Expression, characterization, and gene knockdown of zebrafish doublecortin-like protein kinase

Doublecortin-like protein kinase (DCLK) is a protein Ser/Thr kinase expressed in brain and believed to play crucial roles in neuronal development. To investigate the biological significance of DCLK, we isolated cDNA clones for zebrafish DCLK (zDCLK) and found that there were five splice variants of the kinase. In this study, the catalytic properties of a major isoform of zDCLK, which we designated as zDCLK1, and of an N-terminal truncated mutant retaining the kinase domain were examined by expressing them in Escherichia coli. Mutational analysis of recombinant zDCLK suggested that the kinase was activated not only by phosphorylation at Thr-576 in the activation loop but also by autophosphorylation at the other site(s) in the catalytic domain. zDCLK significantly phosphorylated protein substrates such as myelin basic protein, histones, and synapsin I. Subcellular localization of zDCLK and its N-terminal deletion mutant implicated that microtubule-association of zDCLK is mediated through N-terminal doublecortin like domain of this enzyme. Western blotting analysis and whole mount in situ hybridization revealed that zDCLK was highly expressed in brain and eyes after 24-h post fertilization. Gene knockdown of zDCLK using morpholino-based antisense oligonucleotides induced significant increase of apoptotic cells in the central nervous systems and resulted in the increase of the morphologically abnormal embryos in a dose-dependent manner. These results suggest that zDCLK may play crucial roles in the central nervous systems during the early stage of embryogenesis.     

The DC-module of doublecortin: dynamics, domain boundaries, and functional implications

The doublecortin-like (DC) domains, which usually occur in tandem, constitute novel microtubule-binding modules. They were first identified in doublecortin (DCX), a protein expressed in migrating neurons, and in the doublecortin-like kinase (DCLK). They are also found in other proteins, including the RP1 gene product which-when mutated-causes a form of inherited blindness. We previously reported an X-ray structure of the N-terminal DC domain of DCLK (N-DCLK), and a solution structure of an analogous module of human doublecortin (N-DCX). These studies showed that the DC domain has a tertiary fold closely reminiscent of ubiquitin and similar to several GTPase-binding domains. We now report an X-ray structure of a mutant of N-DCX, in which the C-terminal fragment (residues 139-147) unexpectedly shows an altered, "open" conformation. However, heteronuclear NMR data show that this C-terminal fragment is only transiently open in solution, and assumes a predominantly "closed" conformation. While the "open" conformation may be artificially stabilized by crystal packing interactions, the observed switching between the "open" and "closed" conformations, which shortens the linker between the two DC-domains by approximately 20 A, is likely to be of functional importance in the control of tubulin polymerization and microtubule bundling by doublecortin.     

Cleavage of doublecortin-like kinase by calpain releases an active kinase fragment from a microtubule anchorage domain

Doublecortin-like kinase (DCLK) is widely expressed in postmitotic neurons throughout the embryonic nervous system. DCLK consists of an N-terminal doublecortin domain, responsible for its localization to microtubules, and a C-terminal serine-threonine kinase domain. Here we report that DCLK is a physiological substrate for the cysteine protease calpain. Cleavage of DCLK by calpain severs the kinase domain from its microtubule anchorage domain and releases it into the cytoplasm. The isolated kinase domain retains catalytic activity and is structurally similar to CPG16, a second product of the DCLK gene expressed in the adult brain that lacks the doublecortin domain. We propose that in neurons cleavage of DCLK by calpain represents a calcium responsive mechanism to regulate localization of the DCLK kinase domain.     

Microtubule/MAP-affinity regulating kinase (MARK) is activated by phenylarsine oxide in situ and phosphorylates tau within its microtubule-binding domain

Tau is a microtubule-associated protein (MAP) that is functionally modulated by phosphorylation and that is hyperphosphorylated in several neurodegenerative diseases. Because phosphorylation regulates both normal and pathological tau functioning, it is of interest to identify the signaling pathways and enzymes capable of modulating tau phosphorylation in vivo. Previously, it was demonstrated that in SH-SY5Y human neuroblastoma cells and rat primary cortical cultures tau is phosphorylated at Ser262/356, within its microtubule-binding domain, by a staurosporine-sensitive protein kinase in response to the vicinal thiol-directed agent phenylarsine oxide. The current study demonstrates the presence of a 100-kDa protein kinase activity in SH-SY5Y cells that associates with microtubules, phosphorylates tau at Ser262/356, is activated by phenylarsine oxide, and is inhibited by the protein kinase inhibitor staurosporine. Isolation of individual protein bands from a polyacrylamide gel revealed two closely spaced proteins containing Ser262/356-directed protein kinase activity. Mass spectrometry analysis indicated that these protein bands correspond to the 100-kDa microtubule/MAP-affinity regulating kinase (MARK), which has been shown previously to phosphorylate tau within its microtubule-binding domain. Immunoblot analysis of the protein kinase bands confirmed this finding, providing the first demonstration that activation of endogenous MARK results in increased tau phosphorylation within its microtubule-binding domain in situ.     

