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Matrix protein of Vesicular stomatitis virus harbours a cryptic mitochondrial-targeting motif

¹ Centre for Gene Therapeutics, McMaster University, 1200 Main Street W MDCL-5023, Hamilton, ON L8N 3Z5, Canada
² University of Ottawa Heart Institute, 40 Ruskin Street, Ottawa, ON, Canada
³ Ottawa Regional Cancer Centre, University of Ottawa, 503 Smyth Road, Ottawa, ON, Canada

Correspondence
Brian D. Lichty
lichtyb{at}mcmaster.ca

	ABSTRACT

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Vesicular stomatitis virus (VSV) is a rhabdovirus that has attracted attention of late as an oncolytic virus and as a vaccine vector. Mutations in the matrix (M) gene of VSV yield attenuated strains that may be very useful in both settings. As a result of this interest in the M protein, this study analysed various M–green fluorescent protein (GFP) fusion constructs. Remarkably, fusion of the N terminus of the M protein to GFP targeted the fluorescent protein to the surface of mitochondria. Mutational analysis indicated that a mitochondrial-targeting motif exists within aa 33–67. Expression of these fusion proteins led to loss of mitochondrial membrane permeability and to an alteration in mitochondrial organization mirroring that seen during viral infection. In addition, a portion of the M protein present in infected cells co-purified with mitochondria. This work may indicate a novel function for this multifunctional viral protein.

	MAIN TEXT

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Vesicular stomatitis virus (VSV) is the prototypical rhabdovirus, bearing a negative-stranded genome of 11 kb comprising five genes encoding the nucleocapsid, phosphoprotein, matrix (M) protein, glycoprotein and polymerase. With four of these proteins apparently devoted to replication and structure of the virus, it appears that the M protein is primarily responsible for modulating virus–host cell interactions. Although it is one of the smallest gene products encoded in the VSV genome, the M protein has some of the most crucial and diversified roles in the control of VSV replication and pathogenesis, and a thorough understanding of this protein will aid the design of improved therapeutic VSV-based vectors. A number of functions have been attributed to the M protein, including a role in inhibiting the viral RNA-dependent RNA polymerase (Carroll & Wagner, 1979; Clinton et al., 1978), as well as an important role in mediating budding of virions from the infected cell (Harty et al., 2001; Jayakar et al., 2000). The M protein also plays a crucial role in helping VSV to escape cellular antiviral programmes. This appears to be accomplished by blocking the expression of antiviral gene products (such as beta interferon) in response to infection, thereby allowing the virus to replicate unabated. This inhibition of cellular gene expression has been attributed to the ability of the M protein to block both cellular transcription (Black & Lyles, 1992) and nucleocytoplasmic transport (Petersen et al., 2000, 2001; von Kobbe et al., 2000). Indeed, it now appears that VSV employs this block in nucleocytoplasmic mRNA transport to thwart host innate immune mechanisms (Stojdl et al., 2003). This inhibition appears to involve an interaction between the M protein and the nuclear pore (von Kobbe et al., 2000) and is mediated via the mRNA export factor Rae1 (Faria et al., 2005). The cytopathic effect (CPE) induced by VSV infection has been attributed to the M protein and expression of M protein alone is capable of inducing CPE (Blondel et al., 1990; Kopecky & Lyles, 2003a, b; Kopecky et al., 2001). In most cells, this effect is due to inhibition of host-cell gene expression (Kopecky & Lyles, 2003b), whilst in others (e.g. L929 cells) M protein mutants allow expression of the death receptor apoptotic pathway by the infected cell (Gaddy & Lyles, 2005).

In an attempt to dissect the function of the N terminal portion of the M protein, we created a series of constructs fused to enhanced green fluorescent protein (EGFP) and expressed them in mammalian cells. In the course of this work, a fusion protein was created (in pEGFP-N1; Clontech) comprising the N-terminal 72 aa of the M protein fused to EGFP (WT+72–GFP) Surprisingly, WT+72–GFP showed perfect co-localization with mitochondrial markers, including anti-cytochrome c monoclonal antibody (Zymed) staining (Fig. 1a) and the mitochondrial marker OCT–DsRed2 (ornithine carbamyl transferase pre-sequence fused to DsRed2) (Harder et al., 2004) (Fig. 1b). To ensure that this localization was not an artefact of fusion to GFP, we constructed fusions with the unrelated fluorescent protein DsRed2 and once again observed targeting to mitochondria. Mitochondrial targeting was confirmed in U2OS, BHK and HeLa cell lines, as well as primary human foreskin fibroblasts (not shown).

