Introduction

JPCD

Journal of Plant Cell Development

2832-5311

Open Access Pub

United States

10.14302/issn.2832-5311.jpcd-22-4182

JPCD-22-4182

research-article

Integrated Management of Sclerotinia Sclerotiorum, An Emerging Fungal Pathogen Causing White Mold Disease

Faruk

Md. Iqbal

1 *

Principal Scientific Officer, Plant Pathology Division, Bangladesh Agricultural Research Institute, Joydebpur, Gazipur-1701, Bangladesh

Corresponding author

Meijie

Luo

Beijing Academy of Agricultural and Forestry Sciences, China

Md. Iqbal Faruk, Principal Scientific Officer, Plant Pathology Division, Bangladesh Agricultural Research Institute,

Joydebpur

, Gazipur-1701, Bangladesh

mifaruk2012@yahoo.com

The authors have declared that no competing interests exist.

06 06 2022

1 2 1 14 06 05 2022 25 05 2022 06 06 2022

2022

Md. Iqbal Faruk

This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

This article is available from http://openaccesspub.org/jpcd/article/1826

Sclerotiniasclerotiorum, the causal agent for white mold (Sclerotinia stem rot), is a devastating fungal pathogen. Currently, Sclerotinia is most commonly managed using the chemical fungicide which can lead to Sclerotinia resistance development, impacting biodiversity and interfering with key ecosystem services. In this regards, field experiments were conducted during 2017-18 planting seasons to evaluate the efficacy of different components viz. sawdust burning, stable bleaching powder, fungal and bacterial bio-control agents, chemical fungicide Rovral 50 WP and integration of different components for the management white mold disease of bush bean, mustard and garden pea in three different locations viz. in the field of Plant Pathology Division, Bangladesh Agricultural Research Institute, Joydebpur, Gazipur, Regional Agricultural Research Station (RARS), Burirhat, Rangpur and RARS, Ishurdi, Pabna, respectively. The results showed that different treatments displayed varying levels of effectiveness against the disease. All the treatments gave satisfactory reduction of white mold disease development and increased plant growth as well as yield of bush bean, mustard and garden pea. Among the treatments, integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + application fungicide Rovral 50 WP is the best treatment which reduced 97.49%, 77.72%, 72.26% white mold disease incidence and 84.61%, 81.14%, 71.01% white mold disease severity of mustard, bush bean and garden pea, respectively and increasing plant growth parameter as well as 52.16%, 27.74%, 36.97% yield of mustard, bush bean and garden pea, respectively. Application of only fungicide Rovral 50 WP also better treatment in reduction of white mold disease incidence and disease severity and increasing plant growth parameter as well as increasing yield of mustard, bush bean and garden pea. Soil amendment with fungal or bacterial bio-control agents also gave satisfactory results in reduction of white mold disease incidence and disease severity and increasing plant growth parameter as well as increasing yield of mustard, bush bean and garden pea. It could be concluded from the obtained results that integration between bio-control agents as a soil treatment and foliar application chemical fungicide might be useful as a good tool for controlling white mold disease caused by S.sclerotiorum and obtained higher yield of bush bean, mustard and garden pea under field condition.

Sclerotinia sclerotiorum¸ white mold bush bean mustard garden pea bio-control agents Rovral

