Function of two discrete regions is required for nuclear localization of polymerase basic protein 1 of A/WSN/33 influenza virus (H1 N1).

Polymerase basic protein 1 (PB1) of influenza virus (A/WSN/33), when expressed from cloned cDNA in the absence of other viral proteins, accumulates in the nucleus. We have examined the location and nature of the nuclear localization signal of PB1 by using deletion mutants and chimeric constructions with chicken muscle pyruvate kinase, a cytoplasmic protein. Our studies showed some novel features of the nuclear localization signal of PB1. The signal was present internally within residues 180 to 252 of PB1. Moreover, unlike most nuclear localization signals, it was not a single stretch of contiguous amino acids. Instead, it possessed two discontinuous regions separated by an intervening sequence which could be deleted without affecting its nuclear localization property. On the other hand, deletion of either of the two signal regions rendered the protein cytoplasmic, indicating that the function of both regions is required for nuclear localization and that one region alone is not sufficient. Both of these signal regions contained short stretches of basic residues. Possible ways by which this novel bipartite signal can function in nuclear localization are discussed.     

Basic residues of the helix six domain of influenza virus M1 involved in nuclear translocation of M1 can be replaced by PTAP and YPDL late assembly domain motifs

Influenza type A virus matrix (M1) protein possesses multiple functional motifs in the helix 6 (H6) domain (amino acids 91 to 105), including nuclear localization signal (NLS) (101-RKLKR-105) involved in translocating M1 from the cytoplasm into the nucleus. To determine the role of the NLS motif in the influenza virus life cycle, we mutated these and the neighboring sequences by site-directed mutagenesis, and influenza virus mutants were generated by reverse genetics. Our results show that infectious viruses were rescued by reverse genetics from all single alanine mutations of amino acids in the H6 domain and the neighboring region except in three positions (K104A and R105A within the NLS motif and E106A in loop 6 outside the NLS motif). Among the rescued mutant viruses, R101A and R105K exhibited reduced growth and small-plaque morphology, and all other mutant viruses showed the wild-type phenotype. On the other hand, three single mutations (K104A, K105A, and E106A) and three double mutations (R101A/K102A, K104A/K105A, and K102A/R105A) failed to generate infectious virus. Deletion (Delta YRKL) or mutation (4A) of YRKL also abolished generation of infectious virus. However, replacement of the YRKL motif with PTAP or YPDL as well as insertion of PTAP after 4A mutation yielded infectious viruses with the wild-type phenotype. Furthermore, mutant M1 proteins (R101A/K102A, Delta YRKL, 4A, PTAP, 4A+PTAP, and YPDL) when expressed alone from cloned cDNAs were only cytoplasmic, whereas the wild-type M1 expressed alone was both nuclear and cytoplasmic as expected. These results show that the nuclear translocation function provided by the positively charged residues within the NLS motif does not play a critical role in influenza virus replication. Furthermore, these sequences of H6 domain can be replaced by late (L) domain motifs and therefore may provide a function similar to that of the L domains of other negative-strand RNA and retroviruses.     

The N-terminus of porcine circovirus type 2 replication protein is required for nuclear localization and ori binding activities

Porcine circovirus type 2 possesses a circular, single-stranded DNA genome that requires the replication protein (Rep) for virus replication. To characterize the DNA binding potential and the significant region that confers the nuclear localization of the Rep protein, the defined coding regions of rep gene were cloned and expressed. All of the recombinant proteins except for the N-terminal 110 residues deletion mutant could bind to the double-stranded minimal binding site of replication origin (ori). In addition, the N-terminal deletion mutant lacking 110 residues exhibited mainly cytoplasmic staining in the transfected cells in contrast to the others, which localized dominantly in the nucleus, suggesting that this N-terminal domain is essential for nuclear localization. Furthermore, a series of green fluorescence proteins (GFP) containing potential nuclear localization signal (NLS) sequences were tested for their cellular distribution. The ability of the utmost 20 residues of the N-terminal region to target the GFP to the nucleus confirmed its role as a functional NLS.     

