Proteolytic processing of Ty3 proteins is required for transposition.

Ty3 is a retroviruslike element found in Saccharomyces cerevisiae. It encodes GAG3 and GAG3-POL3 polyproteins which are processed into mature proteins found in the Ty3 viruslike particle. In this study, the region encoding a protease that is homologous to retroviral aspartyl proteases was identified and shown to be required for production of mature Ty3 proteins and transposition. The Ty3 protease has the Asp-Ser-Gly consensus sequence found in copia, Ty1, and Rous sarcoma virus proteases, rather than the Asp-Thr-Gly found in most retroviral proteases. The Asp-Ser-Gly consensus is flanked by residues similar to those which flank the active sites of cellular aspartyl proteases. Mutations were made in the Ty3 active-site sequence to examine the role of the protease in Ty3 particle maturation and to test the functional significance of the Ser active-site variant in the consensus sequence. Mutation of the active-site Asp blocked processing of Gag3 and Gag3-Pol3 and allowed identification of a GAG3-POL3 polyprotein. This protein was turned over rapidly in cells expressing the mutant Ty3. Changing the active-site Ser to Thr caused only a modest reduction in the levels of certain Ty3 proteins. Five putative cleavage sites of this protease in Ty3 GAG3 and GAG3-POL3 polyproteins were defined by amino-terminal sequence analysis. The existence of an additional protein(s) of unknown function, encoded downstream of the protease-coding region, was deduced from the positions of these amino termini and the sizes of known Ty3 proteins. Although Ty3 protease cleavage sites do not correspond exactly to known retroviral protease cleavage sites, there are similarities. Residues P3 through P2' in the regions encompassing each of the five sites are uncharged, and no P1 position is occupied by an amino acid with a branched beta carbon.     

Ty1 proteolytic cleavage sites are required for transposition: all sites are not created equal

The retroviral protease is a key enzyme in a viral multienzyme complex that initiates an ordered sequence of events leading to virus assembly and propagation. Viral peptides are initially synthesized as polyprotein precursors; these precursors undergo a number of proteolytic cleavages executed by the protease in a specific and presumably ordered manner. To determine the role of individual protease cleavage sites in Ty1, a retrotransposon from Saccharomyces cerevisiae, the cleavage sites were systematically mutagenized. Altering the cleavage sites of the yeast Ty1 retrotransposon produces mutants with distinct retrotransposition phenotypes. Blocking the Gag/PR site also blocks cleavage at the other two cleavage sites, PR/IN and IN/RT. In contrast, mutational block of the PR/IN or IN/RT sites does not prevent cleavage at the other two sites. Retrotransposons with mutations in each of these sites have transposition defects. Mutations in the PR/IN and IN/RT sites, but not in the Gag/PR site, can be complemented in trans by endogenous Ty1 copies. Hence, the digestion of the Gag/PR site and release of the protease N terminus is a prerequisite for processing at the remaining sites; cleavage of PR/IN is not required for the cleavage of IN/RT, and vice versa. Of the three cleavage sites in the Gag-Pol precursor, the Gag/PR site is processed first. Thus, Ty1 Gag-Pol processing proceeds by an ordered pathway.     

A critical proteolytic cleavage site near the C terminus of the yeast retrotransposon Ty1 Gag protein.

Cleavage of the Gag and Gag-Pol polyprotein precursors is a critical step in proliferation of retroviruses and retroelements. The Ty1 retroelement of Saccharomyces cerevisiae forms virus-like particles (VLPs) made of the Gag protein. Ty1 Gag is not obviously homologous to the Gag proteins of retroviruses. The apparent molecular mass of Gag is reduced from 58 to 54 kDa during particle maturation. Antibodies raised against the C-terminal peptide of Gag react with the 58-kDa polypeptide but not with the 54-kDa one, indicating that Gag is proteolytically processed at the C terminus. A protease cleavage site between positions 401 and 402 of the Gag precursor was defined by carboxy-terminal sequencing of the processed form of Gag. Certain deletion and substitution mutations in the C terminus of the Gag precursor result in particles that are two-thirds the diameter of the wild-type VLPs. While the Ty1 protease is active in these mutants, their transposition rates are decreased 20-fold compared with that of wild-type Ty1. Thus, the Gag C-terminal portion, released in the course of particle maturation, probably plays a significant role in VLP morphogenesis and Ty1 transposition.     

Heterogeneous Functional Ty1 Elements Are Abundant in the Saccharomyces Cerevisiae Genome

