FAO, 2017. Statistics of Food and Agriculture Organization of the United Nations.
Hanson P, Lu SF, Wang JF, Chen W, Kenyon L, Tan CW, Tee KL, Wang YY, Hsu YC, Schafleitner
R, Ledesma D (2016) Conventional and molecular marker-assisted selection and pyramiding
of genes for multiple disease resistance in tomato. Sci Hortic 201:346–354.
Oerke EC (2006). Crop losses to pests. The Journal of Agricultural Science, 144(1),
31-43.
Picó B, Díez MJ, Nuez F (1996). Viral diseases causing the greatest economic losses
to the tomato crop. II. The tomato yellow leaf curl virus—a review. Scientia Horticulturae,
67(3-4), 151-196.
Czosnek H, Laterrot H (1997) A worldwide survey of tomato yellow leaf curl viruses.
Arch. Virol. 142, 1391–1406 pp.
Polston JE, Anderson PK (1997). The emergence of whitefly-transmitted geminiviruses
in tomato in the western hemisphere. Plant disease, 81(12), 1358-1369.
Zamir D, Ekstein-Michelson I, Zakay Y (1994). Mapping and introgression of a tomato
yellow leaf curl virus tolerance gene, Ty-1, Theoretical and Applied Genetics, vol. 88, no. 2, 141-146 pp.
Ghanim, M. and Czosnek, H., 2000, Tomato yellow leaf curl geminivirus (TYLCV-Is) is
transmitted among whiteflies (Bemisia tabaci) in a sex-related manner, J Virol, 74:4738–4745
pp.
Hassan AA, Wafi MS, Quronfilah NE, Obaji UA, Al-Rayis MA, Al-Izabi F (1991) Screening
for tomato yellow leaf curl virus resistance in wild and domestic Lycopersicon accessions.
Tomato Genet Coop Rep, 41, 19-21.
Scott JM (2007). Breeding for resistance to viral pathogens. Genetic improvement of
solanaceous crops, 2, 457-485.
Ji Y, Schuster DJ, Scott JW (2007). Ty-3, a begomovirus resistance locus near the
Tomato yellow leaf curl virus resistance locus Ty-1 on chromosome 6 of tomato. Molecular
Breeding, 20(3), 271-284.
Cho JJ, Custer DM, Brommonschenkel SH, Tanksley SD (1995) Conventional breeding: host-plant
resistance and the use of molecular markers to develop resistance to tomato spot wilt
virus in vegetables.Tospoviruses and Thrips of Floral and Vegetable Crops 431, 367-378.
Mutlu N, Demirelli A, Ilbi H, Ikten C (2015). Development of co-dominant SCAR markers
linked to resistant gene against the Fusarium oxysporum f. sp. radicis-lycopersici.
Theoretical and applied genetics, 128(9), 1791-1798.
Foolad MR (2007) Genome mapping and molecular breeding of tomato. International journal
of plant genomics, 2007.
Consuegra OG, Gómez MP, Zubiaur YM (2015) Pyramiding TYLCV and TSWV resistance genes
in tomato genotypes, Protección Veg., Vol. 30 n. 2: 161-164 pp.
Gómez O, Piñón M, Martínez Y, Quiñones M, Fonseca D, Laterrot H (2004) Breeding for
resistance to begomovirus in tropic-adapted tomato genotypes, Plant Breeding, 123:
275-279 pp.
Mejía L, Teni RE, Vidavski F, Czosnek H, Lapidot M, Nakhla MK, Maxwell DP (2005) Evaluation
of tomato germplasm and selection of breeding lines for resistance to begomoviruses
in Guatemala, Acta Horticulturae, 695:251-255 pp.
Rani IC, Veeraragavathatham D, Sanjutha S (2008) Studies on correlation and path coefficient
analysis on yield attributes in root knot nematode resistant F1 hybrids of tomato,
Journal of Applied Sciences Research, 4(3): 287-295 pp.
De Castro AP, Blanca JM, Díez MJ, Viñals FN (2007) Identification of a CAPS marker
tightly linked to the tomato yellow leaf curl disease resistance gene Ty-1 in tomato,
Eur. J. Plant Pathol, 117:347-356. pp.
Verlaan MG, Hutton SF, Ibrahem RM, Kormelink R, Visser RG, Scott JW, Edwards JD, Bai
Y (2013). The tomato yellow leaf curl virus resistance genes Ty-1 and Ty-3 are allelic
and code for DFDGD-class RNA–dependent RNA polymerases, PLoS Genet, 9(3):e100339.
Jensen KS, Van Betteray B, Smeets J, Yuanfu J, Scott JW, Mejia L, Havey MJ and Maxwell
DP (2007). Co dominant SCAR Marker, P6-25, for Detection of the ty-3, Ty-3, and Ty-3a
alleles at 25 cM o f Chromosome 6 of Tomato. www.plantpath.wisc.edu.
Balliu, A. and Hallidri, M., 2002, Combining ability test between some tomato genotypes,
Acta Hort. (ISHS), 579:123-126 pp.
Padidam, M., Beachy, R. N., Fauquet, C. M. (1995). Tomato leaf curl geminivirus from
India has a bipartite genome and coat protein is not essential for infectivity. Journal
of General Virology, 76(1), 25-35.
Doganlar, S., Frary, A., Daunay, M. C., Lester, R. N., Tanksley, S. D. (2002). A comparative
genetic linkage map of eggplant (Solanum melongena) and its implications for genome
evolution in the Solanaceae. Genetics, 161(4), 1697-1711.
Grandillo, S., Ku, H. M., Tanksley, S. D. (1999). Identifying the loci responsible
for natural variation in fruit size and shape in tomato. Theoretical and Applied Genetics,
99(6), 978-987.
Chen, F.Q., Foolad, M.R., Hyman, J., Clair, D.A. and Beeleman, R.B., 1999, Mapping
QTLs for lycopene and other fruit traits in a Lycopersicon esculentum x L pimpinellifolium cross and comparison of QTLs across tomato species, Mol Breeding, 5: 283-299 pp.
Tanksley, S.D (2004). The genetic developmental and molecular bases of fruit size
and shape variation in tomato, The Plant Cell, 16: 181-189 pp.
Doyle JJ, Doyle J (1987) A rapid DNA isolation procedure from small quantities of
fresh leaf tissues, Phytochem Bull., 19, 11-15 pp.
Zeidan M, Czosnek H (1991). Acquisition of tomato yellow leaf curl virus by the whitefly
Bemisia tabaci. Journal of General.
Scott JW, Schuster DJ (1991). Screening of accessions for resistance to the Florida
tomato geminivirus; TGC Report 41.