Structural basis for the specificity of bipartite nuclear localization sequence binding by importin-alpha

Importin-alpha is the nuclear import receptor that recognizes cargo proteins carrying conventional basic monopartite and bipartite nuclear localization sequences (NLSs) and facilitates their transport into the nucleus. Bipartite NLSs contain two clusters of basic residues, connected by linkers of variable lengths. To determine the structural basis of the recognition of diverse bipartite NLSs by mammalian importin-alpha, we co-crystallized a non-autoinhibited mouse receptor protein with peptides corresponding to the NLSs from human retinoblastoma protein and Xenopus laevis phosphoprotein N1N2, containing diverse sequences and lengths of the linker. We show that the basic clusters interact analogously in both NLSs, but the linker sequences adopt different conformations, whereas both make specific contacts with the receptor. The available data allow us to draw general conclusions about the specificity of NLS binding by importin-alpha and facilitate an improved definition of the consensus sequence of a conventional basic/bipartite NLS (KRX10-12KRRK) that can be used to identify novel nuclear proteins.     

Induction of protein translation by ADAR1 within living cell nuclei is not dependent on RNA editing

Translation of mRNA is usually cytoplasmic. We report that the RNA editing enzyme ADAR1, which catalyzes the deamination of adenosine to inosine in double-stranded RNA substrates, induces translation within the nucleus, possibly at the surface of the nucleolus. This activity does not depend on RNA editing. Two regions within ADAR1 are defined that act independently of each other to induce translation: the first includes the double-stranded RNA binding domains (DRBMs) of ADAR1 while the second maps to the C-terminal portion of the catalytic domain. Point mutations within each domain are identified that reduce nuclear translation; those in the DRBM region are also known to diminish RNA binding. This report adds to the growing functionality ascribed to the nucleus.     

Analysis of a developmentally regulated nuclear localization signal in Xenopus

The 289 residue nuclear oncoprotein encoded by the adenovirus 5 Ela gene contains two peptide sequences that behave as nuclear localization signals (NLS). One signal, located at the carboxy terminus, is like many other known NLSs in that it consists of a short stretch of basic residues (KRPRP) and is constitutively active in cells. The second signal resides within an internal 45 residue region of E1a that contains few basic residues or sequences that resemble other known NLSs. Moreover, this internal signal functions in injected Xenopus oocytes, but not in transfected Xenopus A6 cells, suggesting that it could be regulated developmentally (Slavicek et al. 1989. J. Virol. 63:4047). In this study, we show that the activity of this signal is sensitive to ATP depletion in vivo, efficiently directs the import of a 50 kD fusion protein and can compete with the E1a carboxy-terminal NLS for nuclear import. In addition, we have delineated the precise amino acid residues that comprise the second E1a NLS, and have assessed its utilization during Xenopus embryogenesis. Using amino acid deletion and substitution analyses, we show that the signal consists of the sequence FV(X)7-20MXSLXYM(X)4MF. By expressing in Xenopus embryos a truncated E1a protein that contains only the second NLS and by monitoring its cytoplasmic/nuclear distribution during development with indirect immunofluorescence, we find that the second NLS is utilized up to the early neurula stage. In addition, there appears to be a hierarchy among the embryonic germ layers as to when the second NLS becomes nonfunctional. For this reason, we refer to this NLS as the developmentally regulated nuclear localization signal (drNLS). The implications of these findings for early development are discussed.     

Subcellular distribution of ADAR1 isoforms is synergistically determined by three nuclear discrimination signals and a regulatory motif

