Abstract
Citrus is one of the largest fruit crops grown in Morocco. Citrus crops gain in importance due to the jobs generated during the production process of fresh or processed fruit. Intensive agriculture is characterized by the excessive use of inorganic fertilizers and pesticides. This production system has generated serious environmental contamination problems, thus, it is necessary to implement sustainable production strategies to reduce the use of synthetic chemicals and contribute to soil and water conservation. In this context, Seventy two Rhizobacterial isolates of fluorescent Pseudomonas were isolated from rhizosphere soil of Citrus in the Sapiama nursery. These isolates were tested on germination and growth of Citrus macrophylla rootstock. The results obtained showed that the isolate C11 significantly stimulated germination 16 days after seed inoculation. The C26, C6 and C24 isolates showed PGPR effects improving significantly the growth parameters of C. macrophylla rootstock. They significantly promoted plant height, collar diameter and root length. This study concluded that the Pseudomonas isolates could be potential alternative biofertilizers to chemical products and could be considered as a promising main component for sustainable agriculture development strategy in Citrus farming.
Keywords: Citrus macrophylla, Pseudomonas, PGPR
Introduction
Citrus is one of the most important fruit crops grown in Morocco. It represents an important element in the economy of the country, with an annual production of 1.5 to 2.0 million tons obtained from approximately 125,000 ha (ASPAM, 2019). Souss-Massa-Draa region is the main area of both production and exportation of fresh fruit from Morocco (Boubaker et al., 2009). Given the economic importance of Citrus crops, producers became more and more dependent on agrochemicals as a reliable method to maintain soil productivity and thus to accelerate and improve Citrus production. However, the use of fungicides is increasingly becoming restricted owing to stringent regulation, high cost, environmental pollution and growing public concern about synthetic products (Mesnage and Antoniou, 2018). Therefore, the challenge is to develop healthy and effective strategies to enhance nutrition and growth of crops.
Over the last years, organic agricultural system has emerged as an effective alternative to improve crop growth and quality (Willer and Lernoud, 2017). The rhizosphere, narrow zone of soil that surrounds and get influenced by the roots of plant (Prashar et al., 2014), is a highly favorable habitat for the proliferation of microorganisms and exerts a potential impact on plant health and soil fertility (Pathan et al., 2019; Qessaoui et al., 2019a). Bacterial species mostly associated with the plant rhizosphere known as “Plant growth promoting rhizobacteria” (PGPR) are non-pathogenic and reported to be beneficial for plant growth, yield and crop quality (O’Connell, 1992; Ahmad et al., 2008; Esitken et al., 2010; Olanrewaju et al., 2017; Qessaoui et al., 2019a). The success of some of these PGPR in laboratory studies and pilot tests conducted in the field have generated interest by several agrochemical companies in the development and commercialization of Bioproducts formulated with selected efficient PGPR. Several bacteria have been patented and evaluated for commercial use, of which BIOBOOST (Delftia acidovorans), BIOPLIN (Azotobacter spp.), BIOYIELD (Bacillus spp.), COMPETE (Bacillus, Pseudomonas and Streptomyces spp.) and KODIAK (Bacillus subtilis) are used as biofertilizers (Podile and Kishore, 2006).
The plant promoting effect of the PGPR is explained by various mechanisms including: (i) reduction of ethylene production (Glick et al., 1995); (ii) production of plant hormones such as auxins (Egamberdiyeva, 2005), cytokinins (Garcia de Salamone et al., 2001) and gibberellins (Gutierrez-Manero et al., 2001); (iii) enhancement of the symbiotic N2 fixation (Kim and Rees, 1994) and (iv) solubilization of nutrients (Jeon et al., 2003; Glick, 1995). Besides, their role in plants growth promotion, PGPR also act as protectants of soil-borne pathogens (Howell and Stipanovic, 1978; Weller et al., 2002; Guo et al., 2004; Amkraz et al., 2010). The production of siderophores, the synthesis of antibiotics, enzymes and/or fungidical compounds and competition for nutriments and space are the main mechanisms by which PGPR contribute to control plant bioagressors (Compant et al., 2005; Haas and Defago, 2005 ; Qessaoui et al., 2017; Qessaoui et al., 2019a,b).