Introduction

The white mold, caused by the fungus Sclerotinia sclerotiorum (Lib.) de Bary, is a disease with worldwide distribution. The S. sclerotiorum is a soil-borne and cosmopolitan plant pathogenic fungus that infects more than 500 cultivated and wild plant species 1 and causes substantial damage to its host under favourable environments. Low temperatures, between 18-23 °C and high humidity conditions, favor the occurrence of the pathogen. However, the use of contaminated and/or infected seeds, continuous crops in monoculture, succession of crops with susceptible species or hosts, mild nocturnal temperatures (below 18ºC), prolonged rains during cultivation, excessive nitrogen fertilization and uncontrolled irrigation water supplied cause white mold to spread, assuming great economic and social importance 234. Plant infection occurs either by myceliogenic germination of sclerotia or by ascospores released from apothecia during carpogenic germination of sclerotia. The myceliogenically germinating sclerotia are the main source of infection on processing tomato crops leading to rotting of aerial parts of the plant in contact with soil 56. The disease can cause disastrous crop failure as disease incidences have been recorded from 60-80% and variable yield losses ranged from traces to 100% in several economically important crops worldwide 7. Due to the abundant production of sclerotia, which allow for the survival of the fungus in the soil for more than 10 years, white-mold is considered a disease of difficult control 8. Currently, Sclerotinia is most commonly managed using the chemical fungicide 910. A sole reliance on chemical fungicides can lead to Sclerotinia resistance development, while also impacting biodiversity and interfering with key ecosystem services 11. As a result, the interest to obtain alternative management options against the disease is to be sought. Recent research has spurred the development of alternatives for chemical fungicides. Soil disinfection through solarization has proven an effective strategy for control of pathogens, such as Sclerotinia1213. Although solarization combined with applications of chemical fungicide yields substantial reductions of S. minor incidence 9, efficacy of such practice depends on local climatic conditions. Biological control of Sclerotinia has also been investigated, with various antagonistic fungi affecting white mould sclerotia both under in vitro as in field conditions 141516. Although successful biological control of Sclerotinia is mainly restricted to greenhouse production systems. Cotes et al. 17 reported that Trichodermakoningiops (Th003) has shown potential for Sclerotinia control. For the particular case of Sclerotinia, a single pest management strategy has not yielded satisfactory control and integrated tactics (combining physical, cultural, chemical or biological control) are urgently needed 18. In this regards Naema et. al. 19 reported that the integration between Billis and compost was the most effective treatment where it reduced effectively the white mold disease incidence and disease severity (88.24 and 92.37%) respectively of tomato. In Bangladesh, S. sclerotiorum becoming as resurged phytopathogen for various crop including vegetables, fruits and field crops especially in cooler part of the country. First S. sclerotiorum was recorded on mustard in 2008 then chili, brinjal and cabbage, country bean in 2011, marigold in 2011, jackfruit in 2012 and lentil in 2014 20. Moreover, high infection was observed on mustard, brinjal, cauliflower, garden pea and bush bean. The number of host range for the pathogen is increasing day by day 2122. There is limited information available on chemical control of white mold disease in Bangladesh. Therefore, the development of disease management especially integrated disease management technologies is urgently needed in Bangladesh. In this regards, the present studies have been design to develop an integrated management technologies against the S. sclerotiorum causing white mold disease.

Materials and Methods

For development an integrated management package of white mold disease, three field experiments were conducted in three different locations viz. in the field of Plant Pathology Division, Bangladesh Agricultural Research Institute, Joydebpur, Gazipur, Regional Agricultural Research Station (RARS), Burirhat, Rangpur and RARS, Ishurdi, Pabna with three different crops viz. bush bean, mustard and garden pea, respectively during Rabi season of 2017-18. The experiments were laid out in a RCB design with three replications. Eight treatments viz. T₁= Saw dust burning of soil, T₂= Stable bleaching powder (20 kg/ha) in soil, T₃= Trichoderma based bio-fungicide in soil, T₄= Bacillus based bio-control agent (BCA) in soil, T₅= Fungicidal spray three times with Rovral 50 WP, T₆= T₁ + T₂+ T₃ + T₄, T₇= T₁ + T₂ + T₃ + T₄ + T₅ and T₈= Control were applied in these experiments. The unit plot size was 3 m x 2.5 m. T. harzianum isolates collected and isolated previously in Plant Pathology Division was multiplied in the mixture of Grasspea and wheat bran with mustard oilcake substrates. The formulated Trichoderma was used to mass multiplication in vermi-compost and it is designated Trichoderma based bio-fungicide. Trichoderma based bio-fungicide was added @ 3 tha^-1 5 days before seed sowing and mixed properly with soil and kept 5 days for Trichoderma establishment in soil. The bacteria Bacillus was formulated in the liquid culture with the concentration of 2.0 × 107 CFU/ml and spraying in soil before seed sowing. Stable bleaching powder was added @20 kgha^-1 5 days before seed sowing and properly mixed with the soil. In case of saw dust burning, 6 cm thick layer of dry saw dust cover with plot soil and burned the soil properly. After burning the ash were mixed with the soil. Foliar application of fungicide Rovral 50 WP was started just after phenotypic symptom initiation of disease in the plant. The fungicide Rovral 50 WP was sprayed @ 2 g/l of water and 3 sprays were done at 10-12 days interval. The varieties BARI Sarisha-14, BARIMotorshuti-3 and BARIJharshim-1 were used. Fertilizers, weeding and irrigation were applied as per recommendation of the crop. The experiment was monitored regularly to observe the onset of Sclerotinia rot disease in the field.

