian orchards leading to reduced labour costs (Jiménez et al., 2007Jiménez S, Pinochet J, Gogorcena Y, Betrán JA, Moreno MA (2007) Influence of different vigor cherry rootstocks on leaves and shoots mineral composition. Sci Hortic 112(1): 73-79. https://doi.org/10.1016/j.scienta.2006.12.010). Agricultural economists have have also demonstrated that it takes eight years to recover the investment for moderately dense planting on Gisela rootstocks, compared to up to 15 years for an orchard with standard trees on Mazzard rootstock.

In the first two bearing years (2018-2019), yields were very low, and there were no significant differences observed among rootstocks (data not shown). However, ‘Šumadinka’ began to produce fruit in the second year after planting, consistent with our earlier findings regarding this cultivar (Milošević, 1997Milošević T, 1997. Special topics in fruit growing. Faculty of Agronomy & Community for Fruits and Vegetables, Čačak-Belgrade, Serbia, pp: 237-255. (in Serbian).). Significant differences among rootstocks became evident in the last cropping year (2020) (Table 1). The highest average yield per tree (Y) on heavy, shallow and acidic soil was induced by the invigorating Adara, the semi-vigorous MaxMa 14 and the dwarfing Gisela 5 rootstocks with no significant differences among them. However, sour cherry trees on Gisela 5 in intensive orchards yielded less than more vigorous clonal rootstocks, as reported by Bujdosó et al. (2004)Bujdosó G, Hrotkó K, Stehr R, 2004. Evaluation of sweet and sour cherry cultivars on German dwarfing rootstocks in Hungary. J Fruit Ornam Plant Res 12: 233-244.. Possible reasons for discrepancias between our results and those of other authors for that rootstock include tree age, training system, cultural practices and site conditions.

Colt, Gisela 6 and the Myrobalan seedlings induced the lowest and statistically similar yields. These rootstocks also promoted the lowest and similar CY for the last two years of the trial, whereas the highest CY was observed with Adara and Gisela 5, respectively. Other authors have also reported that rootstocks significantly affected the yield of sour cherry (Hrotkó et al., 1996Hrotkó K, Nádosy F, Végvári G, Füzesséry A, 1996. Growth and productivity of sour cherry varieties grafted on different Mahaleb rootstocks. Acta Hortic 410: 499-502. https://doi.org/10.17660/ActaHortic.1996.410.81; Bujdosó et al., 2004Bujdosó G, Hrotkó K, Stehr R, 2004. Evaluation of sweet and sour cherry cultivars on German dwarfing rootstocks in Hungary. J Fruit Ornam Plant Res 12: 233-244.; Kopytowski & Markuszewski, 2010Kopytowski J, Markuszewski B (2010) The effect of the rootstock on growth, yielding and fruit quality of three cultivars of sour cherry cultivated in the Warmia region. J Fruit Ornam Plant Res 18(2): 177-184.; Magyar & Hrotkó, 2013Magyar L, Hrotkó K, 2013. The effect of rootstock and spacing on the growth and yield of ‘Kantorjánosi 3’ sour cherry variety in intensive orchard. Acta Hortic 981: 373-378. https://doi.org/10.17660/ActaHortic.2013.981.58). In a study of Anderson et al. (1996)Anderson JL, Lindstrom TE, del Real-Laborde JI, 1996. Rootstock effects on growth and productivity of ‘Montmorency’ sour cherry. Acta Hortic 410: 511-518. https://doi.org/10.17660/ActaHortic.1996.410.84, MaxMa 14 induced the heaviest yield in comparison with other clonal rootstocks, whereas Wocior (2008)Wociór S (2008) The effect of rootstocks on the growth and yielding of sour cherry cv. ‘Łutowka’. Acta Agrobot 61(1): 123-127. https://doi.org/10.5586/aa.2008.016 reported that Colt induced moderate productivity, which partially confirmed our results. Krymsk 6 and Cigančica exhibited an intermediate level of yield per tree. Nevertheless, Long et al. (2019)Long LE, Iezzoni A, Seavert C, Auvil T, Kaiser C, Brewer LJ, 2019. New cherry rootstock and cultivar interactions directly affect orchard profitability. Acta Hortic 1235: 197-206. https://doi.org/10.17660/ActaHortic.2019.1235.26 noted that Krymsk 6 rootstock produced sufficient cherry yields for growers to exceed all costs of production. The low Y and CY values observed with Myrobalan in the current study are likely due to the rootstock’s incompatibility with the cv. ‘Šumadinka’ which significantly restricts its application in the production of sour cherries.

