Analysis of the protein kinome of Entamoeba histolytica

Protein kinases play important roles in almost all major signaling and regulatory pathways of eukaryotic organisms. Members in the family of protein kinases make up a substantial fraction of eukaryotic proteome. Analysis of the protein kinase repertoire (kinome) would help in the better understanding of the regulatory processes. In this article, we report the identification and analysis of the repertoire of protein kinases in the intracellular parasite Entamoeba histolytica. Using a combination of various sensitive sequence search methods and manual analysis, we have identified a set of 307 protein kinases in E. histolytica genome. We have classified these protein kinases into different subfamilies originally defined by Hanks and Hunter and studied these kinases further in the context of noncatalytic domains that are tethered to catalytic kinase domain. Compared to other eukaryotic organisms, protein kinases from E. histolytica vary in terms of their domain organization and displays features that may have a bearing in the unusual biology of this organism. Some of the parasitic kinases show high sequence similarity in the catalytic domain region with calmodulin/calcium dependent protein kinase subfamily. However, they are unlikely to act like typical calcium/calmodulin dependent kinases as they lack noncatalytic domains characteristic of such kinases in other organisms. Such kinases form the largest subfamily of kinases in E. histolytica. Interestingly, a PKA/PKG-like subfamily member is tethered to pleckstrin homology domain. Although potential cyclins and cyclin-dependent kinases could be identified in the genome the likely absence of other cell cycle proteins suggests unusual nature of cell cycle in E. histolytica. Some of the unusual features recognized in our analysis include the absence of MEK as a part of the Mitogen Activated Kinase signaling pathway and identification of transmembrane region containing Src kinase-like kinases. Sequences which could not be classified into known subfamilies of protein kinases have unusual domain architectures. Many such unclassified protein kinases are tethered to domains which are Cysteine-rich and to domains known to be involved in protein-protein interactions. Our kinome analysis of E. histolytica suggests that the organism possesses a complex protein phosphorylation network that involves many unusual kinases.     

PTB domain-directed substrate targeting in a tyrosine kinase from the unicellular choanoflagellate Monosiga brevicollis

Choanoflagellates are considered to be the closest living unicellular relatives of metazoans. The genome of the choanoflagellate Monosiga brevicollis contains a surprisingly high number and diversity of tyrosine kinases, tyrosine phosphatases, and phosphotyrosine-binding domains. Many of the tyrosine kinases possess combinations of domains that have not been observed in any multicellular organism. The role of these protein interaction domains in M. brevicollis kinase signaling is not clear. Here, we have carried out a biochemical characterization of Monosiga HMTK1, a protein containing a putative PTB domain linked to a tyrosine kinase catalytic domain. We cloned, expressed, and purified HMTK1, and we demonstrated that it possesses tyrosine kinase activity. We used immobilized peptide arrays to define a preferred ligand for the third PTB domain of HMTK1. Peptide sequences containing this ligand sequence are phosphorylated efficiently by recombinant HMTK1, suggesting that the PTB domain of HMTK1 has a role in substrate recognition analogous to the SH2 and SH3 domains of mammalian Src family kinases. We suggest that the substrate recruitment function of the noncatalytic domains of tyrosine kinases arose before their roles in autoinhibition.     

Comparative kinomics of Plasmodium organisms: unity in diversity

Phosphorylation by protein kinases is a very common and crucial process in many signal transduction pathways in eukaryotes. This review describes comparative protein kinase analysis of two apicomplexa Plasmodium falciparum (3D7 strain) and Plasmodium yoelii yoelii (17XNL strain) which are causative agents of malaria in human and African rat respectively. Sensitive bioinformatics techniques enable identification of 82 and 60 putative protein kinases in P. falciparum and P. yoelii yoelii respectively and these sequences could be classified into known subfamilies of protein kinases. The most populated kinase subfamilies in both the plasmodium species correspond to CAMK and CMGC groups. Analysis of domain architectures enables detection of uncommon domain organization in kinases of both the organisms such as kinase domain tethered to EF hands as well as PH domain. Components of MAPK signaling pathway is not well conserved in plasmodium organisms. Such observations suggest that plasmodium protein kinases are highly divergent from other eukaryotes. A transmembrane kinase with 6 membrane spanning segments in P. falciparum seems to have no orthologue in P. yoelii yoelii. 19 P. falciparum kinases have been found to cluster separately from P. yoelii yoelii kinases and hence these kinases are unique to P. falciparum genome. Only 28 orthologous pairs of kinases seem to be present between these two plasmodium organisms. Comparative kinome analysis of two plasmodium species has thus provided clues to the function of many protein kinases based upon their classification and domain organization and also implicate marked differences even between two plasmodium organisms.     