Data Collection and Analysis

Data on different plant growth parameters viz. plant height and plant weight were taken 45-50 days after seed sowing. Data on disease incidence and disease severity data were started at the time of disease appeared and it was continuing until maturity of the crops. Yield data per unit area was also recorded. In case of garden pea, number of pods per plant, weight of pods per plant and pod yield was also recorded.

The disease incidence of white mold disease that caused by S. sclerotiorum was calculated by following formulae:-

Disease incidence= (Number of plant infected per plot/Total number of plant per plot) X100

The disease severity of white mold disease that caused by S. sclerotiorum was assessed using disease scale proposed by Grau et al.23 consisted of three categories: 0 to 3, where; (0= no detectable symptoms, 1= appearance of a 1-2 cm water-soaked lesion on the crown region of the plant, 2= appearance of a 2 cm water-soaked lesion covering the stem base of the plant, 3= plant completely dead)

Disease Severity % = ∑ (a x b) / N x K x 100

Where: a = Number of infected leaves in each category.

b = Numerical value of each category.

N = Total number of examined leaves.

K = The highest degree of infection category.

The percent data were converted into arcsine transformation values before statistical analysis. Data were analyzed statistically by using the MSTATC program. The treatment effects were compared by applying the least significant different (LSD) test at P=0.05 level.

Results and Discussion Integrated Management of White Mold Disease of Mustard

Effects of different treatments against white mold disease caused by soil-borne pathogen S. sclerotiorumof mustard are presented in table 1, table 2 and Figure 1. Significant difference was observed among the treatments. The highest disease incidence 62.56% and disease severity 69.33% was recorded from control and the lowest disease incidence 1.57% and disease severity 10.67% was recorded from integration of sawdust burning + stable bleaching powder + Trichoderma based bio-fungicide + Bacillus based bio-control agent + Rovral 50 WP (T7) treatment which was followed by the application Rovral 50 WP (T5) where the white mold disease incidence 5.91% and disease severity 18.67% (table 1). Other treatment also gave significantly lower white mold disease incidence range from 25.47% to 38.87% and disease severity from 37.33% to 44.00% compared to control but significantly differ from T5 and T7 treatments. Integration of different treatments viz. saw dust burning + soil amendments with Trichoderma based bio-fungicide+ bacillus based bio-control agent + foliar application of fungicide Rovral 50 WP (T7) gave the highest reduction of white mold disease incidence and severity by 97.49% and 84.61%, respectively followed by the foliar application of fungicide Rovral 50 WP where the reduction of disease incidence and severity was 90.55% and 73.07%, respectively. Saw dust burning and soil amendments with Trichoderma based bio-fungicideand bacillus based bio-control agent also gave significant reduction of white mold disease incidence range from 37.88 to 56.63% and disease severity range from 36.54 to 46.16% but less effective than T5 and T7 treatments. Integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + application fungicide Rovral 50 WP gave the highest plant height and plant weight followed by Rovral 50 WP, Trichoderma based bio-fungicide, bacillus based bio-control agent and saw dust burning treatments. The lowest plant height and plant weight was recorded from control (Table 2).

Figure 1. Experimental field view of integrated management of white mold disease of mustard at RARS, Burirhat, Rangpur and white mold disease symptom in control plot and disease free plot in the field

Table 1. Effect of different treatments and its integration against white mold disease incidence and disease severity of mustard

Treatments	Disease incidence (%)	Reduction of disease incidence than control (%)	Disease severity (PDI)	Reduction of disease severity than control (%)
T₁= Sawdust burning	25.47 e(30.31)	59.29	38.67 c(38.44)	44.22
T₂= Stable bleaching powder	38.87 b(38.55)	37.88	44.00 b(41.54)	36.54
T₃= Trichoderma based bio-fungicide	30.95 cd(33.79)	50.53	37.33 c(37.66)	46.16
T₄= Bacillus based bio-control agent	34.10 bc(35.73)	45.49	40.67 bc(39.62)	41.34
T₅= Rovral 50 WP	5.91 f(13.92)	90.55	18.67 d(25.47)	73.07
T₆= T₁ +T₂ +T₃ +T₄	27.13 de(31.37)	56.63	38.67 c(38.44)	44.22
T₇= T₁ +T₂ +T₃ +T₄+ T₅	1.57 g(7.12)	97.49	10.67 e(19.04)	84.61
T₈= Control	62.56 a(52.28)	-	69.33 a(56.38)	-
LSD	3.125	-	2.393	-

Values in a column having same letter did not differ significantly (P=0.05) by LSD; values within the parenthesis is the Arcsin Transformed value.