The YE is a complex index that accounts the relationship between production and tree growth. Gisela 5 trees outperformed trees on other rootstocks in terms of YE, with Krymsk 6 trees coming in second (Table 2). Jadczuk et al. (1998)Jadczuk E, Sadowski A, Stepniewska M (1998) Growth and yield of ‘Schattenmorelle’ cherry trees in relation to the type of root system. Acta Hortic 468: 385-392. https://doi.org/10.17660/ActaHortic.1998.468.48 found that smaller sour cherry trees on dwarf rootstocks prompted higher YE compared to more vigorous trees or invigorating rootstocks. The lowest YE were observed in Colt trees, probably due to their low CY and relatively high tree vigour as assessed by TCSA. Similar findings were reported by Bujdosó et al. (2004)Bujdosó G, Hrotkó K, Stehr R, 2004. Evaluation of sweet and sour cherry cultivars on German dwarfing rootstocks in Hungary. J Fruit Ornam Plant Res 12: 233-244. for the same rootstocks.

Leaf and stem properties

Determination of leaf dimensions and its area is an important criterion in understanding various physiological processes such as respiration, transpiration, photosynthesis, light interception, water and nutrient use, flowering, fruit set, crop growth, yield, and fruit quality (Barlow, 1980Barlow HWB, 1980. The relationship between leaf size and shoot length in apple. J Hortic Sci 55(3): 279-283. https://doi.org/10.1080/00221589.1980.11514935; Picchioni & Weinbaum, 1995Picchioni GA, Weinbaum SA (1995) Retention and the kinetics of uptake and export of foliage-applied, labelled boron by apple, pear, prune, and sweet cherry leaves. J Am Soc Hortic Sci 120(1): 28-35. Available at: https://doi.org/10.21273/JASHS.120.1.28.). The trees on Adara, Colt and MaxMa 14 had the largest Ll in this investigation (Table 2). Myrobalan and Gisela 5 induced the lowest values with no significant differences between them. Rootstocks such as MaxMa 14, Colt, Myrobalan, Adara and Cigančica induced the highest and statistically similar leaf width (Lw), whereas the smallest was observed in trees on Krymsk 6. In the study of Pérez-Sánchez et al. (2008)Pérez-Sánchez R, Gómez-Sánchez MA, Morales-Corts R (2008) Agromorphological characterization of traditional Spanish sweet cherry (Prunus avium L.), sour cherry (Prunus cerasus L.) and duke cherry (Prunus × gondouinii Rehd.) cultivars. Span J Agric Res 6(1): 42-55. Available at: https://doi.org/10.5424/sjar/2008061-293., Ll and Lw of sour cherries were between 8.96-11.19 cm and 4.47-6.78 cm respectively, which is consistent with our results.

Regarding LA, significant differences among rootstocks were observed (Table 2). The more vigorous rootstocks such as Colt, MaxMa 14, Adara and Cigančica promoted the highest and statistically similar values, while the semi-dwarf Krymsk 6 induced the lowest LA. These findings align closely with those proposed by Cittadini & Peri (2006)Cittadini ED, Peri L, 2006. Estimation of leaf area in sweet cherry using a non-destructive method. Rev Invest Agropec 35(1): 143-150. who, suggested estimating LA for cherry trees by multiplying the product of Ll and Lw with a coefficient usually between 0.67 and 0.75, i.e. 0.6612. In our previous study on pear (Milošević et al., 2015Milošević T, Milošević N, Mašković P, 2015. Do the rootstocks determine tree growth, productivity and fruit quality of pears, which grow on typical heavy and acidic soil? Erwerbs-Obstbau 57(3): 125-134. https://doi.org/10.1007/s10341-015-0239-5), we also found significant effect of rootstocks on leaf dimensions and LA. As noted by Rouphael et al. (2010)Rouphael Y, Mouneimne AH, Rivera CM, Cardarelli M, Marucci A, Colla G (2010) Allometric models for non-destructive leaf area estimation in grafted and ungrafted watermelon (Citrullus lanatus Thunb.). J Food Agr Environ 8(1): 161-165., it can generally be inferred that leaves of ‘Šumadinka’ on Colt, MaxMa 14, Adara and Cigančica may receive more sunlight and thus be more photosynthetically active, leading to increased carbohydrate production available for enhanced vegetative growth. However, it’s important to consider that fruit trees with higher LA may be more susceptible to pest and disease colonization, and have higher transpiration (Vanneste et al., 2004Vanneste JL, Cornich DA, Spinelli F, Yu J (2004) Colonization of apple and pear leaves by different strains of biological control agents of fire blight. New Zeal Plant Prot 57: 49-53. https://doi.org/10.30843/nzpp.2004.57.6888).

For centuries, stems of cherries have been used in traditional medicine as a diuretic and for the treatment of urinary tract infections, the prevention of cardiovascular diseases, and lowering blood pressure and cholesterol probably due to its wider availability (Švarc-Gajić et al., 2018Švarc-Gajić J, Cerdá V, Clavijo S, Suáres R, Maskovic P, Cvetanovic A, et al., 2018. Bioactive compounds of sweet and sour cherry stems obtained by subcritical water extraction. J Chem Technol Biotechnol 93(6): 1627-1635. https://doi.org/10.1002/jctb.5532). In fruit trees, they represent the connection between fruit and bearing shoots. Fresh fruits for markets are picked with the stalk. As depicted in Table 2, the ANOVA showed that rootstock significantly affected the SL. Adara induced the highest value, whereas the lowest and statistically similar values were produced by Myrobalan and Gisela 6, respectively. To the best of our knowledge, no research has previously examined the impact of rootstock on cherry stems.

