The PINOID protein kinase regulates organ development in Arabidopsis by enhancing polar auxin transport

Arabidopsis pinoid mutants show a strong phenotypic resemblance to the pin-formed mutant that is disrupted in polar auxin transport. The PINOID gene was recently cloned and found to encode a protein-serine/threonine kinase. Here we show that the PINOID gene is inducible by auxin and that the protein kinase is present in the primordia of cotyledons, leaves and floral organs and in vascular tissue in developing organs or proximal to meristems. Overexpression of PINOID under the control of the constitutive CaMV 35S promoter (35S::PID) resulted in phenotypes also observed in mutants with altered sensitivity to or transport of auxin. A remarkable characteristic of high expressing 35S::PID seedlings was a frequent collapse of the primary root meristem. This event triggered lateral root formation, a process that was initially inhibited in these seedlings. Both meristem organisation and growth of the primary root were rescued when seedlings were grown in the presence of polar auxin transport inhibitors, such as naphthylphtalamic acid (NPA). Moreover, ectopic expression of PINOID cDNA under control of the epidermis-specific LTP1 promoter provided further evidence for the NPA-sensitive action of PINOID. The results presented here indicate that PINOID functions as a positive regulator of polar auxin transport. We propose that PINOID is involved in the fine-tuning of polar auxin transport during organ formation in response to local auxin concentrations.     

The AGC kinase,PINOID, blocks interactive ABCB/PIN auxin transport

Plant growth and development is determined by intracellular and intercellular auxin gradients that are controlled at first hand by auxin efflux catalysts of the ABCB/PGP and PIN families. ABCB transport activity was shown to be counter-actively regulated by protein phosphorylation by the AGC protein kinase, PINOID (PID), that is coordinated by interaction with the immunophilin-like FKBP42, TWISTED DWARF1 (TWD1). In contrast, PID was shown to determine PIN polarity, however, the direct impact of PID on PIN activity has yet not been tested. Co-expression in yeast indicates that PID had no effect on PIN1,2 alone but specifically inhibits interactive ABCB1-PIN1/PIN2 auxin efflux in an action that is dependent on its kinase activity. PIN1-PID co-transfection in N. benthamiana revealed that PID blocks PIN1-mediated auxin efflux without changing PIN1 location. In summary, these data provide evidence that PID phosphorylation does not only determine PIN polarity but also has a direct impact on transport activity of the activity of the binary PIN-ABCB1 complex.     

Antagonistic regulation of PIN phosphorylation by PP2A and PINOID directs auxin flux

In plants, cell polarity and tissue patterning are connected by intercellular flow of the phytohormone auxin, whose directional signaling depends on polar subcellular localization of PIN auxin transport proteins. The mechanism of polar targeting of PINs or other cargos in plants is largely unidentified, with the PINOID kinase being the only known molecular component. Here, we identify PP2A phosphatase as an important regulator of PIN apical-basal targeting and auxin distribution. Genetic analysis, localization, and phosphorylation studies demonstrate that PP2A and PINOID both partially colocalize with PINs and act antagonistically on the phosphorylation state of their central hydrophilic loop, hence mediating PIN apical-basal polar targeting. Thus, in plants, polar sorting by the reversible phosphorylation of cargos allows for their conditional delivery to specific intracellular destinations. In the case of PIN proteins, this mechanism enables switches in the direction of intercellular auxin fluxes, which mediate differential growth, tissue patterning, and organogenesis.     

