Ensemble Structure of the Highly Flexible Complex Formed between Vesicular Stomatitis Virus Unassembled Nucleoprotein and its Phosphoprotein Chaperone.

Nucleocapsid assembly is an essential process in the replication of the non-segmented, negative-sense RNA viruses (NNVs). Unassembled nucleoprotein (N(0)) is maintained in an RNA-free and monomeric form by its viral chaperone, the phosphoprotein (P), forming the N(0)-P complex. Our earlier work solved the structure of vesicular stomatitis virus complex formed between an N-terminally truncated N (NΔ21) and a peptide of P (P60) encompassing the N(0)-binding site, but how the full-length P interacts with N(0) remained unknown. Here, we combine several experimental biophysical methods including size exclusion chromatography with detection by light scattering and refractometry, small-angle X-ray and neutron scattering and nuclear magnetic resonance spectroscopy with molecular dynamics simulation and computational modeling to characterize the NΔ21(0)-PFL complex formed with dimeric full-length P. We show that for multi-molecular complexes, simultaneous multiple-curve fitting using small-angle neutron scattering data collected at varying contrast levels provides additional information and can help refine structural ensembles. We demonstrate that (a) vesicular stomatitis virus PFL conserves its high flexibility within the NΔ21(0)-PFL complex and interacts with NΔ21(0) only through its N-terminal extremity; (b) each protomer of P can chaperone one N(0) client protein, leading to the formation of complexes with stoichiometries 1N:P2 and 2N:P2; and (c) phosphorylation of residues Ser60, Thr62 and Ser64 provides no additional interactions with N(0) but creates a metal binding site in PNTR. A comparison with the structures of Nipah virus and Ebola virus N(0)-P core complex suggests a mechanism for the control of nucleocapsid assembly that is common to all NNVs.

Structure of the C-terminal domain of lettuce necrotic yellows virus phosphoprotein.

Lettuce necrotic yellows virus (LNYV) is a prototype of the plant-adapted cytorhabdoviruses. Through a meta-prediction of disorder, we localized a folded C-terminal domain in the amino acid sequence of its phosphoprotein. This domain consists of an autonomous folding unit that is monomeric in solution. Its structure, solved by X-ray crystallography, reveals a lollipop-shaped structure comprising five helices. The structure is different from that of the corresponding domains of other Rhabdoviridae, Filoviridae, and Paramyxovirinae; only the overall topology of the polypeptide chain seems to be conserved, suggesting that this domain evolved under weak selective pressure and varied in size by the acquisition or loss of functional modules.

Self-organization of the vesicular stomatitis virus nucleocapsid into a bullet shape.

The typical bullet shape of Rhabdoviruses is thought to rely on the matrix protein for stabilizing the nucleocapsid coil. Here we scrutinize the morphology of purified and recombinant nucleocapsids of vesicular stomatitis virus in vitro. We elucidate pH and ionic strength conditions for their folding into conical tips and further growth into whole bullets, and provide cryo-electron microscopy reconstructions of the bullet tip and the helical trunk. We address conformational variability of the reconstituted nucleocapsids and the issue of constraints imposed by the binding of matrix protein. Our findings bridge the gap between the isolated nucleoprotein-RNA string in its form of an undulating ribbon, and the tight bullet-shaped virion skeleton.

Ensemble structure of the modular and flexible full-length vesicular stomatitis virus phosphoprotein.

The phosphoprotein (P) is an essential component of the viral replication machinery of non-segmented negative-strand RNA viruses, connecting the viral polymerase to its nucleoprotein-RNA template and acting as a chaperone of the nucleoprotein by preventing nonspecific encapsidation of cellular RNAs. The phosphoprotein of vesicular stomatitis virus (VSV) forms homodimers and possesses a modular organization comprising two stable, well-structured domains concatenated with two intrinsically disordered regions. Here, we used a combination of nuclear magnetic resonance spectroscopy and small-angle X-ray scattering to depict VSV P as an ensemble of continuously exchanging conformers that captures the dynamic character of this protein. We discuss the implications of the dynamics and the large conformational space sampled by VSV P in the assembly and functioning of the viral transcription/replication machinery.

CC2D1A is a regulator of ESCRT-III CHMP4B.

Endosomal sorting complexes required for transport (ESCRTs) 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 human immunodeficiency virus type 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.

Structure of the vesicular stomatitis virus N°-P complex.

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 (N(Δ21)) and a peptide of 60 amino acids (P(60)) encompassing the molecular recognition element (MoRE) of P that binds RNA-free N (N(0)). 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.

The N(0)-binding region of the vesicular stomatitis virus phosphoprotein is globally disordered but contains transient α-helices.

The phosphoprotein (P) of vesicular stomatitis virus (VSV) interacts with nascent nucleoprotein (N), forming the N(0)-P complex that is indispensable for the correct encapsidation of newly synthesized viral RNA genome. In this complex, the N-terminal region (P(NTR)) of P prevents N from binding to cellular RNA and keeps it available for encapsidating viral RNA genomes. Here, using nuclear magnetic resonance (NMR) spectroscopy and small-angle X-ray scattering (SAXS), we show that an isolated peptide corresponding to the 60 first N-terminal residues of VSV P (P(60)) and encompassing P(NTR) has overall molecular dimensions and a dynamic behavior characteristic of a disordered protein but transiently populates conformers containing α-helices. The modeling of P(60) as a conformational ensemble by the ensemble optimization method using SAXS data correctly reproduces the α-helical content detected by NMR spectroscopy and suggests the coexistence of subensembles of different compactness. The populations and overall dimensions of these subensembles are affected by the addition of stabilizing (1M trimethylamine-N-oxide) or destabilizing (6M guanidinium chloride) cosolvents. Our results are interpreted in the context of a scenario whereby VSV P(NTR) constitutes a molecular recognition element undergoing a disorder-to-order transition upon binding to its partner when forming the N(0)-P complex.

