Mary Shannon Moore

The Peptide Repeat Domain of Nucleoporin Nup98 Functions as a Docking Site in Transport across the Nuclear Pore Complex

We report the cDNA deduced primary structure of a wheat germ agglutinin-reactive nuclear pore complex (NPC) protein of rat. The protein, termed Nup98 (for nucleoporin of 98 kDa), contains numerous GLFG and FG repeats and some FXFG repeats and is thus a vertebrate member of a family of GLFG nucleoporins that were previously discovered in yeast. Immunoelectron microscopy showed Nup98 to be asymmetrically located at the nucleoplasmic side of the NPC. Nup98 functions as one of several docking site nucleoporins in a cytosolic docking activity-mediated binding of a model transport substrate. The docking site of Nup98 was mapped to its N-terminal half, which contains all of the peptide repeats. A recombinant segment of this region depleted the docking activity of cytosol. We suggest that the peptide repeat domain of Nup98, together with peptide repeat domains of other nucleoporins, forms an array of sites for mediated docking of transport substrate, and that bidirectional transport across the NPC proceeds by repeated docking and undocking reactions.

Viral protein R regulates nuclear import of the HIV‐1 pre‐integration complex

Replication of human immunodeficiency virus type 1 (HIV‐1) in non‐dividing cells critically depends on import of the viral pre‐integration complex into the nucleus. Genetic evidence suggests that viral protein R (Vpr) and matrix antigen (MA) are directly involved in the import process. An in vitro assay that reconstitutes nuclear import of HIV‐1 pre‐integration complexes in digitonin‐permeabilized cells was used to demonstrate that Vpr is the key regulator of the viral nuclear import process. Mutant HIV‐1 pre‐integration complexes that lack Vpr failed to be imported in vitro, whereas mutants that lack a functional MA nuclear localization sequence (NLS) were only partially defective. Strikingly, the import defect of the Vpr− mutant was rescued when recombinant Vpr was re‐added. In addition, import of Vpr− virus was rescued by adding the cytosol of HeLa cells, where HIV‐1 replication had been shown to be Vpr‐independent. In a solution binding assay, Vpr associated with karyopherin α, a cellular receptor for NLSs. This association increased the affinity of karyopherin α for basic‐type NLSs, including that of MA, thus explaining the positive effect of Vpr on nuclear import of the HIV‐1 pre‐integration complex and BSA–NLS conjugates. These results identify the biochemical mechanism of Vpr function in transport of the viral pre‐integration complex to, and across, the nuclear membrane.

The two steps of nuclear import, targeting to the nuclear envelope and translocation through the nuclear pore, require different cytosolic factors

We have isolated two cytosolic fractions from Xenopus oocytes that contain all of the activity necessary to support both steps of nuclear import in digitonin-permeabilized mammalian cells: binding at the nuclear envelope and translocation through the nuclear pore. The first cytosolic fraction (fraction A) interacts with an import-competent, but not a mutant, nuclear localization sequence-bearing conjugate and stimulates its accumulation at the nuclear envelope in an ATP-independent fashion. The second cytosolic fraction (fraction B) gives no discernible effect when added alone; but when added either together with fraction A, or after fraction A, stimulates the passage of the conjugate from the outer nuclear envelope to the interior of the nucleus in an ATP-dependent fashion.

Cysteine-Rich LIM-Only Proteins CRP1 and CRP2 Are Potent Smooth Muscle Differentiation Cofactors

Cysteine-rich LIM-only proteins, CRP1 and CRP2, expressed during cardiovascular development act as bridging molecules that associate with serum response factor and GATA proteins. SRF-CRP-GATA complexes strongly activated smooth muscle gene targets. CRP2 was found in the nucleus during early stages of coronary smooth muscle differentiation from proepicardial cells. A dominant-negative CRP2 mutant blocked proepicardial cells from differentiating into smooth muscle cells. Together with SRF and GATA proteins, CRP1 and CRP2 converted pluripotent 10T1/2 fibroblasts into smooth muscle cells, while muscle LIM protein CRP3 inhibited the conversion. Thus, LIM-only proteins of the CRP family play important roles in organizing multiprotein complexes, both in the cytoplasm, where they participate in cytoskeletal remodeling, and in the nucleus, where they strongly facilitate smooth muscle differentiation.

