N2,N2-dimethylguanosine-specific tRNA methyltransferase contains both nuclear and mitochondrial targeting signals in Saccharomyces cerevisiae

The TRM1 gene of Saccharomyces cerevisiae encodes a tRNA modification enzyme, N2,N2-dimethylguanosine-specific tRNA methyltransferase, which modifies both mitochondrial and cytoplasmic tRNAs. The enzyme is targeted to mitochondria for the modification of mitochondrial tRNAs. Cellular fractionation and indirect immunofluorescence studies reported here demonstrate that this enzyme is also localized to the nucleus. Further, immunofluorescence experiments using strains that overproduce the enzyme show a staining at the periphery of the nucleus suggesting that the enzyme is found in a subnuclear destination near or at the nuclear membrane. There is no obvious cytoplasmic staining in these overproducing strains. Fusion protein technology was used to begin to localize sequences involved in the nuclear targeting of this enzyme. Indirect immunofluorescence studies indicate that sequences between the first 70 and 213 NH2-terminal amino acids of the methyltransferase are sufficient to target Escherichia coli beta-galactosidase to nuclei.     

Mechanism and a Peptide Motif for Targeting Peripheral Proteins to the Yeast Inner Nuclear Membrane

Trm1 is a tRNA specific m₂²G methyltransferase shared by nuclei and mitochondria in Saccharomyces cerevisiae . In nuclei, Trm1 is peripherally associated with the inner nuclear membrane (INM). We investigated the mechanism delivering/tethering Trm1 to the INM. Analyses of mutations of the Ran pathway and nuclear pore components showed that Trm1 accesses the nucleoplasm via the classical nuclear import pathway. We identified a Trm1 cis-acting sequence sufficient to target passenger proteins to the INM. Detailed mutagenesis of this region uncovered specific amino acids necessary for authentic Trm1 to locate at the INM. The INM information is contained within a sequence of less than 20 amino acids, defining the first motif for addressing a peripheral protein to this important subnuclear location. The combined studies provide a multi-step process to direct Trm1 to the INM: (i) translation in the cytoplasm; (ii) Ran-dependent import into the nucleoplasm; and (iii) redistribution from the nucleoplasm to the INM via the INM motif. Furthermore, we demonstrate that the Trm1 mitochondrial targeting and nuclear localization signals are in competition with each other, as Trm1 becomes mitochondrial if prevented from entering the nucleus.     

Amino-terminal extension generated from an upstream AUG codon increases the efficiency of mitochondrial import of yeast N2,N2-dimethylguanosine-specific tRNA methyltransferases.

Fusions between the TRM1 gene of Saccharomyces cerevisiae and COXIV or DHFR were made to examine the mitochondrial targeting signals of N2,N2-dimethylguanosine-specific tRNA methyltransferase [tRNA (m2(2)G)dimethyltransferase]. This enzyme is responsible for the modification of both mitochondrial and cytoplasmic tRNAs. We have previously shown that two forms of the enzyme are translated from two in-frame ATGs in this gene, that they differ by a 16-amino-acid amino-terminal extension, and that both the long and short forms are imported into mitochondria. Results of studies to test the ability of various TRM1 sequences to serve as surrogate mitochondrial targeting signals for passenger protein import in vitro and in vivo showed that the most efficient signal derived from tRNA (m2(2)G)dimethyltransferase included a combination of sequences from both the amino-terminal extension and the amino terminus of the shorter form of the enzyme. The amino-terminal extension itself did not serve as an independent mitochondrial targeting signal, whereas the amino terminus of the shorter form of tRNA (m2(2)G)dimethyltransferase did function in this regard, albeit inefficiently. We analyzed the first 48 amino acids of tRNA (m2(2)G)dimethyltransferase for elements of primary and secondary structure shared with other known mitochondrial targeting signals. The results lead us to propose that the most efficient signal spans the area around the second ATG of TRM1 and is consistent with the idea that there is a mitochondrial targeting signal present at the amino terminus of the shorter form of the enzyme and that the amino-terminal extension augments this signal by extending it to form a larger, more efficient mitochondrial targeting signal.     

Subcellular locations of MOD5 proteins: mapping of sequences sufficient for targeting to mitochondria and demonstration that mitochondrial and nuclear isoforms commingle in the cytosol.

