Calcium-regulated protein kinase cascades and their transcription factor targets.

In the nervous system, calcium signals associated with electrical activation of neurons induce gene transcription that may be important for long-lasting adaptation. The type of transcriptional response is determined by the properties of the calcium signal that include subcellular localisation, amplitude, duration and the physical site of entry. Here we review calcium-regulated protein kinase cascades and discuss potential mechanisms through which they propagate calcium signals to and within the nucleus and control the activity of transcription factors and transcriptional co-activators.

Control of recruitment and transcription-activating function of CBP determines gene regulation by NMDA receptors and L-type calcium channels.

Recruitment of the coactivator CBP by signal-regulated transcription factors and stimulation of CBP activity are key regulatory events in the induction of gene transcription following Ca2+ flux through ligand- and/or voltage-gated ion channels in hippocampal neurons. The mode of Ca2+ entry (L-type Ca2+ channels versus NMDA receptors) differentially controls the CBP recruitment step to CREB, providing a molecular basis for the observed Ca2+ channel type-dependent differences in gene expression. In contrast, activation of CBP is triggered irrespective of the route of Ca2+ entry, as is activation of c-Jun, that recruits CBP independently of phosphorylation at major regulatory c-Jun phosphorylation sites, serines 63 and 73. This control of CBP recruitment and activation is likely relevant to other CBP-interacting transcription factors and represents a general mechanism through which Ca2+ signals associated with electrical activity may regulate the expression of many genes.

c-Jun functions as a calcium-regulated transcriptional activator in the absence of JNK/SAPK1 activation.

Calcium is the principal second messenger in the control of gene expression by electrical activity in neurons. Recruitment of the coactivator CREB-binding protein, CBP, by the prototypical calcium-responsive transcription factor, CREB and stimulation of CBP activity by nuclear calcium signals is one mechanism through which calcium influx into excitable cells activates gene expression. Here we show that another CBP-interacting transcription factor, c-Jun, can mediate transcriptional activation upon activation of L-type voltage-gated calcium channels. Calcium-activated transcription mediated by c-Jun functions in the absence of stimulation of the c-Jun N-terminal protein kinase (JNK/SAPK1) signalling pathway and does not require c-Jun amino acid residues Ser63 and Ser73, the two major phosphorylation sites that regulate c-Jun activity in response to stress signals. Similar to CREB-mediated transcription, activation of c-Jun-mediated transcription by calcium signals requires calcium/ calmodulin-dependent protein kinases and is dependent on CBP function. These results identify c-Jun as a calcium-regulated transcriptional activator and suggest that control of coactivator function (i.e. recruitment of CBP and stimulation of CBP activity) is a general mechanism for gene regulation by calcium signals.

ERK activation induces phosphorylation of Elk-1 at multiple S/T-P motifs to high stoichiometry.

Elk-1, a member of the TCF family of Ets domain proteins, contains a C-terminal transcriptional activation domain with multiple copies of the MAPK core consensus sequence S/T-P. This region is phosphorylated by MAP kinases in vitro and in vivo, but the extent and kinetics of phosphorylation at the different sites have not been investigated in detail. We prepared antisera against the phosphorylated forms of residues T353, T363, T368, S383, S389 and T417. The antisera specifically recognize the phosphorylated Elk-1 C terminus and are specific for their cognate sites, as assessed by peptide competition and mutagenesis experiments. Analysis of cells stably expressing Elk-1 in vivo shows that following serum or TPA stimulation, residues T353, T363, T368, S383, S389 and T417 become phosphorylated with similar kinetics. Mutation of any one site does not prevent phosphorylation of the others. Mutation to alanine of S383, F378 or W379, which virtually abolishes transcriptional activation by Elk-1, does not affect phosphorylation of any sites tested. Analysis of Elk-1 using two-dimensional gel electrophoresis shows that following ERK activation Elk-1 receives at least six phosphates in addition to those present prior to stimulation. We propose that the Elk-1 C-terminal regulatory domain becomes stoichiometrically phosphorylated following growth factor stimulation.

Mechanisms controlling gene expression by nuclear calcium signals.

Nuclear calcium is an important regulator of gene expression following membrane depolarisation of electrically excitable cells. Here we describe nuclear calcium transients in hippocampal neurons following activation of calcium influx through L-type voltage-sensitive calcium channels and N-methyl-D-aspartate (NMDA) receptors, as well as following calcium release from intracellular caffeine-sensitive stores. Increases in nuclear calcium activate gene transcription by a mechanism that is distinct from gene regulation by cytoplasmic calcium signals and involves the cAMP response element (CRE) and the CRE binding protein, CREB. The nuclear calcium/calmodulin dependent (CaM) protein kinase IV, which is expressed in cultured hippocampal neurons and in the mouse pituitary cell line AtT20, may function as a mediator of nuclear calcium-induced transcription.

The p38 and ERK MAP kinase pathways cooperate to activate Ternary Complex Factors and c-fos transcription in response to UV light.