Regulation of protein kinases by lipids

Membranes are sites of intense signaling activity within the cell, serving as dynamic scaffolds for the recruitment of signaling molecules and their substrates. The specific and reversible localization of these signaling molecules to membranes is critical for the appropriate activation of downstream signaling pathways. Phospholipid-binding domains, including C1, C2, PH, and PX domains, play critical roles in the membrane targeting of protein kinases. Recent structural studies have identified a new membrane association domain, the Kinase Associated 1 (KA1) domain, which targets a number of yeast and mammalian protein kinases to membranes containing acidic phospholipids. Despite an abundance of localization studies on lipid-binding proteins and structural studies of the isolated lipid-binding domains, the question of how membrane binding is coupled to the activation of the kinase catalytic domain has been virtually untouched. Recently, structural studies on protein kinase C (PKC) have provided some of the first structural insights into the allosteric regulation of protein kinases by lipid second messengers.     

PfPKB, a novel protein kinase B-like enzyme from Plasmodium falciparum: I. Identification, characterization, and possible role in parasite development

Extracellular signals control various important functions of a eukaryotic cell, which is often achieved by regulating a battery of protein kinases and phosphatases. Protein Kinase B (PKB) is an important member of the phosphatidylinositol 3-kinase-dependent signaling pathways in several eukaryotes, but the role of PKB in protozoan parasites is not known. We have identified a protein kinase B homologue in Plasmodium falciparum (PfPKB) that is expressed mainly in the schizonts and merozoites. Even though PfPKB shares high sequence homology with PKB catalytic domain, it lacks a pleckstrin homology domain typically found at the N terminus of the mammalian enzyme. Biochemical studies performed to understand the mechanism of PfPKB catalytic activation suggested (i) its activation is dependent on autophosphorylation of a serine residue (Ser-271) in its activation loop region and (ii) PfPKB has an unusual N-terminal region that was found to negatively regulate its catalytic activity. We also identified an inhibitor of PfPKB activity that also inhibits P. falciparum growth, suggesting that this enzyme may be important for the development of the parasite.     

Genome-wide comparative analyses of domain organisation of repertoires of protein kinases of Arabidopsis thaliana and Oryza sativa

A comparative analysis on protein kinases encoded in the completely sequenced genomes of two plant species, namely Arabidopsis thaliana and Oryza sativa spp japonica cv. Nipponbare is reported in the current study. We have analysed 836 and 1386 kinases identified from A. thaliana and the O. sativa genomes respectively. Their classification into known subfamilies reveals selective expansions of the plant receptor kinase subfamily comprising of Ser/Thr receptor kinases. The presence of calcium dependent kinases, and potential absence of cyclic nucleotide-dependent protein kinase of the type found in other (non-plant) eukaryotes, are other notable features of the two plant kinomes described here. An analysis on domain organisation of each of the protein kinases encoded in the plant genome has been carried out. Uncommon composition of functional domains like nuclear translocation factor domain, redox sensor domain (PAS), ACT and lectin domains are observed in few protein kinases shared between the two plant species. Biochemical functions characteristic of the domains recruited in these protein kinase gene products suggest their mode of regulation by alternate cellular localisation, oxidation potential, amino acid flux and binding of carbohydrates. Occurrence of multi-functional kinases with diverse enzymatic modules, such as Transposases and peptidases, tethered to the kinase catalytic domain is another interesting feature of the protein kinase complement of the O. sativa genome. Co-occurrence of diverse nucleotide and carbohydrate binding domains with catalytic kinase domain containing gene products has also been observed. Putative homologues of protein kinases of A. thaliana that regulate plant-specific physiological processes like ethylene hormone response, somatic embryogenesis and pathogen defence have been identified in O. sativa genome as well.     

