| تعداد نشریات | 285 |
| تعداد نشریات سازمان | 83 |
| تعداد شمارهها | 3,112 |
| تعداد مقالات | 34,675 |
| تعداد مشاهده مقاله | 49,896,043 |
| تعداد دریافت فایل اصل مقاله | 80,219,789 |
Screening of fungal strains isolated from dead insects for production of plant litter-degrading enzymes | ||
| Mycologia Iranica | ||
| مقاله 12، دوره 7، شماره 1 - شماره پیاپی 1013، شهریور 2020، صفحه 155-161 اصل مقاله (483.91 K) | ||
| نوع مقاله: Original Article | ||
| شناسه دیجیتال (DOI): 10.22092/mi.2020.123124 | ||
| نویسندگان | ||
| A. Armand1؛ S.A. Khodaparast* 1؛ H. Masigol1؛ H. P. Grossart2 | ||
| 1Department of Plant Protection, Faculty of Agricultural Sciences, University of Guilan, Rasht, Iran | ||
| 2Department of Experimental Limnology, Leibniz Institute of Freshwater Ecology and Inland Fisheries, Stechlin, Germany | ||
| چکیده | ||
| Exploring the enzymatic capabilities of fungi is of great importance to better understand their ecological roles and improving their manifold usage in industry. Therefore, rapid and reliable screening methods to evaluate fungal enzymatic potentials are needed. In this study, 76 fungal strains were isolated and identified from insect pests from citrus plantations in Guilan province, northern Iran. All the strains belonged to Akanthomyces and Lecanicillium (Ascomycota: Hypocreales). Plate assay methods were applied to investigate fungal ability to produce the following enzymes: Endo-1,4-β-glucanase (CM-cellulase, endoglucanase and endocellulase), β-Glucosidase, Cellobiodydrolase, pectinase and laccase. The results showed that the majority of the strains were able to produce at least one of these enzymes. The cellulolytic activity was found in 33 % and laccase activity was detected in 11 % of all strains tested. Interestingly, the enzymatic ability of strains identified as A. muscarius and A. lecanii, were generally different, likely confirming their taxonomic position. | ||
| کلیدواژهها | ||
| Enzymatic potential؛ Akanthomyces؛ Lecanicillium؛ citrus plantations | ||
| اصل مقاله | ||
|
INTRODUCTION
Recently, the enzymatic potential of fungi has gained great attention for their manifold applications in different industries such as paper production (Witayakran & Ragauskas 2009), biofuel generation (Wilson 2009), bioremediation (Strong & Claus 2011), phytopathogen management (Kikot et al. 2009), etc. For instance, fungal strains including Cryphonectria parasitica (Murrill) M.E. Barr, Thermomyces lanuginosus Tsikl., and Rhizopus oryzae Went & Prins. Geerl. are frequently used in food processing (Jensen et al. 2006), detergent production (Johnsen et al. 1997), and pharmaceutical industries (Loureiro et al. 2009), respectively. One of the most predominant fungi used in large-scale production of enzymes is Aspergillus from which 12 different industrial enzymes are currently used in various industrial sectors including the production of rubber, milk and other dairy products, as well as bread (Park et al. 2017). In addition to their industrial applications, fungi possess an enormous ecological role being parasitic or saprophytic degraders of plant lignocellulosic materials in either aquatic or terrestrial ecosystems (Lundell et al. 2010). Moreover, pectin can be found in lignocellulosic residues to varying degrees based on their original source (Sánchez 2009). The lignocellulolytic enzymes-producing fungi are more prevalent in the phylum Basidiomycota than Ascomycota, in particular, white-rot (e.g., Phanerochaete chrysosporium Burds.) (Leonowicz et al. 1999) and brown-rot fungi (e.g., Fomitopsis palustris (Berk. & M.A. Curtis) Gilb. & Ryvarden) (Yoon & Kim 2005). However, both Dikarya phyla (Ascomycota and Basidiomycota) are differently involved in lignocellulose degradation processes. Ascomycota dominate during the first stages of litter degradation (Koide et al. 2005) by hydrolyzing cellulose (Osono et al. 2003) while Basidiomycota are considered to be prevalent in the later stages of plant litter decomposition (Osono 2007). Cordycipitaceae belong to the order Hypocreales (Sung et al. 2007) and members of this family are mainly associated with arthropods (Chen et al. 2019), plants (Avery et al. 2011), etc. In particular, some genera such as Akanthomyces Lebert and LecanicilliumW. Gams, H.C. Evans & Zare have been applied as biopesticides because of their well-known entomopathogenecity (Goettel et al. 2008, Helaly et al. 2017) and their inhibitory activity against fungal plant pathogens (Ownley et al. 2010). In this context, the production of cuticle-degrading enzymes has been the subject of many studies (Ali & Moharram 2014; Gandarilla-Pacheco et al. 2015). However, the ability of these fungi to produce plant litter-degrading enzymes has been rarely investigated. The main goal of this study was to evaluate the production of plant litter-degrading enzymes in fungi associated with insects collected from citrus plantations in Guilan province. This study can improve our knowledge about the enzymatic activities of fungi which is important for understanding their role in soil and forest ecosystems.
