Interaction of the C-Terminal Domains of Sendai Virus N and P Proteins: Comparison of Polymerase-Nucleocapsid Interactions within the Paramyxovirus Family

Interaction of the C-terminal domains of Sendai virus (SeV)P and N proteins is crucial for RNA synthesis by correctly positioningthe polymerase complex (L+P) onto the nucleocapsid (N/RNA).To better understand this mechanism within the paramyxovirusfamily, we have studied the complex formed by the SeV C-terminaldomains of P (PX) and N (N_TAIL) proteins by solution nuclearmagnetic resonance spectroscopy. We have characterized SeV N_TAIL,which belongs to the class of intrinsically disordered proteins,and precisely defined the binding regions within this latterdomain and within PX. SeV N_TAIL binds with residues 472 to 493,which have a helical propensity (residues 477 to 491) to thesurface created by helices ${alpha}$ 2 and ${alpha}$ 3 of PX with a 1:1 stoichiometry,as was also found for measles virus (MV). The binding interfaceis dominated by charged residues, and the dissociation constantwas determined to be 57 ± 18 µM under conditionsof the experiment (i.e., in 0.5 M NaCl). We have also shownthat the extreme C terminus of SeV N_TAIL does not interact withPX, which is in contrast to MV, where a second binding sitewas identified. In addition, the interaction surfaces of theMV proteins are hydrophobic and a stronger binding constantwas found. This gives a good illustration of how selection pressureallowed the C-terminal domains of N and P proteins to evolveconcomitantly within this family of viruses in order to leadto protein complexes having the same three-dimensional fold,and thus the same function, but with completely different bindinginterfaces.

INTRODUCTION

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INTRODUCTION

Sendai virus (SeV) was discovered in 1952 (26) and is also referredto as murine parainfluenza virus as it was found to infect therespiratory tract of mice, to cause pneumonia, and to readilyspread to uninfected animals. It has recently been shown thatSeV was able to replicate in the upper and lower respiratorytracts of chimpanzees and African green monkeys and could, therefore,theoretically also cause zoonotic disease in humans (37). SeVbelongs to the paramyxovirus family. This family includes severalhuman pathogens, such as human parainfluenza viruses, measlesand mumps viruses, which cause severe respiratory diseases ininfants and young children. Despite extensive vaccination campaignsagainst measles and mumps, the diseases have not been eradicatedand outbreaks even occur within vaccinated populations (36).Moreover, no vaccine exists for human parainfluenza viruses.As for other paramyxoviruses, the genome of SeV is a negative-sensesingle-stranded RNA molecule, approximately 15,000 nucleotidesin length. Within the virion, the nucleoprotein (N) packagesthe genomic RNA into a helical protein-RNA complex termed thenucleocapsid, with a stoichiometry of one N protomer for sixnucleotides (6, 13, 24). In the cytoplasm of an infected cell,the viral RNA polymerase uses the nucleocapsid as a templatefor both the replication and encapsidation of the viral genome,as well as the transcription to messenger RNAs encoding theviral proteins. The viral RNA polymerase has no known homologuein humans and is therefore an interesting target for antiviraltreatment. This enzyme is constituted of two proteins, the large(L) protein and the phosphoprotein (P). The L protein containsthe polymerase activity as well as the capping and polyadenylationactivities (1, 15, 41). The P protein plays a crucial role inthe enzyme by positioning L onto the N/RNA template throughan interaction with the C-terminal domain of N (14). WithoutP, L is not functional. The N, P, and L proteins of SeV andmeasles and mumps viruses are functionally equivalent. However,sequence identity between proteins from these viruses is limited,and the viruses have been placed in different genera (Respirovirus,Morbilivirus, and Rubulavirus, respectively).

The Paramyxoviridae L protein is the least-characterized proteinof the replicative complex and is also the biggest protein encodedby the viral genome ( $~$ 2,250 amino acids [aa]). Bioinformaticstudies showed that six regions of good conservation can bedefined within the L protein sequences. These regions have beenproposed to be important for the various enzymatic activitiesnecessary for viral transcription and replication (31, 35).

SeV P protein (568 aa) is a modular protein with distinct functionaldomains (39). The N-terminal part of P (PNT) is a chaperonefor N and prevents it from binding to nonviral RNA in the infectedcell (11). The C-terminal part of P (PCT) is only functionalas an oligomer and forms with L the polymerase complex (8).PNT is poorly conserved and unstructured in solution (18, 19),while PCT contains the oligomerization domain (PMD) that foldsas a homotetrameric coiled coil (40) containing the L bindingregion and a C-terminal partially folded domain, PX (residues474 to 568), identified as the nucleocapsid binding site (33).Interestingly, PX is also expressed as an independent polypeptidein infected cells (10). PX has a C-subdomain (residues 516 to568) that consists of three ${alpha}$ -helices arranged in an antiparalleltriple-helical bundle linked to an unfolded flexible N-subdomain(residues 474 to 515) (3) (Fig. 1). The structure of the entireSeV PCT was modeled by combining the independently obtainedthree-dimensional (3D) structures of its constituent parts withsmall-angle scattering data on the whole domain (3). All paramyxovirusP proteins are likely to be oligomeric, containing sequencerepeats in the central region of the molecule characteristicof helical coiled coils (8). Despite the low sequence conservation,the extreme C terminus of measles virus (MV) P protein (XD,residues 459 to 507) adopts a similar ${alpha}$ -helical fold to the SeVPX C-subdomain (16) (Fig. 1). As for the corresponding regionof P from mumps virus (residues 343 to 392), spectroscopic studieshave shown that it is also predominantly ${alpha}$ -helical, but witha lesser degree of tertiary organization (21). Nevertheless,in all three viruses it is this very C-terminal end of P thatinteracts with the nucleocapsid.

