Plant
Volume 5, Issue 1, January 2017, Pages: 23-30

Survey of Chickpea (Cicer arietinum L) Ascochyta Blight (Ascochyta rabiei Pass.) Disease Status in Production Regions of Ethiopia

Megersa Tadesse1, *, Losenge Turoop1, Chris O. Ojiewo2

1Research Methods Program, Jomo Kenyatta University of Agriculture and Technology, Nairobi, Kenya

2International Crops Research Institute for Semi-Arid Tropics, Addis Ababa, Ethiopia

Email address:

(M. Tadesse)

*Corresponding author

To cite this article:

Megersa Tadesse, Losenge Turoop, Chris O. Ojiewo. Survey of Chickpea (Cicer arietinum L) Ascochyta Blight (Ascochyta rabiei Pass.) Disease Status in Production Regions of Ethiopia. Plant. Vol. 5, No. 1, 2017, pp. 23-30. doi: 10.11648/j.plant.20170501.15

Received: April 27, 2016; Accepted: October 13, 2016; Published: December 2, 2016


Abstract: Chickpea (Cicer arietinum L.) is one of the most important pulse crops in Ethiopia. Earlier reports and field observations have shown that Ascochyta blight caused by Ascochyta rabiei is one of the most devastating diseases of this crop in Ethiopia. Survey was conducted during August 2015 to February 2016 to determine the status of the blight disease in major chickpea the growing area of Ethiopia. A total of 251 on-station and on-farm fields were surveyed. Ascochyta blight was observed in 30 of the 251 fields and incidence ranged from 0 to 45.6 % with mean of < 10%. The highest mean incidence was observed in Ensaro district of Amhara region (46.6%) followed by Lume district of Oromia region (15%). The severity varied from 1 to 7 with mean severity of 1 to 3.2 which was observed in few fields. The low incidence and severity of the disease observed in the 2015/2016 season was associated with the drought conditions occasioned by El nino conditions.

Keywords: Ascochyta Blight, Chickpea, Drought, Prevalence, Incidence, Severity


1. Introduction

Chickpea is legume crop in reducing poverty and hunger, improving human health and nutrition, improving incomes especially to smallholder women farmers and enhancing ecosystem balance. The crop is grown in more than 50 countries and is third in production after dry bean and field pea (FAOSTAT, 2014). Africa accounts for 5% of world's chickpea production, mostly from Ethiopia, Malawi, Tanzania and Kenya in Eastern Africa and Morocco in North Africa. Ethiopia is among the top five world producers of chickpea (FAO, 2014). Ethiopia is the largest producer of chickpea in Africa, accounting for about 60% of the continent’s production in 2014.

Despite its importance in Ethiopia, its productivity (1.9 tons ha-1;CSA, 2015) is still relatively low compared to its potential under well managed production (5 tons ha-1). Although many factors contribute towards low chickpea production, blight disease caused by Ascohcyta rabiei (Pass.) Lab. is one of the major limiting factors. This disease has been reported in Ethiopia as well as in 35 countries across six continents (Pande et al., 2005; Nene et al., 1996).

Ascochyta blight causes death to plant, reduces seed quality and causes yield losses up to 100% (Haware, 1998; Nene et al., 1996; Pande et al., 2005; Pande et al., 2011; Knights and Siddique, 2002; Merzoug et al., 2009; PRRP, 2008 and Chongo et al., 2000). It is usually associated with severe reduction in chickpea yield and quality, especially under cool and wet conditions (Kaiser 1997). Blight disease can infect all above-ground plant parts.

Ascochyta blight problem in Ethiopia has been aggravated by changes in chickpea production and rainfall patterns (Abate et al., 2011). Continuous rainfall and cloudy weather conditions during growing season enhance the development and spread of the disease (Jhorar et al., 1998). The disease occurs at all physiological stages ranging from seedling to maturity (Singh and Sharma, 1998). Other climatic factors such as temperature, relative humidity, wetness duration and windiness favor the occurrence and spread of the disease (Weltzein and Kaak, 1984; Trapero-Casas and Kaiser, 1992; Reddy and Singh, 1990). Therefore, timely measures at all growth stages should be taken to prevent chickpea from Ascochyta blight. Farmers in Ethiopia try to get over it by planting late when the rains have subsided, but end up with the challenge of terminal drought.

Development of effective disease management strategy depends, among others, on the timely detection and precise identification of the pathogen and timely application of the control measures. Survey and identification of plant pathogens is important to understand the association of pathogens with a specific host plant and to map out their geographic distribution (Agrios, 1997). In Ethiopia, despite the importance, the blight disease has not been extensively studied and there is no current quantitative information on the status of blight foliar disease on chickpea production. Therefore, the main objective of this study was to determine chickpea ascochyta blight status in the chickpea production regions of Ethiopia.

