An epitope proximal to the carboxyl terminus of the alpha-subunit is located near the lobe tips of the phosphorylase kinase hexadecamer

The regulation of glycogenolysis in the brain

The key regulatory enzymes of glycogenolysis are phosphorylase kinase, a hetero-oligomer with four different types of subunits, and glycogen phosphorylase, a homodimer. Both enzymes are activated by phosphorylation and small ligands, and both enzymes have distinct isoforms that are predominantly expressed in muscle, liver, or brain; however, whole-transcriptome high-throughput sequencing analyses show that in brain both of these enzymes are likely composed of subunit isoforms representing all three tissues. This Minireview examines the regulatory properties of the isoforms of these two enzymes expressed in the three tissues, focusing on their potential regulatory similarities and differences. Additionally, the activity, structure, and regulation of the remaining enzyme necessary for glycogenolysis, glycogen-debranching enzyme, are also reviewed.

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.

The structure of the large regulatory α subunit of phosphorylase kinase examined by modeling and hydrogen-deuterium exchange

Phosphorylase kinase (PhK), a 1.3 MDa regulatory enzyme complex in the glycogenolysis cascade, has four copies each of four subunits, (αβγδ)₄ , and 325 kDa of unique sequence (the mass of an αβγδ protomer). The α, β and δ subunits are regulatory, and contain allosteric activation sites that stimulate the activity of the catalytic γ subunit in response to diverse signaling molecules. Due to its size and complexity, no high resolution structures have been solved for the intact complex or its regulatory α and β subunits. Of PhK's four subunits, the least is known about the structure and function of its largest subunit, α. Here, we have modeled the full-length α subunit, compared that structure against previously predicted domains within this subunit, and performed hydrogen-deuterium exchange on the intact subunit within the PhK complex. Our modeling results show α to comprise two major domains: an N-terminal glycoside hydrolase domain and a large C-terminal importin α/β-like domain. This structure is similar to our previously published model for the homologous β subunit, although clear structural differences are present. The overall highly helical structure with several intervening hinge regions is consistent with our hydrogen-deuterium exchange results obtained for this subunit as part of the (αβγδ)₄ PhK complex. Several low exchanging regions predicted to lack ordered secondary structure are consistent with inter-subunit contact sites for α in the quaternary structure of PhK; of particular interest is a low-exchanging region in the C-terminus of α that is known to bind the regulatory domain of the catalytic γ subunit.

The regulatory α and β subunits of phosphorylase kinase directly interact with its substrate, glycogen phosphorylase

The selective phosphorylation of glycogen phosphorylase (GP) by its only known kinase, phosphorylase kinase (PhK), keeps glycogen catabolism tightly regulated. In addition to the obligatory interaction between the catalytic γ subunit of PhK and the phosphorylatable region of GP, previous studies have suggested additional sites of interaction between this kinase and its protein substrate. Using short chemical crosslinkers, we have identified direct interactions of GP with the large regulatory α and β subunits of PhK. These newfound interactions were found to be sensitive to ligands that bind PhK.

Mass Spectrometric Analysis of Surface-Exposed Regions in the Hexadecameric Phosphorylase Kinase Complex

Phosphorylase kinase (PhK) is a 1.3 MDa (αβγδ)4 enzyme complex, in which αβγδ protomers associate in D2 symmetry to form two large octameric lobes that are interconnected by four bridges. The approximate locations of the subunits have been mapped in low-resolution cryo-electron microscopy structures of the complex; however, the disposition of the subunits within the complex remains largely unknown. We have used partial proteolysis and chemical footprinting in combination with high-resolution mass spectrometry to identify surface-exposed regions of the intact nonactivated and phospho-activated conformers. In addition to the known interaction of the γ subunit's C-terminal regulatory domain with the δ subunit (calmodulin), our exposure results indicate that the catalytic core of γ may also anchor to the PhK complex at the bottom backside of its C-terminal lobe facing away from the active site cleft. Exposed loops on the α and β regulatory subunits within the complex occur at regions overlapping with tissue-specific alternative RNA splice sites and regulatory phosphorylatable domains. Their phosphorylation alters the surface exposure of α and β, corroborating previous biophysical and biochemical studies that detected phosphorylation-dependent conformational changes in these subunits; however, for the first time, specific affected regions have been identified.

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.

Structure and location of the regulatory β subunits in the (αβγδ)4 phosphorylase kinase complex

Phosphorylase kinase (PhK) is a hexadecameric (αβγδ)(4) complex that regulates glycogenolysis in skeletal muscle. Activity of the catalytic γ subunit is regulated by allosteric activators targeting the regulatory α, β, and δ subunits. Three-dimensional EM reconstructions of PhK show it to be two large (αβγδ)(2) lobes joined with D(2) symmetry through interconnecting bridges. The subunit composition of these bridges was unknown, although indirect evidence suggested the β subunits may be involved in their formation. We have used biochemical, biophysical, and computational approaches to not only address the quaternary structure of the β subunits within the PhK complex, i.e. whether they compose the bridges, but also their secondary and tertiary structures. The secondary structure of β was determined to be predominantly helical by comparing the CD spectrum of an αγδ subcomplex with that of the native (αβγδ)(4) complex. An atomic model displaying tertiary structure for the entire β subunit was constructed using chemical cross-linking, MS, threading, and ab initio approaches. Nearly all this model is covered by two templates corresponding to glycosyl hydrolase 15 family members and the A subunit of protein phosphatase 2A. Regarding the quaternary structure of the β subunits, they were directly determined to compose the four interconnecting bridges in the (αβγδ)(4) kinase core, because a β(4) subcomplex was observed through both chemical cross-linking and top-down MS of PhK. The predicted model of the β subunit was docked within the bridges of a cryoelectron microscopic density envelope of PhK utilizing known surface features of the subunit.