Isolation and characterization of a <Emphasis Type="Italic">Paramecium</Emphasis> cDNA clone encoding a putative serine/threonine protein kinase

Mitogen-activated protein (MAP) kinases, a closely related family of protein kinases, are involved in cell cycle regulation and differentiation in yeast and human cells. They have not been documented in ciliates. We used PCR to amplify DNA sequences of a ciliated protozoan—Paramecium caudatum—using primers corresponding to amino acid sequences that are common to MAP kinases. We isolated and sequenced one putative MAP kinase-like serine/threonine kinase cDNA from P. caudatum. This cDNA, called pcstk1 (Paramecium caudatum Serine/Threonine Kinase 1) shared approximately 35% amino acid identity with MAP kinases from yeast. MAP kinases are activated by phosphorylation of specific threonine and tyrosine residues. These two amino acid residues are conserved in the PCSTK1 sequence at positions Thr 159 and Tyr 161. The PSTAIRE motif, which is characteristic of the CDK2 gene family, cannot be found in ORF of PCSTK1. The highest homology score was to human STK9, which contains MAP type kinase domains. Comparisons of expression level have shown that pcstk1 is expressed equally in cells at different stages (sexual and asexual). We discussed the possibility, as in other organisms, that a family of MAP kinase genes exists in P. caudatum.     

MAP kinases and CDKs: kinetic basis for catalytic activation

Protein kinases constitute one of the largest enzyme families encoded by the human genome. Owing to their critical role in virtually all aspects of signal transduction, protein kinases have evolved stringent mechanisms for their regulation, which classically falls into two categories: regulation by pseudosubstrate autoinhibitory domains, and remodeling of the catalytic core in response to phosphorylation and/or protein/protein interactions. While the action of pseudosubstrate domains can be explained by simple competitive autoinhibition kinetics, it is less well understood how active site phosphorylation and/or protein/protein interactions alter rates of catalysis. Here, the kinetic basis for kinase activation is discussed in relation to the MAP kinase, ERK2, and the cyclin-dependent kinase, CDK2/cyclin A, two enzymes of central importance to mammalian cell growth and division, and which serve as prototypic models of nonautoinhibitory regulation.     

The repertoire of protein kinases encoded in the draft version of the human genome: atypical variations and uncommon domain combinations

Background

Phosphorylation by protein kinases is central to cellular signal transduction. Abnormal functioning of kinases has been implicated in developmental disorders and malignancies. Their activity is regulated by second messengers and by the binding of associated domains, which are also influential in translocating the catalytic component to their substrate sites, in mediating interaction with other proteins and carrying out their biological roles.

Result

Using sensitive profile-search methods and manual analysis, the human genome has been surveyed for protein kinases. A set of 448 sequences, which show significant similarity to protein kinases and contain the critical residues essential for kinase function, have been selected for an analysis of domain combinations after classifying the kinase domains into subfamilies. The unusual domain combinations in particular kinases suggest their involvement in ubiquitination pathways and alternative modes of regulation for mitogen-activated protein kinase kinases (MAPKKs) and cyclin-dependent kinase (CDK)-like kinases. Previously unexplored kinases have been implicated in osteoblast differentiation and embryonic development on the basis of homology with kinases of known functions from other organisms. Kinases potentially unique to vertebrates are involved in highly evolved processes such as apoptosis, protein translation and tyrosine kinase signaling. In addition to coevolution with the kinase domain, duplication and recruitment of non-catalytic domains is apparent in signaling domains such as the PH, DAG-PE, SH2 and SH3 domains.

Conclusions

Expansion of the functional repertoire and possible existence of alternative modes of regulation of certain kinases is suggested by their uncommon domain combinations. Experimental verification of the predicted implications of these kinases could enhance our understanding of their biological roles.

     

Influence of human p16(INK4) and p21(CIP1) on the in vitro activity of recombinant Plasmodium falciparum cyclin-dependent protein kinases.

