Abstract

ORIGINAL PAPERS

Structure-function analysis of two variants of mumps virus hemagglutinin-neuraminidase protein

Gerardo Santos-López^I; Thomas Scior^II; María del Tránsito Borraz-Argüello^I; Verónica Vallejo-Ruiz^I; Irma Herrera-Camacho^III; José Tapia-Ramírez^IV; Julio Reyes-Leyva^I

^ILaboratorio de Biología Molecular y Virología, Centro de Investigación Biomédica de Oriente, Instituto Mexicano del Seguro Social, Metepec, Puebla, México

^IIDepartamento de Farmacia, Facultad de Ciencias Químicas

^IIICentro de Química, Instituto de Ciencias, Benemérita Universidad Autónoma de Puebla, Puebla, Pue., México

^IVDepartamento de Genética y Biología Molecular, Centro de Investigación y Estudios Avanzados, Instituto Politécnico Nacional, México, D.F., México

^{Address for correspondence} Address for correspondence: Dr. Gerardo Santos-López Laboratorio de Biología Molecular y Virología Centro de Investigación Biomédica de Oriente Instituto Mexicano del Seguro Social Km. 4.5 Carretera Federal Atlixco-Metepec 74360 Metepec, Puebla, México Phone. (Fax): +52 2444440122 E-mail: gerardo.santos.lopez@gmail.com. gerardo.santos@imss.gob.mx

ABSTRACT

A point mutation from guanine (G) to adenine (A) at nucleotide position 1081 in the hemagglutinin-neuraminidase (HN) gene has been associated with neurovirulence of Urabe AM9 mumps virus vaccine. This mutation corresponds to a glutamic acid (E) to lysine (K) change at position 335 in the HN glycoprotein. We have experimentally demonstrated that two variants of Urabe AM9 strain (HN-A₁₀₈₁ and HN-G₁₀₈₁) differ in neurotropism, sialic acidbinding affinity and neuraminidase activity. In the present study, we performed a structure-function analysis of that amino acid substitution; the structures of HN protein of both Urabe AM9 strain variants were predicted. Based on our analysis, the E/K mutation changes the protein surface properties and to a lesser extent their conformations, which in turn reflects in activity changes. Our modeling results suggest that this E/K interchange does not affect the structure of the sialic acid binding motif; however, the electrostatic surface differs drastically due to an exposed short alpha helix. Consequently, this mutation may affect the accessibility of HN to substrates and membrane receptors of the host cells. Our findings appear to explain the observed differences in neurotropism of these vaccine strains.

Key-Words: Hemagglutinin-neuraminidasa, mumps virus, paramyxovirus, 3D structure prediction, sialic acid.

Mumps virus (MuV) is a negative-sense single-stranded RNA virus belonging to the Paramyxoviridae family; MuV causes an acute infectious disease with fever, headache, myalgia and parotitis in children and young people. Massive vaccination programs have decreased the incidence of MuV infection worldwide; however, mumps epidemics have reemerged and its incidence is rising in several countries [1-3].

Several MuV strains, including L-Zagreb, Leningrad-3 and Urabe AM9, have been associated with a high incidence of post-vaccinal aseptic meningitis [4-6]. The Urabe AM9 strain has several viral subpopulations that vary at different positions in their genomes. One polymorphic site that defines two viral subpopulations, possessing either guanine or adenine (G/A) at position 1081 in the hemagglutinin-neuraminidase (HN) gene that codes for glutamate (E) or lysine (K) at position 335 of the HN protein, has been frequently associated with postvaccination meningitis cases [7]. The frequent isolation of viruses with the HN-A₁₀₈₁ genotype in post-vaccination meningitis cases has led to extensive discussion concerning the usefulness of this mutation as a genetic marker for virulence [7-10]. However, the role played by this mutation in mumps virus virulence is not well understood.

Recently, we identified a virus variant isolated from Urabe AM9 vaccine with HN-K₃₃₅ that was efficiently replicated in both human neuroblastoma cells and newborn rat brain; under the same conditions HN-E₃₃₅ virus replicated very little [11]. The MuV HN glycoprotein recognizes sialylated glycoconjugates as receptors, leading to virus attachment to host cell membranes and entry into the cell. Due to its sialicacid binding activity, the HN glycoprotein is responsible for hemagglutination and hemadsorption. Viral HN glycoprotein is a specific sialic-acid-binding lectin (HA, hemagglutination) that recognizes glycoconjugate molecules as receptors for the virus to attach to membrane surfaces of host cells. HN also acts as an enzyme (NA, neuraminidase or sialidase) that removes sialic acid (neuraminic acid) moieties from viral progeny to prevent self-aggregation, favoring the release of virions from the cell. In addition, HN activates fusion protein, thereby participating in the internalization of viral particles through the fusion of the cell and viral membranes [12].