Table 2. Effect of different treatments and its integration on the plant growth and yield of mustard

Treatments	Plant Height (cm)	Plant weight (gplant^-1)	Yield(kgha^-1)	Yield higher than control (%)
T₁= Sawdust burning	74.00 de	7.20 d	1073.0 c	30.18
T₂= Stable bleaching powder	72.00 e	7.00 d	825.4 d	9.23
T₃= Trichoderma based bio-fungicide	78.93 bc	7.73 c	1178.0 c	36.40
T₄= Bacillus based bio-control agent	75.00 cde	7.27 cd	1086.0 c	31.01
T₅= Rovral 50 WP	82.07 ab	8.27 b	1306.0 b	42.63
T₆= T₁ +T₂ +T₃ +T₄	77.27 cd	7.40 cd	1156.0 c	35.19
T₇= T₁ +T₂ +T₃ +T₄+ T₅	86.20 a	10.73 a	1566.0 a	52.16
T₈= Control	64.27 f	5.60 c	749.2 d	-
LSD	4.142	0.479	120.6	-

Values in a column having same letter did not differ significantly (P=0.05) by LSD.

Regarding the yield of mustard, the highest yield of mustard at 1566 kgha^-1 was obtained from integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agent + application fungicide Rovral 50 WP treatment which was followed by Rovral 50 WP, Trichoderma based bio-fungicide, integration saw dust burning + stable bleaching powder + + Bacillus based bio-control agent, only Bacillus based bio-control agent and saw dust burning treatments where the yield was 1306, 1178, 1156, 1086 and 1073 kgha^-1, respectively (table 2). The lower yield of mustard 749.2 and 825.4 kgha^-1were recorded from the stable bleaching powder and control treatments, respectively. Yield was higher 52.16% compared to control due to integration saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + Rovral 50 WP where as it was 42.63% due to application of Rovral 50 WP. Soil amendment with Trichoderma based bio-fungicide gave 36.40% higher yield compared to control where it was 35.19%, 31.01% and 30.18 % by the integration saw dust burning + stable bleaching powder + Trichoderma based bio-fungicide + Bacillus based bio-control agent, Bacillus based bio-control agent and saw dust burning, respectively compared to control. Soil treatment with stable bleaching power was the least effective treatment in reduction of white mold disease incidence, disease severity and increasing plant growth as well as yield of mustard.

Integrated Management of White Mold Disease of Bush Bean

Effect of different treatments on the incidence and severity of white mold disease and plant growth as well as yield of bush are presented in table 2, Table 3 and Figure 2. Results showed that all the treatments significantly reduced white mold disease incidence, disease severity and increasing plant growth as well as yield of bush bean (Table 3 and Table 4 and Figure 2). The highest disease incidence 11.13% and disease severity 70.67% was recorded in control and the lowest disease incidence 2.48% and disease severity 33.33% was observed in the treatment when integration of different treatments viz. saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + Rovral 50 WP was used which was followed by the fungicidal treatment Rovral 50 WP, integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents, soil amendment with Trichoderma based bio-fungicide and saw dust burning.

Table 3. Effect of different treatments and its integration against white mold disease of bush bean

Treatments	Disease incidence(%)	Reduction of disease incidence than control (%)	Disease severity (PDI)	Reduction of disease severity than control (%)
T₁= Sawdust burning	3.91 c(11.38)	64.87	33.33 c (35.26)	52.84
T₂= Stable bleaching powder	4.08 bc(12.01)	63.34	41.33 b (40.00)	41.52
T₃= Trichoderma based bio-fungicide	3.12 c(11.37)	71.97	32.00 c(34.45)	54.72
T₄= Bacillus based bio-control agent	4.95 b(12.15)	55.53	36.00 bc(36.85)	49.06
T₅= Rovral 50 Wp	3.05 d(10.05)	72.59	18.67 d(25.50)	73.58
T₆= T₁ +T₂ +T₃ +T₄	2.70 de(9.45)	75.74	33.33 c(35.25)	52.84
T₇= T₁ +T₂ +T₃ +T₄+ T₅	2.48 e(9.05)	77.72	13.33 e(21.27)	81.14
T₈= Control	11.13 a(19.46)	-	70.67 a(57.28)	-
LSD	0.7409	-	4.082	-

Values in a column having same letter did not differ significantly (P=0.05) by LSD; values within the parenthesis is the Arcsin Transformed value.