According to Vercier (1934)Vercier J (1934) La determination rapide des varieties de fruits, poires-pomes. Librairie Bailliere de Fils, Paris. (in French)., sour cherries can be classified into three groups based on the length of the stalk: short (less than 35 mm), medium-long (35-50 mm) and long (greater than 50 mm). Therefore, it can be stated that ‘Šumadinka’ belongs to the group of cultivars with a short stalk, which is a desirable feature in the trade of fresh fruits. In the studies of Pérez-Sánchez et al. (2008)Pérez-Sánchez R, Gómez-Sánchez MA, Morales-Corts R (2008) Agromorphological characterization of traditional Spanish sweet cherry (Prunus avium L.), sour cherry (Prunus cerasus L.) and duke cherry (Prunus × gondouinii Rehd.) cultivars. Span J Agric Res 6(1): 42-55. Available at: https://doi.org/10.5424/sjar/2008061-293., SL of commercial sour cherries varied between 3.34 and 4.81 cm. Conversely, Radičević et al. (2012)Radičević S, Cerović R, Lukić M, Paunović SA, Jevremović D, Milenković S, Mitrović M (2012) Selections of autochthonous sour cherry (Prunus cerasus L.) in Feketić region. Genetika 44(2): 285-297. https://doi.org/10.2298/GENSR1202285R reported values ranging from 4.26 to 5.01 cm, respectively, for promising genotypes of wild sour cherry populations. From all these studies, it is evident that the scion genotype exerts a strong influence on this trait.

Fruit physical properties

Fruit physical properties evaluated during the last cropping year (2020) were significantly affected by rootstocks (Tables 3 and 4), consistent with findings of previous cherry rootstock studies (Cantín et al., 2010Cantín CM, Pinochet J, Gogorcena Y, Moreno MA, 2010. Growth, yield and fruit quality of ‘Van’ and ‘Stark Hardy Giant’ sweet cherry cultivars as influenced by grafting on different rootstocks. Sci Hortic 123(3): 329-335. https://doi.org/10.1016/j.scienta.2009.09.016; Long et al., 2019Long LE, Iezzoni A, Seavert C, Auvil T, Kaiser C, Brewer LJ, 2019. New cherry rootstock and cultivar interactions directly affect orchard profitability. Acta Hortic 1235: 197-206. https://doi.org/10.17660/ActaHortic.2019.1235.26; Milošević et al., 2020Milošević T, Milošević N, Mladenović J (2020) Combining fruit quality and main antioxidant attributes in the sour cherry: The role of new clonal rootstock. Sci Hortic 265: e109236. Available at: https://doi.org/10.1016/j.scienta.2020.109236). Gisela 6 induced the highest FW of ‘Šumadinka’, followed by Adara and Gisela 5, while Myrobalan resulted in the lowest FW (Table 3), with a reduction of ~33% compared to Gisela 6. Rootstocks such as Cigančica, Colt, MaxMa 14 and Krymsk 6 induced statistically similar FW, suggesting comparable potential to enhance FW under heavy and acidic soil conditions. Higher fruit weight is advantageous from the processing stendpoint, as it reduces solid waste (mainly pits) per ton of processed cherries (Siddiq et al., 2011Siddiq M, Iezzoni A, Khan A, Breen P, Sebolt AM, Dolan KD, et al., 2011. Characterization of new tart cherry (Prunus cerasus L.): selections based on fruit quality, total anthocyanins, and antioxidant capacity. Int J Food Prop 14(2): 471-480. https://doi.org/10.1080/10942910903277697). Generally, FW is influenced by crop load, with a noted relationship between lower yields in some years and higher FW and vice versa (Moreno et al., 2001Moreno MA, Adrada R, Aparicio J, Betrán JA (2001) Performance of ‘Sunburst’ sweet cherry grafted on different rootstocks. J Hortic Sci Biotechnol 76(2): 167-173. https://doi.org/10.1080/14620316.2001.11511345). In addition, Blagojević et al. (2006)Blagojević M, Miletić R, Rakićević M, Mitrović M, Glišić I, Karaklajić-Stajić Ž, 2006. Initial cropping of sour cherry under the dense planting system. Agroznanje 7(4): 5-10. (In Serbian with English abstract). and Nenadović Mratinić et al. (2006)Nenadović Mratinić E, Milatović D, Đurović D (2006) Biological characteristics of sour cherry cultivars in the Danube region of Belgrade. ZborNauč Rad 12(3): 24-29. (in Serbian with English abstract). reported average FW for ‘Šumadinka’ of 7.40 g and 7.57 g, respectively, consistent with our data. Although most sour cherries are processed, a small portion of the ‘morello’ fruit in Europe is sold at a premium on the fresh market. According to Iezzoni (1996)Iezzoni AF, 1996. Sour cherry cultivars: objectives and methods of fruit breeding and characteristics of principal commercial cultivars. In: Cherries: Crop physiology, production and uses; Webster AD, Looney NE (eds.). pp: 113-123. CAB International, Wallingford, UK., fruits weighing 6-8 g are preferred, aligning with the FW observed in our trial.

