James H. Hurley

Crystal Structure of a Phosphatidylinositol 3-Phosphate-Specific Membrane-Targeting Motif, the FYVE Domain of Vps27p

Phosphatidylinositol 3-phosphate regulates membrane trafficking and signaling pathways by interacting with the FYVE domains of target proteins. The 1.15 A structure of the Vps27p FYVE domain reveals two antiparallel beta sheets and an alpha helix stabilized by two Zn2+-binding clusters. The core secondary structures are similar to a rabphilin-3A Zn2+-binding domain and to the C1 and LIM domains. Phosphatidylinositol 3-phosphate binds to a pocket formed by the (R/K)(R/K)HHCR motif. A lattice contact shows how anionic ligands can interact with the phosphatidylinositol 3-phosphate-binding site. The tip of the FYVE domain has basic and hydrophobic surfaces positioned so that nonspecific interactions with the phospholipid bilayer can abet specific binding to phosphatidylinositol 3-phosphate.

Structure of the regulatory complex of Escherichia coli IIIGlc with glycerol kinase

The phosphocarrier protein IIIGlc is an integral component of the bacterial phosphotransferase (PTS) system. Unphosphorylated IIIGlc inhibits non-PTS carbohydrate transport systems by binding to diverse target proteins. The crystal structure at 2.6 A resolution of one of the targets, glycerol kinase (GK), in complex with unphosphorylated IIIGlc, glycerol, and adenosine diphosphate was determined. GK contains a region that is topologically identical to the adenosine triphosphate binding domains of hexokinase, the 70-kD heat shock cognate, and actin. IIIGlc binds far from the catalytic site of GK, indicating that long-range conformational changes mediate the inhibition of GK by IIIGlc. GK and IIIGlc are bound by hydrophobic and electrostatic interactions, with only one hydrogen bond involving an uncharged group. The phosphorylation site of IIIGlc, His90, is buried in a hydrophobic environment formed by the active site region of IIIGlc and a 3(10) helix of GK, suggesting that phosphorylation prevents IIIGlc binding to GK by directly disrupting protein-protein interactions.

Structure, Mechanism, and Regulation of Mammalian Adenylyl Cyclase

The discovery of 39,59-cyclic adenosine monophosphate (cAMP) in the late 1950s by Sutherland and co-workers was the pivotal event that led to our current paradigm of hormone signaling through second messengers. Despite the subsequent discovery of many other second messengers, cAMP has never left center stage. The adenylyl cyclases are the family of enzymes that synthesize cAMP (1–5). Breakthroughs in determining the first structures of the mammalian adenylyl cyclase catalytic core (6, 7) provide a new context for understanding the action of many regulators, both physiological and pharmacological: free metal ions, P-site inhibitors, forskolin, G-proteins, Ca/calmodulin, and protein phosphorylation. Understanding the catalytic mechanism of an enzyme is a prerequisite to understanding its regulation. Here I will describe the essentials of catalysis and then consider how these elements are controlled by each of the major regulators.

Structure of Type IIβ Phosphatidylinositol Phosphate Kinase: A Protein Kinase Fold Flattened for Interfacial Phosphorylation

Phosphoinositide kinases play central roles in signal transduction by phosphorylating the inositol ring at specific positions. The structure of one such enzyme, type IIbeta phosphatidylinositol phosphate kinase, reveals a protein kinase ATP-binding core and demonstrates that all phosphoinositide kinases belong to one superfamily. The enzyme is a disc-shaped homodimer with a 33 x 48 A basic flat face that suggests an electrostatic mechanism for plasma membrane targeting. Conserved basic residues form a putative phosphatidylinositol phosphate specificity site. The substrate-binding site is open on one side, consistent with dual specificity for phosphatidylinositol 3- and 5-phosphates. A modeled complex with membrane-bound substrate and ATP shows how a phosphoinositide kinase can phosphorylate its substrate in situ at the membrane interface.

Crystal Structure and Allosteric Activation of Protein Kinase C βII

Protein kinase C (PKC) isozymes are the paradigmatic effectors of lipid signaling. PKCs translocate to cell membranes and are allosterically activated upon binding of the lipid diacylglycerol to their C1A and C1B domains. The crystal structure of full-length protein kinase C βII was determined at 4.0 Å, revealing the conformation of an unexpected intermediate in the activation pathway. Here, the kinase active site is accessible to substrate, yet the conformation of the active site corresponds to a low-activity state because the ATP-binding side chain of Phe629 of the conserved NFD motif is displaced. The C1B domain clamps the NFD helix in a low-activity conformation, which is reversed upon membrane binding. A low-resolution solution structure of the closed conformation of PKCβII was derived from small-angle X-ray scattering. Together, these results show how PKCβII is allosterically regulated in two steps, with the second step defining a novel protein kinase regulatory mechanism.