MATERIALS AND METHODS
Isolation and Identification of Fungi Plant sucking insects (scales and aphids) infested with fungi were collected from citrus orchards (sweet orange, sour orange, mandarin) and transformed to the laboratory. Insects’ exoskeleton was disinfected using 1 % sodium hypochlorite for three min and then thoroughly rinsed with distilled water. Afterward, the exoskeleton was smashed and small parts were cultivated in potato dextrose agar (PDA). The plates were incubated at 25 °C in a 12:12 light-dark regime. In samples with fungal structures, the direct culturing method was applied for isolation (Stone et al. 2004). In these cases, a small piece of mycelium or conidial mass on the top of insect bodies was removed using a sterile needle and transferred to or streaked out on agar containing media. After five days of incubation, growing colonies were sub-cultured by transferring a small piece of mycelia to a new PDA medium and incubated at the same conditions for three days. Finally, the hyphal tip technique was used to obtain pure cultures. All cultures were kept at 4 °C for further studies. The fungal strains were identified based on their morphological (Zare & Gams 2004, 2008) as well as molecular features including growth rate, characteristics of the colonies such as shape, color, and pigment production (on PDA medium), the structure of conidia, conidiophore branches, phialides and crystal formation (on PCA medium) that have been already described in Armand (2020). Twelve representative strains were deposited in the Fungal Collection of the Iranian Research Institute of Plant Protection, Iran (refer to Armand 2020 for further information).
Enzymatic screening Cellulolytic and pectinolytic activities were evaluated using the MEA medium (30 g of malt extract with 20 g of agar in 1 L H2O) amended separately with either 7.5 g carboxymethyl cellulose (CMC), 7.5 g cellobiose (CEL), 5 g Avicel (AVL) and 5 g pectic acid (PGA) per liter. CMC, cellobiose, AVL and PGA were considered as indicators of Endo-1,4-β-glucanases (CM-cellulase, endoglucanae and endocellulase), β-Glucosidases and Cellobiodydrolase (exocellobiohydrolase, exocellulase and Avicelase) and pectinases, respectively. Seven-day-old mycelia were transferred to the medium and kept at room temperature for three weeks. To estimate the enzyme activity, 15 ml of Congo Red (1 mg ml-1) was poured into the medium as an indicator. Subsequently, petri dishes were gently shaken for 15 min and finally rinsed with distilled water. Thereafter, 30 ml of 1 M NaCl were added (Pointing 1990). The ligninolytic activity was also measured using the mentioned medium amended with 0.1 % wt/vol 2,2′--Azino-bis 3-ethylbenzothiazoline-6-sulfonic acid di-ammonium salt (ABTS). Seven-day-old mycelia were transferred to the medium, kept at room temperature for three weeks, and checked daily (Masigol et al. 2019). The results were considered positive (production of laccases) when the area around the colonies turned blue. Removal of color from the medium by 0-33, 33-66 and 66-100% in all tested plates were detected as weak, medium and strong reactions, respectively (Masigol et al. 2019). This considers the different growth rates of the tested strains for the five different substrates to cluster the strains by using hierarchical cluster analysis in SPSS 16.0 according to the Ward method (Ward 1963).