Getting across the nuclear pore complex

The nuclear pore complex (NPC) connects the cytoplasm and nucleus through the nuclear envelope and serves as the pipeline for moving material between the two compartments. Macromolecules that move through the NPC range in size from the very small (for example, ions and ATP) to the very large (for example, ribonucleoprotein particle complexes). Unlike translocation across other organelle membranes, proteins do not have to be unfolded to be transported through the NPC, and the NPC also routinely transports large, multicomponent substrates in both directions. This review focuses on current understanding of the different mechanisms by which macromolecules move across the NPC.

Ran and Nuclear Transport

The last several years have witnessed an explosion in our understanding of how proteins and RNAs traffic into and out of the nucleus. Although an increasing number of proteins have been implicated in different nuclear transport pathways, the small GTPase Ran appears to play a central role in coordinating and driving much of this nuclear traffic. Recently there have been several excellent reviews describing the multiple pathways of nuclear transport (1–5); consequently this review will focus on what is currently known about Ran and its biochemical properties and what is presently understood of the role of the Ran GTPase cycle during nuclear transport.

A G protein involved in nucleocytoplasmic transport: the role of Ran.

Ran is the only known member of the Ras superfamily of small GTP-binding proteins to be localized primarily inside the nucleus. Recently, Ran was unexpectedly identified as one of the soluble factors required for nuclear import. As this protein has also been implicated in RNA export, nuclear import and export may be more closely related than previously thought, with Ran playing a key role in each.

ERK2 enters the nucleus by a carrier-independent mechanism.

In stimulated cells, the mitogen-activated protein kinase ERK2 (extracellular signal-regulated kinase 2) concentrates in the nucleus. Evidence exists for CRM1-dependent, mitogen-activated protein kinase kinase-mediated nuclear export of ERK2, but its mechanism of nuclear entry is not understood. To determine requirements for nuclear transport, we tagged ERK2 with green fluorescent protein (GFP) and examined its nuclear uptake by using an in vitro import assay. GFP-ERK2 entered the nucleus in a saturable, time- and temperature-dependent manner. Entry of GFP-ERK2, like that of ERK2, required neither energy nor transport factors and was visible within minutes. The nuclear uptake of GFP-ERK2 was inhibited by wheat germ agglutinin, which blocks nuclear entry by binding to carbohydrate moieties on nuclear pore complex proteins. The nuclear uptake of GFP-ERK2 also was reduced by excess amounts of recombinant transport factors. These findings suggest that ERK2 competes with transport factors for binding to nucleoporins, which mediate the entry and exit of transport factors. In support of this hypothesis, we showed that ERK2 binds directly to a purified nucleoporin. Our data suggest that GFP-ERK2 enters the nucleus by a saturable, facilitated mechanism, distinct from a carrier- and energy-dependent import mechanism and involves a direct interaction with nuclear pore complex proteins.

The death effector domain protein PEA-15 prevents nuclear entry of ERK2 by inhibiting required interactions.

ERK2 nuclear-cytoplasmic distribution is regulated in response to hormones and cellular state without the requirement for karyopherin-mediated nuclear import. One proposed mechanism for the movement of ERK2 into the nucleus is through a direct interaction between ERK2 and nucleoporins present in the nuclear pore complex. Previous reports have attributed regulation of ERK2 localization to proteins that activate or deactivate ERK2, such as the mitogen-activated protein (MAP) kinase kinase MEK1 and MAP kinase phosphatases. Recently, a small non-catalytic protein, PEA-15, has also been demonstrated to promote a cytoplasmic ERK2 localization. We found that the MAP kinase insert in ERK2 is required for its interaction with PEA-15. Consistent with its recognition of the MAP kinase insert, PEA-15 blocked activation of ERK2 by MEK1, which also requires the MAP kinase insert to interact productively with ERK2. To determine how PEA-15 influences the localization of ERK2, we used a permeabilized cell system to examine the effect of PEA-15 on the localization of ERK2 and mutants that have lost the ability to bind PEA-15. Wild type ERK2 was unable to enter the nucleus in the presence of an excess of PEA-15; however, ERK2 lacking the MAP kinase insert largely retained the ability to enter the nucleus. Binding assays demonstrated that PEA-15 interfered with the ability of ERK2 to bind to nucleoporins. These results suggest that PEA-15 sequesters ERK2 in the cytoplasm at least in part by interfering with its ability to interact with nucleoporins, presenting a potential paradigm for regulation of ERK2 localization.

Protein translocation: Nuclear export – out of the dark

Abstract Nuclear protein export has, in contrast to nuclear protein import, been a poorly understood process; but now, the signals and cellular machinery that govern protein export from the nucleus are beginning to be elucidated.