Glutathione S-Transferase P1 Protects Against Amodiaquine Quinoneimines-Induced Cytotoxicity but Does Not Prevent Activation of Endoplasmic Reticulum Stress in HepG2 Cells.

Formation of the reactive amodiaquine quinoneimine (AQ-QI) and N-desethylamodiaquine quinoneimine (DEAQ-QI) plays an important role in the toxicity of the anti-malaria drug amodiaquine (AQ). Glutathione conjugation protects against AQ-induced toxicity and GSTP1 is able to conjugate its quinoneimine metabolites AQ-QI and DEA-QI with glutathione. In this study, HepG2 cells transiently transfected with the human GSTP1 construct were utilized to investigate the protective effect of GSTP1 in a cellular context. HepG2 cells were exposed to synthesized QIs, which bypasses the need for intracellular bioactivation of AQ or DEAQ. Exposure was accompanied by decreased cell viability, increased caspase 3 activity, and decreased intracellular GSH levels. Using high-content imaging-based BAC-GFP reporters, it was shown that AQ-QI and DEAQ-QI specifically activated the endoplasmic reticulum (ER) stress response. In contrast, oxidative stress, DNA damage, or inflammatory stress responses were not activated. Overexpression of GSTP1 resulted in a two-fold increase in GSH-conjugation of the QIs, attenuated QI-induced cytotoxicity especially under GSH-depletion condition, abolished QIs-induced apoptosis but did not significantly inhibit the activation of the ER stress response. In conclusion, these results indicate a protective role of GSTP1 by increasing enzymatic detoxification of AQ-QI and DEAQ-QI and suggest a second protective mechanism by interfering with ER stress induced apoptosis.

The major substrates for TAP in vivo are derived from newly synthesized proteins.

The transporter associated with antigen processing (TAP) is a member of the family of ABC transporters that translocate a large variety of substrates across membranes. TAP transports peptides from the cytosol into the endoplasmic reticulum for binding to MHC class I molecules and for subsequent presentation to the immune system. Here we follow the lateral mobility of TAP in living cells. TAP's mobility increases when it is inactive and decreases when it translocates peptides. Because TAP activity is dependent on substrate, the mobility of TAP is used to monitor the intracellular peptide content in vivo. Comparison of the diffusion rates in peptide-free and peptide-saturated cells indicates that normally about one-third of all TAP molecules actively translocate peptides. However, during an acute influenza infection TAP becomes fully employed owing to the production and degradation of viral proteins. Furthermore, TAP activity depends on continuing protein translation. This implies that MHC class I molecules mainly sample peptides that originate from newly synthesized proteins, to ensure rapid presentation to the immune system.

Head-head/tail-tail relative orientation of the pore-forming domains of the heterodimeric ABC transporter TAP.

BACKGROUND: The transporter associated with antigen processing (TAP) is a heterodimeric member of the large family of ABC transporters. The study of interactions between the subunits TAP1 and TAP2 can reveal the relative orientation of the transmembrane segments, which form a translocation pore for peptides. This is essential for understanding the architecture of TAP and other ABC transporters. RESULTS: The amino-terminal six transmembrane segments (TMs) of human TAP1, TAP1 (1-6), and the amino-terminal five TMs of TAP2, TAP2(1-5), are thought to constitute the pore of TAP. Two new approaches are used to define dimer interactions. We show that TM6 of TAP1 (1-6) is able to change topology post-translationally. This TM, along with a cytoplasmic tail, is translocated into the endoplasmic reticulum lumen, unless TAP2 is expressed. Coexpression of TM(4-5) of TAP2 stabilizes the topology of TAP1 (1-6), even when the TM1 of TAP1 is subsitituted with another sequence. This suggests that the carboxy-terminal TMs of the pore-forming domains TAP1 (1-6) and TAP2(1-5) interact. An alternative assay uses photobleaching in living cells using TAP1 (1-6) tagged with the green fluorescent protein (GFP). Coexpression with TAP2(1-5) results in reduced movement of the heterodimer within the endoplasmic reticulum membrane, as compared with the single TAP1 (1-6) molecule. In contrast, TAP2(1-4) has no effect on the mobility of TAP1 (1-6)-GFP, indicating the importance of TM5 of TAP2 for dimer formation. Also, TM1 of both TAP1 and TAP2 is essential for formation of a complex with low mobility. CONCLUSIONS: Dimerization of the pore-forming transmembrane domains of TAP1 (TM1-6) with its TAP2 counterpart (TM1-5) prevents the post-translational translocation of TM6 of TAP1 and results in a complex with reduced mobility within the endoplasmic reticulum membrane compared with the free subunit. These techniques are used to show that the pore-forming domains of TAP are aligned in a head-head/tail-tail orientation. This positions the following peptide-binding segments of the two TAP subunits to one side of the pore.

