Integrase mediates nuclear localization of Ty3.

Retroviruses in nondividing cells and yeast retrotransposons must transit the nuclear membrane in order for integration to occur. Mutations in a bipartite basic motif in the carboxyl-terminal domain of the Ty3 integrase (IN) protein were previously shown to block transposition at a step subsequent to 3'-end processing of Ty3 extrachromosomal DNA. In this work, the Ty3 IN was shown to be sufficient to target green fluorescent protein to the nucleolus. Mutations in the bipartite basic motif abrogated this localization. The region containing the motif was shown to be sufficient for nuclear but not subnuclear localization of a heterologous protein. Viruslike particles (VLPs) from cells expressing a Ty3 element defective for nuclear localization were inactive in an in vitro integration assay, suggesting that nuclear entry is required to form active VLPs or that this motif is required for post-nuclear entry steps. Ty3 inserts at transcription initiation sites of genomic tRNA genes and plasmid-borne 5S and U6 RNA genes transcribed by RNA polymerase III. In situ hybridization with Ty3- and Ty3 long terminal repeat-specific probes showed that these elements which are associated with tRNA genes do not colocalize with the ribosomal DNA (rDNA). However, a PCR assay of cells undergoing transposition showed that Ty3 insertion does occur into the 5S genes, which, in yeast, are interspersed with the rDNA and therefore, like Ty3 IN, associated with the nucleolus.

A truncation mutant of the 95-kilodalton subunit of transcription factor IIIC reveals asymmetry in Ty3 integration.

Position-specific integration of the retroviruslike element Ty3 near the transcription initiation sites of tRNA genes requires transcription factors IIIB and IIIC (TFIIIB and TFIIIC). Using a genetic screen, we isolated a mutant with a truncated 95-kDa subunit of TFIIIC (TFIIIC95) that reduced the apparent retrotransposition of Ty3 into a plasmid-borne target site between two divergently transcribed tRNA genes. Although TFIIIC95 is conserved and essential, no defect in growth or transcription of tRNAs was detected in the mutant. Steps of the Ty3 life cycle, such as protein expression, proteolytic processing, viruslike particle formation, and reverse transcription, were not affected by the mutation. However, Ty3 integration into a divergent tDNA target occurred exclusively in one orientation in the mutant strain. Investigation of this orientation bias showed that TFIIIC95 and Ty3 integrase interacted in two-hybrid and glutathione S-transferase pulldown assays and that interaction with the mutant TFIIIC95 protein was attenuated. The orientation bias observed here suggests that even for wild-type Ty3, the protein complexes associated with the long terminal repeats are not equivalent in vivo.

Ten-kilodalton domain in Ty3 Gag3-Pol3p between PR and RT is dispensable for Ty3 transposition.

Ty3 is a gypsy-type, retrovirus-like element found in the budding yeast Saccharomyces cerevisiae. In cells overexpressing Ty3 under the GAL1 upstream activation sequence, Ty3 RNA, proteins, and DNA are made. Elucidation of the molecular masses and amino-terminal sequences of protease and reverse transcriptase indicated the existence of an additional intervening domain, designated J, in the Ty3 Gag3-Pol3p polyprotein. A region analogous to J can be found in many retrotransposable elements closely related to Ty3; however, J does not correspond to any of the highly conserved retroviral protein domains. Ty3 mutants deleted for the J-coding region showed moderately reduced transposition frequency but greatly reduced levels of Ty3 DNA. These results show that under galactose regulation, the Ty3 J domain is not absolutely essential.

The Brf and TATA-binding protein subunits of the RNA polymerase III transcription factor IIIB mediate position-specific integration of the gypsy-like element, Ty3.

Ty3 integrates into the transcription initiation sites of genes transcribed by RNA polymerase III. It is known that transcription factors (TF) IIIB and IIIC are important for recruiting Ty3 to its sites of integration upstream of tRNA genes, but that RNA polymerase III is not required. In order to investigate the respective roles of TFIIIB and TFIIIC, we have developed an in vitro integration assay in which Ty3 is targeted to the U6 small nuclear RNA gene, SNR6. Because TFIIIB can bind to the TATA box upstream of the U6 gene through contacts mediated by TATA-binding protein (TBP), TFIIIC is dispensable for in vitro transcription. Thus, this system offers an opportunity to test the role of TFIIIB independent of a requirement of TFIIIC. We demonstrate that the recombinant Brf and TBP subunits of TFIIIB, which interact over the SNR6 TATA box, direct integration at the SNR6 transcription initiation site in the absence of detectable TFIIIC or TFIIIB subunit B". These findings suggest that the minimal requirements for pol III transcription and Ty3 integration are very similar.