Ascochyta blight epidemics are a recurrent phenomenon in Ethiopia (Asrat et al., 2015), indicating that no cultivars are immune to A. rabiei as the pathogen continues to evolve the ability to overcome resistant varieties (Chen et al., 2004). More effort is needed to identify new sources of resistance. Knowledge of genetic variation of pathogen populations is required for successful resistance breeding (Peever et al., 2004). However, recent observations indicate that the disease occurrence is becoming variable over seasons due to changes in precipitation that favour disease development and severe pod infection (Abang and Malhotra, 2008). Considering that even resistant chickpea varieties are susceptible to Ascochyta blight during the reproductive phase, concerted effort is needed to ensure the development of lines that are resistant at all developmental stages of the crop (Abang and Malhotra, 2008).

2. Materials and Methods

Disease Survey and Sampling

Field surveys were conducted between August 2015 to February 2016 during the chickpea growing season in four major regions (Oromia, Ahmara, SPNNP and Tigray) of Ethiopia for the determination of the prevalence, incidence, and severity of chickpea blight disease. Emphasis was put on areas where chickpea is an important crop, or areas known to be hot spots of the disease. Fields sampled were 5 to 10 km a part. A total of 251 fields covering 83 districts were surveyed from both farmers' and experimental fields based on reports received from farmers, local extension agents and collaborative research centers on disease occurence. In each location, crop condition, growth stage, disease symptoms, and aphid populations was recorded on 10 to 20 plants selected at random while walking in a diagonal path. Infected chickpea plant samples (leaves, stems and pods) were placed in labeled plastic bags and were taken to the EIAR laboratory for isolation and further analysis.

Geographic features like latitude, longitude and altitude were recorded from all surveyed areas using handheld Global Positioning System (GPS), to trace back the specific locations and symptoms of blight fungi. Percent of disease prevalence, incidence and severity (1–9 rating scale; 1= No visible symptoms; 2= minute lesions prominent on the apical stems; 3= lesions up to 5‒10 mm in size and slight drooping of apical stems; 4= lesions obvious on all plant parts and clear drooping of apical stems; 5= lesions on all plants parts, defoliation initiated, breaking and drying of branches slight to moderate; 6= lesions as in 5, defoliation, broken, dry branches common, some plants killed; 7= Lesions as in 5, defoliation, broken, dry branches very common, up to 25% of plants killed; 8= symptoms as in 7 but up to 50% of the plants killed; 9= Symptoms as in 7 but up to 100% of the plants killed (Jan and Wiese 1991; Chen and Muehlbauer 2003; Chen et al., 2004; Sharma et al., 2005 and Pande et al., 2011) were recorded for each field. Disease prevalence was determined by ratio of number of locations showing chickpea disease to total number of locations/fields. Field incidence of each field was calculated by totaling the number of plants with symptoms and converting to percent. The severity rating represents an average severity for the plants examined in each field.

Data collected from the survey was coded and checked for consistence and completeness and analyzed using R statistical procedures. Descriptive statistics were used to summarize the data. Analysis was conducted by disaggregating important relevant information by district and region so that comparison could be made.

3. Results and Discussion

Field surveys generate knowledge on the current status of Ascochyta blight disease prevalence, incidence and severity, which forms the basis of priority setting in the integrated disease management. Such knowledge is currently lacking or outdated for chickpea Ascochyta blight pathosystem in Ethiopia and should be updated annually. Ascochyta blight is a serious disease, which is mostly prevalent in cool humid weather conditions. Although the disease is prevalent in Ethiopia, reports on its incidence and severity are scanty. In the present survey, the estimate disease status of four regions were made according to disease prevalence, incidence and severity of chickpea blight.

Disease symptoms were observed early in October in few fields. Hot and dry weather associated with the 2015/2016 El nino arrested disease progress in all regions. Similar results have been reported (Ahmed et al., 2008). Ascochyta blight is epidemic (Ahmed et al., 2005; Chang et al., 2000, 2003) in the surveyed area, and disease prevalence and severity depends on weather conditions, including precipitation (Chang et al., 2000, 2003), particularly relative humidity (Trapero-Casas and Kaiser, 1992). Cloudiness and prolonged wet weather favour rapid development and spread of the disease. The results of this study demonstrate very low distribution of the disease in almost all chickpea growing areas limited by blight-unfavoured weather conditions of this season as compared to observations in earlier seasons. The results obtained in this study are similar to those reported by Chongo et al. (2002), Gurjar et al. (2010), Pande et al. (2012), Nene et al. (2012) and Ali and Ozkan (2015).