ADAR1 is an RNA-specific adenosine deaminase that edits RNA sequences. We have demonstrated previously that different ADAR1 isoforms are induced during acute inflammation. Here we show that the mouse ADAR1 isoforms are differentially localized in cellular compartments and that their localization is controlled by several independent signals. Nuclear import of the full-length ADAR1 is predominantly regulated by a nuclear localization signal at the C terminus (NLS-c), which consists of a bipartite basic amino acid motif plus the last 39 residues of ADAR1. Deletion of the NLS-c causes the truncated ADAR1 protein to be retained in the cytoplasm. The addition of this sequence to pyruvate kinase causes the cytoplasmic protein to be localized within the nucleus. The localization of nuclear ADAR1 is determined by a dynamic balance between the nucleolar binding activity of the nucleolar localization signal (NoLS) in the middle of the protein and the exporting activity of the nuclear exporter signal (NES) near the N terminus. The NoLS consists of a typical monopartite cluster of basic residues followed by the third double-stranded RNA-binding domain. These signals act independently; however, NES function can be completely silenced by the NLS-c when a regulatory motif within the catalytic domain and the NoLS are deleted. Thus, the intracellular distribution of the various ADAR1 isoforms is determined by NLS-c, NES, NoLS, and a regulatory motif.     

Efficiency of importin alpha/beta-mediated nuclear localization sequence recognition and nuclear import. Differential role of NTF2.

Little quantitative, kinetic information is available with respect to the process of nuclear import of conventional nuclear localization sequence (NLS)-containing proteins, which initially involves recognition and docking at the nuclear pore by importin alpha/beta. This study compares the binding and nuclear import properties of mouse (m) and yeast (y) importin (IMP) subunits with respect to the NLSs from the SV40 large tumor antigen (T-ag), and the Xenopus laevis phosphoprotein N1N2. m- and y-IMPalpha recognized both NLSs, with y-IMPalpha exhibiting higher affinity. m-IMPbeta greatly enhanced the binding of m-IMPalpha to the T-ag and N1N2 NLSs, but y-IMPbeta did not significantly affect the affinity of y-IMPalpha for the T-ag NLS. In contrast, y-IMPbeta enhanced y-IMPalpha binding to the NLS of N1N2, but to a lesser extent than the enhancement of m-IMPalpha binding by m-IMPbeta. NLS-dependent nuclear import was reconstituted in vitro using the different importin subunits together with the transport factors Ran and NTF2. Whereas T-ag NLS-mediated nuclear import did not exhibit an absolute requirement for NTF2, N1N2 NLS-mediated transport strictly required NTF2. High levels of NTF2 inhibited nuclear accumulation conferred by both NLSs. We conclude that different NLSs possess distinct nuclear import properties due to differences in recognition by importin and requirements for NTF2.     

Identification and Functional Characterization of a Novel Nuclear Localization Signal Present in the Yeast Nab2 Poly(A)+ RNA Binding Protein

The nuclear import of proteins bearing a basic nuclear localization signal (NLS) is dependent on karyopherin α/importin α, which acts as the NLS receptor, and karyopherin β1/importin β, which binds karyopherin α and mediates the nuclear import of the resultant ternary complex. Recently, a second nuclear import pathway that allows the rapid reentry into the nucleus of proteins that participate in the nuclear export of mature mRNAs has been identified. In mammalian cells, a single NLS specific for this alternate pathway, the M9 NLS of heterogeneous nuclear ribonucleoprotein A1 (hnRNPA1), has been described. The M9 NLS binds a transport factor related to karyopherin β1, termed karyopherin β2 or transportin, and does not require a karyopherin α-like adapter protein. A yeast homolog of karyopherin β2, termed Kap104p, has also been described and proposed to play a role in the nuclear import of a yeast hnRNP-like protein termed Nab2p. Here, we define a Nab2p sequence that binds to Kap104p and that functions as an NLS in both human and yeast cells despite lacking any evident similarity to basic or M9 NLSs. Using an in vitro nuclear import assay, we demonstrate that Kap104p can direct the import into isolated human cell nuclei of a substrate containing a wild-type, but not a defective mutant, Nab2p NLS. In contrast, other NLSs, including the M9 NLS, could not function as substrates for Kap104p. Surprisingly, this in vitro assay also revealed that human karyopherin β1, but not the Kap104p homolog karyopherin β2, could direct the efficient nuclear import of a Nab2p NLS substrate in vitro in the absence of karyopherin α. These data therefore identify a novel NLS sequence, active in both yeast and mammalian cells, that is functionally distinct from both basic and M9 NLS sequences.     

