Forty seven chilli (Capsicum annum L.) genotypes were evaluated for their genetic potential to drought tolerant at germination stage using 12.5% polyethylene (PEG, MW6000). Relative germination energy (RGE), relative germination rate (RGR), relative germination index (RGI), relative vitality index (RVI) and their relative PEG injury rate were computed to identify the most tolerant genotypes on germination stage. Significant differences were observed among the genotypes, treatments and their interactions for evaluated traits suggesting a great amount of variability for drought tolerant in chilli. Based on aggregated score of RGE, RGR, RGI and RVI parameters BD-10906, BD-10912, BD-10911, BD-10916 and BD-10913 were the top five genotypes, whereas BD-10902, RT-20, AM-29, BD-10893 and BD-10930 lowermost five genotypes in the rank of drought tolerant which is an indication of their tolerant and susceptible to drought stress. The lowest relative PEG injury rate was observed in tolerant genotypes, contrary the highest rate was recorded in susceptible genotypes. Dendrogram using Agglomerative Clustering Method grouped the 47 genotypes into four different clusters at the 0.668 co-phenetic correlation coefficient. Drought tolerant chilli genotypes grouped in cluster I, while the susceptible genotypes clustered together in group III and IV and a number of moderate tolerant genotypes gathered in cluster II. Consequently the maximum mean values of tested parameters viz. RGR (91.30), RGE (30.43), RGI (40.58) and RVI (54.10) were observed in clusters I. Positive and significant correlation values were observed between the tolerant indications parameters. RGI showed comparatively strong and positive correlation with all tested parameters. Thus, tolerant and susceptible genotypes will be progressed for further tolerant study in seedling stage.
Published in | Journal of Plant Sciences (Volume 7, Issue 4) |
DOI | 10.11648/j.jps.20190704.12 |
Page(s) | 76-85 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
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Copyright © The Author(s), 2019. Published by Science Publishing Group |
Chilli (Capsicum annum L.), Drought, Germination, Tolerance Indices, Relative Injury Rate, Polyethylene Glycol
[1] | Wang XY, Vinocur P, Altman A. 2003. Plant responses to drought, salinity and extreme temperatures: Towards genetic engineering for stress tolerant. Planta 218 (1): 1-14. |
[2] | Bayoumi TY, Manal HE, Metwali EM. 2008. Application of physiological and biochemical indices as a screening technique for drought tolerant in wheat genotypes. African Journal of Biotechnology 7: 2341-2352. |
[3] | DAE. 2017. Department of Agricultural Extension (DAE) report 2017 production, target and achievement of DAE thorough field service wing. Khamarbari, Farmgate, Dhaka-1215, p19. |
[4] | Dey NC, Alam MS, Sajjan AK, Bhuiyan MA, Ghose L, Ibaraki Y, Karim F. 2011. Assessing Environmental and Health Impact of Drought in the Northwest Bangladesh. Journal of Environmental Science & Natural Resources 4 (2): 89-97. |
[5] | Pessarakli M. 1999. Handbook of plant and crop stresss (2nd ed.), New York, NY: Marcel Dekker Inc. |
[6] | Foolad MR, Zhang LP, Subbiah P. 2003. Genetics of drought tolerant during seed germination in tomato: Inheritance and QTL mapping. Genome 46: 536-545. |
[7] | Nuruddin M, Md. Madramootoo CA, Dodds GT. 2003. Effects of water stress at different growth stages on greenhouse tomato yield and quality. Hort Science 38: 1389-1393. |
[8] | Rahman S, Islam MT, Hossain MA. 2016. Characterization of chilli germplasm. In: MT Islam, Afroz R, Rahman S and Molla MR (Editors), Annual Research Report on Plant Genetic Resources Conservation and Management 2015-16, Plant Genetic Resources Centre, Bangladesh Agricultural Research Institute, Joydebpur, Gazipur-1701, 40-51. |