Mutations in nonconserved domains of Ty3 integrase affect multiple stages of the Ty3 life cycle.

Ty3, a retroviruslike element of Saccharomyces cerevisiae, transposes into positions immediately upstream of RNA polymerase III-transcribed genes. The Ty3 integrase (IN) protein is required for integration of the replicated, extrachromosomal Ty3 DNA. In retroviral IN, a conserved core region is sufficient for strand transfer activity. In this study, charged-to-alanine scanning mutagenesis was used to investigate the roles of the nonconserved amino- and carboxyl-terminal regions of Ty3 IN. Each of the 20 IN mutants was defective for transposition, but no mutant was grossly defective for capsid maturation. All mutations affecting steady-state levels of mature IN protein resulted in reduced levels of replicated DNA, even when polymerase activity was not grossly defective as measured by exogenous reverse transcriptase activity assay. Thus, IN could contribute to nonpolymerase functions required for DNA production in vivo or to the stability of the DNA product. Several mutations in the carboxyl-terminal domain resulted in relatively low levels of processed 3' ends of the replicated DNA, suggesting that this domain may be important for binding of IN to the long terminal repeat. Another class of mutants produced wild-type amounts of DNA with correctly processed 3' ends. This class could include mutants affected in nuclear entry and target association. Collectively, these mutations demonstrate that in vivo, within the preintegration complex, IN performs a central role in coordinating multiple late stages of the retrotransposition life cycle.

A chimeric Ty3/Moloney murine leukemia virus integrase protein is active in vivo.

This report describes the results of experiments to determine whether chimeras between a retrovirus and portions of Ty3 are active in vivo. A chimera between Ty3 and a Neo(r)-marked Moloney murine leukemia virus (M-MuLV) was constructed. The C-terminal domain of M-MuLV integrase (IN) was replaced with the C-terminal domain of Ty3 IN. The chimeric retroviruses were expressed from an amphotrophic envelope packaging cell line. The virus generated was used to infect the human fibrosarcoma cell line HT1080, and cells in which integration had occurred were selected by G418 resistance. Three independently integrated viruses were rescued. In each case, the C-terminal Ty3 IN sequences were maintained and short direct repeats of the genomic DNA flanked the integration site. Sequence analysis of the genomic DNA flanking the insertion did not identify a tRNA gene; therefore, these integration events did not have Ty3 position specificity. This study showed that IN sequences from the yeast retrovirus-like element Ty3 can substitute for M-MuLV IN sequences in the C-terminal domain and contribute to IN function in vivo. It is also one of the first in vivo demonstrations of activity of a retrovirus encoding an integrase chimera. Studies of chimeras between IN species with distinctive integration patterns should complement previous work by expanding our understanding of the roles of nonconserved domains.

Integration of the yeast retrovirus-like element Ty3 upstream of a human tRNA gene expressed in yeast.

The retrovirus-like element Ty3 of Saccharomyces cerevisae integrates into the yeast genomic DNA in a position specific manner. Ty3 integrates within 1-2 base pairs of the site of transcription initiation by RNA polymerase III. The human tRNA(Lys)3 gene was used as a target for transposition in a plasmid-based assay to determine whether Ty3 integration can be targeted to a human tRNA gene. Each transposition event observed was adjacent to the site of initiation of transcription of the human tRNA gene. Therefore, heterologous tRNA genes can serve as targets for Ty3 in yeast. This is a first step toward development of a system for targeted integrations in heterologous organisms.

RNA polymerase III interferes with Ty3 integration.

