3. Results and discussion Pathogens

3. Results and discussion Pathogens were isolated from heavily infected jackfruit of seven different locations of Birbhum and Burdwan districts in the month of February (Average day temperature, high 28 C, low 12 C, clear sunny days). Based on light microscopic observations it was found that the isolated pathogens from all of the localities showed more or less similar morphology and were identified as Rhizopus sp. (Fig. 2). When they were cultured on malt agar plates, white, cottony mycelia were observed and on maturation blackish spores were developed from those mycelia. Microscopic observation reveals aseptate vegetative hyphae, bunch (2–5) of sporangiophores from nodes, below which presence of rhizoids and stolons connecting the nodes indicating the isolates as species of Rhizopus. VBAM1, one of the representative strains isolated from a heavily infected young fruit and which was surface sterilized before isolation was selected arbitrarily for further studies. Based on the 28S rDNA sequence homology and phylogenetic analysis (Fig. 3) the isolated pathogen VBAM1 was identified as Rhizopus stolonifer. Consensus sequence of 611 bp of D1/D2 region of 28S rDNA gene was generated from forward and reverse sequence data using aligner software. It has been reported by several workers that several species of Rhizopus viz. R. artocarpi (Roy, 1983) R. oryzae, R. stolonifer, etc. can cause the fruit rot of jackfruit in different parts of the world (Nelson, 2005). Thus the present observation corroborates with the earlier findings. Degradation of pectic components of plant tissue is almost inevitable in rot diseases particularly in fruit and vegetable rots (AlHindi et al., 2011; Monilola and Abiola, 2011; Adisa and Fajola, 1982). The degree of pectinase production is an indicative of pathogenic potential of the isolate for rot pathogens. Prominent zones of clearance were observed on pectin agar plates containing the visual growth of the isolated pathogens when stained with 1% CTAB (Fig. 4), which indicated the utilization of pectin strongly by the strains. During quantification it was found that the amount of reducing sugar increases along with days of incubation in all of the seven pathogenic isolates (Fig. 5). Among the seven different isolates the pathogen VBAM1 can produce a maximum of 611.26 lg/ml of reducing sugar after 5th day of incubation. It was also found that the concentration of protein also increases in culture medium in relation to sugar concentrations (Fig. 5). After 5th day of incubation the protein concentration in case of VBAM1 reached a maximum of 151.86 lg/ml. The increase of the amount of reducing sugar indicates the pectinase enzyme production by the isolated pathogens. The increase of protein concentrations also supports the results. The amount of pectinase produced by the strain is significant enough to be a potent pathogen. During antifungal studies it was found that isolated pathogens can tolerate a high concentration of Mancozeb and Bavistin. No distinct zones of inhibition were found in the culture plates when Mancozeb and Bavistin were used even at higher concentration like 500 lg/ml or more. The copper oxychloride fungicide Blytone was more effective than other two fungicides. Blytone can inhibit the fungal growth at a concentration of 200 lg/ml. Control of R. stolonifer causing fruit rot of stone fruit, using copper oxychloride fungicide was reported (Korsten et al., 1993). It has also been reported that higher concentrations of copper compounds in food, and inhalation or swallowing of the compounds may cause harm in mammalian bodies (EFSA Scientific Report, 2008). Sometimes farmers use overdose of pesticides to get quick and better result
R. Ghosh et al. / Biological Control 83 (2015) 29–36
Fig. 6. Inhibition zones produced against isolated fungal pathogen Rhizopus stolonifer VBAM1 by biocontrol strains viz. Pseudomonas poae VBK1 (A), Burkholderia cenocepacia VBC7 (B), Lactococcus lactis subsp. lactis LABW4 (C), and the Cell free supernatant of Pseudomonas poae VBK1 (D).
Table 2 In vivo application of five biocontrol organisms to prevent rot formation by Rhizopus stolonifer VBAM1. Standard error values are given in the parenthesis considering n = at least 5.
Treatment with biocontrol organisms
Formation of rot in percent (%)
Uninoculated control on plant
Plant inoculated with Bukholderia cenocepacia VBC7 (5 107 CFU/ml)
Plant inoculated with Pseudomonas poae VBK1
Uninoculated control (harvested immature fruit of 15–20 days)
Inoculated harvested immature fruit with Rhizopus stolonifer VBAM1 (104 spores/ml)
Inoculated harvested immature fruit with Rhizopus stolonifer VBAM1 followed by
forgetting the environmental concern. This may worsen the situation. Moreover growing resistance to copper among fungal and bacterial pathogens of plants is also becoming a concern to the scientific community (Kumar et al., 2007; Cervintes and GutierrezCorona, 1994).