Mass spectrometry reveals differences in stability and subunit interactions between activated and nonactivated conformers of the (αβγδ)4 phosphorylase kinase complex

Phosphorylase kinase (PhK), a 1.3 MDa enzyme complex that regulates glycogenolysis, is composed of four copies each of four distinct subunits (α, β, γ, and δ). The catalytic protein kinase subunit within this complex is γ, and its activity is regulated by the three remaining subunits, which are targeted by allosteric activators from neuronal, metabolic, and hormonal signaling pathways. The regulation of activity of the PhK complex from skeletal muscle has been studied extensively; however, considerably less is known about the interactions among its subunits, particularly within the non-activated versus activated forms of the complex. Here, nanoelectrospray mass spectrometry and partial denaturation were used to disrupt PhK, and subunit dissociation patterns of non-activated and phospho-activated (autophosphorylation) conformers were compared. In so doing, we have established a network of subunit contacts that complements and extends prior evidence of subunit interactions obtained from chemical crosslinking, and these subunit interactions have been modeled for both conformers within the context of a known three-dimensional structure of PhK solved by cryoelectron microscopy. Our analyses show that the network of contacts among subunits differs significantly between the nonactivated and phospho-activated conformers of PhK, with the latter revealing new interprotomeric contact patterns for the β subunit, the predominant subunit responsible for PhK's activation by phosphorylation. Partial disruption of the phosphorylated conformer yields several novel subcomplexes containing multiple β subunits, arguing for their self-association within the activated complex. Evidence for the theoretical αβγδ protomeric subcomplex, which has been sought but not previously observed, was also derived from the phospho-activated complex. In addition to changes in subunit interaction patterns upon phospho-activation, mass spectrometry revealed a large change in the overall stability of the complex, with the phospho-activated conformer being more labile, in concordance with previous hypotheses on the mechanism of allosteric activation of PhK through perturbation of its inhibitory quaternary structure.

A review of methods used for identifying structural changes in a large protein complex

This chapter explores the structural responses of a massive, hetero-oligomeric protein complex to a single allosteric activator as probed by a wide range of chemical, biochemical, and biophysical approaches. Some of the approaches used are amenable only to large protein targets, whereas others push the limits of their utility. Some of the techniques focus on individual subunits, or portions thereof, while others examine the complex as a whole. Despite the absence of crystallographic data for the complex, the diverse techniques identify and implicate a small region of its catalytic subunit as the master allosteric activation switch for the entire complex.

The glucoamylase inhibitor acarbose is a direct activator of phosphorylase kinase

Phosphorylase kinase (PhK), an (alphabetagammadelta)(4) complex, stimulates energy production from glycogen in the cascade activation of glycogenolysis. Its large homologous alpha and beta subunits regulate the activity of the catalytic gamma subunit and account for 81% of PhK's mass. Both subunits are thought to be multidomain structures, and recent predictions based on their sequences suggest the presence of potentially functional glucoamylase (GH15)-like domains near their amino termini. We present the first experimental evidence of such a domain in PhK by demonstrating that the glucoamylase inhibitor acarbose binds PhK, perturbs its structure, and stimulates its kinase activity.

Expressed phosphorylase b kinase and its alphagammadelta subcomplex as regulatory models for the rabbit skeletal muscle holoenzyme

Understanding the regulatory interactions among the 16 subunits of the (alphabetagammadelta)(4) phosphorylase b kinase (PhK) complex can only be achieved through reconstructing the holoenzyme or its subcomplexes from the individual subunits. In this study, recombinant baculovirus carrying a vector containing a multigene cassette was created to coexpress in insect cells alpha, beta, gamma, and delta subunits corresponding to rabbit skeletal muscle PhK. The hexadecameric recombinant PhK (rPhK) and its corresponding alphagammadelta trimeric subcomplex were purified to homogeneity with proper subunit stoichiometries. The catalytic activity of rPhK at pH 8.2 and its ratio of activities at pH 6.8 versus pH 8.2 were comparable to those of PhK purified from rabbit muscle (RM PhK), as was the hysteresis (autoactivation) in the rate of product formation at pH 6.8. Both the rPhK and alphagammadelta exhibited only a very low Ca(2+)-independent activity and a Ca(2+)-dependent activity similar to that of the native holoenzyme with [Ca(2+)](0.5) of 0.4 microM for the RM PhK, 0.7 microM for the rPhK, and 1.5 microM for the alphagammadelta trimer. The RM PhK, rPhK, and alphagammadelta subcomplex were also all activated through self-phosphorylation. Using cross-linking and limited proteolysis, the alpha-gamma intersubunit contacts previously observed within the intact RM PhK complex were also observed within the recombinant alphagammadelta subcomplex. Our results indicate that both the rPhK and alphagammadelta subcomplex are promising models for future structure-function studies on the regulation of PhK activity through intersubunit contacts, because both retained the regulatory properties of the enzyme purified from skeletal muscle.

The structure of phosphorylase kinase holoenzyme at 9.9 angstroms resolution and location of the catalytic subunit and the substrate glycogen phosphorylase

Phosphorylase kinase (PhK) coordinates hormonal and neuronal signals to initiate the breakdown of glycogen. The enzyme catalyzes the phosphorylation of inactive glycogen phosphorylase b (GPb), resulting in the formation of active glycogen phosphorylase a. We present a 9.9 Å resolution structure of PhK heterotetramer (αβγδ)₄ determined by cryo-electron microscopy single-particle reconstruction. The enzyme has a butterfly-like shape comprising two lobes with 222 symmetry. This three-dimensional structure has allowed us to dock the catalytic γ subunit to the PhK holoenzyme at a location that is toward the ends of the lobes. We have also determined the structure of PhK decorated with GPb at 18 Å resolution, which shows the location of the substrate near the kinase subunit. The PhK preparation contained a number of smaller particles whose structure at 9.8 Å resolution was consistent with a proteolysed activated form of PhK that had lost the α subunits and possibly the γ subunits.

