Effect of chronic exposure to ketohexoses on pancreatic ß-cell function in INS-1 rat insulinoma cells.

Glucotoxicity, impaired insulin secretion, suppression of insulin gene expression, and apoptosis, in pancreatic ß-cells caused by chronic hyperglycemia is a key component of the pathogenesis of type 2 diabetes. Recently, it has been reported that rare sugar d-allulose has antihyperglycemic and antihyperlipidemic effects in diabetic rats. However, the direct effects of rare sugars including d-allulose on pancreatic ß-cell function are unclear. In this study, we investigated whether chronic exposure to ketohexoses causes glucotoxicity, suppression of insulin gene expression, and apoptosis, in INS-1 rat pancreatic insulinoma cells. d-Fructose, d-tagatose, l-allulose, and l-sorbose treatment for 1-week reduced insulin gene expression, whereas d-allulose, d-sorbose, l-fructose, and l-tagatose did not. All ketohexoses were transported into INS-1 cells, but were not metabolized. In addition, the ketohexoses did not induce apoptosis and did not affect glucose metabolism. These results suggest that long-term administration of d-allulose, d-sorbose, l-fructose, and l-tagatose does not affect pancreatic ß-cell function.

12-O-Tetradecanoylphorbol 13-acetate promotes proliferation and epithelial-mesenchymal transition in HHUA cells cultured on collagen type I gel: A feasible model to find new therapies for endometrial diseases.

HHUA endometrial adenocarcinoma cells aggregated into spheroids when cultured on collagen type I gels. 12-O-Tetradecanoylphorbol 13-acetate, a PKC activator, disassembled the spheroids through epithelial-mesenchymal transition and increased their proliferation rate, while inducing cell death under monolayer culture conditions. These unusual behaviors of endometrial epithelial cells with collagen fibers could be a target for the treatment of some endometrial diseases.

NF90-NF45 is essential for ß cell compensation under obesity-inducing metabolic stress through suppression of p53 signaling pathway.

The Nuclear Factor 90 (NF90)-NF45 complex has been known to regulate the progression of transcription, mRNA stability, translational inhibition, RNA export and microRNA biogenesis. However, the physiological functions of the NF90-NF45 complex remain unclear. We newly discovered that the NF90-NF45 complex was expressed in primary ß cells and established cell lines. Therefore, in this study, we focused on the function of the endogenous NF90-NF45 complex in the ß cells. To investigate this issue, we generated ß-cell-specific NF90-NF45 deficient mice. These mice exhibited hyperglycaemia and lower plasma insulin levels under a high fat diet together with decreased islet mass. To uncover this mechanism, we performed a whole-genome expression microarray of the total RNA prepared from ß cell lines treated with siRNAs targeting both NF90 and NF45. In this result, we found an activation of p53 signaling in the NF90-NF45-knockdown cells. This activation was supported by elevation of luciferase activity derived from a reporter plasmid harboring p53 binding sites in the NF90-NF45-knockdown cells. Furthermore, the knockdown of NF90-NF45 resulted in a significant retardation of the ß cell line growth rates. Importantly, a dominant negative form of p53 rescues the growth retardation in BTC6 cells depleted of NF90-NF45, suggesting that NF90-NF45 would be positively involved in ß cell proliferation through suppression of p53 signal pathway. Taken together, NF90-NF45 is essential for ß cell compensation under obesity-inducing metabolic stress via repression of p53 signaling.

Analysis of protein kinases by Phos-tag SDS-PAGE.

