Adaptive responses of two distinct wheat varieties to drought stress through microbial-augmented vermicompost | [Pakistan Journal of Botany • 2025]

Author(s):

1. ALI AHMAD: Department of Agronomy, University of Agriculture,Faisalabad 38000,Pakistan

2. ZUBAIR ASLAM: Department of Agronomy, University of Agriculture,Faisalabad 38000,Pakistan

3. KORKMAZ BELLİTÜRK: Department of Soil Science and Plant Nutrition, Faculty of Agriculture, Tekirdağ Namık Kemal University,59030 Süleymanpaşa/Tekirdağ,Turkey

4. SADDAM HUSSAIN: Department of Agronomy, University of Agriculture,Faisalabad 38000,Pakistan

5. IRSHAD BIBI: Institute of Soil and Environmental Sciences, University of Agriculture,Faisalabad 38000,Pakistan

Abstract:

Wheat, a vital cereal crop, is predominantly grown in arid and semi-arid regions, making it susceptible to drought stress. The adverse effects of drought on wheat can potentially be mitigated through the application of cellulolytic microbes-enriched vermicompost. To explore this, two field studies were conducted at the Student Research Farm, Agronomy Department, University of Agriculture Faisalabad, during 2020-21 and 2021-22. The research examined the impact of cellulolytic microbesenriched vermicompost on the agronomic, physiological, and enzymatic antioxidant traits of wheat under varying soil moisture levels. The treatments included: (a) Three soil moisture levels: well-watered (D0, 70% field capacity), moderate drought (D1, 45% field capacity), and severe drought (D2, 30% field capacity). (b) Two wheat varieties: Galaxy-13 (drought-sensitive) and Faisalabad-08 (drought-tolerant). (c) Four microbial enriched vermicompost levels: VT0 (control, no vermicompost), VT1 (6 t/ha wheat straw vermicompost), VT2 (6 t/ha rice straw vermicompost), and VT3 (4 t/ha cow dung vermicompost). The results revealed that the highest crop growth and yield were achieved with 4 t/ha cow dung vermicompost (VT3), followed by rice straw vermicompost (VT2) and wheat straw vermicompost (VT1). The lowest performance was observed in the control (VT0) across both wheat cultivars. Faisalabad-08 consistently outperformed Galaxy-13 in growth and yield under both moderate and severe drought conditions. The findings further highlighted that drought stress significantly reduced agronomic, physiological, biochemical, and growth traits of wheat. However, the application of vermicompost enhanced these characteristics and improved yield, even under water-limited conditions.

Page(s): 1615-1630

DOI: 10.30848/PJB2025-5(28)

Published: Journal: Pakistan Journal of Botany, Volume: 57, Issue: 5, Year: 2025

Keywords:

Vermicompost , Field experiment , Microbes , Wheat cultivars , Drought levels , Straw

References:

[1] Ahmad A.,Aslam Z.,Bellitürk K.,Hussain S.,Bibi I. .2022 .Soil application of cellulolytic microbe-enriched vermicompost modulated the morpho-physiological and biochemical responses of wheat cultivars under different moisture regimes. J. Soil Sci. Plant, 22 : 4153-4167.

[2] Ahmad A.,Aslam Z.,Abbas R.N.,Bellitürk K.,Hussain S.,Hussain S.,Ahmad M.,Zulfiqar U.,Moussa I.M.,Elshikh M.S. .2024 .Enhancing wheat crop resilience to drought stress through cellulolytic microbe-enriched cow dung vermicompost. ACS Omega, 9 : 2123-2133.

[3] Ahmad A.,Aslam Z.,Hussain S.,BiBi A.,Javed T.,Hussain S.,Alotaibi S.S.,Kalaji H.M.,Telesiński A.,Iwai C.B.,Kumar U. .2022 .Rice straw vermicompost enriched with cellulolytic microbes ameliorate the negative effect of drought in wheat through modulating the morphophysiological attributes. Front. Environ. Sci., 902999 : 902999.

[4] Ahmad A.,Aslam Z.,Awan T.H.,Syed S.,Hussain S.,Hussain S.,Bellitürk K.,Bashir S. .2025 .Drought stress in wheat: mechanisms, effects and mitigation through vermicompost. Pak. J. Bot., 57(1) : 47-60.

