The nonlinear structure of the desmoplakin plakin domain and the effects of cardiomyopathy-linked mutations.

Desmoplakin is a cytoplasmic desmosomal protein that plays a vital role in normal intercellular adhesion. Mutations in desmoplakin can result in devastating skin blistering diseases and arrhythmogenic right ventricular cardiomyopathy, a heart muscle disorder associated with ventricular arrhythmias, heart failure, and sudden death. The desmoplakin N-terminal region is a 1056-amino-acid sequence of unknown structure. It mediates interactions with other desmosomal proteins, is found in a variety of plakin proteins, and spans what has been termed the "plakin domain," which includes residues 180-1022 and consists of six spectrin repeats (SRs) and an Src homology 3 domain. Herein we elucidate the architecture of desmoplakin's plakin domain, as well as its constituent tandem SRs. Small-angle X-ray scattering analysis shows that the entire plakin domain has an "L" shape, with a long arm and a short arm held at a perpendicular angle. The long arm is 24.0 nm long and accommodates four stably folded SRs arranged in tandem. In contrast, the short arm is 17.9 nm in length and accommodates two independently folded repeats and an extended C-terminus. We show that mutations linked to arrhythmogenic right ventricular cardiomyopathy (K470E and R808C) cause local conformational alterations, while the overall folded structure is maintained. This provides the first structural and mechanistic insights into an entire plakin domain and provides a basis for understanding the critical role of desmoplakin in desmosome function.

The desmoglein-specific cytoplasmic region is intrinsically disordered in solution and interacts with multiple desmosomal protein partners.

The desmoglein-specific cytoplasmic region (DSCR) is a conserved region of unknown structure and function that uniquely defines the desmoglein family of cell adhesion molecules. It is the site of caspase cleavage during apoptosis, and its mutation is linked to cardiomyopathy. Here, we reveal that a 276-residue DSCR construct of human desmoglein 1 is intrinsically disordered and forms an interaction hub for desmosomal proteins. In solution, it contains 6.5% helical and 10.3% beta-strand structure based on circular dichroism spectroscopy. A single monomeric state with a predominantly unfolded structure is found by size-exclusion chromatography and analytical ultracentrifugation. Thermal stability assays and nuclear magnetic resonance spectroscopy reveal a nonglobular structure under a range of solution conditions. However, the introduction of detergent micelles increases structure to 18% helical and 16% beta-strand character, suggesting an inducible structure. The DSCR exhibits weak but specific interactions with plakoglobin, the plakin domain of desmoplakin, plakophilin 1, and the cytoplasmic domain of desmocollin 1. The desmoglein 1 membrane proximal region also interacts with all four DSCR ligands, strongly with plakoglobin and plakophilin and more weakly with desmoplakin and desmocollin 1. Thus, the DSCR is an intrinsically disordered functional domain with an inducible structure that, along with the membrane proximal region, forms a flexible scaffold for cytoplasmic assembly at the desmosome.

Phospholipid-interacting proteins by solution-state NMR spectroscopy.

Signaling lipids are found in specific subcellular membranes, where they recruit and regulate cytosolic proteins and contribute to bilayer structure and dynamics. These interactions are vital for signaling and membrane trafficking pathways and contribute to the organization, growth, and differentiation of the cell. However, the analysis of the physical and chemical mechanisms of membrane interaction and lipid recognition is technically challenging, motivating the development of new NMR methods to study lipid and bilayer binding by peripheral membrane proteins in solution. We describe methods that have been optimized for the FYVE and phox (PX) domains of the EEA1 and Vam7p proteins, respectively, both of which specifically recognize phosphatidylinositol 3-phosphate (PtdIns3P) within endocytic membranes. Solution-state NMR methods were used to characterize the phosphoinositide and membrane interaction sites and affinities and can be used to illustrate protein:micelle structures and phospholipid specificities. The methods are generally applicable and can be used to discover and characterize the phospholipid interactions of other membrane-interacting protein domains.

Rab1 guanine nucleotide exchange factor SidM is a major phosphatidylinositol 4-phosphate-binding effector protein of Legionella pneumophila.

