Inosine Triphosphate Pyrophosphatase (ITPase): Functions, Mutations, Polymorphisms and Its Impact on Cancer Therapies.
Mazin Abdulaziz ZamzamiPublished in: Cells (2022)
Inosine triphosphate pyrophosphatase (ITPase) is an enzyme encoded by the ITPA gene and functions to prevent the incorporation of noncanonical purine nucleotides into DNA and RNA. Specifically, the ITPase catalyzed the hydrolysis of (deoxy) nucleoside triphosphates ((d) NTPs) into the corresponding nucleoside monophosphate with the concomitant release of pyrophosphate. Recently, thiopurine drug metabolites such as azathioprine have been included in the lists of ITPase substrates. Interestingly, inosine or xanthosine triphosphate (ITP/XTP) and their deoxy analogs, deoxy inosine or xanthosine triphosphate (dITP/dXTP), are products of important biological reactions such as deamination that take place within the cellular compartments. However, the incorporation of ITP/XTP, dITP/dXTP, or the genetic deficiency or polymorphism of the ITPA gene have been implicated in many human diseases, including infantile epileptic encephalopathy, early onset of tuberculosis, and the responsiveness of patients to cancer therapy. This review provides an up-to-date report on the ITPase enzyme, including information regarding its discovery, analysis, and cellular localization, its implication in human diseases including cancer, and its therapeutic potential, amongst others.
Keyphrases
- early onset
- endothelial cells
- papillary thyroid
- cancer therapy
- genome wide
- end stage renal disease
- copy number
- late onset
- chronic kidney disease
- squamous cell
- ejection fraction
- induced pluripotent stem cells
- mycobacterium tuberculosis
- newly diagnosed
- pluripotent stem cells
- prognostic factors
- ms ms
- drug delivery
- room temperature
- single molecule
- high throughput
- gene expression
- replacement therapy
- health information
- squamous cell carcinoma
- pulmonary tuberculosis
- patient reported outcomes
- childhood cancer
- drug induced
- ionic liquid
- transcription factor
- patient reported
- smoking cessation
- molecular dynamics simulations