Ultrastructural Characterization of Phagophores Using Electron Tomography on Cryoimmobilized and Freeze Substituted Samples.

Electron tomography has significantly contributed to recent findings regarding the biogenesis of the phagophore, an organelle which initiates autophagic sequestration. The information obtained from 1.9nm slices through the tomograms have revealed that during biogenesis the phagophore is in contact with the membranes of apposing organelles to form tubular connections and membrane contact sites (MCSs). The most reported and established tubular connections occur between the phagophore and the endoplasmic reticulum. However, as the phagophore continues to grow and expand, connections and MCSs have also been reported to occur between the phagophore and several other organelles in a possible attempt to utilize lipids for membrane expansion from alternative sources. Since the lifespan of the phagophore is only a few minutes and membrane connections and MCSs are very dynamic, capturing these two events requires precision during fixation. Up to date there is no quicker alternative for sample preservation in transmission electron microscopy than cryoimmobilization. In this report, we describe our protocol for cryoimmobilization using high-pressure freezing and freeze substitution, and report our first findings on phagophore morphology using this approach.

Biogenesis of the Semliki Forest virus RNA replication complex.

The nonstructural (ns) proteins nsP1 to -4, the components of Semliki Forest virus (SFV) RNA polymerase, were localized in infected cells by confocal microscopy using double labeling with specific antisera against the individual ns proteins. All ns proteins were associated with large cytoplasmic vacuoles (CPV), the inner surfaces of which were covered by small invaginations, or spherules, typical of alphavirus infection. All ns proteins were localized by immuno-electron microscopy (EM) to the limiting membranes of CPV and to the spherules, together with newly labeled viral RNA. Along with earlier observations by EM-autoradiography (P. M. Grimley, I. K. Berezesky, and R. M. Friedman, J. Virol. 2:326-338, 1968), these results suggest that individual spherules represent template-associated RNA polymerase complexes. Immunoprecipitation of radiolabeled ns proteins showed that each antiserum precipitated the other three ns proteins, implying that they functioned as a complex. Double labeling with organelle-specific and anti-ns-protein antisera showed that CPV were derivatives of late endosomes and lysosomes. Indeed, CPV frequently contained endocytosed bovine serum albumin-coated gold particles, introduced into the medium at different times after infection. With time, increasing numbers of spherules were also observed on the cell surfaces; they were occasionally released into the medium, probably by secretory lysosomes. We suggest that the spherules arise by primary assembly of the RNA replication complexes at the plasma membrane, guided there by nsP1, which has affinity to lipids specific for the cytoplasmic leaflet of the plasma membrane. Endosomal recycling and fusion of CPV with the plasma membrane can circulate spherules between the plasma membrane and the endosomal-lysosomal compartment.

Elimination of phosphorylation sites of Semliki Forest virus replicase protein nsP3.

nsP3 is one of the four RNA replicase subunits encoded by alphaviruses. The specific essential functions of nsP3 remain unknown, but it is known to be phosphorylated on serine and threonine residues. Here we have completed mapping of the individual phosphorylation sites on Semliki Forest virus nsP3 (482 amino acids) by point mutational analysis of threonine residues. This showed that threonines 344 and 345 represented the major threonine phosphorylation sites in nsP3. Experiments with deletion variants suggested that nsP3 itself had no kinase activity; instead, it was likely to be phosphorylated by multiple cellular kinases. Phosphorylation was not necessary for the peripheral membrane association of nsP3, which was mediated by the N-terminal region preceding the phosphorylation sites. Two deletion variants of nsP3 with either reduced or undetectable phosphorylation were studied in the context of virus infection. Cells infected with mutant viruses produced close to wild type levels of infectious virions; however, the rate of viral RNA synthesis was significantly reduced in the mutants. A virus totally defective in nsP3 phosphorylation and exhibiting a decreased rate of RNA synthesis also exhibited greatly reduced pathogenicity in mice.

Phosphorylation site analysis of Semliki forest virus nonstructural protein 3.

Nonstructural protein 3 (Nsp3) is an essential subunit of the alphavirus RNA replication complex, although its specific function(s) has yet to be well defined. Previously, it has been shown that Semliki Forest virus Nsp3 (482 amino acids) is a phosphoprotein, and, in the present study, we have mapped its major phosphorylation sites. Mass spectrometric methods utilized included precursor ion scanning, matrix-assisted laser desorption/ionization mass spectrometry used in conjunction with on-target alkaline phosphatase digestions, and tandem mass spectrometry. Two-dimensional peptide mapping was applied to separate tryptic (32)P-labeled phosphopeptides of Nsp3. Radiolabeled peptides were then subjected to Edman sequencing, and phosphoamino acid analysis. In addition, radiolabeled Nsp3 was cleaved successively with cyanogen bromide and trypsin, and microscale iron-chelate affinity chromatography was used to enrich phosphopeptides. By combining these methods, we showed that Nsp3 is phosphorylated on serine residues 320, 327, 332, 335, 356, 359, 362, and 367, and is heavily phosphorylated on peptide Gly(338)-Lys(415), which carries 7-12 phosphates distributed over its 13 potential phosphorylation sites. These analytical findings were corroborated by constructing a Nsp3 derivative devoid of phosphorylation. The results represent the first determination of phosphorylation sites of an alphavirus nonstructural protein, but the approach can be utilized in phosphoprotein analysis in general.