The DCX-domain tandems of doublecortin and doublecortin-like kinase

The doublecortin-like domains (DCX), which typically occur in tandem, are novel microtubule-binding modules. DCX tandems are found in doublecortin, a 360-residue protein expressed in migrating neurons; the doublecortin-like kinase (DCLK); the product of the RP1 gene that is responsible for a form of inherited blindness; and several other proteins. Mutations in the gene encoding doublecortin cause lissencephaly in males and the 'double-cortex syndrome' in females. We here report a solution structure of the N-terminal DCX domain of human doublecortin and a 1.5 A resolution crystal structure of the equivalent domain from human DCLK. Both show a stable, ubiquitin-like tertiary fold with distinct structural similarities to GTPase-binding domains. We also show that the C-terminal DCX domains of both proteins are only partially folded. In functional assays, the N-terminal DCX domain of doublecortin binds only to assembled microtubules, whereas the C-terminal domain binds to both microtubules and unpolymerized tubulin.     

DCLK1 phosphorylates the microtubule‐associated protein MAP7D1 to promote axon elongation in cortical neurons

Doublecortin‐like kinase 1 (DCLK1) is a member of the neuronal microtubule‐associated doublecortin (DCX) family and functions in multiple stages of neural development including radial migration and axon growth of cortical neurons. DCLK1 is suggested to play the roles in part through its protein kinase activity, yet the kinase substrates of DCLK1 remain largely unknown. Here we have identified MAP7D1 (microtubule‐associated protein 7 domain containing 1) as a novel substrate of DCLK1 by using proteomic analysis. MAP7D1 is expressed in developing cortical neurons, and knockdown of MAP7D1 in layer 2/3 cortical neurons results in a significant impairment of callosal axon elongation, but not of radial migration, in corticogenesis. We have further defined the serine 315 (Ser 315) of MAP7D1 as a DCLK1‐induced phosphorylation site and shown that overexpression of a phosphomimetic MAP7D1 mutant in which Ser 315 is substituted with glutamic acid (MAP7D1 S315E), but not wild‐type MAP7D1, fully rescues the axon elongation defects in Dclk1 knockdown neurons. These data demonstrate that DCLK1 phosphorylates MAP7D1 on Ser 315 to facilitate axon elongation of cortical neurons. © 2016 Wiley Periodicals, Inc. Develop Neurobiol 77: 419–437, 2017     

Formin-1 protein associates with microtubules through a peptide domain encoded by exon-2

Formin family proteins coordinate actin filaments and microtubules. The mechanisms by which formins bind and regulate the actin cytoskeleton have recently been well defined. However, the molecular mechanism by which formins coordinate actin filaments and microtubules remains poorly understood. We demonstrate here that Isoform-Ib of the Formin-1 protein (Fmn1-Ib) binds to microtubules via a protein domain that is physically separated from the known actin-binding domains. When expressed at low levels in NIH3T3 fibroblasts, Fmn1-Ib protein localizes to cytoplasmic filaments that nocodazole disruption confirmed as interphase microtubules. A series of progressive mutants of Fmn1-Ib demonstrated that deletion of exon-2 caused dissociation from microtubules and a stronger association with actin membrane ruffles. The exon-2-encoded peptide binds purified tubulin in vitro and is also sufficient to localize GFP to microtubules. Exon-2 does not contain any known formin homology domains. Deletion of exon 5, 7, 8, the FH1 domain or FH2 domain did not affect microtubule binding. Thus, our results indicate that exon-2 of Fmn1-Ib encodes a novel microtubule-binding peptide. Since formin proteins associate with actin filaments through the FH1 and FH2 domains, binding to interphase microtubules through this exon-2-encoded domain provides a novel mechanism by which Fmn1-Ib could coordinate actin filaments and microtubules.     