Several symptoms were found on chickpea during the surveys, which included lesions, wilt, foliar yellowing and yellow stunt. These symptoms were discernible in the early stages of development but later they became difficult to distinguish. Lesions started occurring at vegetative stages but later it became difficult to distinguish from moisture stress or nutrient deficiency. Ascochyta rabiei attacked the aerial parts of chickpea plant; on leaflets the lesions were either round or elongated, bearing irregularly depressed brown dots surrounded by a brownish red margin. On the green pods, the lesions were circular with dark margins with pycnidia arranged in concentric circles. The infected seeds had the lesions too. Elongated, brown lesions were also observed on the stem and petiole, which bore black dots that girdled the affected portion. Where lesions girdled the stem, the portion above the point of attack rapidly died. Where the main stem was girdled at the collar region, the whole plant died. In the fields where the disease had advanced, patches of diseased plants were prominent in the field and slowly spread, involving the entire field. Symptoms started occurring at vegetative stage and the spread was high at flowering and pod setting stages, varying among few observed fields.

A total of 251 farms from 83 districts were surveyed keeping in view the disease severity, topography and environmental conditions of these areas. Levels of Ascochyta blight varied among crop districts, but the disease was absent in most districts, limiting interpretation of these differences. The prevalence of chickpea ascochyta blight in different areas are given in Table 1 and Figure 1. We note mean disease prevalence for the area surveyed ranged from 0 to 25 %. It is evident from the table that maximum prevalence (25%) was recorded in Debre Brihan area followed by East Shewa (15%). The prevalence of the disease in other surveyed areas varied from 0 to 10%. Most of the chickpea growing areas have not shown disease prevalence and this indicates that the weather condition of this year was not conducive for ascochyta blight development. In Debre Brihan zone, particularly in Ensaro district blight disease was moderately prevalent. The disease was more prevalent during flowering/pod setting stage in surveyed fields (Figure 3.1).

Figure 1. Prevalence of chickpea ascochyta blight disease by growth stages in major chickpea growing regions of Ethiopia (2015).

Most of this blight prevalence at flowering/pod setting was observed in Amhara region followed by Oromia region with <10% (Figure 3.1). From the survey, less disease prevalence was also observed during full podding (<10%) which varied across surveyed areas with the exception of a few fields which had >40% (Figure 3.1). The individual prevalence of chickpea blight in each area is given in Table 1. The 2015/16 growing season was extremely dry throughout most of chickpea growing areas of Ethiopia, resulting in negligible blight disease levels.

The mean disease incidence for area surveyed ranged from 0 to 45.6 % and that of average severity varied from 1 to 3.2. Moderate disease incidence was observed in Debre Brihan (45.6%) area of Amhara region while low disease incidence was observed in East Shewa (15.5%), Wolaita (9.3%), North Shewa (5%), North Wollo (2.5%) and South Wollo (2.1%). Particularly, in Minjar district of North Shewa Zone, the blight disease was observed on research station with high incidence (82%). The maximum disease severity (3.2) was observed in East Shewa zone of Oromia region. No ascochyta blight was observed in the surveyed areas of Oromia region except East Shewa area. Most of the surveyed fields showed very low levels Ascochyta blight severity (mean < 2) (Table 1), likely due to the hot and dry weather condition. Ascochyta blight was not observed in Tigray region during the growing season of 2015/16. In the SNNP region, ascochyta blight symptoms were observed only in one field around November, but the distribution was low. The same situation was reported in Canada (Chongo et al., 2002). Besides the scanty rainfall, the temperature in all areas was relatively high during survey period, thereby limiting the chances of blight occurrence in these areas (Table 2). The individual mean prevalence, incidence and severities of chickpea blight in each areas are given in Table 1.

Table 1. Prevalence, incidence, and severity of Ascochyta blight in major chickpea growing areas of Ethiopia (2015).