A nuclear export signal in the matrix protein of Influenza A virus is required for efficient virus replication

The influenza A virus matrix 1 protein (M1) shuttles between the cytoplasm and the nucleus during the viral life cycle and plays an important role in the replication, assembly, and budding of viruses. Here, a leucine-rich nuclear export signal (NES) was identified specifically for the nuclear export of the M1 protein. The predicted NES, designated the Flu-A-M1 NES, is highly conserved among all sequences from the influenza A virus subtype, but no similar NES motifs are found in the M1 sequences of influenza B or C viruses. The biological function of the Flu-A-M1 NES was demonstrated by its ability to translocate an enhanced green fluorescent protein (EGFP)-NES fusion protein from the nucleus to the cytoplasm in transfected cells, compared to the even nuclear and cytoplasmic distribution of EGFP. The translocation of EGFP-NES from the nucleus to the cytoplasm was not inhibited by leptomycin B. NES mutations in M1 caused a nuclear retention of the protein and an increased nuclear accumulation of NEP during transfection. Indeed, as shown by rescued recombinant viruses, the mutation of the NES impaired the nuclear export of M1 and significantly reduced the virus titer compared to titers of wild-type viruses. The NES-defective M1 protein was retained in the nucleus during infection, accompanied by a lowered efficiency of the nuclear export of viral RNPs (vRNPs). In conclusion, M1 nuclear export was specifically dependent on the Flu-A-M1 NES and critical for influenza A virus replication.     

Intracellular localization of the viral polymerase proteins in cells infected with influenza virus and cells expressing PB1 protein from cloned cDNA.

The biosynthesis, nuclear transport, and formation of a complex among the influenza polymerase proteins were studied in influenza virus-infected MDBK cells by using monospecific antisera. To obtain these monospecific antisera, portions of cloned cDNAs encoding the individual polymerase proteins (PB1, PB2, or PA) of A/WSN/33 influenza virus were expressed as fusion proteins in Escherichia coli, and the purified fusion proteins were injected into rabbits. Studies using indirect immunofluorescence showed that early in the infectious cycle (4 h postinfection) of influenza virus, PB1 and PB2 are present mainly in the nucleus, whereas PA is predominantly present in the cytoplasm of the virus-infected cells. Later, at 6 to 8 h postinfection, all three polymerase proteins are apparent both in the cytoplasm as well as the nucleus. Radiolabeling and immunoprecipitation analyses showed that the three polymerase proteins remain physically associated as a complex in either the presence or the absence of ribonucleoproteins. In the cytoplasm, the majority of the polymerase proteins remain unassociated, whereas in the nucleus they are present as a complex of three polymerase proteins. To determine whether a polymerase protein is transported into the nucleus individually, PB1 was expressed from the cloned cDNA by using the simian virus 40 late promoter expression vector. PB1 alone, in the absence of the other polymerase proteins or the nucleoprotein, accumulates in the nucleus. This suggests that the formation of a complex with other viral protein(s) is not required for either nuclear transport or nuclear accumulation of PB1 protein and that the PB1 protein may contain an intrinsic signal(s) for nuclear transport.     

The nuclear location signal

A short sequence of predominantly basic amino acids Pro-Pro-Lys-Lys-Lys-Arg-Lys-Val from SV40 Large T is responsible for the normal nuclear location of the protein. Alteration of Lys-128 to each of six different residues other than Arg renders Large T cytoplasmic, whereas single amino acid changes in the surrounding region impair but do not prevent nuclear accumulation. When transposed to the amino terminus of cytoplasmic Large T species, or Escherichia coli beta-galactosidase or of chicken muscle pyruvate kinase, the sequence around Lys-128 of Large T is able to direct the recipient protein to the nucleus. This demonstrates that these amino acids can be sufficient for nuclear location and can act as a nuclear location signal. A computer search of over 2500 proteins reveals that some other nuclear proteins (for example, BK virus Large T, SV40 VP2 and adenovirus 72kDa DNA binding protein) contain very similar basic tracts, but so too do some presumed non-nuclear proteins (for example, poliovirus VP3). We suggest that the related sequence acts as the nuclear location signal in the other nuclear proteins but that the sequence does not function in all cases, perhaps because it is not accessible. A similar, but shorter or less basic sequence, was detected in a number of other nuclear proteins, for example, polyoma virus Large T, SV40 VP1 and several histones. However, such sequences were also found in many other proteins. Perhaps the shorter basic sequences can also act as nuclear location signals, but to be functional they need to be exposed (for example, at the amino terminus of the protein as in SV40 VP1) or to be present in multiple copies.     