MOD5, a gene responsible for the modification of A37 to isopentenyl A37 of both cytosolic and mitochondrial tRNAs, encodes two isozymes. Initiation of translation at the first AUG of the MOD5 open reading frame generates delta 2-isopentenyl pyrophosphate:tRNA isopentanyl transferase I (IPPT-I), which is located predominantly, but not exclusively, in the mitochondria. Initiation of translation at a second AUG generates IPPT-II, which modifies cytoplasmic tRNA. IPPT-II is unable to target to mitochondria. The N-terminal sequence present in IPPT-I and absent in IPPT-II is therefore necessary for mitochondrial targeting. In these studies, we fused MOD5 sequences encoding N-terminal regions to genes encoding passenger proteins, pseudomature COXIV and dihydrofolate reductase, and studied the ability of these chimeric proteins to be imported into mitochondria both in vivo and in vitro. We found that the sequences necessary for mitochondrial import, amino acids 1 to 11, are not sufficient for efficient mitochondrial targeting and that at least some of the amino acids shared by IPPT-I and IPPT-II comprise part of the mitochondrial targeting information. We used indirect immunofluorescence and cell fractionation to locate the MOD5 isozymes in yeast. IPPT-I was found in two subcellular compartments: mitochondria and the cytosol. We also found that IPPT-II had two subcellular locations: nuclei and the cytosol. The nuclear location of this protein is surprising because the A37-->isopentenyl A37 modification had been predicted to occur in the cytoplasm. MOD5 is one of the first genes reported to encode isozymes found in three subcellular compartments.     

Simian immunodeficiency virus Vpx is imported into the nucleus via importin alpha-dependent and -independent pathways

Vpx protein of human immunodeficiency virus type 2/simian immunodeficiency virus (SIV) has been implicated in the transport of the viral genome into the nuclei of nondividing cells. The mechanism by which Vpx enters the nucleus remains unknown. Here we have identified two distinct noncanonical nuclear localization signals (NLSs) in Vpx of SIV(smPbj1.9) and defined the pathways for its nuclear import. Although nuclear targeting signals identified here are distinct from known nuclear import signals, translocation of Vpx into the nucleus involves the interaction of its N-terminal NLS (amino acids 20 to 40) or C-terminal NLS (amino acids 65 to 75) with importin alpha and, in the latter case, also with importin beta. Collectively, these results suggest that importins interact with Vpx and ensure the effective import of Vpx into the nucleus to support virus replication in nondividing cells.     

Adaptations required for mitochondrial import following mitochondrial to nucleus gene transfer of ribosomal protein S10

The minimal requirements to support protein import into mitochondria were investigated in the context of the phenomenon of ongoing gene transfer from the mitochondrion to the nucleus in plants. Ribosomal protein 10 of the small subunit is encoded in the mitochondrion in soybean and many other angiosperms, whereas in several other species it is nuclear encoded and thus must be imported into the mitochondrial matrix to function. When encoded by the nuclear genome, it has adopted different strategies for mitochondrial targeting and import. In lettuce (Lactuca sativa) and carrot (Daucus carota), Rps10 independently gained different N-terminal extensions from other genes, following transfer to the nucleus. (The designation of Rps10 follows the following convention. The gene is indicated in italics. If encoded in the mitochondrion, it is rps10; if encoded in the nucleus, it is Rps10.) Here, we show that the N-terminal extensions of Rps10 in lettuce and carrot are both essential for mitochondrial import. In maize (Zea mays), Rps10 has not acquired an extension upon transfer but can be readily imported into mitochondria. Deletion analysis located the mitochondrial targeting region to the first 20 amino acids. Using site directed mutagenesis, we changed residues in the first 20 amino acids of the mitochondrial encoded soybean (Glycine max) rps10 to the corresponding amino acids in the nuclear encoded maize Rps10 until import was achieved. Changes were required that altered charge, hydrophobicity, predicted ability to form an amphipathic alpha-helix, and generation of a binding motif for the outer mitochondrial membrane receptor, translocase of the outer membrane 20. In addition to defining the changes required to achieve mitochondrial localization, the results demonstrate that even proteins that do not present barriers to import can require substantial changes to acquire a mitochondrial targeting signal.     

The basic domain of plant B-ZIP proteins facilitates import of a reporter protein into plant nuclei.

