An Integrated Structural Mechanism for Relief of Autoinhibition and Membrane Targeting in Cytohesin Family Guanine Nucleotide Exchange Factors: A Dissertation

Guanine nucleotide exchange factors (GEFs) regulate and organize diverse cellular processes through their role in converting GTPases from the inactive GDP bound state to the active GTP bound state. An increasing number of GEFs undergo autoregulatory mechanisms through complex intramolecular interactions. Relief of autoinhibition involves specific phosphorylation or binding to lipid and/or effector proteins at sites distal from the catalytic domain, and is often coupled to membrane recruitment. In Cytohesin Arf GEFs, the catalytic Sec7 domain is autoinhibited by a linker region and C-terminal helix flanking a Pleckstrin Homology (PH) domain. Upon binding of the PH domain to low abundance phosphoinositides, the GTPase Arf6-GTP can both relieve autoinhibition and recruit Cytohesins to the plasma membrane. This thesis focuses on determining the molecular mechanism underlying both these functions. The structural mechanisms by which Arf6-GTP binding relieves autoinhibition were studied using biochemical and crystallographic studies. The crystal structure of the Grp1 PH domain in complex with Arf6 revealed that Arf6-GTP binding relieves autoinhibition through competitive sequestration of the inhibitory elements into grooves formed at the periphery of the interface. Importantly, the interaction orients all known membrane targeting components to a common surface. Detailed biochemical studies showed a common mode of binding among Cytohesin family members in which phosphoinositide head group binding primes the interaction with Arf6, and membrane recruitment of both stimulatory and substrate Arf enhances the effect. To assess changes in the Sec7 domain conformation upon activation, Size Exclusion Chromatography in line with Small Angle X-Ray Scattering (SEC-SAXS) was performed. The unique nature of this data led to the development of a novel data analysis and processing strategy. A graphically based, python-extensible software package was created for data normalization, buffer correction, Guinier Analysis, and constant background subtraction. As an unbiased substitute for traditional buffer subtraction, a method to reconstruct the protein scattering through singular value decomposition (SVD) and linear combination of the basis vectors was developed. These methods produced exceptional data quality and allowed versatility for application to other data collection techniques or systems, especially those lacking confident buffer matching or low signal. SEC-SAXS confirmed the overall structure of autoinhibited Grp1 in solution and showed only slight overall changes upon activation by deletion of the autoinhibitory Cterminal helix. Fusion of Arf6 with Grp1 produced a consistently elongated shape in the active state that was incompatible with the autoinhibited or theoretical active positions of the Sec7 domain. Monte Carlo and rigid body modeling using known structural domains revealed a requirement for Sec7-PH linker flexibility in addition to Sec7 domain mobility. These data support an integrated structural model whereby phosphoinositides and Arf-GTP support nucleotide exchange at membranes through allosteric activation, membrane recruitment, and large-scale rearrangement of the Sec7 domain. Overall, these findings offer insight into Cytohesin function that can be applied to assess relief of autoinhibition in the context of other GEFs and GTPases

Structural Organization and Dynamics of Homodimeric Cytohesin Family Arf GTPase Exchange Factors in Solution and on Membranes

Membrane dynamic processes require Arf GTPase activation by guanine nucleotide exchange factors (GEFs) with a Sec7 domain. Cytohesin family Arf GEFs function in signaling and cell migration through Arf GTPase activation on the plasma membrane and endosomes. In this study, the structural organization of two cytohesins (Grp1 and ARNO) was investigated in solution by size exclusion-small angle X-ray scattering and negative stain-electron microscopy and on membranes by dynamic light scattering, hydrogen-deuterium exchange-mass spectrometry and guanosine diphosphate (GDP)/guanosine triphosphate (GTP) exchange assays. The results suggest that cytohesins form elongated dimers with a central coiled coil and membrane-binding pleckstrin-homology (PH) domains at opposite ends. The dimers display significant conformational heterogeneity, with a preference for compact to intermediate conformations. Phosphoinositide-dependent membrane recruitment is mediated by one PH domain at a time and alters the conformational dynamics to prime allosteric activation by Arf-GTP. A structural model for membrane targeting and allosteric activation of full-length cytohesin dimers is discussed

Structural basis for membrane recruitment and allosteric activation of cytohesin family Arf GTPase exchange factors

Membrane recruitment of cytohesin family Arf guanine nucleotide exchange factors depends on interactions with phosphoinositides and active Arf GTPases that, in turn, relieve autoinhibition of the catalytic Sec7 domain through an unknown structural mechanism. Here, we show that Arf6-GTP relieves autoinhibition by binding to an allosteric site that includes the autoinhibitory elements in addition to the PH domain. The crystal structure of a cytohesin-3 construct encompassing the allosteric site in complex with the head group of phosphatidyl inositol 3,4,5-trisphosphate and N-terminally truncated Arf6-GTP reveals a large conformational rearrangement, whereby autoinhibition can be relieved by competitive sequestration of the autoinhibitory elements in grooves at the Arf6/PH domain interface. Disposition of the known membrane targeting determinants on a common surface is compatible with multivalent membrane docking and subsequent activation of Arf substrates, suggesting a plausible model through which membrane recruitment and allosteric activation could be structurally integrated

Specificity and membrane partitioning of Grsp1 signaling complexes with Grp1 family Arf exchange factors

The Arf exchange factor Grp1 selectively binds phosphatidylinositol 3,4,5-triphosphate [PtdIns(3,4,5)P(3)], which is required for recruitment to the plasma membrane in stimulated cells. The mechanisms for phosphoinositide recognition by the PH domain, catalysis of nucleotide exchange by the Sec7 domain, and autoinhibition by elements proximal to the PH domain are well-characterized. The N-terminal heptad repeats in Grp1 have also been shown to mediate homodimerization in vitro as well as heteromeric interactions with heptad repeats in the FERM domain-containing protein Grsp1 both in vitro and in cells [Klarlund, J. K., et al. (2001) J. Biol. Chem. 276, 40065-40070]. Here, we have characterized the oligomeric state of Grsp1 and Grp1 family proteins (Grp1, ARNO, and Cytohesin-1) as well as the oligomeric state, stoichiometry, and specificity of Grsp1 complexes with Grp1, ARNO, and Cytohesin-1. At low micromolar concentrations, Grp1 and ARNO are homodimeric whereas Cytohesin-1 and Grsp1 are monomeric. When mixed with Grsp1, Grp1 homodimers and Cytohesin-1 monomers spontaneously re-equilibrate to form heterodimers, whereas approximately 50% of ARNO remains homodimeric under the same conditions. Fluorescence resonance energy transfer experiments suggest that the Grsp1 heterodimers with Grp1 and Cytohesin-1 adopt a largely antiparallel orientation. Finally, formation of Grsp1-Grp1 heterodimers does not substantially influence the binding of Grp1 to the headgroups of PtdIns(3,4,5)P(3) or PtdIns(4,5)P(2), nor does it influence partitioning with liposomes containing PtdIns(3,4,5)P(3), PtdIns(4,5)P(2), and/or phosphatidylserine