Endophytes: An Overview
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Endophytic bacteria are those that live inside of plants for at least some of the plant's life cycle but do not cause any outwardly apparent symptoms of the disease. In light of the fact that endophytes are a source of phytochemicals of high value, it is essential to bioprospect these microorganisms in order to find a wide variety of related phytochemicals that have some sort of therapeutic effect. Plant endophytes can stimulate plant growth in a number of different ways, including fixing atmospheric nitrogen, creating phytohormones, preventing the spread of phytopathogens, and improving mineral uptake. Endophytes possess different types of bioactivity, such as antibacterial, anticancer, antifungul and antiviral agents.
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References
- [1]. Owen, N. L., & Hundley, N. (2004). Endophytes—the chemical synthesizers inside plants. Science progress, 87(2), 79-99.
- [2]. Guerre, P. (2015). Ergot alkaloids produced by endophytic fungi of the genus Epichloë. Toxins, 7(3), 773-790.
- [3]. Takach, J. E., Mittal, S., Swoboda, G. A., Bright, S. K., Trammell, M. A., Hopkins, A. A., & Young, C. A. (2012). Genotypic and chemotypic diversity of Neotyphodium endophytes in tall fescue from Greece. Applied and environmental microbiology, 78(16), 5501-5510.
- [4]. Dutta, D., Puzari, K. C., Gogoi, R., & Dutta, P. (2014). Endophytes: exploitation as a tool in plant protection. Brazilian archives of Biology and Technology, 57, 621-629.
- [5]. Harman, G., Khadka, R., Doni, F., & Uphoff, N. (2021). Benefits to plant health and productivity from enhancing plant microbial symbionts. Frontiers in Plant Science, 11, 610065.
- [6]. Mishra, S., Singh, A., Keswani, C., Saxena, A., Sarma, B. K., & Singh, H. B. (2015). Harnessing plant-microbe interactions for enhanced protection against phytopathogens. Plant microbes symbiosis: applied facets, 111-125.
- [7]. Stone, J. K., Polishook, J. D., & White, J. F. (2004). Endophytic fungi. Biodiversity of fungi: inventory and monitoring methods, 241, 270.
- [8]. Sieber, T. N. (2007). Endophytic fungi in forest trees: are they mutualists?. Fungal biology reviews, 21(2-3), 75-89.
- [9]. Hallmann, J. (2001). Endophytic Bacteria. Biotic interactions in plant–pathogen associations, 87.
- [10]. Mano, H., & Morisaki, H. (2008). Endophytic bacteria in the rice plant. Microbes and environments, 23(2), 109-117.
- [11]. Singh, M., Kumar, A., Singh, R., & Pandey, K. D. (2017). Endophytic bacteria: a new source of bioactive compounds. 3 Biotech, 7, 1-14.
- [12]. Giauque, H., & Hawkes, C. V. (2013). Climate affects symbiotic fungal endophyte diversity and performance. American journal of botany, 100(7), 1435-1444.
- [13]. Sun, X., & Guo, L. D. (2012). Endophytic fungal diversity: review of traditional and molecular techniques. Mycology, 3(1), 65-76.
- [14]. Chowdhary, K., & Kaushik, N. (2015). Fungal endophyte diversity and bioactivity in the Indian medicinal plant Ocimum sanctum Linn. Plos one, 10(11), e0141444.
- [15]. Seabloom, E. W., Condon, B., Kinkel, L., Komatsu, K. J., Lumibao, C. Y., May, G., McCulley, R.L. & Borer, E. T. (2019). Effects of nutrient supply, herbivory, and host community on fungal endophyte diversity. Ecology, 100(9), e02758.
- [16]. Coombs, J. T., & Franco, C. M. (2003). Isolation and identification of actinobacteria from surface-sterilized wheat roots. Applied and environmental microbiology, 69(9), 5603-5608.
- [17]. Chen, J., Wang, H., & Guo, S. X. (2012). Isolation and identification of endophytic and mycorrhizal fungi from seeds and roots of Dendrobium (Orchidaceae). Mycorrhiza, 22, 297-307.
- [18]. Martinez-Klimova, E., Rodríguez-Peña, K., & Sánchez, S. (2017). Endophytes as sources of antibiotics. Biochemical pharmacology, 134, 1-17.
- [19]. Zhang, H. W., Song, Y. C., & Tan, R. X. (2006). Biology and chemistry of endophytes. Natural product reports, 23(5), 753-771.
