蛋白组氨酸磷酸酶研究进展

主要概括磷酸酶的种类,原核细胞磷酸组氨酸生物功能及调控,哺乳动物组氨酸残基磷酸化、去磷酸化,以及组氨酸磷酸酶及其底物的最新研究进展. 信号转导在生长发育及细胞功能中起极其重要的作用. 无论在原核还是真核细胞,蛋白质磷酸化是细胞内信号转导的关键机制. 研究最多的可逆的真核蛋白磷酸化,主要发生在含有羟基的丝氨酸、苏氨酸和酪氨酸残基上. 不同的激酶和磷酸酶受不同机制的调节,而调节过程中出现的差异是人类很多疾病的潜在基础. 与大量有关羟基磷酸化氨基酸的报道相比,有关氨基磷酸化氨基酸的报道甚少. 据估计,自然界中存在的磷酸组氨酸比磷酸酪氨酸多10 ~ 100倍,但不如磷酸丝氨酸丰富. 虽然对脊椎动物蛋白质中存在磷酸组氨酸的认识可以追溯到20世纪60年代初, 但由于研究手段的限制,至今对脊椎动物蛋白组氨酸激酶及组氨酸磷酸酶的结构及功能知之甚少. 但是,近几年的研究有突破性的发现,克隆和重组表达哺乳动物组氨酸磷酸酶为研究氨基磷酸化氨基酸的生物功能翻开新的一章.     

Mammalian histidine kinases

Protein phosphorylation is one of the most ubiquitous and important types of post-translational modification for the regulation of cell function. The importance of two-component histidine kinases in bacteria, fungi and plants has long been recognised. In mammals, the regulatory roles of serine/threonine and tyrosine kinases have attracted most attention. However, the existence of histidine kinases in mammalian cells has been known for many years, although little is still understood about their biological roles by comparison with the hydroxyamino acid kinases. In addition, with the exception of NDP kinase, other mammalian histidine kinases remain to be identified and characterised. NDP kinase is a multifunctional enzyme that appears to act as a protein histidine kinase and as such, to regulate the activation of some G-proteins. Histone H4 histidine kinase activity has been shown to correlate with cellular proliferation and there is evidence that it is an oncodevelopmental marker in liver. This review mainly concentrates on describing recent research on these two types of histidine kinase. Developments in methods for the detection and assay of histidine kinases, including mass spectrometric methods for the detection of phosphohistidines in proteins and in-gel kinase assays for histone H4 histidine kinases, are described. Little is known about inhibitors of mammalian histidine kinases, although there is much interest in two-component histidine kinase inhibitors as potential antibiotics. The inhibition of a histone H4 histidine kinase by genistein is described and that of two-component histidine kinase inhibitors of structurally-related mammalian protein kinases. In addition, recent findings concerning mammalian protein histidine phosphatases are briefly described.     

Tyrosine-kinases in bacteria: from a matter of controversy to the status of key regulatory enzymes

When considering protein phosphorylation in bacteria, phosphorylation of aspartic acid and histidine residues mediated by the two-component systems is the first to spring to mind. And yet other phosphorylation systems have been described in bacteria in the past 20 years including eukaryotic-like serine/threonine kinases and more recently tyrosine-kinases. Among the latter, a peculiar type is widespread among bacteria, but not in higher organisms. These enzymes possess unique structural features defining thus a new family of enzymes termed Bacterial tyrosine kinases (BY-kinases). BY-kinases have been shown to be mainly involved in polysaccharide production, but their ability to phosphorylate endogenous substrates indicates that they participate in the regulation of other functions of the bacterial cell. Recent advances in mass spectrometry based phosphoproteomics provided lists of many new phosphotyrosine-proteins, indicating that BY-kinases may be involved in regulating a large array of other cellular functions. One may expect that in a near future, tyrosine phosphorylation will turn out to be one of the key regulatory processes in the bacterial cell and will yield new insights into the understanding of its physiology.     