Protein kinase C inhibits type VI adenylyl cyclase by phosphorylating the regulatory N domain and two catalytic C1 and C2 domains

We previously showed that phosphorylation of Ser(10) of the N terminus domain of the type VI adenylyl cyclase (ACVI) partly mediated protein kinase C (PKC)-induced inhibition of ACVI. We now report that phosphorylation of the other two cytosolic domains (C1 and C2), which form the catalytic core complex of ACVI, also contributes to PKC-mediated inhibition. In vitro phosphorylation by PKC of the recombinant C1a and C2 domains, and of the synthetic peptides representing potential PKC phosphorylation sites, suggests that Ser(568) and Ser(674) of the C1 domain and Thr(931) of the C2 domain might act as substrates for PKC. We next created several full-length ACVI mutants in which one or more of the four likely PKC phosphorylation sites (Ser(10), Ser(568), Ser(674), and Thr(931)) were mutated to alanine. Simultaneous mutation of at least two of the three likely residues located in the N and C1 domains (Ser(10), Ser(568), and Ser(674)) was required to render ACVI variants completely insensitive to PKC treatment. In contrast, a single mutation of Thr(931) was sufficient to create a functional ACVI mutant that exhibited no detectable PKC-mediated inhibition, demonstrating the essentiality of Thr(931) to PKC-mediated regulation. Based on these results, we propose that the three cytosolic domains of ACVI might form a regulatory complex. Phosphorylation of this regulatory complex at different sites might induce a fine-tuning of the catalytic core complex and subsequently lead to alternation in the catalytic activity of ACVI.     

Tyrosine phosphorylation of protein kinase D in the pleckstrin homology domain leads to activation

Protein kinase D (PKD) is a member of the AGC family of Ser/Thr kinases and is distantly related to protein kinase C (PKC). Formerly known as PKCmu, PKD contains protein domains not found in conventional PKC isoforms. A functional pleckstrin homology (PH) domain is critical for the regulation of PKD activity. Here we report that PKD is tyrosine-phosphorylated within the PH domain, leading to activation. This phosphorylation is mediated by a pathway that consists of the Src and Abl tyrosine kinases and occurs in response to stimulation with pervanadate and oxidative stress. Mutational analysis revealed three tyrosine phosphorylation sites (Tyr(432), Tyr(463), and Tyr(502)), which are regulated by the Src-Abl pathway, and phosphorylation of only one of these (Tyr(463)) leads to PKD activation. By using a phospho-specific antibody, we show that Abl directly phosphorylates PKD at Tyr(463) in vitro, and in cells phosphorylation of this site is sufficient to mediate full activation of PKD. Mutation of the other two sites, Tyr(432) and Tyr(502), had no significant influence on PKD activity. These data reveal a tyrosine phosphorylation-dependent activation mechanism for PKD and suggest that this event contributes to the release of the autoinhibitory PKD PH domain leading to kinase activation and downstream responses.     

The Microtubule Binding Properties of CENP-E's C-Terminus and CENP-F

CENP-E (centromere protein E) and CENP-F (centromere protein F), also known as mitosin, are large, multi-functional proteins associated with the outer kinetochore. CENP-E features a well-characterized kinesin motor domain at its N-terminus and a second microtubule-binding domain at its C-terminus of unknown function. CENP-F is important for the formation of proper kinetochore–microtubule attachment and, similar to CENP-E, contains two microtubule-binding domains at its termini. While the importance of these proteins is known, the details of their interactions with microtubules have not yet been investigated. We have biochemically and structurally characterized the microtubule-binding properties of the amino- and carboxyl-terminal domains of CENP-F as well as the carboxyl-terminal (non-kinesin) domain of CENP-E. CENP-E's C-terminus and CENP-F's N-terminus bind microtubules with similar affinity to the well-characterized Ndc80 complex, while CENP-F's C-terminus shows much lower affinity. Electron microscopy analysis reveals that all of these domains engage the microtubule surface in a disordered manner, suggesting that these factors have no favored binding geometry and may allow for initial side-on attachments early in mitosis.     

Structure and interactions of PAS kinase N-terminal PAS domain: model for intramolecular kinase regulation

PAS domains are sensory modules in signal-transducing proteins that control responses to various environmental stimuli. To examine how those domains can regulate a eukaryotic kinase, we have studied the structure and binding interactions of the N-terminal PAS domain of human PAS kinase using solution NMR methods. While this domain adopts a characteristic PAS fold, two regions are unusually flexible in solution. One of these serves as a portal that allows small organic compounds to enter into the core of the domain, while the other binds and inhibits the kinase domain within the same protein. Structural and functional analyses of point mutants demonstrate that the compound and ligand binding regions are linked, suggesting that the PAS domain serves as a ligand-regulated switch for this eukaryotic signaling system.     