Regulation of protein kinase C by the cytoskeletal protein calponin

Previous studies from this laboratory have shown that, upon agonist activation, calponin co-immunoprecipitates and co-localizes with protein kinase Cepsilon (PKCepsilon) in vascular smooth muscle cells. In the present study we demonstrate that calponin binds directly to the regulatory domain of PKC both in overlay assays and, under native conditions, by sedimentation with lipid vesicles. Calponin was found to bind to the C2 region of both PKCepsilon and PKCalpha with possible involvement of C1B. The C2 region of PKCepsilon binds to the calponin repeats with a requirement for the region between amino acids 160 and 182. We have also found that calponin can directly activate PKC autophosphorylation. By using anti-phosphoantibodies to residue Ser-660 of PKCbetaII, we found that calponin, in a lipid-independent manner, increased auto-phosphorylation of PKCalpha, -epsilon, and -betaII severalfold compared with control conditions. Similarly, calponin was found to increase the amount of (32)P-labeled phosphate incorporated into PKC from [gamma-(32)P]ATP. We also observed that calponin addition strongly increased the incorporation of radiolabeled phosphate into an exogenous PKC peptide substrate, suggesting an activation of enzyme activity. Thus, these results raise the possibility that calponin may function in smooth muscle to regulate PKC activity by facilitating the phosphorylation of PKC.     

Regulation of the antigen-induced F-actin response in rat basophilic leukemia cells by protein kinase C

Multivalent antigen that is capable of binding to and crosslinking the IgE receptors on rat basophilic leukemia (RBL) cells, induces a rapid and sustained rise in the content of filamentous actin. This reorganization of the actin may be responsible for changes in cellular morphology during the degranulation process. The antigen-stimulated polymerization of actin can be blocked in a dose-dependent manner by protein kinase inhibitors which also block degranulation. Conversely, reagents such as PMA, 1,2-dioctanoyl-sn-glycerol (diC8), and 1-oleoyl-2-acetyl-glycerol (OAG) which stimulate protein kinase C (PKC) also activate the rise in F-actin, although they have no effect on degranulation by themselves. The actin response which can be stimulated by the PKC activators can also be blocked by protein kinase inhibitors indicating that the PMA- and OAG-induced response is probably through activation of a protein kinase. Depletion of PKC activity through long term (20 h) exposure of RBL cells to PMA, also inhibited the F-actin response when the cells were stimulated with either multivalent antigen or OAG. External Ca++, which is an absolute requirement for degranulation, is not necessary for the rise in F-actin, but may modulate the response. Furthermore, ionomycin, which induces a large Ca++ influx, does not stimulate the F-actin increase even at doses that cause degranulation. These results suggest that activation of a protein kinase, such as PKC, may be responsible for signaling the polymerization of actin in RBL cells and that a rise in intracellular Ca++ is neither necessary nor sufficient for this response.     

Regulation of shoot branching by auxin

The idea that apically derived auxin inhibits shoot branching by inhibiting the activity of axillary buds was first proposed 70 years ago, but it soon became clear that its mechanism of action was complex and indirect. Recent advances in the study of axillary bud development and of auxin signal transduction are allowing a better understanding of the role of auxin in controlling shoot branching. These studies have identified a new role for auxin early in bud development as well as some of the second messengers involved in mediating the branch-inhibiting effects of auxin.     

Regulation of protein kinase CK1alphaLS by dephosphorylation in response to hydrogen peroxide

Low levels of hydrogen peroxide (H(2)O(2)) are mitogenic to mammalian cells and stimulate the hyperphosphorylation of heterogeneous nuclear ribonucleoprotein C (hnRNP-C) by protein kinase CK1alpha. However, the mechanisms by which CK1alpha is regulated have been unclear. Here it is demonstrated that low levels of H(2)O(2) stimulate the rapid dephosphorylation of CK1alphaLS, a nuclear splice form of CK1alpha. Furthermore, it is demonstrated that either treatment of endothelial cells with H(2)O(2), or dephosphorylation of CK1alphaLS in vitro enhances the association of CK1alphaLS with hnRNP-C. In addition, dephosphorylation of CK1alphaLS in vitro enhances the kinase's ability to phosphorylate hnRNP-C. While CK1alpha appears to be present in all metazoans, analysis of CK1alpha genomic sequences from several species reveals that the alternatively spliced nuclear localizing L-insert is unique to vertebrates, as is the case for hnRNP-C. These observations indicate that CK1alphaLS and hnRNP-C represent conserved components of a vertebrate-specific H(2)O(2)-responsive nuclear signaling pathway.     

