Structural characterization of the catalytic γ and regulatory β subunits of phosphorylase kinase in the context of the hexadecameric enzyme complex

In the tightly regulated glycogenolysis cascade, the breakdown of glycogen to glucose‐1‐phosphate, phosphorylase kinase (PhK) plays a key role in regulating the activity of glycogen phosphorylase. PhK is a 1.3 MDa hexadecamer, with four copies each of four different subunits (α, β, γ and δ), making the study of its structure challenging. Using hydrogen‐deuterium exchange, we have analyzed the regulatory β subunit and the catalytic γ subunit in the context of the intact non‐activated PhK complex to study the structure of these subunits and identify regions of surface exposure. Our data suggest that within the non‐activated complex the γ subunit assumes an activated conformation and are consistent with a previous docking model of the β subunit within the cryoelectron microscopy envelope of PhK.     

A model for activation of the hexadecameric phosphorylase kinase complex deduced from zero‐length oxidative crosslinking

Phosphorylase kinase (PhK) is a hexadecameric (αβγδ)₄ enzyme complex that upon activation by phosphorylation stimulates glycogenolysis. Due to its large size (1.3 MDa), elucidating the structural changes associated with the activation of PhK has been challenging, although phosphoactivation has been linked with an increased tendency of the enzyme's regulatory β‐subunits to self‐associate. Here we report the effect of a peptide mimetic of the phosphoryltable N‐termini of β on the selective, zero‐length, oxidative crosslinking of these regulatory subunits to form β–β dimers in the nonactivated PhK complex. This peptide stimulated β–β dimer formation when not phosphorylated, but was considerably less effective in its phosphorylated form. Because this peptide mimetic of β competes with its counterpart region in the nonactivated enzyme complex in binding to the catalytic γ‐subunit, we were able to formulate a structural model for the phosphoactivation of PhK. In this model, the nonactivated state of PhK is maintained by the interaction between the nonphosphorylated N‐termini of β and the regulatory C‐terminal domains of the γ‐subunits; phosphorylation of β weakens this interaction, leading to activation of the γ‐subunits.     

The hybrid Four‐CBS‐Domain KINβγ subunit functions as the canonical γ subunit of the plant energy sensor SnRK1

The AMPK/SNF1/SnRK1 protein kinases are a family of ancient and highly conserved eukaryotic energy sensors that function as heterotrimeric complexes. These typically comprise catalytic α subunits and regulatory β and γ subunits, the latter function as the energy‐sensing modules of animal AMPK through adenosine nucleotide binding. The ability to monitor accurately and adapt to changing environmental conditions and energy supply is essential for optimal plant growth and survival, but mechanistic insight in the plant SnRK1 function is still limited. In addition to a family of γ‐like proteins, plants also encode a hybrid βγ protein that combines the Four‐Cystathionine β‐synthase (CBS)‐domain (FCD) structure in γ subunits with a glycogen‐binding domain (GBD), typically found in β subunits. We used integrated functional analyses by ectopic SnRK1 complex reconstitution, yeast mutant complementation, in‐depth phylogenetic reconstruction, and a seedling starvation assay to show that only the hybrid KINβγ protein that recruited the GBD around the emergence of the green chloroplast‐containing plants, acts as the canonical γ subunit required for heterotrimeric complex formation. Mutagenesis and truncation analysis further show that complex interaction in plant cells and γ subunit function in yeast depend on both a highly conserved FCD and a pre‐CBS domain, but not the GBD. In addition to novel insight into canonical AMPK/SNF/SnRK1 γ subunit function, regulation and evolution, we provide a new classification of plant FCD genes as a convenient and reliable tool to predict regulatory partners for the SnRK1 energy sensor and novel FCD gene functions.     