The final step in the formation of 25S rRNA in Saccharomyces cerevisiae is performed by 5'-->3' exonucleases.

The final stage in the formation of the two large subunit rRNA species in Saccharomyces cerevisiae is the removal of internal transcribed spacer 2 (ITS2) from the 27SB precursors. This removal is initiated by endonucleolytic cleavage approximately midway in ITS2. The resulting 7S pre-rRNA, which is easily detectable, is then converted into 5.8S rRNA by the concerted action of a number of 3'-->5' exonucleases, many of which are part of the exosome. So far the complementary precursor to 25S rRNA resulting from the initial cleavage in ITS2 has not been detected and the manner of its conversion into the mature species is unknown. Using various yeast strains that carry different combinations of wild-type and mutant alleles of the major 5'-->3' exonucleases Rat1p and Xrn1p, we now demonstrate the existence of a short-lived 25.5S pre-rRNA whose 5' end is located closely downstream of the previously mapped 3' end of 7S pre-rRNA. The 25.5S pre-rRNA is converted into mature 25S rRNA by rapid exonucleolytic trimming, predominantly carried out by Rat1p. In the absence of Rat1p, however, the removal of the ITS2 sequences from 25.5S pre-rRNA can also be performed by Xrn1p, albeit somewhat less efficiently.

Membrane topology and dimerization of the two subunits of the transporter associated with antigen processing reveal a three-domain structure.

Presentation of peptides derived from cytosolic and nuclear proteins by MHC class I molecules requires their translocation across the membrane of the endoplasmic reticulum (ER) by a specialized ABC (ATP-binding cassette) transporter, TAP. To investigate the topology of the heterodimeric TAP complex, we constructed a set of C-terminal deletions for the TAP1 and TAP2 subunits. We identified eight and seven transmembrane (TM) segments for TAP1 and TAP2, respectively. TAP1 has both its N and C terminus in the cytoplasm, whereas TAP2 has its N terminus in the lumen of the ER. A putative TM pore consists of TM1-6 of TAP1 and, by analogy, TM1-5 of TAP2. Multiple ER-retention signals are present within this region, of which we positively identified TM1 of both TAP subunits. The N-terminal domain containing TM1-6 of TAP1 is sufficient for dimerization with TAP2. A second, independent dimerization domain, located between the putative pore and the nucleotide-binding cassette, lies within the cytoplasmic peptide-binding domains, which are anchored to the membrane via TM doublets 7/8 and 6/7 of TAP1 and TAP2, respectively. We present a model in which TAP is composed of three subdomains: a TM pore, a cytoplasmic peptide-binding pocket, and a nucleotide-binding domain.

Transposase is the only nematode protein required for in vitro transposition of Tc1.