[5] Akram M. .2011 .Growth and yield components of wheat under water stress of different growth stages. Bangladesh J. Agri. Res., 36(3) : 455-468.

[6] Paul Amita,Shivashankari S.,Joseph P.V. .2017 .Study of Cellulase activity in Eisenia foetida used in the degradation of paper waste. Int. J. Sci. Appl, 4(5) : 57-65.

[7] Andersen M.N.,Jensen C.R.,Losch R. .1992 .The interaction effects of potassium and drought in field-grown barley. 1. Yield water-use efficiency and growth. Acta Agric. Scand. B Soil Plant Sci., 42 : 34-44.

[8] Anjum S.A.,Tanveer M. .2016 .Effect of progressive drought stress on growth, leaf gas exchange, and antioxidant production in two maize cultivars. Environ. Sci. Pollut, 23 : 17132-17141.

[9] Anjum S.A.,Ashraf U.,Zohaib A.,Tanveer M.,Naeem M.,Iftikhar A.L.I.,Tabassum T.,Nazir U. .2017 .Growth and developmental responses of crop plants under drought stress: a review. Zemdirbyste-Agric. , 104 : 267-276.

[10] Ansari W.A.,Atri N.,Singh B.,Pandey S. .2017 .Changes in antioxidant enzyme activities and gene expression in two muskmelon genotypes under progressive water stress. Biol. Plant, 6 : 333-341.

[11] Arancon N.Q.,Edwards C.A.,Bierman P.,Welch C.,Metzger J.D. .2004 .Influences of vermicomposts on field strawberries, 1. Effects on growth and yields. , 93 : 145-153.

[12] Aslam Z.,Ahmad A.,Abbas R.N.,Sarwar M.,Bashir S. .2023 .Morpho-physiological, biochemical and yield responses of wheat (Triticum aestivum L.) to vermicompost, simple compost and NP fertilizer applications. , 55(6) : 2143-2154.

[13] Aslam Z.,Ahmad A.,Bashir S.,Hussain S.,Bellitürk K.,Ahmad J.N.,Ullah E.,Tanvir S.,Abbas T. .2022 .Effect of integrated nutrient management practices on physiological, morphological and yield parameters of chilli (Capsicum annum L.). Pak. J. Bot., 54(6) : 2143-2150.

[14] Aslam Z.,Bashir S.,Hassan W.,Bellitürk K.,Ahmad N.,Niazi N.K.,Khan A.,Khan M.I.,Chen Z.,Maitah M. .2019 .Unveiling the efficiency of vermicompost derived from different biowastes on wheat (Triticum aestivum L.) Plant growth and soil health. Agronomy., 10 : 791.

[15] Barik T.,J.M.L. Gulati L.M.,Garnayak D.K.,Bastia D.K. .2011 .Production of vermicompost from agricultural wastes. Agri. Rev., 31(3) : 172-183.

[16] Chance B.,Maehly A.C. .1955 .Assay of catalase and peroxidase. Methods Enzymol, 2 : 764-775.

[17] Chaves M.M. J.S.,Pereira J.,Maroco M.L.,Rodrigues C.P.,Ricardo M.L.,Osorio J.,Carvalho T.,Faria C.,Pinheiro C. .2002 .How plants cope with water stress in the field? Photosynthesis and growth. , 89 : 907-916.

[18] Chaves M.M. .1991 .Effects of water deficits on carbon assimilation. J. Exp. Bot., 42 : 1-16.

[19] Davatgar N.,Neishabouri M.R.,Sepaskhah A.R.,Soltani A. .2009 .Physiological and morphological responses of rice (Oryza sativa L.) to varying water stress management strategies. Int. J. Plant Prod, 3 : 19-32.

[20] FAO. .2017 .. , : .

[21] Farooq M.,Wahid A.,Kobayashi N.,Fujita D.,Basra S.M.A. .2009 .Plant drought stress: effects, mechanisms and management. , 29 : 153-188.

[22] Flexas J. ,Bota J.,Loreto F.,Sharkey T.D.C.G. .2004 .Diffusive and metabolic limitations to photosynthesis under drought and salinity in C3 plants. Plant Biol, 6 : 269-279.

[23] Flexas J. and H.,Medrano J. and H. .2008 .Water-inhibition of photosynthesis in C3 plants, stomatal and non-stomatal limitation revisited. , 183 : 183-189.