Significant differences were observed among rootstocks, despite the typically stable and genetically regulated nature of SW in Prunus spp. Stones of ‘Šumadinka’ grafted onto Adara and Gisela 5 showed the highest values, whereas the lowest SW was induced by Krymsk 6. A previous study by Milošević et al. (2014)Milošević T, Milošević N, Milivojević J, Glišić I, Nikolić R, 2014. Experiences with Mazzard and Colt sweet cherry rootstocks in Serbia which are used for high density planting system under heavy and acidic soil conditions. Sci Hortic 176(12): 261-272. https://doi.org/10.1016/j.scienta.2014.07.020 confirmed the rootstock influence on this trait.

The flesh rate (FRa) or fruit flesh percentage represents the edible part of the fruit (mesocarp and skin) in the total FW and is an important parameter for the processing industry due to lower losses of raw material and desirable properties for consumers (Milošević et al., 2014Milošević T, Milošević N, Milivojević J, Glišić I, Nikolić R, 2014. Experiences with Mazzard and Colt sweet cherry rootstocks in Serbia which are used for high density planting system under heavy and acidic soil conditions. Sci Hortic 176(12): 261-272. https://doi.org/10.1016/j.scienta.2014.07.020, 2020Milošević T, Milošević N, Mladenović J (2020) Combining fruit quality and main antioxidant attributes in the sour cherry: The role of new clonal rootstock. Sci Hortic 265: e109236. Available at: https://doi.org/10.1016/j.scienta.2020.109236). Đorović & Živaljević (1980)Đorović V, Živaljević M, 1980. Examination of some pomological features in the cherry cultivars that is being grown in Metohija. Jug Voć 53/54: 15-20. (in Serbian with English abstract). declared that if the percentage of stone in sour cherry is less than 10%, it can be used as a raw material for processing.

In the present trial, trees on Krymsk 6 and Gisela 6 produced the highest and similar FRa, followed by Colt, whereas the lowest value was observed on Myrobalan. One possible explanation is that Krymsk 6 had a smaller SW than Colt, Myrobalan, and Cigančica. Milutinovic et al. (2008)Milutinovic M, Nikolic D, Rakonjac V, Fotiric M (2008) Pomological properties of ‘Oblacinska’ sour cherry clones on different rootstocks. Acta Hortic 795: 209-214. https://doi.org/10.17660/ActaHortic.2008.795.28 also found a significant rootstock influence on the fruit flesh percentage but reported smaller values than those observed in the present study.

Fruit shape and size are determined by fruit dimensions. Trees of ‘Šumadinka’ grafted on Gisela 6, Gisela 5 and Adara were statistically similar with the highest fruit length (L), whereas on Gisela 6 and Adara were similar with the highest fruit width (W) (Table 4). Gisela 6 promoted the highest fruit thickness (T). The lowest values of all three dimensions were produced by Myrobalan. For example, the reduction in T was 14% on Myrobalan compared to Gisela 6. Overall, Gisela 6 was the best rootstock in improving fruit size. In other studies on sour cherries, rootstocks also significantly affected fruit dimensions (Kopytowski & Markuszewski, 2010Kopytowski J, Markuszewski B (2010) The effect of the rootstock on growth, yielding and fruit quality of three cultivars of sour cherry cultivated in the Warmia region. J Fruit Ornam Plant Res 18(2): 177-184.). In our trial, Gisela 6, Gisela 5 and Adara induced fruit diameters >24 mm. This is the minimal accepted limit for the diameter of sweet cherries in Serbia intended for export to the foreign market (Milošević et al., 2014Milošević T, Milošević N, Milivojević J, Glišić I, Nikolić R, 2014. Experiences with Mazzard and Colt sweet cherry rootstocks in Serbia which are used for high density planting system under heavy and acidic soil conditions. Sci Hortic 176(12): 261-272. https://doi.org/10.1016/j.scienta.2014.07.020). Lower average fruit diameter of sour cherry on clonal rootstocks than those obtained in this study was recorded by Bujdosó et al. (2004)Bujdosó G, Hrotkó K, Stehr R, 2004. Evaluation of sweet and sour cherry cultivars on German dwarfing rootstocks in Hungary. J Fruit Ornam Plant Res 12: 233-244. and Milošević et al. (2020)Milošević T, Milošević N, Mladenović J (2020) Combining fruit quality and main antioxidant attributes in the sour cherry: The role of new clonal rootstock. Sci Hortic 265: e109236. Available at: https://doi.org/10.1016/j.scienta.2020.109236 for the same cultivar. Adequate fruit size and fruit equatorial diameter (thickness) is absolutely essential for good commercial cherry market value (Whiting et al., 2005Whiting MD, Lang G, Ophardt D (2005) Rootstock and training system affect sweet cherry growth, yield, and fruit quality. HortScience 40(3): 582-586. https://doi.org/10.21273/HORTSCI.40.3.582). Consumers and retailers prefer ‘morello’ type sour cherries that have large and sweeter fruits with short, green stems (Iezzoni, 1996Iezzoni AF, 1996. Sour cherry cultivars: objectives and methods of fruit breeding and characteristics of principal commercial cultivars. In: Cherries: Crop physiology, production and uses; Webster AD, Looney NE (eds.). pp: 113-123. CAB International, Wallingford, UK.; Schuster, 2019Schuster, M. (2019) Sour cherries for fresh consumption. Acta Hortic 1235: 113-118. https://doi.org/10.17660/ActaHortic.2019.1235.15.).

