Transframe Protein Research Articles

Impact of HIV type 1 protease, reverse transcriptase, cleavage site, and p6 mutations on the virological response to quadruple therapy with saquinavir, ritonavir, and two nucleoside analogs.

Genotype alterations of HIV-1 protease, reverse transcriptase, cleavage sites p7/p1 and p1/p6, as well as p6(gag) and transframe protein p6* were studied in an observational cohort of 42 individuals who received antiretroviral therapy consisting of saquinavir, ritonavir, and two nucleoside analogs. In a multivariate logistic regression analysis, the prior protease inhibitor experience (odds ratio, 6.20; 95% CI, 1.22-31.38) and the presence of primary protease mutations (odds ratio, 9.99; 95% CI, 1.05-94.72) were independently associated with virological failure. Moreover, a trend was observed in that individuals with N-terminal amino acid insertions in the proline-rich motif of the p6(gag) protein were less likely to experience virological failure (OR, 0.17; 95% CI, 0.02-1.35; p = 0.09). In contrast, the presence of secondary protease, reverse transcriptase, or cleavage site mutations was not independently associated with treatment failure. However, mutations at cleavage site p7/p1 (p = 0.01) and C-terminal p6* mutations (p = 0.02) were both associated with primary protease mutations. In conclusion, the presence of primary protease mutations was the most important predictor of the subsequent virological response. Moreover, there is some evidence that insertions in the proline-rich area of the p6(gag) protein may affect the virological response. The relationship between mutations of cleavage sites or C-terminal p6* residues and protease mutations suggests that these alterations may serve a compensatory role, increasing viral fitness.

Characterisation of IS 153, an IS 3-family Insertion Sequence Isolated from Lactobacillus sanfranciscensis and its use for Strain Differentiation

An insertion sequence has been identified in the genome of Lactobacillus sanfranciscensis DSM 20451T as segment of 1351 nucleotides containing 37-bp imperfect terminal inverted repeats. The sequence of this element encodes two out of phase, overlapping open reading frames, orfA and orfB, from which three putative proteins are produced. OrfAB is a transframe protein produced by -1 translational frame shifting between orf A and orf B that is presumed to be the transposase. The large orfAB of this element encodes a 342 amino acid protein that displays similarities with transposases encoded by bacterial insertion sequences belonging to the IS3 family. In L. sanfranciscensis type strain DSM 20451T multiple truncated IS elements were identified. Inverse PCR was used to analyze target sites of four of these elements, but except of their highly AT rich character not any sequence specificity was identified so far. Moreover, no flanking direct repeats were identified. Multiple copies of IS153 were detected by hybridization in other strains of L. sanfranciscensis. Resulting hybridization patterns were shown to differentiate between organisms at strain level rather than a probe targeted against the 16S rDNA. With a PCR based approach IS153 or highly similar sequences were detected in L. acidophilus, L. casei, L. malefermentans, L. plantarum, L. hilgardii, L. collinoides L. farciminis L. sakei and L. salivarius, L. reuteri as well as in Enterococcus faecium, Pediococcus acidilactici and P. pentosaceus.

Competitive Inhibition of Human Immunodeficiency Virus Type-1 Protease by the Gag-Pol Transframe Protein

The human immunodeficiency virus type-1 (HIV-1) transframe protein p6* is located between the structural and enzymatic domains of the Gag-Pol polyprotein, flanked by the nucleocapsid (NC) and the protease (PR) domain at its amino and carboxyl termini, respectively. Here, we report that recombinant highly purified HIV-1 p6* specifically inhibits mature HIV-1 PR activity. Kinetic analyses and cross-linking experiments revealed a competitive mechanism for PR inhibition by p6*. We further demonstrate that the four carboxyl-terminal residues of p6* are essential but not sufficient for p6*-mediated inhibition of PR activity. Based on these results, we suggest a role of the transframe protein p6* in regulating HIV-1 PR activity during viral replication.

Importance of the cysteine-rich carboxyl-terminal half of V protein for Sendai virus pathogenesis.