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FIG. 1. Schematic representation of the sequences of the C-terminal domains of N and P proteins used or discussed in this article. (From top to bottom) SeV N_TAIL, with the striped region indicating the SeV P protein binding site on N_TAIL, as suggested by the work of Çevik et al. (7), and the black regions indicating the two predicted ${alpha}$ helices (Jpred program). Two shorter SeV N_TAIL constructs were also used: N_TAIL(443-524) and N_TAIL(443-501). For comparison, the MV N_TAIL is shown with the two regions involved in binding to the C-terminal domain of MV P protein (XD) indicated: region 488 to 504, which undergoes induced ${alpha}$ -helical folding (16, 22), and the additional site region 517 to 525 found by Bourhis et al. (5). The C-terminal domain of SeV P protein (PX [474 to 568]) and the C-terminal domain of MV protein P (XD [459 to 507]) are also depicted. In the last two domains, the gray regions correspond to the three ${alpha}$ helices observed in these domains.

As for other paramyxoviruses, SeV N protein (524 aa) is dividedinto two regions (27): the well-conserved N_CORE (residues 1to 400) and the hypervariable N_TAIL (residues 401 to 524) (Fig.1). SeV N_CORE contains all the regions required for self-assemblyand RNA binding, whereas SeV N_TAIL is involved in PX binding(9). In all Paramyxoviridae, N_TAIL has very few predicted secondarystructure elements (18). Using various biochemical and biophysicalapproaches, it was shown that N_TAIL of MV is unstructured insolution (4) but undergoes an induced folding in the presenceof the C-terminal domain of MV P (4, 16). Using both solutionnuclear magnetic resonance (NMR) spectroscopy and X-ray crystallography,Kingston et al. (22) confirmed that a specific region of MVN_TAIL (residues 487 to 503) (Fig. 1) binds as an ${alpha}$ -helix to thesurface created by the second ( ${alpha}$ 2) and third ( ${alpha}$ 3) helices of MVXD (Fig. 1), in an orientation parallel to helix 3, creatinga four-helix bundle. Recently an additional site (residues 517to 525) within MV N_TAIL has been shown to be involved in bindingto XD but retains its unfolded character (5). In contrast, itwas shown that the nucleocapsid binding domain of the mumpsP protein, does not bind to N_TAIL but to its structured N_COREdomain (21). Altogether these results showed that polymerasebinding mechanisms are similar in morbiliviruses (MV) and respiroviruses(SeV) but differ significantly in rubulaviruses (mumps virus).However, some differences also seem to exist between the MVand SeV polymerase binding mechanisms. Çevik et al. (7)have identified, by mutation and deletion, residues in SeV N_TAIL(residues 461 to 472) that are essential for the interactionwith P, but unlike for measles virus, these residues do notmatch the main predicted ${alpha}$ -helix in SeV N_TAIL (Fig. 1). Moreovermutant studies of SeV PX have shown that not only residues inthe folded C-subdomain, but also a few residues in the unfoldedN-subdomain of PX (absent in the MV study; Fig. 1), are importantfor the complex formation with N (42).

The aim of this work is to study in detail the interaction betweenSeV PX and N_TAIL and to unequivocally define the precise regionswithin PX and N_TAIL that mediate association of the polymerasewith the nucleocapsid in SeV and to compare these results withthe MV XD-N_TAIL complex (22). For this, various SeV N_TAIL constructswere created by deleting two regions within the entire N_TAILdomain (Fig. 1). These N_TAIL constructs were then characterizedand used for binding assays involving PX using mainly NMR spectroscopy.The results show that PX and N_TAIL bind through an interactionbetween residues 472 to 493 of N_TAIL and helices ${alpha}$ 2 and ${alpha}$ 3 ofPX. The N_TAIL extreme C terminus was shown not to interact withPX, in contrast to what was found for MV (5).

While on a global level the mechanisms of transcription andreplication in SeV and measles and mumps viruses are very similar,on a molecular level some differences exist which highlightthe evolutional flexibility of viruses. Knowledge about thesedifferences in viral working strategy is important for findingways of attacking these viruses.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Expression and purification. (i) SeV C-terminal domain of P protein (X protein). The SeV X protein (PX) spanning aa 474 to 568 of the P protein(Swiss-Prot accession no. P04859) was overproduced with an amino-terminalhexa-His tag followed by a factor Xa cleavage site and purifiedas described previously (28, 39).

(ii) SeV N_TAIL, N_TAIL(443-524), and N_TAIL(443-501). A synthetic gene coding for the Harris strain of SeV N_TAIL (havingthe same amino acid sequence as the N_TAIL Fushimi strain Q07097,apart from a single mutation at position 410 [E410K]) was producedby GENEART GmbH (Regensburg, Germany) with its DNA sequenceadapted to the Escherichia coli codon usage. This gene was clonedvia the NdeI and XhoI restriction sites into the pET-TEV vectorthat is a modified pET28a (Novagen) in which the thrombin cleavagesite (CTGGTGCCGCGCGGCAGC) was replaced with a TEV cleavage site(GAAAACCTGTATTTTCAGGGC) and the T7 tag (ATGACTGGTGGACAGCAAATGGGTCGC)was deleted. The expressed protein (N_TAIL) consisted of an amino-terminalhexa-His tag followed by a TEV cleavage site. After TEV cleavage,the N_TAIL construct contained three additional residues (GHM)at the N terminus. The two shorter constructs, N_TAIL(443-524)and N_TAIL(443-501), were obtained by subcloning the correspondingregion into an expression vector giving rise to a protein havingan amino-terminal nona-His tag followed by a TEV cleavage site(RoBioMol cloning platform; IBS, Grenoble, France). The threeconstructs were then produced in E. coli BL21(DE3) (Novagen)at 37°C after induction with 1 mM isopropyl-ß-D-thiogalactopyranoside(IPTG).