The regulatory beta subunit of phosphorylase kinase interacts with glyceraldehyde-3-phosphate dehydrogenase

Skeletal muscle phosphorylase kinase (PhK) is an (alphabetagammadelta) 4 hetero-oligomeric enzyme complex that phosphorylates and activates glycogen phosphorylase b (GP b) in a Ca (2+)-dependent reaction that couples muscle contraction with glycogen breakdown. GP b is PhK's only known in vivo substrate; however, given the great size and multiple subunits of the PhK complex, we screened muscle extracts for other potential targets. Extracts of P/J (control) and I/lnJ (PhK deficient) mice were incubated with [gamma- (32)P]ATP with or without Ca (2+) and compared to identify potential substrates. Candidate targets were resolved by two-dimensional polyacrylamide gel electrophoresis, and phosphorylated glyceraldehyde-3-phosphate dehydrogenase (GAPDH) was identified by matrix-assisted laser desorption ionization mass spectroscopy. In vitro studies showed GAPDH to be a Ca (2+)-dependent substrate of PhK, although the rate of phosphorylation is very slow. GAPDH does, however, bind tightly to PhK, inhibiting at low concentrations (IC 50 approximately 0.45 microM) PhK's conversion of GP b. When a short synthetic peptide substrate was substituted for GP b, the inhibition was negligible, suggesting that GAPDH may inhibit predominantly by binding to the PhK complex at a locus distinct from its active site on the gamma subunit. To test this notion, the PhK-GAPDH complex was incubated with a chemical cross-linker, and a dimer between the regulatory beta subunit of PhK and GAPDH was formed. This interaction was confirmed by the fact that a subcomplex of PhK missing the beta subunit, specifically an alphagammadelta subcomplex, was unable to phosphorylate GAPDH, even though it is catalytically active toward GP b. Moreover, GAPDH had no effect on the conversion of GP b by the alphagammadelta subcomplex. The interactions described herein between the beta subunit of PhK and GAPDH provide a possible mechanism for the direct linkage of glycogenolysis and glycolysis in skeletal muscle.

CrossSearch, a user-friendly search engine for detecting chemically cross-linked peptides in conjugated proteins

Chemical cross-linking and high resolution MS have been integrated successfully to capture protein interactions and provide low resolution structural data for proteins that are refractive to analyses by NMR or crystallography. Despite the versatility of these combined techniques, the array of products that is generated from the cross-linking and proteolytic digestion of proteins is immense and generally requires the use of labeling strategies and/or data base search algorithms to distinguish actual cross-linked peptides from the many side products of cross-linking. Most strategies reported to date have focused on the analysis of small cross-linked protein complexes (<60 kDa) because the number of potential forms of covalently modified peptides increases dramatically with the number of peptides generated from the digestion of such complexes. We report herein the development of a user-friendly search engine, CrossSearch, that provides the foundation for an overarching strategy to detect cross-linked peptides from the digests of large (>or=170-kDa) cross-linked proteins, i.e. conjugates. Our strategy combines the use of a low excess of cross-linker, data base searching, and Fourier transform ion cyclotron resonance MS to experimentally minimize and theoretically cull the side products of cross-linking. Using this strategy, the (alpha beta gamma delta)(4) phosphorylase kinase model complex was cross-linked to form with high specificity a 170-kDa betagamma conjugate in which we identified residues involved in the intramolecular cross-linking of the 125-kDa beta subunit between its regulatory N terminus and its C terminus. This finding provides an explanation for previously published homodimeric two-hybrid interactions of the beta subunit and suggests a dynamic structural role for the regulatory N terminus of that subunit. The results offer proof of concept for the CrossSearch strategy for analyzing conjugates and are the first to reveal a tertiary structural element of either homologous alpha or beta regulatory subunit of phosphorylase kinase.

Single molecule analyses of the conformational substates of calmodulin bound to the phosphorylase kinase complex

The four integral delta subunits of the phosphorylase kinase (PhK) complex are identical to calmodulin (CaM) and confer Ca(2+) sensitivity to the enzyme, but bind independently of Ca(2+). In addition to binding Ca(2+), an obligatory activator of PhK's phosphoryltransferase activity, the delta subunits transmit allosteric signals to PhK's remaining alpha, beta, and gamma subunits in activating the enzyme. Under mild conditions about 10% of the delta subunits can be exchanged for exogenous CaM. In this study, a CaM double-mutant derivatized with a fluorescent donor-acceptor pair (CaM-DA) was exchanged for delta to assess the conformational substates of PhKdelta by single molecule fluorescence resonance energy transfer (FRET) +/-Ca(2+). The exchanged subunits were determined to occupy distinct conformations, depending on the absence or presence of Ca(2+), as observed by alterations of the compact, mid-length, and extended populations of their FRET distance distributions. Specifically, the combined predominant mid-length and less common compact conformations of PhKdelta became less abundant in the presence of Ca(2+), with the delta subunits assuming more extended conformations. This behavior is in contrast to the compact forms commonly observed for many of CaM's Ca(2+)-dependent interactions with other proteins. In addition, the conformational distributions of the exchanged PhKdelta subunits were distinct from those of CaM-DA free in solution, +/-Ca(2+), as well as from exogenous CaM bound to the PhK complex as delta'. The distinction between delta and delta' is that the latter binds only in the presence of Ca(2+), but stoichiometrically and at a different location in the complex than delta.

Evidence for the location of the allosteric activation switch in the multisubunit phosphorylase kinase complex from mass spectrometric identification of chemically crosslinked peptides

Phosphorylase kinase (PhK), an (alphabetagammadelta)(4) complex, regulates glycogenolysis. Its activity, catalyzed by the gamma subunit, is tightly controlled by phosphorylation and activators acting through allosteric sites on its regulatory alpha, beta and delta subunits. Activation by phosphorylation is predominantly mediated by the regulatory beta subunit, which undergoes a conformational change that is structurally linked with the gamma subunit and that is characterized by the ability of a short chemical crosslinker to form beta-beta dimers. To determine potential regions of interaction of the beta and gamma subunits, we have used chemical crosslinking and two-hybrid screening. The beta and gamma subunits were crosslinked to each other in phosphorylated PhK, and crosslinked peptides from digests were identified by Fourier transform mass spectrometry, beginning with a search engine developed "in house" that generates a hypothetical list of crosslinked peptides. A conjugate between beta and gamma that was verified by MS/MS corresponded to crosslinking between K303 in the C-terminal regulatory domain of gamma (gammaCRD) and R18 in the N-terminal regulatory region of beta (beta1-31), which contains the phosphorylatable serines 11 and 26. A synthetic peptide corresponding to residues 1-22 of beta inhibited the crosslinking between beta and gamma, and was itself crosslinked to K303 of gamma. In two-hybrid screening, the beta1-31 region controlled beta subunit self-interactions, in that they were favored by truncation of this region or by mutation of the phosphorylatable serines 11 and 26, thus providing structural evidence for a phosphorylation-dependent subunit communication network in the PhK complex involving at least these two regulatory regions of the beta and gamma subunits. The sum of our results considered together with previous findings implicates the gammaCRD as being an allosteric activation switch in PhK that interacts with all three of the enzyme's regulatory subunits and is proximal to the active site cleft.

