PHYSIOLOGICAL AND MOLECULAR CHARACTERIZATION OF Ascochyta rabiei ISOLATES FROM VARIOUS CHICKPEA AREAS ACROSS IKR, IRAQ

Authors

  • Emad M. Al-Maaroof
  • Rezan M. Salih

DOI:

https://doi.org/10.36103/ijas.v53i2.1537

Keywords:

Aschochta blight disease, Cicer arietinum, Physiological races, molecular diagnosis, fungal disease.

Abstract

From 2017 to 2019, 51 A. rabiei isolates were isolated from 259 chickpea fields across IKR. On different media, 32 isolates showed significant differences in morphological characteristics. The isolates were divided into six groups based on colony color, five groups on mycelium color and three groups on pycnidia color. CSMDA was the best media for mycelial growth. AS-28 significantly surpassed all other isolates in colony diameter despite media type. A. rabiei growth varied between 15-35°C, the maximum growth occured at 25°C and ceased at 35°C. The mean conidia and pycnedia dimensions in isolates AS-19 and AS-9 ranged from 20.0*7.5μm and 70.8*47.9μm to 21.8*9.0μm and 140.7*93.6μm in AS-11 and AS-18 respectively. The isolates were classified into four groups and 15 races based on pathogenicity and virulence. Race 1 exhibited high aggressiveness and virulence against all differentials, whereas the other races explored variable virulence spectrum. Sulaimani had the greatest A. rabiei diversity, with nine different races accounting for 60% of population, followed by Erbil with five races (33%). Halabja and Garmian each contribute three and two races, accounting for 20% and 12% of the total. Races 4 and 5 were the most populous and widely spread in IKR. The ITS region was amplified to a541bp band in all A. rabiei isolates. The length of the nucleotide sequences ranged from 481 to 541bp. The ITS sequences of all the isolates were registered at the NCBI Gen Bank under different accession numbers. The phylogenetic tree clearly shows that all the isolates are grouped in one cluster and have a high degree of similarity.

References

Abbo, S., Y. Saranga,, Z. Peleg, Z. Kerem,, S. Lev-Yadun, and A. Gopher. 2009. Reconsidering domestication of legumes versus cereals in the ancient near east. Quart. Rev. Biolog. 84: 29-50.

Ali, S.R., S.M. Iqbal, U. Iqbal, A. Ghafoor, and A. Akram. 2009. Pathogenic diversity in Ascochyta rabiei (PASS.) Lab., of chickpea. Pakistan J. of Botany. 41(1): 413-419

Alnuaimi, A.D., D. Wiesenfeld, N. O’Brien-Simpson, E.C. Reynolds, B. Peng, and M. McCullough. 2014. The development and validation of a rapid genetic method for species identification and genotyping of medically important fungal pathogens using high-resolution melting curve analysis. Mol. Oral. Microbiol. 29(3):117-130

Al-Taae A.K. 2006. Record of new race of Ascochyta rabiei on chickpea in Nineveh province. J. of Al-Rafedian Sci. 17: 27-38

Ambardar, V.K and S.K. Singh. 1996. Identification and elucidation of Ascochyta rabiei isolates of chickpea in Jammu. Indian J. Plant Pathol. 26: 4-8

Atik, O., S. Ahmed, M. Abang, A. Imtiaze, A. Baum, M.Yaprak, and S. Murad. 2013. Pathogenic and genetic diversity of Didymella rabiei affecting chickpea in Syria. Crop Prot. 46 :70-79

Bahr, L., M. María, N. Barolo, M. Tosello and S. López. 2016. Ascochyta blight: isolation, characterization, and development of a rapid method to detect inhibitors of the chickpea fungal pathogen A. rabiei. Fungal Biol., 120(3): 424-432.

Bayraktar, H., F.S. Dolar, and M. Tör. 2007. Determination of genetic diversity within Ascochyta rabiei (Pass.) Labr., the cause of Ascochyta blight of chickpea in Turkey, J Plant Pathol. 89(3): 341‒ 347

Bedi P.S, and S.S. Aujla. 1969. Variability in Phyllosticta rabiei (Pass.) Trot., the incidents of blight disease of gram. Punjab J. of Res. 6: 103-106

Benzohra, I.E., B.S. Bendahmane, M. Labdi, and M.Y. Benkada. 2013. Sources of resistance in chickpea germplasm to three pathotypes of Ascochyta rabiei in Algeria. World App. Sci. J. 21(6): 873-878

Chalupova, J., Raus, M., Sedlářová, M. and Šebela, M. 2014. Identification of fungal microorganisms by MALDI-TOF mass spectrometry. Bio. Ad. 32(1): 230–241.