We investigated the activation of c-fos transcription following UV irradiation, a 'stress' stimulus. In both HeLa TK- and NIH 3T3 cells the Serum Response Element is required for efficient UV-induced c-fos transcription, and in HeLa TK- cells the Ternary Complex Factor (TCF) binding site contributes substantially to activation. Consistent with this, UV irradiation activates LexA-TCF fusion proteins more strongly in HeLa TK- than in NIH 3T3 cells. The TCF C-termini of the TCFs are substrates for UV-induced MAP kinases: both the Elk-1 and SAP-1a C-termini are efficiently phosphorylated by the p38 MAPK, but only the Elk-1 C-terminus is a good substrate for the SAPK/JNKs. The specificity and activation kinetics of TCF C-terminal kinases, and the susceptibility of transcriptional activation by LexA-TCF fusion proteins to specific inhibitors of different MAPK pathways, show that both the ERK and p38 MAPK pathways contribute to TCF activation in response to UV irradiation. Activity of both these pathways is also required for the response of the c-fos gene itself to UV stimulation.

Biochemical characterization of the multifunctional Ca2+/calmodulin-dependent protein kinase type IV expressed in insect cells.

We have expressed the rat brain Ca2+/calmodulin (CaM)-dependent protein kinase type IV in insect cells. The recombinant enzyme is produced as a single polypeptide that migrates on SDS-polyacrylamide gel electrophoresis at 61 kDa. Recombinant CaM kinase IV undergoes slow CaM-dependent autophosphorylation. The autophosphorylation of CaM kinase IV occurs on serine residues but is not accompanied by the generation of a CaM-independent activity, as previously reported for the cerebellar enzyme. Comparison of peptide and protein phosphorylation by the recombinant CaM kinase IV and the cerebellar enzyme showed differences in their catalytic activities. The deduced primary sequence of CaM kinase IV contained a domain, 315Phe-Asn-Ala-Arg-Arg-Lys-Leu-Lys323, also found in the regulatory domain of CaM kinase II alpha (residues 293-300). Truncation of CaM kinase IV at Leu313 (at a position analogous to Leu290 in CaM kinase II alpha) generated a fully active, CaM-independent enzyme. This truncated enzyme no longer bound CaM. These data confirm that CaM kinase IV demonstrates intrasteric regulation by an autoinhibitory domain and provides insight into a potentially common mechanism for the regulation of the CaM-dependent multifunctional protein kinases. A number of synthetic peptides were examined for their phosphorylation by both CaM kinase II and IV. These studies showed that several peptides derived from phospholamban were preferential substrates for CaM kinase II whereas a peptide derived from S6 ribosomal protein was selectively phosphorylated by CaM kinase IV. Kinetic analysis of several peptide substrates suggests that while both CaM kinase II and IV recognize the sequence motif represented by R-X-X-T/S, other structural features are also involved in defining the unique substrate specificity of CaM kinase IV.

Calmodulin-dependent protein kinase II mediates inactivation of MPF and CSF upon fertilization of Xenopus eggs.

In vertebrates, unfertilized eggs are arrested at second meiotic metaphase by a cytostatic factor (CSF), an essential component of which is the product of the c-mos proto-oncogene. CSF prevents ubiquitin-dependent degradation of mitotic cyclins and thus inactivation or the M phase-promoting factor (MPF). Fertilization or parthenogenetic activation triggers a transient increase in the cytoplasmic free Ca2+ (reviewed in refs 5 and 6), inactivates both CSF and MPF, and releases eggs from meiotic metaphase arrest. A calmodulin-dependent process is required for cyclin degradation to occur in cell-free extracts prepared from metaphase II-arrested eggs (CSF extracts) when the free Ca2+ concentration is transiently raised in the physiological micromolar range. Here we show that when a constitutively active mutant of calmodulin-dependent protein kinase II (CaM KII) is added to a CSF extract, cyclin degradation and Cdc2 kinase inactivation occur even in the absence of Ca2+, and the extract loses its ability to cause metaphase arrest when transferred into embryos. Furthermore, specific inhibitors of CaM KII prevent cyclin degradation after calcium addition. Finally, the direct microinjection of constitutively active CaM KII into unfertilized eggs inactivates Cdc2 kinase and CSF, even in the absence of a Ca2+ transient. The target for Ca(2+)-calmodulin is thus CaM KII.

Regulation of intrasteric inhibition of the multifunctional calcium/calmodulin-dependent protein kinase.

A regulatory region involved in both autoinhibition and calmodulin (CaM) binding has previously been identified in the multifunctional Ca2+/CaM-dependent protein kinase (CaM kinase II). We have tested the role of various segments of the regulatory region in autoinhibition by the analysis of a series of truncation, substitution, and deletion mutants of the CaM kinase II alpha subunit (CaM kinase II alpha). Unexpectedly, the sequence Lys-Lys-Phe-Asn at positions 291-294, adjacent to the CaM binding domain, was found to be sufficient to maintain an inhibited state in a truncated form of the kinase. However, these residues are not essential in the context of the full-length protein, indicating the importance of additional residues from the overlapping CaM binding domain. We propose here a molecular model for CaM kinase II alpha based on the three-dimensional structure of the cAPK-PKI-(5-24) (protein kinase inhibitor fragment) complex. It is predicted from this model that autoinhibition is of the pseudosubstrate variety and that autophosphorylation of Thr-286 could occur by an intersubunit reaction in the holoenzyme complex.