The Sendai virus V protein is a nonstructural trans-frame protein whose cysteine-rich C-terminal half is fused to the acidic N-terminal half of the P protein via mRNA editing. We recently created a mutant by disrupting the editing motif, which is devoid of mRNA editing and hence unable to produce the V protein, and demonstrated that this V(-) virus replicated normally or even faster with augmented gene expression and cytopathogenicity in cells in vitro, but was strongly attenuated in pathogenicity for mice (A. Kato, K. Kiyotani, Y. Sakai, T. Yoshida, and Y. Nagai, EMBO J. 16:578-587, 1997). Thus, although categorized as a nonessential protein, the V protein appeared to encode a luxury function required for the viral in vivo pathogenesis. Here, we created another version of a V-deficient mutant, VdeltaC, encoding only the N-terminal half but not the V-specific C-terminal half, by introducing a stop codon in the trans-V frame, and then we compared its in vitro and in vivo phenotypes with those of the V(-) and wild-type viruses. The VdeltaC virus was found to be similar to the wild-type virus in vitro with no augmented gene expression and cytopathogenicity, but in vivo, it resembled the V(-) virus, displaying a similarly attenuated phenotype. Thus, the pathogenicity determinant in the V protein was mapped to the C-terminal half. The N-terminal half was likely sufficient to confer normal (wild-type) in vitro phenotypes.

Inhibition of transpositional recombination by OrfA and OrfB proteins encoded by insertion sequence IS3.

An insertion element IS3 is flanked by terminal inverted repeat (IR) sequences. IS3 encodes two, out-of-phase, overlapping open reading frames, orfA and orfB, from which three proteins are produced. OrfAB is a transframe protein produced by -1 translational frameshifting between orfA and orfB, and it is known to be IS3 transposase. OrfA and OrfB are the proteins produced without frameshifting, but their functions have not been elucidated. A plasmid carrying an IS3 mutant that produces only transposase generates miniplasmids--which are the IS3-mediated intramolecular transposition products--as well as characteristic IS3 circles and linear IS3 molecules. OrfA inhibited the generation of these small molecules to a lesser degree, but OrfB did not. OrfB, together with OrfA, however, inhibited the generation more strongly than OrfA alone. OrfA also inhibited the intermolecular transposition of mini-IS3 with the chloramphenicol-resistance gene flanked by IRs to a reduced frequency, and OrfB together with OrfA inhibited it almost completely. OrfA and/or OrfB did not, however, repress transcription from the promoter in the left-terminal region preceding orfA. The results obtained above show that OrfA and OrfB are not repressors but are inhibitors of transpositional recombination promoted by transposase. OrfA with an alpha helix-turn-alpha helix DNA-binding motif may compete with transposase to bind to terminal IRs. OrfA, together with OrfB that has a DDE motif conserved in retroviral integrases, may inhibit the formation of an active transpososome consisting oftransposase, two terminal IRs and target DNA for the strand transfer reaction. IS3 with a limited size, 1258 bp in length, uses strategies of translational frameshifting and coupling to produce transposase as well as negative regulators to make its copies at a low level, which minimizes a deleterious effect of transposition on bacterial hosts.

The HIV-1 nef transframe protein has significant sequence and structural similarity to chemokines, as assessed by threading (inverse folding), sequence analysis, and molecular modeling

The HIV-1 nef transframe protein has significant sequence and structural similarity to chemokines, as assessed by threading (inverse folding), sequence analysis, and molecular modeling

Sequence‐Specific Resonance Assignments of the 1H‐NMR Spectra and Structural Characterization in Solution of the HIV‐1 Transframe Protein p6*

The frameshift protein p6* encoded directly upstream of the protease in the human immunodeficiency virus type 1 (HIV-1) pol reading frame is thought to be a natural inhibitor of protease activation and to play a role in the polyprotein processing of Gag and Gag-Pol precursors. To allow structural characterization of the p6* transframe protein, the p6* coding region was cloned into the vector pGEX-KG and expressed in Escherichia coli as a fusion protein with glutathione S-transferase (GST) under the control of the tac promoter. Thrombin cleavage of the construct resulted in a 70-amino-acid polypeptide which is extended by two additional residues at the N-terminus compared to the natural p6* sequence. The native purification procedure including an affinity and a size-exclusion chromatography step yielded sufficient amounts of highly pure protein suitable for NMR spectroscopy. Fluorescence, circular dichroism and 1H-NMR spectroscopy were applied to characterize the structure of protein. Two-dimensional NMR spectra provided essentially complete sequence-specific resonance assignments at pH 5.9. Although there is evidence for a helix-forming tendency in the N-terminus of the protein, the experiments indicate that p6* has no overall stable secondary or tertiary structure with the single tryptophan exposed in aqueous solution. However, the results reported herein open the way to characterize further the interaction of p6* with the HIV-1 protease in structural and functional in vitro studies.