Chen, W., C.J. Coyne, T.L. Peever and F.J. Muhlbauer. 2004. Characterization of chickpea differentials for pathogenicity assay of Ascochyta blight and identification of chickpea accessions resistant to Didymella rabiei. Plant Pathol. 53(6): 759-769

Chongo, G., B. Gossen, D. Adhikari and S. Rimmer. 2004. Genetic Diversity of Ascochyta rabiei in Canada. Plant Dis. 8(1): 4-10

Desjardins, P. and D. Conklin. 2010. Nano Drop micro volume quantitation of nucleic acids. J. of Vis. Exp. 22 (45): 2565.

Dolar, F.S., and A. Gürcan. 1992. Pathogenic variability and race appearance of Ascochyta rabiei (Pass.) Labr. in Turkey. J. Turk. Phytopathol., 21: 61-65

FAO. 2019. FAOSTAT Statistical Database of the United Nation Food and Agricultural Organization (FAO) statistical division, Rome, Italy

Gharbi S, N. Karkachi, M. Kihal and j. Henni. 2013. Carbon sources and pH effect on pectinolytic activity production by Ascochyta rabiei isolated from chickpea (Cicer arietinum L.) in West Algeria. African J. of Microbiol Res. 7(27): 3483-3488

Gowen S.R, M. Orton, B. Thurley and A. White. 1989. Variation in pathogenicity of Ascochyta rabiei on chickpeas. Tropical Pest Manag. 35(2): 180–6

Grewal, J.S. 1981. Evidence of physiological races in Ascochyta rabiei in chickpea. In: Ascochyta blight and winter sowing of chickpea. Saxena, MC and Singh, KB (eds), CAB, ICARDA, Syria

Imtiyaz, M., M. Abang, S. Ahmed, B. Bayaa and M. Baum. 2011. Pathotype IV, a new and highly virulent pathotype of Didymella rabiei, causing ascochyta blight in chickpea in Syria. Plant Dis. 95(9): 1192-1193

Iqbal, S., A. Ghafoor, N. Ayub and Z.Ahmad. 2004. Pathogenic diversity in Ascochyta rabiei isolates collected from Pakistan. Pakistan J. of Bot. 36: 429–37

Jamil, F.F., I. Haq, N. Sarwar, S. Alam, J. Khan, M. Hanif, I. Khan, M. Sarwar and M. Haq. 2002. Screening of ten advanced chickpea lines for blight and wilt resistance. The Nucleus. 39(1-2): 95-100

Jamil, F.F, M. Sarwar, J. Khan, M. Zahid, S. Yousaf, H. Arshad and I. Haq. 2010. Genotyping with RAPD markers resolves pathotype diversity in the Ascochyta blight and Fusarium wilt pathogens of chickpea in Pakistan. Pakistan J. Bot. 42(2): 1369-1378

Kaur, S. 1995. Phytotoxicity of solanapyrones produced by the fungus Ascochyta rabiei and their possible role in blight of chickpea (Cicer arietinum). Plant Sci. 109(1): 23-29

Kosiada, T. 2012. In vitro growth of some species of Ascochyta Lib. Cent. Eur. J. Biol., 76: 1076-1083

Kottapalli P., P.M. Gaur, S. Katiyar, S. Pande and K. Gali. 2009. Mapping and validation of QTLs for resistance to an Indian isolate of Ascochyta blight pathogen in chickpea. Euphytica. 165(1): 79-88

Madeira F., Y.M. Park and J. Lee. 2019. The EMBL-EBI search and sequence analysis tools APIs in 2019. Nucleic Acids Res. 47(1): W636-W641. DOI:10.1093/nar/gkz 268

Mahiout, D., B.S. Bendahmane, M.Y. Benkada, and M. Rickauer. 2015. Characterization of Ascochyta rabiei (Pss.) Labr. Isolated from diseased chickpea field in six region of Northwestern Algeria. Am.-Euras.J. Agric. Env. Sci. 15(6):1136-1146

Malunga, L.N., S.D. Bar-El, E. Zinal, Z. Berkovich, S. Abbo and R. Reifen. 2014. The potential use of chickpeas in development of infant follow-on formula. Nut. J. 13(8): 1-6

Merga, B. and J. Haji. 2019. Economic importance of chickpea: Production, value, and world trade. Cogent Food and Agr. 5: 1615718.