Normal‐mode‐based modeling of allosteric couplings that underlie cyclic conformational transition in F1 ATPase

F₁ ATPase, a rotary motor comprised of a central stalk ( γ subunit) enclosed by three α and β subunits alternately arranged in a hexamer, features highly cooperative binding and hydrolysis of ATP. Despite steady progress in biophysical, biochemical, and computational studies of this fascinating motor, the structural basis for cooperative ATPase involving its three catalytic sites remains not fully understood. To illuminate this key mechanistic puzzle, we have employed a coarse‐grained elastic network model to probe the allosteric couplings underlying the cyclic conformational transition in F₁ ATPase at a residue level of detail. We will elucidate how ATP binding and product (ADP and phosphate) release at two catalytic sites are coupled with the rotation of γ subunit via various domain motions in α ₃ β ₃ hexamer (including intrasubunit hinge‐bending motions in β subunits and intersubunit rigid‐body rotations between adjacent α and β subunits). To this end, we have used a normal‐mode‐based correlation analysis to quantify the allosteric couplings of these domain motions to local motions at catalytic sites and the rotation of γ subunit. We have then identified key amino acid residues involved in the above couplings, some of which have been validated against past studies of mutated and γ ‐truncated F₁ ATPase. Our finding strongly supports a binding change mechanism where ATP binding to the empty catalytic site triggers a series of intra‐ and intersubunit domain motions leading to ATP hydrolysis and product release at the other two closed catalytic sites. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Structural evidence for co-evolution of the regulation of contraction and energy production in skeletal muscle

Skeletal muscle phosphorylase kinase (PhK) is a Ca²⁺-dependent enzyme complex, (αβγδ)₄, with the δ subunit being tightly bound endogenous calmodulin (CaM). The Ca²⁺-dependent activation of glycogen phosphorylase by PhK couples muscle contraction with glycogen breakdown in the “excitation-contraction-energy production triad.” Although the Ca²⁺-dependent protein-protein interactions among the relevant contractile components of muscle are well characterized, such interactions have not been previously examined in the intact PhK complex. Here we show that zero-length cross-linking of the PhK complex produces a covalent dimer of its catalytic γ and CaM subunits. Utilizing mass spectrometry, we determined the residues cross-linked to be in an EF hand of CaM and in a region of the γ subunit sharing high sequence similarity with the Ca²⁺-sensitive molecular switch of troponin I that is known to bind actin and troponin C, a homolog of CaM. Our findings represent an unusual binding of CaM to a target protein and supply an explanation for the low Ca²⁺ stoichiometry of PhK that has been reported. They also provide direct structural evidence supporting co-evolution of the coordinate regulation by Ca²⁺ of contraction and energy production in muscle through the sharing of a common structural motif in troponin I and the catalytic subunit of PhK for their respective interactions with the homologous Ca²⁺-binding proteins troponin C and CaM.     

Nucleotide sequence of the genes coding for alpha, beta and gamma subunits of the proton-translocating ATPase of Escherichia coli

A nucleotide sequence of 2328 base pairs comprising a portion of the gene cluster for the proton-translocating ATPase of $\text{E. coli}$ was determined. The sequence covers most of the gene for α subunit, the entire gene for γ subunit and the amino terminal portion of the gene for β subunit, along with the flanking regions of these genes. The amino acid sequences of these subunits deduced from the DNA sequences indicate that the α and γ subunits have 513 and 287 amino acid residues, respectively. A possible secondary structure for each subunit was estimated from the inferred primary structure. The intercistronic regions between the genes for α and γ and between γ and β are 49 and 26 base pairs, respectively. The significance of codon usage in these genes is discussed in correlation with their expression.     

Reconstitution of ATPase from the isolated subunits of coupling factor F1's of Escherichia coli and thermophilic bacterium PS3

ATPase was reconstituted from mixtures of isolated subunits of coupling factor, F₁ ATPase of E. coli (EF₁) and thermophilic bacterium PS3 (TF₁); ability to hydrolyze ATP was attained from the combination of α and β subunits from EF₁ and γ subunit from TF₁, α and β from TF₁ and γ from EF₁, and α and γ from EF₁ and β from TF₁. The β subunit of TF₁ also could complement the EF₁ from an E. coli mutant defective in this subunit. This is the first demonstration of interspecies in vitro recombination of ATPase activity from isolated subunits.     

