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Volume 6, Issue 1, Pages (July 2000)

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1 Volume 6, Issue 1, Pages 139-148 (July 2000)
Activation of Human Liver Glycogen Phosphorylase by Alteration of the Secondary Structure and Packing of the Catalytic Core  Virginia L. Rath, Mark Ammirati, Peter K. LeMotte, Kimberly F. Fennell, Mahmoud N. Mansour, Dennis E. Danley, Thomas R. Hynes, Gayle K. Schulte, David J. Wasilko, Jayvardhan Pandit  Molecular Cell  Volume 6, Issue 1, Pages (July 2000) DOI: /S (05)

2 Figure 1 Overview of the Structure of Active Human Liver Glycogen Phosphorylase Cα trace in Molscript showing key secondary structures described in the text (Kraulis 1991). One subunit of the functional dimer is colored purple, the other gray; the N and C-terminal domains that make up each subunit are labeled. The catalytic site is marked by the cofactor, PLP. (A) The regulatory face of the enzyme is exposed to the cytosol and includes the AMP site and the phosphorylation site. The first residue visible in the electron density map (5) is labeled N-ter. The phosphorylation site (Ser-14-P) binds across the cap (residues 42′-45′) of the AMP site. The cap is followed by helix 2 (residues 48–78), which forms the base of the AMP site and extends across the width of the protein. The cap of one AMP site leads to helix 2, which forms the base of the AMP site from the other subunit. The outside edge of the AMP site is bounded by the adenine loop, residues 315–324. (B) The catalytic face of the enzyme is bound to the glycogen particle. The 40 residues that undergo structural rearrangement on activation are highlighted in ribbons. The 250's loop (residues 250′-260′) becomes ordered and forms a binding site for the gate (residues 280–289), whose length is shortened by extending helix 8 (residues 286–310) one turn. This shorter gate can no longer extend itself to form a binding site for the glucose analog or the 380's loop (residues 376–386). The 380's loop becomes less well ordered and moves away from the catalytic site. The tower helices (residues 267–274) from each subunit connect the 250's loop and the gate and pack together to form the heart of the subunit interface. On activation, they are shortened, and hydrogen bonds between them are lost. Molecular Cell 2000 6, DOI: ( /S (05) )

3 Figure 2 Refolding and Repacking the Protein Core
Cartoon showing the structural changes that occur on the catalytic face of the enzyme in the (A) inactive and active conformations of HLGP a. The subunits of the functional dimer are shown as circles; N, N-terminal domain; C, C-terminal domain. In the inactive structure, the caffeine site is formed but unoccupied (Phe-285 and Tyr-613 in light blue); solid red cylinder, two turn extension of the tower helix; red dotted lines, hydrogen bonds between the tower helices; dashed black lines, disordered regions of the 250's loop. In the active structure, the subunit rotation axis is shown in green; the caffeine site is absent owing to the displacement of Phe-285; helix 8 is extended by one turn (solid purple cylinder). Inactive (C) and active (D) conformations of HLGP a showing the secondary structural elements and ten residues identified from the structure of yeast glycogen phosphorylase that undergo rearrangement upon activation (Kraulis 1991). Note the shortened gate and the position of Tyr-280, poised to bind substrate. Molecular Cell 2000 6, DOI: ( /S (05) )

4 Figure 3 Differences in the Structure of the AMP Binding Site
(A) Comparison of the AMP site in inactive and active HLGP a. Stereo diagram of the AMP site in active liver phosphorylase (helices, strands, and coils in black; side chains and AMP represented in ball-and-stick form with atom-specific gray-scale), superimposed on the AMP site of inactive HLGP a (helices, strands, and coils in gray; side chains as gray sticks), made in Molscript (Kraulis 1991). (B) Comparison of the AMP site in muscle and liver phosphorylase. Stereo diagram of the AMP site in tetrameric RMGP b (helices, strands, and coils in black; side chains and AMP represented in ball-and-stick form with atom specific gray-scale [Sprang et al. 1991]), superimposed on the AMP site of active HLGP a (helices, strands, and coils in gray, side chains as gray sticks, and AMP represented as black ball-and-stick), made in Molscript (Kraulis 1991). Residues 42′, 44′, and 45′ of the cap that form hydrogen bonds and van der Waals contacts to AMP in both structures are omitted for clarity. In muscle phosphorylase, the adenine N6 amino group is specified by the main chain carbonyls of residues 315, 318, and the side chain of Phe-316. Molecular Cell 2000 6, DOI: ( /S (05) )

5 Figure 4 Contacts between AMP and Phosphorylase
(A) Interactions between Muscle phosphorylase and AMP. Chemdraw figure (CambridgeSoft 1999) showing the hydrogen bonds and principal van der Waals contacts ( Å, wavy lines) between AMP and tetrameric rabbit muscle phosphorylase b (Sprang et al. 1991). (B) Interactions between HLGP a and AMP. Chemdraw figure (CambridgeSoft 1999) showing the hydrogen bonds and principal van der Waals contacts between AMP and active HLGP a. Molecular Cell 2000 6, DOI: ( /S (05) )

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