For ¹⁵N or ¹⁵N/¹³C isotopic labeling, E. coli BL21(DE3) freshlytransformed with the appropriate plasmid was grown in 2 litersof M9 minimal medium containing, respectively, 1 g/liter ¹⁵NH₄Cl,1 g/liter ¹⁵NH₄Cl, and 2 g/liter [¹³C]glucose as sole nitrogenand carbon sources.

The same protocol was used to purify N_TAIL, N_TAIL(443-524),and N_TAIL(443-501). The cell pellet containing the recombinantprotein was resuspended in 30 ml Tris-HCl buffer (50 mM [pH8]) and 500 mM NaCl supplemented with 300 µl of proteaseinhibitor cocktail (stock solution, 50x) (Complete; BoehringerMannheim). Cells were disrupted by sonication, and the solubleextract was then recovered after centrifugation at 45,000 xg for 45 min at 4°C. The supernatant was injected onto animmobilized metal affinity chromatography (IMAC)-Ni column (5cm by 1.5 cm) (QIAGEN), previously equilibrated in Tris-HClbuffer (50 mM [pH 8])-500 mM NaCl, containing 5 mM imidazole.A step gradient of imidazole (5, 20, and 350 mM) was used forelution (25 ml for the 5 and 20 mM fractions and 12 ml for the350 mM fraction). Imidazole in the N_TAIL-containing fractionwas then removed by dialysis against Tris-HCl buffer (50 mM[pH 8]), 500 mM NaCl. The polyhistidine tag was cleaved offusing a TEV protease/N_TAIL mass ratio of 1:100 overnight at20°C. The N_TAIL constructs were further purified by a secondNi column equilibrated in the same buffer as the first one.The unbound fractions of this column containing the N_TAIL constructs(without the His tag) were concentrated and loaded on a Superdex75 (1.6 cm by 60 cm) column (GE Healthcare) equilibrated inpotassium phosphate buffer (50 mM [pH 6]) and 500 mM NaCl. Elutedfractions of each column were analyzed by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) for the presence of the recombinantprotein and verification of protein purity.

Protein concentrations were calculated using the following theoreticalabsorption coefficients at 280 nm (obtained by using ProtParamat the EXPASY server): 12,490 M^–1 cm^–1 for N_TAILand 5,500 M^–1 cm^–1 for the two shorter N_TAIL constructs.

Mass spectrometry. Matrix-assisted laser desorption ionization-time of flight (MALDI-TOF)experiments, used to verify the mass of the purified proteins,were performed on a Voyager Elite spectrometer (Perspective).

Biochemical binding assays. For binding experiments, $~$ 5 µg of purified His-tagged SeVPX was immobilized on nickel beads (50 µl) (QIAGEN) andfurther incubated for 60 min at 20°C with 8 µg ofpurified SeV N_TAIL in 50 mM Tris-HCl (pH 8) in the presenceof 0, 100, 300, or 500 mM NaCl. Beads were washed with the samebuffer, and immobilized material was eluted with 30 µlof 500 mM imidazole. Samples were heat denatured before SDS-PAGEanalysis.

NMR spectroscopy. (i) NMR sample preparation. All NMR samples (N_TAIL constructs and PX) used were preparedin potassium phosphate buffer (50 mM [pH 6]) with 500 mM NaCl,0.02% NaN₃, protease inhibitor cocktail [Complete; BoehringerMannheim]) and 10% D₂O. Dithiothreitol was added to the PX samplebecause of the presence of a single cysteine residue. All sampleshad a protein concentration around 1 mM unless described differently.

(ii) NMR experiments. NMR spectra were acquired at 25°C on a 600-MHz Varian Inovaspectrometer equipped with a triple-resonance (¹H, ¹³C, ¹⁵N)probe including shielded z-gradients. 2D ¹H-¹⁵N correlationspectra of the three N_TAIL constructs were typically recordedusing spectral widths of 7620 x 1,300 Hz, 512 x 170 complexpoints, and offsets of 4.7 x 118 ppm. For {¹H}-¹⁵N steady-stateheteronuclear nuclear Overhauser effect (NOE) experiments (20)a 3-s 1.7-kHz WALTZ16 decoupling scheme centered at the amideproton frequencies was used to saturate the amide proton signals,which was replaced by a 3-s delay in the reference experiment.The recycle delay in both experiments was set to 2 s. HeteronuclearNOE values per amide group were obtained from the ratio betweensignal intensities in the saturated and the reference experiments,where the standard deviation in the noise was taken as a measurefor the error in the signal intensity. 2D HET-SOFAST experimentswere recorded as described by Schanda et al. (34), using a 0.2-srecycle delay and selective ¹⁵N pulses centered around 8.0 ppm.A ¹H 140° PC9 excitation pulse with an average field strengthof 0.36 kHz and a REBURP refocusing pulse with an average fieldstrength of 0.87 kHz were used. To keep the acquisition timeshort, only 384 complex points were used in the ¹H dimension.Information on the structural compactness (34) was obtainedfrom the ratio between the signal intensity in an experimentwhere the aliphatic protons were selectively inverted and thatof a reference experiment.

Resonance assignment of the short construct N_TAIL(443-501) wasperformed using a series of triple-resonance NMR experiments:a CBCA(CO)NH experiment which correlates (C^ß_i-1 andC_i-1 to H^N_i and N_i), and a CBCANH experiment which provides,in addition, the correlation of C^ß_i and C_i to H^N_iand N_i. Carbon side-chain resonances were extracted from an(H)C(C) total correlated spectroscopy (TOCSY)-(CO)NH experiment.Biopack sequences provided by Varian were used with minor modification.Due to the unfolded character of N_TAIL, the chemical shift dispersionfor all nuclei is limited. Therefore, semiconstant time acquisitionwas performed along the ¹⁵N dimension. The spectral widths alongthe ¹³C, ¹⁵N, and ¹H dimensions were, respectively, 10,000 Hz,1,125 Hz, and 6,000 Hz. Data were processed using nmrPipe (12)and analyzed using nmrview (17). For the indirect dimensions,the time-domain signal was extended using linear predictionby 30 data points prior to apodization and fast Fourier transform(FFT). Arginine side-chain NH resonances were assigned usinga Arg-(H)C(C)TOCSY-NH experiment (32). The chemical shift assignmentwas carried out in a semiautomated manner using a home-modifiedversion of Smartnotebook (version 3.2) (38) and has been depositedin the Biological Magnetic Resonance Data Bank (BMRB) underaccession no. 15123. H^N-H^N NOEs were obtained from a 3D (H)N-NOEspectroscopy (NOESY)-(H)N-heteronuclear single quantum correlation(HSQC) experiment (150-ms mixing time) recorded on a VarianInova 800-MHz spectrometer equipped with a cryogenically cooledprobe.