Difference in nucleocytoplasmic shuttling sequences of rat and human constitutive active/androstane receptor

Fluorescence recovery after photobleaching (FRAP) in spontaneous multinuclear cells shows that both rat and human constitutive active/androstane receptors (CARs) are shuttling proteins with both nuclear localization signals (NLSs) and nuclear export signals (NESs). We previously identified two NLSs in rat CAR: NLS1 in the hinge region (residues 100-108) and NLS2 in the ligand-binding domain (residues 111-320). In the present study, we compared the intracellular localization signals between rat and human CARs. There was a marked difference in their intracellular localization in COS-7 cells because, unlike rat CAR, human CAR does not contain NLS1 due to an amino acid change at position 106. A CRM1-dependent leucine-rich NES, which is sensitive to an inhibitory effect of leptomycin B, was found in the cytoplasmic retention region previously identified within the ligand-binding domain of rat CAR (residues 220-258). We found that human CAR instead has a NES in the ligand-binding domain between residues 170 and 220. Also, we detected CRM1-independent C-terminal NESs between residues 317-358 of rat and human CARs. Removal of NLS1 by N-terminal truncation and mutation of xenochemical response signal caused rat CAR to localize in the cytoplasm of COS-7 cells, which we suspect is due to the masking of NLS2.     

Identification of nuclear and nucleolar localization signals in the herpes simplex virus regulatory protein ICP27.

Previous work has shown that the herpes simplex virus type 1 (HSV-1) regulatory protein ICP27 localizes to the cell nucleus and that certain mutant ICP27 polypeptides localize preferentially in nucleoli. To map the signals in ICP27 which mediate its nuclear localization, we identified the portions of ICP27 which can direct a cytoplasmic protein, pyruvate kinase (PK), to nuclei. Our results demonstrate that ICP27 contains multiple nuclear localization signals (NLSs) that function with differing efficiencies. First, ICP27 possesses a strong NLS, mapping to residues 110 to 137, which bears similarity to the bipartite NLSs found in Xenopus laevis nucleoplasmin and other proteins. Second, ICP27 possesses one or more weak NLSs which map to a carboxyl-terminal portion of the protein between residues 140 and 512. Our PK-targeting experiments also demonstrate that ICP27 contains a relatively short sequence, mapping to residues 110 to 152, that can function as a nucleolar localization signal (NuLS). This signal includes ICP27's strong NLS as well as 15 contiguous residues which consist entirely of arginine and glycine. This latter sequence is very similar to an RGG box, a putative RNA-binding motif found in a number of cellular proteins which are involved in nuclear RNA processing. To confirm the results of the PK-targeting experiments, we mutated the ICP27 gene by deleting sequences encoding either the strong NLS or the RGG box. Deletion of the strong NLS (residues 109 to 138) resulted in an ICP27 molecule that was only partially defective for nuclear localization, while deletion of the RGG box (residues 139 to 153) resulted in a molecule that was nuclear localized but excluded from nucleoli. Recombinant HSV-1s bearing either of these deletions were unable to replicate efficiently in Vero cells, suggesting that ICP27's strong NLS and RGG box carry out important in vivo functions.     

Cytosolic import factor- and Ran-independent nuclear transport of ribosomal protein L5

Ribosomal protein L5 is a shuttling protein that, in Xenopus oocytes, is involved in the nucleocytoplasmic transport of 5S rRNA. As demonstrated earlier, L5 contains three independent nuclear import signals (NLSs), which function in oocytes as well as in somatic cells. Upon physical separation, these NLSs differ in respect to their capacity to bind to nuclear import factors in vitro and to mediate the nuclear import of a heterologous RNP in vivo. As reported in this communication, analysis of the in vitro nuclear import activity of these three NLSs reveals that they also differ in respect to their requirements for cytosolic import factors and Ran. Nuclear import mediated by the N-terminal and the central NLS depends on cytosolic import factor(s) and Ran, whereas import via the C-terminal NLS occurs independently from these factors. Thus, the presence of multiple NLSs in ribosomal protein L5 appears to allow for efficient nuclear transport via utilisation of multiple, mechanistically different import pathways.     