Solution structure of the C-terminal nucleoprotein-RNA binding domain of the vesicular stomatitis virus phosphoprotein.

Beyond common features in their genome organization and replication mechanisms, the evolutionary relationships among viruses of the Rhabdoviridae family are difficult to decipher because of the great variability in the amino acid sequence of their proteins. The phosphoprotein (P) of vesicular stomatitis virus (VSV) is an essential component of the RNA transcription and replication machinery; in particular, it contains binding sites for the RNA-dependent RNA polymerase and for the nucleoprotein. Here, we devised a new method for defining boundaries of structured domains from multiple disorder prediction algorithms, and we identified an autonomous folding C-terminal domain in VSV P (P(CTD)). We show that, like the C-terminal domain of rabies virus (RV) P, VSV P(CTD) binds to the viral nucleocapsid (nucleoprotein-RNA complex). We solved the three-dimensional structure of VSV P(CTD) by NMR spectroscopy and found that the topology of its polypeptide chain resembles that of RV P(CTD). The common part of both proteins could be superimposed with a backbone RMSD from mean atomic coordinates of 2.6 A. VSV P(CTD) has a shorter N-terminal helix (alpha(1)) than RV P(CTD); it lacks two alpha-helices (helices alpha(3) and alpha(6) of RV P), and the loop between strands beta(1) and beta(2) is longer than that in RV. Dynamical properties measured by NMR relaxation revealed the presence of fast motions (below the nanosecond timescale) in loop regions (amino acids 209-214) and slower conformational exchange in the N- and C-terminal helices. Characterization of a longer construct indicated that P(CTD) is preceded by a flexible linker. The results presented here support a modular organization of VSV P, with independent folded domains separated by flexible linkers, which is conserved among different genera of Rhabdoviridae and is similar to that proposed for the P proteins of the Paramyxoviridae.

Circular permutation and deletion studies of myoglobin indicate that the correct position of its N-terminus is required for native stability and solubility but not for native-like heme binding and folding.

We studied the effect of deleted and circularly permuted mutations in sperm whale myoglobin and present here results on three classes of mutants: (i) a deletion mutant, Mb(1)(-)(99), in which the C-terminal helices, G and H, were removed; (ii) two circular permutations, Mb-B_GHA, in which helix B is N-terminal and helix A is C-terminal, and Mb-C_GHAB, in which helix C is N-terminal and helices A and B are C-terminal; and (iii) a deleted circular permutation, Mb-HAB_F, in which helix H is N-terminal, helix F is C-terminal, and helix G is deleted. The conformational characteristics of the apo and holo forms of these mutants were determined at neutral pH, by spectroscopic and hydrodynamic methods. The apo form of the deleted and permuted mutants exhibited a stronger tendency to aggregate and had lower ellipticity than the wild type. The mutants retained the ability to bind heme, but only the circularly permuted holoproteins had native-like heme binding and folding. These results agree with the theory that myoglobin has a central core that is able to bind heme, but also indicate that the presence of N- and C-terminal helices is necessary for native-like heme pocket formation. Because the holopermuteins were less stable than the wild-type protein and aggregated, we propose that the native position of the N-terminus is important for the precise structural architecture of myoglobin.

Origin of the anomalous circular dichroism spectra of many apomyoglobin mutants.

Several authors have reported that many sperm whale apomyoglobin mutants show anomalous circular dichroism spectra. These mutants have a low molar ellipticity compared to the wild-type protein but in several cases have the same stability of unfolding. A model in which native apomyoglobin is not folded in the same manner as that in other proteins and in which mutants show progressive reductions in their degree of folding has been suggested to explain this phenomenon. However, nuclear magnetic resonance of the native apomyoglobin conformation has shown that this state is folded and compact, raising the possibility that the anomalous circular dichroism spectra could have another explanation. We studied several mutants with anomalous circular dichroism spectra and found that these proteins were all contaminated with nucleic acid that contributed to the ultraviolet absorption and caused uncertainty in the determination of protein concentration. The resulting overestimation of the concentration of apomyoglobin explains the phenomenon of anomalous circular dichroism spectra. We describe a procedure to remove the contaminant nucleic acid which yields accurate protein concentration measurements and provides the normal circular dichroism spectra. Our findings support a well-structured native conformation for apomyoglobin and may also be of the interest to scientists working with the purification of recombinant proteins.

Fast purification of the Apo form and of a non-binding heme mutant of recombinant sperm whale myoglobin.

As molecular biology has developed it has become possible to abundantly produce heterologous proteins in bacteria and to design serial amino acid substitutions for the generation of modified proteins, an approach also known as protein engineering. Sperm whale myoglobin, a protein of broad interest, has been cloned for several years now and a large collection of mutants has been produced. The presence of heme stabilizes the protein, which is recovered soluble from the bacterial pellet, and most purification protocols take advantage of this property for myoglobin purification directly from the pellet. However, recovery from the column resin is poor with these methods making them expensive and the procedure for removing heme is laborious and drastic when the apo form of Mb is required. In the case of proteins with severe mutations, which bind heme weakly or do not bind it at all, such methods cannot be employed without massive loss of productivity. Here, we describe a modified method, which is both low cost and rapid, for the purification of the soluble apo form of Mb from Escherichia coli inclusion bodies. Biophysical characterization of the protein after purification shows that the purified apoMb retains its native conformation and is soluble. This modified method is also used for the purification of a non-heme-binding apoMb mutant, demonstrating its efficiency when dealing with drastic mutations.