Linking protein kinase CK2 and auxin transport

Studies performed in different organisms have highlighted the importance of protein kinase CK2 in cell growth and cell viability. However, the plant signaling pathways in which CK2 is involved are largely unknown. We have reported that a dominant-negative mutant of CK2 in Arabidopsis thaliana shows phenotypic traits that are typically linked to alterations in auxin-dependent processes. We demonstrated that auxin transport is, indeed, impaired in these mutant plants, and that this correlates with misexpression and mislocalization of PIN efflux transporters and of PINOID. Our data establishes a link between CK2 activity and the regulation of auxin homeostasis in plants, strongly suggesting that CK2 might be required at multiple points of the pathways regulating auxin fluxes.Key words: protein kinase CK2, root development, auxin, PIN, PINOIDThe plant hormone auxin plays critical roles in plant growth and development.¹ The most abundant natural auxin is the indol-3-acetic acid (IAA), which is synthesized in young apical tissues and then transported to the growing zones of the stem and root. The major route for long distance IAA movement is via the vascular tissue, but, additionally, a slower transport via cell-to-cell (called polar transport) is critical to generate auxin gradients within tissues. Formation of correct auxin gradients is thought to be essential for many plant developmental processes.² In recent years, the IAA transporters have been identified, establishing the molecular basis to understand how auxin transport is regulated. In particular, the identification of the family of plasma-resident PIN proteins, the members of which function as IAA efflux carriers, and the knowledge of their polar localization in the plasma membrane (PM), contributed to generate models predicting the direction of IAA fluxes.^3,4The factors that govern PIN targeting to a particular membrane domain are still not understood. It is known that PIN proteins constitutively undergo cycles of exocytosis and endocytosis to and from the PM, using distinct sorting and recycling endosome trafficking pathways.^5–7 Phosphorylation/dephosphorylation by the Ser/Thr kinase PINOID (PID) and the protein phosphatase 2A, respectively, controls PIN proteins apical/basal localization at the PM, via the GNOM-mediated vesicle trafficking system.⁸ Interestingly, PID is a member of the plant AGC kinases, and, as it happens with its mammals AGC counterparts, is activated by a membrane-associated 3-phosphoinositide-dependent kinase (PDK1).⁹ Moreover, a functional similarity between PIN polar localization in response to auxin and glucose receptor (GLUT4) asymmetrical distribution in response to insulin, has been pointed out.¹⁰ In both cases, cargo proteins (GLUT4 and PIN, respectively) are transported from endosomal vesicles to PM and the process is mediated by PDK1-activated AGC kinases.Protein kinase CK2 is a Ser/Thr kinase evolutionary conserved in eukaryotes, which plays key roles in cell survival, cell division and other cellular processes. A loss-of-function mutant of CK2 in Arabidopsis, obtained by overexpression of a CK2α-inactive subunit, confirmed the essential role of this protein kinase for plant viability.¹¹ Moreover, CK2mut plants showed a dramatic decrease of lateral root formation, inhibition of root growth and overproliferation of root hairs. We have further demonstrated that auxin transport is impaired in this plants, which is concomitant with missexpression of most of the PM-resident PIN proteins, and of PID.