Region Zone No. of districts covered No. of fields surveyed Disease Prevalence (%) Disease Incidence (%) Disease Severity (1-9 rating)
Range Mean Range Mean
Oromia East Harage 4 13 0 0 0 1 1
West Harage 3 15 0 0 0 1 1
South West Shewa 9 28 0 0 0 1 1
North Shewa 1 3 0 0 0 1 1
Arsi 2 12 0 0 0 1 1
Bale 3 8 0 0 0 1 1
East shewa 7 39 15 0-84 15.5 1-7 3.2
Amhara South Gonder 5 5 0 0 0 1 1
North Gonder 4 15 0 0 0 1 1
West Gonder 2 9 0 0 0 1 1
East Gonder 2 6 0 0 0 1 1
North Shewa 5 31 10 0-82 5 1-4 1.8
North Wollo 7 9 8 0-15 2.5 1-3 1.6
South Wollo 1 1 5 5-40 2.1 1-3 1.4
Debre Brihan 2 6 25 5-86 45.6 2-5 2.3
SNNP Gurage 3 6 0 0 0 1 1
Silte 1 2 0 0 0 1 1
Hadiya 1 2 0 0 0 1 1
Wolaita 2 8 5 56 9.3 1-6 2.0
Tigray West Tigray 3 4 0 0 0 1 1
Central Axum 3 10 0 0 0 1 1
North West Tigray 5 12 0 0 0 1 1
North Tigray 1 1 0 0 0 1 1
East Tigray 3 3 0 0 0 1 1
South Tigray 3 3 0 0 0 1 1

Drought was widespread in Ethiopia during 2015/16 growing season. Northern and central parts of Ethiopia received lower amounts of rain than other areas and this was not favourable to ascochyta blight development. Although infection started in some fields in some regions, further disease development was arrested due to drought conditions. Most fields that were surveyed between October and December were in Oromia and Amhara Region (Table 1). Even though symptoms of ascochyta blight started at vegetative stages in some fields, severity was generally low in these fields, ranging from 1 to 7 (Table 3.1). Two fields in East Shewa research sites had disease severities up to 9 on the scale used. Majority of fields had no disease. Moderate disease incidence observed in some districts was probably due to cool temperature and relatively high humidity conditions that are suitable for disease development (Pande et al., 2005) and conducive to the development of the sexual stage (Raheem et al., 2008). Debre- Birhan is a highland area with higher altitude (2750 m.a.s.l) and high humidity (65.91%) (Table 2) which favoured development and spread of the pathogen in the area. Most other places were disease-free with generally low disease incidence throughout the country. This was most likely due to hot and dry weather conditions brought by El Nino drought of 2015. No Ascochyta blight infection was detected in 19 of 25 zones in 2015⁄2016. Without anticipation of the 2015/2016 drought, and in the usual bid to avoid the disease, most chickpea farmers planted late which also helped to limit disease occurrence and development. Similar results were reported by Atik et al. (2010); Chongo et al. (2002) and Ahmed et al. (2008) who found low severity in many fields due to drought conditions.

Table 2. Summary table showing location, altitude, latitude, longitude and climatic characteristics of the chickpea growing areas showed blight symptoms 2015/16 crop season.

Zone No of fields Altitude (m) Latitude (N) Longitude (E) Rainfall (mm) Relative humidity (%) Maximum temp (°C) Minimum temp (°C)
East Shewa 12 1763 8.68245 39.13644 74.94 57.37 31.6 5.5
Debre Birhan 6 2750 9.79380 38.91766 67.56 65.91 22.0 1.7
North Shewa 8 1785 8.90808 39.41695 67.57 57.74 20.9 3.4
North Wollo 2 2266 12.6256 39.03724 88.49 59.74 28.3 10.3
South Wollo 1 2316 10.8346 39.81012 55.84 71.97 28.5 9.8
Wolaita 1 1880 7.0400 37.9200 131.39 65.39 29.7 13.4

The survey revealed that disease incidence and severity were low but varied low from locality to locality due to hot and dry weather conditions. Similarly, Ahmed et al. (2008) has also reported existence of blight disease variation among surveyed areas of Alberta which was associated to dry conditions. The observed incidence and severity of the disease in surveyed areas may be associated with the presence of favorable environmental condition. Increase in humidity favors the distribution of the pathogen (Pande et al., 2005).

Climate data on temperature, rainfall and relative humidity were compiled monthly for 2014/15 and 2015/16 growing seasons (Table 3). Weather conditions for both years differed substantially. Mean temperatures of growing seasons was highest in 2015/16. Similarly, rainfall distribution was quite different in both years. Mean relative humidity for 2015/16 was 58.71%, which was 5.52% less than that of 2014/15. Unlike in 2015/16, the cropping season in 2014⁄2015 was more favourable for disease development, and infections were observed on several locations on both cultivated chickpea varieties and wild relatives. Symptoms on chickpea seedlings were reported around mid of September in 2014⁄2015 in central parts of Ethiopia, which was much earlier than in this 2015/16. The widespread occurrence and early appearance of ascochyta blight symptoms in previous year was attributed to cool and wet weather conditions favourable for pathogen spread and infection, to high levels of inoculum in chickpea- production areas, and to planting of infected seed. This finding is in agreement with that of Chang et al. (2003) who found widespread Ascochyta blight on chickpea.