Protein kinases regulate almost all biological processes including cell proliferation, differentiation, apoptosis, and gene expression. Dysregulation of protein phosphorylation caused by abnormal activity and expression of protein kinases results in the onset of various diseases such as cancer and metabolic syndromes. The activities of a large number of protein kinases are regulated by phosphorylation. Therefore, analysis of the phosphorylation status of protein kinases is important for elucidation of biological phenomena and the pathogenesis of diseases. To investigate protein phosphorylation, phosphate-binding tag molecule "Phos-tag" was developed. In addition, various techniques and tools using Phos-tag such as Phos-tag SDS-PAGE, have been developed for analysis and profiling of protein phosphorylation. Here, we describe the methods and analytical techniques that use Phos-tag for investigation of protein kinase phosphorylation and the applications of phosphorylation analysis. SIGNIFICANCE: Protein kinases play pivotal roles in regulating many biological processes and pathogenesis of diseases. Determination of phosphorylation status of protein kinases can provide the essential information for their activation. This review provides analytical techniques for analysis of phosphorylation status of protein kinases by Phos-tag SDS-PAGE. We believe that this review would help readers to study in kinomics research.

Na+/Ca2+ exchanger mediates cold Ca2+ signaling conserved for temperature-compensated circadian rhythms.

Circadian rhythms are based on biochemical oscillations generated by clock genes/proteins, which independently evolved in animals, fungi, plants, and cyanobacteria. Temperature compensation of the oscillation speed is a common feature of the circadian clocks, but the evolutionary-conserved mechanism has been unclear. Here, we show that Na+/Ca2+ exchanger (NCX) mediates cold-responsive Ca2+ signaling important for the temperature-compensated oscillation in mammalian cells. In response to temperature decrease, NCX elevates intracellular Ca2+, which activates Ca2+/calmodulin-dependent protein kinase II and accelerates transcriptional oscillations of clock genes. The cold-responsive Ca2+ signaling is conserved among mice, Drosophila, and Arabidopsis The mammalian cellular rhythms and Drosophila behavioral rhythms were severely attenuated by NCX inhibition, indicating essential roles of NCX in both temperature compensation and autonomous oscillation. NCX also contributes to the temperature-compensated transcriptional rhythms in cyanobacterial clock. Our results suggest that NCX-mediated Ca2+ signaling is a common mechanism underlying temperature-compensated circadian rhythms both in eukaryotes and prokaryotes.

Candidate plasticity gene 16 and jun dimerization protein 2 are involved in the suppression of insulin gene expression in rat pancreatic INS-1 ß-cells.

Chronic hyperglycemia causes pancreatic ß-cell dysfunction, impaired insulin secretion and the suppression of insulin gene expression. This phenomenon is referred to as glucotoxicity, and is a critical component of the pathogenesis of type 2 diabetes. We previously reported that the expression of candidate plasticity gene 16 (CPG16) was higher in rat pancreatic INS-1 ß-cells under glucotoxic conditions and CPG16 suppressed insulin promoter activity. However, the molecular mechanisms of the CPG16-mediated suppression of insulin gene expression are unclear. In this study, we found that CPG16 directly bound and phosphorylated jun dimerization protein 2 (JDP2), an AP-1 family transcription factor. CPG16 co-localized with JDP2 in the nucleus of INS-1 cells. JDP2 bound to the G1 element of the insulin promoter and up-regulated promoter activity. Finally, CPG16 suppressed the up-regulation of insulin promoter activity by JDP2 in a kinase activity-dependent manner. These results suggest that CPG16 suppresses insulin promoter activity by phosphorylating JDP2.

Sodium/glucose cotransporter 2 is expressed in choroid plexus epithelial cells and ependymal cells in human and mouse brains.

