Self-association of the α Subunit of Phosphorylase Kinase as Determined by Two-hybrid Screening

Ayers, Nancy A.; Wilkinson, Deborah A.; Fitzgerald, Thomas J.; Carlson, Gerald M.

doi:10.1074/jbc.274.50.35583

Cited by 16 publications

(15 citation statements)

References 49 publications

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“…The most straightforward explanation for those two-hybrid results would be that the full-length wild type ␤ subunit is unable to self-associate because its N terminus interacts with its C terminus, thus blocking self-association of the latter. Such a conclusion could not be reached from two-hybrid data, however, because observed homodimeric interactions could represent either intrasubunit or intersubunit interactions, which would be indistinguishable unless a single small region selfassociated (47). The possibility of intersubunit interactions is of special concern with PhK because ␤␤ dimers can be readily formed in activated PhK by a short cross-linker (42).…”

Section: Discussionmentioning

confidence: 92%

CrossSearch, a User-friendly Search Engine for Detecting Chemically Cross-linked Peptides in Conjugated Proteins

Nadeau

Wyckoff

Paschall

et al. 2008

Molecular & Cellular Proteomics

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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 userfriendly search engine, CrossSearch, that provides the foundation for an overarching strategy to detect crosslinked peptides from the digests of large (>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 (␣␤␥␦) 4 phosphorylase kinase model complex was cross-linked to form with high specificity a 170-kDa ␤␥ conjugate in which we identified residues involved in the intramolecular cross-linking of the 125-kDa ␤ subunit between its regulatory N terminus and its C terminus. This finding provides an explanation for previously published homodimeric two-hybrid interactions of the ␤ 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 ␣ or ␤ regulatory subunit of phosphorylase kinase. Molecular & Cellular Proteomics 7:739 -749, 2008.Chemical cross-linking of proteins is a versatile technique with uses ranging from screening to obtaining relative or absolute structural information for interacting proteins (1). For large proteins that are refractive to techniques such as crystallography or NMR, cross-linking provides a means of gaining moderate to low resolution structural data by generating distance measurements between specific regions of interacting proteins (intermolecular cross-linking) or individual proteins (intramolecular cross-linking). Advances in modern MS methods have promoted a resurgence in the use of crosslinking by eliminating the need for large quantities of conjugates (term used herein to denote either proteins or peptides that are covalently cross-linked) to isolate and identify distinct regions of inter-or intramolecular cross-linked peptides (2, 3). Nanomolar amounts of conjugates are now routinely digested in gel to provide sufficient quantities of peptides for detection by MS meth...

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Section: Discussionmentioning

confidence: 92%

CrossSearch, a User-friendly Search Engine for Detecting Chemically Cross-linked Peptides in Conjugated Proteins

Nadeau

Wyckoff

Paschall

et al. 2008

Molecular & Cellular Proteomics

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“…However, whether these regions may reflect preferential assembly sites for Tpr monomers remains uncertain because yeast reporter gene activity is not necessarily equally proportional to the actual interactions between different pairs of fusion proteins. It can be modulated by various factors, including fusion protein stability and nuclear import and sterical constraints (Ye and Worman, 1995;Ayers et al, 1999).…”

Section: Discussionmentioning

confidence: 99%

Amino Acid Substitutions of Coiled-Coil Protein Tpr Abrogate Anchorage to the Nuclear Pore Complex but Not Parallel, In-Register Homodimerization

Hase

Kuznetsov

Cordes

2001

MBoC

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Tpr is a protein component of nuclear pore complex (NPC)-attached intranuclear filaments. Secondary structure predictions suggest a bipartite structure, with a large N-terminal domain dominated by heptad repeats (HRs) typical for coiled-coil-forming proteins. Proposed functions for Tpr have included roles as a homo-or heteropolymeric architectural element of the nuclear interior. To gain insight into Tpr's ultrastructural properties, we have studied recombinant Tpr segments by circular dichroism spectroscopy, chemical cross-linking, and rotary shadowing electron microscopy. We show that polypeptides of the N-terminal domain homodimerize in vitro and represent ␣-helical molecules of extended rod-like shape. With the use of a yeast two-hybrid approach, arrangement of the coiled-coil is found to be in parallel and in register. To clarify whether Tpr can self-assemble further into homopolymeric filaments, the full-length protein and deletion mutants were overexpressed in human cells and then analyzed by confocal immunofluorescence microscopy, cell fractionation, and immuno-electron microscopy. Surplus Tpr, which does not bind to the NPC, remains in a soluble state of ϳ7.5 S and occasionally forms aggregates of entangled molecules but neither self-assembles into extended linear filaments nor stably binds to other intranuclear structures. Binding to the NPC is shown to depend on the integrity of individual HRs; amino acid substitutions within these HRs abrogate NPC binding and render the protein soluble but do not abolish Tpr's general ability to homodimerize. Possible contributions of Tpr to the structural organization of the nuclear periphery in somatic cells are discussed. INTRODUCTIONThe nuclear pore complex (NPC) is a highly complex structure of eightfold rotational symmetry that serves as the gateway for the exchange of cellular material between cytoplasm and nucleus in eukaryotes. Its core structure consists of central globular subunits flanked by a ring-like structure (annulus) at both the NPC's cytoplasmic (outer) and nucleoplasmic (inner) side. Both annuli are attachment sites for fibrils, also arranged in an eightfold symmetrical pattern but of distinctive shape and protein composition (for recent reviews, see Ohno et al., 1998;Stoffler et al., 1999;Ryan and Wente, 2000). Fibrils emanating from the outer annulus exist as short tufts of ϳ50 nm in length, whereas the rectilinear fibrils of 5-7 nm in diameter attached to the inner annulus vary in length. Approximately 60 -100 nm from the NPC's inner annulus, the intranuclear fibrils are laterally interconnected by another ring-like structure, sometimes described as the "terminal ring." Together, terminal ring and fibrils proximal to the NPC proper are considered to represent a structural and functional entity, called the nuclear "fishtrap" or "basket" (Ris, 1989(Ris, , 1991Jarnik and Aebi, 1991;Goldberg and Allen, 1992).Emanating from the terminal ring, additional fibrils project further into the nuclear interior. In amphibian oocytes these fibrils can be seve...