RESULTS
Considering all five substrates testing for Endo-1,4-β-glucanase, β-Glucosidase, Cellobiodydrolase, pectinase and laccase activities of the fungal strains, nearly 35.52 % of all strains did not show any positive reactions. In addition, 35.52 %, 1.52 %, 6.57 %, 9.21 % and 2.63 % of the strains revealed one, two, three, four and five positive reactions, respectively. Based on the hierarchical clustering analysis of five enzymatic activities, the strains were placed in two clades. One clade, mainly consists of A. lecanii and Akanthomyces sp. strains, while the other contains A. muscarius with some minor exceptions (Fig.1a). About 71 %, 76 % and 86 % of all strains did not reveal any cellulo-, pectino- and lignolytic activities, respectively. On average, 13 %, 5 %, and 11 % of the strains showed high, medium and low cellulolytic activity, respectively. In addition, high, medium and low pectinase activity was observed in 9 %, 3 %, and 12 % of the tested strains, respectively. Only 7.89 %, 2.63 %, and 3.94 % of the strains showed a low, medium and high ligninolytic activity, respectively (Fig. 1b). A Venn diagram (Fig. 1c) shows all possible logical combinations between different enzymes. Regarding cellulolytic activity, 12 strains (nearly 16 %) produced Endo-1,4-β-glucanase, β-Glucosidase as well as Cellobiodydrolase, including O1103-1, R128-1, R128-2 and Sh901-3 strains with strong activities for all mentioned enzymes. In addition, two strains including F901-2 and 243 were able to produce cellulolytic enzymes, pectinase as well as laccase (Fig. 1c). Interestingly, A. muscarius and A. lecanii showed different enzymatic activities (Fig. 1d). In general, the enzymatic diversity of A. muscarius strains were higher than A. lecanii strains. To illustrate, nearly 60% of A. muscarius strains showed positive activities in at least three cultures amended with the abovementioned substrates. For instance, A. muscarius strain F901-2 showed enzymatic activities in all five cultures amended with ABTS, AVL, CEL, CMC, and PGA. In contrast, 46 % of A. lecanii strains showed no enzymatic activities at all.
Fig 1. Enzymatic profiling for Endo-1,4-β-glucanase, β-Glucosidase, Cellobiodydrolase, pectinase and laccase activities and the dendrogram inferred from hierarchical cluster analysis of 76 Akanthomyces strains isolated from Guilan, Iran. Positive degradation activities are shown on a semi-quantitative scale: white represents no activity, whereas light to dark green squares represent low, medium and high activities, respectively (a). Composition of enzymatic activities (b). A Venn diagram showing overlapping enzymatic activities with respect to all tested strains in this study (c). The enzymatic ability of A. muscarius and A. lecanii (d) (ABTS: Azino-bis 3-ethylbenzothiazoline-6-sulfonic acid diammonium salt, AVL: Avicel, CMC: Carboxymethyl cellulose, CEL: Cellobiose and PGA: Polygalacturonase A).
DISCUSSION
In this study, the majority of our strains did not show any activities for the tested enzymes (Fig. 1b). We showed that even though the isolated fungi are usually associated with insects, some isolates were also able to produce enzymes to degrade plant litter. Fungal strains from insects have been previously tested for their high chitinase potential (Charnley & Leger 1991, Charnley 2003, Charnley & Collins 2007), therefore, the focus of this study was to analyze the activity of cellulolytic- ligninolytic and pectinolytic enzymes.
The findings of this study are interesting from a taxonomic point of view since A. muscarius and A. lecanii species were generally differentiated by analyzing their enzymatic abilities (Fig. 1a). This differentiation is promising because there has been confusion over species delineation in the members of Cordycipitaceae, leaving morphological characters unreliable to distinguish a natural taxonomic group (Hodge et al. 2005). Therefore, a combination of morphological, molecular as well as ecological characterizations seems to offer an effective approach to overcome difficulties in species identifications.
