Evolutionary divergence of nocturnin led to redox regulation in mammalian orthologs

Jun 8, 2026Biochemistry and biophysics reports

How evolutionary changes in nocturnin led to redox control in mammals

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Abstract

Mammalian Nocturnin (NOCT) may function as a redox sensor that dynamically modulates NADP(H) availability in response to oxidative stress.

NADP(H) and NAD(H) are crucial cofactors for nearly 500 metabolic reactions, influencing cellular function and redox balance.
Alterations in NADP(H) regulation are linked to diseases such as neurodegenerative and cardiovascular disorders.
Mammalian NOCT undergoes a process where cysteine-mediated disulfide bond formation leads to its oligomerization and inactivation.
The reduction of these cysteines restores NOCT to its active monomeric form.
In mammals, mitochondrial NOCT primarily exhibits oligomerization, while the cytosolic environment maintains NOCT in a monomeric state.
The emergence of mitochondrial NOCT in mammals coincides with the presence of redox-sensitive cysteines, suggesting an adaptation to oxidative conditions.

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NADP(H) and NAD(H) are essential cofactors involved in nearly 500 metabolic reactions, making them fundamental to cellular function and redox homeostasis. Loss of redox homeostasis through alterations in NADP(H) regulation has been implicated in various diseases, including neurodegenerative disorders and cardiovascular diseases. The levels of these metabolites are tightly regulated and highly compartmentalized. Nocturnin (NOCT), a circadian clock-controlled phosphatase, hydrolyzes both oxidized and reduced forms of NADP(H) and exists in cytosolic and mitochondrial forms. Here, we compare the activity ofand mammalian NOCT, which reveals a novel redox-dependent regulatory mechanism in mammals. Mammalian NOCT undergoes cysteine-mediated disulfide bond formation, leading to enzyme oligomerization and inactivation, while reduction of these cysteines restores NOCT to its monomeric, active form. In contrast,NOCT lacks these regulatory cysteines, does not oligomerize, and remains constitutively active. We show that oligomerization of mammalian NOCT occurs physiologically in the mitochondria while the comparatively highly reduced environment of the cytosol keeps NOCT in its monomeric conformation. Furthermore, sequence analysis reveals that mitochondrial NOCT emerges predominantly in mammals and coincides with the acquisition of redox-sensitive cysteines, highlighting a possible adaptation to oxidative metabolic environments. These findings suggest that mammalian NOCT functions as a redox sensor, dynamically modulating NADP(H) availability in response to oxidative stress. Understanding NOCT's evolution and regulation offers new insights into NADP(H) metabolism and its broader implications for oxidative stress. Xenopus Xenopus laevis

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Evolutionary divergence of nocturnin led to redox regulation in mammalian orthologs

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