¹² In addition, PIN proteins accumulated in endosomal vesicles and auxin gradients were disturbed, both in roots and shoots of CK2mut plants. In particular, root columella cells were depleted of auxin, although the maximum at the quiescent center was unchanged. Starch granule staining with lugol revealed that columella cells retained their fate, although their organization and/or cell shape were clearly affected (Fig. 1).Open in a separate windowFigure 1Lugol-stained starch granules in uninduced (−Dex) and Dex-induced (+Dex) CK2mut roots. In the central part of the figure, a sketch of the main morphogenetic characteristics of mutant roots (right plantlet) as compared to wild-type roots (left plantlet) is shown. Note the shorter roots, wavy phenotype, absence of lateral roots and overproliferation of root hairs in mutant plants.Our results strongly suggest that CK2 is a regulator of auxin-dependent responses, most likely by participating in the regulation of auxin transport. Strikingly, depletion of CK2 activity inhibits some auxin-dependent physiological responses whereas it enhances others. For instance, whereas shoot phototropism was completely absent, root gravitropism was enhanced.¹² Figure 2 shows a time-course of DR5rev::GFP-derived signal after changing the gravity vector, in mutant and control Arabidopsis roots. The progressive auxin translocation to the lower side of the root after gravistimulation is more rapid and sustained in mutant than in control roots, which is likely responsible for the enhanced response to gravity found in mutant roots. Based on these results, we postulate that CK2 might act at different points of the auxin-induced regulatory pathway. As far as is known, the core module that regulates auxin transport is constituted by the protein kinase PID and a protein of the NPH3-domain family. NPH3-containing proteins play important roles in phototropic and gravitropic responses, and regulate polarity and endocytosis of PIN proteins.¹³ As has been proposed by other authors, the participation of one AGC kinase and one NPH3-like protein upstream of an ARF factor might be a common theme in response to different stimulus that are signaled by auxin.¹⁴ We propose that one of the functions of CK2 is the regulation of the activity of core proteins (Fig. 3). Mammalian AGC kinases are well known substrates of CK2 and CK2-dependent phosphorylation is critical for a full display of their activity. The PID and the NPH3-containing protein sequences contain numerous acidic-based motifs that are predicted CK2 phosphorylation sites. Moreover, according to Arabidopsis phosphoproteome databases, several members of the NPH3-containing protein family are predicted to be phosphorylated.¹⁵ In addition, we do not discard the possibility that other proteins involved in PIN transport might also be regulated by CK2-dependent phosphorylation. Experiments are in progress in our laboratory to assess the regulatory role of CK2 in auxin transport.Open in a separate windowFigure 2Time course of auxin relocation during root gravitropic response, as visualized by DR5rev::GFP fluorescence. Root pictures were taken at the indicated times after changing the direction of the gravity vector. Translocation of auxin to the lower part of the root is more rapid in Dex-induced CK2mut plants. Arrows indicate asymmetrical DR5::GFP fluorescence.Open in a separate windowFigure 3Proposed model for the role of CK2 in regulating auxin transport. The core module that regulates auxin transport (shown here as a black box) is constituted by the protein kinase PID and a protein of the NPH3-domain family. PID regulates apical-basal targeting of PIN proteins, by phosphorylating conserved Ser residues present in PIN hydrophilic loops.¹⁶ On the other hand, the family of NPH3-containing proteins regulates polarity and endocytosis of PIN proteins.¹³ There is also a functional similarity between the intracellular transport of PIN proteins and that of the glucose receptor (GLUT4),¹⁰ two processes that are signaled by AGC kinases. We propose that CK2 might be a regulator of the activity of the core proteins, by phosphorylating either the AGC kinase and/or the NPH3-containing protein. Mammalian CK2 is a known regulator of the activity of AGC kinases and other proteins participating in signaling pathways, such as in the Wnt/β-catenin signaling pathway.¹⁷     