[9] | Rauf S, Sadaqat HA, Khan IA. 2018. Effect of moisture regimes on combining ability variations of seedling traits in sunflower (Helianthus annuus L.). Candian Journal of Plant Science 88: 323-329. |
[10] | Khayatnezhad M, Gholamin R, Jamaatie-Somarin SH, Zabihi-Mahmoodabad R. 2010. Effects of PEG stress on corn cultivars (Zea mays L.) at germination stage. World Applied Sciences Journal 11 (5): 504-506. |
[11] | Nepomuceno AL, Oostrerhuis DM, Stewart JM. 1998. Physiological responses of cotton leaves and roots to water deficit induced by Poly ethylene Glycol. Environmental and Experimental Botany 40: 29-41. |
[12] | Khodarahmpour Z. 2011. Effect of drought stress induced by polyethylene glycol (PEG) on germination indices in corn (Zea mays L.) hybrids. African Journal of Biotechnology 10 (79): 18222-18227. |
[13] | Rajendran RA, Muthiah AR, Manickam A, Shanmugasundaram P, John Joel A. 2011. Indices of drought tolerant in sorghum (Sorghum bicolor L. Moench) genotypes at early stages of plant growth. Research Journal of Agriculture and Biological Sciences 7: 42-46. |
[14] | Kulkarni M, Deshpande U. 2007. In-vitro screening of tomato genotypes for drought resistance using polyethylene glycol. African Journal Biotechnology 6: 691-696. |
[15] | Almaghrabi OA. 2012. Impact of drought stress on germination and seedling growth parameters of some wheat cultivars Life Science Journal 9: 590-598. |
[16] | Lu Z, Neumann PM. 1998. Water stressed maize, barley and rice seedlings show species diversity in mechanisms of leaf growth inhibition. Journal of Experimental Botany. 49: 1945-1952. |
[17] | Dodd GL and Donovan LA. 1999. Water potential and ionic effects on germination and seedling growth of two cold desert shrubs. American Journal of Botany 86: 1146-1153. |
[18] | Ghebremariam KM, Liang Y, Li C, Li Y, Qin L. 2013. Screening of tomato inbred-lines for drought tolerant at germination and seedling stage. Journal of Agricultural Science 5 (11) E-ISSN 1916-9760. |
[19] | Li Y. 2008. Effect of salt stress on seed germination and seedling growth of three salinity plants. Pakistan Journal of Biological Science 11: 1268-1272. |
[20] | 20. Lihua S, Wen LW, Fen CS. 2005. Effect of PEG on seed germination of Ailanthus altissima. Journal of Agricultural Sciences. 26: 25-29. |
[21] | STAR version 2.0.1. 2014. Biometrics and Breeding Informatics, PBGB Division, International Rice Research Institute, Los Banos, Laguna. |
[22] | Rajendran RA, Muthiah AR, Manickam A, Shanmugasundaram P, John Joel A. 2011. Indices of drought tolerant in sorghum (Sorghum bicolor L. Moench) genotypes at early stages of plant growth. Research Journal of Agriculture and Biological Sciences 7: 42-46. |
[23] | Datta JK, Mondal T, Banerjee A, Mondal NK. 2011. Assessment of drought tolerant of selected wheat cultivars under laboratory condition. Journal of Agricultural Science and Technology 7: 383-393. |
[24] | Saint Pierre C, Crossa JL, Bonnett D, Yamaguchi-Shinozaki K, Reynolds MP. 2012. Phenotyping transgenic wheat for drought resistance. Journal of Experimental Botany 63: 1799-1808. |
[25] | Van den Berg L and Zeng YJ. 2006. Response of South African indigenous grass species to drought stress induced by polyethylene glycol (PEG) 6000. South African Journal of Botany 72: 284-286. |
[26] | Cui L, Yan L, Jitao Z, Lei L. 2011. Effects of osmotic stress on germination characteristics of tomato. Agricultural Research in the Arid Areas 29: 173-179. |