Among the diverse range of PGPR identified, Pseudomonas is a wide distributed bacteria, which is considered as one of the most extensively studied and used in organic production system. Within the genus, fluorescent Pseudomonas bacteria the most studied (Weller, 1988). They are reported to prevent proliferation of plant pathogens and stimulate plant growth by facilitating either uptake of nutrients from soil or producing certain plant growth promoting substances (Weller, 1988; Sutra et al., 2000; Boudyach et al., 2004; Qessaoui et al., 2019a). Nevertheless, limited information is available on the promoting effect of fluorescent Pseudomonas on the growth of Citrus plants. Thus, the present research is aimed to (1) isolate fluorescent Pseudomonas from the rhizospheric soil of Citrus plants (Citrus macrophylla), (2) select efficient strains able to improve seed germination and growth of Citrus rootstocks.
Material and methods
Fluorescent Pseudomonas isolation
Citrus root samples and soil adhering were collected from Citrus trees at Sapiama nursery, Taroudant, Morocco. The bacterial communities of the rhizosphere (RS) and the endorhizosphere (ER) were isolated as described by Dommergues and Mangenot (1970) and Amkraz (2010). One gram of rhizospheric soil, obtained by shaking roots, was added to 9 ml of sterile physiological water and the mixture was agitated for 15 min. Serial dilutions were prepared, and 0.1 ml of each dilution was dropped onto King B medium (King et al., 1954), supplemented with 100 g ml-1 of cycloheximide to suppress fungi. Three replicates were incubated at 28 °C for 72 h. Results were expressed as colony forming units per gram (cfu g-1) of rhizospheric soil. Fluorescent colonies on King B medium were sub-cultured twice before storage at 4 °C on yeast dextrose carbonate agar (YDC) (Jiménez et al., 2004) and at -80 °C in 40% glycerol (Parke et al., 1986). The isolates were identified in the plant protection laboratory at INRA Agadir (Qessaoui et al, 2019a).
Effect of fluorescent Pseudomonas on seeds germination of C. macrophylla rootstock
Seeds of Citrus macrophylla were surface disinfected with 30% sodium hypochlorite solution during 5 min and air-dried. Seeds were then treated with isolated Pseudomonas (108 cfu ml-1) in Xantham gum 0.5% (Boubyach et al., 2001). Control seeds were treated by Xantham gum in the same conditions. All treatments were performed in three replicates with 10 seeds of each treatment. The inoculated seeds were placed in Petri dishes covered with Whatman paper and were incubated at 25±2°C. The percent of germination was calculated form 14th to 30th days after treatment.
Effect of fluorescent Pseudomonas on C. macrophylla rootstock growth
During transplantation, C. macrophylla roots were inoculated with the Pseudomonas (108 cfu ml-1) using dipping method for 20s. After inoculation, the seedlings were transplanted into the plastic pots contains a mixture of sand and peat in a ratio of 2:1 (v/v). All treatments were performed in three replicates with nine plants of each replicate. The plant height, number of leaves and collar diameter of seedlings were evaluated at the second month after transplantation.
Statistical analysis
The seed germination and PGPR parameters were calculated for each Pseudomonas isolate. The data were subjected to the analysis of variance test (ANOVA) using Statistica software (Version 6). Any difference mentioned is significant at p less than 0.01 using Duncan’s tests.
Results
Fluorescent Pseudomonas isolation
The result shows the total number of bacteria per gram of soil and the percentage of fluorescent bacteria in both soils. Numbers of total bacteria were significantly higher in the rhizospheric soil compared to the endorhizosphere soil. However, the fluorescent Pseudomonas were significantly abundant in the endorhizosphere soil (Table 1). Seventy two (72) Pseudomonas isolates were selected in this work. These isolates were tested on seed germination and on the growth of C. macrophylla rootstock.
Effect of fluorescent Pseudomonas on seeds germination of C. macrophylla rootstock
The results of germination showed that among 72 isolates, 30 have shown an inhibition effect on seed germination of C. macrophylla rootstock ( these results were excluded in the study). Among 42 isolates that showed a positive effect, only isolate C11 has a significant effect from 16th day after inoculation compared to the control (Figure 1).
Inoculation of C. macrophylla rootstock roots
Among 42 isolates tested on plant growth parameters, three (C6, C24 and C26) showed a significant effect on C. macrophylla rootstock growth at the 2nd month after transplantation (Table 2).
The two isolates, C6 and C24, showed a significant effect on C. macrophylla rootstock height with 50 cm and 52% respectively. They showed a gain of 21 and 25 % respectively compared to control (Table 2). For the number of leaves, three isolates (C6, C24 and C26) showed no significant effect on leaf number compared to the control at 2nd month of transplantation (Table 2).