Identification and Characterization of the Linear IS3 Molecules Generated by Staggered Breaks

Insertion sequences IS3 encodes two, out-of-phase, overlapping open reading frames, orfA and orfB. The OrfAB transframe protein that is IS3 transposase is produced by -1 translational frameshifting between orfA and orfB. Efficient production of the IS3 transposase in the cells harboring the IS3-carrying plasmid has been shown to generate miniplasmids as well as characteristic minicircles, called IS3 circles, consisting of the entire IS3 sequence and one of the 3-base pair sequences flanking IS3 in the parental plasmid. Here, we show that the IS3 transposase also generates the linear molecules of IS3 with 3-nucleotide overhangs at the 5'-ends. The nucleotide sequences of the overhangs are the same as those flanking IS3 in the parental plasmid, suggesting that the linear IS3 molecules are generated from the parental plasmid DNA by staggered double strand breaks at the end regions of IS3. The linear IS3 molecules are likely to be the early intermediates in the transposition reaction, which proceeds in a non-replicative manner.

Characterization of cocksfoot mottle sobemovirus genomic RNA and sequence comparison with related viruses

The genome of cocksfoot mottle virus (CfMV) is a positive-sense ssRNA molecule of 4082 nucleotides as revealed by sequencing the entire genome. The 5'-untranslated region of the genome is 69 nucleotides and the 3'-untranslated region is 225 nucleotides in length. The coding region contains four open reading frames (ORFs). The organization of CfMV ORFs differs significantly from that of the previously sequenced sobemoviruses southern bean mosaic virus and rice yellow mottle virus. ORF1 encodes a protein having a calculated molecular mass of 12.3 kDa. The function of this protein is unknown. The next ORF codes for the putative VPg and serine protease. The ORF2a product consists of 568 amino acids, with a calculated molecular mass of 60.9 kDa. The replicase of CfMV is translated as part of a polyprotein by--1 ribosomal frameshifting in ORF2a. The calculated molecular mass of the transframe protein is 103.4 kDa. ORF3 encodes the 27.6 kDa coat protein. This has been verified by amino acid sequencing of the CfMV coat protein N terminus. Northern blots of total RNA from CfMV-infected barley leaves reveal the 4.1 kb genomic RNA band and one virus-specific band of 1.2 kb, which may represent a subgenomic RNA for coat protein synthesis.

The Putative Replicase of the Cocksfoot Mottle Sobemovirus Is Translated as a Part of the Polyprotein by -1 Ribosomal Frameshift

The polyprotein of cocksfoot mottle sobemovirus (CfMV) is encoded by two overlapping open reading frames (ORF). The ORF 2a codes for the putative VPg and serine protease and the ORF 2b codes for the putative replicate. The consensus signals for a -1 ribosomal frameshifting event are found at the very beginning of the overlapping region of these ORFs. The shifty heptanucleotide in CfMV is UUUAAAC, and the secondary structure after the shifty sequence is predicted to be a stem-loop. In vitro translation of the CfMV RNA in wheat germ extract produced proteins of several sizes, including one of 100 kDa. According to the nucleotide sequence data, no single ORF is capable of directing the synthesis of a 100-kDa protein. A chimetic β-glucuronidase-CfMV cDNA containing the entire ORF 2a and 2b overlap region including frameshift signals was constructed. A trans-frame protein of 108 kDa was produced from this construct with an efficiency of 26-29% by in vitro translation in wheat germ extract. CfMV is the first sobemovirus in which the putative replicase is reported to be produced as a part of a polyprotein by a -1 frameshift event. The replicases of the sobemoviruses are related to the luteovirus subgroup II replicases, which are known to be produced by -1 ribosomal frameshift. The reported amino acid sequences of the putative replicases of sobemo- and subgroup II luteoviruses were compared to that of the putative replicase of CfMV. This comparison revealed more extensive homology between these groups than previously reported.

