Cdk pathway: Cyclin-dependent kinases and cyclin-dependent kinase inhibitors

Many mechanisms either activate or inhibit the cdks and thereby either promote or arrest progression through the mitotic cell cycle. Since the signal transduction pathways emanating from extracellular mitogens and the agents controlling these pathways are complicated there may yet be novel mechanisms of cell cycle regulation remaining to be elucidated. In this article we outline the different techniques used to study the cell cycle and its regulation. These include: establishing that the cell cycle is arrested by propidium iodide staining followed by FACS analysis or by measuring ³H-thymidine incorporation into DNA; measuring the amount of cyclin/cdk associated kinase activity; assessing the steady-state expression profiles of cyclins, cdks and ckis by immunoblotting; and investigating the formation of complexes between these proteins by coimmunoprecipitations. Caveats and advantages of each technique are discussed. Following this paradigm yielded the discovery of the cell cycle inhibitors p27^Kip1 and p21^Cip1 and could very well lead to the discovery or novel cell cycle regulatory mechanisms.     

Microtubule regulation in mitosis: tubulin phosphorylation by the cyclin-dependent kinase Cdk1

The activation of the cyclin-dependent kinase Cdk1 at the transition from interphase to mitosis induces important changes in microtubule dynamics. Cdk1 phosphorylates a number of microtubule- or tubulin-binding proteins but, hitherto, tubulin itself has not been detected as a Cdk1 substrate. Here we show that Cdk1 phosphorylates beta-tubulin both in vitro and in vivo. Phosphorylation occurs on Ser172 of beta-tubulin, a site that is well conserved in evolution. Using a phosphopeptide antibody, we find that a fraction of the cell tubulin is phosphorylated during mitosis, and this tubulin phosphorylation is inhibited by the Cdk1 inhibitor roscovitine. In mitotic cells, phosphorylated tubulin is excluded from microtubules, being present in the soluble tubulin fraction. Consistent with this distribution in cells, the incorporation of Cdk1-phosphorylated tubulin into growing microtubules is impaired in vitro. Additionally, EGFP-beta3-tubulin(S172D/E) mutants that mimic phosphorylated tubulin are unable to incorporate into microtubules when expressed in cells. Modeling shows that the presence of a phosphoserine at position 172 may impair both GTP binding to beta-tubulin and interactions between tubulin dimers. These data indicate that phosphorylation of tubulin by Cdk1 could be involved in the regulation of microtubule dynamics during mitosis.     

Activation of latent cyclin-dependent kinase 5 (Cdk5)-p35 complexes by membrane dissociation

Cyclin-dependent kinase 5 (Cdk5) is a Ser/Thr kinase of increasingly recognized importance in a large number of fields, ranging from neuronal migration to synaptic plasticity and neurodegeneration. However, little is known about its mechanism of activation beyond its requirement for binding to p35 or p39. We have examined membrane interactions as one method of regulating the Cdk5-p35 complex. The kinase activity of Cdk5-p35 is low when it is bound to membranes. The Cdk5-p35 found in rat brain extract associates with membranes in two ways. Approximately 75% of complexes associate with membranes via ionic interactions only, and the remaining 25% associate with membranes via ionic interactions together with lipidic interactions. Solubilization with detergent or high-salt solution activates Cdk5-p35 several fold, and this activation is reversible. Therefore, membrane interactions represent a novel mechanism for the regulation of Cdk5-p35 kinase activity.     

The cyclin-dependent kinase Cdk5 controls multiple aspects of axon patterning in vivo

Cyclin-dependent kinase 5 (Cdk5) is one of a subfamily of Cdks involved in the control of cell differentiation and morphology rather than cell division. Specifically, Cdk5 and its activating subunit, p35, have been implicated in growth cone motility during axon extension. Both Cdk5 and p35 are expressed in post-mitotic neurons and are localized to growth cones [1] [2] [3] [4]. The Cdk5-p35 complex interacts with the Rac GTPase, a protein required for growth cone motility [5]. Studies using cultured neurons have suggested that Cdk5 activity controls the efficiency of neurite extension [3] [4]. Mutant mice lacking p35 exhibit subtle axon-guidance defects [6], but these mice have severe defects in neuronal migration [6] [7] [8], making it difficult to define precisely the role of the Cdk5-p35 complex in vivo. Here, we examined Cdk5 function in axon patterning in the Drosophila embryo. Although our data support the idea that Cdk5-p35 is involved in axonogenesis, they do not support the view that Cdk5 simply promotes growth cone motility. Instead, we found that disrupting Cdk5 function caused widespread errors in axon patterning.     