The collar diameter was evaluated in order to determine the effect of selected isolates on plant vigor of C. macrophylla rootstock. The results showed a significant effect of two isolates, C6 and C26, with a gain of 19 and 21% respectively, compared to the control (Table 2).
The 3 isolates (C24, C26 and C6) have shown a positive effect on height and collar diameter of C. macrophylla rootstock. They also have a significant effect on proliferation of the root system of C. macrophylla rootstock (Figure 2).These three isolates were identified as isolates of Pseudomonas spp.
Discussion
The Pseudomonas isolates identified in this study stimulate the growth of Citrus rootstock C. macrophylla in greenhouse conditions. Stimulating the growth of plants inoculated with each of these isolates could be explained by several mechanisms. For example by improving uptake of water and nutrients needed by plants and the inhibition of pathogenic agents which can damage growth of rootstocks. The phytohormones synthesized by rhizobacteria and the solubilization of phosphate stimulate the development of the root system and aerial part of plants. Some PGPR have the ability to synthesize indole-3-acetic acid (IAA), known for its beneficial effect on rooting and root development (Egamberdiyeva, 2005). Production of antibiotics and siderophores by bacteria which inhibit pathogenic fungi and bacteria that compete with plants for nutrition and space, thus allowing availability of nutrients and space. They consequently promote plant growth (Digat et al.,1993). The results of this study are consistent with numerous studies that have demonstrated the stimulation of plant growth after inoculation by bacteria. Indeed, Glick et al., (2007) reported that inoculation of plants with PGPR stimulates the growth and yield of plants, by the solubilization of phosphate, potassium and by stimulating the absorption of atmospheric nitrogen. The Pseudomonas act positively on the development of root system and stimulated significantly the length of the stem and collar diameter of plants (Gamalero et al., 2002; Satrani et al., 2009). Similarly, Esitken et al., (2006) showed that Pseudomonas BA-8 and Bacillus OSU-142 alone or in combination increase the nutrition, growth and yield of cherry plants. The results of the present study showed that the Pseudomonas C11 have potential to increase seed germination and the Pseudomonas C24, C26 and C6 have potential to increase the growth and vigor of Citrus rootstock plants. These bacteria could be a promising alternative as a bio-fertilizer for Citrus rootstock production.
References
Ahmad F., Ahmad I., Khan M. (2008). Screening of free-living rhizospheric bacteria for their multiple plant growth promoting activities. Microbiological research, 163: 173-181.
Amkraz N., Boudyach E., Boubaker H., Bouizgarne B., Aoumar A.A.B. (2010). Screening for fluorescent pseudomonades, isolated from the rhizosphere of tomato, for antagonistic activity toward Clavibacter michiganensis subsp. michiganensis. World Journal of Microbiology and Biotechnology, 26: 1059-1065.
Boudyach E., Fatmi M., Akhayat O., Benizri E., Aoumar A.A.B. (2001). Selection of antagonistic bacteria of Clavibacter michiganensis subsp. michiganensis and evaluation of their efficiency against bacterial canker of tomato. Biocontrol Science and Technology, 11: 141-149.
Boudyach E., Fatmi M., Boubaker H., Aoumar A.A.B., Akhayat O. (2004). Effectiveness of fluorescent pseudomonads strains HF 22 and HF 142 to control bacterial canker of tomato. Journal of Food Agriculture and Environment, 2: 115-120.
Compant S., Duffy B., Nowak J., Clément C., Barka E.A. (2005). Use of plant growth-promoting bacteria for biocontrol of plant diseases: principles, mechanisms of action, and future prospects. Applied and Environmental Microbiology, 71: 4951-4959.
Dobbelaere S., Vanderleyden J., Okon Y. (2003). Plant growth-promoting effects of diazotrophs in the rhizosphere. Critical Reviews in Plant Sciences, 22: 107-149.
Dommergues Y., Mangenot F. (1970). Écologie microbienne du sol.
Egamberdiyeva D. (2005). Plant‐growth‐promoting rhizobacteria isolated from a Calcisol in a semi‐arid region of Uzbekistan: biochemical characterization and effectiveness. Journal of Plant Nutrition and Soil Science, 168: 94-99.