Identification of nuclear import and export signals within Fli-1: roles of the nuclear import signals in Fli-1-dependent activation of megakaryocyte-specific promoters

The Ets factor Friend leukemia integration 1 (Fli-1) is an important regulator of megakaryocytic (Mk) differentiation. Here, we demonstrate two novel nuclear localization signals (NLSs) within Fli-1: one (NLS1) is located at the N terminus, and another (NLS2) is within the Ets domain. Nuclear accumulation of Fli-1 reflected the combined functional effects of the two discrete NLSs. Each NLS can independently direct nuclear transport of a carrier protein, with mutations within the NLSs affecting nuclear accumulation. NLS1 has a bipartite motif, whereas the NLS2 region contains a nonclassical NLS. Both NLSs bind importin alpha (IMPalpha) and IMPbeta, with NLS1 and NLS2 being predominantly recognized by IMPalpha and IMPbeta, respectively. Fli-1 also contains one nuclear export signal. Leptomycin B abolished its cytoplasmic accumulation, showing CRM1 dependency. We demonstrate that Ets domain binding to specific target DNA effectively blocks IMP binding, indicating that the targeted DNA binding plays a role in localizing Fli-1 to its destination and releasing IMPs for recycling back to the cytoplasm. Finally, by analyzing full-length Fli-1 carrying NLS1, NLS2, and combined NLS1-NLS2 mutations, we conclude that two functional NLSs exist in Fli-1 and that each NLS is sufficient to target Fli-1 to the nucleus for activation of Mk-specific genes.     

Multiple nuclear localization sequences allow modulation of 5-lipoxygenase nuclear import

The nuclear import of proteins typically requires the presence of a nuclear localization sequence (NLS). Some proteins have more than one NLS, but the significance of having multiple NLSs is unclear. The enzyme 5-lipoxygenase (5-LO) has three NLSs that, unlike the tight cluster of basic residues of the classical SV40 large T antigen NLS, contain dispersed basic residues. When attached to green fluorescent protein (GFP), individual 5-LO NLSs caused quantitatively and statistically less import than the SV40 NLS. Combined 5-LO NLSs produced nuclear import that was comparable to that of the SV40 NLS. As expected, GFP/NLS proteins displayed relatively uniform import in all cells. However, a fusion protein of GFP plus the 5-LO protein, modified to contain only one functional NLS, produced some cells with import and some cells without import. A GFP/5-LO fusion protein containing two functional NLSs produced four identifiable levels of nuclear import. Quantitative and visual analysis of a population of cells expressing the intact GFP/5-LO protein, with three intact NLSs, indicated five levels of nuclear import. This suggested that the subcellular distribution of 5-LO may vary widely in normal cells of the body. Consistent with this, immunohistochemical staining of lung sections found that individual macrophages, in situ, displayed cell-specific levels of import of 5-LO. Since nuclear accumulation is known to affect 5-LO activity, multiple NLSs may allow graded regulation of activity via controlled import. Multiple NLSs on other proteins may likewise allow fine control of protein action through modulation of the level of import.     

Hepatitis Delta Antigen Mediates the Nuclear Import of Hepatitis Delta Virus RNA

Hepatitis delta virus (HDV) RNA replicates in the nuclei of virus-infected cells. The mechanism of nuclear import of HDV RNA is so far unknown. Using a fluorescein-labeled HDV RNA introduced into partially permeabilized HeLa cells, we found that HDV RNA accumulated only in the cytoplasm. However, in the presence of hepatitis delta antigen (HDAg), which is the only protein encoded by HDV RNA, the HDV RNA was translocated into the nucleus, suggesting that nuclear import of HDV RNA is mediated by HDAg. Deletion of the nuclear localization signal (NLS) or RNA-binding motifs of HDAg resulted in the failure of nuclear import of HDV RNA, indicating that both the NLS and an RNA-binding motif of HDAg are required for the RNA-transporting activity of HDAg. Surprisingly, any one of the three previously identified RNA-binding motifs was sufficient to confer the RNA-transporting activity. We have further shown that HDAg, via its NLS, interacts with karyopherin α2 in vitro, suggesting that nuclear import of the HDAg-HDV RNA complex is mediated by the karyopherin α2β heterodimer. The nuclear import of HDV RNA may be the first biological function of HDAg in the HDV life cycle.     