[27] | Alaei M, Zaefizadeh M, Khayatnezhad M, Alaei Z, Alaei Y. 2010. Evaluation of germination properties of different durum wheat genotypes under osmotic stress. Middle-East Journal of Scientific Research 6 (6): 642-646. |
[28] | Hakizimana F, Haley SD, Turnipseed EB. 2000. Repeatability and genotype × environment interaction of coleoptile length measurements in winter wheat. Crop Science 40: 1233-1237. |
[29] | Dhanda SS, Sethi GS, Behl RK. 2004. Indices of drought tolerant in wheat genotypes at early stages of plant growth. Journal of Agronomy and Crop Science 190: 1-6. |
[30] | Awan SI, Ahmed MS, Farooq J, Ahmad SD, Ilyas M, Shah AH, Khan MF, Ali S, Hasan L. 2011. Genetic model analysis on seedling and maturity traits in wheat under rainfed conditions. Frontiers of Agriculture in China 5: 486-496. |
[31] | Leishman, MR, Westoby M. 1994. The role of seed size in seedling establishment in dry soil conditions -experimental evidence from semi-arid species. Journal of Ecology 82 (2): 249-258. |
[32] | Raziuddin, Swati ZA, Bakht J, Farhatullah, Khan NU, Shafi M, Akmal M, Hassan G. 2010. In situ assessment of morpho-physiological responses of wheat (Triticum aestivum L.) genotypes to drought. Pakistan Journal of Botany 42: 3183-3195. |
[33] | Khakwani AA, Dennett MD, Munir M. 2011. Early growth response of six wheat varieties under artificial osmotic stress condition. Pakistan Journal of Agricultural Sciences 48: 118-123. |
[34] | Ahsan AFMS. Physiological and biochemical mechanisms of drought tolerant in wheat. PhD Dissertation. 2018. Department of Agronomy, Bangladesh Agricultural University, Mymensingh, Bangladesh. |
[35] | Baloch MJ, Dunwell J, Khakwani AA, Dennett M, Jatoi WA, Channa SA. 2012. Assessment of wheat cultivars for drought tolerant via osmotic stress imposed at early seedling growth stages. Journal of Agricultural Research 50 (3): 299310. |
APA Style
Md. Rezwan Molla, Iftekhar Ahmed, Rumman Ara, Lutful Hassan, Md. Motiar Rohman. (2019). Screening of Chilli (Capsicum annum L.) Genotypes for Drought Tolerant at Seedling Emergence Stage. Journal of Plant Sciences, 7(4), 76-85. https://doi.org/10.11648/j.jps.20190704.12
ACS Style
Md. Rezwan Molla; Iftekhar Ahmed; Rumman Ara; Lutful Hassan; Md. Motiar Rohman. Screening of Chilli (Capsicum annum L.) Genotypes for Drought Tolerant at Seedling Emergence Stage. J. Plant Sci. 2019, 7(4), 76-85. doi: 10.11648/j.jps.20190704.12
AMA Style
Md. Rezwan Molla, Iftekhar Ahmed, Rumman Ara, Lutful Hassan, Md. Motiar Rohman. Screening of Chilli (Capsicum annum L.) Genotypes for Drought Tolerant at Seedling Emergence Stage. J Plant Sci. 2019;7(4):76-85. doi: 10.11648/j.jps.20190704.12
@article{10.11648/j.jps.20190704.12, author = {Md. Rezwan Molla and Iftekhar Ahmed and Rumman Ara and Lutful Hassan and Md. Motiar Rohman}, title = {Screening of Chilli (Capsicum annum L.) Genotypes for Drought Tolerant at Seedling Emergence Stage}, journal = {Journal of Plant Sciences}, volume = {7}, number = {4}, pages = {76-85}, doi = {10.11648/j.jps.20190704.12}, url = {https://doi.org/10.11648/j.jps.20190704.12}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.jps.20190704.12}, abstract = {Forty seven chilli (Capsicum annum L.) genotypes were evaluated for their genetic potential to drought tolerant at germination stage using 12.5% polyethylene (PEG, MW6000). Relative germination energy (RGE), relative germination rate (RGR), relative germination index (RGI), relative vitality index (RVI) and their relative PEG injury rate were computed to identify the most tolerant genotypes on germination stage. Significant differences were observed among the genotypes, treatments and their interactions for evaluated traits suggesting a great amount of variability for drought