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“…Protein expression of all ␣ and ␥ constructs was verified by Western analysis, with minor modification, as previously described (24) using either a DNA BD crossreactive LexA polyclonal Ab (kindly provided by Dr. Erica Golemis, Fox Chase Cancer Center) or an AD cross-reactive hemagglutinin mAb (Roche Molecular Biochemicals). Positive associations between ␣ and ␥ constructs were monitored by transcriptional activation of the LEU2 gene by growth on defined media lacking leucine (Leu Ϫ ) and of the lacZ reporter gene by liquid ␤-galactosidase assays using o-nitrophenyl galactopyranoside as substrate (22,25).…”

Section: Methodsmentioning

confidence: 99%

“…Two-hybrid Plasmid Construction-All PhK ␣ constructs were engineered as previously described (22). Rabbit skeletal muscle PhK ␥ cDNA was kindly provided by Dr. Donald J. Graves (Iowa State University) and used as the template for the preparation of all ␥ constructs.…”

Section: Methodsmentioning

confidence: 99%

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The Calmodulin-binding Domain of the Catalytic γ Subunit of Phosphorylase Kinase Interacts with Its Inhibitory α Subunit

Rice

Nadeau

Yang

et al. 2002

Journal of Biological Chemistry

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Chemical cross-linking as a probe of conformation has consistently shown that activators, including Ca 2؉ ions, of the (␣␤␥␦) 4 phosphorylase kinase holoenzyme (PhK) alter the interactions between its regulatory ␣ and catalytic ␥ subunits. The ␥ subunit is also known to interact with the ␦ 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 ␥ (residues 343-386) and ␣ (residues 1060 -1237) subunits interact. The association of this region of ␣ with ␥ was corroborated by the isolation of a crosslinked fragment of ␣ containing residues 1015-1237 from an ␣؊␥ dimer that had been formed within the PhK holoenzyme by formaldehyde, a nearly zero-length cross-linker. Because the region of ␥ that we found to interact with ␣ 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 ␣ subunit and found that the region of ␣ that interacts with ␥ was, in fact, perturbed by Ca 2؉ . The results herein support the existence of a Ca 2؉ -sensitive communication network among the ␦, ␥, and ␣ subunits, with the regulatory domain of ␥ 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 ␥ subunit of PhK.Phosphorylase kinase (PhK) 1 , a Ca 2ϩ -dependent enzyme involved in the regulation of glycogenolysis, is among the largest and most complex enzymes known. Structurally, PhK is composed of four copies each of four different subunits, (␣␤␥␦) 4 and has a mass of 1.3 ϫ 10 6 Da (for reviews see Refs. 1-3). Of the four subunits, ␥ is catalytic, whereas the remaining three are regulatory: ␣ and ␤ exert quaternary constraint on the activity of ␥, and ␦ is an intrinsic molecule of calmodulin (CaM). To fully understand how PhK integrates diverse physiological signals to regulate glycogenolytic flux in skeletal muscle, it is first essential to understand how intrasubunit and intersubunit interactions within the hexadecameric holoenzyme change in response to effector ligands, and in so doing, control its catalytic activity. Despite the increased availability of structural information regarding PhK, interactions associated with activation and involving specific regions of individual subunits, in particular the ␣ and ␤ subunits, have largely remained uncharacterized. In this study, we have focused on delineating interacting regions between the large ␣ and catalytic ␥ subunits to advance our understanding of how structural perturbations correlate with activation of this complex holoenzyme.By using chemical cross-linkers as s...

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Self-association of the α Subunit of Phosphorylase Kinase as Determined by Two-hybrid Screening

Cited by 16 publications

References 49 publications

CrossSearch, a User-friendly Search Engine for Detecting Chemically Cross-linked Peptides in Conjugated Proteins

CrossSearch, a User-friendly Search Engine for Detecting Chemically Cross-linked Peptides in Conjugated Proteins

Amino Acid Substitutions of Coiled-Coil Protein Tpr Abrogate Anchorage to the Nuclear Pore Complex but Not Parallel, In-Register Homodimerization

The Calmodulin-binding Domain of the Catalytic γ Subunit of Phosphorylase Kinase Interacts with Its Inhibitory α Subunit

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