Reversible phosphorylation of histidine residues in vertebrate proteins

Knowledge on kinases and phosphatases acting on serine, threonine and tyrosine residues of vertebrate proteins is huge. These enzymes are still under intensive investigation at present. This is in sharp contrast to what is known about kinases and phosphatases acting on histidine, arginine, lysine and aspartate residues in vertebrate proteins. It also is in contrast to extensive studies of histidine/aspartate phosphorylation in prokaryotes. This minireview briefly summarizes what we have learned about the reversible phosphorylation of histidine residues in mammals. It is described how the field developed during 40 years of science. The article especially highlights the discovery of the first protein histidine phosphatase from vertebrates. Having identified and characterized a protein histidine phosphatase provides at least one desperately required tool to handle and study phosphorylation and dephosphorylation of histidine residues in vertebrates in more detail. Recent evidence even suggests an involvement of histidine phosphorylation in signal transduction.     

Histidine phosphorylation in biological systems

Histidine phosphorylation is important in prokaryotes and occurs to the extent of 6% of total phosphorylation in eukaryotes. Nevertheless phosphohistidine residues are not normally observed in proteins due to rapid hydrolysis of the phosphoryl group under acidic conditions. Many rapid processes employ phosphohistidines, including the bacterial phosphoenolpyruvate:sugar phosphotransferase system (PTS), the bacterial two-component systems and reactions catalyzed by enzymes such as nucleoside diphosphate kinase and succinyl-CoA synthetase. In the PTS, the NMR structure of the phosphohistidine moiety of the phosphohistidine-containing protein was determined but no X-ray structures of phosphohistidine forms of PTS proteins have been elucidated. There have been crystal structures of a few phosphohistidine-containing proteins determined: nucleoside diphosphate kinase, succinyl-CoA synthetase, a cofactor-dependent phosphoglycerate mutase and the protein PAE2307 from the hyperthermophilic archaeon Pyrobaculum aerophilum. A common theme for these stable phosphohistidines is the occurrence of ion-pair hydrogen bonds (salt bridges) involving the non-phosphorylated nitrogen atom of the histidine imidazole ring with an acidic amino acid side chain.     

Is PhoR–PhoP partner fidelity strict? PhoR is required for the activation of the pho regulon in Streptomyces coelicolor

Two-component regulatory systems play a key role in the cell metabolism adaptation to changing nutritional and environmental conditions. The fidelity between the two cognate proteins of a two-component system is important since it determines whether a specific response regulator integrates the signals transmitted by different sensor kinases. Phosphate regulation in Streptomyces coelicolor is mostly mediated by the PhoR-PhoP two-component system. Previous studies elucidated the mechanisms that control phosphate regulation as well as the genes directly regulated by the response regulator PhoP (pho regulon) in this organism. However, the role of the histidine kinase PhoR in Streptomyces coelicolor had not been unveiled so far. In this work, we report the characterization of a non-polar ΔphoR deletion mutant in S. coelicolor that keeps its native promoter. Induction of the phoRP operon was dependent upon phosphorylation of PhoP, but the ΔphoR mutant expressed phoP at a basal level. RT-PCR and reporter luciferase assays demonstrated that PhoR plays a key role in the activation of the pho regulon in this organism. Our results point towards a strict cognate partner specificity in terms of the phosphorylation of PhoP by PhoR thus corroborating the tight interaction between the two-components of this system.     

Synthesis of [(32)P]phosphoramidate for use as a low molecular weight phosphodonor reagent