A microtubule-binding domain in dynactin increases dynein processivity by skating along microtubules

Microtubule-associated proteins (MAPs) use particular microtubule-binding domains that allow them to interact with microtubules in a manner specific to their individual cellular functions. Here, we have identified a highly basic microtubule-binding domain in the p150 subunit of dynactin that is only present in the dynactin members of the CAP-Gly family of proteins. Using single-particle microtubule-binding assays, we found that the basic domain of dynactin moves progressively along microtubules in the absence of molecular motors - a process we term 'skating'. In contrast, the previously described CAP-Gly domain of dynactin remains firmly attached to a single point on microtubules. Further analyses showed that microtubule skating is a form of one-dimensional diffusion along the microtubule. To determine the cellular function of the skating phenomenon, dynein and the dynactin microtubule-binding domains were examined in single-molecule motility assays. We found that the basic domain increased dynein processivity fourfold whereas the CAP-Gly domain inhibited dynein motility. Our data show that the ability of the basic domain of dynactin to skate along microtubules is used by dynein to maintain longer interactions for each encounter with microtubules.     

Identification of the ATP-binding domain of vaccinia virus thymidine kinase

Although small in size (20 kDa), the vaccinia virus (VV) thymidine kinase protein (EC 2.7.1.21 TK) is a relatively complex enzyme which must contain domains involved in binding both substrates (ATP and thymidine) and a feedback inhibitor (dTTP), as well as sequences directing the association of individual protein monomers into a functional tetrameric enzyme. Alignment of predicted amino acid sequences of the thymidine kinase genes from a variety of sources was used to identify highly conserved regions as a first step toward locating potential regions housing essential domains. A conserved domain (domain I) near the amino terminus of VV TK protein had characteristics consistent with a nucleotide-binding site. Analysis of the nucleotide substrate specificity of VV TK indicated that ATP acts as the major phosphate donor for thymidine phosphorylation while GTP, CTP, and UTP were inefficient substrates. Site-directed mutagenesis was performed on domain I to generate 11 mutant enzymes. Comparison of the wild-type and mutant proteins with regard to enzyme activity revealed that two of the mutant enzymes, T18 and S19, exhibited enhanced enzyme activity (3.73-fold and 1.35-fold, respectively) relative to the control. The other mutations introduced led to greatly reduced levels of enzyme activity which correlated with a reduced or altered ability of the mutant enzymes to bind ATP as determined by ATP-agarose affinity chromatography. Wild-type VV TK bound to an ATP affinity column could also be eluted with dTTP. Glycerol gradient separation of wild-type TK in the presence or absence of dTTP indicated that dissociation of the tetrameric complex was not the means by which enzymatic inhibition was achieved. Taken together, these results suggest that (i) domain I (amino acids 11-22) of the VV TK corresponds to the ATP-binding site, and (ii) that dTTP is able to interfere with ATP binding, either directly or indirectly, and thereby inhibit enzymatic activity without dissociating the native enzyme.     

Insulin receptor kinase domain autophosphorylation regulates receptor enzymatic function.

We have studied a series of insulin receptor molecules in which the 3 tyrosine residues which undergo autophosphorylation in the kinase domain of the beta-subunit (Tyr1158, Tyr1162, and Tyr1163) were replaced individually, in pairs, or all together with phenylalanine or serine by in vitro mutagenesis. A single-Phe replacement at each of these three positions reduced insulin-stimulated autophosphorylation of solubilized receptor by 45-60% of that observed with wild-type receptor. The double-Phe replacements showed a 60-70% reduction, and substitution of all 3 tyrosine residues with Phe or Ser reduced insulin-stimulated tyrosine autophosphorylation by greater than 80%. Phosphopeptide mapping each mutant revealed that all remaining tyrosine autophosphorylation sites were phosphorylated normally following insulin stimulation, and no new sites appeared. The single-Phe mutants showed insulin-stimulated kinase activity toward a synthetic peptide substrate of 50-75% when compared with wild-type receptor kinase activity. Insulin-stimulated kinase activity was further reduced in the double-Phe mutants and barely detectable in the triple-Phe mutants. In contrast to the wild-type receptor, all of the mutant receptor kinases showed a significant reduction in activation following in vitro insulin-stimulated autophosphorylation. When studied in intact Chinese hamster ovary cells, insulin-stimulated receptor autophosphorylation and tyrosine phosphorylation of the cellular substrate pp185 in the single-Phe and double-Phe mutants was progressively lower with increased tyrosine replacement and did not exceed the basal levels in the triple-Phe mutants. However, all the mutant receptors, including the triple-Phe mutant, retained the ability to undergo insulin-stimulated Ser and Thr phosphorylation. Thus, full activation of the insulin receptor tyrosine kinase is dependent on insulin-stimulated Tris phosphorylation of the kinase domain, and the level of autophosphorylation in the kinase domain provides a mechanism for modulating insulin receptor kinase activity following insulin stimulation. By contrast, insulin stimulation of receptor phosphorylation on Ser and Thr residues by cellular serine/threonine kinases can occur despite markedly reduced tyrosine autophosphorylation.     

