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

Rice, Nancy A.; Nadeau, Owen W.; Yang, Qing; Carlson, Gerald M.

doi:10.1074/jbc.m201229200

Cited by 27 publications

(57 citation statements)

References 48 publications

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“…The first of these, the GH-15 family of glycosyl hydrolases, provided several good template matches that extended from residues 41 to 670. These results differed from two previous reports that predicted only the GH-15 (␣/␣) 6 catalytic core to be present in ␤ (22, 24), extending approximately through its first 480 residues (22). Just C-terminal to the GH-15 catalytic core, Carriere et al (23) predicted a small loop followed by an additional domain (termed B), which extended from residues 492 to 676; however, they were unable to achieve fold recognition for this domain.…”

Section: Discussioncontrasting

confidence: 56%

“…An independent analysis of the primary structure of ␤ using the Pfam database also predicted a GHL fold for this region of the subunit (69). Our predicted domain structures for residues 40 -670 of the ␤ subunit mirrored that of the shorter domain predicted by Carriere et al (23) and are topologically similar to several domains observed in the template glucodextranase crystal structure (61), comprising an (␣/␣) 6 catalytic core connected to the B and C domains by a short loop (61).…”

Section: Discussionsupporting

confidence: 51%

“…The GH-15 thread coverage of ␤ is indicated in a two-color scheme, with blue and gray representing, respectively, the (␣/␣) 6 -barrel fold for the catalytic domain (A) and a mixed 2°structure corresponding to the B and C domains found in bacterial and archaeal glucoamy- lases and glucodextranases (61). The protein structurally closest to the best model of this region is Anthrobacter globiformus glucodextranase (PDB code 1ULV) (61), with a template modeling score of 0.8462 and root mean square deviation of 1.92 Å, indicating a good topographical match (62).…”

Section: Determination Of 2°structure Of the ␤ Subunit Within The Phkmentioning

confidence: 99%

“…The catalytic ␥ subunit comprises an N-terminal catalytic core (residues 1-298) that has a typical protein kinase fold (2, 3) and a C-terminal regulatory domain (␥CRD) that binds both the intrinsic calmodulin (␦) subunit (4,5), as well as the regulatory ␣ subunit (6). The activity of ␥ in the (␣␤␥␦) 4 complex is tightly regulated by the ␣ (138.4 kDa), ␤ (125.2 kDa), and ␦ (16.7 kDa) subunits, which together promote constraining quaternary (4°) interactions on ␥ (44.7 kDa) that are attenuated by signaling molecules from metabolic, hormonal, and neural pathways that target each of the three regulatory subunits (7,8).…”

mentioning

confidence: 99%

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Structure and Location of the Regulatory β Subunits in the (αβγδ)4 Phosphorylase Kinase Complex

Nadeau

Lane

et al. 2012

Journal of Biological Chemistry

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Background: Structural information concerning the phosphorylatable regulatory ␤ subunit of phosphorylase kinase was lacking. Results: Chemical, biochemical, biophysical, and computational approaches revealed secondary, tertiary, and quaternary structures for this subunit. Conclusion: The ␤ subunit is helical and forms the ␤ 4 -bridged core in the (␣␤␥␦) 4 kinase complex. Significance: These findings reveal the architecture of the complex, which provides an explanation for the conformational changes in its bridged core associated with activating ␤-phosphorylation.

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Section: Discussioncontrasting

confidence: 56%

Section: Discussionsupporting

confidence: 51%

Section: Determination Of 2°structure Of the ␤ Subunit Within The Phkmentioning

confidence: 99%

mentioning

confidence: 99%

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Structure and Location of the Regulatory β Subunits in the (αβγδ)4 Phosphorylase Kinase Complex

Nadeau

Lane

et al. 2012

Journal of Biological Chemistry

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“…S5, Table S1, and SI Methods). Formaldehyde, which has one of the shortest crosslinking spans (<3 Å) was used to yield specific covalent adducts between neighboring chaperonin subunits both within a single ring and across the rings (30,31). Given the similarity in molecular weight and isoelectric point of the TRiC subunits, and hence of their covalently linked dimers, we separated the cross-linked subunits by 2D-PAGE (Fig.…”

Section: Validation Of Subunit Arrangement By Biochemical Near-neighbormentioning

confidence: 99%

4.0-Å resolution cryo-EM structure of the mammalian chaperonin TRiC/CCT reveals its unique subunit arrangement

Yao

Baker

Jakana

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

157

147

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The essential double-ring eukaryotic chaperonin TRiC/CCT (TCP1-ring complex or chaperonin containing TCP1) assists the folding of ∼5-10% of the cellular proteome. Many TRiC substrates cannot be folded by other chaperonins from prokaryotes or archaea. These unique folding properties are likely linked to TRiC's unique heterooligomeric subunit organization, whereby each ring consists of eight different paralogous subunits in an arrangement that remains uncertain. Using single particle cryo-EM without imposing symmetry, we determined the mammalian TRiC structure at 4.7-Å resolution. This revealed the existence of a 2-fold axis between its two rings resulting in two homotypic subunit interactions across the rings. A subsequent 2-fold symmetrized map yielded a 4.0-Å resolution structure that evinces the densities of a large fraction of side chains, loops, and insertions. These features permitted unambiguous identification of all eight individual subunits, despite their sequence similarity. Independent biochemical near-neighbor analysis supports our cryo-EM derived TRiC subunit arrangement. We obtained a Cα backbone model for each subunit from an initial homology model refined against the cryo-EM density. A subsequently optimized atomic model for a subunit showed ∼95% of the main chain dihedral angles in the allowable regions of the Ramachandran plot. The determination of the TRiC subunit arrangement opens the way to understand its unique function and mechanism. In particular, an unevenly distributed positively charged wall lining the closed folding chamber of TRiC differs strikingly from that of prokaryotic and archaeal chaperonins. These interior surface chemical properties likely play an important role in TRiC's cellular substrate specificity.asymmetric reconstruction | atomic model | subunit structure

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Calmodulin

Yap¹,

Ikura²

2004

Handbook of Metalloproteins

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CaM is a ubiquitous eukaryotic calcium binding protein that interacts with hundreds of proteins including kinases and phosphatases, transmembrane ion channels and pumps, and cytoskeletal regulatory proteins. In response to an increase in intracellular calcium, CaM undergoes a major conformational change enabling target binding and activation. In some cases, CaM is able to bind target proteins in the absence of, or independently of, Ca 2+ ; in others, CaM binding may induce inactivation. The structural plasticity of calmodulin is demonstrated by the diversity observed in its interaction with various targets.

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

Cited by 27 publications

References 48 publications

Structure and Location of the Regulatory β Subunits in the (αβγδ)4 Phosphorylase Kinase Complex

Structure and Location of the Regulatory β Subunits in the (αβγδ)4 Phosphorylase Kinase Complex

4.0-Å resolution cryo-EM structure of the mammalian chaperonin TRiC/CCT reveals its unique subunit arrangement

Calmodulin

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