Phosphoramidate serves as a useful phosphodonor reagent in protein and peptide phosphorylation, notably in studying two-component signal transduction systems in which low molecular weight phosphodonors can substitute for the phosphodonor function of histidine protein kinases in in vitro phosphorylation studies of response regulator proteins. A convenient method for the synthesis of radiolabeled phosphoramidate has not been developed, and this has limited its broader use. Here we report the synthesis of radiolabeled ammonium hydrogen phosphoramidate [(NH(4))H(32)PO(3)NH(2)] which is achieved by activation of [(32)P]orthophosphate with ethyl isocyanate followed by aminolysis with ammonium hydroxide to form the desired phosphoramidate. The procedure is conveniently carried out in a microfuge tube and requires only two successive precipitation steps to obtain pure ammonium hydrogen phosphoramidate. Molar yields of 15-30% and specific activities of 10-20 Ci/mol are readily achieved. Phosphorylation of microgram quantities of response regulator proteins CheY, CheB, and DrrA is shown. Low level, but detectable, nonspecific phosphorylation was observed for reactions near ambient temperatures when substrate response regulators lacking the active site aspartate but containing histidine residues are used. More significant levels of nonspecific phosphorylation were observed for reactions at elevated temperatures when using a nonresponse regulator control protein (RNase A).     

Systematic dissection and trajectory-scanning mutagenesis of the molecular interface that ensures specificity of two-component signaling pathways

Two-component signal transduction systems enable bacteria to sense and respond to a wide range of environmental stimuli. Sensor histidine kinases transmit signals to their cognate response regulators via phosphorylation. The faithful transmission of information through two-component pathways and the avoidance of unwanted cross-talk require exquisite specificity of histidine kinase-response regulator interactions to ensure that cells mount the appropriate response to external signals. To identify putative specificity-determining residues, we have analyzed amino acid coevolution in two-component proteins and identified a set of residues that can be used to rationally rewire a model signaling pathway, EnvZ-OmpR. To explore how a relatively small set of residues can dictate partner selectivity, we combined alanine-scanning mutagenesis with an approach we call trajectory-scanning mutagenesis, in which all mutational intermediates between the specificity residues of EnvZ and another kinase, RstB, were systematically examined for phosphotransfer specificity. The same approach was used for the response regulators OmpR and RstA. Collectively, the results begin to reveal the molecular mechanism by which a small set of amino acids enables an individual kinase to discriminate amongst a large set of highly-related response regulators and vice versa. Our results also suggest that the mutational trajectories taken by two-component signaling proteins following gene or pathway duplication may be constrained and subject to differential selective pressures. Only some trajectories allow both the maintenance of phosphotransfer and the avoidance of unwanted cross-talk.     

拟南芥植物中的双组分信号系统

双组分信号系统是普遍存在于原核和真核细胞中,在进化上较保守的信号转导系统,主要由组氨酸蛋白激酶和应答调控器组成。双组分信号系统在植物的生长和发育中起非常重要的作用。随着拟南芥基因组测序的完成和功能基因组的深入研究发现,在拟南芥基因组中有55种参与双组分信号系统磷酸传递的蛋白。本文应用生物信息学的基本手段,如序列比较、多个序列比对、系统进化树分析、跨膜区分析、二级结构预测等,对这些蛋白进行系统分类,结构分析,并对在信号转导中已知功能的蛋白进行归类总结,便于人们了解双组分信号系统的作用机制及其在植物中的功能。     

Crystal structure of the histidine-containing phosphotransfer protein ZmHP2 from maize

In higher plants, histidine-aspartate phosphorelays (two-component system) are involved in hormone signaling and stress responses. In these systems, histidine-containing phosphotransfer (HPt) proteins mediate the signal transmission from sensory histidine kinases to response regulators, including integration of several signaling pathways or branching into different pathways. We have determined the crystal structure of a maize HPt protein, ZmHP2, at 2.2 A resolution. ZmHP2 has six alpha-helices with a four-helix bundle at the C-terminus, a feature commonly found in HPt domains. In ZmHP2, almost all of the conserved residues among plant HPt proteins surround this histidine, probably forming the docking interface for the receiver domain of histidine kinase or the response regulator. Arg102 of ZmHP2 is conserved as a basic residue in plant HPt proteins. In bacteria, it is replaced by glutamine or glutamate that form a hydrogen bond to Ndelta atoms of the phospho-accepting histidine. It may play a key role in the complex formation of ZmHP2 with receiver domains.     

