Plant secondary metabolites have a variety of functions, including mediating relationships between organisms, responding to environmental challenges, and protecting plants against infections, pests, and herbivores. In a similar way, through controlling plant metabolism, plant microbiomes take part in many of the aforementioned processes indirectly or directly. Researchers have discovered that plants may affect their microbiome by secreting a variety of metabolites, and that the microbiome could likewise affect the metabolome of the host plant. Pesticides are agrochemicals that are employed to safeguard humans and plants from numerous illnesses in urban green zones, public health initiatives, and agricultural fields. The careless use of chemical pesticides is destroying our ecology. As a result, it is necessary to investigate environmentally benign alternatives to pathogen management, such as plant-based metabolites. According to literature, plant metabolites have been shown to have the ability to battle plant pathogens. Phenolics, flavonoids, and alkaloids are a few of the secondary metabolites of plants that have been covered in this study.

The field of plant pathology has adopted targeted genome editing technology as one of its most crucial and effective genetic tools. Due to its simplicity, effectiveness, versatility, CRISPR together with CRISPR-associated proteins found in an adaptive immune system of prokaryotes have recently attracted the interest of the scientific world. Plant disease resistance must be genetically improved for sustainable agriculture. Plant biology and biotechnology have been transformed by genome editing, which makes it possible to perform precise and targeted genome modifications. Editing offers a fresh approach by genetically enhancing plant disease resistance and quickening resistance through breeding. It is simpler to plan and implement, has a greater success rate, is more adaptable and less expensive than other genome editing methods. Importantly CRISPR/Cas9 has recently surpassed plant science as well as plant disease. After years of research, scientists are currently modifying and rewriting genomes to create crop plants which are immune to particular pests and diseases. The main topics of this review are current developments in plant protection using CRISPR/Cas9 technology in model plants and commodities in response to viral, fungal, and bacterial infections, as well as potential applications and difficulties of numerous promising CRISPR/Cas9-adapted approaches.