The cytoskeletal organizing protein Cdc42-interacting protein 4 associates with phosphorylase kinase in skeletal muscle

Phosphorylase kinase is a key enzyme in regulating glycogenolytic flux in skeletal muscle in response to changing energy demands. In the present study, we sought to identify interacting proteins of phosphorylase kinase by yeast two-hybrid screening. Screening a rabbit skeletal muscle cDNA library with the exposed C-terminus of the alpha subunit (residues 1060-1237), we identified eight independent, yet overlapping, constructs of cdc42-interacting protein 4 (CIP4). Immunocytochemistry indicated that CIP4 colocalized with phosphorylase kinase in vivo, and the cognate binding domain on CIP4 was determined to lie between residues 398 and 545. While this region of CIP4 does contain a known src homology 3 domain, transient transfections and coimmunoprecipitation experiments showed that this domain is not responsible for the dimeric interaction. Based upon sequence analysis the association is inferred to be mediated by two proline-rich sequences in CIP4, residues 436-439 and 441-444, that bind to a cognate WW domain found between residues 1107 and 1129 of PhKalpha.

Caspase-3 dependent cleavage and activation of skeletal muscle phosphorylase b kinase

Phosphorylase b kinase (PhK) is a key enzyme involved in the conversion of glycogen to glucose in skeletal muscle and ultimately an increase in intracellular ATP. Since apoptosis is an ATP-dependent event, we investigated the regulation of skeletal muscle PhK during apoptosis. Incubation of PhK with purified caspase-3 in vitro resulted in the highly selective cleavage of the regulatory alpha subunit and resulted in a 2-fold increase in PhK activity. Edman protein sequencing of a stable 72 kD amino-terminal fragment and a 66 kD carboxy-terminal fragment revealed a specific caspase-3 cleavage site within the alpha subunit at residue 646 (DWMD G). Treatment of differentiated C2C12 mouse muscle myoblasts with the inducers of apoptosis staurosporine, TPEN, doxorubicin, or UV irradiation resulted in the disappearance of the alpha subunit of PhK as determined by immunoblotting, as well as a concurrent increase in caspase-3 activity. Moreover, induction of apoptosis by TPEN resulted in increased phosphorylase activity and sustained ATP levels throughout a 7 h time course. However, induction of apoptosis with staurosporine, also a potent PhK inhibitor, led to a rapid loss in phosphorylase activity and intracellular ATP, suggesting that PhK inhibition by staurosporine impairs the ability of apoptotic muscle cells to generate ATP. Thus, these studies indicate that PhK may be a substrate for caspase regulation during apoptosis and suggest that activation of this enzyme may be important for the generation of ATP during programmed cell death.

Cryoelectron microscopy reveals new features in the three-dimensional structure of phosphorylase kinase

Phosphorylase kinase (PhK), a regulatory enzyme in the cascade activation of glycogenolysis, is a 1.3-MDa hexadecameric complex, (alphabetagammadelta)(4). PhK comprises two arched octameric (alphabetagammadelta)(2) lobes that are oriented back-to-back with overall D(2) symmetry and connected by small bridges. These interlobal bridges, arguably the most questionable structural component of PhK, are one of several structural features that potentially are artifactually generated or altered by conventional sample preparation techniques for electron microscopy (EM). To minimize such artifacts, we have solved by cryoEM the first three-dimensional (3D) structure of nonactivated PhK from images of frozen hydrated molecules of the kinase. Minimal dose electron micrographs of PhK in vitreous ice revealed particles in a multitude of orientations. A simple model was used to orient the individual images for 3D reconstruction, followed by multiple rounds of refinement. Three-dimensional reconstruction of nonactivated PhK from approximately 5000 particles revealed a bridged, bilobal molecule with a resolution estimated by Fourier shell correlation analysis at 25 A. This new structure suggests that several prominent features observed in the structure of PhK derived from negatively stained particles arise as artifacts of specimen preparation. In comparison to the structure from negative staining, the cryoEM structure shows three important differences: (1) a dihedral angle between the two lobes of approximately 90 degrees instead of 68 degrees, (2) a compact rather than extended structure for the lobes, and (3) the presence of four, rather than two, connecting bridges, which provides the first direct evidence for these components as authentic elements of the kinase solution structure.

Ca2+-induced structural changes in phosphorylase kinase detected by small-angle X-ray scattering

Phosphorylase kinase (PhK), a 1.3-MDa (alphabetagammadelta)(4) hexadecameric complex, is a Ca(2+)-dependent regulatory enzyme in the cascade activation of glycogenolysis. PhK comprises two arched (alphabetagammadelta)(2) octameric lobes that are oriented back-to-back with overall D(2) symmetry and joined by connecting bridges. From chemical cross-linking and electron microscopy, it is known that the binding of Ca(2+) by PhK perturbs the structure of all its subunits and promotes redistribution of density throughout both its lobes and bridges; however, little is known concerning the interrelationship of these effects. To measure structural changes induced by Ca(2+) in the PhK complex in solution, small-angle X-ray scattering was performed on nonactivated and Ca(2+)-activated PhK. Although the overall dimensions of the complex were not affected by Ca(2+), the cation did promote a shift in the distribution of the scattering density within the hydrated volume occupied by the PhK molecule, indicating a Ca(2+)-induced conformational change. Computer-generated models, based on elements of the known structure of PhK from electron microscopy, were constructed to aid in the interpretation of the scattering data. Models containing two ellipsoids and four cylinders to represent, respectively, the lobes and bridges of the PhK complex provided theoretical scattering profiles that accurately fit the experimental data. Structural differences between the models representing the nonactivated and Ca(2+)-activated conformers of PhK are consistent with Ca(2+)-induced conformational changes in both the lobes and the interlobal bridges.