[24] Gajalakshmi S.A.,Abbasi S.A. .2004 .Earthworms and vermicomposting. Ind. J. Biotechnol., 3 : 486-494.

[25] Garcia A.C.,Santos L.A.,Izquierdo F.G.,Rumjanek V.M.,Castro R.N.,Santos and L.G.A. de Souza F.S. dos .2014 .Potentialities of vermicompost humic acids to alleviate water stress in rice plants (Oryza sativa L.). J. Geochem. Explor., 136 : 48-54.

[26] Garg V.K.,Gupta R. .2009 .Biotechnology for agro-industrial residues utilization. , : 431-456.

[27] Giannopolitis C.N. and S.K.,Ries C.N. and S.K. .1977 .Superoxide dismutases. I. Occurrence in higher plants. Plant, 59 : 309-314.

[28] .2019 .. Government of Pakistan, : 20.

[29] Hafez E.M.,Omara A.E.D.,Alhumaydhi F.A.,ElEsawi M.A. .2020 .Minimizing hazard impacts of soil salinity and water stress on wheat plants by soil application of vermicompost and biochar. Physiol. Plant, 172(2) : 587-602.

[30] Hosseinzadeh S.R.,Amiri H.,Ismaili A. .2016 .Effect of vermicompost fertilizer on photosynthetic characteristics of chickpea (Cicer arietinum L.) under drought stress. , 54(1) : 87-92.

[31] Huerta E.,Vidal O.,Jarquin A.,Geissen V.,Gomez R. .2010 .Effect of vermicompost on the growth and production of Amashito Pepper, interactions with earthworms and rhizobacteria. Compost Sci. Util, 18 : 282-288.

[32] Hussain S.,Farooq W.,Hasan S.,Ul-Allah M.,Tanveer M.,Nawaz A. .2018 .Drought stress in sunflower: Physiological effects and its management through breeding and agronomic alternatives. Agric, 201 : 152-166.

[33] Jat R.S. and I.P.S.,Ahlawat R.S. and I.P.S. .2006 .Direct and residual effect of vermicompost, biofertilizers and phosphorus on soil nutrient dynamics and productivity of chickpea-fodder maize sequence. J. Sustain. Agric., 28 : 41-54.

[34] Ji X.,Shiran B.,Wan J.,Lewis D.C.,Jenkins C.L.D.,Condon A.G.,Richards R.A.,Dolferus R. .2010 .Importance of pre-anthesis anther sink strength for maintenance of grain number during reproductive stage water stress in wheat. Plant. Cell Environ, 33 : 926-942.

[35] Jyotsana P.,Vijayalakshmi K.,Prasanna N.D.,Shaheen S.K. .2010 .Isolation, characterization of cellulase producing Lysinibacillus Sphaericus (MTCC no. 9468) from gut of Eisenia foetida. The Bioscan., 6(2) : 325-327.

[36] Kale B.C.,Mallesh B.,Kubra D.J.,Bagyaraj D.J. .1992 .Influence of vermicompost application on the available macronutrients and selected microbial population in a paddy field. Biochem, 24 : 1317-1320.

[37] Khakwani A.A.,Dennet M.D.,Munir M. .2011 .Drought tolerance screening of wheat varieties by inducing water stress conditions. Songklanakarin J. Sci. Technol, 33(2) : 135-142.

[38] Kmeťova M.,Kovačik P. .2014 .The impact of vermicompost application on the yield parameters of maize (Zea mays L.) observed in selected phenological growth stages (BBCHscale). Acta Fytotech, 17 : 100-108.

[39] Lawlor D.W.,Cornic G. .2002 .Photosynthetic carbon assimilation and associated metabolism in relation to water deficits in higher plants. Plant Cell Environ, 25 : 275-294.

[40] Marinari S.,Masciandaro G.,Ceccanti B.,Grego S. .2000 .Influence of organic and mineral fertilizers on soil biological and physical properties. , 72 : 9-17.

[41] Matos G.D.,Arruda M.A.Z. .2003 .Vermicompost as natural adsorbent for removing metal ions from laboratory effluents. , 39 : 81-88.

[42] Mitchell J.H.,Siamhan D.,Wamala M.H.,Risimeri J.B.,Chinyamakobvu E.,Henderson S.A.,Fukai S. .1998 .The use of seedling leaf death score for evaluation of drought resistance of rice. Field Crops Res., 55 : 129-139.