Diabetes mellitus (DM) is now recognized as one of the risk factors for Alzheimer's disease (AD), and the disease-modifying effects of anti-diabetic drugs on AD have recently been attracting great attention. Sodium/glucose cotransporter 2 (SGLT2) inhibitors are a new class of anti-diabetic drugs targeting the SGLT2/solute carrier family 5 member 2 (SLC5A2) protein, which is known to localize exclusively in the brush border membrane of early proximal tubules in the kidney. However, recent data suggest that it is also expressed in other tissues. In the present study, we investigated the expression of SGLT2/SLC5A2 in human and mouse brains. Immunohistochemical staining of paraffin sections from autopsied human brains and C3H/He mouse brains revealed granular cytoplasmic immunoreactivity in choroid plexus epithelial cells and ependymal cells. Immunoblot analysis of the membrane fraction of mouse choroid plexus showed distinct immunoreactive bands at 70 and 26 kDa. Band patterns around 70 kDa in the membrane fraction of the choroid plexus were different from those in the kidney. Reverse transcription-polymerase chain reaction analysis confirmed the expression of Slc5a2 mRNA in the mouse choroid plexus. Our results provide in vivo evidence that SGLT2/SLC5A2 is expressed in cells facing the cerebrospinal fluid, in addition to early proximal tubular epithelial cells. These findings suggest that SGLT2 inhibitors may have another site of action in the brain. The effects of SGLT2 inhibitors on brain function and AD progression merit further investigation to develop better treatment options for DM patients.

Evaluation of the Anti-Proliferative Activity of Rare Aldohexoses against MOLT-4F and DU-145 Human Cancer Cell Line and Structure-Activity Relationship of D-Idose.

D-Allose (D-All), a C-3 epimer of D-glucose (D-Glc), is a naturally rare monosaccharide, which shows anti-proliferative activity against several human cancer cell lines. Unlike conventional anticancer drugs, D-All targets glucose metabolism and is non-toxic to normal cells. Therefore, it has attracted attention as a unique "seed" compound for anticancer agents. However, the anti-proliferative activities of the other rare aldohexoses have not been examined yet. In this study, we evaluated the anti-proliferative activity of rare aldohexoses against human leukemia MOLT-4F and human prostate cancer DU-145 cell lines. We found that D-All and D-idose (D-Ido) at 5 mM inhibited cell proliferation of MOLT-4F cells by 46 % and 60 %, respectively. On the other hand, the rare aldohexoses at 5 mM did not show specific anti-proliferative activity against DU-145 cells. To explore the structure-activity relationship of D-Ido, we evaluated the anti-proliferative activity of D-sorbose (D-Sor), 6-deoxy-D-Ido, and L-xylose (L-Xyl) against MOLT-4F cells and found that D-Sor, 6-deoxy-D-Ido, and L-Xyl showed no inhibitory activity at 5 mM, suggesting that the aldose structure and the C-6 hydroxy group of D-Ido are important for its activity. Cellular glucose uptake assay and western blotting analysis of thioredoxin-interacting protein (TXNIP) expression suggested that the anti-proliferative activity of D-Ido is induced by inhibition of glucose uptake via TXNIP-independent pathway.

Development of a d-allose-6-phosphate derivative with anti-proliferative activity against a human leukemia MOLT-4F cell line.

d-Allose, a C-3 epimer of d-glucose, is a naturally occurring rare monosaccharide that shows anti-proliferative activity against several human cancer cell lines. However, d-allose requires a relatively high concentration for the activity to be observed. Thus, developing more potent derivatives is needed for application. In cells, d-allose is converted to d-allose-6-phosphate (A6P), which is responsible for the anti-proliferative activity of d-allose. In this study, we synthesized A6P derivative 1 with biodegradable protecting groups, which showed higher anti-proliferative activity than A6P against a MOLT-4F human leukemia cell line. Similarly protected derivative of d-glucose-6-phosphate (G6P) (2) and tetraacetyl-A6P (3) showed weaker and less activity compared with 1, respectively, suggesting that both A6P moiety and the protecting group on the phosphate group are responsible for the activity. In addition, significantly weaker induction of thioredoxin-interacting protein (TXNIP) expression by 1 compared with d-allose suggests that 1 exhibited cytotoxicity through the synergetic effect of inducing TXNIP expression and other mechanisms.

Candidate plasticity gene 16 mediates suppression of insulin gene expression in rat insulinoma INS-1 cells under glucotoxic conditions.