Table 3. Monthly average rainfall, relative humidity, monthly maximum temperature and minimum temperature of 2014/15 and 2015/16 for chickpea growing areas in Ethiopia.

  Aug Sept Oct Nov
Parameter 2014/15 2015/16 2014/15 2015/16 2014/15 2015/16 2014/15 2015/16
Average Rainfall (mm) 257.10 200.34 140.52 119.06 89.95 67.64 36.76 30.67
Average Relative Humidity (%) 73.56 67.90 72.63 67.89 66.03 59.35 63.28 59.67
Maximum Temperature (°C) 28.30 31.00 28.40 29.50 28.40 30.70 29.40 30.00
Minimum Temperature (°C) 2.10 2.90 3.20 5.80 2.20 5.30 2.10 3.30
  Dec Jan Feb Mean
Parameter 2014/15 2015/16 2014/15 2015/16 2014/15 2015/16 2014/15 2015/16
Average Rainfall (mm) 12.88 13.87 6.46 1.96 20.17 4.18 85.6 62.5
Average Relative Humidity (%) 57.44 55.05 57.40 51.75 59.29 49.35 64.2 58.7
Maximum Temperature (°C) 29.30 29.70 29.90 31.00 31.30 32.00 29.2 31.5
Minimum Temperature (°C) 0.10 1.00 2.40 -0.20 4.10 5.20 2.3 3.3

Increasing climate variability with the change in climate is recognized unequivocally. With the changing climate patterns and cropping systems, host, pathogen and favourable environment interactions are leading to diseases epidemics in a range of crops. These three essential components are required simultaneously for a disease to occur. Ascochyta blight is thought to be largely influenced by microclimate of the crop which in turn is influenced by prevailing weather conditions. Climate variability is adding a new dimension to managing plant diseases by altering the equilibrium of host-pathogen interactions resulting in either increased epidemic outbreaks or new pathogens surfacing as threats or less known pathogens causing severe yield losses (Aggarwal, 2003). Climate variability has positive and negative impacts on host-pathogen interactions. However, climatic changes could result changes in diseases/pathogens (Pande and Sharma, 2010).

Associations of disease with El-Nino have been made and indicate the potential for future epidemics if weather patterns become more variable (Checkley et al., 2000; Rodó et al., 2002). Plant pathogens have varying ranges of temperature requirements that affect the various steps in disease infection cycles such as penetration, pathogen survival, dispersal, epidemic development, survival and sexual reproduction. Cooler temperature and wetter conditions are associated with increased incidence on blights in chickpea (Pande et al., 2010; Panagga et al., 2004).

Microclimatic factors such as plant temperature, relative humidity, rainfall, moisture, surface wetness and light interception can affect the sporulation of fungi. Any alteration in these factors would retard AB development. Rainfall and high relative humidity (> 95%) are critical for most epiphytotics, with temperature also playing an important role in development (Shtienberg et al., 2000). When the temperature is favourable and the moisture requirements of a pathogen on a susceptible host are fully met, an epidemic is likely to develop (Jhorar et al., 1998; Pande et al., 2005) which was observed during this survey. Under favorable conditions such as cool and moist weather (>350 mm annual rainfall, 23–25) °C temperature and > 95% relative humidity) the disease may cause 100% yield loss (Hassani, 1981; Nene and Reddy, 1987).

Rainfall has influence on epiphytotic and revealed that high rainfall resulted in high chickpea blight incidence. Ketelaer et al. (1988) reported monthly rainfall of 40 mm were needed before an epidemic of AB occurred. Rain splashing may accelerate the disease spread and keep the leaf surface wet. Increasing leaf wetness periods increase the disease severity (Armstrong et al., 2004). Relative humidity directly influences sporulation by many fungi and has implication for the persistence of wetness. Temperature has important effects on the lifecycle of Ascochyta rabiei, the infection process, and disease development. Ascochyta blight infection and disease development occur in the temperature range of 5 - 30°C, with an ideal temperature of 20°C (Trapero-Casas and Kaiser, 2007). Disease severity increased with increasing temperatures to a maximum of 20°C, then declined sharply at temperatures above 25-30°C. The present finding showed that ascochyta blight occurence in 2014/15 was relatively higher than in 2015/16. The temperature and rainfall variability within the rainfed ecologies is very high, leading to varying intensities of moisture deficit in the country.