Analysis of protein interactions within the cytokinin-signaling pathway of Arabidopsis thaliana

The signal of the plant hormone cytokinin is perceived by membrane-located sensor histidine kinases and transduced by other members of the plant two-component system. In Arabidopsis thaliana, 28 two-component system proteins (phosphotransmitters and response regulators) act downstream of three receptors, transmitting the signal from the membrane to the nucleus and modulating the cellular response. Although the principal signaling mechanism has been elucidated, redundancy in the system has made it difficult to understand which of the many components interact to control the downstream biological processes. Here, we present a large-scale interaction study comprising most members of the Arabidopsis cytokinin signaling pathway. Using the yeast two-hybrid system, we detected 42 new interactions, of which more than 90% were confirmed by in vitro coaffinity purification. There are distinct patterns of interaction between protein families, but only a few interactions between proteins of the same family. An interaction map of this signaling pathway shows the Arabidopsis histidine phosphotransfer proteins as hubs, which interact with members from all other protein families, mostly in a redundant fashion. Domain-mapping experiments revealed the interaction domains of the proteins of this pathway. Analyses of Arabidopsis histidine phosphotransfer protein 5 mutant proteins showed that the presence of the canonical phospho-accepting histidine residue is not required for the interactions. Interaction of A-type response regulators with Arabidopsis histidine phosphotransfer proteins but not with B-type response regulators suggests that their known activity in feedback regulation may be realized by interfering at the level of Arabidopsis histidine phosphotransfer protein-mediated signaling. This study contributes to our understanding of the protein interactions of the cytokinin-signaling system and provides a framework for further functional studies in planta.     

The arcB gene of Escherichia coli encodes a sensor-regulator protein for anaerobic repression of the arc modulon

The arcA (dye) and arcB genes of Escherichia coli are responsible for anaerobic repression of target operons and regulons of aerobic function (the arc modulon). The amino acid sequence of ArcA (Dye) indicated that it is the regulator protein of a two-component control system. Here we show that ArcB is a membrane sensor protein on the basis of its deduced amino acid sequence (778 residues), hydropathicity profile, and cellular distribution. On the carboxyl end of the ArcB sequence there is an additional domain showing homology with conserved regions of regulator proteins. Deletion into this domain destroyed ArcB function. ArcB conserved a histidine residue for autophosphorylation of the sensor proteins, and aspartic residues important for the regulator proteins.     

Two-component response regulators Ssk1p and Skn7p additively regulate high-osmolarity adaptation and fungicide sensitivity in Cochliobolus heterostrophus

Filamentous ascomycetous fungi possess many histidine kinases and two conserved response regulators, Ssk1p and Skn7p, in their two-component signaling systems. We previously reported that the fungus unique group III histidine kinase regulates high-osmolarity adaptation and iprodione/fludioxonil fungicide sensitivity by controlling the phosphorylation of Hog1-type mitogen-activated protein kinase (MAPK) in filamentous ascomycetes. Here, we have characterized the response regulator genes ChSsk1 and ChSkn7 in the southern corn leaf blight fungus Cochliobolus heterostrophus. Both ChSsk1- and ChSkn7-disrupted mutants showed little sensitivity to high-osmolarity stress and moderate resistance to the iprodione/fludioxonil fungicides. The phosphorylation of Hog1-type MAPK BmHog1p induced by high-osmolarity stress and fungicide treatments was only regulated by ChSsk1p, indicating that ChSkn7p has roles in high-osmolarity adaptation and fungicide sensitivity that are independent from the activation of BmHog1p. The Chssk1 Chskn7 double mutants clearly showed higher sensitivity to osmolar stress and higher resistance to fungicides than the single mutants. The dose responses of the double mutants fit well with those of the group III histidine kinase-deficient strain. These results suggest that in filamentous ascomycetes, the Ssk1- and Skn7-type response regulators control high-osmolarity adaptation and fungicide sensitivity additively with differential mechanisms under the regulation of the group III histidine kinase. This study provides evidence that filamentous fungi have a unique two-component signaling system that is different from that of yeast and is responsible for high-osmolarity adaptation and fungicide sensitivity.     