Chronic hyperglycemia causes pancreatic ß-cell dysfunction, impaired insulin secretion and suppression of insulin gene expression, referred to as glucotoxicity. Insulin gene expression is regulated by several protein kinases and protein phosphatases. However, the molecular mechanisms of the suppressed insulin gene expression in glucotoxicity are not fully understood. In this study, we employed rat insulinoma INS-1 cells as a model of pancreatic glucotoxicity. In INS-1 cells, insulin gene expression is up-regulated by incubation with 11.2 mM glucose for 7 days and down-regulated by incubation with 22.4 mM glucose for the same period. To identify the protein kinases and protein phosphatases involved in the suppression of insulin gene expression, we analyzed gene expression in INS-1 cells cultured with 11.2 mM or 22.4 mM glucose for 7 days using microarray analysis and real-time PCR. The expression levels of nine protein kinases were affected by glucotoxic conditions. In particular, CPG16 expression level was increased in INS-1 cells under these conditions. Transfection of CPG16 decreased insulin promoter activity, whereas kinase-dead mutant of CPG16 did not affect this. These results suggest that CPG16 plays a role in the suppression of insulin gene expression in pancreatic ß-cells under glucotoxic conditions.

A method for profiling the phosphorylation state of tyrosine protein kinases.

Protein kinases are known to be implicated in various biological phenomena and diseases through their involvement in protein phosphorylation. Therefore, analysis of the activity of protein kinases by examination of their phosphorylation state is important to elucidate their mechanisms. However, a method for analyzing the phosphorylation state of entire protein kinases in cells is not established. In the present study, we developed a new profiling method to analyze the expression and phosphorylation state of protein kinases using a Multi-PK antibody and Phos-tag 2D-PAGE. When HL-60 cells were differentiated into macrophage-like cells induced by 12-O-tetradecanoylphorbol-13-acetate, we observed significant changes in the expression and phosphorylation state of immunoreactive spots by this method. These results show that tyrosine kinase expression levels and phosphorylation state are changed by differentiation. Taken together, the developed method will be a useful tool for analysis of intracellular tyrosine protein kinases.

A negative feedback loop between nuclear factor 90 (NF90) and an anti-oncogenic microRNA, miR-7.

Alterations in microRNAs (miRNAs) levels deeply correlate with tumorigenesis. However, the molecular mechanism for the regulation of the miRNA production in tumors is not fully understood. We previously reported that downregulation of miR-7, which is an anti-oncogenic miRNA, was caused by overexpression of the nuclear factor 90 (NF90)-nuclear factor 45 (NF45) complex through the binding of double-stranded (ds) RNA-binding proteins to primary miR-7, resulting in promotion of tumorigenesis (Higuchi et al 2016). During this study, we found that the level of NF90 protein was dramatically decreased by overexpression of miR-7. Interestingly, the miR-7-mediated reduction in NF90 family proteins was only observed in NF90 protein, but not in NF110 protein, which is a longer form of the NF90 gene. Luciferase reporter analysis indicated that the overexpression of miR-7 significantly repressed the luciferase activity in the coding region of NF90 mRNA harboring a predicted target sequence of miR-7. The luciferase activity of the reporter vector, which has a mutated miR-7 target site in the coding region, was the same in the control and miR-7 overexpressed cells. Furthermore, the translation of TARGET-tagged NF90 mRNA without the 3'UTR of the NF90 mRNA was inhibited by the overexpression of miR-7. These results imply that miR-7 suppresses NF90 at the protein level through the binding of miR-7 to the complementary site of the seed sequence in the coding region of the NF90 mRNA. We further confirmed increased endogenous NF90 protein levels in SK-N-SH cells transfected with antisense oligonucleotides targeting miR-7, indicating that miR-7-mediated translational repression of NF90 is a physiological event. Taken together with our previous findings (Higuchi et al 2016), it suggests that the level of NF90 is increased by a negative feedback loop between NF90 and miR-7 in tumor tissues under physiological conditions.