4. Conclusion

Chickpea is affected by a host of different pathogens despite its importance as the major pulse crop in Ethiopia. Ascochyta blight disease emerging as a potential threat to chickpea production. Basic information on the occurrences and geographic distribution of blight disease is very important for setting research priorities for further disease management strategies in different agro-ecologies. The distribution and incidence of ascochyta blight disease of chickpea varied in each region, but incidence and severity was generally low. Ethiopian agriculture is mostly rainfed, whereas inter-annual and seasonal rainfall variability is high and droughts are frequent in many parts of the country. High incidence in some locations, such as Debre Birhan and East Shewa are probably due to the presence of effective vectors and environmental conditions favouring their population buildup and movement. Depending on the environmental conditions and the availability of alternate hosts, the deleterious effect of blight can vary from season to season in the same area. There is likelihood that the status of these diseases can change to epidemic levels especially with climate change. A detailed analysis of the climatic factors responsible for absence of this disease needs further investigations. This information on ascochyta blight status will be helpful for growers for planning and administering blight management strategies to reduce the blight populations below their threshold levels.

Acknowledgements

The authors would like to thank staff members of chickpea Breeding Sections of Debre Zeit Agricultural Research Center (DZARC) and International Crop Research Institute for Semi-Arid Tropics (ICRISAT) for their assistance. The financial support provided by Regional University Forum For Capacity Building in Agriculture (RUFORUM) and ICRISAT are also acknowledged.