Ty3, a gypsylike retrotransposon of budding yeast, integrates at the transcription initiation site of genes transcribed by RNA polymerase III (pol III). It was previously shown that integration in vitro requires intact promoter elements and the pol III transcription factors TFIIIB and TFIIIC. In order to test the effect of pol III on integration, increasing amounts of a pol III-containing fraction were added to Ty3 in vitro integration reactions. The pol III-containing fraction was inhibitory to integration. These results are consistent with a model where the Ty3 integration complex and pol III recognize similar features of the stable transcription complex and compete with each other for access to the transcription initiation site.

Ty3 integrase mutants defective in reverse transcription or 3'-end processing of extrachromosomal Ty3 DNA.

Ty3, a retroviruslike element in Saccharomyces cerevisiae, encodes an integrase (IN) which is essential for position-specific transposition. The Ty3 integrase contains the highly conserved His-Xaa(3-7)-His-Xaa(23-32)-Cys-Xaa(2)-Cys and Asp, Asp-Xaa(35)-Glu [D,D(35)E] motifs found in retroviral integrases. Mutations were introduced into the coding region for the Ty3 integrase to determine the effects in vivo of changes in conserved residues of the putative catalytic triad D,D(35)E and the nonconserved carboxyl-terminal region. Ty3 viruslike particles were found to be associated with significant amounts of linear DNA of the approximate size expected for a full-length reverse transcription product and with plus-strand strong-stop DNA. The full-length, preintegrative DNA has at each 3' end 2 bp that are removed prior to or during integration. Such 3'-end processing has not been observed for other retroviruslike elements. A mutation at either D-225 or E-261 of the Ty3 integrase blocked transposition and prevented processing of the 3' ends of Ty3 DNA in vivo, suggesting that the D,D(35)E region is part of the catalytic domain of Ty3 IN. Carboxyl-terminal deletions of integrase caused a dramatic reduction in the amount of Ty3 DNA in vivo and a decrease in reverse transcriptase activity in vitro but did not affect the apparent size or amount of the 55-kDa reverse transcriptase in viruslike particles. The 115-kDa viruslike particle protein, previously shown to react with antibodies to Ty3 integrase, was shown to be a reverse transcriptase-IN fusion protein. These results are consistent with a role for the integrase domain either in proper folding of reverse transcriptase or as part of a heterodimeric reverse transcriptase molecule.

Cellular stress inhibits transposition of the yeast retrovirus-like element Ty3 by a ubiquitin-dependent block of virus-like particle formation.

Many stress proteins and their cognates function as molecular chaperones or as components of proteolytic systems. Viral infection can stimulate synthesis of stress proteins and particular associations of viral and stress proteins have been documented. However, demonstrations of functions for stress proteins in viral life cycles are few. We have initiated an investigation of the roles of stress proteins in eukaryotic viral life cycles using as a model the Ty3 retrovirus-like element of Saccharomyces cerevisiae. During stress, Ty3 transposition is inhibited; Ty3 DNA is not synthesized and, although precursor proteins are detected, mature Ty3 proteins and virus-like particles (VLPs) do not accumulate. The same phenotype is observed in the constitutively stressed ssa1 ssa2 mutant, which lacks two cytoplasmic members of the hsp70 family of chaperones. Ty3 VLPs preformed under nonstress conditions are degraded more rapidly if cells are shifted from 30 degrees C to 37 degrees C. These results suggest that Ty3 VLPs are destroyed by cellular stress proteins. Elevated expression of the yeast UBP3 gene, which encodes a protease that removes ubiquitin from proteins, allows mature Ty3 proteins and VLPs to accumulate in the ssa1 ssa2 mutant, suggesting that, at least under stress conditions, ubiquitination plays a role in regulating Ty3 transposition.

Requirement of RNA polymerase III transcription factors for in vitro position-specific integration of a retroviruslike element.

The yeast retroviruslike element Ty3 inserts at the transcription initiation sites of genes transcribed by RNA polymerase III (Pol III). An in vitro integration assay was developed with the use of Ty3 viruslike particles and a modified SUP2 tyrosine transfer RNA (tRNA(Tyr)) gene target. Integration was position-specific and required Ty3 integrase, Pol III transcription factor (TF) IIIB-, TFIIIC-, and Pol III-containing fractions showed that TFIIIB and TFIIIC, together, were sufficient for position-specific Ty3 integration, but not for transcription. This report demonstrates that in vitro integration of a retroelement can be targeted by cellular proteins.