Facile preparation of highly active casein kinase 1 using Escherichia coli constitutively expressing lambda phosphatase.

Casein kinase 1 (CK1) is a widely expressed Ser/Thr kinase in eukaryotic organisms that is involved in various cellular processes (e.g., circadian rhythm and apoptosis). Therefore, preparing highly active CK1 and investigating its properties in vitro have important implications for understanding the biological roles of the kinase. However, recombinant CK1 undergoes autoinactivation via autophosphorylation in Escherichia coli cells and thus is undesirably prepared as a phosphorylated and inactivated kinase. To circumvent this problem, we established a protein expression system using E. coli strain BL21(DE3)pλPP in which λ protein phosphatase (λPPase) is constitutively expressed. Using this system, recombinant CK1 isoforms (α, δ and ε) were readily prepared as unphosphorylated forms. Furthermore, we found that CK1s prepared using BL21(DE3)pλPP showed markedly higher activity than those prepared by the conventional BL21(DE3). Finally, we demonstrated that the kinase activity of CK1δ from BL21(DE3)pλPP was higher than that prepared by a conventional method consisting of troublesome steps such as in vitro λPPase treatment. Thus, this simple method using BL21(DE3)pλPP is valuable for preparing highly active CK1s. It may also be applicable to other kinases that are difficult to prepare because of phosphorylation in E. coli cells.

Thyroid stimulating hormone stimulates the expression of glucose transporter 2 via its receptor in pancreatic ß cell line, INS-1 cells.

Thyroid stimulating hormone (TSH) stimulates the secretion of thyroid hormones by binding the TSH receptor (TSHR). TSHR is well-known to be expressed in thyroid tissue, excepting it, TSHR has also been expressed in many other tissues. In this study, we have examined the expression of TSHR in rat pancreatic islets and evaluated the role of TSH in regulating pancreas-specific gene expression. TSHR was confirmed to be expressed in rodent pancreatic islets and its cell line, INS-1 cells. TSH directly affected the glucose uptake in INS cells by up-regulating the expression of GLUT2, and furthermore this process was blocked by SB203580, the specific inhibitor of the p38 MAPK signaling pathway. Similarly, TSH stimulated GLUT2 promoter activity, while both a dominant-negative p38MAPK α isoform (p38MAPK α-DN) and the specific inhibitor for p38MAPK α abolished the stimulatory effect of TSH on GLUT2 promoter activity. Finally, INS-1 cells treated with TSH showed increased protein level of glucokinase and enhanced glucose-stimulated insulin secretion. Together, these results confirm that TSHR is expressed in INS-1 cells and rat pancreatic islets, and suggest that activation of the p38MAPK α might be required for TSH-induced GLUT2 gene transcription in pancreatic ß cells.

Multi-PK antibodies: Powerful analytical tools to explore the protein kinase world.

Diverse biological events are regulated through protein phosphorylation mediated by protein kinases. Some of these protein kinases are known to be involved in the pathogenesis of various diseases. Although 518 protein kinase genes were identified in the human genome, it remains unclear how many and what kind of protein kinases are expressed and activated in cells and tissues under varying situations. To investigate cellular signaling by protein kinases, we developed monoclonal antibodies, designated as Multi-PK antibodies, that can recognize multiple protein kinases in various biological species. These Multi-PK antibodies can be used to profile the kinases expressed in cells and tissues, identify the kinases of special interest, and analyze protein kinase expression and phosphorylation state. Here we introduce some applications of Multi-PK antibodies to identify and characterize the protein kinases involved in epigenetics, glucotoxicity in type 2 diabetes, and pathogenesis of ulcerative colitis. In this review, we focus on the recently developed technologies for kinomics studies using the powerful analytical tools of Multi-PK antibodies.