References

  1. Abang, M. M. & Malhotra, R. (2008).Chickpea and climate change. ICARDA Caravan, Rev Agric Dry Areas 25, 48–50.
  2. Abate, T., Shiferaw, B., Gebeyehu, S., Amsalu, B., Negash, K., Assefa, K., Eshete, M., Aliye, S. & Hagmann J. (2011). A systems and partnership approach to agricultural research and development lessons from Ethiopia. Outlook on Agriculture 40(3), 213-220.
  3. Aggarwal, P. K. (2003). Impact of climate change on Indian agriculture. J. Plant Biology 30(2), 189–198.
  4. Agrios, G. N. (1997). Plant pathology. 4 th ed. Academic Press, San Diego, 635p.
  5. Ahmed, H. U., Chang, K. F., Hwang, S. F. & Howard, R. J. (2005). The occurrence of ascochyta blight on chickpea in southern Alberta in 2004. Can. Plant Dis. Surv. 85, 78-79.
  6. Ahmed, H. U., Chang, K. F., Hwang, S. F. & Howard, R. J. (2008). Survey of ascochyta blight on chickpea in southern Alberta in 2007. Can. Plant Dis. Surv. 85, 107-109.
  7.  Ali Kahraman, & Zuhal Ozkan (2015). Ascochyta Blight of Chickpea, Selcuk Journal of Agriculture and Food Sciences, 29(2), 62-66.
  8. Armstrong-Cho, C., Gossen, B. D. & Chongo, G. (2004). Impact of continuous or interrupted leaf wetness on infection of chickpea by Ascochyta rabiei. Can. J Plant Pathol. 26, 134-141.
  9.  Asrat, Z. E. (2015). Epidemiology and Management Of Ascochyta Blight (Didymella Rabiei) On Chickpea In Centeral Rift Valley, Ethiopia, Master Thesis Submitted to Department of Plant sciences, Haramaya University, Haramaya.
  10. Atik Omar, Michael Baum, Ahmed El-Ahmed, Seid Ahmed, Mathew M. Abang, Mohammad M. Yabrak, Samer Murad, Siham Kabbabeh & Aladdin Hamwieh (2010).Chickpea Ascochyta Blight: Disease Status and Pathogen Mating Type Distribution in Syria,J, Phytopathol 159, 443–449.
  11. Central Statistical Authority (CSA) (2015). Agricultural Sample Survey, 2014/15. Results on Area, Production and Yield of Major Crops by Sector and Season. Statistical bulletin 171. Addis Ababa, Ethiopia.
  12. Chang, K. F., Howard, R. J., Briant, M. A., Burke, D. A. & Clawson, M. (2000). Survey for ascochyta blight and root rot diseases of chickpea in southern Alberta in 1999. Can. Plant Dis. Surv. 80, 83-85.
  13. Chang, K. F., Hwang, S. F., Howard, R. J., Turnbull, G. D. & Blade, S. F. (2003). Occurrence of ascochyta blight and root rot diseases on chickpea in Alberta in 200 and 2002. Can. Plant Dis. Surv. 83, 103-104.
  14. Checkley, W., Epstein, L. D., Gilman, R. H., Figueroa, D. & Cama, R. I. (2000). Effect of El Niño and ambient temperature on hospital admissions for diarrhoeal diseases in Peruvian children. Lancet 355, 442–450.
  15. Chen, W. & Muehlbauer, F. J. (2003).An improved technique for virulence assay of Ascochyta rabiei on chickpea. International Chickpea & Pigeonpea Newsletter 10, 31–33.
  16. Chen, W., Coyne, T. C. J., Peever, T.L. & Muehlbauer, F. J. (2004). Characterization of chickpea differentials for pathogenicity assay of Ascochyta blight and identification of chickpea accessions resistant to Didymella rabiei. Plant Pathol 53, 759–769.
  17. Chen, W., Coyne, T. C. J., Peever, T.L. & Muehlbauer, F. J. (2004). Characterization of chickpea differentials for pathogenicity assay of Ascochyta blight and identification of chickpea accessions resistant to Didymella rabiei. Plant Pathol 53, 759–769.
  18. Chongo, G., Banniza, S. & Warkentin, T. (2002). Occurrence of ascochyta blight and other diseases of chickpea in Saskatchewan in the 2001 drought year. Can. Plant Dis. Surv. 82, 85-88.
  19. Chongo, G., Buchwaldt, L., Anderson, K. & Gossen, B. D. (2000). Saskatchewan chickpea disease survey 1999. Can. Plant. Dis. Surv. 80, 86-87.
  20. FAOSTAT (2014). Food and Agricultural Organization (FAO), Bulletin of Statistics. Crop production. Available at: http://www.faostat.fao.org.
  21. Gurjar, G., Mishra, M., Kotkar, H., Upasani, M., Soni, P., Tamhane, V., Kadoo, N., Giri, A. & Gupta, V., (2010). Major Biotic Stresses of Chickpea and Strategies for their Control. Pests and Pathogens: Management Strategies.BS Publications, ISBN: 978-81-7800-227-9.
  22. Hassani, A. A. (1981). Modalities d'expression de la resistance d'um cultiver de pois chiche (Cicer arietinum L.) a Ascochyta rabiei (Pass.) Lab.University de Rennes I. France. A Ph. D. Thesis.
  23. Haware, M. P. (1998). Diseases of chickpea. In ‘The pathology of food and pasture legumes’. (Eds DJ Allen, JM Lenne) pp. 473–516. (ICARDA, CAB International: Wallingford, UK).
  24. Jan, H. & Wiese, M. V. (1991). Virulence forms of Ascochyta rabiei affecting chickpea in the Palouse. Plant Disease, 75, 904–906.
  25. Jhorar, O. P., Butler, D. R. & Mathuda, S.S. (1998). Effects of leaf wetness duration, relative humidity, light and dark on infection and sporulation by Didymella rabbiei on Chickpea. Plant Pathology, 47, 586-594.
  26. Jhorar, O. P., Mathauda, S. S., Singh, G., Butler, D. R. & Mavis, H. S. (1997). Relationship between climatic variables and Ascochyta blight of chickpea in Punjab (India). Agr. Forest Meteor. 87, 171-7.
  27. Kaiser, W. J. (1997). Inter-and international spread of Ascochyta pathogens of chickpea, faba bean, and lentil. Canadian Journal of Plant Pathology. 19, 215-224.