IS 1-encoded proteins, InsA and the InsA-B′-InsB transframe protein (transposase): Functions deduced from their DNA-binding ability

Insertion sequence IS 1 encodes a transframe protein, InsA-B′-InsB, which is produced from two out-of-phase reading frames, insA and B′- insB, by translational frameshifting at a run of adenines. Unless the frameshifting event occurs, the InsA protein is produced from IS 1. We found that cells harboring a plasmid carrying an IS 1 mutant with a single adenine insertion in the run of adenines contained miniplasmids. Cloning and DNA sequencing analyses of the miniplasmids revealed that they had a deletion extending from an inverted repeat (IR) at the left end of IS 1. This indicates that they were generated by IS 1-mediated deletion due to efficient production of the InsA-B′-InsB transframe protein that is IS 1 transposase. Both the InsA protein and transposase were partially purified as a fusion protein with collagen-LacZ by LacZ-specific affinity column chromatography. The InsA ∗ and the collagenolyzed InsA ∗ were found to bind specifically to a 24-bp region within each of the IRs at the ends of IS 1. The transposase Tnp ∗ and the collagenolyzed Tnp ∗ were found to bind to the sequence with or without IR, but preferentially to that with IR. The nonspecific DNA-binding ability of transposase may be involved in recognition of the target DNA, an important process of transposition of IS 1. Both InsA and transposase have the IR-specific DNA binding ability and a common polypeptide segment containing the α-helix-turn-α-helix motif, supporting the previous indication that InsA competes with transposase to bind to IRs and thus becomes a transposition inhibitor. Based on the observations described in this article, we speculate that transposase of IS 1 consists of at least two domains, the N-terminal half, which almost entirely overlaps InsA, and the C-terminal half, which almost entirely overlaps B′-InsB. The frameshifting event adds the latter domain to the former to give the transposase activity recognizing IRs and the target sequence to initiate the transposition reaction.

Kinetics and mechanism of autoprocessing of human immunodeficiency virus type 1 protease from an analog of the Gag-Pol polyprotein.

Upon renaturation, the polyprotein MBP-delta TF-Protease-delta Pol, consisting of HIV-1 protease and short native sequences from the trans-frame protein (delta TF) and the polymerase (delta Pol) fused to the maltose-binding protein (MBP) of Escherichia coli, undergoes autoprocessing to produce the mature protease in two steps. The initial step corresponds to cleavage of the N-terminal sequence to release the protein intermediate Protease-delta Pol, which has enzymatic activity comparable to that of the mature enzyme. Subsequently, the mature enzyme is formed by a slower cleavage at the C terminus. The rate of increase in enzymatic activity is identical to that of the appearance of MBP-delta TF and the disappearance of the MBP-delta TF-Protease-delta Pol. Initial rates are linearly dependent on the protein concentration, indicating that the N-terminal cleavage is first-order in protein concentration. The reaction is competitively inhibited by pepstatin A and has a pH rate profile similar to that of the mature enzyme. These results and molecular modeling studies are discussed in terms of a mechanism in which a dimeric full-length fusion protein must form prior to rate-limiting intramolecular cleavage of the N-terminal sequence that leads to an increase in enzymatic activity.

Expression and purification of the mouse mammary tumor virus gag-pro transframe protein p30 and characterization of its dUTPase activity

The mouse mammary tumor virus gag-pro transframe protein (p30) contains the nucleocapsid protein domain derived from the 3' end of gag, fused to 154 residues encoded by the 5' region of the pro open reading frame. The DNA coding for p30 was cloned into the plasmid pALTER-1, and an additional nucleotide was inserted by site-directed mutagenesis to allow the read-through from the gag into the pro open reading frame. The obtained insert was then cloned into pGEX-2T, a plasmid containing the glutathione S-transferase gene of Schistosoma japonicum and a nucleotide sequence encoding for a thrombin cleavage site. The chimeric protein (GST-p30) was isolated by affinity chromatography on a glutathione-Sepharose 4B column, and after thrombin treatment, the excised p30 was further purified on a single-stranded DNA-agarose column. This protein showed dUTPase activity, with only negligible cleavage of dATP, dGTP, dCTP, dTTP, or UTP. Its apparent Km for dUTP was 28 microM. The enzyme was inhibited by EDTA, but its effect could be reversed by Mg2+ and other divalent cations. dUTPase activity was also detected in purified mouse mammary tumor virus, and p30 was the only protein recognized by antibodies directed towards the carboxyl-terminal sequence of the dUTPase coding region.