Subcellular distribution of cyclin-dependent kinase-like 5 (CDKL5) is regulated through phosphorylation by dual specificity tyrosine-phosphorylation-regulated kinase 1A (DYRK1A).

Cyclin-dependent kinase-like 5 (CDKL5) is a Ser/Thr protein kinase primarily expressed in the central nervous system and is known to cause X-linked neurodevelopmental disorders such as Rett syndrome. However, the mechanisms regulating CDKL5 have not yet been fully clarified. Therefore, in this study, we investigated the protein kinase that directly phosphorylates CDKL5, identifying it as dual specificity tyrosine-phosphorylation-regulated kinase 1A (DYRK1A), an enzyme binding to and phosphorylating CDKL5. We showed that subcellular distribution of CDKL5 was regulated by its phosphorylation by DYRK1A. In mouse neuroblastoma Neuro2a cells, CDKL5 was localized in both the cytosol and nucleus, whereas DYRK1A showed a typical nuclear localization. When CDKL5 and DYRK1A were co-expressed, the cytosolic localization of CDKL5 was significantly increased. Results of site-directed mutagenesis revealed that the phosphorylation site was Ser-308, in the vicinity of the nuclear localization signal. A mutation mimicking the phosphorylated serine residue by aspartate substitution (S308D) changed CDKL5 localization to the cytosol, whereas the corresponding alanine-substituted analog, CDKL5(S308A), was primarily localized to the nucleus. Taken together, these results strongly suggested that DYRK1A bound to CDKL5 and phosphorylated it on Ser-308, thus interfering with its nuclear localization.

Phosphorylated TandeMBP: A unique protein substrate for protein phosphatase assay.

To analyze a variety of protein phosphatases, we developed phosphorylated TandeMBP (P-TandeMBP), in which two different mouse myelin basic protein isoforms were fused in tandem, as a protein phosphatase substrate. P-TandeMBP was prepared efficiently in four steps: (1) phosphorylation of TandeMBP by a protein kinase mixture (Ca(2+)/calmodulin-dependent protein kinase Iδ, casein kinase 1δ, and extracellular signal-regulated kinase 2); (2) precipitation of both P-TandeMBP and protein kinases to remove ATP, Pi, and ADP; (3) acid extraction of P-TandeMBP with HCl to remove protein kinases; and (4) neutralization of the solution that contains P-TandeMBP with Tris. In combination with the malachite green assay, P-TandeMBP can be used to detect protein phosphatase activity without using radioactive materials. Moreover, P-TandeMBP served as an efficient substrate for PPM family phosphatases (PPM1A, PPM1B, PPM1D, PPM1F, PPM1G, PPM1H, PPM1K, and PPM1M) and PPP family phosphatase PP5. Various phosphatase activities were also detected with high sensitivity in gel filtration fractions from mouse brain using P-TandeMBP. These results indicate that P-TandeMBP might be a powerful tool for the detection of protein phosphatase activities.

Suppression of MicroRNA-7 (miR-7) Biogenesis by Nuclear Factor 90-Nuclear Factor 45 Complex (NF90-NF45) Controls Cell Proliferation in Hepatocellular Carcinoma.