Baculovirus-mediated overexpression of the phosphorylase b kinase holoenzyme and alpha gamma delta and gamma delta subcomplexes

Recombinant baculoviruses were created and used to coexpress rat phosphorylase kinase (Phk) alpha, gamma, and delta subunits and rabbit beta subunit in insect cells. Coexpression allowed creation of the (alphabetagammadelta)4 hexadecamer, the alphagammadelta heterotrimer, and the gammadelta heterodimeric subcomplexes. Neither the individual alpha, beta, or gamma subunit nor any complex containing the beta subunit other than the hexadecameric holoenzyme was obtained in soluble form. The expressed complexes exhibited pH- and [Ca2+]-dependent specific activities that were similar to those of the Phk holoenzyme purified from rabbit skeletal muscle (SkM Phk). SkM Phk, expressed Phk, and the alphagammadelta subcomplex were activated by exogenous calmodulin and underwent Ca(2+)-dependent autophosphorylation. In some of these features there were subtle differences that could likely be attributed to differences in the covalent modification state of the baculovirus-driven expressed protein. Our results provide an important avenue to probe the detailed characterization of the structure of Phk and the function of the individual domains of the subunits using baculovirus-mediated expression of Phk and Phk subcomplexes.

The calmodulin-binding domain of the catalytic gamma subunit of phosphorylase kinase interacts with its inhibitory alpha subunit: evidence for a Ca2+ sensitive network of quaternary interactions

Chemical cross-linking as a probe of conformation has consistently shown that activators, including Ca(2+) ions, of the (alphabetagammadelta)(4) phosphorylase kinase holoenzyme (PhK) alter the interactions between its regulatory alpha and catalytic gamma subunits. The gamma subunit is also known to interact with the delta subunit, an endogenous molecule of calmodulin that mediates the activation of PhK by Ca(2+) ions. In this study, we have used two-hybrid screening and chemical cross-linking to dissect the regulatory quaternary interactions involving these subunits. The yeast two-hybrid system indicated that regions near the C termini of the gamma (residues 343-386) and alpha (residues 1060-1237) subunits interact. The association of this region of alpha with gamma was corroborated by the isolation of a cross-linked fragment of alpha containing residues 1015-1237 from an alpha-gamma dimer that had been formed within the PhK holoenzyme by formaldehyde, a nearly zero-length cross-linker. Because the region of gamma that we found to interact with alpha has previously been shown to contain a high affinity binding site for calmodulin (Dasgupta, M., Honeycutt, T., and Blumenthal, D. K. (1989) J. Biol. Chem. 264, 17156-17163), we tested the influence of Ca(2+) on the conformation of the alpha subunit and found that the region of alpha that interacts with gamma was, in fact, perturbed by Ca(2+). The results herein support the existence of a Ca(2+)-sensitive communication network among the delta, gamma, and alpha subunits, with the regulatory domain of gamma being the primary mediator. The similarity of such a Ca(2+)-dependent network to the interactions among troponin C, troponin I, and actin is discussed in light of the known structural and functional similarities between troponin I and the gamma subunit of PhK.

A Ca(2+)-dependent global conformational change in the 3D structure of phosphorylase kinase obtained from electron microscopy

Phosphorylase kinase (PhK), a Ca(2+)-dependent regulatory enzyme of the glycogenolytic cascade in skeletal muscle, is a 1.3 MDa hexadecameric oligomer comprising four copies of four distinct subunits, termed alpha, beta, gamma, and delta, the last being endogenous calmodulin. The structures of both nonactivated and Ca(2+)-activated PhK were determined to elucidate Ca(2+)-induced structural changes associated with PhK's activation. Reconstructions of both conformers of the kinase, each including over 11,000 particles, yielded bridged, bilobal structures with resolutions estimated by Fourier shell correlation at 24 A using a 0.5 correlation cutoff, or at 18 A by the 3sigma (corrected for D(2) symmetry) threshold curve. Extensive Ca(2+)-induced structural changes were observed in regions encompassing both the lobes and bridges, consistent with changes in subunit interactions upon activation. The relative placement of the alpha, beta, gamma, and delta subunits in the nonactivated three-dimensional structure, relying upon previous two-dimensional localizations, is in agreement with the known effects of Ca(2+) on subunit conformations and interactions in the PhK complex.

Three-dimensional structure of phosphorylase kinase at 22 A resolution and its complex with glycogen phosphorylase b

Phosphorylase kinase (PhK) integrates hormonal and neuronal signals and is a key enzyme in the control of glycogen metabolism. PhK is one of the largest of the protein kinases and is composed of four types of subunit, with stoichiometry (alphabetagammadelta)(4) and a total MW of 1.3 x 10(6). PhK catalyzes the phosphorylation of inactive glycogen phosphorylase b (GPb), resulting in the formation of active glycogen phosphorylase a (GPa) and the stimulation of glycogenolysis. We have determined the three-dimensional structure of PhK at 22 A resolution by electron microscopy with the random conical tilt method. We have also determined the structure of PhK decorated with GPb at 28 A resolution. GPb is bound toward the ends of each of the lobes with an apparent stoichiometry of four GPb dimers per (alphabetagammadelta)(4) PhK. The PhK/GPb model provides an explanation for the formation of hybrid GPab intermediates in the PhK-catalyzed phosphorylation of GPb.

Studies on interaction of phosphorylase kinase from rabbit skeletal muscle with glycogen in the presence of ATP and ADP

The influence of ATP on complex formation of phosphorylase kinase (PhK) with glycogen in the presence of Ca(2+) and Mg(2+) has been studied. The initial rate of complex formation decreases with increasing ATP concentration, the dependence of the initial rate on the concentration of ATP having a cooperative character. Formation of the complex of PhK with glycogen in the presence of ATP occurs after a lag period, which increases with increasing ATP concentration. The dependence of the initial rate of complex formation (v) on the concentration of non-hydrolyzed ATP analogue, beta,gamma-methylene-ATP, follows the hyperbolic law. A correlation between PhK-glycogen complex formation and (32)P incorporation catalyzed by PhK itself and by the catalytic subunit of cAMP-dependent protein kinase has been shown. For ADP (the product and allosteric effector of the PhK reaction) the dependence of v on ADP concentration has a complicated form, probably due to the sequential binding of ADP at two allosteric sites on the beta subunit and the active site on the gamma subunit.

