The genome of measles virus is encapsidated by multiple copies of the nucleoprotein (N), forming helical nucleocapsids of molecular mass approaching 150 Megadalton. The intrinsically disordered C-terminal domain of N (N TAIL ) is essential for transcription and replication of the virus via interaction with the phosphoprotein P of the viral polymerase complex. The molecular recognition element (MoRE) of N TAIL that binds P is situated 90 amino acids from the folded RNA-binding domain (N CORE ) of N, raising questions about the functional role of this disordered chain. Here we report the first in situ structural characterization of N TAIL in the context of the entire N-RNA capsid. Using nuclear magnetic resonance spectroscopy, small angle scattering, and electron microscopy, we demonstrate that N TAIL is highly flexible in intact nucleocapsids and that the MoRE is in transient interaction with N CORE . We present a model in which the first 50 disordered amino acids of N TAIL are conformationally restricted as the chain escapes to the outside of the nucleocapsid via the interstitial space between successive N CORE helical turns. The model provides a structural framework for understanding the role of N TAIL in the initiation of viral transcription and replication, placing the flexible MoRE close to the viral RNA and, thus, positioning the polymerase complex in its functional environment.is a member of the Paramyxoviridae family of the Mononegavirales order of negative sense, single stranded RNA viruses. The viral genome is encapsidated by multiple copies of the nucleoprotein (N) forming a helical nucleocapsid. Transcription and replication of the viral RNA are initiated by an interaction between N and the polymerase complex, composed of the phosphoprotein (P) and the RNAdependent RNA polymerase (1). N consists of two domains: N CORE (residues 1-400), responsible for the interaction with the viral RNA and for maintaining the nucleocapsid structure, and a long intrinsically disordered domain, N TAIL (residues 401-525) serving as the anchor point for the polymerase complex (2, 3). The molecular recognition element (MoRE) (residues 485-502) of the disordered N TAIL interacts with the C-terminal three-helix bundle domain, XD, of P (residues 459-507) (4) and thereby recruits the polymerase complex onto the nucleocapsid template (5, 6).The realization that intrinsically disordered proteins (IDPs) are functional despite a lack of structure (7-9) has revealed entirely new paradigms that appear to redefine our understanding of the role of conformational flexibility in molecular interactions (10-12). Until now most IDPs have been studied in isolation, or in the presence of a single interaction partner, although it is evident that a real physiological environment could influence the nature and relevance of apparent intrinsic disorder. In this context resolving the question of whether the protein is actually disordered in situ is of paramount importance. In this case the mechanistic role of the extensive disorder present in N TA...
SummaryThe spectrin superfamily of proteins plays key roles in assembling the actin cytoskeleton in various cell types, crosslinks actin filaments, and acts as scaffolds for the assembly of large protein complexes involved in structural integrity and mechanosensation, as well as cell signaling. α-actinins in particular are the major actin crosslinkers in muscle Z-disks, focal adhesions, and actin stress fibers. We report a complete high-resolution structure of the 200 kDa α-actinin-2 dimer from striated muscle and explore its functional implications on the biochemical and cellular level. The structure provides insight into the phosphoinositide-based mechanism controlling its interaction with sarcomeric proteins such as titin, lays a foundation for studying the impact of pathogenic mutations at molecular resolution, and is likely to be broadly relevant for the regulation of spectrin-like proteins.
Replication of non-segmented negative-strand RNA viruses requires the continuous supply of the nucleoprotein (N) in the form of a complex with the phosphoprotein (P). Here, we present the structural characterization of a soluble, heterodimeric complex between a variant of vesicular stomatitis virus N lacking its 21 N-terminal residues (NΔ21) and a peptide of 60 amino acids (P60) encompassing the molecular recognition element (MoRE) of P that binds RNA-free N (N0). The complex crystallized in a decameric circular form, which was solved at 3.0 Å resolution, reveals how the MoRE folds upon binding to N and competes with RNA binding and N polymerization. Small-angle X-ray scattering experiment and NMR spectroscopy on the soluble complex confirms the binding of the MoRE and indicates that its flanking regions remain flexible in the complex. The structure of this complex also suggests a mechanism for the initiation of viral RNA synthesis.
A protein band of approximately 166 kDa was detected in the soluble fraction of root tips and young leaves of maize seedlings, based on Western blot analysis using antibodies raised against mouse macrophage nitric oxide synthase (NOS) and rabbit brain NOS. NOS activity was present in these soluble fractions, as determined by L-[U-IR C]citrulline synthesis from L-[U-IR C]arginine. Immunofluorescence showed that the maize NOS protein is present in the cytosol of cells in the division zone and is translocated into the nucleus in cells in the elongation zone of maize root tips. These results indicate the existence of a NOS enzyme in maize tissues, with the localization of this protein depending on the phase of cell growth.z 1999 Federation of European Biochemical Societies.
The phosphoprotein (P) is an essential component of the replication machinery of rabies virus (RV) and vesicular stomatitis virus (VSV), and the oligomerization of P, potentially controlled by phosphorylation, is required for its function. Up to now the stoichiometry of phosphoprotein oligomers has been controversial. Size exclusion chromatography combined with detection by multiangle laser light scattering shows that the recombinant unphosphorylated phosphoproteins from VSV and from RV exist as dimers in solution. Hydrodynamic analysis indicates that the dimers are highly asymmetric, with a Stokes radius of 4.8-5.3 nm and a frictional ratio larger than 1.7. Small-angle neutron scattering experiments confirm the dimeric state and the asymmetry of the structure and yield a radius of gyration of about 5.3 nm and a cross-sectional radius of gyration of about 1.6-1.8 nm. Similar hydrodynamic properties and molecular dimensions were obtained with a variant of VSV phosphoprotein in which Ser60 and Thr62 are substituted by Asp residues and which has been reported previously to mimic phosphorylation by inducing oligomerization and activating transcription. Here, we show that this mutant also forms a dimer with hydrodynamic properties and molecular dimensions similar to those of the wild type protein. However, incubation at 30 degrees C for several hours induced self-assembly of both wild type and mutant proteins, leading to the formation of irregular filamentous structures.
Endosomal sorting complexes required for transport (ESCRT) regulate diverse processes ranging from receptor sorting at endosomes to distinct steps in cell division and budding of some enveloped viruses. Common to all processes is the membrane recruitment of ESCRT-III that leads to membrane fission. Here, we show that CC2D1A is a novel regulator of ESCRT-III CHMP4B function. We demonstrate that CHMP4B interacts directly with CC2D1A and CC2D1B with nanomolar affinity by forming a 1:1 complex. Deletion mapping revealed a minimal CC2D1A-CHMP4B binding construct, which includes a short linear sequence within the third DM14 domain of CC2D1A. The CC2D1A binding site on CHMP4B was mapped to the N-terminal helical hairpin. Based on a crystal structure of the CHMP4B helical hairpin two surface patches were identified that interfere with CC2D1A interaction as determined by surface plasmon resonance. Introducing these mutations into a C-terminal truncation of CHMP4B that exerts a potent dominant negative effect on HIV-1 budding, revealed that one of the mutants lost this effect completely. This suggests that the identified CC2D1A binding surface might be required for CHMP4B polymerization, which is consistent with the finding that CC2D1A binding to CHMP4B prevents CHMP4B polymerization in vitro. Thus, CC2D1A might act as a negative regulator of CHMP4B function.
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