Calcium depletion blocks the maturation of rotavirus by altering the oligomerization of virus-encoded proteins in the ER.

Maturation of rotavirus occurs in the ER. The virus transiently acquires an ER-derived membrane surrounding the virus particle before the eventual formation of double-shelled particles. The maturation process includes the retention and selective loss of specific viral protein(s) as well as the ER-derived membrane during formation of the outer capsid of the mature virus. When infected cells were depleted of Ca++ by use of the ionophore A23187 in calcium-free medium, membrane-enveloped intermediates were seen to accumulate. When Mn++, an efficient Ca++ competitor, was used to replace Ca++ in the medium, the accumulation of the enveloped intermediate was again observed, pointing to an absolute requirement of Ca++ in the maturation process. It was previously demonstrated in this laboratory that a hetero-oligomeric complex of NS28, VP7, and VP4 exists which may participate in the budding of the single-shelled particle into the ER (Maass, D. R., and P. H. Atkinson, 1990. J. Virol. 64:2632-2641). The present study demonstrates that either in the absence of Ca++ or in the presence of tunicamycin, a glycosylation inhibitor, VP7 is excluded from these hetero-oligomers. In the presence of Mn++, VP4 was blocked in forming a hetero-oligomeric complex with NS28 and VP7. The electrophoretic mobility of the viral glycoproteins synthesized in the presence of the ionophore were found to be altered. This size difference was attributed to altered N-linked glycosylation and carbohydrate processing of the viral glycoproteins. These results imply a major role for calcium and the state of glycosylation of NS28 in the assembly and acquisition of specific viral protein conformations necessary for the correct association of proteins during virus maturation in the ER.

Rotavirus proteins VP7, NS28, and VP4 form oligomeric structures.

Sucrose gradient sedimentation analysis of rotavirus SA11-infected Ma104 cells revealed the presence of oligomers of VP7, the structural glycoprotein, and NS28, the nonstructural glycoprotein. Cross-linking the proteins, either before or after sucrose gradient centrifugation, stabilizes oligomers, which can be analyzed by nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) after immunoprecipitation. The major NS28 oligomer was tetrameric, though dimers and higher-order structures were observed as well. VP7 formed predominantly dimers, and again tetramers and higher oligomeric forms were present. Each oligomer of VP7 and NS28 sedimented at the same characteristic rate through the sucrose gradient either in the presence or absence of cross-linking. Monomers could not be cross-linked to form oligomers, demonstrating that cross-linked oligomers were not artifactually derived from monomers. Reversing the cross-linking of immunoprecipitated VP7 on reducing SDS-PAGE resulted in the appearance of only the monomeric form of VP7. Dissociation of the NS28 oligomers resulted in stable dimers as well an monomers. In the faster-sedimenting fractions, a 16S to 20S complex, which contained the rotavirus outer shell proteins VP7 and VP4 cross-linked to NS28, was observed. These complexes were shown not to be associated with any known subviral particle. The association of VP4, NS28, and VP7 may represent sites on the endoplasmic reticulum membrane that participate in the budding of the single-shelled particles into the lumen of the endoplasmic reticulum, where maturation to double-shelled particles occurs.

Retention by the endoplasmic reticulum of rotavirus VP7 is controlled by three adjacent amino-terminal residues.

The rotavirus outer capsid glycoprotein, VP7, is an endoplasmic reticulum (ER) membrane-associated glycoprotein in both infected and transfected cells. It was previously demonstrated in this laboratory and by others that both the cleaved signal sequence (H2) and the first NH2-terminal 61 amino acids of VP7 are sufficient and necessary for ER retention of this molecule. Using site-specific mutagenesis and transfection techniques, we show that residues Ile-9, Thr-10, and Gly-11 were specifically necessary for ER retention. These results further define the ER retention sequence of VP7 and demonstrate that conservative changes, apparently innocuous in only three adjacent amino acids, can lead to major solubility and compartmentalization changes. It was found that placement of the first 31 mature NH2-terminal residues of VP7, in addition to the cleaved ER translocation signal sequence, was sufficient to retain the enzymatically active chimeric alpha-amylase in the ER; this enzyme is normally secreted. Deletions of the residues Ile-9, Thr-10, and Gly-11 within the amylase chimera containing 31 VP7 amino acids resulted in secretion of enzymatically active protein. It was also observed that the residues of VP7 presented in certain chimeras were able to abolish alpha-amylase enzymatic activity. These chimeras are presumably misfolded since it was demonstrated by pulse-chase experiments that these molecules are degraded in the ER. We surmise that a favorable conformation is necessary for retention since ER retention and activity of the chimeras depend on the primary sequence context.