We have found that HN- K₃₃₅ virus possesses higher affinity towards α2,6-linked sialic acid residues than does the HN- E₃₃₅ virus. This type of sialic acid is abundantly exposed on the membrane surface of human neuroblastoma cells, facilitating HN- K₃₃₅ virus entry into the cells. Additionally, HN- K₃₃₅ virus has 11 times higher neuraminidase activity than does HN- E₃₃₅, contributing to virus release [13].

Our objective was to explore other functional differences between the viral variants and how the E₃₃₅/K substitution affects the putative structure and other physicochemical properties of MuV HN protein. The in silico-generated structures for HN-E₃₃₅ and HN-K₃₃₅ proteins were compared, and their putative impact on activity and function were examined.

Material and Methods

Viruses and Cells

The HN-K₃₃₅ and HN-E₃₃₅ variants of Urabe AM9 mumps virus vaccine were initially purified by plaque assay [11]. The viruses were replicated in green monkey kidney Vero and CV1P cells and human neuroblastoma SH-SY5Y cells grown in high glucose Dulbecco's modified minimum essential medium, supplemented with 10% fetal bovine serum, 100 U/mL penicillin and 100 µg/mL streptomycin. The medium was also supplemented with non-essential amino acids and 8 mM sodium pyruvate for culturing SH-SY5Y cells. All media and culture supplements were purchased from Sigma-Aldrich Chemicals (St. Louis, MO, USA).

Hemadsorption Assays

The hemadsorption activity of MuV variants was determined in infected cell cultures at 4ºC. Monolayers of Vero cells at 48 hpi were washed with DMEM and incubated for 30 min with a 2% suspension of human O Rh+ erythrocytes in DMEM. After extensive washing, the erythrocytes adsorbed on membrane cells were observed and their numbers estimated visually with phase contrast microscopy.

Trypsin Treatment of Susceptible Cells

SH-SY5Y cells were cultured on 24-well plates. At 24 h after seeding, the cells were treated with different concentrations of bovine pancreatic trypsin for 10 min at 37ºC. Cells were then washed twice with DMEM and inoculated with virus. Untreated cells were also inoculated with either HN-K₃₃₅ or HN-E₃₃₅ viruses and used as controls. Viral titers in recovered supernatants were determined by counting plaque-forming units per mL (PFU/mL) in CV-1P cells at 48 hpi, as described previously [11].

Sialic Acid-Binding Affinity

Affinity for sialic acid was tested in competitive antiviral assays, as reported previously [13]. Briefly, each virus variant was mixed with 5-200 µg/mL of colominic acid (α2,8-linked polysialic acid) and incubated for 1 h at 4ºC. The same concentrations of lactose or D-galactose were used as a control of virus infection inhibition. Culture supernatants were collected at 48 h pi, and viral titers were calculated as PFU/mL in CV-1P cells. Regression analyses of antiviral data were performed with KyPlot v2.0 beta 13 software (www.woundedmoon.org/win32/kyplot.htmL). Dose-response equations were used to calculate the 50% inhibitory concentration (IC₅₀) values for each oligosaccharide and virus variant.

Sequence Analysis and Prediction of Secondary Structure

The genetic sequences of HN-K₃₃₅ and HN-E₃₃₅ variants of Urabe AM9 mumps virus were determined [11], and the primary structures of their HN proteins were deduced. The amino acid sequences of three crystallized HN glycoproteins from Newcastle disease virus (NDV, accession: AF212323), human parainfluenza virus 3 (HuPIV-3, accession: AY283063) and simian parainfluenza virus 5 (SV5, accession: K02870) were obtained from GeneBank. HN amino acid sequences were aligned and compared with those of these paramyxoviruses, using ClustalW 1.8 (http://www.ebi.ac.uk/clustalw) [14]. The secondary structure was predicted by algorithms included in the following programs: Antheprot (http://antheprotpbil.ibcp.fr) [15], Psi-Pred (http://bioinf.cs.ucl.ac.uk/psipred/ psiform.html) [16], J-Pred (http://www.compbio.dundee.ac.uk/~www-jpred/submit.html) [17] and Prof (http://www.aber.ac.uk/~phiwww/prof) [18], and a secondary-structure-based alignment was obtained with ESPript 2.2 software (http://espript.ibcp.fr/ESPript/cgi-bin/ESPript.cgi) [19].