The regulatory mechanisms of most cyclin dependent protein kinases (CDKs) are well understood and are highly conserved in eukaryotes. CDKs from the malaria parasite, Plasmodium falciparum, appear to be regulated in a similar manner with regard to cyclin binding and phosphorylation. In order to further understand their regulatory mechanisms, we examined two classes of cyclin dependent kinase inhibitors (CDIs) to inhibit a panel of plasmodial CDKs. We find that Pfmrk and PfPK5 are inhibited by heterologous p21(CIP1) with varying degrees of inhibition. In contrast, PfPK6, a kinase with sequence features characteristic of both a CDK and MAP kinase, is unaffected by this CDI. Furthermore, the CDK4/6 specific CDI, p16(INK4), fails to inhibit these plasmodial CDKs. Taken together, these results suggest that plasmodial CDKs may be regulated by the binding of inhibitory proteins in vivo.     

Identification of functionally distinct regions that mediate biological activity of the protein kinase a homolog Tpk2

Kinases regulate key signaling processes that are increasingly implicated in development and disease. Kinase modulators have become important therapeutic tools and often target catalytic domains that are among the most structurally and functionally conserved regions of these enzymes. Such therapies lose efficacy as mutations conferring resistance arise. Because interactions between distinct and often distant regions of kinases can be critical, we took an unbiased genetic approach to identify sites within the protein kinase A homolog Tpk2 that contribute to its biological activity. Because many of these map outside the conserved core, this approach should be broadly useful in identifying new, more kinase-specific therapeutic targets.     

A new identity for MLK3 as an NIMA-related,cell cycle-regulated kinase that is localized near centrosomes and influences microtubule organization

Although conserved counterparts for most proteins involved in the G(2)/M transition of the cell cycle have been found in all eukaryotes, a notable exception is the essential but functionally enigmatic fungal kinase NIMA. While a number of vertebrate kinases have been identified with catalytic domain homology to NIMA, none of these resemble NIMA within its extensive noncatalytic region, a region critical for NIMA function in Aspergillus nidulans. We used a bioinformatics approach to search for proteins with homology to the noncatalytic region of NIMA and identified mixed lineage kinase 3 (MLK3). MLK3 has been proposed to serve as a component in MAP kinase cascades, particularly those resulting in the activation of the c-Jun N-terminal kinase (JNK). Here we describe the first in-depth study of endogenous MLK3 and report that, like NIMA, MLK3 phosphorylation and activity are enhanced during G(2)/M, whereas JNK remains inactive. Coincident with the G(2)/M transition, a period marked by dramatic reorganization of the cytoplasmic microtubule network, endogenous MLK3 transiently disperses away from the centrosome and centrosomal-proximal sites where it is localized during interphase. Furthermore, when overexpressed, MLK3, like NIMA, localizes to the centrosomal region, induces profound disruption of cytoplasmic microtubules and a nuclear distortion phenotype that differs from mitotic chromosome condensation. Cellular depletion of MLK3 protein using siRNA technology results in an increased sensitivity to the microtubule-stabilizing agent taxol. Our studies suggest a new role for MLK3, separable from its function in the JNK pathway, that may contribute to promoting microtubule instability, a hallmark of M phase entry.     

Functional assignment of MAPK phosphatase domains

Mitogen-activated protein kinase (MAPK) pathways are well conserved in most organisms, from yeast to humans. The principal components of these pathways are MAP kinases whose activity is regulated by phosphorylation, implicating various MAPK protein effectors-in particular, protein phosphatases that inactivate MAPKs by dephosphorylation. The molecular basis of binding specificity of such regulatory phosphatases to MAPKs is poorly understood. To try to pinpoint potential functional regions within the sequences and to help identify new family members, we have applied a multimotif pattern-recognition approach to characterize two MAPK phosphatase subfamilies (tyrosine-specific and dual specificity) that are crucial in the regulation of MAPKs. We built "fingerprints" for these two subfamilies that are unique to, and highly discriminatory for, each group of proteins. The fingerprints were used in a genome-wide screen, identifying more than 80 MAPK phosphatase domains, several of which were in partial sequences or unclassified proteins. We confirmed experimentally that one predicted MAPK phosphatase orthologue in Xenopus binds to ERK1/2, suggesting a role in MAPK signaling and thus supporting our functional predictions. Further analysis, mapping the fingerprints on the three-dimensional structure of MAPK phosphatases, revealed that some of the fingerprint motifs reside in the N-terminal noncatalytic regions coinciding with reported MAPK binding sites, while others lie within the catalytic phosphatase domain. These results also suggest the presence of putative allosteric sites in the catalytic region for modulation of protein-protein interactions, and provide a framework for future experimental validation.     