Subunit component and their roles in the sodium-transport NADH: quinone reductase of a marine bacterium,Vibrio alginolyticus

The sodium-transport respiratory chain NADH: quinone reductase of a marine bacterium, Vibrio alginolyticus, was purified by high-performance liquid chromatography. The purified quinone reductase, which catalyses the reduction of ubiquinone to ubiquinol, was composed of three subunits, α, β and γ, with apparent molecular weights of 52 000, 46 000 and 32 000, respectively. The subunit β contained one molecule of FAD per molecule and catalysed the reduction of ubiquinone to ubisemiquinone. The subunit α contained FMN as a prosthetic group. The quinone reductase was reconstituted from α and βγ, but not from α and β, and the maximum activity was obtained at the equimolar amounts of FAD(β) and FMN(α). The molecular weight of quinone reductase complex was estimated to be 254 000, which corresponded to a dimer of αβγ complex or α₂β₂γ₂. The subunit γ increased the affinity of β for ubiquinone-1. The reaction catalysed by FMN-containing α-subunit was essential for the generation of membrane potential in proteoliposomes and the coupling site of sodium pump in the quinone reductase was localised to this reaction step.     

Neuronal cell surface ATP synthase mediates synthesis of extracellular ATP and regulation of intracellular pH

The ATP synthase is known to play important roles in ATP generation and proton translocation within mitochondria. Here, we now provide evidence showing the presence of functional ecto‐ATP synthase on the neuronal surface. Immunoblotting revealed that the α, β subunits of ATP synthase F₁ portion are present in isolated fractions of plasma membrane and biotin‐labelled surface protein from primary cultured neurons; the surface distribution of α, β subunits was also confirmed by immunofluorescence staining. Moreover, α and β subunits were also found in fractions of plasma membrane and lipid rafts isolated from rat brain, and flow cytometry analysis showed α subunits on the surface of acutely isolated brain cells. Activity assays showed that the extracellular ATP generation of cultured neurons could be compromised by α, β subunit antibodies and ATP synthase inhibitors. pH_i (intracellular pH) analysis demonstrated that at low extracellular pH, α or β subunit antibodies decreased pH_i of primary cultured neurons. Therefore, ATP synthase on the surface of neurons may be involved in the machineries of extracellular ATP generation and pH_i homoeostasis.     

A Gene Located at 56F1-2 inDrosophila melanogasterEncodes a Novel Metazoan β-like Subunit of Casein Kinase II

Drosophila melanogastercasein kinase II (DmCKII) is composed of catalytic α and regulatory β subunits associated as an α₂β₂heterotetramer. Using the two-hybrid system, we have screened aDrosophilaembryo cDNA library for proteins that interact with DmCKII α. One of the cDNAs encodes a novel β-like polypeptide, which we designate β′.In situhybridization localizes the corresponding gene to 56F1-2, a site distinct from that of both the β gene and theStellatefamily of β-like sequences. The predicted sequence of β′ is more closely related to the β subunit ofDrosophilaand other metazoans than to the Stellate family of proteins, suggesting that it is a second regulatory subunit.In vitroreconstitution studies show that a GST-β′ fusion protein associates with the α subunit to generate a tetrameric complex with regulatory properties similar to those of the native α₂β₂holoenzyme. The data are consistent with the proposed role of the β′ subunit as an integral component of the holoenzyme.     

EVIDENCE FOR A SPECIALIZED LOCALIZATION OF THE CHLOROPLAST ATP‐SYNTHASE SUBUNITS α, β, AND γ IN THE EYESPOT APPARATUS OF CHLAMYDOMONAS REINHARDTII (CHLOROPHYCEAE)1

The eyespot apparatus (EA) of Chlamydomonas reinhardtii P. A. Dang. consists of two layers of carotenoid‐rich lipid globules subtended by thylakoids. The outermost globule layer is additionally associated with the chloroplast envelope membranes and the plasma membrane. In a recent proteomic approach, we identified 202 proteins from isolated EAs of C. reinhardtii via at least two peptides, including, for example, structural components, signalling‐related proteins, and photosynthetic‐related membrane proteins. Here, we have analyzed the proteins of the EA with regard to their topological distribution using thermolysin to find out whether the arrangement of globules and membranes provides protection mechanisms for some of them. From about 230 protein spots separated on two‐dimensional gels, the majority were degraded by thermolysin. Five major protein spots were protected against the action of this protease. These proteins and some that were degradable were identified by mass spectrometry. Surprisingly, the thermolysin‐resistant proteins represented the α and β subunits of the soluble CF₁ complex of the chloroplast ATP synthase. Degradable proteins included typical membrane proteins like LHCs, demonstrating that thermolysin is not in general sterically prevented by the EA structure from reaching membrane‐associated proteins. A control experiment showed that the CF₁ complex of thylakoids is efficiently degraded by thermolysin. Blue native PAGE of thermolysin‐treated EAs followed by SDS‐PAGE revealed that the α and β subunits are present in conjunction with the γ subunit in a thermolysin‐resistant complex. These results provide strong evidence that a significant proportion of these ATP‐synthase subunits have a specialized localization and function within the EA of C. reinhardtii.     