Construction and Analysis of Theoretical 3D Models

The putative 3D structures and their homodimeric arrangements were obtained using the Swiss-Model Server (http://swissmodel.expasy.org) [20]. The quality of predicted structures was verified with the program WhatChek [21], also provided by the Swiss-Model Server. The molecular surface models of proteins were calculated with DeepView 3.7 and the electrostatic potentials fitted to their surfaces (http://ca.expasy.org/spdbv) [22]. Electrostatic potentials were calculated with partial atomic charges of the GROMOS 43A1 force field and with dielectric constants of 4 and 80 for the protein and solvent, respectively, using the Poisson-Boltzmann method and electric charge cut-off values of -1.8 kT/e and +1.8 kT/e for the negative and positive charges, respectively. Molecular surface models were built, assuminga solvent radius of 1.4 Å. We used Site Finder of MOE 2006.08 for the prediction of putative active sites in the mumps virus model [23]. The algorithm skips shallow surface grooves and concentrates on deeper and more surrounded locations in the protein matrix that have tight atomic packing. Final structural representations were obtained using the programs DeepView and MOE.

Results and Discussion

Studies on Cellular Membrane Receptors for HN-K₃₃₅ and HNE₃₃₅ Virus Variants.

We previously demonstrated that the HN-K₃₃₅ variant of Urabe AM9 vaccine is efficiently replicated in human neuroblastoma cells, whereas the HN- E₃₃₅ virus variant is replicated significantly less [11]. We made further studies and found that sialic acid is an important component of cell receptors for MuV, since viral infection was completely avoided by treatment of Vero and SH-SY5Y cells with C. perfringens neuraminidase before inoculation. However, these two variants differed in their sialic acid binding activity [13]. Table 1 shows the results of several assays of hemagglutinin-neuraminidase; the HN- K₃₃₅ and HN-E₃₃₅ variants of Urabe AM9 were found to have different biological activities.

Since several cell membrane glycoconjugates have terminal α2,3-, α2,8- or α2,6-linked sialic acid residues, we performed antiviral assays using sialylated and non-sialylated molecules as competitive inhibitors. We found that both virus variants interacted with all the sialylated molecules; however, the HNK₃₃₅ variant had higher affinity towards α2,6-linked sialic acid residues, whereas the HN- E₃₃₅ variant preferred α2,3-linked sialic acids [13]. This makes sense, given the higher neurotropism of the HN-K₃₃₅ virus [11] and the abundance of α2,6-linked sialic acid found on human nerve cells [13].

We performed other inhibition assays and observed that HN-K₃₃₅ possesses a higher affinity towards α2,8-linked sialic acids (colominic acid), which was evidenced by competence with colominic acid (Figure 1). IC₅₀ values were 35.3 ± 4.2 and 80.7 ± 6.5 for HN-K₃₃₅ and HN-E₃₃₅, respectively. Along with higher expression of α2,6-linked sialic acids, it is well known that neuroblastoma cell membranes express α2,8-linked sialic acid [23], which would be advantageous for HN-K₃₃₅ replication.

We used hemadsorption assays to investigate the direct interaction of viruses with sialic acids. MuV-variant infected cells were incubated with human O red blood cells (RBC); both types of infected cells presented hemadsorption. Treatment of human RBC with C. perfringens neuraminidase completely eliminated their adsorption to cells infected with HN-K₃₃₅ or HN-E₃₃₅ virus variants (data not shown). This demonstrates that hemadsorption is mediated by sialic acid, which is recognized by both variants of Urabe AM9 mumps virus. These data are similar to what was found in previous assays, which showed that viral infection of both MuV variants is avoided by treatment of cells with C. perfringens neuraminidase [13].

In order to determine the role of membrane proteins in virus infection, we treated neuroblatoma cells with trypsin for 10 minutes. Increasing trypsin concentration enhanced virus infectivity (Figure 1). Since trypsin is a broad-range protease, it appears that cell membrane proteins play only a minor role in MuV entry into cells and that trypsin action favors infection by uncovering membrane glycolipids, as has been demonstrated in studies of in vitro infection with Sendai virus [25] and porcine rubulavirus LPMV [26].