Secondary C chemical shift values ( ${Delta}$ ${delta}$ _sec C) were calculated usingthe sequence-specific random coil C chemical shift values providedby Wishart et al. (43).

NMR titration and K_D determination. (i) ¹⁵N-PX and unlabeled N_TAIL. Unlabeled N_TAIL from two batches (115 µl at 3.1 mM and100 µl at 1.7 mM) was gradually added to a 507-µl0.47 mM ¹⁵N-labeled PX sample. After each addition, a 2D ¹H-¹⁵NHSQC spectrum was recorded to follow the effect of the interactionof N_TAIL on the PX signal positions and intensities. The finalN_TAIL concentration was 0.73 mM, corresponding to a 2.2 excesswith respect to PX, taking into account the lower PX concentration(0.33 mM) due to dilution of the sample.

(ii) ¹⁵N-N_TAIL and unlabeled PX. The titration of ¹⁵N-N_TAIL with unlabeled PX was performed intwo stages. First, 490 µl of 1 mM PX was added in ninesteps to a 535-µl 0.3 mM ¹⁵N-N_TAIL sample. This samplewas concentrated back to 500 µl, followed by additionof another 400 µl 1 mM PX in three steps, reaching a finalratio [N_TAIL]/[PX] ratio of 1:4.9.

(iii) ¹⁵N N_TAIL(443-501) and unlabeled PX. A ¹⁵N-N_TAIL(443-501) 490-µl 0.6 mM sample was used, and250 µl of a 2 mM unlabeled PX sample was gradually addedto this sample, following the chemical shift changes from ¹H-¹⁵NHSQC spectra.

(iv) K_D determination. The dissociation constant K_D can be estimated from the changesin chemical shifts of the ¹⁵N-labeled protein (A) caused byaddition of the unlabeled binding partner (B), by fitting thechemical shift changes to the following equation for a two-statemodel in fast exchange:

Formula 1 (1)
where

Formula 2 (2)
is the combinedvalue of observed proton and nitrogen chemical shift changesof one peak at a certain ratio of A to B, R is a scaling factorset to 6.5 determined from the ratio of variances in amide protonand nitrogen chemical shifts as observed in the BioMagResBank,and ${Delta}$ ${delta}$ _end is the final chemical shift difference between freeand complexed protein A.

RESULTS

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RESULTS

SeV N_TAIL belongs to the class of intrinsically disordered proteins. The SeV N_TAIL nucleotide sequence showed a high frequency ofE. coli rare codons clustered in the middle of the sequence,which is likely to cause expression problems in E. coli. Indeed,no SeV N_TAIL production was obtained when the natural gene wasexpressed in E. coli BL21(DE3) nor in E. coli strains supplementedwith tRNA genes for rare codons [BL21(DE3)RIL and Rosetta(DE3)].To improve SeV N_TAIL expression, an optimized N_TAIL syntheticgene was produced in which 70% of the codons were changed, includingall of the E. coli rare codons. This synthetic gene was thencloned in an expression vector. N_TAIL and the two shorter constructs,N_TAIL(443-524) and N_TAIL(443-501), were produced from the syntheticgene in E. coli BL21(DE3) as described in Materials and Methods.A high-level production of the three SeV N_TAIL constructs wasobtained in both LB medium and M9 minimal medium. For SeV N_TAILas well as N_TAIL(443-524) and N_TAIL(443-501), the protein wasmainly recovered in the soluble fraction of bacterial lysates.The proteins were purified to homogeneity in three steps. Theidentity of the recombinant products was confirmed by mass spectrometryanalysis and N-terminal sequencing. SeV N_TAIL and the two shorterconstructs displayed an abnormally slow migration in SDS-PAGEeven after heat denaturation (Fig. 2). They migrated with apparentmolecular masses (MMs) of $~$ 21, 16, and 12 kDa, respectively,for N_TAIL, N_TAIL(443-524), and N_TAIL(443-501), whereas theirMMs are 13.4, 8.9, and 6.7 kDa. SeV N_TAIL, N_TAIL(443-524), andN_TAIL(443-501) were eluted from the gel filtration column assymmetrical peaks with elution volumes corresponding to globularproteins with masses of $~$ 31.4, 19.8, and 12.9 kDa, respectively(data not shown). This behavior has already been observed forother intrinsically disordered proteins and also for MV N_TAIL(27). The same profile was observed regardless of the natureof the buffer (50 mM Tris-HCl [pH 8], 50 mM potassium phosphate[pH 6]) and the presence of different NaCl concentrations (0.2,0.3, and 0.5 M). These first results confirm that SeV N_TAILdoes not adopt a well-folded structure (18).

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FIG. 2. Purified SeV N_TAIL constructs. Shown are results of Coomassie blue staining of a 15% SDS-PAGE. Lane 1, size markers, indicated in kilodaltons; lane 2, N_TAIL; lane 3, N_TAIL(443-524); lane 4, N_TAIL(443-501).