Table 4. Effect of different treatments and its integration on the growth and yield of bush bean

Treatments	Plant Height (cm)	Plant weight (gplant^-1)	Yield (t/ha)	Yield higher than control (%)
T₁= Sawdust burning	15.13 d	9.83 c	14.83 cd	15.85
T₂= Stable bleaching powder	16.07cd	9.43 c	14.22 e	12.24
T₃= Trichoderma based bio-fungicide	17.93 bc	9.67 c	15.65 b	20.25
T₄= Bacillus based bio-control agent	17.23 bcd	9.83 c	14.48 de	13.81
T₅= Rovral 50 WP	19.23 ab	12.17 b	15.68 b	20.41
T₆= T₁ +T₂ +T₃ +T₄	18.03 bc	12.17 b	15.17 c	17.73
T₇= T₁ +T₂ +T₃ +T₄+ T₅	20.93 a	13.67 a	17.27 a	27.74
T₈= Control	12.10 e	7.00 d	12.48 f	-
LSD	2.274	1.212	0.387	-

Values in a column having same letter did not differ significantly (P=0.05) by LSD

Figure 2. Experimental field view of integrated management of white mold disease of bush bean in Plant Pathology Division, BARI, Gazipur and white mold disease symptom in control plot and disease free plot in the field

Integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + Rovral 50 WP gave the highest reduction of disease incidence 77.72% and disease severity 81.14% compared to control. Application of fungicide Rovral 50 WP reduced 75.74% disease incidence and 73.58% disease severity followed by integration saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents, soil amendments with Trichoderma based bio-fungicide and saw dust burning treatments where the reduction of disease incidence 72.59%, 71.97% and 64.87% and disease severity 52.84%, 54.72% and 52.84%, respectively compared to control.

Integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + Rovral 50 WP gave the highest plant height and plant weight followed by the application fungicide Rovral 50 WP, soil amendments with Trichoderma based bio-fungicideand integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agent treatments. Soil and foliar application of different treatments gave appreciable higher yield of bush bean compared to control. The lowest yield of groundnut was recorded under control by 12.48 tha^-1(Table 4). The yield was increased to 14.22-17.27 tha^-1due to application of different treatments. Integration of saw dust burning + stable bleaching powder + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + foliar application fungicide Rovral 50 WP gave the highest yield 17.27 tha^-1 followed by foliar application Rovral 50 WP, soil amendments with Trichoderma based bio-fungicide, integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents and saw dust burning treatments where the yield was 15.68, 15.65, 15.17 and 14.83 tha^-1, respectively. Soil treatment with Bacillus based bio-control agent gave lower yield 14.48 tha^-1 followed by the application of stable bleaching powder where the yield was 14.22 tha^-1 compared to other treatments. The maximum yield increased 27.74% compared to control was obtained by integration of saw dust burning + stable bleaching powder + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + foliar application fungicide Rovral 50 WP followed by foliar application Rovral 50 WP, soil amendments with Trichoderma based bio-fungicide, integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents and saw dust burning treatments where the yield was 20.41%, 20.25%, 17.73% and 15.85%, respectively higher than control (Table 4). The least effective treatment was stable bleaching powderfollowed by soil treatment with Bacillus based bio-control agent where the yield was 13.81% and 12.24%, respectively higher than control..