View larger version (35K): [in this window] [in a new window]   Fig. 1. Association of VSV M protein with mitochondria. (a) U2OS cells were transfected with WT+72–GFP and stained for the presence of cytochrome c. The merged image is shown in colour (with co-localization visible as yellow fluorescence). (b) U2OS cells were co-transfected with WT+72–GFP and OCT–DsRed2. (c) HeLa cells were transfected with WT+91–GFP and fixed cells were subjected to immunoelectron microscopic analysis using a gold-labelled anti-GFP antibody. Gold beads (arrows) were found at the surface of mitochondria in WT+91–GFP-transfected cells. Bar, 500 nm. (d) U2OS cells were co-transfected with OCT–DsRed2 and full-length M–GFP (upper three panels). Cells were exposed to cold PBS containing 50 µg digitonin ml–1, washed with cold PBS and fixed with 4 % paraformaldehyde. Most of the green fluorescence was lost following digitonin permeabilization of the plasma membrane. A portion of the punctate green fluorescence that persisted co-localized with mitochondria. When cells were co-transfected with OCT–DsRed2 and GFP (lower two panels), digitonin treatment released all of the GFP fluorescence, whilst the mitochondria retained red fluorescence. (e) Infected HEK 293 cells were fractionated by differential centrifugation into nuclear (lane 1), mitochondrial (lane 2) and cytoplasmic (lane 3) fractions. Fractions were loaded on 10 % (upper two panels) or 15 % (lower two panels) SDS-polyacrylamide gels and Western blotted. The blots were probed for VSV M protein, GAPDH (cytoplasmic marker), Cox IV (mitochondrial marker) and histone H3 (nuclear marker).

When cells were transfected with full-length M protein fused to GFP, they displayed a diffuse green fluorescence in agreement with the reported distribution of M (Glodowski et al., 2002). This distribution fitted with the various functions attributed to this protein, but made it difficult to determine whether some of the M protein expressed in the cell was associated with the mitochondria. In order to specifically view full-length M51R M–GFP fusion protein associated with membrane-bound organelles such as the mitochondria, we employed a strategy for preferential permeabilization of the plasma membrane with digitonin. U2OS cells on coverslips were co-transfected with full-length M51R M–GFP and OCT–DsRed2 fusion constructs. As a negative control, cells were also co-transfected with EGFP and OCT–DsRed2. The next day, transfected cells were treated with digitonin (50 µg ml^–1 in PBS) and plasma membrane permeabilization of cells was determined by staining briefly with trypan blue and viewing under a microscope. Coverslips were washed three times with ice-cold PBS, fixed and viewed. In cells co-transfected with M–GFP and OCT–DsRed2, most of the green fluorescence was removed from the cells by washing, whilst the red fluorescence was retained, indicating selective permeabilization of the plasma membrane. Under these conditions, much of the residual green fluorescence co-localized with the red mitochondrial marker, indicating that some of the full-length M–GFP fusion protein was in fact associated with mitochondria (Fig. 1d). Green fluorescence was lost entirely in all cases where control cells expressing EGFP and OCT–DsRed2 were treated in this manner (Fig. 1d).

Infected cells were subjected to fractionation by differential centrifugation using a standard protocol (Cavadini et al., 2002). The resulting nuclear, mitochondrial and cytoplasmic fractions were Western blotted and probed for M protein, glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as a cytoplasmic marker (polyclonal antibody; Abcam), histone H3 as a nuclear marker (polyclonal antibody; Santa Cruz) and Cox IV as a mitochondrial marker (monoclonal antibody; Molecular Probes) (Fig. 1e). The results clearly demonstrated the presence of M protein in the washed mitochondrial pellet isolated from infected cells.

Further characterization of the mitochondrial-targeting signal demonstrated that the N-terminal fragments of M extending as far as aa 120 (of 229 aa) targeted fluorescent proteins to the mitochondria (Fig. 2a). In addition, fragments beginning at one of the alternative start methionines, M33 (M33–72–GFP), were also targeted to mitochondria, whilst fragments beginning at the other alternative start codon, M51 (M51–91–GFP), were not. However, a fragment including only aa 1–50 (WT+50–GFP) did not target GFP to mitochondria, indicating that the targeting motif spans M51, but does not require M51 (Fig. 2a), as also shown by deletion of M51 (WT+72 M51–GFP). M33 was also not required, as demonstrated by the WT+72 M33A–GFP construct. It should also be noted that when these fragments were fused to the C terminus of GFP (GFP–WT+72 and GFP–WT+91), they failed to localize to the mitochondria. This is typical of mitochondrial-targeting motifs found at the N termini of proteins (Gordon et al., 2000).

View larger version (55K): [in this window] [in a new window]   Fig. 2. Characterization of the mitochondrial-targeting motif in VSV M protein. (a) A series of fusion proteins was constructed, localizing the targeting motif to the region between aa 33 and 72. The amino acid sequence of the N terminus of VSV M protein (Indiana strain) is indicated. Alternative start codons (M33 and M51) are shown as enlarged letters. Fusion proteins beginning at M1 and M33 showed mitochondrial localization, whilst fusions beginning at M51 did not. Clusters of like-coloured amino acids were mutated to alanines and expressed as GFP fusions to search for mutations that abolished mitochondrial localization. (b) Cells transfected with the WT+91–GFP construct and counterstained with MitoTracker red. (c) Cells transfected with a fusion protein of the first 91 aa of M and GFP, where 66FT67 [underlined in (a)] was mutated to AA.