Knowledge related to the D_g would be valuable in designing the grading process as the R_a relates the W to the L of the fruit, indicating its tendency toward an oblong shape (Mohsenin, 1980Mohsenin, N.N., 1980. Physical properties of plant and animal materials: Structure, physical characteristics and mechanical properties. Gardan and Beach Science Pub. Inc., NY, pp: 51-87.). Data summarized in Table 4 revealed that Gisela 6 and Adara rootstocks induced similar and the highest values of both D_g and R_a. The lowest D_g value was observed in trees on Myrobalan, whereas the lowest and statistically similar R_a was produced by Myrobalan and Cigančica. Pérez-Sánchez et al. (2008)Pérez-Sánchez R, Gómez-Sánchez MA, Morales-Corts R (2008) Agromorphological characterization of traditional Spanish sweet cherry (Prunus avium L.), sour cherry (Prunus cerasus L.) and duke cherry (Prunus × gondouinii Rehd.) cultivars. Span J Agric Res 6(1): 42-55. Available at: https://doi.org/10.5424/sjar/2008061-293. reported that the average D_g of sour cherries evaluated in their study varied between 16.57 mm and 20.49 mm, whereas Milinović et al. (2012)Milinović B, Jelačić T, HalapijaKazija D, Čiček D, Vujević P, 2012. Phenological, pomological and physical characteristics of 13 sour cherry (Prunus cerasus L.) cultivars planted in D. Zelina. Pomol Croat 18(1-4): 53-64. (in Croatian). noted values between 18.37 mm and 22.75 mm. Hence, fruits from trees of ‘Šumadinka’ on Myrobalan and Cigančica rootstocks had more elongated (heart-shaped) fruits compared to other rootstocks. In all the other rootstocks, fruits were oblate in shape and had a relatively uniform shape factor.