Defective calmodulin-mediated nuclear transport of the sex-determining region of the Y chromosome (SRY) in XY sex reversal

The sex-determining region of the Y chromosome (SRY) plays a key role in human sex determination, as mutations in SRY can cause XY sex reversal. Although some SRY missense mutations affect DNA binding and bending activities, it is unclear how others contribute to disease. The high mobility group domain of SRY has two nuclear localization signals (NLS). Sex-reversing mutations in the NLSs affect nuclear import in some patients, associated with defective importin-beta binding to the C-terminal NLS (c-NLS), whereas in others, importin-beta recognition is normal, suggesting the existence of an importin-beta-independent nuclear import pathway. The SRY N-terminal NLS (n-NLS) binds calmodulin (CaM) in vitro, and here we show that this protein interaction is reduced in vivo by calmidazolium, a CaM antagonist. In calmidazolium-treated cells, the dramatic reduction in nuclear entry of SRY and an SRY-c-NLS mutant was not observed for two SRY-n-NLS mutants. Fluorescence spectroscopy studies reveal an unusual conformation of SRY.CaM complexes formed by the two n-NLS mutants. Thus, CaM may be involved directly in SRY nuclear import during gonadal development, and disruption of SRY.CaM recognition could underlie XY sex reversal. Given that the CaM-binding region of SRY is well-conserved among high mobility group box proteins, CaM-dependent nuclear import may underlie additional disease states.     

Kinetic properties of nuclear transport conferred by the retinoblastoma (Rb) NLS

The retinoblastoma (RB) tumor suppressor is a nuclear phosphoprotein central to control of cellular proliferation. We have previously shown that human RB possesses an evolutionarily conserved bipartite nuclear localization sequence (NLS) (KRSAEGSNPPKPLKKLR877) resembling that of nucleoplasmin. Here we analyze the kinetic properties of the RB NLS in detail with respect to recognition by cellular nuclear import factors, the importins (IMPs), and nuclear transport properties, comparing results to those for the NLSs from SV40 large tumor antigen (T-ag) and the Xenopus laevis phosphoprotein N1N2. Binding affinities of different IMPalpha subunits for the Rb NLS, in the absence or presence of IMPbeta subunits were determined, and NLS-dependent nuclear import reconstituted in vitro for the first time using purified IMPalpha/beta subunits together with recombinant human RanGDP and nuclear transport factor 2 (NTF2). RB NLS-mediated transport had a strict requirement for all components, with high NTF2 concentrations inhibiting transport. As in the case of transport mediated by the T-ag- and N1N2-NLSs, nuclear import of an RB-NLS containing beta-Gal fusion protein was reduced or abolished when anti-IMPalpha or beta antibody was added to cytosolic extract, respectively, confirming that RB NLS-mediated nuclear import occurs through action of IMPalpha/beta. We conclude that although mediated by IMPalpha/beta, and similar in most respects to transport mediated by the similarly bipartite N1N2 NLS, nuclear import conferred by the RB NLS has distinct properties, in part due to the affinity of its interaction with IMPalpha.     

An ADAR that edits transcripts encoding ion channel subunits functions as a dimer

In this report, we establish that Drosophila ADAR (adenosine deaminase acting on RNA) forms a dimer on double-stranded (ds) RNA, a process essential for editing activity. The minimum region required for dimerization is the N-terminus and dsRNA-binding domain 1 (dsRBD1). Single point mutations within dsRBD1 abolish RNA-binding activity and dimer formation. These mutations and glycerol gradient analysis indicate that binding to dsRNA is important for dimerization. However, dimerization can be uncoupled from dsRNA-binding activity, as a deletion of the N-terminus (amino acids 1-46) yields a monomeric ADAR that retains the ability to bind dsRNA but is inactive in an editing assay, demonstrating that ADAR is only active as a dimer. Different isoforms of ADAR with different editing activities can form heterodimers and this can have a significant effect on editing in vitro as well as in vivo. We propose a model for ADAR dimerization whereby ADAR monomers first contact dsRNA; however, it is only when the second monomer binds and a dimer is formed that deamination occurs.