The import of large molecules into the nucleus is an active process that requires the presence in cis of a nuclear localization signal (NLS). Although these signals have been well characterized in mammalian, yeast, and amphibian nuclear proteins, no plant NLS has yet been described. The NLSs identified so far generally contain clusters of basic amino acids. This characteristic feature prompted us to test several basic domains from the plant DNA-binding proteins TGA-1A and TGA-1B and the TATA box-binding protein TFIID for nuclear targeting function. When tested as N-terminal fusions to the beta-glucuronidase protein, only those constructs containing the DNA binding (basic) domain of the basic-zipper (B-ZIP) region of TGA-1A or TGA-1B conferred nuclear import. These results suggest a close association or overlap of the DNA binding and nuclear targeting domains of B-ZIP proteins. We also demonstrated that a wild-type but not a mutant simian virus 40 large T-antigen NLS facilitates import into plant nuclei, indicating a strong conservation between nuclear import mechanisms in animals and plants.     

Characterization of Arabidopsis enhanced disease susceptibility mutants that are affected in systemically induced resistance

The evolutionarily recent transfer of the gene for cytochrome c oxidase subunit 2 (cox2) from the mitochondrion to the nucleus in legumes is shown to have involved novel gene-activation steps. The acquired mitochondrial targeting presequence is bordered by two introns. Characterization of the import of soybean Cox2 indicates that the presequence is cleaved in a three-step process which is independent of assembly. The final processing step takes place only in the mitochondria of legume species, and not in several non-legume plants. The unusually long presequence of 136 amino acids consists of three regions: the first 20 amino acids are required for mitochondrial targeting and can be replaced by another presequence; the central portion of the presequence is required for efficient import of the Cox2 protein into mitochondria; and the last 12 amino acids, derived from the mitochondrially encoded protein, are required for correct maturation of the imported protein. The acquisition of a unique presequence, and the capacity for legume mitochondria to remove this presequence post-import, are considered to be essential adaptations for targeting of Cox2 to the mitochondrion and therefore activation of the transferred gene in the nucleus.     

Phosphorylation mediates the nuclear targeting of the maize Rab17 protein

The maize abscisic acid-responsive Rab17 protein localizes to the nucleus and cytoplasm in maize cells. In-frame fusion of Rab17 to the reporter protein β-glucuronidase (GUS) directed GUS to the nucleus and cytoplasm in transgenic Arabidopsis thaliana and in transiently transformed onion cells. Analysis of chimeric constructs identified one region between amino acid positions 66–96, which was necessary for targeting GUS to the nucleus. This region contains a serine cluster followed by a putative consensus site for protein kinase CK2 phosphorylation, and a stretch of basic amino acids resembling the simian virus 40 large T antigen-type nuclear localization signal (NLS). Mutation of two basic amino acids in the putative NLS had a weak effect on nuclear targeting in the onion cell system and did not modify the percentage of nuclear fusion protein in the Arabidopsis cells. The mutation of three amino acids in the consensus site for CK2 recognition resulted in the absence of in vitro phosphorylated forms of Rab17 and in a strong decrease of GUS enzymatic activity in isolated nuclei of transgenic Arabidopsis. These results suggest that phosphorylation of Rab17 by protein kinase CK2 is the relevant step for its nuclear location, either by facilitating binding to specific proteins or as a direct part of the nuclear targeting apparatus.     

A non-canonical transferable signal mediates nuclear import of simian immunodeficiency virus Vpx protein

Protein transport into the nucleus is generally considered to involve specific nuclear localization signals (NLS) though it is becoming increasingly evident that efficient and well controlled import of proteins which lack a canonical NLS also occurs in cells. Vpx, a 112 amino acid protein from human immunodeficiency virus type 2 (HIV-2) and the closely related simian immunodeficiency virus (SIV) is one such protein, which does not have an identifiable canonical NLS and is yet efficiently imported to the nuclear compartment. Here we report that Vpx protein is imported to the nucleus independently of virus-encoded cofactors. When fusions of truncated versions of Vpx with full-length beta-galactosidase (beta-Gal) were tested, the region from Vpx 61 to 80 was found to be sufficient to mediate the import of the heterologous cytoplasmic protein to the nucleus. Inactivation of Vpx NLS precluded nuclear import of Vpx and reduced virus replication in non-dividing macrophage cultures, even when functional integrase and Gag matrix proteins implicated in viral nuclear import were present. Importantly, we identified and characterized a novel type of 20 amino acid transferable nuclear import signal in Vpx that is distinct from other import signals described. In addition, we show that the minimal nuclear targeting domain identified here overlaps with helical domain III (amino acid (aa) 64-82) and the structural integrity of this helical motif is critical for the nuclear import of Vpx. Taken together, these data suggest that Vpx is imported to the nucleus via a novel import pathway that is dependent on its 20 amino acid unique nuclear targeting signal, and that the nuclear import property of Vpx is critical for the optimal virus replication in non-dividing cells such as macrophages.     