  28. Ketelare, E., Diekmann. M., & Weltzien, H. C. (1988). International Spread of Ascochyta rabiei in Chickpea seeds: An attempt at prognosis. Int. Chickpea Newsl. 18, 21-23.
  29. Knights, E. J. & Siddique, K. H. (2002). Manifestation of Botrytis cinerea on chickpeas in Australia. In: Workshop Proceedings Integrated Management of Botrytis Grey Mould of Chickpea in Bangladesh and Australia. (Bangladesh Agricultural Research Institute: Joydebpur, Gazipur, Bangladesh) pp. 70–77.
  30. Merzoug, A., Benfreha, F., Taleb, M. & Belabid, L. (2009). Fungal disease of Pea Pisum sativum ) and Chickpea ( Cicer arietinum) in Northwestern Algeria. In Abstracts, 10th Arab Congress of Plant Protection, October 26 - 30, 2009, Beirut, Lebanon.
  31. Nene, Y. L. & Reddy, M. V. (1987). Chickpea diseases and their control. In: The Chickpea (M.C. Saxena, K. B. Singh, Ed.), CAB International, Oxon, UK, 233‒270.
  32. Nene, Y. L., Reddy, M. V., Haware, M. P., Ghanekar, A. M,, Amin, K. S., Pande, S. & Sharma M. (2012). Field Diagnosis of Chickpea Diseases and their Control. Information Bulletin No. 28 (revised). Patancheru, A.P. 502 324, India: International Crops Research Institute for the Semi-Arid Tropics. 60 pp.
  33. Nene, Y. L., Sheila, V. K. & Sharma, S. B. (1996). A world list of chickpea and pigeonpea pathogens, 5th edition, ICRISAT, Patancheru, India. Pg 27.
  34. Pande, S. & Sharma, M. (2010). Climate Change: Potential Impact on Chickpea and Pigeonpea Diseases in the Rainfed Semi-Arid Tropics (SAT). In: 5th International Food Legumes Research Conference (IFLRC V) & 7th European Conference on Grain Legumes (AEP VII) April 26-30, 2010- Antalya, Turkey.
  35. Pande, S., Sharma, M., Gaur, P. M., & Gowda C. L. (2010). Host Plant Resistance to Ascochyta Blight of Chickpea. Information Bulletin No. 82. Patancheru 502 324, Andhra Pradesh, India: International Crops Research Institute for the Semi-Arid Tropics. 40 pp.
  36. Pande, S., Sharma, M., Nagavardhini, A. & Rameshwar, T. (2012). High Throughput Phenotyping of Chickpea Diseases: Stepwise identification of host plant resistance. Information Bulletin No. 92 Patancheru 502 324, Andhra Pradesh, India:International Crops Research Institute for the Semi- Arid Tropics. 56 pp.
  37. Pande, S., Sharma,M., Gaur, P. M., Tripathi, S., Kaur, L., Basandrai, A., Khan., T., Gowda, C. L. & Siddique, K. H. (2011).Development of screening techniques and identification of new sources of resistance to Ascochyta blight disease of chickpea. Australasian Plant Pathology, 40, 149–156.
  38. Pande, S., Siddique, K. H., Kishore, G. K., Bayaa, B., Gaur, P. M., Gowda, C. L., Bretag, T. W. & Crouch, J.H. (2005). Ascochyta blight of chickpea (Cicer arietinum L.): A review of biology, pathogenicity, and disease management. Aust. J. Agric. Res. 56, 317-332.
  39. Pangga, I. B., Chakaraborthy, S. & Yates, D. (2004). Canopy size and induced resistance to Stylosanthes scabra determine anthracnose severity at high CO2. Phytopathology 94, 221-227.
  40. Peever, T. L., Salimath, S. S., Su, G., Kaiser, W. J. & Muehlbauer, J. (2004) Historical and contemporary multilocus population structure of Ascochyta rabiei (teleomorph:Didymella rabiei) in the Pacific Northwest of the United States. Mol Ecol, 13, 291–309.
  41. Pesticide Risk Reduction Program (2008). Pest Management Centre, Canada.
  42. Reddy, M. V. & Singh, K. B. (1990). Relationship between Ascochyta blight severity and yield loss in chickpea and identification of resistant lines. Phytopathol Mediterr 29, 32–38.
  43. Rhaiem, A., Cherif, M., Peever, T. L. and Dyer, P. S. (2008). Population structure and mating system of Ascochyta rabiei in Tunisia: evidence for the recent introduction of mating type 2. Plant Pathol, 57, 540–551.
  44. Rodó, X., Pascual, M., Fuchs, G., & Faruque, A. S. (2002). ENSO and cholera: A nonstationary link related to climate change? Proc Nat Acad Sci USA, 99, 12901– 12906.
  45. Sharma, Y.R., Singh, G. & Kaur, L. (2005). A rapid technique for Ascochyta blight resistance in chickpea. International Chickpea Pigeonpea Newsletter 2, 34–35.
  46. Shtienberg, D., Vintal, H., Brener, S. & Retig, B. (2000). Rational management of Didymella rabiei in chickpea by integration of genotype resistance and post infection application of fungicides. Phytopathology. 90, 834-842.
  47. Singa, G. & Sharma, Y. R. (1998). Ascochoyta blight of chickpea. In: Upadhyay, R.K.Mukerji, K. G. and Rajak, R. L. (eds.), IPM System in agriculture. New Delhi, India. Addity Books(P) Ltd.p.163-195.
  48. Trapero-Casas & Kaiser, W. J. (2007). Differences between ascospores and conidia of Didymella rabiei in spore germination and infection of chickpea. Phytopathology, 97, 1600–1607.
  49. Trapero-Casas, A. & Kaiser, W. J. (1992). Influence of temperature, wetness period, plant age, and inoculums concentration on infection and development of Ascochyta blight of chickpea. Phytopathology 82, 586‒596.
  50. Weltein, H. C. & Kaak, H. J. (1984). Epidemiological aspects of Ascochyta blight in Chickpea. Euphytica 24, 209-211.

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