Nucleoside diphosphate kinase of Trypanosoma brucei

Nucleoside diphosphate kinase (NDPK) is a highly conserved, multifunctional enzyme. Its originally described function is the phosphorylation of nucleoside diphosphates to the corresponding triphosphates, using ATP as the phosphate donor and a high-energy phosphorylated histidine residue as the reaction intermediate. More recently, a host of additional functions of NDPK have been discovered. Some of these correlate with the capacity of NDPK to transphosphorylate other proteins, in a manner reminiscent of bacterial two-component systems. Other functions may be mediated by direct DNA-binding of NDPK.This study describes the identification of NDPK from the parasitic protozoon Trypanosoma brucei. The genome of this major disease agent contains a single gene for NDPK. The predicted amino acid sequence of the trypanosomal enzyme is highly conserved with respect to all other species. The protein is constitutively expressed and is present in procyclic and in bloodstream forms. Immunofluorescence and immuno-electron microscopy demonstrate that trypanosomal NDPK (TbNDPK) is predominantly localized in the cell nucleus. Histidine phosphorylation of TbNDPK is essentially resistant to the experimental compound LY266500, a potent inhibitor of histidine phosphorylation of trypanosomal succinyl coenzyme A synthase.     

Purification of soluble and active RaxH, a transmembrane histidine protein kinase from Xanthomonas oryzae pv. oryzae required for AvrXa21 activity

The RaxHR two-component regulatory system (TCS) of the rice pathogen Xanthomonas oryzae pv. oryzae is required for AvrXa21 activity. RaxH is a typical transmembrane histidine protein kinase (HK), whereas RaxR is its concomitant response regulator (RR). Here, we report the isolation of soluble, active amounts of recombinant His-tagged full-length RaxH and RaxR following growth of Escherichia coli over-expressing strains in the presence of sorbitol and glycine betaine. Full-length His-RaxH showed similar autophosphorylation activities to that of a truncated version of the protein (His-t-RaxH), lacking the N-terminal transmembrane region. Transphosphorylation assays revealed that only full-length RaxH was able to induce phosphorylation of His-RaxR, indicating that the N-terminal region of RaxH may be required for transphosphorylation of RaxR. Using site-directed mutagenesis we also demonstrated that residues histidine 222 in RaxH and aspartate 51 in RaxR are essential for phosphorylation activities of these proteins. Utilization of compatible solutes may be widely applied for purification of soluble, active recombinant transmembrane proteins, and in particular for purification of transmembrane HKs.     

Autophosphorylation activity of the Arabidopsis ethylene receptor multigene family

Receptors for the gaseous phytohormone ethylene show sequence similarity to bacterial two-component histidine kinases. These receptors are encoded by a multigene family that can be divided into subfamilies 1 and 2. It has been previously shown that a subfamily 1 Arabidopsis thaliana ethylene receptor, ETR1, autophosphorylates in vitro on a conserved histidine residue (1). However, sequence comparisons between the five ethylene receptor family members suggest that subfamily 2 members do not have all the motifs necessary for histidine kinase activity. Further, a tobacco subfamily 2 receptor, NTHK1, autophosphorylates on serines and threonines in vitro (2). Here we show that all five Arabidopsis ethylene receptor proteins autophosphorylate in vitro. We analyzed the nature of the phosphorylated amino acids by acid/base stability and bi-dimensional thin layer electrophoresis and demonstrated that unlike ETR1 all other ethylene receptors autophosphorylate predominantly on serine residues. ERS1, the only other subfamily 1 receptor, is able to phosphorylate on both histidine and serine residues in the presence of Mn2+. However, histidine autophosphorylation is lost when ERS1 is assayed in the presence of both Mg2+ and Mn2+, suggesting that this activity may not occur in vivo. Furthermore, mutation of the histidine residue conserved in two-component systems does not abolish serine autophosphorylation, eliminating the possibility of a histidine to serine phosphotransfer. Our biochemical observations complement the recently published genetic data that histidine kinase activity is not necessary for ethylene receptor function in plants and suggest that ethylene signal transduction does not occur through a phosphorelay mechanism.