Identification and structure characterization of a Cdk inhibitory peptide derived from neuronal-specific Cdk5 activator

The activation of cyclin-dependent kinase 5 (Cdk5) depends on the binding of its neuronal specific activator Nck5a. The minimal activation domain of Nck5a is located in the region of amino acid residues 150 to 291 (Tang, D., Chun, A. C. S., Zhang, M., and Wang, J. H. (1997) J. Biol. Chem. 272, 12318-12327). In this work we show that a 29-residue peptide, denoted as the alphaN peptide, encompassing amino acid residues Gln145 to Asp173 of Nck5a is capable of binding Cdk5 to result in kinase inhibition. This peptide also inhibits an active phospho-Cdk2-cyclin A complex, with a similar potency. Direct competition experiments have shown that this inhibitory peptide does not compete with Nck5a or cyclin A for Cdk5 or Cdk2, respectively. Steady state kinetic analysis has indicated that the alphaN peptide acts as a non-competitive inhibitor of Cdk5. Nck5a complex with respect to the peptide substrate. To understand the molecular basis of kinase inhibition by the peptide, we determined the structure of the peptide in solution by circular dichroism and two-dimensional 1H NMR spectroscopy. The peptide adopts an amphipathic alpha-helical structure from residues Ser149 to Arg162 which can be further stabilized by the helix-stabilizing solvent trifluoroethanol. The hydrophobic face of the helix is likely to be the kinase binding surface.     

A Cdk5 inhibitory peptide reduces tau hyperphosphorylation and apoptosis in neurons

The extracellular aggregation of amyloid beta (Abeta) peptides and the intracellular hyperphosphorylation of tau at specific epitopes are pathological hallmarks of neurodegenerative diseases such as Alzheimer's disease (AD). Cdk5 phosphorylates tau at AD-specific phospho-epitopes when it associates with p25. p25 is a truncated activator, which is produced from the physiological Cdk5 activator p35 upon exposure to Abeta peptides. We show that neuronal infections with Cdk5 inhibitory peptide (CIP) selectively inhibit p25/Cdk5 activity and suppress the aberrant tau phosphorylation in cortical neurons. Furthermore, Abeta(1-42)-induced apoptosis of these cortical neurons was also reduced by coinfection with CIP. Of particular importance is our finding that CIP did not inhibit endogenous or transfected p35/Cdk5 activity, nor did it inhibit the other cyclin-dependent kinases such as Cdc2, Cdk2, Cdk4 and Cdk6. These results, therefore, provide a strategy to address, and possibly ameliorate, the pathology of neurodegenerative diseases that may be a consequence of aberrant p25 activation of Cdk5, without affecting 'normal' Cdk5 activity.     

Control of cyclin-dependent kinase 5 (Cdk5) activity by glutamatergic regulation of p35 stability

Although the roles of cyclin-dependent kinase 5 (Cdk5) in neurodevelopment and neurodegeneration have been studied extensively, regulation of Cdk5 activity has remained largely unexplored. We report here that glutamate, acting via NMDA or kainate receptors, can induce a transient Ca(2+)/calmodulin-dependent activation of Cdk5 that results in enhanced autophosphorylation and proteasome-dependent degradation of a Cdk5 activator p35, and thus ultimately down-regulation of Cdk5 activity. The relevance of this regulation to synaptic plasticity was examined in hippocampal slices using theta burst stimulation. p35(-/-) mice exhibited a lower threshold for induction of long-term potentiation. Thus excitatory glutamatergic neurotransmission regulates Cdk5 activity through p35 degradation, and this pathway may contribute to plasticity.     