Mishra, N.K., and B.P. Tripathi. 2015. Effect of culture media on growth, colony character and sporulation of three foliar pathogens of guava. The Bioscan.10(4):1701-1705

Nene, Y.L., and M.V. Reddy. 1987. Chickpea diseases and their control. In ‘The chickpea’. (Eds MK Saxena, KB Singh, C Johansen) pp, 233-270. (CAB International: Oxon, UK).

Ozkilinc, H., O. Frenkel, S. Abbob, R. Eshed, A. Sherman, R. Ophirc and C. Can. 2010. A comparative study of Turkish and Israeli populations of Didymella rabiei, the Ascochyta blight pathogen of chickpea. Plant Pathol. 59(3): 492–503.

Pande, S., K.H Siddique, G.K Kishore, B.M. Bayaa, P.M. Guar, C.L. Gowda and J.H. Crouch. 2005. Ascochyta blight of chickpea: a review of biology, pathogenicity, and disease management. Aus. J. Ag. Res., 56(4): 317-332

Pande, S., P.Guar, M. Sharma, J. Rao, B. Rao and G. Kishore. 2007. Identification of single and multiple disease resistance in desi chickpea genotypes to Ascochyta blight, Botrytis gray mold and Fusarium wilt. Sat e Journal. 3(1):1-4.

Porta-Puglia A, A. Infantino, P. Crino, R. Angelini and G. Venora. 1997. Ascochyta blight of chickpea: present status and prospects. Pakistani J. of Phytopathol. 9: 8-15

Qureshi, S.H. and S.S. Alam. 1984. Pathogenic behavior of Ascochyta rabiei isolates on different cultivars of chickpea in Pakistan. Int. chickpea News.,10: 29-31

Schoch, C.L, K.A. Seifert, S. Huhndorf, V. Robert, J. Spouge and W. Chen. 2012. Nuclear ribosomal internal transcribed spacer (ITS) region as a universal DNA barcode marker for Fungi. Proc Natl Acad Sci USA 109(16): 6241-6246

Ram,S. and P. Mahinder. 1993. Comparative growth and sporulation of Ascochyta rabiei races on different media and temperature. J. Mycol. Pl. Pathol. 23(2):200-203

Reddy, M.V. and S. Kabbabeh. 1985. Pathogenic variability in Ascochyta rabiei (Pass.) Labr. in Syria and Lebanon. Phytopathol. Medit., 24: 265-266

Rhaiem, A., M. Chérif, P. Dyer and T.L. Peever, (2007). Distribution of mating types and genetic diversity of Ascochyta rabiei populations in Tunisia revealed by mating-type specific PCR and random amplified polymorphic DNA (RAPD) markers. J. Phytopathol. 155(10): 596–605

Türkkan, M. and F.S. Dolar. 2009. Determination of pathogenic variability of Didymella rabiei, the agent of ascochyta blight of chickpea in Turkey. Turkish J. Agric. For., 33(6): 585-591

Udupa, S., F. Weigand, M. Saxena, and G. Kahl. 1998. Genotyping with RAPD and microsatellite markers resolves pathotype diversity in the ascochyta blight pathogen of chickpea. Theo. and App. Gen. 97(1): 299-307

Vir S, and J. Grewal. 1974. Physiologic specialization in Ascochyta rabiei the causal organism of gram blight. Indian Phytopathol. 27(3): 355–360

Wang, T., L. Wang, J. Zhang and W. Dong. 2011. A simplified universal genomic DNA extraction protocol suitable for PCR. Genet Mol. Res. 10(1): 519-525

Wiese, K.A., C.A. Bradely, J.S. Pasche, and N.C. Gudmestand. 2009. Resistance to QoI fungicides in Ascochyta rabiei from chickpea in the Northern Great Plains. Plant Dis., 93(5): 528-536.

Downloads

Published

2022-04-29

Issue

Section

Articles

How to Cite

Al-Maaroof, E. M. ., & M. Salih, R. . (2022). PHYSIOLOGICAL AND MOLECULAR CHARACTERIZATION OF Ascochyta rabiei ISOLATES FROM VARIOUS CHICKPEA AREAS ACROSS IKR, IRAQ. IRAQI JOURNAL OF AGRICULTURAL SCIENCES, 53(2), 297-314. https://doi.org/10.36103/ijas.v53i2.1537

Similar Articles

51-60 of 214

You may also start an advanced similarity search for this article.