Overview of gene expression techniques with an emphasis on vitamin D related studies

Abstract

Each cell controls when and how its genes must be expressed for proper function. Every function in a cell is driven by signaling molecules through various regulatory cascades. Different cells in a multicellular organism may express very different sets of genes, even though they contain the same DNA. The set of genes expressed in a cell determines the set of proteins and functional RNAs it contains, giving it its unique properties. Malfunction in gene expression harms the cell and can lead to the development of various disease conditions. The use of rapid high-throughput gene expression profiling unravels the complexity of human disease at various levels. Peripheral blood mononuclear cells (PBMC) have been used frequently to understand gene expression homeostasis in various disease conditions. However, more studies are required to validate whether PBMC gene expression patterns accurately reflect the expression of other cells or tissues. Vitamin D, which is responsible for a multitude of health consequences, is also an immune modulatory hormone with major biological activities in the innate and adaptive immune systems. Vitamin D exerts its diverse biological effects in target tissues by regulating gene expression and its deficiency, is recognized as a public health problem worldwide. Understanding the genetic factors that affect vitamin D has the potential benefit that it will make it easier to identify individuals who require supplementation. Different technological advances in gene expression can be used to identify and assess the severity of disease and aid in the development of novel therapeutic interventions. This review focuses on different gene expression approaches and various clinical studies of vitamin D to investigate the role of gene expression in identifying the molecular signature of the disease.

PLAIN LANGUAGE SUMMARY

Gene optimizations are essential in maintaining biological functions. Gene dysregulation results in disease progression. Advanced analytical techniques determine the link between impaired genes and disease conditions. This knowledge can be applied to design clinical trials to aid novel therapeutic interventions and disease prevention.

Keywords:

• Gene expression
• RT-PCR
• microarray
• RNA-Seq
• PBMC
• vitamin D
• clinical trial

Transparency

Declaration of funding

The authors are supported by grants from NIH/NCCIH (5R33AT010637) and the Malcolm Feist Endowed Chair in Diabetes.

Declaration of financial/other relationships

The authors have no relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript. This includes employment, consultancies, honoraria, stock ownership or options, expert testimony, grants or patents received or pending, or royalties.

Peer reviewers on this manuscript have no relevant financial or other relationships to disclose.

Acknowledgements

The authors thank Ms. Georgia Morgan for excellent editing and confirm that they are responsible for the final version submitted.