Phosphorylation of MCM3 protein by cyclin E/cyclin-dependent kinase 2 (Cdk2) regulates its function in cell cycle

MCM2-7 proteins form a stable heterohexamer with DNA helicase activity functioning in the DNA replication of eukaryotic cells. The MCM2-7 complex is loaded onto chromatin in a cell cycle-dependent manner. The phosphorylation of MCM2-7 proteins contributes to the formation of the MCM2-7 complex. However, the regulation of specific MCM phosphorylation still needs to be elucidated. In this study, we demonstrate that MCM3 is a substrate of cyclin E/Cdk2 and can be phosphorylated by cyclin E/Cdk2 at Thr-722. We find that the MCM3 T722A mutant binds chromatin much less efficiently when compared with wild type MCM3, suggesting that this phosphorylation site is involved in MCM3 loading onto chromatin. Interestingly, overexpression of MCM3, but not MCM3 T722A mutant, inhibits the S phase entry, whereas it does not affect the exit from mitosis. Knockdown of MCM3 does not affect S phase entry and progression, indicating that a small fraction of MCM3 is sufficient for normal S phase completion. These results suggest that excess accumulation of MCM3 protein onto chromatin may inhibit DNA replication. Other studies indicate that excess of MCM3 up-regulates the phosphorylation of CHK1 Ser-345 and CDK2 Thr-14. These data reveal that the phosphorylation of MCM3 contributes to its function in controlling the S phase checkpoint of cell cycle in addition to the regulation of formation of the MCM2-7 complex.     

Histamine metabolism and its role in central nervous system function

The present day data concerning biosynthesis, storage, release and inactivation of histamine in the brain of mammals are given. The possibility to regulate histamine of the action of physiologically active substances is discussed.     

A model of the complex between cyclin-dependent kinase 5 and the activation domain of neuronal Cdk5 activator.

Tau protein kinase II (TPKII) is a heterodimer comprising a catalytic cyclin-dependent kinase subunit (Cdk5) and a regulatory protein called neuronal Cdk5 activator (Nck5a). TPKII is somewhat reminiscent, therefore, of the Cdk2-cyclin complex important in cell cycle regulation. In fact, although the amino acid sequence of Nck5a has little similarity to those of cyclins, recent experimental results obtained by site-directed mutagenesis studies have indicated that its activation domain, Nck5a*, may adopt a conformation of the cyclin-fold structure. Based on this structural inference, a 3-dimensional model of the Cdk5-Nck5a*-ATP complex was derived from the X-ray structure of Cdk2-cyclinA-ATP complex. The computed structure for TPKII is fully compatible with experimental data derived from studies of the Cdk5-Nck5a system, and also predicts which amino acid residues might be involved in formation of the Cdk5-Nck5a* interface and ATP binding pocket in TPKII. The computational structure also shows the interactive region of Nck5a* and the T-loop of Cdk5, a critical region in TPKII which functions as a gate-control-lever of the catalytic cleft. Furthermore, a physical mechanism is put forth to explain why the activation of TPKII is not dependent upon phosphorylation of the Cdk5 subunit, a puzzle long-standing in this area. These findings provide a model with which to consider design of compounds which might serve as inhibitors of TPKII.     

Twice switched at birth: cell cycle-independent roles of the neuron-specific cyclin-dependent kinase 5 (Cdk5) in non-neuronal cells

Cdk5 (cyclin-dependent kinase 5 or initially NCLK for neuronal CDC2-like kinase) was switched twice at its birth nearly twenty years ago: first it was thought to be cyclin-dependent, second it was assumed to be primarily of importance in neuronal cells—both turned out not to be the case. In this review we want to discuss issues of pharmacological inhibition, to highlight the versatile roles, and to summarize the growing evidence for the functional importance of Cdk5 in non-neuronal tissues, such as blood cells, tumor cells, epithelial cells, the vascular endothelium, testis, adipose and endocrine tissues. The organizing principles we follow are apoptosis/cell death, migration/motility, aspects of inflammation, and, finally, secretion/metabolism.     

