Functional dissection of nuclear envelope mRNA translocation system: effects of phorbol ester and a monoclonal antibody recognizing cytoskeletal structures

Unidirectional transport of poly(A)-containing mRNA [poly(A)+ mRNA] through the nuclear envelope pore complex is thought to be an energy (ATP or GTP)-dependent process which involves a nuclear envelope nucleoside triphosphatase (NTPase). In the intact envelope, this enzyme is regulatable by poly(A) binding and by poly(A)-dependent phosphorylation/dephosphorylation of other components of the mRNA translocation system, which are as yet unidentified. Monoclonal antibodies (mAbs) were elicited against the poly(A) binding nuclear envelope fraction isolated from rat liver. The mAbs were screened for their modulatory effects on mRNA transport in vitro. One stable clone decreased the efflux of rapidly labeled RNA and of one specific mRNA (ovalbumin) from isolated nuclei. It increased the binding of poly(A) to the envelope and increased the maximal catalytic rate of the NTPase, but it did not alter the apparent Km of the enzyme or the extent of its stimulation by poly(A). The nuclear envelope-associated protein kinase that down-regulates the NTPase was inhibited by the antibody, while other protein kinases were not affected. Because both the NTPase and mRNA efflux were inhibited by the tumor promoter, 12-O-tetradecanoylphorbol 13-acetate, the sensitive kinase is probably protein kinase C. Protein kinase C was found to be associated with the isolated nuclear envelope. The antibody reacted with both a Mr 83,000 and a Mr 65,000 nuclear envelope polypeptide from rat liver and other tissues. By immunofluorescence microscopy in CV-1 cells, the antibody localized to the nuclear envelope and, in addition, to cytoplasmic filaments which show some superposition with the microfilament network.     

Differential effect of insulin and epidermal growth factor on the mRNA translocation system and transport of specific poly(A+) mRNA and poly(A-) mRNA in isolated nuclei

The efficiency of efflux of rapidly labeled poly(A)-containing mRNA from isolated rat liver nuclei was found to be modulated by insulin and epidermal growth factor (EGF) in a biphasic but opposite way. At physiological concentrations (10 pM insulin and 1 pM EGF), maximal stimulation of the transport rate by insulin (to 137%) and maximal inhibition by EGF (to 69%) were obtained; at higher concentrations (greater than 100 pM and greater than 10 pM, respectively), the amount of poly(A)-containing mRNA released into the postnuclear supernatant was nearly identical with the level found in untreated nuclei (= 100%). Using mRNA entrapped into closed nuclear envelope (NE) vesicles as a model system, it was found that the modulation of nuclear efflux of mRNA by the two growth factors occurs at the level of translocation through the nuclear pore. The NE nucleoside-triphosphatase (NTPase) activity, which is thought to mediate nucleocytoplasmic transport of at least some mRNAs, responded to insulin and EGF in the same manner as the mRNA transport rate. The increase in NTPase activity caused by insulin and the decrease in NTPase activity caused by EGF were found to be due to changes of the maximal catalytic rate; the Michaelis constant of the enzyme remained almost constant. Investigating the effect of the two growth factors on transport of specific mRNAs, poly(A)-containing actin mRNA was found to display the same alteration in efflux rate as rapidly labeled, total poly(A)-containing mRNA. In contrast, efflux of histone H4 mRNA, which lacks a 3'-poly(A) sequence, decreased in response to insulin and reached minimum levels at the same concentration at which maximum levels of actin mRNA transport rate were obtained. Studying the mechanism of action of insulin and EGF on NE mRNA translocation system, insulin was found to cause an enhancement of NE-associated phosphoprotein phosphatase activity, resulting in a dephosphorylation of the NE poly(A) binding site (= mRNA carrier) and, hence, in a decrease in its affinity to poly(A) [the poly(A) binding affinity of the poly(A)-recognizing mRNA carrier within the envelope is increased after phosphorylation]. EGF, on the other hand, stimulated the protein kinase, which phosphorylates the carrier, and, hence increased the NE poly(A) binding affinity. Because the stage of phosphorylation of the mRNA carrier (which is coupled with the NTPase within the intact NE structure) is inversely correlated with the activity of the NTPase, an enhancement of poly(A)-containing mRNA transport rate by insulin and an inhibition by EGF are observed.     

Evidence for a direct interaction of Rev protein with nuclear envelop mRNA-translocation system.