Fruit chemical properties

Regarding the SSC, fruits of ‘Šumadinka’ on Krymsk 6 had the highest values, while those on Gisela 5 had the lowest average values (Table 5). Fruits on Cigančica had the highest average TA, while the lowest TA value was found on Colt. In contrast, fruits of ‘Šumadinka’ on Colt had the highest RI mean value, with the lowest value observed for Cigančica. The effect of different rootstocks on SSC, TA and RI in sour cherries has also been found to be significant by other authors (Kopytowski & Markuszewski, 2010Kopytowski J, Markuszewski B (2010) The effect of the rootstock on growth, yielding and fruit quality of three cultivars of sour cherry cultivated in the Warmia region. J Fruit Ornam Plant Res 18(2): 177-184.). However, Milutinovic et al. (2008)Milutinovic M, Nikolic D, Rakonjac V, Fotiric M (2008) Pomological properties of ‘Oblacinska’ sour cherry clones on different rootstocks. Acta Hortic 795: 209-214. https://doi.org/10.17660/ActaHortic.2008.795.28 reported that rootstock did not significantly influence SSC and TA. These discrepancies may be due to the different cultivars and rootstock used, as well as factors such as season, crop load, training system, cultural practices and edapho-climatic conditions (Kopytowski & Markuszewski, 2010Kopytowski J, Markuszewski B (2010) The effect of the rootstock on growth, yielding and fruit quality of three cultivars of sour cherry cultivated in the Warmia region. J Fruit Ornam Plant Res 18(2): 177-184.; Lakatos et al., 2014Lakatos L, Szabó Z, Soltész M, Nyéki J, Dussi MC, Szabó T, Sun Z, 2014. The influence of meteorological variables on sour cherry quality parameters. Acta Hortic 1020: 287-292. https://doi.org/10.17660/ActaHortic.2014.1020.41). The variations in SSC and acidity are commonly observed. Pérez-Sánchez et al. (2008)Pérez-Sánchez R, Gómez-Sánchez MA, Morales-Corts R (2008) Agromorphological characterization of traditional Spanish sweet cherry (Prunus avium L.), sour cherry (Prunus cerasus L.) and duke cherry (Prunus × gondouinii Rehd.) cultivars. Span J Agric Res 6(1): 42-55. Available at: https://doi.org/10.5424/sjar/2008061-293. noted that SSC and TA varied from 15.34 to 17.52 °Brix and 0.62 to 1.37%, respectively, whereas Siddiq et al. (2011)Siddiq M, Iezzoni A, Khan A, Breen P, Sebolt AM, Dolan KD, et al., 2011. Characterization of new tart cherry (Prunus cerasus L.): selections based on fruit quality, total anthocyanins, and antioxidant capacity. Int J Food Prop 14(2): 471-480. https://doi.org/10.1080/10942910903277697 reported values of 13.7 to 20.2 °Brix and 1.13 to 1.41%, respectively. Grafe & Schuster (2014)Grafe C, Schuster M, 2014. Physicochemical characterization of fruit quality traits in a German sour cherry collection. Sci Hortic 180: 24-31. https://doi.org/10.1016/j.scienta.2014.09.047 reported that TA in sour cherry varied from 1.3-3.1 g malic acid per 100 g fresh weight. All these studies indicate that the above compounds mostly depend on the cultivar, rootstock, fruit maturity stage and climatic conditions during fruit ripening. Higher SSC have been shown to provide processing benefits, particularly when making cherry juice concentrate, according to Siddiq et al. (2011)Siddiq M, Iezzoni A, Khan A, Breen P, Sebolt AM, Dolan KD, et al., 2011. Characterization of new tart cherry (Prunus cerasus L.): selections based on fruit quality, total anthocyanins, and antioxidant capacity. Int J Food Prop 14(2): 471-480. https://doi.org/10.1080/10942910903277697. Namely, the cherry juice with a higher soluble solid level as a starting material would save time and energy, resulting in lower processing costs for the cherry concentrate industry. In the present study, the SSC values were much lower compared to other studies, whereas the contents of TA were within the limits of them. The main reason could be that rainy and cold weather was common during the fruit ripening period (data not shown). Otherwise, SSC, TA and RI (SSC/TA ratio) are key factors in determining the consumer’s acceptability in stone fruits, including cherries (Crisosto et al., 2003Crisosto CH, Crisosto GM, Metheney P, 2003. Consumer acceptance of Brooks and Bing cherries is mainly dependent on fruit SSC and visual skin colour. Postharvest Biol Technol 28(1): 159-167. https://doi.org/10.1016/S0925-5214(02)00173-4). These authors also reported that sour cherry is a fruit characterized by exceptionally sour taste with intense overall aroma. In sour cherry fruit sourness is primarily affected by the presence of organic acids, mainly malic acid. In general, consumers usually prefer cherries with higher SSC/TA ratios and visual skin colour. Papp et al. (2010)Papp N, Szilvassy B, Abranko L, Szabo T, Pfeiffer P, Szabo Z et al. (2010) Main quality attributes and antioxidants in Hungarian sour cherries: identification of genotypes with enhanced functional properties. Int J Food Sci Technol 45(2): 395-402. https://doi.org/10.1111/j.1365-2621.2009.02168.x and Wojdyło et al. (2014)Wojdyło A, Nowicka P, Laskowski P, Oszmiański J (2014) Evaluation of sour cherry (Prunus cerasus L.) fruits for their polyphenol content, antioxidant properties, and nutritional components. J Agric Food Chem 62(51): 12332-12345. https://doi.org/10.1021/jf504023z noted that RI in sour cherries varied from 9.6 to 15.8 and/or from 5.8 to 15.3, respectively, which confirms our results. In addition, sour cherries with RI ≥ 11.0 have a balanced flavour and are suitable for fresh consumption, although which this was not case in this study. However, fruit of ‘Šumadinka’ could be recommended for this purpose in certain cases (Milošević, 1997Milošević T, 1997. Special topics in fruit growing. Faculty of Agronomy & Community for Fruits and Vegetables, Čačak-Belgrade, Serbia, pp: 237-255. (in Serbian).).

The data in Table 6 revealed that rootstocks significantly affected the sugar content in fruits of ‘Šumadinka’ sour cherry, which agrees with earlier studies on this fruit type (Milutinovic et al., 2008Milutinovic M, Nikolic D, Rakonjac V, Fotiric M (2008) Pomological properties of ‘Oblacinska’ sour cherry clones on different rootstocks. Acta Hortic 795: 209-214. https://doi.org/10.17660/ActaHortic.2008.795.28; Kopytowski & Markuszewski, 2010Kopytowski J, Markuszewski B (2010) The effect of the rootstock on growth, yielding and fruit quality of three cultivars of sour cherry cultivated in the Warmia region. J Fruit Ornam Plant Res 18(2): 177-184.). The highest IS and TS values were induced by Colt, whereas the lowest values were found with Cigančica. Comparing Cigančica to Colt, the decrease in IS and TS content was 36% and 35%, respectively.

Sweetness in cherry fruit is mainly influenced by IS (glucose and fructose), while sourness is primarily caused by the presence of organic acids (Proietti et al., 2019Proietti S, Moscatello S, Villani F, Mecucci F, Walker RP, Famiani F, Battistelli A (2019) Quality and nutritional compounds of Prunus cerasus L. var. Austera fruit grown in central Italy. HortScience 54(6): 1005-1012. Available at: https://doi.org/10.21273/HORTSCI13960-19).