MAP Kinase analyser: A tool for plant kinase and substrate analysis

MAPK (Mitogen Activated Protein Kinase) is a Ser/Thr kinase, which plays a crucial role in plant growth and development, transferring the extra cellular stimuli into intracellular response etc. Manual identification of these MAPK in the plant genome is tedious and time taking process. There are number of online servers which predict the P-site (phosphorylation site), find the motifs and domain but there is no specific tool which can identify all them together. In order to identify the P-Site, phosphorylation site consensus sequences and domain of the MAPK in plant genome, we developed a tool, MAP Kinase analyzer. MAP kinase analyzer take protein sequence as input in the fasta format and the output of tool includes: 1) The prediction of the phosphorylation site viz., Serine (S), Threonine (T), and Tyrosine (Y), Contex, Position, Score and phosphorylating kinase as well as the graphical output; 2) Phosphorylation site consensus sequence pattern for different kinases and 3) Domain information about the MAPK's. The MAP kinase analyser tool and supplementary files can be downloaded from http://www.bioinfogbpuat/mapk_OWN_1/.     

Identification of new members of the MAPK gene family in plants shows diverse conserved domains and novel activation loop variants

Background

Mitogen Activated Protein Kinase (MAPK) signaling is of critical importance in plants and other eukaryotic organisms. The MAPK cascade plays an indispensible role in the growth and development of plants, as well as in biotic and abiotic stress responses. The MAPKs are constitute the most downstream module of the three tier MAPK cascade and are phosphorylated by upstream MAP kinase kinases (MAPKK), which are in turn are phosphorylated by MAP kinase kinase kinase (MAPKKK). The MAPKs play pivotal roles in regulation of many cytoplasmic and nuclear substrates, thus regulating several biological processes.

Results

A total of 589 MAPKs genes were identified from the genome wide analysis of 40 species. The sequence analysis has revealed the presence of several N- and C-terminal conserved domains. The MAPKs were previously believed to be characterized by the presence of TEY/TDY activation loop motifs. The present study showed that, in addition to presence of activation loop TEY/TDY motifs, MAPKs are also contain MEY, TEM, TQM, TRM, TVY, TSY, TEC and TQY activation loop motifs. Phylogenetic analysis of all predicted MAPKs were clustered into six different groups (group A, B, C, D, E and F), and all predicted MAPKs were assigned with specific names based on their orthology based evolutionary relationships with Arabidopsis or Oryza MAPKs.

Conclusion

We conducted global analysis of the MAPK gene family of plants from lower eukaryotes to higher eukaryotes and analyzed their genomic and evolutionary aspects. Our study showed the presence of several new activation loop motifs and diverse conserved domains in MAPKs. Advance study of newly identified activation loop motifs can provide further information regarding the downstream signaling cascade activated in response to a wide array of stress conditions, as well as plant growth and development.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1244-7) contains supplementary material, which is available to authorized users.     

MAPK级联途径调控植物细胞胞质分裂

胞质分裂(cytokinesis)是细胞分裂的最后关键一步,产生2个含有完整的遗传物质和胞质细胞器的子细胞．植物胞质分裂包括细胞板的形成,这一过程是在成膜体的牵引下由一些植物特有的步骤完成的．促分裂原活化蛋白激酶(MAPK)级联途径在真核生物中是高度保守的,由MAPKs,MAPKKs,MAPKKKs组成,通过MAPKKK→ MAPKK → MAPK的逐级磷酸化传递细胞信号．近来的研究表明, NACK-MAPKKK→MAPKK→MAPK→MAP65构成的信号途径调控植物细胞的胞质分裂．本文就这一信号途径,总结了植物胞质分裂机制的研究进展,并对其中的问题进行了讨论与展望．