Translational Control in Production of Transposase and in Transposition of Insertion Sequence IS3

IS3 (1258 bp in length) contains two open reading frames, orfA and orfB , which are out of phase and overlap each other. We show here that three proteins of 10, 32 and 42 kDa in size are encoded by IS3. The 10 kDa protein is the product of orfA and is here called OrfA. The ATG codon of orfB which overlaps the termination codon of orfA is utilized to produce the 32 kDa protein (here called OrfB), in a manner depending on translation of orfA. The 42 kDa protein is a transframe protein (here called OrfB), which is synthesized from orfA and orfB by -1 translational frameshifting at the A4G motif present in the overlapping region. Both the frameshifting event to produce OrfB and the coupled translation event to produce OrfB are greatly stimulated by a pseudo knot structure located in the overlapping region between orfA and orfB . A mutant IS3 with a single base insertion in the A4G motif efficiently produces the OrfB transframe protein without frameshifting. This mutant was found not to mediate co-integration but to mediate adjacent deletion to produce various miniplasmids and minicircles in large amounts. The OrfB transframe protein is necessary and sufficient for formation of these deletion products, implying that it is the transposase. Most of the minicircles consisted solely of the entire IS3 sequence and a three base-pair sequence between the IS3 ends. The significance of minicircle formation is discussed.

The nucleic acid-binding zinc finger protein of potato virus M is translated by internal initiation as well as by ribosomal frameshifting involving a shifty stop codon and a novel mechanism of P-site slippage.

The genes for the capsid protein CP and the nucleic acid-binding 12K protein (pr12) of potato virus M (PVM) constitute the 3' terminal gene cluster of the PVM RNA genome. Both proteins are presumably translated from a single subgenomic RNA. We have identified two translational strategies operating in pr12 gene expression. Internal initiation at the first and the second AUG codon of the pr12 coding sequence results in the synthesis of the 12K protein. In addition the protein is produced as a CP/12K transframe protein by ribosomal frameshifting. For these studies parts of the CP and pr12 coding sequences including the putative frameshift region were introduced into an internal position of the beta-glucuronidase gene. Mutational analyses in conjunction with in vitro translation experiments identified a homopolymeric string of four adenosine nucleotides which together with a 3' flanking UGA stop codon were required for efficient frameshifting. The signal AAAAUGA is the first frameshift signal with a shifty stop codon to be analyzed in the eukaryotic system. Substitution of the four consecutive adenosine nucleotides by UUUU increased the efficiency of frameshifting, while substitution by GGGG or CCCC dramatically reduced the synthesis of the transframe protein. Also, UAA and UAG could replace the opal stop codon without effect on the frameshifting event, but mutation of UGA to the sense codon UGG inhibited transframe protein formation. These findings suggest that the mechanism of ribosomal frameshifting at the PVM signal is different from the one described by the 'simultaneous slippage' model in that only the string of four adenosine nucleotides represents the slippery sequence involved in a -1 P-site slippage.

Translational frameshifting by barley yellow dwarf virus RNA (PAV serotype) in Escherichia coli and in eukaryotic cell-free extracts.

The open reading frame (39K ORF) at the 5' end of the genome of barley yellow dwarf virus, PAV serotype (BYDV-PAV), overlaps with a 60K ORF by 13 nucleotides. Several approaches were used to show that the 60K ORF (putative polymerase gene) is translated by a low-frequency frameshift event in which some ribosomes shift into the 60K ORF rather than terminate at the 39K ORF stop codon. A sequence encompassing this region of overlap induced minus one (-1) translational frameshifting in heterologous and native contexts. In Escherichia coli, with the alpha subunit of lacZ used as a reporter gene, the rate of frameshifting caused by the BYDV-PAV sequence was approximately 3%. Amino acid sequencing of the transframe protein confirmed that ribosomes slip into the -1 frame in the overlapping region which includes a consensus shifty heptanucleotide: GGGUUUU. In a wheat germ translation system, BYDV-PAV genomic RNA from virions frameshifted about twice as efficiently as full-length transcripts from a cDNA clone. Frameshifting in rabbit reticulocyte lysates was much lower for either template. The identity of the 99-kDa wheat germ translation product was verified as the transframe protein by immunoprecipitation with antibody specific for the 60K ORF. These results support our previous observations of frameshifting in protoplasts and illustrate a subtle molecular control mechanism between this pathogen and its host cells.