To further characterize SeV N_TAIL and the two shorter constructs,several NMR experiments were recorded. The 2D ¹H-¹⁵N HSQC spectrumof SeV N_TAIL (Fig. 3A) represents a typical spectrum of an unfoldedprotein, since the signals are centered around 8.3 ppm in the¹H dimension. A total of 122 intense signals of the expected126 backbone amides can be identified, as well as 9 less-intensesignals, which probably result from a minor conformation (themass spectrum of the sample only showed one component). Excludingthese 9 lower-intensity signals, all peaks have narrow linewidths, indicative of a flexible protein. In addition to thebackbone signals, the expected side-chain signals of Trp (2residues), Asn (3 residues), and Gln (4 residues) are presentin the spectrum. Comparison of the 2D ¹H-¹⁵N HSQC spectra ofthe three N_TAIL constructs (Fig. 3) shows that the structuralenvironments of the three proteins are identical, since thespectra superimpose perfectly. Only a very few signals (boxesin Fig. 3) are different, which presumably represent the amidesof residues at the boundaries of the constructs. Interestingly,the set of smaller signals is present in both N_TAIL and N_TAIL(443-524)but absent in N_TAIL(443-501).

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FIG. 3. 2D ¹H-¹⁵N HSQC of (A) SeV N_TAIL, (B) N_TAIL(443-524), and (C) N_TAIL(443-501) recorded at 25°C on a 600-MHz spectrometer. Positive contour levels are presented in black and negative contour levels in gray. The two negative signals around 108 ppm in the nitrogen dimension are folded signals that resonate around 129 ppm. Dashed lines connect the two signals from the Asn and Gln side-chain NH₂ groups. The spectra are typical for a disordered protein, and the spectra of the different constructs superimpose perfectly. The few peaks that do not superimpose are indicated by gray boxes and presumably correspond to residues at the boundaries of the constructs.

In order to further characterize the structural properties ofthe N_TAIL constructs, we measured both ¹⁵N heteronuclear NOE(hetNOE) (20) values that give information on fast local motions,as well as ${lambda}$ _NOE values from the HET-SOFAST (34) experiment, thatreport on "structural compactness" (data not shown). The majorityof residues in the three constructs are very flexible, as evidencedby low hetNOE values (<0.35), and have an unstructured character,as evidenced by ${lambda}$ _NOE values between 0.6 and 1. However, in allthree N_TAIL constructs, the same 10 residues have hetNOE valuesbetween 0.35 and 0.6 and ${lambda}$ _NOE values ranging from 0.25 to 0.5,and thus represent a region that is less flexible and has arelatively high structural compactness.

SeV N_TAIL binds to the surface created by the second ( ${alpha}$ 2) and third ( ${alpha}$ 3) helices of PX. NMR experiments are necessarily performed at high protein concentrations,and we previously found that PX at such high concentrationsis only stable in 0.5 M NaCl (3). In order to analyze the effectof ionic strength on the interaction between SeV PX and N_TAIL,binding experiments were carried out using His-tagged PX immobilizedon a metal affinity support, which was further incubated withN_TAIL. Besides small amounts of N_TAIL unspecifically recoveredin the eluted fractions in the absence of PX (since no His tagis present in N_TAIL), we observed roughly the same amount ofN_TAIL eluting with His-tagged PX whatever the ionic strength(between 0 and 500 mM NaCl) (Fig. 4). Therefore, all NMR experimentson mixtures of PX and N_TAIL were performed at 0.5 M NaCl.

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FIG. 4. Binding of SeV N_TAIL to PX is not influenced by ionic strength. Shown are the results of Coomassie blue staining by 15% SDS-PAGE. Lane M, size markers indicated in kilodaltons. The two following lanes contain purified PX and N_TAIL proteins as specific markers. The next two lanes show two control experiments in which immobilized tagged PX on nickel beads was incubated without N_TAIL and N_TAIL was incubated without PX. Coelution experiments were performed with immobilized tagged PX incubated with N_TAIL and washed with different NaCl concentrations (0, 100, 300, and 500 mM).

NMR chemical shifts are very sensitive to the local environmentof the nuclear spin, and NMR is therefore a very useful techniqueto map protein interaction sites. While labeling only one ofthe two interacting proteins, the effect of the binding partnercan be studied by recording ¹H-¹⁵N HSQC spectra after additionof increasing amounts of the unlabeled binding partner. In thecase of strong binding, the signals of the free protein willdisappear and new signals of the complex will appear, whichis referred to as "slow exchange." When the two proteins onlybind weakly, signals will move to a new position while addingthe binding partner, reaching a plateau value when saturatingthe complex, which is referred to as "fast exchange." In thecase of intermediate exchange, signals will broaden during thecourse of the titration. In the case of PX, about 20 signalsare affected by the addition of unlabeled N_TAIL. Some peaksonly change position, while others clearly show line broadening,which in some cases even causes the signal to become too broadto be detected above the noise level (Fig. 5A). The chemicalshift changes along the protein sequence are shown in Fig. 5B,where negative bars indicate residues that could not be followeddue to extreme line broadening. Clearly, only residues in thefolded C-subdomain are affected, and more specifically the N_TAILbinding site is located on the surface created by the second( ${alpha}$ 2) and third ( ${alpha}$ 3) helices of PX, as shown in Fig. 5C.

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FIG. 5. Titration of ¹⁵N-PX with N_TAIL. (A) Superimposition of seven ¹H-¹⁵N HSQC spectra at relative ratios of N_TAIL to PX that are indicated on the top right of the figure. This zoom illustrates PX resonances that shift (bold), broaden (boxed), or disappear (italic) upon N_TAIL binding, which is typical for intermediate exchange. (B) Backbone amide chemical shift variations between the free and bound forms of PX. Chemical shift changes larger than the average chemical shift change plus 1 standard deviation (0.065 ppm) were considered significant and are represented by the orange (>0.065 ppm) and red (>0.13 ppm) bars. Some residues from the His tag (<474) are missing in the spectrum; all of the other gaps represent proline residues. Green bars correspond to residues showing extreme line broadening. (C) Ribbon representation of the lowest-energy structure of the PX C-subdomain (Protein Data Bank accession no. 1R4G), color coded according to the chemical shift changes shown in panel B. Balls represent the backbone amide groups that are affected by the presence of N_TAIL. (D) Relative chemical shift changes for V559 versus the ratio between ¹⁵N-PX and N_TAIL concentrations. The intersection at a ratio of 1:1 implies that one PX molecule binds to one N_TAIL molecule.