Integrated Management of White Mold Disease of Garden Pea

Effect of different treatments on the incidence and severity of white mold disease and plant growth as well as yield of bush are presented in Table 4, table 5. Results showed that all the treatments significantly reduced the white mold disease incidence and disease severity as compared to control (Table 4). The incidence (%) and severity (%) of white mold disease of garden pea varied significantly among the treatments. The highest white mold disease incidence 11.43% and disease severity 9.90% was recorded from control treatment. The incidence and severity of white mold disease reduced significantly range from 3.17%-11.43% and 2.87%-6.60%, respectively due to application of different treatments (Table 4). The highest reduction of disease incidence 72.26% and disease severity 71.01% compared to control was obtained by integration of saw dust burning + stable bleaching powder + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + foliar application fungicide Rovral 50 WP followed by foliar application Rovral 50 WP, soil amendments with Trichoderma based bio-fungicide, integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents and saw dust burning treatments where the reduction of disease incidence 71.13%, 63.43%, 50.04% and 49.52% and disease severity 70.00%, 67.68%, 58.79% and 55.85%, respectively. (table 5). All the treatments showed significant effect on yield and yield contributing characters of garden pea except plant height and number of pods per plant (Table 6). The highest weight of pods per plant (16.28) was recorded in T₇ (integration of saw dust burning + stable bleaching powder + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents + foliar application fungicide Rovral 50 WP) which was followed by integration of saw dust burning + soil amendments with Trichoderma based bio-fungicide + bacillus based bio-control agents, foliar application Rovral 50 WP, soil amendments with Trichoderma based bio-fungicide, Bacillus based bio-control agent and saw dust burning treatments. Integration of saw dust burning + stable bleaching powder + Trichoderma based bio-fungicide + bacillus based bio-control agents + Rovral 50 WP, foliar application Rovral 50 WP and soil amendments with Trichoderma based bio-fungicidegave higher yield of garden pea followed by saw dust burning, Bacillus based bio-control agent and integration of saw dust burning + stable bleaching powder + Trichoderma based bio-fungicide + bacillus based bio-control agent treatments. (Figure 3)

Table 5. Effect of different treatments against incidence and severity of white mold disease of garden pea

Treatments	Disease incidence (%)	Reduction of disease incidence than control (%)	Disease severity (PDI)	Reduction of disease severity than control (%)
T₁= Sawdust burning	5.77 c(2.40)	49.52	4.37 c(2.08)	55.85
T₂= Stable bleaching powder	8.36 b(2.89)	26.86	6.60 b(2.57)	33.33
T₃= Trichoderma based bio-fungicide	5.71 c(2.39 )	50.04	4.08 cd(2.02)	58.79
T₄= Bacillus based bio-control agent	7.66 b(2.76 )	32.98	6.55 b(2.55)	33.83
T₅= Rovral 50 WP	3.30 d(1.81)	71.13	2.97 de(1.72)	70.00
T₆= T₁ +T₂ +T₃ +T₄	4.18 d(2.04)	63.43	3.20 cde(1.78)	67.68
T₇= T₁ +T₂ +T₃ +T₄+ T₅	3.17 d(1.78 )	72.26	2.87 e(1.69)	71.01
T₈= Control	11.43 a(3.38)	-	9.90 a(3.14)	-
LSD (p≥0.05)	0.2538		0.2930	-

Values in a column having same letter did not differ significantly (P=0.05) by LSD. Values in the parentheses indicated as square root transform value

Table 6. Effect of different treatments on plant height, yield and yield contributing characters of garden pea

Treatments	Plant height (cm)	No. of pods/ plant	Weight of pods/ Plant (g)	Pod yield (t/ha)	Yield higher than control (%)
T₁= Saw dust burning of soil	59.20	3.46	12.27 bc	6.60 ab	27.42
T₂= Stable bleaching powder (20 kg/ha) in soil	58.93	3.80	11.49 bc	5.72 bc	16.26
T₃=Trichoderma based bio-fungicide in soil	62.80	3.35	13.27 abc	7.14 a	32.91
T₄= Bacillus based biocontrol agent (BCA) in soil	58.93	3.30	12.47 bc	6.44 ab	25.62
T₅= Fungicidal spray three times with Rovral 50 WP	59.80	3.44	13.20 abc	7.37 a	35.01
T₆= T₁ + T₂ + T₃+ T₄	57.40	4.42	14.51 ab	6.42 ab	25.39
T₇= T₁ + T₂+ T₃ + T4 + T₅	58.27	4.53	16.28 a	7.60 a	36.97
T₈= Control	57.07	2.96	10.12 c	4.79 c	-
LSD	NS	NS	2.882	1.236	-

Values in a column having same letter did not differ significantly (P=0.05) by LSD. NS = Not Significant

Figure 3. Experimental field view of integrated management of white mold disease garden pea at RARS, Ishurdi, Pabna and white mold disease symptom in the field