Krymsk 6 induced the highest SU content in fruits of cv. ‘Šumadinka’, followed by Colt and Myrobalan. Nevertheless, sucrose content in cherries is not as abundant as the fructose and glucose individual soluble sugars. In this trial, MaxMa 14 produced the lowest sucrose content although it did not significantly differ from Adara, Gisela 5 and Gisela 6. In the study of Kopytowski & Markuszewski (2010)Kopytowski J, Markuszewski B (2010) The effect of the rootstock on growth, yielding and fruit quality of three cultivars of sour cherry cultivated in the Warmia region. J Fruit Ornam Plant Res 18(2): 177-184., TS content significantly varied among cultivars and rootstocks ranging from 5.4% in fruits of ‘English Morello’ on Mazzard to 7.6% in ‘Újfehértói Fürtös’ on Mahaleb. Similar tendencies were found by Milutinovic et al. (2008)Milutinovic M, Nikolic D, Rakonjac V, Fotiric M (2008) Pomological properties of ‘Oblacinska’ sour cherry clones on different rootstocks. Acta Hortic 795: 209-214. https://doi.org/10.17660/ActaHortic.2008.795.28 who noted that on the Oblačinska clonal rootstock, TS and IS in fruits of 10 promising clones of ‘Oblačinska’ genotype varied from 6.5% to 10.6% and from 3.7% to 6.0%, respectively. On Mahaleb seedlings those traits ranged from 6.2% to 10.3% and 4.4% to 5.9%, respectively. Our sugar content values were comparable to those obtained by Nenadović Mratinić et al. (2006)Nenadović Mratinić E, Milatović D, Đurović D (2006) Biological characteristics of sour cherry cultivars in the Danube region of Belgrade. ZborNauč Rad 12(3): 24-29. (in Serbian with English abstract). for cv. ‘Šumadinka’ and by Radičević et al. (2012)Radičević S, Cerović R, Lukić M, Paunović SA, Jevremović D, Milenković S, Mitrović M (2012) Selections of autochthonous sour cherry (Prunus cerasus L.) in Feketić region. Genetika 44(2): 285-297. https://doi.org/10.2298/GENSR1202285R for other commercial sour cherries grown under Serbian conditions.

A high and balanced sugar-acid ratio is imposed as an imperative goal in many sour cherry breeding programs around the world. Due to their high acidity and the low sugar content as well as the small fruit size of most cultivated cultivars, sour cherry is mainly used in fruit processing (Schuster, 2019Schuster, M. (2019) Sour cherries for fresh consumption. Acta Hortic 1235: 113-118. https://doi.org/10.17660/ActaHortic.2019.1235.15.). In our trial, SI or sugar/acid ratio was highest in the trees on Colt, followed by Myrobalan and Gisela 6. Consumers acceptance appears to be dependent on the ratio between sugar and acid contents in stone fruits including cherries (Crisosto et al., 2003Crisosto CH, Crisosto GM, Metheney P, 2003. Consumer acceptance of Brooks and Bing cherries is mainly dependent on fruit SSC and visual skin colour. Postharvest Biol Technol 28(1): 159-167. https://doi.org/10.1016/S0925-5214(02)00173-4). Interestingly, Myrobalan was the rootstock that generally produced the poorest agronomical and pomological properties evaluated in this study with the exception of SI value, which may be attributed to lower fruit acid content. Therefore, while some rootstocks may be a good choice for improving certain traits, they may negatively impact others (Hajagos et al., 2012Hajagos A, Spornberger A, Modl P, Vegvari G, 2012. The effect of rootstocks on the development of fruit quality parameters of some sweet cherry (Prunus avium L.) cultivars, ‘Regina’ and ‘Kordia’, during the ripening process. Acta Univ Sapientiae Agr Environ 4: 59-70.).

The lowest SI value was produced by Cigančica due to its low TS content and high acidity. Fruits of ‘Šumadinka’ on this rootstock are more suitable for juice and other processing industries, as acidity is one of the major contributors to the flavour of products (Siddiq et al., 2011Siddiq M, Iezzoni A, Khan A, Breen P, Sebolt AM, Dolan KD, et al., 2011. Characterization of new tart cherry (Prunus cerasus L.): selections based on fruit quality, total anthocyanins, and antioxidant capacity. Int J Food Prop 14(2): 471-480. https://doi.org/10.1080/10942910903277697). In addition, high sugar content and, to a lesser extent, high acid content seem to increase fruit quality as evaluated by consumers (Callahan, 2003Callahan A, 2003. Breeding for fruit quality. Acta Hortic 622: 295-302. https://doi.org/10.17660/ActaHortic.2003.622.27; Crisosto et al., 2003Crisosto CH, Crisosto GM, Metheney P, 2003. Consumer acceptance of Brooks and Bing cherries is mainly dependent on fruit SSC and visual skin colour. Postharvest Biol Technol 28(1): 159-167. https://doi.org/10.1016/S0925-5214(02)00173-4). Otherwise, Radičević et al. (2012)Radičević S, Cerović R, Lukić M, Paunović SA, Jevremović D, Milenković S, Mitrović M (2012) Selections of autochthonous sour cherry (Prunus cerasus L.) in Feketić region. Genetika 44(2): 285-297. https://doi.org/10.2298/GENSR1202285R reported SI values between 10.30 and 14.11, which are much higher than those obtained in our study.