Despite the abundance of Ty1 RNA in Saccharomyces cerevisiae, Ty1 retrotransposition is a rare event. To determine whether transpositional dormancy is the result of defective Ty1 elements, functional and defective alleles of the retrotransposon in the yeast genome were quantitated. Genomic Ty1 elements were isolated by gap repair-mediated recombination of pGTy1-H3(Δ475-3944)HIS3, a multicopy plasmid containing a GAL1/Ty1-H3 fusion element lacking most of the gag domain (TYA) and the protease (PR) and integrase (IN) domains. Of 39 independent gap repaired pGTyHIS3 elements isolated, 29 (74%) transposed at high levels following galactose induction. The presence of restriction site polymorphisms within the gap repaired region of the 29 functional pGTyHIS3 elements indicated that they were derived from at least eight different genomic Ty1 elements and one Ty2 element. Of the 10 defective pGTyHIS3 elements, one was a partial gap repair event while the other nine were derived from at least six different genomic Ty1 elements. These results suggest that most genomic Ty1 elements encode functional TYA, PR and IN proteins. To understand how functional Ty1 elements are regulated, we tested the hypothesis that a TYB protein associates preferentially in cis with the RNA template that encodes it, thereby promoting transposition of its own element. A genomic Ty1 mhis3AI element containing either an in-frame insertion in PR or a deletion in TYB transposed at the same rate as a wild-type Ty1mhis3AI allele, indicating that TYB proteins act efficiently in trans. This result suggests in principle that defective genomic Ty1 elements could encode trans-acting repressors of transposition; however, expression of only one of the nine defective pGTy1 isolates had a negative effect on genomic Ty1 mhis3AI element transposition in trans, and this effect was modest. Therefore, the few defective Ty1 elements in the genome are not responsible for transpositional dormancy.     

The genomic RNA in Ty1 virus-like particles is dimeric

The yeast retrotransposon Ty1 resembles retroviruses in a number of important respects but also shows several fundamental differences from them. We now report that, as in retroviruses, the genomic RNA in Ty1 virus-like particles is dimeric. The Ty1 dimers also resemble retroviral dimers in that they are stabilized during the proteolytic maturation of the particle. The stabilization of the dimer suggests that one of the cleavage products of TyA1 possesses nucleic acid chaperone activity.     

The production of hybrid Ty:IFN virus-like particles in yeast.

The yeast retrotransposon Ty encodes proteins that assemble into virus-like particles (Ty-VLPs) which can be readily purified. We have recently shown that expression of the pl protein encoded by the TYA gene of Ty is sufficient for particle formation. In this paper we show that when a heterologous coding sequence, human interferon-alpha 2 (IFN), is fused in frame to the TYA gene, the resulting p1-IFN fusion protein is still assembled into VLPs. These Ty:IFN-VLPs can be easily purified to near homogeneity and furthermore, they induce an antibody response to interferon when they are injected into rabbits. Therefore, these data show that hybrid Ty-VLPs can be used as a convenient system for the efficient purification of fusion proteins in yeast.     

Inducible proteolytic inactivation of OPA1 mediated by the OMA1 protease in mammalian cells

The mammalian mitochondrial inner membrane fusion protein OPA1 is controlled by complex patterns of alternative splicing and proteolysis. A subset of OPA1 isoforms is constitutively cleaved by YME1L. Other isoforms are not cleaved by YME1L, but they are cleaved when mitochondria lose membrane potential or adenosine triphosphate. In this study, we show that this inducible cleavage is mediated by a zinc metalloprotease called OMA1. We find that OMA1 small interfering RNA inhibits inducible cleavage, helps retain fusion competence, and slows the onset of apoptosis, showing that OMA1 controls OPA1 cleavage and function. We also find that OMA1 is normally cleaved from 60 to 40 kD by another as of yet unidentified protease. Loss of membrane potential causes 60-kD protein to accumulate, suggesting that OMA1 is attenuated by proteolytic degradation. We conclude that a proteolytic cascade controls OPA1. Inducible cleavage provides a mechanism for quality control because proteolytic inactivation of OPA1 promotes selective removal of defective mitochondrial fragments by preventing their fusion with the mitochondrial network.     

Site-specific protein cleavage in vivo by an intein-derived protease

Site-specific protein cleavage is a ubiquitous process in cellular protein metabolism, yet molecular tools to provide control of protein cleavage inside living cells remain scarce. Here, we show that the C-terminal intein fragment of the non-canonical Ssp (Synechocystis sp. PCC6803) DnaB S1 split-intein can be used as a site-specific protease for in vivo protein cleavage both in bacterial and eukaryotic cells. Mutagenesis data indicate a broad tolerance of the intein-derived protease (IP) toward the amino acid upstream of the cleavage site. Furthermore, deletion studies reveal that the recognition sequence for the IP can be as short as ten amino acids. The structural features underlying the cleavage reaction preclude unintended proteolysis of endogenous proteins, thus ensuring that negative effects on cell viability are minimal.     

Bioluminescence detection of proteolytic bond cleavage by using recombinant aequorin

Detection of proteolytic bond cleavage was achieved by taking advantage of the bioluminescence emission generated by the photoprotein aequorin. A genetically engineered HIV-1 protease substrate was coupled with a cysteine-free mutant of aequorin by employing the polymerase chain reaction to produce a fusion protein that incorporates an optimum natural protease cleavage site. The fusion protein was immobilized on a solid phase and employed as the substrate for the HIV-1 protease. Proteolytic bond cleavage was detected by a decrease in the bioluminescence generated by the aequorin fusion protein on the solid phase. A dose-response curve for HIV-1 protease was constructed by relating the decrease in bioluminescence signal with varying amounts of the protease. The system was also used to evaluate two competitive and one noncompetitive inhibitor of the HIV-1 protease. Among the advantages of this assay is that by using recombinant methods a complete bioluminescently labeled protease recognition site can be designed and produced. The assay yields very sensitive detection limits, which are inherent to bioluminescence-based methods. An application of this system may be in the high-throughput screening of biopharmaceutical drugs that are potential inhibitors of a target protease.