Novel Insights into the Biochemical Mechanism of CK1ε and its Functional Interplay with DDX3X

Casein Kinase 1 epsilon (CK1ε) is a member of the serine (Ser)/threonine (Thr) CK1 family, known to have crucial roles in several biological scenarios and, ever more frequently, in pathological contexts, such as cancer. Recently, the human DEAD-box RNA helicase 3 X-linked (DDX3X), involved in cancer proliferation and viral infections, has been identified as one of CK1ε substrates and its positive regulator in the Wnt/β-catenin network. However, the way by which these two proteins influence each other has not been fully clarified. In order to further investigate their interplay, we defined the kinetic parameters of CK1ε towards its substrates: ATP, casein, Dvl2 and DDX3X. CK1ε affinity for ATP depends on the nature of the substrate: increasing of casein concentrations led to an increase of KmATP, while increasing DDX3X reduced it. In literature, DDX3X is described to act as an allosteric activator of CK1ε. However, when we performed kinase reactions combining DDX3X and casein, we did not find a positive effect of DDX3X on casein phosphorylation by CK1ε, while both substrates were phosphorylated in a competitive manner. Moreover, CK1ε positively stimulates DDX3X ATPase activity. Our data provide a more detailed kinetic characterization on the functional interplay of these two proteins.

Altered Affective Behaviors in Casein Kinase 1 Epsilon Mutant Mice

Affective behaviors and mental health are profoundly affected by disturbances in circadian rhythms. Casein kinase 1 epsilon (CSNK1E) is an essential component of the core circadian clock. Mice with tau or null mutation of this gene have shortened and lengthened circadian period respectively. Here we examined anxiety-like, fear, and depressive-like behaviors in both male and female mice of these two different mutants. Compared with wild-type mice, we found reductions in fear and anxiety-like behaviors in both mutant lines and in both sexes, with the tau mutants exhibiting the greatest phenotypic changes. However, the depressive-like behaviors had distinct phenotypic patterns, with markedly less depressive-like behaviors in female null mutants, but not in tau mutants of either sex. To determine whether abnormal light entrainment of tau mutants to 24 hour light-dark cycles contributes to these phenotypic differences, we also examined these behaviors in tau mutants on a 20 hour light-dark cycle close to their endogenous circadian period. The normalized entrainment restored more wild-type-like behaviors for fear and anxiety, but it induced depressive-like behavior in tau mutant females. These data show that both mutations of Csnk1e broadly affect fear and anxiety-like behaviors, while the effects on depressive-like behavior vary with genetics, photoperiod, and sex, suggesting that the mechanisms by which Csnk1e affects fear and anxiety-like behaviors may be similar, but distinct from those affecting depressive-like behavior. Our study also provides experimental evidence in support of the hypothesis of beneficial outcomes from properly entrained circadian rhythms in terms of the anxiety-like and fear behaviors.

Altered Body Weight Regulation in CK1ε Null and tau Mutant Mice on Regular Chow and High Fat Diets

Disruption of circadian rhythms results in metabolic dysfunction. Casein kinase 1 epsilon (CK1ε) is a canonical circadian clock gene. Null and tau mutations in CK1ε show distinct effects on circadian period. To investigate the role of CK1ε in body weight regulation under both regular chow (RC) and high fat (HF) diet conditions, we examined body weight on both RC and HF diets in CK1ε-/- and CK1εtau/tau mice on a standard 24 hr light-dark (LD) cycle. Given the abnormal entrainment of CK1εtau/tau mice on a 24 hr LD cycle, a separate set of CK1εtau/tau mice were tested under both diet conditions on a 20 hr LD cycle, which more closely matches their endogenous period length. On the RC diet, both CK1ε-/- and CK1εtau/tau mutants on a 24 hr LD cycle and CK1εtau/tau mice on a 20 hr LD cycle exhibited significantly lower body weights, despite similar overall food intake and activity levels. On the HF diet, CK1εtau/tau mice on a 20 hr LD cycle were protected against the development of HF diet-induced excess weight gain. These results provide additional evidence supporting a link between circadian rhythms and energy regulation at the genetic level, particularly highlighting CK1ε involved in the integration of circadian biology and metabolic physiology.