Ty3 transposes in mating populations of yeast: a novel transposition assay for Ty3.

Ty3 is a retrotransposon of Saccharomyces cerevisiae that integrates just upstream of the transcription initiation site of genes transcribed by RNA polymerase III. Ty3 transcription is pheromone-inducible in haploid cells and is mating-type regulated in diploid cells. The specificity of Ty3 integration was exploited in the design of a novel target into which transposition of Ty3 elements could be selected. The target plasmid contains divergently oriented tRNA genes with 19 base pairs separating the two tRNA gene coding sequences. An inactive ochre suppressor tRNA(Tyr) gene with a modified transcription initiation region was used as the selectable marker and a tRNA(Val) (AAC) gene was used to direct Ty3 integration into the transcription initiation region of the suppressor tRNA(Tyr) gene. Integration of Ty3 activated expression of the suppressor tRNA gene, which resulted in suppression of ochre nonsense alleles ade2-101(0) and lys2-1(0) and allowed cell growth on selective medium. Based on the activity of this target, Ty3, under control of a galactose-inducible promoter and present on a high copy-number plasmid, was estimated to transpose into the genome at a rate of 5.6 x 10(-3) per cell division. We show here that induction of Ty3 transcription from its natural promoter results in transposition. Ty3 elements in strains of the a or alpha mating-type transposed efficiently to target plasmids in cells of the opposite mating-type. Thus, natural transposition of Ty3 is regulated temporally to occur in mating populations.

Transposition of the yeast retroviruslike element Ty3 is dependent on the cell cycle.

Host cell cycle genes provide important functions to retroviruses and retroviruslike elements. To define some of these functions, the cell cycle dependence of transposition of the yeast retroviruslike element Ty3 was examined. Ty3 is unique among retroviruslike elements because of the specificity of its integration, which occurs upstream of genes transcribed by RNA polymerase III. A physical assay for Ty3 transposition which takes advantage of this position-specific integration was developed. The assay uses PCR to amplify a product of Ty3 integration into a target plasmid that carries a modified tRNA gene. By using the GAL1 upstream activating sequence to regulate expression of Ty3, transposition was detected within one generation of cell growth after Ty3 transcription was initiated. This physical assay was used to show that Ty3 did not transpose when yeast cells were arrested in G1 during treatment with the mating pheromone alpha-factor. The restriction of transposition was not due to changes in transcription of either Ty3 or tRNA genes or to aspects of the mating pheromone response unrelated to cell cycle arrest. The block of the Ty3 life cycle was reversed when cells were released from G1 arrest. Examination of Ty3 intermediates during G1 arrest indicated that Ty3 viruslike particles were present but that reverse transcription of the Ty3 genomic RNA into double-stranded DNA had not occurred. In G1, the Ty3 life cycle is blocked after particle assembly but before the completion of reverse transcription.

The Cys-His motif of Ty3 NC can be contributed by Gag3 or Gag3-Pol3 polyproteins.

The major structural proteins capsid and nucleocapsid (NC) of the Saccharomyces cerevisiae retroviruslike element Ty3 are produced as domains within the Gag3 and Gag3-Pol3 precursor polyproteins. Ty3 NC contains one copy of the conserved motif CX2CX4HX4C found in most retroviral NC proteins. We show here that NC proteins derived by processing of these different precursor species differ at their carboxyl termini. To determine whether the Cys-His motifs of these nascent NC domains contribute differently to replication, Gag3 and Gag3-Pol3 fusion proteins containing wild-type or mutant Cys-His domains were expressed from separate constructs. Although the Cys-His box was shown to be essential for polyprotein processing of a wild-type Ty3 element, this domain could be contributed from Gag3 or as part of Gag3-Pol3. These data suggest that the functions of the retroviral NC Cys-His domain contributed from Gag and Gag-Pol are redundant.

Positive and negative regulatory elements control expression of the yeast retrotransposon Ty3.