tolerant in chilli. Based on aggregated score of RGE, RGR, RGI and RVI parameters BD-10906, BD-10912, BD-10911, BD-10916 and BD-10913 were the top five genotypes, whereas BD-10902, RT-20, AM-29, BD-10893 and BD-10930 lowermost five genotypes in the rank of drought tolerant which is an indication of their tolerant and susceptible to drought stress. The lowest relative PEG injury rate was observed in tolerant genotypes, contrary the highest rate was recorded in susceptible genotypes. Dendrogram using Agglomerative Clustering Method grouped the 47 genotypes into four different clusters at the 0.668 co-phenetic correlation coefficient. Drought tolerant chilli genotypes grouped in cluster I, while the susceptible genotypes clustered together in group III and IV and a number of moderate tolerant genotypes gathered in cluster II. Consequently the maximum mean values of tested parameters viz. RGR (91.30), RGE (30.43), RGI (40.58) and RVI (54.10) were observed in clusters I. Positive and significant correlation values were observed between the tolerant indications parameters. RGI showed comparatively strong and positive correlation with all tested parameters. Thus, tolerant and susceptible genotypes will be progressed for further tolerant study in seedling stage.}, year = {2019} }
TY - JOUR T1 - Screening of Chilli (Capsicum annum L.) Genotypes for Drought Tolerant at Seedling Emergence Stage AU - Md. Rezwan Molla AU - Iftekhar Ahmed AU - Rumman Ara AU - Lutful Hassan AU - Md. Motiar Rohman Y1 - 2019/08/28 PY - 2019 N1 - https://doi.org/10.11648/j.jps.20190704.12 DO - 10.11648/j.jps.20190704.12 T2 - Journal of Plant Sciences JF - Journal of Plant Sciences JO - Journal of Plant Sciences SP - 76 EP - 85 PB - Science Publishing Group SN - 2331-0731 UR - https://doi.org/10.11648/j.jps.20190704.12 AB - Forty seven chilli (Capsicum annum L.) genotypes were evaluated for their genetic potential to drought tolerant at germination stage using 12.5% polyethylene (PEG, MW6000). Relative germination energy (RGE), relative germination rate (RGR), relative germination index (RGI), relative vitality index (RVI) and their relative PEG injury rate were computed to identify the most tolerant genotypes on germination stage. Significant differences were observed among the genotypes, treatments and their interactions for evaluated traits suggesting a great amount of variability for drought tolerant in chilli. Based on aggregated score of RGE, RGR, RGI and RVI parameters BD-10906, BD-10912, BD-10911, BD-10916 and BD-10913 were the top five genotypes, whereas BD-10902, RT-20, AM-29, BD-10893 and BD-10930 lowermost five genotypes in the rank of drought tolerant which is an indication of their tolerant and susceptible to drought stress. The lowest relative PEG injury rate was observed in tolerant genotypes, contrary the highest rate was recorded in susceptible genotypes. Dendrogram using Agglomerative Clustering Method grouped the 47 genotypes into four different clusters at the 0.668 co-phenetic correlation coefficient. Drought tolerant chilli genotypes grouped in cluster I, while the susceptible genotypes clustered together in group III and IV and a number of moderate tolerant genotypes gathered in cluster II. Consequently the maximum mean values of tested parameters viz. RGR (91.30), RGE (30.43), RGI (40.58) and RVI (54.10) were observed in clusters I. Positive and significant correlation values were observed between the tolerant indications parameters. RGI showed comparatively strong and positive correlation with all tested parameters. Thus, tolerant and susceptible genotypes will be progressed for further tolerant study in seedling stage. VL - 7 IS - 4 ER -