The chemical shift changes as a function of PX and N_TAIL concentrationswere fitted to equation 1, using both the dissociation constantK_D and the plateau value ${Delta}$ ${delta}$ _end as fitting parameters. In thisway, an average K_D of 57 ± 18 µM was found, using13 of the affected peaks. Using the ${Delta}$ ${delta}$ _end values, a 1:1 stoichiometryof the complex could be determined, as shown for Val559 in Fig.5D.

The binding site of SeV N_TAIL is only located in one region having a helical propensity. In order to precisely define residues of N_TAIL involved in PXbinding, a similar NMR experiment was done involving ¹⁵N-N_TAILand unlabeled PX. About 20 N_TAIL signals are affected by thepresence of PX (Fig. 6). Some signals only change position,while others clearly show line broadening as was observed forPX resonances in presence of N_TAIL. All of the affected N_TAILsignals are not only found in the 2D ¹H-¹⁵N HSQC of N_TAIL(443-524)but also in the spectrum of the shortest construct, N_TAIL(443-501),allowing us to conclude that the N_TAIL binding region on PXis only located between residues 443 and 501 and thus that theextreme C terminus of SeV N_TAIL does not interact with PX. Interactionbetween ¹⁵N-N_TAIL(443-501) and unlabeled PX confirmed that thesame resonances are affected by the presence of PX in both N_TAILand N_TAIL(443-501). As we assigned the resonances of this shorterconstruct (Fig. 7), the PX binding site can now be mapped onthe N_TAIL(443-501) sequence, and comprises residues 472 to 493.In panels A to D of Fig. 8, an overview of the structural propertiesof N_TAIL(443-501) is presented, where the PX interaction site,as identified from the titration with PX (Fig. 8E), is indicatedby the gray area. Chemical shift deviations from random coilof the C atoms in the region 477 to 491 are higher than 0.9ppm and indicate that this region, which falls within the PXinteraction site, shows a helical tendency in uncomplexed N_TAIL.This is confirmed by the higher hetNOE values that indicatereduced flexibility, low ${lambda}$ _NOE values that evidence the presenceof a structured region, and strong H^N-H^N(i,i + 1) NOEs, as wellas the presence of H^N-H^N(i,i + 2) NOEs, which are both typicalfor an ${alpha}$ -helical structure. The region is slightly smaller thanthe ${alpha}$ helix (residues 477 to 493) predicted by the consensusmethod used for protein secondary structure prediction (Jpred;http://www.compbio.dundee.ac.uk/ $~$ www-jpred/). In Fig. 8F and G,the hetNOE and ${lambda}$ _NOE values of N_TAIL(443-501) in complex withPX are shown. Several data points in the interaction site arelacking, since many resonances strongly broaden or even disappearupon interaction. Moreover, error bars are larger for all otherresidues in the interaction site as a result of the signal broadening.Nevertheless, the average hetNOE for residues in the PX interactionsite (residues 472 to 493 [gray area in Fig. 8]) has changedfrom 0.29 ± 0.17 (21 residues) to 0.47 ± 0.20(12 residues), clearly indicating the rigidification of thisregion in N_TAIL upon interaction with PX. Regions of N_TAIL thatdo not interact with PX remain very flexible. The observationof strong H^N-H^N(i,i + 1) NOEs for residues at the edges of theinteraction site (Fig. 8H) (which thus experience less signalbroadening) confirms that, in complex with PX, N_TAIL(477-491)folds as an ${alpha}$ -helix. The PX interaction site of N_TAIL containsfive arginine residues. Their side-chain NH resonances are affectedby binding to PX (white bars in Fig. 8E). Moreover, four outof the five arginine side chains become less flexible when boundto PX (white bars in Fig. 8B and F), indicating that these positivelycharged residues are directly involved in binding to PX.

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FIG. 6. Interaction of ¹⁵N N_TAIL(401-524) with PX. An enlargement of the seven ¹H-¹⁵N HSQC spectra with different relative ratios of N_TAIL and PX is shown. Dashed arrows indicate peaks that change position upon addition of PX, whereas disappearing peaks are indicated by a dashed circle.

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FIG. 7. Assigned HSQC of N_TAIL(443-501) recorded at 25°C on an 800-MHz spectrometer. Positive contour levels are presented in black and negative contour levels in gray. Backbone amide resonances are indicated in boldface and side-chain NH (R, W, and Q) and NH (N) are in italic. Arginine side chains are folded twice (–42 ppm), and tryptophan side chains are folded once (+21 ppm).

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FIG. 8. Characterization of N_TAIL(443-501) free and in complex with PX. (A) Secondary C chemical shifts, where high positive values indicate helical propensity, (B) hetNOE, (C) ${lambda}$ _NOE, and (D) H^N-H^N NOEs of N_TAIL(443-501) free. For the i,i + 1 NOEs in panel D, the thickness of the line indicates strong, medium, or weak. (E) Backbone and arginine side-chain combined NH chemical shift changes upon interaction with PX. Chemical shift changes superior to 0.045 ppm (dashed line) were considered significant. Open bars in panels B, E, and F are from arginine side-chain NH resonances. (F and G) hetNOE (F) and HET-SOFAST (G) of N_TAIL(443-501) in complex with PX. (H) H^N-H^N NOEs in complex with PX. Note that several data points are missing, as several resonances disappeared upon interaction with PX. The gray area highlights the region affected by PX binding.