Calcineurin B-like domains in the large regulatory alpha/beta subunits of phosphorylase kinase

Phosphorylase kinase (PhK) is a large hexadecameric complex that catalyzes the phosphorylation and activation of glycogen phosphorylase (GP). It consists in four copies each of a catalytic subunit (gamma) and three regulatory subunits (alpha beta delta). Delta corresponds to endogenous calmodulin, whereas little is known on the molecular architecture of the large alpha and beta subunits, which probably arose from gene duplication. Here, using sensitive methods of sequence analysis, we show that the C-terminal domain (named domain D) of these alpha and beta subunits can be significantly related to calcineurin B-like (CBL) proteins. CBL are members of the EF-hand family that are involved in the regulation of plant-specific kinases of the CIPK/PKS family, and relieve autoinhibition of their target kinases by binding to their regulatory region. The relationship highlighted here suggests that PhK alpha and/or beta domain D may be involved in a similar regulation mechanism, a hypothesis which is supported by the experimental observation of a direct interaction between domain D of PhKalpha and the regulatory region of the Gamma subunit. This finding, together the identification of significant similarities of domain D with the preceding domain C, may help to understand the molecular mechanism by which PhK alpha and/or beta domain D might regulate PhK activity.     

Casein kinase II α subunits affect multiple developmental and stress-responsive pathways in Arabidopsis

Casein kinase II (formerly known as CK2), a ubiquitous Ser/Thr kinase, plays critical roles in all higher organisms including plants. The CK2 holoenzyme consists of two catalytic α subunits and two regulatory β subunits. The Arabidopsis genome has four α subunit and four β subunit genes, and members of both the α and β subunit families have been shown to be localized in the cytoplasm, nucleus and also in chloroplasts. However, the biological roles of CK2 subunits have not been fully characterized yet. Here we identified T-DNA insertion mutants in three α subunit genes (α1, α2 and α3) and made double and triple mutants. The CK2 α1α2α3 triple mutants displayed reduced CK2 activity compared with wild-type seedlings. Phenotypic characterization showed that CK2 α1α2α3 triple mutants are late flowering under both long- and short-day conditions. Genes encoding floral integrators are differentially regulated in the triple mutant compared with the wild-type plants. CK2 α1α2α3 triple mutants also displayed reduced hypocotyl growth, smaller cotyledon size and a reduced number of lateral roots compared with wild-type seedlings under light. Abscisic acid-induced blockage of seed germination and cotyledon greening is reduced in CK2 α subunit mutants in an additive manner. Moreover, CK2 α subunit mutants are also hyposensitive to a NaCl-induced blockage of seed germination. Taken together, these data suggest that CK2 α subunits affect diverse developmental and stress responsive pathways in Arabidopsis.     

Spectroscopy-Based Modelling of the 3D Structure of the β Subunit of the High Affinity IgE Receptor

Abstract

The high affinity IgE receptor, possesses a tetrameric structure. The 243 residue β subunit is a polytopic protein with four hydrophobic membrane-spanning segments, whereas the individual α and γ subunits are bitopic proteins each containing one transmembrane domain in their monomeric form. In the proposed topographical model (Blank et al., 1989), the four trans-membrane α helices of the β subunit are connected by three loop sequences.

To study the individual subunits and intact receptor, this membrane protein was divided into domains such as its loop peptides, cytoplasmic peptides and transmembrane helices according to Blank et al., 1989. The 3D structure of the synthesized loop peptides and cytoplasmic peptides were calculated; CD and/or NMR data were used as appropriate to generate the resultant structures which were then used as data basis for the higher level calculations.

The four individual transmembrane helices of the β subunit were characterised, first of all, by mapping the relative lipophilicity of their surfaces using lipophilic probes. A second procedure, docking of the individual helices in pairs, was used to predict helix–helix interactions.