Yield was 36.97% higher compared to control in the integration of saw dust burning + stable bleaching powder + Trichoderma based bio-fungicide + bacillus based bio-control agents + Rovral 50 WP treatment followed by foliar application Rovral 50 WP, soil amendments with Trichoderma based bio-fungicide, Bacillus based bio-control agent, saw dust burning and integration of saw dust burning + stable bleaching powder + Trichoderma based bio-fungicide + bacillus based bio-control agent treatments where the yield was 35.01%, 32.91%, 27.42%, 25.62% and 25.39%, respectively higher than control. The least effective treatment was stable bleaching powder where the yield was 16.26% higher than control (Table 6).

fFrom these study it is observed that integration of bio-control agents as soil application with foliar application of chemical fungicide Rovral 50 WP (Iprodione) is the best treatment for management of white mold disease caused by S. sclerotiorum and increasing plant growth as well as yield of different crops viz. mustard, bush bean and garden pea. Soil treatment with only Trichoderma based bio-fungicide or Bacillus based bio-control agent or foliar application of only chemical fungicide Rovral 50 WP (Iprodione) also better for significant reduction in incidence and severity of white mold disease caused by S. sclerotiorum and increasing plant growth as well as yield of different crops viz. mustard, bush bean and garden pea. Different workers reported the antagonistic activity of the mycoparasitic fungi viz.Coniothyriumminitans, Trichoderma spp., Gliocladiumspp. Sporidesmiumsclerotivorum, Fusarium, Hormodendrum, Mucor, Penicillium, Aspergillus, Stachybotrys, and bacterial bio-control agents viz. Bacillus species, Pseudomonas spp. P. chlororaphisagainst S. sclerotiorum24252627. Simon and John 28 reported that disease caused by S. sclerotiorum was significantly reduced by a combination of bio-control agents and a single application of Iprodione fungicide. They also reported that only bio-control agent or Iprodione fungicide also effective against the disease caused by S. sclerotiorum but differ than integrated approaches. Shivpuri et al. 29 observed that fungicides, carbendazim, thiophenate methyl and phenylpyrrole had completely inhibited the growth of S. sclerotiorumat all tested concentrations in vitro. Eisa et al.30 recorded that under field conditions combining the fungicide Folicur with compost has enhanced the control of white rot of onion and bulb yield compared with using alone. Abdel-Kader et al. 31 found that combination of compost + T. harzianum+ thyme and compost + T. harzianum+ lemon grass reduced the peanut crown rot disease incidence at both pre- and post-emergence growth stages, respectively compared with untreated control. Therefore, it could be concluded from the obtained results that integration between bio-control agents as a soil treatment and foliar application chemical fungicide might be useful as a good tool for controlling white mold disease caused by S.sclerotiorum and obtained higher yield of bush bean, mustard and garden pea under field condition. Foliar application of only fungicide Rovral 50 WP also better treatment in reduction of white mold disease incidence and disease severity and increasing plant growth parameter as well as increasing yield of mustard, bush bean and garden pea. Based on findings of the present investigation these two treatments may be recommended for controlling white mold disease caused by S.sclerotiorum of bush bean, mustard and garden pea under field condition in Bangladesh.

Sharma

D Meena

R Verma

S Saharan

Mehta

Singh

Kumar

de Bary causing sclerotinia rot in Brassicas: a review

2015 J Oilseed Brassica 6 1 44

Leite

R M V B C

Occurrence of diseases caused byScleriotiniasclerotiorumin sunflower and soybean (3). Londrina: Embrapa soybean

2005 Technical Communiqué

C Juliatti

White stem rot of soybean: Management and use of fungicides in search of sustainability in production systems (p. 33)

2010

Composer

Uberlândia:

Silva

L H C P

D Campos

Silva

J R C

Management of soybean white mold. Phytosanitary management of agroenergy crops

2010 205 214

Lavras: UFLA

Gao

Han

Chen

Qin

Huang

Biological control of oilseed rape Sclerotinia stem rot byBacillussubtilisstrain Em7. Biocontrol Sci

2014 Technol 24 39 52

H Purdy

History, diseases, symptomatology, host range, geographic distribution, and impact

1979 Phytopathology 69 875 880

Mehta

Sclerotinia stem rot-an emerging threat in mustard

2009 Plant Dis Res 24 72 73

M Reis

L Tomazini

Viability ofSclerotiniasclerotiorumsclerotia at two depths in soil

2005 Summa Phytopathologica 31 97 99

R Patrício

Sinigagliaa

Tessarioli

Cantarellab

Ghini

Solarization and fungicides for the control of drop, bottom rot and weeds in lettuce

2006

Crop Prot.25:

31 38

10.