Signaling crossroads: the function of Raf kinase inhibitory protein in cancer, the central nervous system and reproduction

The Raf kinase inhibitory protein 1 (RKIP-1) and its orthologs are conserved throughout evolution and widely expressed in eukaryotic organisms. In its non-phosphorylated form RKIP-1 negatively regulates the Raf/MEK/ERK pathway by interfering with the activity of Raf-1. In its phosphorylated state, RKIP-1 dissociates from Raf-1 and inhibits GRK-2, a negative regulator of G-protein coupled receptors (GPCRs). Available data indicate that the phosphorylation of RKIP-1 by PKC can stimulate both the Raf/MEK/ERK and GPCR pathways. RKIP-1 has also been implicated as a negative regulator of the NF-kappaB pathway. Recent studies have shown that phosphorylated RKIP-1 binds to the centrosomal and kinetochore regions of metaphase chromosomes, where it may be involved in regulating the partitioning of chromosomes and the progression through mitosis. The collective evidence indicates that RKIP-1 regulates the activity and mediates the crosstalk between several important cellular signaling pathways. A variety of ablative interventions suggest that reduced RKIP-1 function may influence metastasis, angiogenesis, resistance to apoptosis, and genome integrity. Attenuation of RKIP-1 may also affect cardiac and neurological functions, spermatogenesis, sperm decapacitation, and reproductive behavior. In this review, the role of RKIP-1 in cellular signaling, and especially its functions revealed using a mouse knockout model, are discussed.     

Neuronal 5-hydroxytryptamine receptors outside the central nervous system

5-HT receptors are present on many types of neurone in the peripheral nervous system (PNS), e.g. sympathetic, parasympathetic, enteric and sensory cells, and mediate complex effects. These include depolarization, cell discharge and facilitation or depression of transmission. If 5-HT receptors can be classified according to the membrane mechanism associated with them, following the system adopted for mollusc neurones, such a classification would have to take into account two kinds of presynaptic and at least four kinds of postsynaptic action. Recent work suggests that a small number of analogues of 5-HT (tryptamine, 5-MOT, LSD) and antagonists (cocaine, methysergide, quipazine) may be useful in differentiating the various kinds of 5-HT receptor in the PNS. It is suggested that no single feature should be relied upon to characterize the receptors; classification might be based on consideration of function, evidence of tachyphylaxis, sensitivity to methysergide, cocaine, etc. On this basis, it is tentatively concluded that there are two kinds of 5-HT receptor mediating excitation in the PNS, neither of which can sensibly be termed an ‘M’ receptor. An interim form of terminology is proposed which makes use of an acronym of the distinctive features. A receptor mediating (E)xcitation, which shows (T)achyphylaxis, is (M)ethysergide (I)nsensitive but is blocked by (C)ocaine might be designated a 5-HT_ETMIC receptor, while a second which differs because it is insensitive to cocaine but activated by (F)ive-methoxytryptamine might be designated a 5-HT_ETMIF receptor. Amongst receptors mediating (I)nhibition, the best characterized is one mediating decreased transmitter release and activated by (L)SD. The term 5-HT_IL receptor is proposed. A second, post-synaptic inhibitory receptor is likely, but has not been adequately characterized at present.     

Targeting Cdk5 Activity in Neuronal Degeneration and Regeneration

The major priming event in neurodegeneration is loss of neurons. Loss of neurons by apoptotic mechanisms is a theme for studies focused on determining therapeutic strategies. Neurons following an insult, activate a number of signal transduction pathways, of which, kinases are the leading members. Cyclin-dependent kinase 5 (Cdk5) is one of the kinases that have been linked to neurodegeneration. Cdk5 along with its principal activator p35 is involved in multiple cellular functions ranging from neuronal differentiation and migration to synaptic transmission. However, during neurotoxic stress, intracellular rise in Ca²⁺ activates calpain, which cleaves p35 to generate p25. The long half-life of Cdk5/p25 results in a hyperactive, aberrant Cdk5 that hyperphosphorylates Tau, neurofilament and other cytoskeletal proteins. These hyperphosphorylated cytoskeletal proteins set the groundwork to forming neurofibrillary tangles and aggregates of phosphorylated proteins, hallmarks of neurodegenerative diseases like Alzheimer’s disease, Parkinson’s disease and Amyotropic Lateral Sclerosis. Attempts to selectively target Cdk5/p25 activity without affecting Cdk5/p35 have been largely unsuccessful. A polypeptide inhibitor, CIP (Cdk5 inhibitory peptide), developed in our laboratory, successfully inhibits Cdk5/p25 activity in vitro, in cultured primary neurons, and is currently undergoing validation tests in mouse models of neurodegeneration. Here, we discuss the therapeutic potential of CIP in regenerating neurons that are exposed to neurodegenerative stimuli.     