It was noticed that when M–GFP or M–DsRed2 fusion proteins were expressed in cultured cells, many of these cells lost their usual tubuloreticular mitochondrial organization and displayed perinuclear punctiform mitochondria (Fig. 3a). In order to quantify the frequency at which this distribution was induced, cells were transfected with WT+91–GFP, WT33–91–GFP and FT-AA+91–GFP (containing the ⁶⁶FT⁶⁷AA mutation) expression constructs. Random microscopic fields were analysed and the proportion of cells displaying punctate or reticulotubular mitochondria was calculated for cells expressing these M–GFP fusion proteins or OCT–GFP alone as a control. At 24 h post-transfection, punctate mitochondria were evident in >60 % of cells expressing WT+91–GFP compared with 24 % of cells expressing WT33–91–GFP and 7 % of cells expressing the mutated FT-AA+91–GFP (Fig. 3b). The intermediate phenotype displayed by the WT33–91–GFP fusion protein may relate to an apparent reduced efficiency of mitochondrial targeting observed when the N-terminal 32 aa are absent (data not shown).

View larger version (57K): [in this window] [in a new window]   Fig. 3. Altered mitochondrial structure and function following transfection and infection. (a) Cells were transfected with the WT+72–GFP fusion construct and stained with MitoTracker red CMXRos (Invitrogen). A merged image is shown indicating an example of the punctate pattern (!) and the reticulotubular pattern (*). (b) Analysis of mitochondrial morphology and MitoTracker red staining. U2OS cells were plated on coverslips and transfected with OCT–GFP (to target GFP to the mitochondria), WT+91–GFP, aa 33–91 fused to GFP (WT 33–91–GFP) or the mutated FT-AA+91–GFP construct. At 24 h post-transfection, the cells were fixed and stained with MitoTracker red. Random fields were analysed under a fluorescent microscope and 80–100 cells were scored as having reticular or punctate mitochondria, as well as reduced MitoTracker staining (compared with non-transfected cells in the same field). The data shown represent the means±SD of four independent transfections. (c) Reduced MitoTracker red staining following co-transfection with M protein N terminus–GFP fusion constructs, shown here for WT+120–GFP. (d) Serial views of a live cell co-transfected with WT+72–GFP and OCT–DsRed2 over a 4 h period demonstrating induced collapse of the mitochondrial network. (e) Serial views of a live cell transfected with OCT–GFP and infected with VSV, viewed over a 2 h period, showing the same structural changes as in (d).

To determine whether VSV infection induced similar alterations in mitochondrial organization, we transfected cells with the mitochondrial marker protein OCT–GFP and infected cells with a recombinant VSV expressing monomeric red fluorescent protein 1 (mRFP1, inserted into pXNDG as described previously; Stojdl et al., 2003) for identification of infected cells. Time-lapse images of live cells were collected. The mitochondria of infected cells were seen to undergo the same alterations in structure (Fig. 3e) as in cells co-transfected with WT+72–GFP and OCT–DsRed2 (Fig. 3d).

The M protein of VSV has several functions attributed to it and in this paper we have added the novel observation that this protein has a mitochondrial-targeting motif in its N terminus. Expression of fragments of M that localized exclusively to the mitochondria led to alterations in both structure and function of the mitochondria. Whilst only a small fraction of the full-length protein present in a cell can be localized to the mitochondria, it is intriguing to note that the mitochondria of infected cells undergo similar alterations.

Many viruses express proteins that localize, at least in part, to mitochondria and many of these proteins alter the apoptotic response of the infected cell (reviewed by Boya et al., 2004). In some cases, these proteins mediate mitochondrial effects very similar to those seen here with VSV M protein (Everett et al., 2000; McCormick et al., 2003). It is reasonable to predict that almost all viruses must evolve some means of dealing with the apoptotic response to infection induced in the host cell in order to carry out their normal life cycle. In fact, removal of this ability can lead to altered pathogenesis in vivo (Itoh et al., 1998; Mossman et al., 1996; Park et al., 2003). We are currently constructing mutant viruses with M protein mutations that prevent targeting of this protein to mitochondria to elucidate the role that this targeting plays in the life cycle of VSV.

Whilst VSV and indeed the M protein itself have been demonstrated to induce apoptosis (Kopecky & Lyles, 2003a, b), this effect is largely due to inhibition of host-cell gene expression (Kopecky & Lyles, 2003b). It is currently unclear whether the mitochondrial functions of the M protein contribute to this pro-apoptotic effect or are in fact working to inhibit this response. Whilst this virus has clearly evolved mechanisms to inhibit expression of host genes such as beta interferon in response to infection, it may have co-evolved a means of ‘managing’ the apoptotic response to this blockade in order to keep the muted host cell alive long enough to produce large numbers of progeny. Ultimately, VSV strains with mutations that prevent the M protein targeting the mitochondria will need to be generated to determine what role, if any, this cryptic mitochondrial-targeting motif has on the life cycle of VSV. To date, attempts described herein to isolate a virus bearing such mutations have failed, possibly indicating that mutation of the highly conserved phenylalanine at position 66 may yield a non-functional M protein. We are currently searching for mutations to less-well-conserved flanking amino acids that may allow the rescue of such a virus.

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Received 12 December 2005; accepted 26 June 2006.

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