Transport of DNA into the nuclei of xenopus oocytes by a modified VirE2 protein of Agrobacterium.

We used Agrobacterium T-DNA nuclear transport to examine the specificity of nuclear targeting between plants and animals and the nuclear import of DNA by a specialized transport protein. Two karyophilic Agrobacterium virulence (Vir) proteins, VirD2 and VirE2, which presumably associate with the transported T-DNA and function in many plant species, were microinjected into Drosophila embryos and Xenopus oocytes. In both animal systems, VirD2 localized to the cell nuclei and VirE2 remained exclusively cytoplasmic, suggesting that VirE2 nuclear localization signals may be plant specific. Repositioning one amino acid residue within VirE2 nuclear localization signals enabled them to function in animal cells. The modified VirE2 protein bound DNA and actively transported it into the nuclei of Xenopus oocytes. These observations suggest a functional difference in nuclear import between animals and plants and show that DNA can be transported into the cell nucleus via a protein-specific pathway.     

Nucleus-targeting domain of the matrix protein (M1) of influenza virus.

The matrix protein M1 of influenza virus A/WSN/33 was shown by immunofluorescent staining to be transported into the nuclei of transfected cells without requiring other viral proteins. We postulated the existence of a potential signal sequence at amino acids 101 to 105 (RKLKR) that is required for nuclear localization of the M1 protein. When CV1 cells were transfected with recombinant vectors expressing the entire M1 protein (amino acids 1 to 252) or just the first 112 N-terminal amino acids, both the complete M1 protein and the truncated M1 protein were transported to the nucleus. In contrast, expression in CV1 cells of vectors coding for M1 proteins with deletions from amino acids 77 to 202 or amino acids 1 to 134 resulted only in cytoplasmic immunofluorescent staining of these truncated M1 proteins without protein being transported to the nucleus. Moreover, no nuclear membrane translocation occurred when CV1 cells were transfected with recombinant vectors expressing M1 proteins with deletions of amino acids 101 to 105 or with substitution at amino acids 101 to 105 of SNLNS for RKLKR. Furthermore, a synthetic oligopeptide corresponding to M1 protein amino acids 90 to 108 was also transported into isolated nuclei derived from CV1 cells, whereas oligopeptides corresponding to amino acid sequences 25 to 40, 67 to 81, and 135 to 164 were not transported into the isolated cell nuclei. These data suggest that the amino acid sequence 101RKLKR105 is the nuclear localization signal of the M1 protein.     

DNA import into mitochondria

In recent decades, it has become evident that the condition for normal functioning of mitochondria in higher eukaryotes is the presence of membrane transport systems of macromolecules (proteins and nucleic acids). Natural competence of the mitochondria in plants, animals, and yeasts to actively uptake DNA may be directly related to horizontal gene transfer into these organelles occurring at much higher rate compared to the nuclear and chloroplast genomes. However, in contrast with import of proteins and tRNAs, little is known about the biological role and molecular mechanism underlying import of DNA into eukaryotic mitochondria. In this review, we discuss current state of investigations in this area, particularly specificity of DNA import into mitochondria and its features in plants, animals, and yeasts; a tentative mechanism of DNA import across the mitochondrial outer and inner membranes; experimental data evidencing several existing, but not yet fully understood mechanisms of DNA transfer into mitochondria. Currently available data regarding transport of informational macromolecules (DNA, RNA, and proteins) into the mitochondria do not rule out that the mechanism of protein and tRNA import as well as tRNA and DNA import into the mitochondria may partially overlap.     

Nuclear and nucleolar targeting sequences of c-erb-A, c-myb, N-myc, p53, HSP70, and HIV tat proteins

Protein import into the cell nucleus requires specific binding of nuclear proteins to the nuclear pore complex. Based on amino acid sequence "motifs" of known nuclear targeting signals, we identified peptides within a number of nuclear proteins with likely nuclear targeting potential and tested their function by transfecting into cells fusion genes that produce the cytoplasmic "reporter" protein, pyruvate kinase (PK), joined to the test sequence. Sequences within c-myb (PLLKKIKQ), N-myc (PPQKKIKS), p53 (PQPKKKP), and c-erb-A (SKRVAKRKL) oncoproteins that direct PK hybrids into the nucleus were identified. A peptide (GRKKRRQRRRAP) of the human immunodeficiency virus (HIV) tat protein (Tat), which contains two short basic regions, targets fusion proteins to the nucleolus. The COOH-terminal basic Tat region (QRRRAP) does not target PK hybrid proteins into the nucleus, but mutation of two basic amino acids in this region decreases but does not abolish nucleolar accumulation mediated by the entire Tat nucleolar targeting sequence. Moreover, the c-Myc nuclear targeting sequence fused to the COOH-terminal basic Tat region (PAAKRVKLDQRRRAP) effectively localizes PK hybrids to the nucleus and nucleolus. A similar sequence (FKRKHKKDISQNKRAVRR) in the human heat-shock protein HSP70 also localizes PK to the nucleus and nucleolus.     