Intracellular distribution of rubella virus nonstructural protein P150.

Antiserum prepared against an amino-terminal fragment of rubella virus (RUB) nonstructural polyprotein was used to study RUB-infected Vero cells. Replicase protein P150 was associated with vesicles and vacuoles of endolysosomal origin and later with large, convoluted, tubular membrane structures. Newly incorporated bromouridine was associated with the same structures and specifically with small membrane invaginations, spherules, indicating that these structures may be the sites of viral RNA synthesis.

Critical residues of Semliki Forest virus RNA capping enzyme involved in methyltransferase and guanylyltransferase-like activities.

The Semliki Forest virus (SFV) replicase protein nsP1 has methyltransferase (MT) and guanylyltransferase-like (GT) activities, which are involved in the capping of viral mRNAs. MT catalyzes the transfer of the methyl group from S-adenosylmethionine (AdoMet) to position 7 of GTP, and this reaction is followed by GT-catalyzed formation of the covalent complex m7GMP-nsP1. These reactions are virus specific and thus potential targets for inhibitors of virus replication. We have mutated residues of SFV nsP1, which are conserved in related proteins of the large alphavirus-like superfamily. Mutations of D64, D90, R93, C135, C142, and Y249 to alanine destroyed or greatly reduced the MT activity of nsP1. All MT-negative mutants lost also the GT activity, confirming that methylation of GTP is an essential prerequisite for the synthesis of the covalent guanylate complex. Mutation of H38 prevented the GT reaction without destroying MT activity. Conservation of residues essential for both reactions in the alphavirus-like superfamily implies that they use a capping mechanism similar to that for the alphaviruses. Residues D64 and D90 were necessary for AdoMet binding, as measured by UV cross-linking. Secondary structure predictions of nsP1 and other proteins of the superfamily place these residues in positions corresponding to AdoMet-binding sites of cellular methyltransferases, suggesting that they all may be structurally related.

Glycosylation of rat NGF receptor ectodomain in the yeast Saccharomyces cerevisiae.

Here we studied the glycosylation of a mammalian protein, the ectodomain of rat nerve growth factor receptor (NGFRe), in Saccharomyces cerevisiae. NGFRe is secreted to the culture medium of S. cerevisiae if it is fused to a polypeptide (hsp 150 delta) carrier. The hsp 150 delta-carrier has 95 serine and threonine residues, which were extensively O-glycosylated. In spite of 41 potential sites, NGFRe lacked O-glycans, whether fused to the carrier or not. Distortion of the conformation of NGFRe by inhibition of disulfide formation did not promote O-glycosylation, whereas N-glycosylation was enhanced. Thus, the serine and threonine residues of the hsp 150 delta-NGFRe fusion protein were highly selectively O-glycosylated.

The hsp150 delta-carrier confers secretion competence to the rat nerve growth factor receptor ectodomain in Saccharomyces cerevisiae.

When the extracellular domain of rat low-affinity nerve growth factor receptor (NGFRe) was synthesized in Saccharomyces cerevisiae with the signal peptide of invertase, NGFRe was translocated to the endoplasmic reticulum (ER) and retained there. However, when NGFRe was fused to the C-terminus of the hsp150 delta-carrier, the hsp150 delta-NGFRe fusion protein was efficiently secreted to the growth medium with no apparent retention in the ER. The NGFRe portion was disulphide-bonded and its single N-glycosylation site was occupied. The hsp150 delta-carrier is an N-terminal signal peptide-containing fragment of a yeast secretory glycoprotein. Hsp150 delta-NGFRe, harvested from the culture medium, inhibited the cross-linking of [125I]NGF to authentic NGFR on the surface of human melanoma cells. Moreover, [125I]NGF could be chemically cross-linked to secretory hsp150 delta-NGFRe, suggesting that the NGFRe portion had adopted a ligand-binding conformation. However, inhibition of the cross-linking by unlabelled NGF was less effective than in the case of the authentic receptor. The hsp150 delta-carrier may have potential in the production of mammalian proteins, which require elaborate folding and disulphide formation in the ER.

Structural features of a polypeptide carrier promoting secretion of a beta-lactamase fusion protein in yeast.

Escherichia coli beta-lactamase was secreted into the culture medium of Saccharomyces cerevisiae in biologically active form, when fused to the C-terminus of the hsp150 delta-carrier. The hsp150 delta-carrier is an N-terminal fragment of the yeast hsp150 protein, having a signal peptide and consisting mostly of a 19 amino acid peptide repeated 11 times in tandem. Here we expressed the hsp150 delta-carrier fragment alone in S. cerevisiae. Apparently due to a positional effect of the gene insertion, large amounts of the hsp150 delta-carrier were synthesized. About half of the de novo synthesized carrier molecules were secreted into the culture medium, the rest remaining mostly in the pre-Golgi compartment. The extensively O-glycosylated carrier fragment was purified from the culture medium under non-denaturing conditions. Circular dichroism spectroscopy showed that it had no regular secondary structure. Nuclear magnetic resonance spectroscopy showed that a non-glycosylated synthetic peptide, the consensus sequence of the repetitive 19 amino acid peptide, also lacked secondary structure. The unstructured carrier polypeptide may facilitate proper folding and secretion of heterologous proteins attached to it.