In this study, we evaluated the capacity of Akanthomyces spp. and one Lecanicillium sp. associated with dead insect bodies for production of cellulo-, ligno- and pectinolytic enzymes (Fig. 1). Based on the results, no basidiomycetes were isolated. This result is generally in accordance with our current knowledge, i.e., a dominance of Ascomycota and Entomophthoromycota associated with insects, since until now only three genera from basidiomycetes have been reported to infect insects (Araújo & Hughes 2016). The fact that Entomophthoromycota usually grows slowly might explain why we could not isolate any of these members. In this study, the fungal strains were found on dead insects in citrus plantations which might indicate the tight association of these fungi with chitin-based substrates. In fact, Cordycipitaceae (including the genus Akanthomyces) are generally considered as entomopathogens (Chiriví-Salomón et al. 2015, Vinit et al. 2018) with a high ability to produce chitinases (Ali et al. 2011, Wang et al. 2012), making them perfect targets for biocontrol approaches (Ali et al. 2009, Wu et al. 2010). Aside from their entomopathogenic affinities, producing enzymes involved in plant litter degradation by the obtained strains is a matter of interest. The fact that insects collected in our study are all plant suckers and Akanthomyces species have been previously reported as common plant endophytes (Vega 2018, Vinit et al. 2018), might suggest they could constantly move from plant hosts to the insects’ body and contribute to their digestion processes.
In addition to their enzymatic properties, other potential applications of Akanthomyces species should not be ignored. Several strains have shown antimicrobial activity against several human bacterial pathogens (Staphylococcus aureus and Cryptococcus neoformans) (Kuephadungphan et al. 2014). Wagenaar et al. (2002) also introduced a new antibiotic called Akanthomycin from A. gracilis. Moreover, they have been accepted as a rich source for a wide range of bioactive secondary metabolites (Helaly et al. 2017) which calls upon scholars to elucidate their unknown diversity.
ACKNOWLEDGEMENTS
This work was financed in part by a grant from the Deputy of Research and Technology of the University of Guilan and Leibniz-Institute of Freshwater Ecology and Inland Fisheries (IGB Berlin), Department of Experimental Limnology and German Academic Exchange Service (DAAD). | ||
| مراجع | ||
|
Ali SS, Moharram AM. 2014. Biodiversity and enzymatic profile of some entomopathogenic fungi. Egyptian Academic Journal of Biological Sciences: Toxicology and Pest Control 6: 73–80.
Ali S, Huang Z, QeZang W, Ren SX. 2011. Production and regulation of extracellular proteases from the entomopathogenic fungus Metarhizium anisopliae (Cordycipitaceae; Hypocreales) in the presence of diamondback moth cuticle. Pakistan Journal of Zoology 43.
Ali S, Huang Z, Ren SX. 2009. Production and extraction of extracellular lipase from the entomopathogenic fungus Isaria fumosoroseus (Cordycipitaceae; Hypocreales). Biocontrol Science and Technology 19: 81–89.
Araújo JP, Hughes DP. 2016. Diversity of entomopathogenic fungi: which groups conquered the insect body? pp. 1–39. In: Advances in genetics (Augustyniuk-Kram, A., & Kram, K.J., eds). Academic Press, Boston.
Armand AR. 2020. The evolutionary structure of Lecanicillium spp. and comparing the methods of low-cost mass production. MSc Thesis, Department of Plant Protection, Faculty of Agricultural sciences, University of Guilan, Iran.
Avery PB, Wekesa VW, Hunter WB, Hall DG, McKenzie CL, Osborne LS, Powell CA, Rogers ME. 2011. Effects of the fungus Isaria fumosorosea (Hypocreales: Cordycipitaceae) on reduced feeding and mortality of the Asian citrus psyllid, Diaphorina citri (Hemiptera: Psyllidae). Biocontrol Science and Technology 21: 1065–1078.
Charnley AK. 2003. Fungal pathogens of insects: cuticle degrading enzymes and toxins. Advances in Botanical Research 40: 241–321.
