1 A Review of Endophytic Microbiota of Medicinal Plants and Their Antimicrobial Properties

       Robeena Sarah, Nida Idrees, and Baby Tabassum

       Toxicology Laboratory, Department of Zoology, Govt. Raza P.G. College, Rampur 244901, India

      1.1 Introduction

Medicinal plants have been used in many parts of the world for thousands of years in traditional treatments for numerous diseases. In rural areas of developing countries, they are still used as a primary source of drugs [1]. About 80% of developing countries use conventional medicines for general health care [2]. Natural products can be obtained from medicinal plants that have proven to be a rich source of biologically active compounds; many of them are used to develop novel chemicals for the pharmaceutical industry. With regard to disease-causing microorganisms, the increasing resistance to therapeutic agents currently in use, such as antibiotics and antiviral agents, has led to renewed interest in exploring novel anti-infective compounds. As approximately 450,000 plant species are available worldwide, of which only one per cent has been phytochemically analyzed, the prospects of locating new bioactive compounds are tremendously positive.

      Medicinal plants are essentially considered complex and dynamic when used in systems for remedial therapy. Hence, their chemical composition depends upon several factors, such as botanical species, genetically determined chemotypes, anatomically a part of the plant (e.g., seed, flower, root, and leaf), storage, sun exposure, humidity, kind of ground, time of harvesting, and ecological area. Moreover, biogenic factors, such as the fungal and bacterial endophytes related to diverse parts of the plant, can influence their chemical composition. In recent years, the research and study of the multiple interactions occurring between endophytes and medicinal plants have modernized our knowledge of plant biology, with entirely unexpected and remarkable application perspectives: the probability of modulating, amplifying, or interfering within the biosynthesis of phytoconstituents (e.g., terpenes, polyphenols, and alkamides), but also to engineer the synthesis of latest molecules directly, for instance with antibiotic activity.

      1.2 Antimicrobial Properties of Medicinal Plants with Particular Reference to Neem (Azadirachtaindica)

There are many reports on conventional medicinal plants and natural products to treat several diseases. Many plant-based medicines utilized in traditional therapeutic systems as agents in the treatment of infectious diseases are recorded in pharmacopoeia, a variety of which have been investigated recently for their efficiency against disease-causing microorganisms. The general antimicrobial activities of medicinal plants and their products, such as essential oils, were analyzed earlier [3,4].

      Moreover, medicinal plants also can play an elementary function against rising antibiotic resistance both directly for their antimicrobial activities (e.g., antibacterial, antiviral, antifungal, and antiparasitic ones) and indirectly by reducing resistance against antibiotics.

There are numerous medicinal plants with well-known antimicrobial activity, including traditional Chinese or Ayurvedic medicine. Among medicinal plants adopted in experimental studies, a classic example is the Azadirachta indica (Figure 1.1) commonly known as neem, an evergreen tree of the sub-tropics and tropics, indigenous to the Indian subcontinent, with a recognized ethnomedicinal value and significance in agriculture and also in the pharmaceutical industry [5]. Every part of the neem plant, such as leaves, fruits, seeds, bark, and roots, contains compounds with proven antioxidant, anti-inflammatory [6], antidiabetic, antibacterial, antigingivitic, antifungal, anticancer, antiviral, antiulcer, neuroprotective, antipyretic, hepatoprotective, nephroprotective, and wound-healing properties. It possesses incredible potential within the field of medicine, pest management, and environmental protection. Neem may be a natural source of eco-friendly herbal pesticides, insecticides, and agro-based chemicals [7]. The impact of mouthwash containing neem on plaque and gingivitis was analyzed in a clinical study, indicating that it may help maintain mouth hygiene and suggest an enhanced effect on preventing oral diseases since it is both cost-effective and easily accessible [8]. Approximately 400 compounds are isolated from various parts of neem until now, and significant bioactive secondary metabolites and relatively 30 compounds are isolated from endophytes of neem [5]. Endophytic fungi of neem produce a wide range of secondary bioactive metabolites with potential compounds, namely, melanin, antimicrobial, antioxidant, anti-inflammatory, insecticides, nematicides, etc. [5].