MicroRNA-7 (miR-7)has been characterized as an anti-oncogenic microRNA (miRNA) in several cancers, including hepatocellular carcinoma (HCC). However, the mechanism for the regulation of miR-7 production in tumors remains unclear. Here, we identified nuclear factor 90 (NF90) and NF45 complex (NF90-NF45) as negative regulators of miR-7 processing in HCC. Expression of NF90 and NF45 was significantly elevated in primary HCC tissues compared with adjacent non-tumor tissues. To examine which miRNAs are controlled by NF90-NF45, we performed an miRNA microarray and quantitative RT-PCR analyses of HCC cell lines. Depletion of NF90 resulted in elevated levels of mature miR-7, whereas the expression of primary miR-7-1 (pri-miR-7-1) was decreased in cells following knockdown of NF90. Conversely, the levels of mature miR-7 were reduced in cells overexpressing NF90 and NF45, although pri-miR-7-1 was accumulated in the same cells. Furthermore, NF90-NF45 was found to bind pri-miR-7-1 in vitro These results suggest that NF90-NF45 inhibits the pri-miR-7-1 processing step through the binding of NF90-NF45 to pri-miR-7-1. We also found that levels of the EGF receptor, an oncogenic factor that is a direct target of miR-7, and phosphorylation of AKT were significantly decreased in HCC cell lines depleted of NF90 or NF45. Of note, knockdown of NF90 or NF45 caused a reduction in the proliferation rate of HCC cells. Taken together, NF90-NF45 stimulates an elevation of EGF receptor levels via the suppression of miR-7 biogenesis, resulting in the promotion of cell proliferation in HCC.

Expression analyses of splice variants of zebrafish cyclin-dependent kinase-like 5 and its substrate, amphiphysin 1.

Mammalian cyclin-dependent kinase-like 5 (CDKL5) is a Ser/Thr protein kinase mainly expressed in the central nervous system and believed to be involved in neuronal functions. However, the functions of CDKL5 in fishes have not been investigated. Therefore, in this study, we cloned and characterized zebrafish CDKL5 (zCDKL5) and its substrate, amphiphysin 1 (zAmph1). Two alternative splice variants of zCDKL5, zCDKL5-Long (zCDKL5-L) and zCDKL5-Short (zCDKL5-S), and three splice variants of zAmph1, zAmph1a, zAmph1b and zAmph1c, were cloned from a zebrafish cDNA library. Using zAmph1a point mutants, we identified Ser-285 and Ser-293 as phosphorylation sites of zAmph1a by CDKL5. Transiently expressed zCDKL5-L and zCDKL5-S colocalized with zAmph1a in the cytoplasm of 293T cells. RT-PCR analysis revealed that zCDKL5-L was first observed 12hours post-fertilization (hpf) and increased thereafter, while zCDKL5-S appeared just after fertilization. zAmph1a was detected in all embryogenic stages and zAmph1b appeared from 12hpf, but the expression of zAmph1c was not observed in our experiments. In adult fish, zCDKL5-L was mainly expressed in the brain, but zCDKL5-S showed ubiquitous expression. zAmph1a was observed most abundantly in the eyes, whereas zAmph1b was predominantly expressed in the brain. zAmph1c was scarcely detected. These results suggest that phosphorylation of Amph1 by CDKL5 may be a common feature throughout animal species.

Cell-based inhibitor screening identifies multiple protein kinases important for circadian clock oscillations.

Molecular oscillation of the circadian clock is based on E-box-mediated transcriptional feedback loop formed with clock genes and their encoding products, clock proteins. The clock proteins are regulated by post-translational modifications such as phosphorylation. We investigated the effects of a series of kinase inhibitors on gene expression rhythms in Rat-1 fibroblasts. The period of the cellular circadian rhythm in culture was lengthened by treatment with SB203580 (p38 MAPK inhibitor), SP600125 (JNK inhibitor), IC261 (CKI inhibitor) and Roscovitine (CDK inhibitor). On the other hand, the period was shortened by SB216763 (GSK-3 inhibitor) or KN93 (CaMKII inhibitor) treatment. Application of 20 µM KN93 completely abolished the rhythmic gene expression. The activity of CaMKII exhibited circadian variation in a phase close to the E-box-mediated transcriptional rhythms. In vitro kinase assay revealed that CaMKII directly phosphorylates N-terminal and Ser/Pro-rich domains of CLOCK, an activator of E-box-mediated transcription. These results indicate a phosphorylation-dependent tuning of the period length by a regulatory network of multiple kinases and reveal an essential role of CaMKII in the cellular oscillation mechanism.