The regulation of cyclin-dependent kinase 5 activity through the metabolism of p35 or p39 Cdk5 activator

Cyclin-dependent kinase 5 (Cdk5) displays kinase activity predominantly in post-mitotic neurons and its physiological roles are unrelated to cell cycle progression. Cdk5 is activated by its binding to a neuron-specific activator, p35 or p39. The protein amount of p35 or p39 is a primary determinant of the Cdk5 activity in neurons, with the amount of p35 or p39 being determined by its synthesis and degradation. The expression of p35 is induced in differentiated neurons and is enhanced by extracellular stimuli such as neurotrophic factors or extracellular matrix molecules, specifically those acting on the ERK/Erg pathway. p35 is a short-lived protein and its degradation determines the life span. Degradation is mediated by the ubiquitin/proteasome system, similar to that for cyclins in proliferating cells. Autophosphorylation of p35 by Cdk5 is a signal for ubiquitination/degradation, and the degradation of p35 is triggered by glutamate treatment in cultured neurons. p35 is cleaved to p25 by calpain at the time of neuronal cell death, and this limited cleavage is suggested to be the cause of neurodegenerative diseases such as Alzheimer's disease. Active Cdk5 changes the cellular localization by cleavage of p35 to p25; p35/Cdk5 is associated with membrane or cytoskeletons, but p25/Cdk5 is a soluble protein. Cleavage also increases the life span of p25 and changes the activity or substrate specificity of Cdk5. p25/Cdk5 shows higher phosphorylating activity to tau than p35/Cdk5 in a phosphorylation site-specific manner. Phosphorylation of p35 suppresses cleavage by calpain. Thus, phosphorylation of p35 modulates its proteolytic pattern, stimulates proteasomal degradation and suppresses calpain cleavage. Phosphorylation is age dependent, as p35 is phosphorylated in foetal brains, but unphosphorylated in adult brains. Therefore, foetal phosphorylated p35 is turned over rapidly, whereas adult unphosphorylated p35 has a long life and is easily cleaved to p25 when calpain is activated. p39 is also a short-lived protein and cleaved to the N-terminal truncation form of p29 by calpain. How the metabolism of p39 is regulated, however, is a future problem to be investigated.     

The role of the Cdk5--p35 kinase in neuronal development.

Cyclin-dependent kinase 5 (Cdk5) plays a key role in proper development of the nervous system. To be activated, Cdk5 associates with regulatory subunits not related to cyclins, such as p35 (the regulatory subunit of Cdk5). In this article, we review some of the experimental evidence supporting a central role for the Cdk5/p35 kinase in neuronal migration and process formation.     

A peptide derived from cyclin-dependent kinase activator (p35) specifically inhibits Cdk5 activity and phosphorylation of tau protein in transfected cells.

Cyclin-dependent kinase-5 (Cdk5) is a serine/threonine kinase activated by its neuron-specific activator, p35, or its truncated form, p25. It has been proposed that the deregulation of Cdk5 activity by association with p25 in human brain tissue disrupts the neuronal cytoskeleton and may be involved in neurodegenerative diseases such as Alzheimer's disease. In this study, we demonstrate that a short peptide (amino acid residues 154-279; Cdk5 inhibitory peptide; CIP), derived from p35, specifically inhibits Cdk5 activity in vitro and in HEK293 cells cotransfected with the peptide and Cdk5/p25, but had no effect on endogenous cdc2 kinase activity. Moreover, we demonstrate that the phosphorylation of tau in HEK293 cells, cotransfected with Cdk5/p25 and CIP, is effectively reduced. These results suggest that CIP specifically inhibits both Cdk5/p25 complex activity and the tau hyperphosphorylation induced by Cdk5/p25. The elucidation of the molecular basis of p25 activation and CIP inhibition of Cdk5 activity may provide insight into mechanisms underlying the pathology of Alzheimer's disease and contribute to therapeutic strategies.