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Vol. 10 No. 1 (2011)

Articles

EFFECT OF THE KIND OF GROWING MEDIUM AND TRANSPLANT GRAFTING ON THE CHERRY TOMATO YIELDING

Submitted: January 4, 2021
Published: 2011-03-31

Abstract

The most popular and efficient growing medium in soilless crop are rockwool but researches try to introduce as well other growing media to horticultural practice.
Nowadays cherry tomato is a widespread typ grown under greenhouse conditions and grafting can be a resource let to obtain cultivars with a higher fruit yielding. Two tomato cultivars: typical cherry ones as ‘Dasher’ with red skin and ‘Organza‘ with yellow skin were grown in the years 2008–2009. Half of the plants were grafted on the stock of ‘Maxifort ‘.Tomatoes were cultivated on organic media such as coconut fiber slabs, wood fiber slabs and rockwool slabs. Grafting increased yielding of cherry tomato in particular cultivated on coconut fiber and wood fiber slabs. The grafting plants of ‘Dasher’ cultivar produced much more fruit than not grafted ones. The increase of fruit weight as a result of grafting was observed in ‘Organza’ cultivar. Grafted plants of ‘Organza’ had significantly less fruit with BER than not grafted ones. ‘Dasher’ yielded considerably less than ‘Organza’. ‘Dasher’ produced the highest yield at the begining of harvest time. The yielding
of ‘Organza’ was at the same level during the entire harvest time. Early yield of both cultivars was the highest on the wood fibre slabs with grafted plants. The growing media used in the experiment – coconut fiber and wood fiber, proved their suitability in tomato soilless cultivation.

References

Agong S.G., Kingetsu M., Yoshida Y., Yazawa S., Masuda M., 2003. Response of tomato genotypes to induced salt stress. J. Afr. Crop Sci. 11 (2), 133–142.
Ahmedi W., Nawaz M.A., Iqbal M.A., Khan M.M., 2007. Effect of different rootstocks on plant nutrient status and yield in Kinnow mandarin (Citrus reticulata Blanco). Pak. J. Bot. 39, 1779–1786.
Bletsos F.A., 2006. Grafting and calcium cyanamide as alternatives to methyl bromide for greenhouse eggplant production. Scientia Hort. 107, 325–331.
Chen G., Fu X., Lips S.H., Sagi M., 2003. Control of plant growth resides in the shoot, and not in the root, in reciprocal grafts of flacca and wild-type tomato (Lycopersicon esculentum), in the presence and absence of salinity stress. Plant and Soil 256, 205–215.
Cockshull K.E., Graves C.J., Cave C.R.J., 1992. The influence of shading on yield of glasshouse tomatoes. J. Hort. Sci. 67 (1), 11–24.
de Koning A.N.M., 1994. Development and dry matter distribution in glasshouse tomato: a quantitative approach. Ph.D. Dissertation. Wageningen Agricultural University, Wageningen, 240 pp.
Erismann N.D., Machado E.C., Tucci M.L.S., 2008. Photosynthetic limitation by CO2 diffusion in drought stressed orange leaves on three rootstocks, Photosynth. Res., 96, 163–172.
Fernandez-Garcia N., Martinez V., Cerda A., Carvajal M., 2002. Water and nutrient uptake of grafted tomato plants grown under saline conditions. J. Plant Physiol. 159, 899–905.
Gäredal L., Lundegärdh B., 1997. A test system with limited beds for evaluation of growing methods, applied to ecologically cultivated greenhouse tomatoes (Lycopersicon esculentum Mill.) Biol. Agri. and Hort. 14, 291–301.
Gruda, N. and W.H. Schnitzler, 2004. Suitability of wood fiber substrates for production of vegetable transplants. II. The effect of wood fiber substrates and their volume weights on the growth of tomato transplants. Sci. Hortic. 100, 333–340.
He Y., Zhu Z., Yang J., Ni X., Zhu B., 2009. Grafting increases the salt tolerance of tomato by improvement of photosynthesis and enhancement of antioxidant enzymes activity. Env. Exper. Botany 66, 270–278.
Jensen, M.H., 1999. Hydroponic worldwide. Acta Hortic., 481, 819–729.
Johkan M., Mitukuri K., Yamasaki S., Mori G., Oda M., 2009. Causes of defoliation and low surival rate of grafted sweet pepper plants. Scientia Hort. 119, 103–107.
Ke D., Salveit M.E., 1988. Plant hormone interaction and phenolic metabolism in the regulation of russet spotting in iceberg lettuce. Plant Physiol. 88, 1136–1140.
Lee J.M., 1994. Cultivation of grafted vegetables. I. Current status, grafting methods, and benefits. Hortic. Sci. 29, 235–239.
Li Y.L., Stanghellini C., Challa H., 2001. Effect of electrical conductivity and transpiration on production of greenhouse tomato (Lycopersicon esculentum L.). Sci. Hortic. 88, 11–29.
Martinez-Rodriguez M.M., Estan M.T., Moyano E., Garcia-Abellan J.O., Flores F.B., Campos J.F., Al-Azzawi M.J., Flowers T.J., Bolarin M.C., 2008. The effectiveness of grafting to improve salt tolerance in tomato when an ‘excluder’ genotype is used as scion. Env. Exper. Botany 63, 392–401.
Maas E.V., Hoffman G.J., 1997. Crop salt tolerance-current assessment. J. Irrig. Drain. Div. 103, 115–134.
Mitchell J.P., Shennan C., Grattan S.R., May D.M., 1991. Tomato fruit quality under water deficit and salinity. J. Am. Soc. Hortic. Sci. 116, 215–221.
Ruiz D., Martinez V., Cerda A., 1997. Citrus response to salinity, growth and nutrient uptake. Tree Physiol. 17, 141–150.
Santa-Cruz A., Martinez-Rodriguez M.M., Perez-Alfocea F., Romero-Aranda R., Bolarin M.C., 2002. The rootstock effect on the tomato salinity response depends on the shoot genotype. Plant Science, 162, 825–831.
Urrestarazu M., Guillén C., Mazuela P.C., Carrasco G. 2008. Wetting agent effect on physical properties of new and reused rockwool and coconut coir waste. Sci. Hort. 116, 104–108.
Venema J.H., Dijk B.E., Bax J.M., Van Hasselt Ph.R., Elzenga J.T.M., 2008. Grafting tomato (Solanum lycopersicum) onto the rootstock of a high-altitude accession of Solanum habrochaites improves suboptimal-temperature tolerance. Env. Exper. Botany, 63, 359–367.

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