Direct visualization of the calmodulin subunit of phosphorylase kinase via electron microscopy following subunit exchange

Calmodulin is a tightly bound, intrinsic subunit (delta) of the hexadecameric phosphorylase-b kinase holoenzyme, (alphabetagammadelta)4. To introduce specifically labeled calmodulin into the phosphorylase-b kinase complex for its eventual visualization by electron microscopy, we have developed a method for rapidly exchanging exogenous calmodulin for the intrinsic delta subunit. This method exploits previous findings that low concentrations of urea in the absence of Ca(2+) ions cause the specific dissociation of only the delta subunit from the holoenzyme [Paudel, H. K., and Carlson, G. M. (1990) Biochem. J. 268, 393-399]. In the current study, phosphorylase-b kinase was incubated with excess exogenous calmodulin and a threshold concentration of urea to promote exchange of its delta subunit with the exogenous calmodulin. Size exclusion HPLC was then used to remove the excess calmodulin from the holoenzyme containing exchanged delta subunits. Using metabolically labeled [35S]calmodulin to allow quantification and optimization of exchange conditions, we achieved exchange of approximately 10% of all delta subunits within 1 h, with the exchanged holoenzyme retaining full catalytic activity. Calmodulins derivatized with Nanogold for visualization by scanning transmission electron microscopy were then exchanged for delta, which for the first time allowed localization of the delta subunit within the bridged, bilobal phosphorylase b kinase holoenzyme complex. The delta subunits were determined to be near the edge of the lobes, just distal to the interlobal bridges and proximal to a previously identified region of the enzyme's catalytic gamma subunit.

New frontiers in gold labeling

Recent advances in gold technology have led to probes with improved properties and performance for cell biologists: higher labeling density, better sensitivity, and greater penetration into tissues. Gold clusters, such as the 1.4-nm Nanogold, are gold compounds that can be covalently linked to Fab' antibody fragments, making small and stable probes. Silver enhancement then makes these small gold particles easily visible by EM, LM, and directly by eye. Another advance is the combination of fluorescent and gold probes for correlative microscopy. Chemical crosslinking of gold particles to many biologically active molecules has made possible many novel probes, such as gold-lipids, gold-Ni-NTA, and gold-ATP.

Self-association of the alpha subunit of phosphorylase kinase as determined by two-hybrid screening

The structural organization of the (alphabetagammadelta)(4) phosphorylase kinase complex has been studied using the yeast two-hybrid screen for the purpose of elucidating regions of alpha subunit interactions. By screening a rabbit skeletal muscle cDNA library with residues 1-1059 of the alpha subunit of phosphorylase kinase, we have isolated 16 interacting, independent, yet overlapping transcripts of the alpha subunit containing its C-terminal region. Domain mapping of binary interactions between alpha constructs revealed two regions involved in the self-association of the alpha subunit: residues 833-854, a previously unrecognized leucine zipper, and an unspecified region within residues 1015-1237. The cognate binding partner for the latter domain has been inferred to lie within the stretch from residues 864-1059. Indirect evidence from the literature suggests that the interacting domains contained within the latter two, overlapping regions may be further narrowed to the stretches from 1057 to 1237 and from 864 to 971. Cross-linking of the nonactivated holoenzyme with N-(gamma-maleimidobutyroxy)sulfosuccin-imide ester produced intramolecularly cross-linked alpha-alpha dimers, consistent with portions of two alpha subunits in the holoenyzme being in sufficient proximity to associate. This is the first report to identify potential areas of contact between the alpha subunits of phosphorylase kinase. Additionally, issues regarding the general utility of two-hybrid screening as a method for studying homodimeric interactions are discussed.

Structural features contributing to complex formation between glycogen phosphorylase and phosphorylase kinase

A polyclonal antibody was generated against a peptide corresponding to a region opposite the regulatory face of glycogen phosphorylase b (P-b), providing a probe for detecting and quantifying P-b when it is bound to its activating kinase, phosphorylase kinase (PhK). Using both direct and competition enzyme-linked immunosorbent assays (ELISAs), we have measured the extent of direct binding to PhK of various forms of phosphorylase, including different conformers induced by allosteric effectors as well as forms differing at the N-terminal site phosphorylated by PhK. Strong interactions with PhK were observed for both P-b', a truncated form lacking the site for phosphorylation, and P-a, the phosphorylated form of P-b. Further, the binding of P-b, P-b', and P-a was stimulated a similar amount by Mg(2+), or by Ca(2+) (both being activators of PhK). Our results suggest that the presence and conformation of P-b's N-terminal phosphorylation site do not fully account for the protein's affinity for PhK and that regions distinct from that site may also interact with PhK. Direct ELISAs detected the binding of P-b by a truncated form of the catalytic gamma subunit of PhK, consistent with the necessary interaction of PhK's catalytic subunit with its substrate P-b. In contrast, P-b' bound very poorly to the truncated gamma subunit, suggesting that the N-terminal phosphorylatable region of P-b may be critical in directing P-b to PhK's catalytic subunit and that the binding of P-b' by the PhK holoenzyme may involve more than just its catalytic core. The sum of our results suggests that structural features outside the catalytic domain of PhK and outside the phosphorylatable region of P-b may both be necessary for the maximal interaction of these two proteins.

Activators of phosphorylase kinase alter the cross-linking of its catalytic subunit to the C-terminal one-sixth of its regulatory alpha subunit

Phosphorylase kinase, a regulatory enzyme of glycogenolysis in skeletal muscle, is a hexadecameric oligomer consisting of four copies each of a catalytic subunit (gamma) and three regulatory subunits (alpha, beta, and delta, the last being endogenous calmodulin). The enzyme is activated by a variety of effectors acting through its regulatory subunits. To probe the quaternary structure of nonactivated and activated forms of the kinase, we used the heterobifunctional, photoreactive cross-linker N-5-azido-2-nitrobenzoyloxysuccinimide. Mono-derivatization of the holoenzyme with the succinimidyl group, followed by photoactivation of the covalently attached azido group, resulted in intramolecular cross-linking to form two distinct heterodimers: a major (alphagamma) and a minor (betadelta) conjugate. Formation of both conjugates was significantly altered in activated conformations of the enzyme induced by phosphorylation, alkaline pH, and several allosteric activators (ADP, exogenous calmodulin/Ca2+, and Ca2+ alone). Of these activating mechanisms, all increased formation of alphagamma, except Ca2+ alone, which inhibited its formation. When cross-linking was carried out at alkaline pH or in the presence of ADP or exogenous calmodulin/Ca2+, the cross-linked enzyme remained activated following removal of the activators; however, cross-linking in the presence of Ca2+ resulted in sustained inhibition. The results indicate that perturbations in the subunit cross-linking forming the alphagamma dimer reflect the subsequent extent of sustained activation of the holoenzyme that is measured. The region cross-linked to the catalytic gamma subunit was confined to the C-terminal 1/6th of the alpha subunit, which contains known regulatory regions. These results suggest that activators of the phosphorylase kinase holoenzyme perturb interactions between the C-terminal region of the inhibitory alpha subunit and the catalytic gamma subunit, ultimately leading to activation of the latter.