[43] Mssacci A,Nabiev S.M.,Pietrosanti L.,Nematov S.K.,Chernikova T.N.,Thor K.,Leipner J. .2008 .Response of photosynthetic apparatus of cotton (Gossypium hirsutum) to the onset of water stress under field conditions studied by gas-exchange analysis and chlorophyll fluorescence imaging. Plant, 46 : 189-195.

[44] Nayyar D.,Gupta D. .2006 .Differential sensitivity of C3 and C4 plants to water deficit stress: association with oxidative stress and antioxidants. Environ. Exp. Bot., 58 : 106-113.

[45] Pagter M.,Bragato C.,Brix H. .2005 .Tolerance and physiological responses of Phragmites australis to water deficit. Aquat, 81 : 285-299.

[46] Parkinson K.J. .1983 .Porometry in SEB. , : .

[47] Parkinson K.J.,Day W.,Leach J.E. .1980 .A portable system for measuring the photosynthesis and transpiration of graminaceous leaves. J. Exp. Bot., 31 : 1441-1453.

[48] Patade S.,Bhargava P.,Suprasanna P. .2011 .Salt and drought tolerance of sugarcane under iso-osmotic salt and water stress: growth, osmolytes accumulation and antioxidant defense. J. Plant Interact, 6 : 275-282.

[49] Natarajan Pathma J. and S. .2012 .Microbial diversity of vermicompost bacteria that exhibit useful agricultural traits and waste management potential. , 1 : 1-19.

[50] Pettigrew W.T. .2004 .Physiological consequences of moisture deficit stress in cotton. Crop Sci., 44 : 1265-1272.

[51] Rosolem C.A.,Sarto M.V.M.,Rocha K.F.,Martins J.D.L.,Alves M.S. .2019 .Does the introgression of BT gene affect physiological cotton response to water deficit? Planta Daninha. , 37 : 1-7.

[52] Sairam R.K.,Saxena D.C. .2001 .Oxidative stress and antioxidants in wheat genotypes, possible mechanism of water stress tolerance. J. Agron. Crop Sci., 184 : 55-61.

[53] Scholander P.L.,Hammel H.T.,Bradstreet E.D.,Hemminsoln E.A. .1964 .Hydrostatic pressure and osmotic potential in leaves of mangroves and some other plants. Proc. Natl, 52 : 119-125.

[54] Sharma K.,Garg V. .2018 .Comparative analysis of vermicompost quality produced from rice straw and paper waste employing earthworm Eisenia fetida (Sav. , 250 : 708-715.

[55] Sinclair T.R.,Vadez V. .2002 .Physiological traits for crop yield improvement in low N and P environments. Plant Soil, 245 : 1-15.

[56] Singh K.,Wijewardana C.,Gajanayake B.,Lokhande S.,Wallace T.,Jones D.,Reddy K.R. .2018 .Genotypic variability among cotton cultivars for heat and drought tolerance using reproductive and physiological traits. Euphytica, 214 : 1-22.

[57] Steel R.G.D.,Torrie J.H.,Dickey D. .1997 .McGraw Hill Book Co. , : .

[58] Taheri-Asghari M.,Daneshian J.,Aliabadi-Farahani H. .2009 .Effects of drought stress and planting density on quality and morphological of Chicory (Cichorium intybus L.). Asian J. Agri. Sci., 1 : 12-14.

[59] Tang A.C.,Kawamitsa Y.,Kanechi M.,Boyer J.S. .2002 .Photosynthesis at low water potentials in leaf discs lacking epidermis. , 89(7) : 861-870.

[60] Tara C.,Alternatives (DA) Sustainable Livelihoods. .2003 .. , : .

[61] Todaka D.,Zhao Y.,Yoshida T.,Kudo M.,Kidokoro S.,Mizoi J. .2017 .Temporal and spatial changes in gene expression, metabolite accumulation and phytohormone content in rice seedlings grown under drought stress conditions. Plant, 90(1) : 61-78.

[62] Wang S.,Wang W.,Chen H.,Li X.,Deng X. .2017 .Physiological mechanisms contributing to increased wateruse efficiency in winter wheat under organic fertilization. PloS One, 12 : 1-21.

[63] .2018 .. World Agriculture Production (WAP), 27 : 1-16.

Citations

Citations are not available for this document.

Citations

Downloads

Views