We report the results of an analysis of Ty3 transcription and identification of Ty3 regions that mediate pheromone and mating-type regulation to coordinate its expression with the yeast life cycle. A set of strains was constructed which was isogenic except for the number of Ty3 elements, which varied from zero to three. Analysis of Ty3 expression in these strains showed that each of the three elements was transcribed and that each element was regulated. Dissection of the long terminal repeat regulatory region by Northern blot analysis of deletion mutants and reporter gene analysis showed that the upstream junction of Ty3 with flanking chromosomal sequences contained a negative control region. A 19-bp fragment (positions 56-74) containing one consensus copy and one 7 of 8-bp match to the pheromone response element (PRE) consensus was sufficient to mediate pheromone induction in either haploid cell type. Deletion of this region, however, did not abolish expression, indicating that other sequences also activate transcription. A 24-bp block immediately downstream of the PRE region contained a sequence similar to the a1-alpha 2 consensus that conferred mating-type control. A single base pair mutation in the region separating the PRE and a1-alpha 2 sequences blocked pheromone induction, but not mating-type control. Thus, the long terminal repeat of Ty3 is a compact, highly regulated, mobile promoter which is responsive to cell type and mating.

Sites of RNA polymerase III transcription initiation and Ty3 integration at the U6 gene are positioned by the TATA box.

The function of a TATA element in RNA polymerase (EC 2.7.7.6) III transcription of a naturally TATA-containing U6 snRNA gene and a naturally TATA-less tRNA gene was probed by transcription and Ty3 transposition analyses. Deletion of the TATA box from a U6 minigene did not abolish transcription and Ty3 integration but changed the positions of initiation and insertion. Insertion of the U6 TATA box at three positions upstream of the TATA-less SUP2 tRNA(Tyr) gene resulted in novel transcription initiation and Ty3 integration patterns that depended upon position of the insertion. Nevertheless, the predominant tRNA gene initiation sites were not affected by insertion of the TATA sequence and remained at a fixed distance from the internal box A promoter element. Insertions of the TATA box upstream of a SUP2 box A mutant affected the level of transcription and restricted the use of upstream start sites, but they neither enhanced the use of TATA-dependent initiation sites nor restored expression to the level of the wild-type gene. We conclude that (i) the U6 TATA box is essential in vivo for correct initiation but not for transcription, (ii) a TATA box does not compensate for a weak box A sequence and so cannot perform equivalently, and (iii) the TATA-binding protein, and probably components of transcription factor IIIB, are present on the target at the time of Ty3 integration.

Yeast retrotransposons.

In the decade since Ty elements were discovered, advocates have argued they could be used as a genetic entrée to elusive host-type functions required by retroviruses. However, the advent of the polymerase chain reaction, coupled with a boom in funding for human immunodeficiency virus research have moved retroviral research apace, raising questions as to whether novel contributions would be realized. The past year, with the implication of the cell cycle and specific host proteins, such as the debranching enzyme and transcription initiation factors, in Ty retrotransposition has provided a positive answer and raised new questions.

Transposition of a Ty3 GAG3-POL3 fusion mutant is limited by availability of capsid protein.

Ty3 encodes structural proteins in its upstream open reading frame (GAG3) and catalytic proteins in an overlapping open reading frame (POL3). As is the case for retroviruses, high levels of structural protein versus catalytic proteins are synthesized and we show here that catalytic proteins are derived from a GAG3-POL3 fusion polyprotein. To evaluate the relative contributions of structural and catalytic components of the Ty3 particle, we perturbed the balance of these proteins by fusing the GAG3 and POL3 frames. This fusion Ty3 was capable of complementing low levels of transposition of a donor Ty3 which contained only cis-acting sequences required for transposition. Examination of extracts of cells expressing the GAG3-POL3 fusion mutant showed that particle formation differed qualitatively and quantitatively from viruslike particle formation by wild-type Ty3. Suprisingly, expression of 238 codons of GAG3, encoding only capsid protein, complemented transposition and particle formation defects of the fusion mutant, showing that the limiting deficiency was in capsid, and not in nucleocapsid, function. In addition, protein containing the capsid domain expressed alone accumulated in the same particulate fraction as viruslike particles, showing that it was sufficient for particle formation. The activity of the Ty3 fusion mutant contrasts with the inviability of mutant retroviruses in which gag and pol frames were fused and argues that retrotransposons tolerate considerable variation in the nucleoprotein complexes that permit replication and integration.