Syp1 is a conserved endocytic adaptor that contains domains involved in cargo selection and membrane tubulation.

Internalization of diverse transmembrane cargos from the plasma membrane requires a similarly diverse array of specialized adaptors, yet only a few adaptors have been characterized. We report the identification of the muniscin family of endocytic adaptors that is conserved from yeast to human beings. Solving the structures of yeast muniscin domains confirmed the unique combination of an N‐terminal domain homologous to the crescent‐shaped membrane‐tubulating EFC/F‐BAR domains and a C‐terminal domain homologous to cargo‐binding μ homology domains (μHDs). In vitro and in vivo assays confirmed membrane‐tubulation activity for muniscin EFC/F‐BAR domains. The μHD domain has conserved interactions with the endocytic adaptor/scaffold Ede1/eps15, which influences muniscin localization. The transmembrane protein Mid2, earlier implicated in polarized Rho1 signalling, was identified as a cargo of the yeast adaptor protein. These and other data suggest a model in which the muniscins provide a combined adaptor/membrane‐tubulation activity that is important for regulating endocytosis.

Normalization of nomenclature for peptide motifs as ligands of modular protein domains

We propose a normalization of symbols and terms used to describe, accurately and succinctly, the detailed interactions between amino acid residues of pairs of interacting proteins at protein:protein (or protein:peptide) interfaces. Our aim is to unify several diverse descriptions currently in use in order to facilitate communication in the rapidly progressing field of signaling by protein domains. In order for the nomenclature to be convenient and widely used, we also suggest a parallel set of symbols restricted to the ASCII format allowing accurate parsing of the nomenclature to a computer‐readable form. This proposal will be reviewed in the future and will therefore be open for the inclusion of new rules, modifications and changes.

The adenylyl and guanylyl cyclase superfamily.

New structures solved in 1997 revealed that the adenylyl cyclase core consists of a pair of catalytic domains arranged in a wreath. Homologous catalytic domains are arranged in diverse adenylyl and guanylyl cyclases as symmetric homodimers or pseudosymmetric heterodimers. The kinship of the adenylyl and guanylyl cyclases has been confirmed by the structure-based interconversion of their nucleotide specificities. Catalysis is activated when two metal-binding aspartate residues on one domain are juxtaposed with a key aspargine-arginine pair on the other. Allosteric activators of mammalian adenylyl cyclase, forskolin and the stimulatory G protein alpha subunit, promote the catalytically optimal juxtaposition of the two domains.

Protein kinase C and phospholipase C: bilayer interactions and regulation.

Protein kinase C and phospholipase C are interfacially active modular enzymes that contain multiple membrane-binding domains. During the past two years, 3D structures and functional data have been reported for the key domains: pleckstrin homology, protein kinase C homology-1 and -2, and the phospholipase C catalytic domain. Roles for membrane bilayer structure and lipid microdomains have become clearly domains has shown how the domains work together to coordinate regulation.

Three discrete regions of mammalian adenylyl cyclase form a site for Gsalpha activation.

The interaction between the α subunit of G protein Gs (Gsα) and the two cytoplasmic domains of adenylyl cyclase (C1 and C2) is a key step in the stimulation of cAMP synthesis by hormones. Mutational analysis reveals that three discrete regions in the primary sequence of adenylyl cyclase affect the EC50values for Gsα activation and thus are the affinity determinants of Gsα. Based on the three-dimensional structure of C2·forskolin dimer, these three regions (C2 α2, C2 α3/β4, and C1β1) are close together and form a negatively charged and hydrophobic groove the width of an α helix that can accommodate the positively charged adenylyl cyclase binding region of Gsα. Two mutations in the C2 α3/β4 region decrease theV max values of Gsα activation without an increase in the EC50 values. Since these three regions are distal to the catalytic site, the likely mechanism for Gsα activation is to modulate the structure of the active site by controlling the orientation of the C2 α2 and α3/β4 structures.