The Tc1 element of Caenorhabditis elegans is a member of the most widespread class of DNA transposons known in nature. Here, we describe efficient and precise transposition of Tc1 in a cell-free system. Tc1 appears to jump by a cut-and-paste mechanism of transposition. The terminal 26 bp of the Tc1 terminal repeats together with the flanking TA sequence are sufficient for transposition. The target site choice in vitro is similar to that in vivo. Transposition is achieved with an extract prepared from nuclei of transgenic nematodes that overexpress Tc1 transposase but also by recombinant transposase purified from Escherichia coli. The simple reaction requirements explain why horizontal spread of Tc1/mariner transposons can occur. They also suggest that Tcl may be a good vector for transgenesis of diverse animal species.

Tc1 transposase of Caenorhabditis elegans is an endonuclease with a bipartite DNA binding domain.

The Tc1 transposon of Caenorhabditis elegans is a member of the Tc1/mariner family of mobile elements. These elements have inverted terminal repeats that flank a single transposase gene. Here we show that Tc1 transposase, Tc1A, has a bipartite DNA binding domain related to the paired domain of mammalian and Drosophila genes. Both the DNA binding domain of Tc1A and the DNA binding site in the inverted repeat of Tc1 can be divided into two subdomains. Methylation interference studies demonstrate adjacent minor and major groove contacts at the inner part of the binding site by the N-terminal 68 amino acids of the DNA binding domain. In addition, Tc1A amino acids 69-142 are essential for major groove contacts at the outer part of the binding site. Recombinant Tc1A is found to be able to introduce a single strand nick at the 5' end of the transposon in vitro. Furthermore, Tc1A can mediate a phosphoryl transfer reaction. A mutation in a DDE motif abolishes both endonucleolytic and phosphoryl transfer activities, suggesting that Tc1A carries a catalytic core common to retroviral integrases and IS transposases.

Characterization of the Caenorhabditis elegans Tc1 transposase in vivo and in vitro.

We have investigated the function of the Tc1A gene of the mobile element Tc1 of Caenorhabditis elegans. Tc1 is a member of a family of transposons found in several animal phyla, such as nematodes, insects, and vertebrates. Two lines of evidence show that Tc1A encodes the transposase of Tc1. First, forced expression of the Tc1A protein in transgenic nematodes results in an enhanced level of transposition of endogenous Tc1 elements. Second, DNase I footprinting and gel retardation assays show that Tc1A binds specifically to the inverted repeats at the ends of the element and that the Tc1A recognition site is located between base pairs 5 and 26 from the ends of Tc1. Functional dissection of the transposase shows the presence of two distinct DNA-binding domains. A site-specific DNA-binding domain is contained within the amino-terminal 63 residues of Tc1A; this region shows sequence similarity to the prokaryotic IS30 transposase. A second, general DNA-binding domain is located between amino acids 71 and 207. Our results suggest that Tc1 is more similar to prokaryotic insertion elements than to eukaryotic transposons such as P elements in Drosophila or Ac and En-1 in plants.

In vitro recognition of an orf virus early promoter in a vaccinia virus extract.

DNA fragments containing varying lengths of the 5' end of an orf virus early gene (ORF3) and its associated promoter were introduced into sodium deoxycholate-solubilized vaccinia virus extracts capable of initiating transcription in vitro from vaccinia virus early promoters. After separation of the radiolabelled products of the reactions on a 5% polyacrylamide/7 M urea gel, discrete transcripts were detected the sizes of which were consistent with initiation of transcription from the orf virus early promoter. This is the first demonstration in a functional assay of the conservation of early transcriptional promoters between an orthopoxvirus and a parapoxvirus.

Vaccinia virus capping enzyme is a transcription initiation factor.