The causative agent of Legionnaires disease, Legionella pneumophila, forms a replicative vacuole in phagocytes by means of the intracellular multiplication/defective organelle trafficking (Icm/Dot) type IV secretion system and translocated effector proteins, some of which subvert host GTP and phosphoinositide (PI) metabolism. The Icm/Dot substrate SidC anchors to the membrane of Legionella-containing vacuoles (LCVs) by specifically binding to phosphatidylinositol 4-phosphate (PtdIns(4)P). Using a nonbiased screen for novel L. pneumophila PI-binding proteins, we identified the Rab1 guanine nucleotide exchange factor (GEF) SidM/DrrA as the predominant PtdIns(4)P-binding protein. Purified SidM specifically and directly bound to PtdIns(4)P, whereas the SidM-interacting Icm/Dot substrate LidA preferentially bound PtdIns(3)P but also PtdIns(4)P, and the L. pneumophila Arf1 GEF RalF did not bind to any PIs. The PtdIns(4)P-binding domain of SidM was mapped to the 12-kDa C-terminal sequence, termed "P4M" (PtdIns4P binding of SidM/DrrA). The isolated P4M domain is largely helical and displayed higher PtdIns(4)P binding activity in the context of the alpha-helical, monomeric full-length protein. SidM constructs containing P4M were translocated by Icm/Dot-proficient L. pneumophila and localized to the LCV membrane, indicating that SidM anchors to PtdIns(4)P on LCVs via its P4M domain. An L. pneumophila DeltasidM mutant strain displayed significantly higher amounts of SidC on LCVs, suggesting that SidM and SidC compete for limiting amounts of PtdIns(4)P on the vacuole. Finally, RNA interference revealed that PtdIns(4)P on LCVs is specifically formed by host PtdIns 4-kinase IIIbeta. Thus, L. pneumophila exploits PtdIns(4)P produced by PtdIns 4-kinase IIIbeta to anchor the effectors SidC and SidM to LCVs.

Lipid interaction networks of peripheral membrane proteins revealed by data-driven micelle docking.

Many signaling and trafficking proteins contain modular domains that bind reversibly to cellular membranes. The structural basis of the intermolecular interactions which mediate these membrane-targeting events remains elusive since protein-membrane complexes are not directly accessible to standard structural biology techniques. Here we report a fast protein-micelle docking methodology that yields three-dimensional model structures of proteins inserted into micelles, revealing energetically favorable orientations, convergent insertion angles, and an array of protein-lipid interactions at atomic resolution. The method is applied to two peripheral membrane proteins, the early endosome antigen 1 (EEA1) FYVE (a zinc finger domain found in the proteins Fab1, YOTB/ZK632.12, Vac1, and EEA1) and Vam7p phagocyte oxidase homology domains, which are revealed to form extensive networks of interactions with multiple phospholipid headgroups and acyl chains. The resulting structural models explain extensive published mutagenesis data and reveal novel binding determinants. The docking restraints used here were based on NMR data, but can be derived from any technique that detects insertion of protein residues into a membrane, and can be applied to virtually any peripheral membrane protein or membrane-like structure.

Interaction between the SH3 domains and C-terminal proline-rich region in NADPH oxidase organizer 1 (Noxo1).

NADPH oxidase organizer 1 (Noxo1), harboring a PX domain, two SH3 domains, and a proline-rich region (PRR), participates in activation of superoxide-producing Nox-family NADPH oxidases. Here, we show that Noxo1 supports superoxide production in a cell-free system for gp91(phox)/Nox2 activation by arachidonic acid. This lipid enhances an SH3-mediated binding of Noxo1 to p22(phox), a protein complexed with Nox oxidases; the binding is known to be required for Nox activation. We also demonstrate that the bis-SH3 domain directly interacts with the Noxo1 PRR. The interaction appears to prevent the bis-SH3 domain and PRR from binding to their target proteins; disruption of the intramolecular interaction facilitates Noxo1 binding to p22(phox) and also allows the PRR to associate with the Nox activator Noxa1, which association is crucial for Nox activation as well. These findings suggest that Nox activation involves a conformational change leading to disruption of the bis-SH3-PRR interaction in Noxo1.

Isoform-specific membrane targeting mechanism of Rac during Fc gamma R-mediated phagocytosis: positive charge-dependent and independent targeting mechanism of Rac to the phagosome.

Rac1 and Rac2 are capable of stimulating superoxide production in vitro, but their targeting and functional mechanisms are still unknown. In the present study, we found that Rac1, 2, and 3 all accumulate at the phagosome during Fc gammaR-mediated phagocytosis, and that the order of accumulation (Rac1 > Rac3 > Rac2) depends on the net positive charge in their polybasic (PB) regions (183-188 aa). Although all GFP-tagged prenylated PB regions of Rac isoforms (GFP-Rac(PB)) and GFP-tagged prenylated 6 Ala (GFP-6A) accumulated during phagocytosis, GFP-Rac2(PB) and GFP-6A showed weak accumulation at the phagosome through a linear structure connecting the phagosome and endomembranes. The PB region of Rac1 showed strong phospholipid interaction with PI(3)P, PI(4)P, PI(5)P, PI(3,4,5)P3, and phosphatidic acid, however, that of Rac2 did not. Constitutively active Rac2, GFP-Rac2(Q61L), was predominantly localized at the endomembranes; these endomembranes fused to the phagosome through the linear structure during phagocytosis, and this accumulation mechanism did not depend on positive charge in the PB region. Our conclusion is that Rac1 directly targets to the phagosome using the positively charged PB region and this accumulation mechanism is likely enhanced by the phospholipids. In addition to this mechanism, Rac2 has a positive charge-independent mechanism in which Rac2 initially targets to endomembranes and then these endomembranes fuse to the phagosome.