R Wilson

de Little

A Wong

J Schupp

J Gibson

Adjustment of soil-surface pH and comparison with conventional fungicide treatments for control of lettuce drop (Sclerotiniaminor). Plant Pathol.54:

2005 393 400

11.

Sorensen

A Stewart

Factors affecting the adoption of new technologies. Emerging technologies for integrated pest management: concepts, research, and implementation

2000

12.

Katan

Physical and cultural methods for the management of soil-borne pathogens

2000 Crop Prot 19 725 731

13.

C Ferraz

Bergamin

Amorim

C Nasser

Viabi-lidade de Sclerotinia sclerotiorumapós a solarização do solo na presença de cobertura monta

2003 Fitopatol. Bras 28 17 26

14.

Jones

Stewart

Selection of mycoparasites of sclerotia ofSclerotiniasclerotiorumisolated from New Zealand soils

2000 New Zeal. J. Crop Hort 28 105 114

15.

Cheng

Jiang

Whipps

Production, survival and efficacy ofConiothyriumminitansconidia produced in shaken liquid culture

2003 FEMS Microbiol. Lett 227 127 131

16.

Rabeendran

J Moot

Stewart

Bio-control of Sclerotinia lettuce drop byConiothyriumminitans andTrichodermahamatum

2006 Biol. Control 39 352 362

17.

M Cotes

A Moreno

F Molano

F Villamizar

Piedrahíta

Prospects for integrated management ofSclerotiniasclerotioruminlettuce. IOBC/wprs

2007 Bulletin 30 6 391 394

18.

V Subbarao

Progress toward integrated management of lettuce drop

1998 Plant Dis 82 1068 1078

19.

Naema

Gomaa

Mahdy

M M

N Fawzy

A Ahmed

Integrated Management of Tomato White Mold Disease Caused bySclerotiniasclerotiorumusing the Combined Treatments of Compost, Chemical Inducers and Fungicides.Middle East

2016 J. Agric. Res 5 4 479 486

20.

D Hossain

Rahman

M M E

Z Rahman

White rot, a new disease of mustard in Bangladesh

2008 Bangladesh J Plant Pathol 24 81 82

21.

K Dey

S Hossain

Walliwallah

Islam

Hoque

Sclerotiniasclerotiorum: An emerging threat for crop production

2008 12

BSPC, BARI, Bangladesh

22.

Rahman

M M E

K Dey

M Hossain

Nonaka

Harada

First report of white mould caused bySclerotiniasclerotiorumon jackfruit

2015 Australasian Plant Disease Notes 10 10

23.

R Grau

L Radke

L Gillespie

Resistance of soybean cultivars toSclerotiniasclerotiorum

1982 Plant Dis 66 506 508

24.

P Budge

S Fenlon

M Whipps

1995 Biol. Control 5 513 522

25.

Bremer

K Hynes

S Erickson

Foliar application of fungal biocontrol agent for the control of white mold of dry bean caused byScle-rotiniasclerotiorum.Bio

2000

Cont.,18:

270 276

26.

D Nelson

Christianson

McClean

Ef-fects of bacteria on sclerotia ofSclerotiniasclerotiorum. In:

2001

The XIth International Sclerotinia Workshop, Central Science Laboratory

York, UK

27.

Savchuk

Fernando

W G D

Effect of timing of application and population dynamics on the degree of biological control ofSclerotiniasclerotiorumby bacte-rial antagonists.FEMS Micro

2004

Eco.49:

379 388

28.

B Simon

W John

Potential for Integrated Control ofSclerotiniasclerotiorumin Glasshouse Lettuce UsingConiothyriumminitansand Reduced Fungicide Application

2001 Phytopathology 91 2 221 227

29.

Shivapuri

K Bhargava

P Chippa

a new threat to mustard cultivation in Rajasthan, In:

2001

Proceeding ofSclerotinia2001, the XI InternationalSclerotiniaWorkshop. Central Science Laboratory

177 178

York, England

30.

Mahdy

H A M M

Effect of different types of compost in combination with some biological agents and folicur fungicide on onion white rot disease

2013 Journal of Applied Sciences Research 9 4 2803 2810

31.

Abdel-Kader

M M

Abdel-Kareem

S El-Mougy

S El-Mohamady

Integration between compost,Trichodermaharzianumand essential oils for controlling Peanut crown rot under field conditions

2013 Journal of Mycology 1 7