Regulation of a mitogen-activated protein kinase kinase kinase,MLTK by PKN

PKNalpha is a fatty acid- and Rho-activated serine/threonine protein kinase having a catalytic domain homologous to members of the protein kinase C family. Recently it was reported that PKNalpha is involved in the p38 mitogen-activated protein kinase (MAPK) signaling pathway. To date, however, how PKNalpha regulates the p38gamma MAPK signaling pathway is unclear. Here we demonstrate that PKNalpha efficiently phosphorylates MLTKalpha (MLK-like mitogen-activated protein triple kinase), which was recently identified as a MAPK kinase kinase (MAPKKK) for the p38 MAPK cascade. Phosphorylation of MLTKalpha by PKNalpha enhances its kinase activity in vitro. Expression of the kinase-negative mutant of PKNalpha inhibited the mobility shift of MLTKalpha caused by osmotic shock in SDS-PAGE. Furthermore, PKNalpha associates with each member of the p38gamma MAPK signaling pathway (p38gamma, MKK6, and MLTKalpha). These results suggest that PKNalpha functions as not only an upstream activator of MLTKalpha but also a putative scaffold protein for the p38gamma MAPK signaling pathway.     

Regulation of the unfolded protein response by microRNAs

The unfolded protein response (UPR) is an adaptive response to the stress that is caused by an accumulation of misfolded proteins in the lumen of the endoplasmic reticulum (ER). It is an important component of cellular homeostasis. During ER stress, the UPR increases the protein-folding capacity of the endoplasmic reticulum to relieve the stress. Failure to recover leads to apoptosis. Specific cellular mechanisms are required for the cellular recovery phase after UPR activation. Using bioinformatics tools, we identified a number of microRNAs that are predicted to decrease the mRNA expression levels for a number of critical components of the UPR. In this review, we discuss the potential role of microRNAs as key regulators of this pathway and describe how microRNAs may play an essential role in turning off the UPR after the stress has subsided.     

Regulation of protein kinase C activity by lipids

Protein kinase C is activated by the simultaneous presence of phospholipid, a diglyceride, and Ca2+. Under physiological conditions the activity of the enzyme is regulated by the availability of diglycerides, which are the products of phosphoinositide hydrolysis. The phospholipid-kinase interactions appear not to be of a highly specific nature. Phosphatidylserine (PS) is presumed to be the endogenous lipid that interacts with the kinase, but other acidic lipids can substitute. On the other hand, the kinase-diglyceride interactions are highly specific in nature, as would be expected of a physiological regulator. These interactions are stereo-specific and stoichiometric with respect to diglyceride. The specificity is directed toward the glycerol backbone and hydrophilic oxygen moieties of the diglyceride. The removal of one or more of the oxygen atoms or the addition of a single methyl group to the glycerol backbone virtually abolishes the activity of a putative diglyceride activator. The extreme specificity of the kinase toward the diglycerides, however, must be contrasted with the abilities of structurally diverse tumor promotors and irritants to activate the kinase. Specific small-molecule antagonists of protein kinase C have yet to be developed. The small-molecule antagonists that have been developed so far have been relatively nonspecific cationic lipids that appear to function by interfering with the interaction between the acidic phospholipids and Ca2+.     

Regulation of nutrient uptake by AMP-activated protein kinase

AMP-activated protein kinase (AMPK) is the downstream component of a protein kinase cascade that is a key regulator of energy balance at both the cellular and whole-body level. AMPK acts to stimulate ATP production and reduce ATP consumption when cellular ATP levels fall, thereby normalizing energy balance. Given the central role of AMPK in cellular carbohydrate and lipid metabolism, AMPK activation has been proposed to be a therapeutic target for conditions associated with dysfunctional nutrient metabolism including obesity, type 2 diabetes, hepatic steatosis, cardiovascular diseases and cancer. One way by which increased ATP production can be achieved is by increasing the supply of nutrient substrates. In the 1990s, AMPK activation was demonstrated to stimulate glucose uptake in striated muscle, thereby improving substrate supply for ATP production. Subsequently AMPK activation was postulated to underlie the increase in glucose uptake that occurs during muscle contraction. More recently, however, several lines of evidence have demonstrated that AMPK activation is unlikely to be required for contraction-mediated glucose uptake. Furthermore, despite the importance of AMPK in cellular and whole-body metabolism, far fewer studies have investigated either the role of AMPK in glucose uptake by non-muscle tissues or whether AMPK regulates the uptake of fatty acids. In the present review, we discuss the role of AMPK in nutrient uptake by tissues, focusing on glucose uptake out with muscle and fatty acid uptake.     