A tentative mechanism of the ternary complex formation between phosphorylase kinase, glycogen phosphorylase b and glycogen

The kinetics of rabbit skeletal muscle phosphorylase kinase interaction with glycogen has been studied. At pH 6.8 the binding of phosphorylase kinase to glycogen proceeds only in the presence of Mg2+, whereas at pH 8.2 formation of the complex occurs even in the absence of Mg2+. On the other hand, the interaction of phosphorylase kinase with glycogen requires Ca2+ at both pH values. The initial rate of the complex formation is proportional to the enzyme and glycogen concentrations, suggesting the formation of the complex with stoichiometry 1:1 at the initial step of phosphorylase kinase binding by glycogen. According to the kinetic and sedimentation data, the substrate of the phosphorylase kinase reaction, glycogen phosphorylase b, favors the binding of phosphorylase kinase with glycogen. We suggest a model for the ordered binding of phosphorylase b and phosphorylase kinase to the glycogen particle that explains the increase in the tightness of phosphorylase kinase binding with glycogen in the presence of phosphorylase b.

Mg2+ induces conformational changes in the catalytic subunit of phosphorylase kinase, whether by itself or as part of the holoenzyme complex

Phosphorylase kinase (PhK) from skeletal muscle is a structurally complex, highly regulated, hexadecameric enzyme of subunit composition (alpha beta gamma delta)4. Previous studies have revealed that the activity of its catalytic gamma subunit is controlled by alterations in quaternary structure initiated at allosteric and covalent modification sites on PhK's three regulatory subunits; however, changes in the conformation of the holoenzyme initiated by the catalytic subunit have been more difficult to document. In this study a monoclonal antibody (mAb gamma79) has been generated against isolated gamma subunit and used as a conformational probe of that subunit. The epitope recognized by this antibody is within the catalytic core of the gamma subunit, between residues 100 and 240, and monovalent fragments of the antibody inhibit the catalytic activity of the holoenzyme, the gamma-calmodulin binary complex, and the free gamma subunit. Activation of PhK by a variety of mechanisms known or thought to act through its regulatory subunits (phosphorylation, ADP binding, or alkaline pH) increased the binding of the holoenzyme to immobilized mAb gamma79, indicating that activation by any of these distinct mechanisms involves repositioning of the portion of the catalytic domain of the gamma subunit containing the epitope for mAb gamma79. The activating ligand Mg2+ also stimulated the binding of the PhK holoenzyme to immobilized mAb gamma79, as well as the binding of mAb gamma79 to immobilized gamma subunit. Thus, Mg2+ increases the accessibility of the mAb gamma79 epitope in both the isolated gamma subunit and in the holoenzyme. Our results suggest that previously reported influences of Mg2+ on the quaternary structure of the PhK holoenzyme are directly mediated by the gamma subunit.

Zero-length crosslinking of the beta subunit of phosphorylase kinase to the N-terminal half of its regulatory alpha subunit

Phosphorylase kinase, a regulatory enzyme of glycogenolysis in skeletal muscle, is a hexadecameric oligomer containing four copies each of four distinct subunits: alpha, beta, gamma, and delta. By intramolecular zero-length crosslinking with transglutaminase, we have previously demonstrated that the regulatory alpha and beta subunits abut one another in the holoenzyme [Nadeau, O. W., and Carlson, G. M. (1994) J. Biol. Chem. 269, 29670-29676]. Selective partial proteolysis of the 138 kDa alpha subunit in holoenzyme that had been crosslinked by transglutaminase has revealed a high molecular weight conjugate corresponding to full-length beta subunit crosslinked to a 60 kDa N-terminal fragment of alpha (determined by SDS-PAGE, Western blotting and N-terminal sequencing). This conjugate was also observed when the enzyme was first activated by partial proteolysis of alpha and then crosslinked by transglutaminase. Both forms of the kinase, generated by either sequential crosslinking and proteolysis or the reverse, coeluted with non-crosslinked hexadecameric control enzyme in size exclusion chromatography, indicating that the crosslinking was intramolecular, i.e., within hexadecamers. This is the first demonstration of any intersubunit interaction involving the N-terminal domain of the alpha subunit and the first region of any subunit shown to interact with the beta subunit. The results are consistent with the predicted path of the polypeptide backbone of the alpha subunits within the holoenzyme and with the proposed location of the beta subunits.

Effector-sensitive cross-linking of phosphorylase b kinase by the novel cross-linker 4-phenyl-1,2,4-triazoline-3,5-dione

The dienophile 4-phenyl-1,2,4-triazoline-3,5-dione (PTD) was identified as a novel protein cross-linker, and utilized as a conformational probe of phosphorylase b kinase (PhK), a hexadecameric enzyme with the subunit composition (alphabetagammadelta)4. In its reaction with this enzyme, PTD produced five major cross-linked conjugates as resolved by denaturing gel electrophoresis: alphabeta, betagammagamma, alphagamma and a doublet of differently migrating homodimers, betabeta1 and betabeta2. Cross-linking in the presence of six different activators of the kinase targeted to its various subunits caused substantial changes in the amounts of three of the conjugates. The formation of alphagamma was increased by all of the activators but the largest enhancement was caused by exogenous Ca2+/calmodulin. All except one of the activators decreased the amount of betagammagamma formed, with Mg2+ having the greatest effect, and all except two increased the amount of betabeta1, with Mg2+ again having the largest influence. From the overall similarity of the changes in cross-linking by PTD induced by the various activators, we conclude that, even though they are targeted to different sites and subunits, they induce activated conformations of PhK that have certain structural features in common. Regarding the mechanism of cross-linking by PTD, its reaction with a model nucleophile suggests that its initial reaction with a side chain nucleophile of PhK involves a 1,4-conjugate addition to form a urazole adduct, with the secondary cross-linking reaction occurring through an as yet unknown pathway.