Characterization of ribosomal frameshifting for expression of pol gene products of human T-cell leukemia virus type I.

For study of the pol gene expression of human T-cell leukemia virus type I (HTLV-I), RNA was transcribed in vitro from proviral DNA and translated in rabbit reticulocyte lysates. This cell-free translation resulted in two major translation products representing the Gag and Gag-Pro polyproteins. By contrast, the Gag-Pro-Pol polyprotein could be readily observed only when translation was performed with mutant mRNA in which the protease (pro) reading frame was aligned to gag to eliminate the frameshifting event in the gag-pro overlap. The results indicated that two independent ribosomal frameshifting events are required for expression of the HTLV-I pol gene product. Studies with mutant DNAs facilitated the characterization of the primary structure of the HTLV-I mRNA responsible for the ribosomal frameshift in the pro-pol overlap and demonstrated that the frameshift occurs at the signal sequence UUUAAAC. Direct amino acid sequencing of the transframe protein localized the site of the frameshift to the asparagine codon AAC.

Transposase-induced excision and circularization of the bacterial insertion sequence IS911.

We have investigated the role of three IS911-specified proteins in transposition in vivo: the products of the upstream (OrfA) and downstream (OrfB) open reading frames, and a transframe protein (OrfAB) produced by -1 translational frameshifting between orfA and orfB. The production of OrfAB alone is shown to lead both to excision and to circularization of the element and to be sufficient for intermolecular transposition into a plasmid target. Simultaneous and independent production of OrfA is shown to stimulate OrfAB-mediated intermolecular transposition while greatly reducing the appearance of transposon circles. We have not been able to detect a role for OrfB. Although under certain conditions, the vector plasmid undergoes precise resealing after IS911 excision, the data suggest that this is not normally the case and that the donor plasmid is not generally conserved. The use of IS911 derivatives carrying mutations in the terminal 2 bp suggested that circle formation represents a site-specific intramolecular transposition event. We present a model which explains both intra- and intermolecular transposition events in terms of a single reaction mechanism of the 'cut and paste' type.

Ribosomal frameshifting in plants: a novel signal directs the −1 frameshift in the synthesis of the putative viral replicase of potato leafroll luteovirus.

The 5.8 kb RNA genome of potato leafroll luteovirus (PLRV) contains two overlapping open reading frames, ORF2a and ORF2b, which are characterized by helicase and RNA polymerase motifs, respectively, and possibly represent the viral replicase. Within the overlap, ORF2b lacks an AUG translational start codon and is therefore presumably translated by -1 ribosomal frameshifting as a transframe protein with ORF2a. This hypothesis was studied by introducing the putative frameshift region into an internal position of the beta-glucuronidase (GUS) gene and testing for the occurrence of frameshifting in vivo by transient expression of GUS activity in potato protoplasts as well as in vitro by translation in the reticulocyte system. Both experimental approaches demonstrate that a -1 frameshift occurs at a frequency of approximately 1%. Site-directed mutagenesis identified the frameshift region and the involvement of the novel heptanucleotide motif UUUAAAU in conjunction with an adjacent stem-loop structure. Part of this stem-loop encodes a basic region in the ORF2b moiety of the transframe protein which was shown by binding experiments with PLRV RNA to represent a nucleic acid-binding domain. These data support a possible biological significance of the frameshift to occur at this position of the large overlap by including the putative RNA template-binding site of the PLRV replicase in the ORF2a/ORF2b transframe protein.

No significant correlation between specific antibodies to mouse mammary tumour virus and human cancer

To study the possible involvement of mouse mammary tumour virus (MMTV) related agent in human cancer we analysed 300 samples of human sera for the presence of antibodies to MMTV structural proteins. All sera were tested by immunoblotting to achieve high specificity. Out of 300 sera, 22 reacted with transframe protein p30, 16 with the ribonucleoprotein p14, six with the envelope glycoprotein gp52 and three with the major core protein p27. Reactivities to p30 and p14 were observed in sera from cancer patients and healthy controls; reactivities to p27 and gp52 predominated in sera of cancer patients. Sera frequently reacted with a 42 kDa protein which is a cellular contaminant of the virus.