Interdomain interaction reconstitutes the functionality of PknA, a eukaryotic type Ser/Thr kinase from Mycobacterium tuberculosis

Eukaryotic type Ser/Thr protein kinases have recently been shown to regulate a variety of cellular functions in bacteria. PknA, a transmembrane Ser/Thr protein kinase from Mycobacterium tuberculosis, when constitutively expressed in Escherichia coli resulted in cell elongation and therefore has been thought to be regulating morphological changes associated with cell division. Bioinformatic analysis revealed that PknA has N-terminal catalytic, juxtamembrane, transmembrane, and C-terminal extracellular domains, like known eukaryotic type Ser/Thr protein kinases from other bacteria. To identify the minimum region capable of exhibiting phosphorylation activity of PknA, we created several deletion mutants. Surprisingly, we found that the catalytic domain itself was not sufficient for exhibiting phosphorylation ability of PknA. However, the juxtamembrane region together with the kinase domain was necessary for the enzymatic activity and thus constitutes the catalytic core of PknA. Utilizing this core, we deduce that the autophosphorylation of PknA is an intermolecular event. Interestingly, the core itself was unable to restore the cell elongation phenotype as manifested by the full-length protein in E. coli; however, its co-expression along with the C-terminal region of PknA can associate them in trans to reconstitute a functional protein in vivo. Therefore, these findings argue that the transmembrane and extracellular domains of PknA, although dispensable for phosphorylation activities, are crucial in responding to signals. Thus, our results for the first time establish the significance of different domains in a bacterial eukaryotic type Ser/Thr kinase for reconstitution of its functionality.     

Brassinosteroid-insensitive-1 is a ubiquitously expressed leucine-rich repeat receptor serine/threonine kinase

Brassinosteroid (BR) mutants of Arabidopsis have pleiotropic phenotypes and provide evidence that BRs function throughout the life of the plant from seedling development to senescence. Screens for BR signaling mutants identified one locus, BRI1, which encodes a protein with homology to leucine-rich repeat receptor serine (Ser)/threonine (Thr) kinases. Twenty-seven alleles of this putative BR receptor have been isolated to date, and we present here the identification of the molecular lesions of 14 recessive alleles that represent five new mutations. BR-insensitive-1 (BRI1) is expressed at high levels in the meristem, root, shoot, and hypocotyl of seedlings and at lower levels later in development. Confocal microscopy analysis of full-length BRI1 fused to green fluorescent protein indicates that BRI1 is localized in the plasma membrane, and an in vitro kinase assay indicates that BRI1 is a functional Ser/Thr kinase. Among the bri1 mutants identified are mutants in the kinase domain, and we demonstrate that one of these mutations severely impairs BRI1 kinase activity. Therefore, we conclude that BRI1 is a ubiquitously expressed leucine-rich repeat receptor that plays a role in BR signaling through Ser/Thr phosphorylation.     

The tumor suppressor CYLD regulates microtubule dynamics and plays a role in cell migration

The familial cylindromatosis tumor suppressor CYLD is known to contain three cytoskeleton-associated protein glycine-rich (CAP-Gly) domains, which exist in a number of microtubule-binding proteins and are responsible for their association with microtubules. However, it remains elusive whether CYLD interacts with microtubules and, if so, whether the interaction is mediated by the CAP-Gly domains. In this study, our data demonstrate that CYLD associates with microtubules both in cells and in vitro, and the first CAP-Gly domain of CYLD is mainly responsible for the interaction. Knockdown of cellular CYLD expression dramatically delays microtubule regrowth after nocodazole washout, indicating an activity for CYLD in promoting microtubule assembly. Our data further demonstrate that CYLD enhances tubulin polymerization into microtubules by lowering the critical concentration for microtubule assembly. In addition, we have identified by wound healing assay a critical role for CYLD in mediating cell migration and found that its first CAP-Gly domain is required for this activity. Thus CYLD joins a growing list of CAP-Gly domain-containing proteins that regulate microtubule dynamics and function.