We found that HN-K₃₃₅ virus neuraminidase preferably hydrolyzed α2,3-linked sialic acids; it had 11 times more activity than the HN-E₃₃₅ neuraminidase (Table 1). There seems to be a conflict between the sialic acid specificities of HN-K₃₃₅ virus to perform either binding or hydrolysis; the former is directed towards α2,6- and the latter against α2,3-linked sialic acids. We found that HN-K₃₃₅ virus binds both α2,6- and α2,3-linked sialic acids; however, only α2,6-linked sialic acids are extensively expressed in the human central nervous system. The finding of α2,3-linked sialic acids in tissues of non-nervous origin led us to the notion that an α2,3-specific neuraminidase might play a role in reducing unproductive virus-cell interactions.

Similarity of Mumps Virus and Other ParamyxoViral HN Proteins

Our findings enabled us to conduct a structural analysis of the underlying events in order to gain more insight for a theoretical level of discussion.

In order to explore how E/K₃₃₅ substitution affected the HN glycoprotein conformation, the secondary, tertiary structures and other physicochemical properties were predicted for both HN-E₃₃₅ and HN-K₃₃₅ proteins.

Alignment of total protein sequences showed that Urabe AM9 mumps virus HN possesses the highest identity to SV5 (44%), another member of the Rubulavirus genus, whereas NDV and HuPIV-3 HNs (belonging to Avulavirus and Respirovirus genera, respectively) has less identity with the total sequence of MuV HN (31% and 22%, respectively). This led us to use the SV5 HN protein for comparison to carry out the structure prediction of MuV HN variants. The total length of the SV5 HN protein (template) is 565 amino acids, but only 448 residues were visible in the 3D structure. Therefore our MuV HN (target) 3D model contains the equivalent number of residues (positions 145-581 in Figure 2). The sequence identity between the target MuV protein (aa 145 to 581) and the template was 50%, somewhat higher than that for the total sequence (44%).

The secondary structure of MuV HN predicted with the Swiss-Model tools was used to perform a structure-based sequence alignment with other paramyxoviral HN proteins (Figure 2). Residue 335 (K/E) of MuV HN was located at the third α-helix (α3), which seems to be conserved in the secondary structure but not in the amino acid sequence of SV5 and NDV.

The secondary structure of the HN proteins of MuV variants was also predicted using the algorithms Garnier, Gibrat, Levin, DPM and Predator (included in the Antheprot suite), as well as Psi-Pred, J-Pred and Prof. The consensus of these algorithms confirmed that MuV HN possesses a rich -sheet structure, and that either K₃₃₅ or E₃₃₅ is located in a short α-helix.

We concluded that HN serves as a multifunctional viral surface glycoprotein (Tables 1 and 2). We analyzed the amino acid sequences of both HN-K₃₃₅ and HN-E₃₃₅ virus variants, searching for residues involved in their biological activities. All critical amino acids involved in the neuraminidase active site of the crystallized proteins of SV5, NDV and HuPIV-3 were found in both MuV variants, demonstrating the importance of this enzymatic activity for paramyxoviruses (Table 2). In addition to its neuraminidase activity, this site has been recognized as the major receptor binding (hemagglutinating, hemadsorbing) domain, suggesting that MuV HN protein uses the same site for both activities [2729]. Experimental point mutations made at several sites of NDV HN protein have shown that residues equivalent to E407, R422 and Y540 of MuV HN are directly involved in receptor binding [30].

A second sialic-acid-binding domain was recently found in NDV HN; it is located at the homodimer interface and involves several residues, the most important being G169 and R516 [31]. Those residues are replaced by P175 and P530 in MuV HN protein. Due to physicochemical differences between these amino acids, it is improbable that the second domain is functional in MuV, as in is the case for the SV5 HN protein, which also possesses P at equivalent residues and does not have the second sialic acid-binding site [29].

Other important residues in HN include the heptad repeats at the membrane proximal domain. This region comprises approximately 90 amino acids and is rich in leucine and isoleucine. The key amino acids (I82, V89, V96, I104, L111 and L118) in the MuV sequence are involved in the interaction of HN with fusion protein as well as in the promotion of cell membrane fusion in other paramyxoviruses, such as NDV, HuPIV-3 and Sendai virus [32,33]; although this region is not observed in the 3D-models. Moreover, all seven cysteines involved in disulfide linkages of template SV5 are conserved in the MuV target model (Figure 2). The second disulfide bond is not present in the NDV HN, while the second and fourth disulfide bonds are not present in HuPIV-3. This finding strengthens the likelihood of correct alignment and 3D modeling.

