Abstract
Accurate selection of reference genes is crucial for reliable gene expression analysis in plants. Traditional reference genes, such as GAPDH and ACT, are widely used but often show variable stability under different conditions, stresses, tissue types, and developmental stages. Recent advances in multi-omics technologies, including transcriptomics, offer new approaches for improving reference gene selection. These methods allow for the integration of diverse datasets to identify genes with stable expression across various environmental stresses and developmental stages, providing more robust and context-specific normalization controls. High-throughput sequencing technologies, such as RNA-seq, have enabled the large-scale identification of stable reference genes, and further enhanced this process by correlating gene expression at the transcript level. Additionally, the application of computational tools helps researchers optimize reference gene selection, making the process more efficient and standardized. Personalized and condition-specific reference gene databases are emerging as valuable resources for selecting the most appropriate genes based on experimental conditions. This paper explores the current trends and challenges in reference to reference gene selection and the potential of a transcriptomics approach to address these challenges. The use of these advanced methods will increase the accuracy and reliability of plant gene expression studies, accelerate discoveries in crop improvement and stress resilience in plant biology and agricultural sciences.