- [20]. Yang, C. J., Zhang, X. G., Shi, G. Y., Zhao, H. Y., Chen, L., Tao, K., & Hou, T. P. (2011). Isolation and identification of endophytic bacterium W4 against tomato Botrytis cinerea and antagonistic activity stability. African journal of Microbiology research, 5(2), 131-136.
- [21]. Dutta, D., Puzari, K. C., Gogoi, R., & Dutta, P. (2014). Endophytes: exploitation as a tool in plant protection. Brazilian archives of Biology and Technology, 57, 621-629.
- [22]. Gimenez, C., Cabrera, R., Reina, M., & Gonzalez-Coloma, A. (2007). Fungal endophytes and their role in plant protection. Current Organic Chemistry, 11(8), 707-720.
- [23]. Grabka, R., d'Entremont, T. W., Adams, S. J., Walker, A. K., Tanney, J. B., Abbasi, P. A., & Ali, S. (2022). Fungal endophytes and their role in agricultural plant protection against pests and pathogens. Plants, 11(3), 384.
- [24]. Bacon, C. W., & Hinton, D. M. (2007). Isolation, in planta detection, and uses of endophytic bacteria for plant protection. Manual of environmental microbiology, 638-651.
- [25]. Redman, R. S., Freeman, S., Clifton, D. R., Morrel, J., Brown, G., & Rodriguez, R. J. (1999). Biochemical analysis of plant protection afforded by a nonpathogenic endophytic mutant of Colletotrichum magna. Plant Physiology, 119(2), 795-804.
- [26]. Hallmann, J., Quadt-Hallmann, A., Mahaffee, W. F., & Kloepper, J. W. (1997). Bacterial endophytes in agricultural crops. Canadian journal of microbiology, 43(10), 895-914.
- [27]. Sahoo, S., Sarangi, S., & Kerry, R. G. (2017). Bioprospecting of endophytes for agricultural and environmental sustainability. Microbial Biotechnology: Volume 1. Applications in Agriculture and Environment, 429-458.
- [28]. Rosenblueth, M., & Martínez-Romero, E. (2006). Bacterial endophytes and their interactions with hosts. Molecular plant-microbe interactions, 19(8), 827-837.
- [29]. Hardoim, P. R., van Overbeek, L. S., & van Elsas, J. D. (2008). Properties of bacterial endophytes and their proposed role in plant growth. Trends in microbiology, 16(10), 463-471.
- [30]. Malfanova, N., Lugtenberg, B. J., & Berg, G. (2013). Bacterial endophytes: who and where, and what are they doing there?. Molecular microbial ecology of the rhizosphere, 1, 391-403.
- [31]. Kobayashi, D. Y., & Palumbo, J. D. (2000). Bacterial endophytes and their effects on plants and uses in agriculture. In Microbial endophytes (pp. 213-250). CRC Press.
- [32]. Quadt-Hallmann, A. N. D. R. E. A., Kloepper, J. W., & Benhamou, N. (1997). Bacterial endophytes in cotton: mechanisms of entering the plant. Canadian journal of microbiology, 43(6), 577-582.
- [33]. Santoyo, G., Moreno-Hagelsieb, G., del Carmen Orozco-Mosqueda, M., & Glick, B. R. (2016). Plant growth-promoting bacterial endophytes. Microbiological research, 183, 92-99.
- [34]. Rashid, S., Charles, T. C., & Glick, B. R. (2012). Isolation and characterization of new plant growth-promoting bacterial endophytes. Applied soil ecology, 61, 217-224.
- [35]. Bakhtiyarifar, M., Enayatizamir, N., & Mehdi Khanlou, K. (2021). Biochemical and molecular investigation of non-rhizobial endophytic bacteria as potential biofertilisers. Archives of Microbiology, 203, 513-521.
- [36]. Dhole, A., Shelat, H., Vyas, R., Jhala, Y., & Bhange, M. (2016). Endophytic occupation of legume root nodules by nif H-positive non-rhizobial bacteria, and their efficacy in the groundnut (Arachis hypogaea). Annals of Microbiology, 66, 1397-1407.
- [37]. Tariq, M., Hameed, S., Yasmeen, T., Zahid, M., & Zafar, M. (2014). Molecular characterization and identification of plant growth promoting endophytic bacteria isolated from the root nodules of pea (Pisum sativum L.). World journal of microbiology and biotechnology, 30(2), 719-725.
- [38]. Joseph, B., & Priya, R. M. (2011). Bioactive Compounds from Endophytes and their Potential in. Am. J. Biochem. Mol. Biol, 1(3), 291-309.
