The Rho-family GTPase, Cdc42, can regulate the actin cytoskeleton through activation of Wiskott-Aldrich syndrome protein (WASP) family members. Activation relieves an autoinhibitory contact between the GTPase-binding domain and the carboxy-terminal region of WASP proteins. Here we report the autoinhibited structure of the GTPase-binding domain of WASP, which can be induced by the C-terminal region or by organic co-solvents. In the autoinhibited complex, intramolecular interactions with the GTPase-binding domain occlude residues of the C terminus that regulate the Arp2/3 actin-nucleating complex. Binding of Cdc42 to the GTPase-binding domain causes a dramatic conformational change, resulting in disruption of the hydrophobic core and release of the C terminus, enabling its interaction with the actin regulatory machinery. These data show that 'intrinsically unstructured' peptides such as the GTPase-binding domain of WASP can be induced into distinct structural and functional states depending on context.
The Rho-family GTP-hydrolysing proteins (GTPases), Cdc42, Rac and Rho, act as molecular switches in signalling pathways that regulate cytoskeletal architecture, gene expression and progression of the cell cycle. Cdc42 and Rac transmit many signals through GTP-dependent binding to effector proteins containing a Cdc42/Rac-interactive-binding (CRIB) motif. One such effector, the Wiskott-Aldrich syndrome protein (WASP), is postulated to link activation of Cdc42 directly to the rearrangement of actin. Human mutations in WASP cause severe defects in haematopoletic cell function, leading to clinical symptoms of thrombocytopenia, immunodeficiency and eczema. Here we report the solution structure of a complex between activated Cdc42 and a minimal GTPase-binding domain (GBD) from WASP. An extended amino-terminal GBD peptide that includes the CRIB motif contacts the switch I, beta2 and alpha5 regions of Cdc42. A carboxy-terminal beta-hairpin and alpha-helix pack against switch II. The Phe-X-His-X2-His portion of the CRIB motif and the alpha-helix appear to mediate sensitivity to the nucleotide switch through contacts to residues 36-40 of Cdc42. Discrimination between the Rho-family members is likely to be governed by GBD contacts to the switch I and alpha5 regions of the GTPases. Structural and biochemical data suggest that GBD-sequence divergence outside the CRIB motif may reflect additional regulatory interactions with functional domains that are specific to individual effectors.
Dysregulation of the calcitonin gene-related peptide (CGRP), a potent vasodilator, is directly implicated in the pathogenesis of migraine. CGRP binds to and signals through the CGRP receptor (CGRP-R), a heterodimer containing the calcitonin receptor-like receptor (CLR), a class B GPCR, and RAMP1, a receptor activity-modifying protein. We have solved the crystal structure of the CLR/RAMP1 N-terminal ectodomain heterodimer, revealing how RAMPs bind to and potentially modulate the activities of the CLR GPCR subfamily. We also report the structures of CLR/RAMP1 in complex with the clinical receptor antagonists olcegepant (BIBN4096BS) and telcagepant (MK0974). Both drugs act by blocking access to the peptide-binding cleft at the interface of CLR and RAMP1. These structures illustrate, for the first time, how small molecules bind to and modulate the activity of a class B GPCR, and highlight the challenges of designing potent receptor antagonists for the treatment of migraine and other class B GPCR-related diseases.
One of the most common motifs for binding RNA in eukaryotes is the RNA binding domain (RBD) or RNA Recognition Motif (RRM). One of the more intriguing aspects of these proteins is their modular nature. Proteins have been found containing from one to four RRMs. In most instances, these domains have some basal level of non-sequence specific RNA binding affinity. In addition, many also have a higher affinity for a specific structure or sequence of RNA. In the cases of heterogenous nuclear ribonucleoprotein A1 (hnRNP A1), yeast poly-A binding protein and splicing factor U2AF65, the individual free energy of binding of the RBDs for RNA are not strictly additive. By invoking a model in which the amino acids connecting adjoining RBDs are considered to be flexible linkers with an interresidue spacing of about 3.5 A, it is possible to predict the apparent association constants for at least some multi-RBD proteins to single-stranded RNA. We have surveyed the literature and found that individual RBDs are separated by 'linker' sequences of highly variable length. These linkers provide a critical determinant of binding affinity and may modulate cis versus trans binding. A clearer understanding of multi-RBD binding is essential to critically evaluating the role of these proteins in RNA splicing, packaging and transport.
Heterogenous nuclear ribonucleoproteins (hnRNPs) such as hnRNP A1 are tightly associated with heterogenous nuclear RNAs (hnRNAs) within eukaryotic nuclei and are thought to be involved in hnRNA processing and splice site selection. The NH2-terminal two-thirds of hnRNP A1 contains two 92-amino acid RNA binding domains (RBDs) that are arranged in tandem and are more than 30% homologous with each other. Following this region is a flexible glycine-rich COOH-terminal domain. We have studied the nucleic acid binding properties of the two isolated RBDs (residues 1-92 and 93-184, respectively) and of A1 fragments corresponding to residues 1-184 and 1-196 (i.e., the latter fragment is called UP1) in order to evaluate their relative contributions to A1 binding. We have determined that the individual RBDs of A1 bind poly[r(epsilon A)], a fluorescent single-stranded RNA (ssRNA), with a surprisingly low apparent association constant of only 1.5 x 10(4) M-1 (1-92) and 4.5 x 10(4) M-1 (93-184), respectively. We hypothesize that this low affinity represents a basal level of binding that is common to most RBD-containing proteins. Oligonucleotide binding studies suggest the interaction site size for the 93-184 fragment is approximately 4 nucleotides or less and salt sensitivity studies indicate that only about 27% of the free energy of binding of this RBD derives from ionic interactions. Since the affinity of the 1-184 fragment is at least 10-fold above that of either of its component RBDs, both must contribute to binding. This conclusion is further supported by the increased occluded site size of 1-184 (n = 14 +/- 2), as compared to its 93-184 RBD (n = 6 +/- 1), and by the biphasic binding that was observed for the UP1:poly(U) interaction at pH 6.0. Our finding that the affinity of the 1-184 fragment is 1000-fold less than the product of the affinities of its 1-92 and 93-184 RBDs is consistent with these domains being joined by a flexible linker. By comparing the affinities of the 1-184 fragment with that for A1, we conclude that together the two RBDs in A1 account for only 53% of the free energy of A1 binding. Comparative binding studies with UP1 demonstrate that the short region spanning residues 185-->195 represents an important determinant of the binding affinity of A1 and, since this region contains a site of dimethylation, it may provide a mechanism for regulating the affinity of A1 for specific nucleic acid targets.
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