Regulation of cAMP-dependent protein kinase activity by glutathionylation

The catalytic subunit of cAMP-dependent protein kinase (cAPK) is susceptible to inactivation by a number of thiol-modifying reagents. Inactivation occurs through modification of cysteine 199, which is located near the active site. Because cysteine 199 is reactive at physiological pH, and modification of this site inhibits activity, we hypothesized that cAPK is a likely target for regulation by an oxidative mechanism, specifically glutathionylation. In vitro studies demonstrated the susceptibility of kinase activity to the sulfhydryl oxidant diamide, which inhibited by promoting an intramolecular disulfide bond between cysteines 199 and 343. In the presence of a low concentration of diamide and reduced glutathione, the kinase was rapidly and reversibly inhibited by glutathionylation. Mutant kinase containing an alanine to cysteine mutation at position 199 was resistant to inhibition by both diamide and glutathionylation, thus implicating this as the oxidation-sensitive site. Mouse fibroblast cells treated with diamide showed a reversible decrease in cAPK activity. Inhibition was dramatically enhanced when cells were first treated with cAPK activators. Using biotin-cysteine as means for detecting and purifying thiolated cAPK from cells, we were able to show that, under conditions in which cAPK is inactivated by diamide, it is also readily thiolated.     

Regulation of protein kinase C activity by gangliosides

The activity of protein kinase C (Ca2+/phospholipid-dependent enzyme) in the presence of phosphatidylserine and its physiological regulator, diacylglycerol, could be suppressed by a mixture of brain gangliosides. Half-maximal inhibition was observed at 30 microM and was nearly complete at 100 microM. Inhibition was observed at all concentrations of Ca2+ between 10(-8) and 10(-4) M. Inhibition of protein kinase C activity could not be reversed by increasing the concentration of diacylglycerol or the substrate, histone. Inhibition was also observed when myelin basic protein or a synthetic myelin basic protein peptide was used as substrate. Among the individual gangliosides, the rank order of potency was GT1b greater than GD1a = GD1b greater than GM3 = GM1. Our results suggest that gangliosides may regulate the responsiveness of protein kinase C to diacylglycerol.     

Regulation of phospholipase D by protein kinase C

In nearly all mammalian cells and tissues examined, protein kinase C (PKC) has been shown to serve as a major regulator of a phosphatidylcholine-specific phospholipase D (PLD) activity, At least 12 distinct isoforms of PKC have been described so far; of these enzymes only the α- and β-isoform were found to regulate PLD activity, While the mechanism of this regulation has remained unknown, available evidence suggests that both phosphorylating and non-phosphorylating mechanisms may be involved. A phosphatidylcholine-specific PLD activity was recently purified from pig lung, but its possible regulation by PKC has not been reported yet. Several cell types and tissues appear to express additional forms of PLD which can hydrolyze either phosphatidylethanolamine or phosphatidylinositol. It has also been reported that at least one form of PLD can be activated by oncogenes, but not by PKC activators, Similar to activated PKC, some of the primary and secondary products of PLD-mediated phospholipid hydrolysis, including phosphatidic acid, 1,2-diacylglycerol, choline phosphate and ethanolamine, also exhibit mitogenic/co-mitogenic effects in cultured cells. Furthermore, both the PLD and PKC systems have been implicated in the regulation of vesicle transport and exocytosis. Recently the PLD enzyme has been cloned and the tools of molecular biology to study its biological roles will soon be available. Using specific inhibitors of growth regulating signals and vesicle transport, so far no convincing evidence has been reported to support the role of PLD in the mediation of any of the above cellular effects of activated PKC.