The crystal structure of a phosphorylase kinase peptide substrate complex: kinase substrate recognition

The structure of a truncated form of the gamma-subunit of phosphorylase kinase (PHKgammat) has been solved in a ternary complex with a non-hydrolysable ATP analogue (adenylyl imidodiphosphate, AMPPNP) and a heptapeptide substrate related in sequence to both the natural substrate and to the optimal peptide substrate. Kinetic characterization of the phosphotransfer reaction confirms the peptide to be a good substrate, and the structure allows identification of key features responsible for its high affinity. Unexpectedly, the substrate peptide forms a short anti-parallel beta-sheet with the kinase activation segment, the region which in other kinases plays an important role in regulation of enzyme activity. This anchoring of the main chain of the substrate peptide at a fixed distance from the gamma-phosphate of ATP explains the selectivity of PHK for serine/threonine over tyrosine as a substrate. The catalytic core of PHK exists as a dimer in crystals of the ternary complex, and the relevance of this phenomenon to its in vivo recognition of dimeric glycogen phosphorylase b is considered.

Differential affinity cross-linking of phosphorylase kinase conformers by the geometric isomers of phenylenedimaleimide

Phosphorylase b kinase (PbK) from skeletal muscle is a highly regulated oligomer consisting of four copies of four distinct subunits (alphabetagamma)delta4. The gamma subunit is catalytic, and the remaining subunits are regulatory. To characterize effector-induced changes in the quaternary structure of the enzyme, we utilized the ortho-, meta, and para-isomers of phenylenedimaleimide (PDM), which in addition to having different geometries, also vary 2.5-fold in their cross-linking spans. Even at concentrations equivalent to the alphabetagammadelta protomers of PbK, all three isomers caused specific, rapid, and extensive cross-linking of the holoenzyme to form primarily alphabeta dimers, plus smaller amounts of betagammagamma and alphagammagamma trimers. The formation of these three conjugates was nearly totally inhibited by a 10-fold molar excess over PDM of N-(o- and p-tolyl)succinimide, which are chemically inert structural analogs of PDM. This inhibition suggests that PbK has binding sites for PDM and that PDM acts as an affinity cross-linker in binding to these sites prior to forming cross-linked conjugates. The largest effect on cross-linking in progressing from o- to p-PDM was on the alphagammagamma trimer, which is preferentially formed by the p-isomer. Activation of the enzyme by either phosphorylation or the allosteric activators ADP and GDP resulted in large increases in the amount of alphagammagamma formed, small increases in betagammagamma, and little change in alphabeta. When cross-linked in the presence of the reversibly activating nucleoside diphosphates, PbK remained activated after their removal, indicating that cross-linking had locked it in the active conformation. Our results provide direct evidence for perturbations in the interactions of the catalytic gamma subunit with the regulatory alpha and beta subunits upon activation of PbK.

Proximal regions of the catalytic gamma and regulatory beta subunits on the interior lobe face of phosphorylase kinase are structurally coupled to each other and with enzyme activation

Phosphorylase kinase from skeletal muscle is a hexadecameric enzyme with the subunit composition (alphabeta gammadelta)4 and a mass of 1.3 x 10(6) Da. The catalytic gamma subunit and the remaining regulatory subunits are packed as a tetrahedral structure composed of two elongated, opposing (alphabeta gammadelta)2 octameric lobes. We show by immunoelectron microscopy with subunit-specific monoclonal antibodies that a portion of the beta subunit occurs on the interior face of the lobes at a region of inter-lobal interactions, and that at a proximal position slightly more central and distal on the interior lobe face lies the base (residues 277 to 290) of the helical domain of the catalytic core of the gamma subunit. Activation of the kinase by a variety of means caused similar increases in the binding to the holoenzyme of the monoclonal antibodies against these two regions of the beta and gamma subunits. Moreover, monovalent fragments of the antibodies against both regions stimulated the activity of the non-activated holoenzyme. Thus, the epitopes of the beta and gamma subunits recognized by the monoclonal antibodies are structurally coupled to each other and with the activation of phosphorylase kinase. Activation of the holoenzyme apparently involves the repositioning of the base of the catalytic domain of the gamma subunit and a proximal region of the beta subunit within the identified area on the interior face of the lobes of the tetrahedral phosphorylase kinase molecule.

Divalent cations but not other activators enhance phosphorylase kinase's affinity for glycogen phosphorylase

To better understand the physical interaction between glycogen phosphorylase-b (P-b) and its only known kinase, phosphorylase kinase (PbK) and the relationship of this interaction to the activation of PbK, direct binding studies are necessary. By utilizing an enzyme-linked immunosorbent assay, a method was developed for measuring the binding of PbK to immobilized P-b under a variety of experimental conditions. A monoclonal antibody specific for the alpha subunit of PbK that had no effect on the phosphorylation of P-b by PbK or on the interaction of PbK with known effectors was used to detect PbK bound to plated P-b. Hyperbolic binding curves were obtained regardless of whether the concentration of Pbk or P-b was varied, and the assay detected changes in relative affinity caused by certain effectors of the kinase. The allosteric effector ADP, alkaline pH, and phosphorylation by cAMP-dependent protein kinase, all activators of PbK, did not cause significant changes in its relative affinity for P-b; however, Ca2+ and Mg2+ ions, which also stimulate PbK, increased its affinity for P-b, with Mg2+ being more effective. Mn2+, which inhibits the P-b conversion activity of PbK, was found to be the most potent enhancer of its affinity for P-b, although divalent cations may enhance binding. Inclusion of ATP analogs in the binding assay with Ca2+ and Mg2+ to stimulate catalytic assay conditions did not further affect the apparent affinity for P-b, which is consistent with the previously reported rapid equilibrium random bi-bi kinetic mechanism for P-b conversion.

Improved immuno double labelling for cell and structural biology

Colloidal gold is the most widely used electron dense marker in biological electron microscopy. The development of procedures for making gold particles of very defined sizes has made double or even multiple labelling possible using gold of two or more different sizes. Lately a new type of electron dense marker has been developed consisting of ligand-stabilized metal atom clusters rather than colloidal particles. The differences between these two types of markers are highlighted and the advantages of using metal atom clusters for immuno labelling of certain biological specimens are discussed. Possible methods of distinguishing two such cluster labels in double labelling experiments are reviewed.