Esitken A., Yildiz H.E., Ercisli S., Donmez M.F., Turan M., Gunes A. (2010). Effects of plant growth promoting bacteria (PGPB) on yield, growth and nutrient contents of organically grown strawberry. Scientia horticulturae 124: 62-66.
Garcia de Salamone I.E., Hynes R.K., Nelson L.M. (2001). Cytokinin production by plant growth promoting rhizobacteria and selected mutants. Canadian journal of microbiology, 47: 404-411.
Glick B.R. (1995). The enhancement of plant growth by free-living bacteria. Canadian journal of microbiology ,41: 109-117.
Glick B.R., Todorovic B., Czarny J., Cheng Z., Duan J., McConkey B. (2007). Promotion of plant growth by bacterial ACC deaminase. Critical Reviews in Plant Sciences, 26: 227-242.
Gutiérrez‐Mañero F.J., Ramos‐Solano B., Probanza A., Mehouachi J., R Tadeo F., Talon M. (2001). The plant‐growth‐promoting rhizobacteria Bacillus pumilus and Bacillus licheniformis produce high amounts of physiologically active gibberellins. Physiologia Plantarum, 111: 206-211.
Haas D., Défago G. (2005). Biological control of soil-borne pathogens by fluorescent pseudomonads. Nature Reviews Microbiology, 3: 307-319.
Jeon J.-S., Lee S.-S., Kim H.-Y., Ahn T.-S., Song H.-G. (2003). Plant growth promotion in soil by some inoculated microorganisms. Journal of Microbiology-Seoul, 41: 271-276.
Jiménez O., Contreras N., Nass H. (2004). Xanthomonas albilineans causal agent of sugarcane(Saccharum sp) leaf scald disease in states Lara and Yaracuy. Revista de la Facultad de Agronomia, 21: 233-245.
Kim J., Rees D.C. (1994). Nitrogenase and biological nitrogen fixation. Biochemistry, 33: 389-397.
King E.O., Ward M.K., Raney D.E. (1954). Two simple media for the demonstration of pyocyanin and fluorescin. Journal of laboratory and clinical medicine, 44: 301-307.
Mesnage R., Antoniou MN. (2018). Ignoring adjuvant toxicity falsifies the safety profile of commercial pesticides. Front Public Health, 5:361.
O’connell, P.F. (1992). Sustainable agriculture - a valid alternative. Outlook on Agriculture, 21: 5-12.
Parke J., Moen R., Rovira A., Bowen G. (1986). Soil water flow affects the rhizosphere distribution of a seed-borne biological control agent, Pseudomonas fluorescens. Soil Biology and Biochemistry, 18: 583-588.
Qessaoui R., Bouharroud R., Amarraque A., Lahmyed H., Ajerrar A., Ait Aabd N., Tahiri A., Mayad E.H., Chebli B. (2019). Effect of Pseudomonas as a preventive and curative control of tomato leafminer Tuta absoluta (lepidoptera: gelechiidae). J. Applied Sci., 19: 473-479.
Raupach G.S., Kloepper J.W. (1998). Mixtures of plant growth-promoting rhizobacteria enhance biological control of multiple cucumber pathogens. Phytopathology, 88: 1158-1164.
Şahin F., Çakmakçi R., Kantar F. (2004). Sugar beet and barley yields in relation to inoculation with N2-fixing and phosphate solubilizing bacteria. Plant and soil, 265: 123-129.
Satrani B., El Ouadihi N., Guedira A., Frey-Klett P., Arahou M., Garbaye J. (2009). Effet de la bactérisation des graines sur la croissance des plants de Cedrus atlantica Manetti. Biotechnologie, Agronomie, Société et Environnement, 13.
Sutra L., Risede J., Gardan L. (2000). Isolation of fluorescent pseudomonads from the rhizosphere of banana plants antagonistic towards root necrosing fungi. Letters in applied microbiology, 31: 289-293.
Weller D.M. (1988). Biological control of soilborne plant pathogens in the rhizosphere with bacteria. Annual Review of Phytopathology, 26: 379-407.
Weller D.M., Raaijmakers J.M., Gardener B.B.M., Thomashow L.S. (2002). Microbial populations responsible for specific soil suppressiveness to plant pathogens. Annual Review of Phytopathology, 40: 309-348.
Willer H., and Lernoud J. (Eds.) (2017). The World of Organic Agriculture. Statistics and Emerging Trends 2017. 18 edition. Research Institute of Organic Agriculture FiBL and IFOAM - Organics International, Frick and Bonn.