The data on the relative lipophilicity of the surfaces as well as the surfaces that favoured helix–helix interactions were used in combination with the spectroscopy-based structures of the loops and cytoplasmic domains to calculate via molecular dynamics, the helix arrangement and 3D structure of the β subunit of the high affinity IgE receptor. In the final analysis, the molecular simulations yielded two structures of the β subunit, which should form a basis for the modelling of the whole high affinity IgE receptor.     

Subunit and domain requirements for adenylate-mediated protection of Snf1 kinase activation loop from dephosphorylation

Members of the AMP-activated protein kinase (AMPK) family are activated by phosphorylation at a conserved threonine residue in the activation loop of the kinase domain. Mammalian AMPK adopts a phosphatase-resistant conformation that is stabilized by binding low energy adenylate molecules. Similarly, binding of ADP to the Snf1 complex, yeast AMPK, protects the kinase from dephosphorylation. Here, we determined the nucleotide specificity of the ligand-mediated protection from dephosphorylation and demonstrate the subunit and domain requirements for this reaction. Protection from dephosphorylation was highly specific for adenine nucleotides, with ADP being the most effective ligand for mediating protection. The full-length α subunit (Snf1) was not competent for ADP-mediated protection, confirming the requirement for the regulatory β and γ subunits. However, Snf1 heterotrimeric complexes that lacked either the glycogen-binding domain of Gal83 or the linker region of the α subunit were competent for ADP-mediated protection. In contrast, adenylate-mediated protection of recombinant human AMPK was abolished when a portion of the linker region containing the α-hook domain was deleted. Therefore, the exact means by which the different adenylate nucleotides are distinguished by the Snf1 enzyme may differ compared with its mammalian ortholog.     

Biosynthetic approach to the structure of F1-ATPase (BF1 factor) from Micrococcus lysodeikticus membranes: in vivo labeling of the polypeptides and study of their relationship

The F₁-ATPase or BF₁ factor was purified from Micrococcus lysodeikticus substrain B grown in a synthetic medium in the presence of tritiated amino acids. When analyzed in sodium dodecyl sulfate-7% polyacrylamide gels, the fresh purified preparation contained α, β, γ subunits (referred as the intrinsic subunits) and two other polypeptides (designated as X and component of relative mobility 1.0) whose status as subunits remains to be established. This overall polypeptide composition was similar to that of the F₁-ATPase isolated from the same strain grown in complex medium (J. Carreira, J. M. Andreu, M. Nieto, and E. Muñoz., 1976 Mol. Cell. Biochem.10, 67–76). The distribution of ³H-labeled amino acids into purified F₁-ATPase and its constituent polypeptides under different stages of growth was used to investigate the biosynthetic relationship between the different polypeptides. The incorporation of amino acids into purified BF₁ factor was slower than that of cytoplasmic and other membrane proteins. In isotope-dilution and chase experiments, F₁-ATPase showed one of the slowest rates of decay of the incorporated label. These results point out that F₁-ATPase of M. lysodeikticus undergoes slower turnover than the overall cytoplasmic and membrane proteins. Pulse and chase experiments allowed us to conclude that the α, β, γ subunits and the components of relative mobility 1.0 are independent with differences in their turnover and therefore do not bear any apparent relation as precursors-products. The two major subunits represent seemingly the “core” of ATPase, the β subunit behaving like the most stable component. On the other hand, the γ subunit appears to be synthesized independently from this α + β complex.     

Subunit composition of AMPK trimers present in the cytokinetic apparatus: Implications for drug target identification

AMP-activated protein kinase has been shown to be a key regulator of energy homeostasis; it has also been identified as a tumor suppressor and is required for correct cell division and chromosome segregation during mitosis. The enzyme is a heterotrimer, with each subunit having more than one isoform, each encoded by a separate gene (two α, two β and three γ isoforms). In human endothelial cells, the activated kinase subunit of AMPK in the cytokinetic apparatus is α2, the minority α subunit, which co-localizes with β2 and γ2. This is the first demonstration of a trimeric complex of AMPK containing the γ2 regulatory subunit becoming selectively activated and being linked to mitotic processes. We also show that α1 and γ1, the predominant AMPK subunits, are almost exclusively localized in the cytoskeleton, while α2 and γ2 are present in all subcellular fractions, including the nuclei. These data suggest that pharmacological interventions targeted to specific AMPK subunit isoforms have the potential to modify selective functions of AMPK.     