The amino terminus of the yeast F1-ATPase beta-subunit precursor functions as a mitochondrial import signal

The ATP2 gene of Saccharomyces cerevisiae codes for the cytoplasmically synthesized beta-subunit protein of the mitochondrial F1-ATPase. To define the amino acid sequence determinants necessary for the in vivo targeting and import of this protein into mitochondria, we have constructed gene fusions between the ATP2 gene and either the Escherichia coli lacZ gene or the S. cerevisiae SUC2 gene (which codes for invertase). The ATP2-lacZ and ATP2-SUC2 gene fusions code for hybrid proteins that are efficiently targeted to yeast mitochondria in vivo. The mitochondrially associated hybrid proteins fractionate with the inner mitochondrial membrane and are resistant to proteinase digestion in the isolated organelle. Results obtained with the gene fusions and with targeting-defective ATP2 deletion mutants provide evidence that the amino-terminal 27 amino acids of the beta-subunit protein precursor are sufficient to direct both specific sorting of this protein to yeast mitochondria and its import into the organelle. Also, we have observed that certain of the mitochondrially associated Atp2-LacZ and Atp2-Suc2 hybrid proteins confer a novel respiration-defective phenotype to yeast cells.     

The nucleus as the site of tRNA methylation

Mouse L-cells were enucleated by exposure to cytochalasin B followed by centrifugation. The resulting karyoplasts, nuclei surrounded by a thin shell of cytoplasm and an outer cell membrane, and cytoplasts, the enucleated cell cytoplasm, were assayed for tRNA methyltransferase activity. The bulk of the enzyme activity was found to be localized in the nuclei. Analysis of the methylated nucleosides produced by the enzyme from the two sources showed that all the base-specific enzyme activities which are found in whole cell extracts were present in the nuclear extracts. The cytoplast extracts retained a low but detectable enzyme activity, which was composed predominantly of only two base-specific activities. This may represent tRNA methyltransferases of the mitochondria or may be cytoplasmic enzymes for late modification reactions.     

Yeast mitochondrial initiator tRNA is methylated at guanosine 37 by the Trm5-encoded tRNA (guanine-N1-)-methyltransferase

The TRM5 gene encodes a tRNA (guanine-N1-)-methyltransferase (Trm5p) that methylates guanosine at position 37 (m(1)G37) in cytoplasmic tRNAs in Saccharomyces cerevisiae. Here we show that Trm5p is also responsible for m(1)G37 methylation of mitochondrial tRNAs. The TRM5 open reading frame encodes 499 amino acids containing four potential initiator codons within the first 48 codons. Full-length Trm5p, purified as a fusion protein with maltose-binding protein, exhibited robust methyltransferase activity with tRNA isolated from a Delta trm5 mutant strain, as well as with a synthetic mitochondrial initiator tRNA (tRNA(Met)(f)). Primer extension demonstrated that the site of methylation was guanosine 37 in both mitochondrial tRNA(Met)(f) and tRNA(Phe). High pressure liquid chromatography analysis showed the methylated product to be m(1)G. Subcellular fractionation and immunoblotting of a strain expressing a green fluorescent protein-tagged version of the TRM5 gene revealed that the enzyme was localized to both cytoplasm and mitochondria. The slightly larger mitochondrial form was protected from protease digestion, indicating a matrix localization. Analysis of N-terminal truncation mutants revealed that a Trm5p active in the cytoplasm could be obtained with a construct lacking amino acids 1-33 (Delta1-33), whereas production of a Trm5p active in the mitochondria required these first 33 amino acids. Yeast expressing the Delta1-33 construct exhibited a significantly lower rate of oxygen consumption, indicating that efficiency or accuracy of mitochondrial protein synthesis is decreased in cells lacking m(1)G37 methylation of mitochondrial tRNAs. These data suggest that this tRNA modification plays an important role in reading frame maintenance in mitochondrial protein synthesis.