- [39]. Strobel, G. A. (2003). Endophytes as sources of bioactive products. Microbes and infection, 5(6), 535-544.
- [40]. Sharma, A., Malhotra, B., Kharkwal, H., Kulkarni, G. T., & Kaushik, N. (2020). Therapeutic agents from endophytes harbored in Asian medicinal plants. Phytochemistry Reviews, 19, 691-720.
- [41]. Adeleke, B. S., & Babalola, O. O. (2021). The plant endosphere-hidden treasures: A review of fungal endophytes. Biotechnology and Genetic Engineering Reviews, 37(2), 154-177.
- [42]. Jamwal, V. L., & Gandhi, S. G. (2019). Endophytes as a source of High-value phytochemicals: Present scenario and future outlook. Endophytes Second. Metabolites Reference Ser. Phytochemistry, 571-590.
- [43]. Venugopalan, A., & Srivastava, S. (2015). Endophytes as in vitro production platforms of high value plant secondary metabolites. Biotechnology advances, 33(6), 873-887.
- [44]. Bazghaleh, N., Hamel, C., Gan, Y., Knight, J. D., Vujanovic, V., Cruz, A. F., & Ishii, T. (2016). Phytochemicals induced in chickpea roots selectively and non-selectively stimulate and suppress fungal endophytes and pathogens. Plant and Soil, 409, 479-493.
- [45]. Mohinudeen, K., Devan, K., & Srivastava, S. (2019). Bioprocessing of endophytes for production of high-value biochemicals. Secondary Metabolites of Plant Growth Promoting Rhizomicroorganisms: Discovery and Applications, 353-390.
- [46]. Ayob, F. W., Mohamad, J., & Simarani, K. (2019). Antioxidants and phytochemical analysis of endophytic fungi isolated from a medicinal plant Catharanthus roseus. Borneo J. Sci. Technol, 1, 62-68.
- [47]. Singh, N. A., & Jain, R. (2022). Diversity and Bioactive Potential of Endophytic Bacteria from High-Value Medicinal Plants. In Bacterial Endophytes for Sustainable Agriculture and Environmental Management (pp. 45-69). Singapore: Springer Singapore.
- [48]. Khiralla, A. (2015). Phytochemical study, cytotoxic and antibacterial potentialities of endophytic fungi from medicinal plants from Sudan. Université de Lorraine.
- [49]. Basit, A., Shah, S. T., Ullah, I., Ullah, I., & Mohamed, H. I. (2021). Microbial bioactive compounds produced by endophytes (bacteria and fungi) and their uses in plant health. Plant Growth-Promoting Microbes for Sustainable Biotic and Abiotic Stress Management, 285-318.
- [50]. Li, Z., Wen, W., Qin, M., He, Y., Xu, D., & Li, L. (2022). Biosynthetic mechanisms of secondary metabolites promoted by the interaction between endophytes and plant hosts. Frontiers in Microbiology, 2584.
- [51]. Cetin, M., Sevik, H., Yigit, N., Ozel, H. B., Aricak, B., & Varol, T. (2018). The variable of leaf micromorphogical characters on grown in distinct climate conditions in some landscape plants. Fresenius Environmental Bulletin, 27(5), 3206-3211.
- [52]. Cetin, M., Sevik, H., Yigit, N., Ozel, H. B., Aricak, B., & Varol, T. (2018). The variable of leaf micromorphogical characters on grown in distinct climate conditions in some landscape plants. Fresenius Environmental Bulletin, 27(5), 3206-3211.
- [53]. Velásquez, A. C., Castroverde, C. D. M., & He, S. Y. (2018). Plant–pathogen warfare under changing climate conditions. Current biology, 28(10), R619-R634.
- [54]. Newman, D. J., & Cragg, G. M. (2020). Plant endophytes and epiphytes: Burgeoning sources of known and "unknown" cytotoxic and antibiotic agents?. Planta medica, 86(13/14), 891-905.
- [55]. Zhang, Z. B., Zeng, Q. G., Yan, R. M., Wang, Y., Zou, Z. R., & Zhu, D. (2011). Endophytic fungus Cladosporium cladosporioides LF70 from Huperzia serrata produces Huperzine A. World Journal of Microbiology and Biotechnology, 27, 479-486.
- [56]. Guerram, M., JIANG, Z. Z., & Zhang, L. Y. (2012). Podophyllotoxin, a medicinal agent of plant origin: past, present and future. Chinese Journal of Natural Medicines, 10(3), 161-169.