Predicted 3D Structure of HN-A₃₃₅ and HN-G₃₃₅ Proteins

The putative three-dimensional structure of the monomeric HN-K₃₃₅ and HN-E₃₃₅ MuV variants were constructed with the SwissProt Server. Substantially similar 3D-models were obtained with Geno3D (http://geno3d-pbil.ibcp.fr/cgi-bin/geno3d_automat.pl?page) [34] and Phyre (http://www.sbg.bio.ic.ac.uk/~phyre); consequently, only the 3Dstructure predicted with the Swiss-Model is presented.

Both target structures are almost identical and presented the classic β-propeller neuraminidase motif [27]. This fold consists of a symmetrical structure, based on six twisted antiparallel β-sheets organized as a super barrel, with the active site at the central region. The head globular domain is formed by residues 145-581 of the MuV HN protein. The stalk region (residues 1-144) of MuV HN was not modeled because the equivalent amino acids were not visible in the electron density maps of crystallized SV5 HN protein [29]. There was no apparent conformational change due to the presence of K or E in the amino acid 335 of HN protein, except for the R-chain, which is distinctly oriented for each amino acid (Figures 3A and 3B).

Superposition of the predicted HN protein structure of MuV variants over the crystallized HN protein structure of SV5, including the neuraminidase inhibitor DANA (2,3dehydro-2-deoxy-N-sialic acid or 2-deoxy-2,3-dehydro-nacetyl-neuraminic acid), permitted the localization of 10 amino acids (R180, D204, E264, Y268, Y303, E407, R422, R512, Y540, E551) that constitute the neuraminidase active site and directly interact with sialic acid. They were exactly the same in the two MuV HN variants (Table 2). The calculated geometrical deviation for the backbone and side chains of these 10 residues constitutes a minor irrelevant change of 0.26 Å, since the entire backbone formed by 448 C-alpha atoms yields the same score (calculated as root mean squared distance).

The structural conformation of the active site was identical for the two MuV variants (Figure 3C), implying that at least at this level the corresponding proteins conserve their enzymatic activity. Nevertheless, the neuraminidase activity of HN-K₃₃₅ virus was higher than that of HN-E₃₃₅ (Table 1) [13]. This is difficult to explain, given the apparent conserved structure of the active sites.

Electrostatic Potential Analysis of HN-K₃₃₅ and HN-E₃₃₅ MuV Proteins

Since evident structural differences that explain the changes in activity were not observed, we decided to investigate the electrostatic characteristics of each HN protein. As K and E residues are positively and negatively-charged amino acids, respectively, their opposite charges likely affect the isoelectric point (pI) of the protein. Indeed, their predicted pI differed significantly: 7.79 for HN-K₃₃₅ versus 6.99 for HN-E₃₃₅. However, we found that purified HN-K₃₃₅ and HN-E₃₃₅ proteins presented pIs of 4.30 and 4.65, respectively (data not shown), similar to porcine rubulavirus HN protein (pI 4.4) and other neuraminidases [35]. This difference between theoretical and experimental values could be because predicted pI is only based on amino acid sequences, although it can be modified in nature by glycosylation, as has been demonstrated for other viral glycoproteins [35,36]. Since, both HN-K₃₃₅ and HN-E₃₃₅ proteins preserved the seven potential N-glycosylation sites (Figure 2), it is probable that as for other MuV strains, at least five are actually occupied by carbohydrate side-chains that reduce the pI values [37,38].

An electrostatic potential map showed a drastic change at the α3 helix, with positive charges loaded on HN-K₃₃₅ and negative charges loaded on HN-E₃₃₅ protein (Figure 3D-G). This amino acid substitution (K/E) appears to affect the surrounding residues, either increasing or decreasing the electrostatic potential of the neighboring β-sheet motifs. Surface representations of the electrostatic potential clearly showed that monomers of HN-K₃₃₅ and HN-E₃₃₅ proteins are quite different, but their differences increase with dimerization; consequently, HN-E₃₃₅ seems to be highly negative, while HN-K dimers possess positive to neutral potential that reaches the upper side of the catalytic domain (Figures 3F and 3G). Attraction and repulsion forces are important factors in the approaching and selective attachment of proteins and other biological macromolecules, and therefore they affect their functionality [39]. More importantly, the electrostatic potential shown by each HN protein could affect its interaction with substrates, cell receptors or other viral proteins.

