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2000
Volume 32, Issue 4
  • ISSN: 0929-8665
  • E-ISSN: 1875-5305

Abstract

Introduction/Objective

Protein phosphatases act as counterparts to protein kinases and are considered crucial for the homeostatic balance of cell signalling. In contrast to kinases, which can be categorized according to their substrate specificity, phosphatases are versatile and can detect substrates with much less distinction; hence, it is challenging to identify the physiological phosphatase-substrate pair. The Oca1 of is a putative protein tyrosine phosphatase (PTP) and is required for cell cycle arrest in response to oxidative stress. The Oca1 mutants are sensitive to mTOR inhibitors, such as caffeine and rapamycin, and are involved in the regulation of TOR function. In an earlier research work, the enzyme exhibited no phosphatase activity and it was suggested that post-translational modifications or additional factors are necessary for it to be functional.

Methods

The modeling of Oca1 was performed to gain insight into the structural aspects. The full-length enzyme, as well as the enzyme without the N-terminal extension, was cloned, expressed, and purified to homogeneity. The structure, function, and stability of the purified enzyme were assessed using circular dichroism, fluorescence, and visible spectroscopy studies.

Results

The Oca1 was expressed and purified from The enzyme has been found to be functional, stable, and exist in an extended monomeric form, with a molecular mass of about 27 kDa. The enzyme without the extended N-terminal random coil has also been functional and slightly more stable than the full-length Oca1.

Conclusion

The purified functional enzyme may be used to gain insights into the biochemical aspects and its role in bioengineering.

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2025-09-23

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/content/journals/ppl/10.2174/0109298665388367250404095840
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Expression, Purification, and Preliminary Characterization of Putative Protein Tyrosine Phosphatase Oca1
PPL 32, 235 (2025); https://doi.org/10.2174/0109298665388367250404095840
/content/journals/ppl/10.2174/0109298665388367250404095840
/content/journals/ppl/10.2174/0109298665388367250404095840
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  • Article Type:     Letter
Keyword(s): caffeine; enzyme; Oca1; phosphorylation; Protein tyrosine phosphatase; rapamycin

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