Fruit of sour cherries is a rich source of primary and secondary compounds that possess many biological activities with high health benefits (Ferretti et al., 2010Ferretti G, Bacchetti T, Belleggia A, Neri D, 2010. Cherry antioxidants: from farm to table. Molecules 15(1): 6993-7005. https://doi.org/10.3390/molecules15106993). Among others, total anthocyanins and hydrosoluble (C, B) and liposoluble (A, E and K) vitamins play an important role as constituents of these phytochemicals. In this trial, trees on Cigančica rootstock produced the highest vitamin C content, followed by MaxMa 14 and Krymsk 6 rootstocks. The lowest content of this compound was promoted by Colt rootstock. On Colt, the reduction in vitamin C was 22% less than on Cigančica. Kopytowski & Markuszewski (2010)Kopytowski J, Markuszewski B (2010) The effect of the rootstock on growth, yielding and fruit quality of three cultivars of sour cherry cultivated in the Warmia region. J Fruit Ornam Plant Res 18(2): 177-184. also reported a significant effect of rootstock and cultivar on the vitamin C content in sour cherry. In their study, vitamin C was higher in fruits from trees on F12/1 clonal rootstock compared to Mazzard and Mahaleb seedlings. Our range of values for the vitamin C content was much higher than those obtained by Kopytowski & Markuszewski (2010)Kopytowski J, Markuszewski B (2010) The effect of the rootstock on growth, yielding and fruit quality of three cultivars of sour cherry cultivated in the Warmia region. J Fruit Ornam Plant Res 18(2): 177-184. and Ferretti et al. (2010)Ferretti G, Bacchetti T, Belleggia A, Neri D, 2010. Cherry antioxidants: from farm to table. Molecules 15(1): 6993-7005. https://doi.org/10.3390/molecules15106993 and much smaller than the data found by Wojdyło et al. (2014)Wojdyło A, Nowicka P, Laskowski P, Oszmiański J (2014) Evaluation of sour cherry (Prunus cerasus L.) fruits for their polyphenol content, antioxidant properties, and nutritional components. J Agric Food Chem 62(51): 12332-12345. https://doi.org/10.1021/jf504023z and Borowy et al. (2017)Borowy A, Chrzanowska E, Kapłan M, 2017. Comparison of three sour cherry cultivars grown in central-eastern Poland. Acta Sci Pol Hortoru 17(1): 63-73. https://doi.org/10.24326/asphc.2018.1.6. This variation may be attributed to differences in cultivars,rootstocks, maturity stage, season, cultural practices and environmental conditions (Lakatos et al., 2014Lakatos L, Szabó Z, Soltész M, Nyéki J, Dussi MC, Szabó T, Sun Z, 2014. The influence of meteorological variables on sour cherry quality parameters. Acta Hortic 1020: 287-292. https://doi.org/10.17660/ActaHortic.2014.1020.41; Proietti et al., 2019Proietti S, Moscatello S, Villani F, Mecucci F, Walker RP, Famiani F, Battistelli A (2019) Quality and nutritional compounds of Prunus cerasus L. var. Austera fruit grown in central Italy. HortScience 54(6): 1005-1012. Available at: https://doi.org/10.21273/HORTSCI13960-19).

The results of this study showed that under shallow, heavy and acidic soil growing conditions, trees grafted on the semi-dwarfing Gisela 6 rootstock and the invigorating Myrobalan seedlings tended to exhibit excessive dwarfing and low yields. Trees of ‘Šumadinka’ on Myrobalan were to be too small in size, unhealthy, displaying visual symptoms of graft incompatibility and were consequently not recommended for usage in commercial orchards. Also, tree growth, yield performance and fruit physical properties on Krymsk 6 were found to be unsatisfactory for the fruit industryAs expected, better tree growth was found on the invigorating Adara and the intermediate vigorous MaxMa 14 and Cigančica rootstocks. The best productivity and fruit size were obtained from Adara and the dwarfing Gisela 5 rootstocks. Adara initially selected for cherry growing on heavy, calcareous soils, demonstrated good adaptation to heavy, acidic soils resulting in higher yield, vigour, yield efficiency and good fruit quality. This rootstock also exhibited the best leaf physical traits. While MaxMa 14 and Cigančica rootstocks showed good yield and some fruit quality properties of further examination is needed to fully understand their potential for growers in similar pedo-climatic conditions. However, ‘Šumadinka’ cultivar grafted on Gisela 5 and Gisela 6 exhibited better fruit physical properties but possessed the poorest fruit chemical composition.Additionally, the inconsistent and unstable behaviour of ‘Šumadinka’ grafted on several rootstocks, especially on Gisela 5, Gisela 6 and Colt, requires further examination in future trials to determine the underlying causes and potential solutions.