Cross-linking of transmembrane helices in proton-translocating nicotinamide nucleotide transhydrogenase from Escherichia coli: implications for the structure and function of the membrane domain

Proton-pumping nicotinamide nucleotide transhydrogenase from Escherichia coli contains an α and a β subunit of 54 and 49 kDa, respectively, and is made up of three domains. Domain I (dI) and III (dIII) are hydrophilic and contain the NAD(H)- and NADP(H)-binding sites, respectively, whereas the hydrophobic domain II (dII) contains 13 transmembrane α-helices and harbours the proton channel. Using a cysteine-free transhydrogenase, the organization of dII and helix-helix distances were investigated by the introduction of one or two cysteines in helix-helix loops on the periplasmic side. Mutants were subsequently cross-linked in the absence and presence of diamide and the bifunctional maleimide cross-linker o-PDM (6 Å), and visualized by SDS-PAGE.In the α₂β₂ tetramer, αβ cross-links were obtained with the αG476C-βS2C, αG476C-βT54C and αG476C-βS183C double mutants. Significant αα cross-links were obtained with the αG476C single mutant in the loop connecting helix 3 and 4, whereas ββ cross-links were obtained with the βS2C, βT54C and βS183C single mutants in the beginning of helix 6, the loop between helix 7 and 8 and the loop connecting helix 11 and 12, respectively. In a model based on 13 mutants, the interface between the α and β subunits in the dimer is lined along an axis formed by helices 3 and 4 from the α subunit and helices 6, 7 and 8 from the β subunit. In addition, helices 2 and 4 in the α subunit together with helices 6 and 12 in the β subunit interact with their counterparts in the α₂β₂ tetramer. Each β subunit in the α₂β₂ tetramer was concluded to contain a proton channel composed of the highly conserved helices 9, 10, 13 and 14.     

Amputation of a C-terminal helix of the γ subunit increases ATP-hydrolysis activity of cyanobacterial F1 ATP synthase

F₁ is a soluble part of F_oF₁-ATP synthase and performs a catalytic process of ATP hydrolysis and synthesis. The γ subunit, which is the rotary shaft of F₁ motor, is composed of N-terminal and C-terminal helices domains, and a protruding Rossman-fold domain located between the two major helices parts. The N-terminal and C-terminal helices domains of γ assemble into an antiparallel coiled-coil structure, and are almost embedded into the stator ring composed of α₃β₃ hexamer of the F₁ molecule. Cyanobacterial and chloroplast γ subunits harbor an inserted sequence of 30 or 39 amino acids length within the Rossman-fold domain in comparison with bacterial or mitochondrial γ. To understand the structure–function relationship of the γ subunit, we prepared a mutant F₁-ATP synthase of a thermophilic cyanobacterium, Thermosynechococcus elongatus BP-1, in which the γ subunit is split into N-terminal α-helix along with the inserted sequence and the remaining C-terminal part. The obtained mutant showed higher ATP-hydrolysis activities than those containing the wild-type γ. Contrary to our expectation, the complexes containing the split γ subunits were mostly devoid of the C-terminal helix. We further investigated the effect of post-assembly cleavage of the γ subunit. We demonstrate that insertion of the nick between two helices of the γ subunit imparts resistance to ADP inhibition, and the C-terminal α-helix is dispensable for ATP-hydrolysis activity and plays a crucial role in the assembly of F₁-ATP synthase.     

Structural homology among the major 7s globulin subunits of soybean seed storage proteins

The soybean seed 7S globulin subunits, i.e. α, α′, β and γ-subunits of β-conglycinin, the γ-conglycinin subunit and the HI/HII and LII subunits of basic 7S globulin were purified and the NH₂-terminal amino acid sequences of all these subunits except the γ-subunit of β-conglycinin were determined. Only the NH₂-terminal regions of the α and α′-subunits showed high sequence homology. However, sequencing of tryptic peptides from the seven subunits revealed that internal region sequences were highly homologous among the four subunits of β-conglycinin. In contrast to the β-conglycinin subunits, no sequence homology was found among the other subunits. On the basis of these results, the major 7S globulin fraction is considered more heterogeneous in primary structure than another major globulin fraction, 11S globulin (glycinin), in soybean seeds.