Takuya Shimamoto scite author profile

We recently showed that a nuclear location signal (NLS)‐containing karyophile forms a stable complex with cytoplasmic components for nuclear pore‐targeting The complex, termed nuclear pore‐targeting complex (PTAC), contained two essential proteins of 54 and 90 kDa, respectively, as estimated by electrophoresis. In this study, we found that the 54 kDa component of PTAC is the mouse homologue of Xenopus importin (m‐importin). Cytoplasmic injection of the antibodies raised against recombinant m‐importin showed an inhibitory effect on nuclear import of a karyophile in living mammalian cells. A portion of cytoplasmically injected antibodies migrated rapidly into the nucleus, indicating dynamic movement of this protein across the nuclear envelope. Moreover, the injected antibodies co‐precipitated the karyophile, in an NLS‐dependent manner, with endogenous m‐importin in the cytoplasm. These results provide in vivo evidence that m‐importin is involved in nuclear protein import through association with a NLS in the cytoplasm before nuclear pore binding.

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Ran-unassisted Nuclear Migration of a 97-kD Component of Nuclear Pore–targeting Complex

Kose

et al. 1997

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A 97-kD component of nuclear pore-targeting complex (the β-subunit of nuclear pore–targeting complex [PTAC]/importin/karyopherin) mediates the import of nuclear localization signal (NLS)-containing proteins by anchoring the NLS receptor protein (the α-subunit of PTAC/importin/karyopherin) to the nuclear pore complex (NPC). The import requires a small GTPase Ran, which interacts directly with the β-subunit. The present study describes an examination of the behavior of the β-subunit in living cells and in digitonin-permeabilized cells. In living cells, cytoplasmically injected β-subunit rapidly migrates into the nucleus. The use of deletion mutants reveals that nuclear migration of the β-subunit requires neither Ran- nor α-subunit–binding but only the NPC-binding domain of this molecule, which is also involved in NLS-mediated import. Furthermore, unlike NLS-mediated import, a dominant-negative Ran, defective in GTP-hydrolysis, did not inhibit nuclear migration of the β-subunit. In the digitonin-permeabilized cell-free import assay, the β-subunit transits rapidly through the NPC into the nucleus in a saturating manner in the absence of exogenous addition of soluble factors. These results show that the β-subunit undergoes translocation at the NPC in a Ran-unassisted manner when it does not carry α-subunit/NLS substrate. Therefore, a requirement for Ran arises only when the β-subunit undergoes a translocation reaction together with the α-subunit/NLS substrate. The results provide an insight to the yet unsolved question regarding the mechanism by which proteins are directionally transported through the NPC, and the role of Ran in this process.

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Constitutive and interleukin-1 (IL-1)-inducible factors interact with the IL-1-responsive element in the IL-6 gene.

Isshiki¹,

Akira²,

Takahashi³

et al. 1990

Mol. Cell. Biol.

272

117

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The interleukin-6 (IL-6) promoter is rapidly and transiently activated with other cytokines, including IL-1, tumor necrosis factor, and platelet-derived growth factor, as well as phorbol esters and agents that increase intracellular cyclic AMP. In this study, we have investigated cis-acting regulatory elements and trans-acting factors responsible for IL-i-induced IL-6 gene expression. Studies on the 5' deletion mutants of the human IL-6 gene suggested that the IL-i-responsive element was mapped within the IL-6 promoter region (-180 to -123) which was homologous to the c-fos serum-responsive enhancer element. Gel retardation assay identified two types of nuclear factors that bound to this region, one constitutive and the other inducible. These two factors recognized a 14-base-pair (bp) palindromic sequence, ACATTGCACAATCT. Furthermore, three copies of this 14-bp palindrome conferred IL-1 responsiveness to the basal enhancerless IL-6 promoter, indicating that a 14-bp-dyad symmetry sequence was an IL-i-responsive element in the IL-6 gene.

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Endotoxic properties of chemically synthesized lipid A part structures. Comparison of synthetic lipid A precursor and synthetic analogues with biosynthetic lipid A precursor and free lipid A

Galanos¹,

Lehmann

Lüderitz³

et al. 1984

Eur J Biochem

170

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Synthetic lipid A part structures corresponding structurally to a biosynthetic lipid A disaccharide precursor have been analyzed for endotoxic activity in several systems in vivo and in vitro.It was found that a synthetic P-1,6-linked D-glucosamine disaccharide, which carries four molar equivalents of (R)-3-hydroxytetradecanoyl residues in positions 2, 3, 2' and 3' and phosphoryl groups in positions 1 and 4' (preparation 406), exhibited lethal toxicity, B lymphocyte mitogenicity, the capacity to engender prostaglandin formation in macrophages and to induce endotoxic tolerance, as well as serological lipid A antigenicity. On a weight basis, preparation 406 was of comparable activity to lipid A precursor and bacterial free lipid A. Preparation 406, like lipid A precursor, lacked, however, the ability to induce the local Shwartzman phenomenon and both preparations were of moderate pyrogenicity. Two further synthetic analogues which contained only one phosphoryl group (preparation 404 at C-4', preparation 405 at C-1) showed comparable or diminished activity depending on the test system employed, except in the capacity to inactivate complement where they exhibited, in contrast to preparation 406, significant activity.The results show that the endotoxic principle of lipopolysaccharides, as postulated previously is embedded in the lipid A component. Our results also suggest initial conclusions on the structural requirements for the expression of endotoxin activities.

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Structure-Activity Relationship of Lipid A: Comparison of Biological Activities of Natural and Synthetic Lipid A's with Different Fatty Acid Compositions1

Kanegasaki

Tanamoto

Yasuda

et al. 1986

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To investigate the structure-activity relationships, various biological activities, including pyrogenicity, lethal toxicity, elicitation of Shwartzman reaction, mitogenicity and tumor necrosis factor (TNF)-inducing activity, were compared among natural and synthetic lipid A's differing in fatty acid composition. In all these tests, natural lipid A's from Escherichia coli and Salmonella minnesota and synthetic LA-15-PP, which carries 3-hydroxy- and 3-acyloxy-tetradecanoyl groups at the 2, 3 and 2', 3' positions, respectively, showed the strongest activities among the tested lipid A's. In contrast, LA-16-PP, in which the amide-bound 3-hydroxytetradecanoic acid at position 2 of LA-15-PP is replaced by 3-hexadecanoyloxytetradecanoic acid, exhibited lower activity than LA-15-PP and natural lipid A's. Although LA-16-PP has been assumed to have a typical Salmonella lipid A structure (and, in fact, it has a structure corresponding to one of the components of Salmonella lipid A), the activity of this synthetic compound was not comparable to that of natural Salmonella lipid A. LA-17-PP, in which tetradecanoic acid is the sole fatty acid component, exhibited relatively strong mitogenicity and TNF-inducing activity, but very low pyrogenicity. The activities of LA-18-PP, which has ester-bound tetradecanoic acid and amide-bound 3-hydroxytetradecanoic acid, were lower than those of LA-17-PP. The results indicate that the differences in fatty acid composition of lipid A's have important influences on the biological activities studied.

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