DISCUSSION

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DISCUSSION

Interaction between PX and N_TAIL is governed by electrostatics. During SeV RNA synthesis, the interaction between the polymerasecomplex (L+P) and the nucleocapsid (N/RNA) occurs via the bindingof the C-terminal domains of P and N proteins. We have now characterizedthe C-terminal domain of SeV N protein (N_TAIL), which, likeMV N_TAIL (4), belongs to the class of intrinsically disorderedproteins, and precisely defined the binding regions within thislatter domain and the C-terminal domain of P (PX). SeV N_TAILwas shown to bind to the surface created by helices ${alpha}$ 2 and ${alpha}$ 3of PX. A similar binding site was observed for MV N_TAIL on XDinvolving the ${alpha}$ 2/ ${alpha}$ 3 face of this latter domain (22). Only oneregion of SeV N_TAIL, involving residues 472 to 493, was shownto bind to PX. Within this region, a stretch of residues (477to 491) has a helical propensity in free N_TAIL. Upon bindingto PX, this stretch of residues rigidifies and gains in structuralcompactness, forming a regular ${alpha}$ -helix. The extreme C terminusof SeV N_TAIL does not interact with PX. This is in contrastwith the observation of two interacting sites within MV N_TAILinvolved in XD binding (Fig. 1) (5, 29).

By displaying the N_TAIL binding site on the 3D structure ofthe PX C-subdomain (Fig. 5C), we can now better explain thephenotypes observed for several mutants created by Tuckis etal. (42) (Fig. 9C). In these PX mutants, clustered charged orhydrophobic residues were changed to alanine residues and testedfor various protein-protein interactions and for viral RNA synthesis.Four of the mutants fall into the C-subdomain of PX. Of thesemutants, the first one, with mutations (L524A, V525A, and I526A)affecting residues within helix ${alpha}$ 1 that is not involved in N_TAILbinding, was completely inactive. Two of the mutations (L524and V525) are located in the hydrophobic core of PX and maydestabilize the PX structure leading to a complete loss of function.Two other mutants with mutations affecting residues within helix ${alpha}$ 3 behave differently. One, located at the N terminus (D549A,E551A, and K553A), retains essentially wild-type activity, whilethe other, located at the C terminus of helix 3 (E560A, E561A,and D562A) is completely inactive in vitro. That the first mutanthas an unaltered activity can be explained by the fact thatthe N-terminal part of helix ${alpha}$ 3 is almost not affected by N_TAILbinding. Only the amides of L552 and K553, both facing to theinterior of the protein, display chemical shift changes uponinteraction with N_TAIL. Most probably, these chemical shiftchanges are caused by an interaction with a side chain of N_TAILthat is directed towards the hydrophobic core. In addition,both side chains of the mutated residues D549 and K553 are notlocated on but point away from the binding site. In contrast,mutations in the C-terminal part of helix ${alpha}$ 3 concern three negativelycharged residues located in a region that is highly affectedby the presence of N_TAIL. These residues create a negative surfacepotential (Fig. 9) necessary for the interaction with N_TAIL,which contains in its PX helical binding region several positivelycharged arginine residues (477-SDIERRIAMRLAERR-491). The interactionbetween SeV N_TAIL and PX is thus mainly driven by electrostaticinteractions.

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FIG. 9. Comparison of the N_TAIL binding site on the SeV PX C-subdomain (top) and on MV XD (bottom). (A and D) Surface representation displaying only the heavy atoms color coded according to the surface potential from red (negative) to blue (positive) and (B and E) surface representation where hydrophobic patches are colored yellow. (C) Ribbon representation of SeV PX C-subdomain showing the residues that were simultaneously mutated by Tuckis et al. (42). (F) Ribbon representation of MV XD in complex with MV N_TAIL (22). All images were created using MOLMOL (25).

The last mutant, located within helix ${alpha}$ 2 (R533A, E535A, and K536A)is still active, although the in vitro transcription activitywas found to be 50% lower. The mutations are located in theregion that is involved in N_TAIL binding. However, the two positivelycharged arginine and lysine residues are both located at theopposite site of the ${alpha}$ 2/ ${alpha}$ 3 face, and mutating them to an alanineresidue should not influence binding. Only the side chain ofE535 points towards the binding site and enlarges the negativelycharged patch created by the glutamic acid residues on helix ${alpha}$ 3. This does probably influence the interaction between PX andN_TAIL, which might be the cause of the lower activity of thismutant. Another mutation that appeared to affect both transcriptionand replication in vitro was the mutation to alanine residuesof N506 and R509 in the unfolded N-subdomain of PX. We haveunambiguously shown that this domain does not directly interactwith N_TAIL and the fact that this mutation influences the functionof the polymerase must thus result from an indirect effect.The unstructured character (2) and the intrinsic dynamics (unpublisheddata) of this subdomain are supposed to be important for placingthe polymerase onto the nucleocapsid, and it is possible thatthis mutant has an altered flexibility which is not optimalfor the action of the P tetramer.

As mentioned above, the N_TAIL helix is placed by its positivelycharged arginine residues in the binding site on the mainlynegatively charged PX ${alpha}$ 2/ ${alpha}$ 3 face. More specifically we showedthat four N_TAIL arginine side chains (R482, R486, R490, andR491) become less flexible upon interaction with PX, while theflexibility of R481 is virtually unaltered. R482, R486, andR490 are located in the region that has helical propensity infree N_TAIL, and they are thus all positioned on the same sideof the helix as they are spaced by four residues which makesabout one helical turn. R491 is located just outside of thehelical region and could well line up with the other argininesto create one positively charged surface area. This surfacecan thus interact with the negatively charged area on PX mainlycreated by E535 on helix ${alpha}$ 2 and both E561 and D562 on helix ${alpha}$ 3,by binding of the N_TAIL helix in a parallel fashion with respectto helix ${alpha}$ 3 of PX. Such a parallel arrangement was also foundfor the MV N_TAIL/XD complex (22).