Charnley AK, Collins SA. 2007. 10 Entomopathogenic Fungi and Their Role in Pest Control. Environmental and Microbial Relationships 4:159.
Charnley AK, Leger RS. 1991. The role of cuticle-degrading enzymes in fungal pathogenesis in insects. (pp. 267–286. In: The fungal spore and disease initiation in plants and animals (Garry, T., Cole, G.T., & Hoch, H.C., eds). Springer, Boston.
Chen WH, Liu C, Han YF, Liang JD, Tian WY, Liang ZQ. 2019. Three novel insect-associated species of Simplicillium (Cordycipitaceae, Hypocreales) from Southwest China. MycoKeys 58: 83–102.
Chiriví-Salomón JS, Danies G, Restrepo S, Sanjuan T. 2015. Lecanicillium sabanense sp. nov. (Cordycipitaceae) a new fungal entomopathogen of coccids. Phytotaxa 234: 63–74.
Gandarilla-Pacheco FL, Morales-Ramos LH, del Socorro Flores-Gonzalez M, Elias-Santos M, Quintero-Zapata I. 2015. Preliminary study of the enzymatic activity of native isolates of entomopathogenic fungi from the citrus area of Mexico in solid culture media. Journal of Pure and Applied Microbiology 9: 579–585.
Goettel MS, Koike M, Kim JJ, Aiuchi D, Shinya R, Brodeur J. 2008. Potential of Lecanicillium spp. for management of insects, nematodes and plant diseases. Journal of invertebrate pathology 98: 256–261.
Helaly SE, Kuephadungphan W, Phongpaichit S, Luangsa-Ard JJ, Rukachaisirikul V, Stadler M. 2017. Five unprecedented secondary metabolites from the spider parasitic fungus Akanthomyces novoguineensis. Molecules 22: 991; doi:10.3390/ molecules22060991.
Hodge KT, Gams W, Samson RA, Korf RP, Seifert KA. 2005. Lectotypification and status of Isaria Pers.: Fr. Taxon 54:485–489.
Jensen A, Dahl S, Sherson D, Sommer B. 2006. Respiratory complaints and high sensitization rate at a rennet‐producing plant. American Journal of Industrial Medicine 49: 858–861.
Johnsen CR, Sorensen TB, Larsen AI, Secher AB, Andreasen E, Kofoed GS, Nielsen LF, Gyntelberg F. 1997. Allergy risk in an enzyme producing plant: a retrospective follow up study. Occupational and Environmental Medicine 54: 671–675.
Kikot GE, Hours RA, Alconada TM. 2009. Contribution of cell wall degrading enzymes to pathogenesis of Fusarium graminearum: a review. Journal of Basic Microbiology 49: 231–241
Koide, K., Osono, T. & Takeda, H., 2005. Colonization and lignin decomposition of Camellia japonica leaf litter by endophytic fungi. Mycoscience 46: 280–286.
Kuephadungphan W, Phongpaichit S, Luangsa-ard JJ, Rukachaisirikul V. 2014. Antimicrobial activity of invertebrate-pathogenic fungi in the genera Akanthomyces and Gibellula. Mycoscience 55: 127–133.
Leonowicz A, Matuszewska A, Luterek J, Ziegenhagen D, Wojtaś-Wasilewska M, Cho NS, Hofrichter M, Rogalski J. 1999. Biodegradation of lignin by white rot fungi. Fungal Genetics and Biology 27: 175–185.
Loureiro G, Tavares B, Pereira C, Lundberg M, Chieira C. 2009. Occupational allergy to fungal lipase in the pharmaceutical industry. Journal of Investigational Allergology and Clinical Immunology 19: 237– 252.
Lundell TK, Mäkelä MR, Hildén K. 2010. Lignin‐modifying enzymes in filamentous basidiomycetes –ecological, functional and phylogenetic review. Journal of Basic Microbiology 50: 5–20.