Minimal requirements for the nuclear localization of p27(Kip1), a cyclin-dependent kinase inhibitor

p27(Kip1) is a cyclin-dependent kinase inhibitor, and its nuclear localization is a prerequisite for it to function as a cell cycle regulator. In the present study, the minimal requirement for the nuclear localization signal (NLS) of p27(Kip1) was determined by analyzing the localization of various mutants of p27(Kip1) tagged with green fluorescent protein (GFP) in HeLa cells and porcine aortic endothelial cells. Wild-type p27(Kip1) exclusively localized into nucleus, while GFP alone localized in both cytosol and nucleus. A comparison of various truncation mutants revealed residues 153-166 to be the minimal region necessary for nuclear localization. However, a fusion of this region to GFP showed cytoplasmic retention in addition to nuclear localization, thus suggesting that some extension flanking this region is required to achieve a full function of NLS. The site-directed mutation of the full-length p27(Kip1) therefore showed that four basic residues (K153, R154, K165, R166), especially R166, play a critical role in the nuclear localization of p27(Kip1).     

Mechanism of microtubule-facilitated "fast track" nuclear import

Although the microtubule (MT) cytoskeleton has been shown to facilitate nuclear import of specific cancer-regulatory proteins including p53, retinoblastoma protein, and parathyroid hormone-related protein (PTHrP), the MT association sequences (MTASs) responsible and the nature of the interplay between MT-dependent and conventional importin (IMP)-dependent nuclear translocation are unknown. Here we used site-directed mutagenesis, live cell imaging, and direct IMP and MT binding assays to map the MTAS of PTHrP for the first time, finding that it is within a short modular region (residues 82-108) that overlaps with the IMPβ1-recognized nuclear localization signal (residues 66-108) of PTHrP. Importantly, fluorescence recovery after photobleaching experiments indicated that disruption of the MT network or mutation of the MTAS of PTHrP decreases the rate of nuclear import by 2-fold. Moreover, MTAS functions depend on mutual exclusivity of binding of PTHrP to MTs and IMPβ1 such that, following MT-dependent trafficking toward the nucleus, perinuclear PTHrP can be displaced from MTs by IMPβ1 prior to import into the nucleus. This is the first molecular definition of an MTAS that facilitates protein nuclear import as well as the first delineation of the mechanism whereby cargo is transferred directly from the cytoskeleton to the cellular nuclear import apparatus. The results have broad significance with respect to fundamental processes regulating cell physiology/transformation.     

The PA subunit is required for efficient nuclear accumulation of the PB1 subunit of the influenza A virus RNA polymerase complex

The RNA genome of influenza virus is transcribed and replicated by the viral RNA polymerase complex in the cell nucleus. We have generated green fluorescent protein (GFP)-tagged polymerase subunits to study the assembly of the polymerase complex. Our results show that individually expressed polymerase basic protein 1 (PB1) and polymerase acidic protein (PA) subunits were distributed in both the cytoplasm and the nucleus, while the polymerase basic protein 2 (PB2) subunit accumulated in the nucleus. Although it has been reported that PB1 alone accumulates in the nucleus, we demonstrate that PB1 requires the coexpression of PA for efficient nuclear accumulation. Our results support a model which proposes that PB1 and PA are transported into the nucleus as a complex.     

Nuclear location of all three influenza polymerase proteins and a nuclear signal in polymerase PB2.

In order to re-examine the sub-cellular location of the three influenza A/NT/60/68 polymerase proteins PB1, PB2 and PA in infected cells, specific antisera for each polymerase component have been prepared by immunizing rabbits with polymerase-beta-galactosidase fusion proteins synthesized in Escherichia coli. We show that polymerase PB1, PB2, and PA are predominantly associated with the nucleus of influenza-infected MDCK cells by immunocytochemical techniques. In the case of polymerase PB2 we investigate the possibility that nuclear accumulation is an intrinsic property of the PB2 protein. Using a vaccinia-PB2 recombinant virus, we show that PB2 accumulates intra-nuclearly in monkey CV-1 cells in the absence of any other influenza protein, suggesting it contains an intrinsic nuclear signal.