Dynamic influences on a high-affinity, high-specificity interaction involving the C-terminal SH3 domain of p67phox.

An analysis of the backbone dynamics of the C-terminal Src homology 3 (SH3) domain of p67(phox), p67(phox)SH3(C), in complex with a 32-residue high-affinity (K(d) = 24 nM) peptide, Pf, from the C-terminal region of p47(phox) is presented. This paper represents the first detailed analysis of the backbone dynamics and the ligand-induced changes therein of a high-affinity, high-specificity interaction involving an SH3 domain. The dynamic features are compared with those in the high-affinity, highly specific interaction between the SH3 domain of C-terminal Src kinase (Csk-SH3) and a proline-rich peptide from proline-enriched phosphatase (PEP). Both systems share common dynamic features especially in the canonical PxxP motif recognition surface where slow micro- to millisecond time scale dynamics persist on complex formation especially in several residues that are implicated in ligand recognition and in stabilizing the SH3 fold. These residues are highly conserved in SH3 domains. Ile505, which lies outside the PxxP recognition motif on p67(phox)SH3(C) and is key in conferring high specificity to the p67(phox)SH3(C)/Pf interaction, becomes more disordered upon complex formation. This behavior is similar to that seen in the residues that constitute the specificity surface in Csk-SH3.

Novel human homologues of p47phox and p67phox participate in activation of superoxide-producing NADPH oxidases.

The catalytic core of a superoxide-producing NADPH oxidase (Nox) in phagocytes is gp91phox/Nox2, a membrane-integrated protein that forms a heterodimer with p22phox to constitute flavocytochrome b558. The cytochrome becomes activated by interacting with the adaptor proteins p47phox and p67phox as well as the small GTPase Rac. Here we describe the cloning of human cDNAs for novel proteins homologous to p47phox and p67phox, designated p41nox and p51nox, respectively; the former is encoded by NOXO1 (Nox organizer 1), and the latter is encoded by NOXA1 (Nox activator 1). The novel homologue p41nox interacts with p22phox via the two tandem SH3 domains, as does p47phox. The protein p51nox as well as p67phox can form a complex with p47phox and with p41nox via the C-terminal SH3 domain and binds to GTP-bound Rac via the N-terminal domain containing four tetratricopeptide repeat motifs. These bindings seem to play important roles, since p47phox and p67phox activate the phagocyte oxidase via the same interactions. Indeed, p41nox and p51nox are capable of replacing the corresponding classical homologue in activation of gp91phox. Nox1, a homologue of gp91phox, also can be activated in cells, when it is coexpressed with p41nox and p51nox, with p41nox and p67phox, or with p47phox and p51nox; in the former two cases, Nox1 is partially activated without any stimulants added, suggesting that p41nox is normally in an active state. Thus, the novel homologues p41nox and p51nox likely function together or in combination with a classical one, thereby activating the two Nox family oxidases.

Diverse recognition of non-PxxP peptide ligands by the SH3 domains from p67(phox), Grb2 and Pex13p.

The basic function of the Src homology 3 (SH3) domain is considered to be binding to proline-rich sequences containing a PxxP motif. Recently, many SH3 domains, including those from Grb2 and Pex13p, were reported to bind sequences lacking a PxxP motif. We report here that the 22 residue peptide lacking a PxxP motif, derived from p47(phox), binds to the C-terminal SH3 domain from p67(phox). We applied the NMR cross-saturation method to locate the interaction sites for the non-PxxP peptides on their cognate SH3 domains from p67(phox), Grb2 and Pex13p. The binding site of the Grb2 SH3 partially overlapped the conventional PxxP-binding site, whereas those of p67(phox) and Pex13p SH3s are located in different surface regions. The non-PxxP peptide from p47(phox) binds to the p67(phox) SH3 more tightly when it extends to the N-terminus to include a typical PxxP motif, which enabled the structure determination of the complex, to reveal that the non-PxxP peptide segment interacted with the p67(phox) SH3 in a compact helix-turn-helix structure (PDB entry 1K4U).