It has previously been demonstrated that vaccinia virus capping enzyme is involved both in the formation of a 5' cap structure and in termination of early transcription. Here we show that capping enzyme has an additional activity which is required for transcription of intermediate genes. VITF-A and VITF-B have been defined as two activities which together with RNA polymerase are necessary and sufficient to transcribe intermediate genes in vitro. VITF-A and the viral capping enzyme are shown to copurify to near homogeneity. Direct evidence that capping enzyme is VITF-A was obtained by complementation of a reconstituted transcription system with viral capping enzyme expressed in Escherichia coli. Although capping enzyme is a cofactor in early transcription termination, intermediate transcription is not terminated in response to the early termination signal. Capping enzyme is shown to form a complex with RNA polymerase in the absence of VITF-B. This appears to be a prerequisite for the formation of a stable initiation complex.

Promoter melting by a stage-specific vaccinia virus transcription factor is independent of the presence of RNA polymerase.

Fractionation of an extract prepared from HeLa cells infected with vaccinia virus resulted in the separation of factors involved in vaccinia virus intermediate transcription. Two activities, VITF-A and VITF-B, in addition to the viral RNA polymerase are necessary and sufficient to direct intermediate transcription in vitro. VITF-B confers intermediate promoter specificity to an early-specific extract prepared from virus particles. A committed complex between VITF-B and the template can sequester VITF-A and RNA polymerase into a pre-initiation complex. VITF-B is further able to melt the promoter at the start site of transcription. Open complex formation is stimulated by ATP. In contrast to prokaryotic and eukaryotic pol III transcription, promoter melting is independent of the presence of RNA polymerase.

Mutational analysis of a vaccinia virus intermediate promoter in vivo and in vitro.

The expression of the vaccinia virus intermediate I3 gene depends on trans-acting factors which are present in an active state prior to DNA replication. However, activation of transcription requires DNA replication in cis (J. C. Vos and H. G. Stunnenberg, EMBO J., 7:3487-3492, 1988). We have made deletion and linker scanner mutations of the I3 promoter to determine the sequence requirements for transcriptional activity and the dependence of DNA replication. The I3 promoter appears to consist of two elements which are essential and sufficient for accurate transcription initiation both in vivo and in vitro. An upstream and a downstream sequence element were defined ranging from -20 to -9 and +1 to +9, respectively. The upstream element appears to be highly homologous to a sequence in the intermediate I8 promoter. A 3-bp substitution in the upstream I3 promoter element resulted in a change of transcriptional specificity from intermediate to late. Finally, the mutations did not result in an activation of the intermediate promoter prior to DNA replication.

Derepression of a novel class of vaccinia virus genes upon DNA replication.

A novel class of vaccinia virus genes, called intermediate, is expressed immediately post-replication and prior to the onset of late gene transcription. Intermediate transcription is dependent on trans-acting factors which are present in an active state in virus-infected cells prior to the onset of DNA replication. Plasmid-borne intermediate genes transfected into vaccinia-virus infected cells are expressed prior to DNA replication, whereas the copies within the viral genome are repressed. DNA replication is essential for activation of viral intermediate transcription and de novo protein synthesis is not required post-replication. In contrast, activation of late transcription depends on DNA replication and continued de novo protein synthesis. Therefore, a subset of intermediate proteins is likely to be trans-activators of late gene transcription. Cell-free extracts differentially transcribe early, intermediate and late genes in a way similar to the temporal expression observed in vivo. A cascade model is discussed for the regulation of gene expression during the viral life-cycle.

Discontinuous transcription or RNA processing of vaccinia virus late messengers results in a 5' poly(A) leader.

We have demonstrated by primer elongation and cap analysis that mature vaccinia virus late transcripts are discontinuously synthesized. We have shown that RNA transcripts from a translocated 11K and from the authentic 11K and 4b late promoters are extended by approximately 35 nucleotides beyond the "start site" determined by S1 mapping using vaccinia genomic DNA as a probe. Sequencing of the RNA and of the first strand cDNA reveal that a homopolymeric poly(A) sequence is linked to the 5' terminus of the RNA transcripts. S1 mapping of RNA transcripts with a DNA probe containing an A-stretch, replacing promoter sequences upstream of position -1, confirms the existence of a poly(A) leader of approximately 35 A-residues.