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HS Chaube, US Singh (1991)
Plant disease management principles and practices
T Taira, N Toma, M Ichi, M Takeuchi, M Ishihara (2005)
Tissue distribution, synthesis stage and ethylene induction of pineapple (Ananas comosus) chitinaseBiosci Biotechnol Biochem, 69
MK Hassan, DE Irving, EK Dann, LM Coates, PJ Hofman (2009)
Sap properties and alk(en)ylresorcinol concentrations in Australian-grown mangoesAnn Appl Biol, 154
X Zou, H Nonogaki, GE Welbaum (2002)
A gel diffusion assay for visualization and quantification of chitinase activityMol Biotechnol, 22
MK Hassan, EK Dann, DE Irving, LM Coates (2007)
Concentrations of constitutive alk(en)ylresorcinols in peel of commercial mango varieties and resistance to postharvest anthracnosePhysiol Mol Plant Pathol, 71
G Johnson, T Cooke, AJ Mead (1992)
Infection and quiescence of mango stem-end rot pathogensActa Horticult, 341
PM Halos, GG Divinagracia (1970)
Histopathology of mango fruits infected by Diplodia natalensisPhilipp Phytopathol, 6
CL Karunanayake, NKB Adikaram, BMM Kumarihamy, BM Ratnayake Bandara, C Abayasekara (2011)
Role of antifungal gallotannins, resorcinols and chitinases in the constitutive defence of immature mango (Mangifera indica L.) against Colletotrichum gloeosporioidesJ Phytopathol, 159
WL Klarman, JB Stanford (1968)
Isolation and purification of an antifungal principle from infected soybeansLife Sci, 7
S Sangchote (1988)
Botryodiplodia stem-end rot of mango and its controlKasetsart J, 22
G Corkidi, KA Balderas-Ruíz, B Taboada, L Serrano-Carreón, E Galindo (2006)
Assessing mango anthracnose using a new three-dimensional image-analysis technique to quantify lesions on fruitPlant Pathol, 55
JC Dodd, D Prusky, P Jeffries (1997)
The mango: Botany, production and uses
DM Joel (1981)
The duct system of the base and stalk of the mango fruitBot Gaz, 142
S Droby, D Prusky, B Jacoby, A Goldman (1986)
The presence of an antifungal compound and its relation to the latency of Alternaria alternata in unripe peels of mango fruitsPhysiol Mol Plant Pathol, 29
D Prusky, NT Keen (1993)
Involvement of antifungal compounds in the resistance of subtropical fruits to fungal decayPlant Dis, 77
GD Sinniah, NKB Adikaram, CL Abayasekara (2013)
Differential defence responses expressed in mango (Mangifera indica L.) cultivars resistant and susceptible to Colletotrichum gloeosporioidesIndian Phytopathol, 66
RD Hitzell (1979)
Colletotrichum acutatum as a cause of anthracnose of mango in New South WalesPlant Dis Rep, 63
DM Joel (1980)
Resin ducts in the mango fruit: a defence systemJ Exp Bot, 31
MJ Gosbee, GI Johnson, DC Joyce (1996)
Infection pathway of the stem end rot fungus Dothiorella dominicana in ‘Kensington’ mango fruitActa Horticult, 455
M Cojocaru, S Droby, E Glotter, A Goldman, H Glottlieb, B Jacoby, D Prusky (1986)
5-(12-heptadecenyl)-resorcinol, the major component of the antifungal agent from the peel of mango fruitPhytochemistry, 25
BR Loveys, SP Robinson, JJ Brophy, EK Chacko (1992)
Mango Sapburn: components of fruit sap and their role in causing skin damageAust J Plant Physiol, 19
PS Negi, KS John, U Rao (2002)
Antimicrobial activity of mango sapEur Food Res Technol, 214
The study investigated the possible role of the three classes of constitutive antifungal substances in mangoes in the differential cultivar resistance to anthracnose and stem-end rot (SER). Fruits of eleven mango cultivars were screened for anthracnose and SER development during ripening. Basal level of antifungal activity due to constitutive gallotannins, resorcinols and chitinase in the fruit peel/latex was determined in six of these cultivars. The results showed a clear variability in the resistance of fruits to anthracnose and SER among cultivars. The cultivars, ‘Gira’ and ‘Karutha Colomban’, were among the most resistant to anthracnose disease but were susceptible to SER. Gallotannin activity was high in unripe and ripe fruit peel of all except ‘Willard’, the cultivar most susceptible to anthracnose but resistant to SER. There was a significant negative correlation between the level of gallotannins in the fruit at ripe stage and anthracnose development among six cultivars tested. ‘Gira’ and ‘Karutha Colomban’ that are among the most resistant cultivars to anthracnose showed higher levels of total resorcinols in the latex and 5-(12-cis-heptadecenyl)resorcinol in the unripe fruit peel. Chitinase activity was highest in ‘Rata’ and ‘Kohu’ that are resistant to SER and lowest in cultivars ‘Gira’ and ‘Karutha Colomban’ that are susceptible to SER. The results suggest that mainly the gallotannins and also 5-(12-cis-heptadecenyl)resorcinol contribute to the cultivar resistance of mango fruit to anthracnose pathogen, Colletotrichum gloeosporioides, while chitinases appear to contribute more to the fruit resistance to the SER pathogen, Botryodiplodia theobromae.
Australasian Plant Pathology – Springer Journals
Published: Oct 27, 2013
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