Nuclear Pore Complex Function Research Articles

Patch clamp and atomic force microscopy demonstrate TATA-binding protein (TBP) interactions with the nuclear pore complex.

The universal TATA-binding protein, TBP, is an essential component of the multiprotein complex known as transcription factor IID (TFIID). This complex, which consists of TBP and TBP-associated factors (TAFs), is essential for RNA polymerase II-mediated transcription. The molecular size of human TBP (37.7 kD) is close to the passive diffusion limit along the transport channel of the nuclear pore complex (NPC). Therefore, the possibility exists that NPCs restrict TBP translocation to the nuclear interior. Here we show for the first time, with patch-clamp and atomic force microscopy (AFM), that NPCs regulate TBP movement into the nucleus and that TBP (10(-15)-10(-10)M) is capable of modifying NPC structure and function. The translocation of TBP was ATP-dependent and could be detected as a transient plugging of the NPC channels, with a concomitant transient reduction in single NPC channel conductance, gamma, to a negligible value. NPC unplugging was accompanied by permanent channel opening at concentrations greater than 250 pM. AFM images demonstrated that the TBP molecules attached to and accumulated on the NPC cytosolic side. NPC channel activity could be recorded for more than 48 hr. These observations suggest that three novel functions of TBP are: to stabilize NPC, to force the NPC channels into an open state, and to increase the number of functional channels. Since TBP is a major component of transcription, our observations are relevant to the understanding of the gene expression mechanisms underlying normal and pathological cell structure and function.

The nuclear pore complex.

The nuclear pore complex (NPC) creates an aqueous channel across the nuclear envelope through which macromolecular transport between nucleus and cytoplasm occurs. Nucleocytoplasmic traffic is bidirectional and involves diverse substrates, including protein and RNA. It is unclear whether import and export are mechanistically similar, but evidence suggests that numerous pathways may be involved. The discovery of filaments that extend out from each side of the NPC suggests that the NPC may also have a structural role, perhaps providing a connection between cytoskeletal elements of the nucleus and cytoplasm. If this suggestion is valid, it remains to be determined whether this aspect of NPC function is related to its role in nuclear transport. This review discusses recent developments regarding the structure of the NPC, characterization of its constituent proteins (nucleoporins), the mechanism by which transport occurs, the function of individual nucleoporins, and the pathway of NPC assembly and disassembly.

Nup1 mutants exhibit pleiotropic defects in nuclear pore complex function.

The NUP1 gene of Saccharomyces cerevisiae encodes one member of a family of nuclear pore complex proteins (nucleoporins) conserved from yeast to vertebrates. We have used mutational analysis to investigate the function of Nup1p. Deletion of either the amino- or carboxy-terminal domain confers a lethal phenotype, but partial truncations at either end affect growth to varying extents. Amino-terminal truncation causes mislocalization and degradation of the mutant protein, suggesting that this domain is required for targeting Nup1p to the nuclear pore complex. Carboxy-terminal mutants are stable but do not have wild-type function, and confer a temperature sensitive phenotype. Both import of nuclear proteins and export of poly(A) RNA are defective at the nonpermissive temperature. In addition, nup1 mutant cells become multinucleate at all temperatures, a phenotype suggestive of a defect in nuclear migration. Tubulin staining revealed that the mitotic spindle appears to be oriented randomly with respect to the bud, in spite of the presence of apparently normal cytoplasmic microtubules connecting one spindle pole body to the bud tip. EM analysis showed that the nuclear envelope forms long projections extending into the cytoplasm, which appear to have detached from the bulk of the nucleus. Our results suggest that Nup1p may be required to retain the structural integrity between the nuclear envelope and an underlying nuclear scaffold, and that this connection is required to allow reorientation of the nucleus in response to cytoskeletal forces.

Most Nuclear Proteins Are Imported by a Single Pathway

Using kinetic competition analysis, we show that the import of most Xenopus oocyte nuclear proteins is directed by a single family of nuclear localization signals (NLS). The transport of microinjected [35S]methionine-labeled nuclear proteins into oocyte nuclei was challenged with saturating concentrations of SV40 large T-antigen NLS peptide-BSA (P(Lys)-BSA) and was assessed by SDS-acrylamide gel electrophoresis and fluorography. P(Lys)-BSA was effective at competing the import of virtually all larger polypeptides but had a less marked effect on the mediated import of many smaller polypeptides. Wheat germ agglutinin, an inhibitor of nuclear pore complex function, enhanced the competitive effects of P(Lys)-BSA on the import of both large and small polypeptides. These data indicate that most 35 S-labeled Xenopus oocyte nuclear proteins, including nucleoplasmin, contain NLSs that are functionally related to the T-antigen NLS and probably employ the same cytosolic NLS receptor(s).