Masigol H, Khodaparast SA, Woodhouse JN, Rojas‐Jimenez K, Fonvielle J, Rezakhani F, Mostowfizadeh‐Ghalamfarsa R, Neubauer D, Goldhammer T., Grossart HP. 2019. The contrasting roles of aquatic fungi and oomycetes in the degradation and transformation of polymeric organic matter. Limnology and Oceanography, 64: 2662–2678.
Osono T. 2007. Ecology of ligninolytic fungi associated with leaf litter decomposition. Ecological Research 22: 955–974.
Osono T, Fukasawa Y, Takeda H. 2003. Roles of diverse fungi in larch needle-litter decomposition. Mycologia 95: 820–826.
Ownley BH, Gwinn KD, Vega FE. 2010. Endophytic fungal entomopathogens with activity against plant pathogens: ecology and evolution. BioControl 55: 113–128.
Park HS, Jun SC, Han KH, Hong SB, Yu JH. 2017. Diversity, application, and synthetic biology of industrially important Aspergillus fungi. Advances in applied microbiology 100: 161–202.
Pointing SB. 1999. Qualitative methods for the determination of lignocellulolytic enzyme production by tropical fungi. Fungal Diversity 2: 17–33
Sánchez C. 2009. Lignocellulosic residues: biodegradation and bioconversion by fungi. Biotechnology Advances 27: 185–194.
Stone JK, Polishook JD, White JF. 2004. Endophytic fungi. pp. 241-270. In: Biodiversity of Fungi, Inventory and Monitoring Methods (Mueller, G.M., Bills, G.F. & Foster, M.S., eds.). Elsevier Academic Press, Burlington.
Strong PJ, Claus H. 2011. Laccase: a review of its past and its future in bioremediation. Critical Reviews in Environmental Science and Technology 41: 373–434.
Sung GH, Hywel-Jones NL, Sung JM, Luangsa-ard JJ, Shrestha B, Spatafora JW. 2007. Phylogenetic classification of Cordyceps and the clavicipitaceous fungi. Studies in Mycology 57: 5–59.
Vega FE. 2018. The use of fungal entomopathogens as endophytes in biological control: a review. Mycologia 110: 4–30.
Vinit K, Doilom M, Wanasinghe DN, Bhat DJ, Brahmanage RS, Jeewon R, Xiao Y, Hyde KD. 2018. Phylogenetic placement of Akanthomyces muscarius, a new endophyte record from Nypafruticans in Thailand. Current Research in Environmental & Applied Mycology 8: 404–417.
Wagenaar MM, Gibson DM, Clardy J. 2002. Akanthomycin, a new antibiotic pyridone from the entomopathogenic fungus Akanthomyces gracilis. Organic Letters 4: 671–673.
Wang Z, Ali S, Huang Z, Ren S. 2012. Production and regulation of extracellular chitinase by Aschersoniaaleyrodis (Cordycipitaceae: Hypocre- ales). Pakistan Journal of Zoology 44: 1255-1260. Ward Jr JH. 1963. Hierarchical grouping to optimize an objective function. Journal of the American Statistical Association 58: 236–244.
Wilson DB. 2009. Cellulases and biofuels. Current Opinion in Biotechnology 20: 295–299.
Witayakran S, Ragauskas AJ. 2009. Modification of high-lignin softwood kraft pulp with laccase and amino acids. Enzyme and Microbial Technology 44: 176–181.
Wu JH, Ali S, Ren SX. 2010. Evaluation of chitinase from Metarhizium anisopliae as biopesticide against Plutella xylostella. Pakistan Journal of Zoology 42: 521–528.
Yoon JJ, Kim YK. 2005. Degradation of crystalline cellulose by the brown-rot basidiomycete Fomitopsis palustris. The Journal of Microbiology 43: 487–492.
Zare R, Gams W. 2004. A monograph of Verticillium section Prostrata, Rostaniha supplement. Plant Pests and Diseases Research Institute, Tehran, Iran.
Zare R, Gams W. 2008. A revision of the Verticillium fungicola species complex and its affinity with the genus Lecanicillium. Mycological Research 112: 811–824. | ||
|
آمار تعداد مشاهده مقاله: 609 تعداد دریافت فایل اصل مقاله: 442 |
||