Sialic acids constitute part of the cell receptors for paramyxoviruses. Their negative charge at physiological pH is due to the carboxyl group and is important for specific interactions with viral or cellular ligands [40]. Sialic acids are located at the terminal position of many glycoproteins and glycolipids on cell membranes. As some of those molecules are rich in sialic acids, their electrostatic potential can be highly negative, avoiding contacts with some molecules, while permitting some specific interactions, such as that with HN protein. This fact may be very important for colominic acid, because this molecule includes various successive Neu5Ac residues and its negative charge is high. The specific interaction of the carboxyl group of DANA (a sialic acid analogue) and the arginine triad (R180, R422 and R512) is conserved in all paramyxovirus HN proteins (Figure 3C).

The precise role of the α3 helix is unknown; it constitutes part of a structurally variable region that also includes the α4 helix, the N-terminal region and the loops 452 (424 in SV5) and 493 (476 in SV5), since HuPIV-3, NDV and SV5 HN proteins differ considerably in the spatial distribution of these domains. The high variability and location of N-linked glycosylation sites at this region suggest that it results in individual characteristics of each HN protein and may account for their differences in cell receptor specificity and cooperation with homologous F protein [29]. Additionally, the exposed localization of α3 helix on the HN protein surface suggests that it has an immunogenic role. Evidence of this comes from a report that variants bearing E₃₃₅ were completely neutralized in vitro, whereas variants containing K₃₃₅ escaped neutralization [9].

Putative Dimeric Structure of HN-K₃₃₅ and HN-E₃₃₅ Proteins

The 3D-models of dimeric structures of MuV HN proteins are depicted in Figures 4A and 4B. These structures are similar to other known HNs, such as NDV and PIV3 dimers. The amino acid E/K₃₃₅ is located at opposite positions of the dimerization site: residues 226 to 237 (MFKTLKIQYLSD in Figure 4C), which explains why the formation of the dimeric structure is not affected by this amino acid change, and it means that HN-K₃₃₅ and HN-E₃₃₅ proteins probably present dimeric forms, as has been observed in other paramyxoviruses [41]. In a previous study, we observed that enzymatic kinetics of two MuV variants presented a cooperative curve, typical of allosteric enzymes, and an oligomerization factor of 2, which suggests that the active enzyme is a dimeric form [13].

In Figure 4C, the small gray and red spheres reflect the non-polar and polar attraction in the contact zone of the dimer. The polar spots coincide with hydrogen bonding, while the non-polar zones involve Van der Waals attractions. The program finds active sites of sialic acid ligand (surrounded by red and gray spheres, top left and bottom right in Figure 4C). The dimer interface is also recognized as a water exclusion zone by favorable hydrophobic contacts and hydrogen bonding (diagonal top right to bottom left in Figure 4C. This in silico evidence could be validated by further physicochemical experiments, such as native and denaturing electrophoresis or Western blot assays in order to identify the putative protein isoforms.

The oligomerization process occurs in the endoplasmic reticulum, where HN is synthesized by associated ribosomes; this is also where the glycosylation process begins [41]. The oligomerization or folding of a protein can be affected by factors such as pH and redox potential. The α3 domain is close to a glycosylation site sequence NSTL between residues 329-332 and is spanned only by two amino acids of the E or K residue. It is not known if this electrostatic change exerts an influence on glycosylation, folding or oligomerization, because these processes are all related in space and time during protein sorting, which can be another differentiating feature between HN proteins. Recently, similar in silico methods, including homology modeling, surface and functional analysis of 3D models to map antigenic sites, were successfully used on different variants of mumps virus to analyze the influence of variability in strains and antigenic sites of mumps viruses [42]. More details about membrane fusion and virus cell interactions can be found in a comprehensive review by Lamb et al. [43].

Concluding Remarks

Although no structural differences were found between HN proteins, their electrostatic potentials were notably affected by the change at amino acid 335. The HN-K₃₃₅ protein possesses a more equilibrated electrostatic potential, whereas HN-E₃₃₅ is predominantly negative. This would explain the different interactions of HN protein with sialic acids used as cell receptors. Experimental evidence suggests that these electrostatic differences are a factor in the high activity of HN-A₁₀₈₁ virus neuraminidase. Nevertheless, further experimental assays to identify the participation of HN protein on MuV neurovirulence are needed.

Acknowledgments

This work was supported by grants from Consejo Nacional de Ciencia y Tecnología (CONACYT: 30625-M, Salud-2003C01-085 and 52639/2007) and Fondo para el Fomento de la Investigación Médica, IMSS (FP-2002/119; FP 2003/028).

Received on 16 July 2008; revised 5 December 2008.

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