Because of solubility problems with PX, all measurements hadto be performed at a salt concentration of 0.5 M. It is possiblethat the affinity between PX and N_TAIL is affected at this saltconcentration and that the measured K_D of 57 µM is anoverestimation compared to when this value is measured underlow-salt conditions. However, evidence has accumulated overthe years indicating that some surface salt bridges can be relativelyinsensitive to NaCl (see reference 30 and references therein).

SeV N and P C-terminal domains form a low-affinity complex. The interaction between the polymerase complex (L+P) and thenucleocapsid (N/RNA) occurs via the binding of the C-terminaldomains of P and N proteins. During RNA synthesis, the P tetrameris proposed to "cartwheel" along the N/RNAs, by on-and-off interactionsvia its PX domains with successive N_TAIL domains, while thepolymerase L, remaining fixed, transcribes or replicates thetemplate RNA (23). Therefore, a weak binding affinity betweenSeV PX and N_TAIL is necessary for movement of the L proteinalong the nucleocapsid. Whereas displacement of P on the nucleocapsidoccurs in steps of N subunits (i.e., per 6 nucleotides), L movesone nucleotide at a time. In this context, the complex betweenPX and N_TAIL should be a temporary complex that should be ableto exist long enough for L to synthesize new RNA, but shortenough for moving on to the next N-protomer. In the case ofMV, a K_D in the 0.1 µM range was found for the complexbetween the entire MV N_TAIL and XD (5). However, when usinga smaller MV N_TAIL construct comprising residues 477 to 505that represents the region that folds upon binding, a K_D of13 µM was found (21, 22). This difference in affinitywas explained by the existence of an extra 9-residue bindingsite in MV N_TAIL located at the extreme C terminus, which keepsits unfolded character during the interaction. As was discussedby Bourhis et al. (5), the high affinity between MV XD and N_TAILprobably does not allow the polymerase to move along the nucleocapsidtemplate as would be needed for RNA synthesis. Therefore, theypropose the intervention of other cellular/viral cofactors thatmediate the interaction. In this study, we have shown that SeVN_TAIL only contains one binding region comprising residues 472to 493 and that the C-terminal end is not involved in PX binding.The low affinity between SeV PX and N_TAIL ensures that the individualPX/N_TAIL complexes are easily disrupted, which thus allows thepolymerase to progress along the N/RNA template. During RNAsynthesis, the four possible PX/N_TAIL complexes are probablynot all formed at the same moment. P probably uses one or morefree PX domains to reach for the subsequent N_TAIL domain(s).The rather low PX/N_TAIL affinity in SeV would thus allow thepolymerase to properly perform its task without the eventualneed for additional viral or host factors. The affinity of thewhole tetrameric polymerase for the N/RNA template, when allfour PX domains interact with four N_TAIL domains, is obviouslyhigher and ensures that the polymerase does stay tightly attachedto the inactive nucleocapsid when it is packaged into a virusparticle.

N and P interactions in paramyxoviruses are different on a molecular level. On a global level, the interactions between the C-terminal domainsof N and P proteins from SeV and MV are very similar, givingrise to a four-helix bundle. MV and SeV N_TAIL are both intrinsicallyunstructured containing a specific region which shows restrictedmotion before undergoing induced folding upon binding. The MVXD and SeV PX C-subdomains not only adopt a similar three-helixbundle fold (3, 16, 22) but present the same binding site fortheir respective N_TAIL partner located on the ${alpha}$ 2/ ${alpha}$ 3 face (22).On a molecular level, however, the binding sites on both complexesare quite different (Fig. 9). While the binding interface ofthe MV N_TAIL-XD complex is dominated by hydrophobic amino acidsas shown by the hydrophobic cleft that is built up by XD ${alpha}$ 2/ ${alpha}$ 3helices (Fig. 9E) and which provides a complementary surfacefor the hydrophobic side of the induced MV N_TAIL ${alpha}$ helix (486-QDSRRSADALLRLQAMAGI-504)(22), we determined that interaction between SeV N_TAIL and PXis mainly driven by electrostatic interactions, as shown bythe negative surface created by PX ${alpha}$ 2/ ${alpha}$ 3 helices (Fig. 9A) andthe positively charged N_TAIL binding sequence.

This result shows once more the great facility of adaptationand evolution of viruses. It gives a good illustration of howselection pressure allowed the C-terminal domains of N and Pto evolve concomitantly within the paramyxovirus family in orderto lead to protein complexes having the same 3D fold and thusthe same function, but with very limited sequence identity.This study also points out that the design of antiviral agentsblocking the interaction between the C-terminal domains of Pand N proteins and thus the synthesis of RNA within the paramyxovirusfamily would require a specific strategy for each genus.

ACKNOWLEDGMENTS

This work was supported by the CNRS, the UJF, and the CEA. K.H.was funded by a fellowship from The Netherlands Organizationfor Scientific Research (NWO) as well as by a postdoctoral fellowshipfrom the French Ministère déléguéà la Recherche.

We thank Joe Curran for providing us with a clone of SeV naturalN_TAIL gene. We also thank Anne Chouquet for technical help incloning the N_TAIL construct and Isabel Ayala for helping uswith the purifications. We thank Marjolaine Noirclerc-Savoyeand Benoit Gallet (RoBioMol at the Institut de Biologie Structurale,Grenoble, France) for the subcloning of the two shorter N_TAILconstructs, David Lemaire and Bernard Dublet for MALDI-TOF experiments,Jean-Pierre Andrieu for N-terminal sequencing, and Paul Schandafor help with SOFAST experiments.

FOOTNOTES

* Corresponding author. Mailing address: CEA Cadarache, IBEB, LEMiRE, Saint-Paul-lez-Durance, F-13108 France. Phone: 33 4 42 25 7863. Fax: 33 4 42 25 6648. E-mail: Laurence.Blanchard{at}cea.fr

Published ahead of print on 25 April 2007.

REFERENCES

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