The interaction of the Rev protein from human immunodeficiency virus type 1 (HIV-1) with the nucleocytoplasmic mRNA-transport system was investigated. In gel-shift assay, the recombinant Rev protein used in this study selectively bound to the Rev-responsive element (RRE) region of HIV-1 env-specific RNA. Nitrocellulose-filter-binding studies and Northern/Western-blotting experiments revealed an association constant of approximately 1 x 10(10) M-1. The Rev protein also strongly bound to isolated nuclear envelopes from H9 cells, containing the poly(A)-binding site (= mRNA carrier) and the nucleoside triphosphatase (= NTPase), which are thought to be involved in nuclear export of poly(A)-rich mRNA. Binding of 125I-Rev to a 110-kDa nuclear-envelope protein, the putative mRNA carrier, could be demonstrated in in vitro experiments. Both efflux of cellular poly(A)-rich RNA, such as actin RNA [but not efflux of poly(A)-free RNA] from isolated nuclei and the nuclear-envelope NTPase activity were strongly inhibited by Rev protein. On the other hand, transport of viral env RNA, containing the Rev-responsive element, was increased in the presence of Rev. Studying the release of RNA from closed nuclear-envelope vesicles containing entrapped RNA, the action of Rev was found to occur at the level of translocation of RNA through the nuclear pore. Evidence is presented that Rev down-regulates the NTPase-driven transport of mRNA lacking the RRE, most likely via binding to the mRNA carrier within the envelope. In contrast to the efflux of RRE-free RNA, ATP-dependent efflux of RRE-containing RNA from resealed nuclear-envelope vesicles was found to be increased, if the RNA was entrapped in the vesicles together with Rev protein. In addition, it was found that phosphorylated Rev, which is transported together with RRE-containing RNA out of the vesicles, becomes dephosphorylated during transport. In the vesicle experiments it is demonstrated for the first time that a protein selectively channels a specific mRNA across the nuclear-envelope pore complex.     

Proteins from rat liver cytosol which stimulate mRNA transport. Purification and interactions with the nuclear envelope mRNA translocation system

Two polysome-associated proteins with particular affinities for poly(A) have been purified from rat liver. These proteins stimulate the efflux of mRNA from isolated nuclei in conditions under which such efflux closely stimulates mRNA transport in vivo, and they are therefore considered as mRNA-transport-stimulatory proteins. Their interaction with the mRNA-translocation system in isolated nuclear envelopes has been studied. The results are generally consistent with the most recently proposed kinetic model of mRNA translocation. One protein, P58, has not been described previously. It inhibits the protein kinase that down-regulates the NTPase, it enhances the NTPase activity in both the presence and the absence of poly(A) and it seems to increase poly(A) binding in unphosphorylated, but not in phosphorylated, envelopes. The other protein, P31, which probably corresponds to the 35,000-Mr factor described by Webb and his colleagues, enhances the binding of poly(A) to the mRNA-binding site in the envelope, thus stimulating the phosphoprotein phosphatase and, in consequence, the NTPase. The possible physiological significance of these two proteins is discussed.     

Studies on protein kinases involved in regulation of nucleocytoplasmic mRNA transport.

The rate of energy-dependent nucleoside triphosphatase (NTPase)-mediated nucleocytoplasmic translocation of poly(A)-containing mRNA [poly(A)+mRNA] across the nuclear envelope is thought to be regulated by poly(A)-sensitive phosphorylation and dephosphorylation of nuclear-envelope protein. Studying the phosphorylation-related inhibition of the NTPase, we found that phosphorylation of one polypeptide of rat liver envelopes by endogenous NI- and NII-like protein kinase was particularly sensitive to poly(A). This polypeptide (106 kDa) was also phosphorylated by nuclear-envelope-bound Ca2+-activated and phospholipid-dependent protein kinase (protein kinase C). Activation of kinase C by tumour-promoting phorbol esters resulted in inhibition of nuclear-envelope NTPase activity and in a concomitant decrease of mRNA (actin) efflux rate from isolated rat liver nuclei. Protein kinase C, but not nuclear envelope NI-like or NII-like protein kinase, was found to be solubilized from the envelope by Triton X-100, whereas the presumable poly(A)-binding site [the 106 kDa polypeptide, representing the putative carrier for poly(A)+mRNA transport] remained bound to this structure. RNA efflux from detergent-treated nuclei lost its susceptibility to phorbol esters. Addition of purified protein kinase C to these nuclei restored the effect of the tumour promoters. Protein kinase C was found to bind also to isolated rat liver nuclear matrices in the absence but not in the presence of ATP. The NII-like nuclear-envelope protein kinase co-purified together with the 106 kDa polypeptide which specifically binds to poly(A) in an ATP-labile linkage.     

Ribonucleic acid efflux from isolated mouse liver nuclei is altered by diet and genotypically determined change in nuclear envelope composition

Differences in immunological abnormalities like autoimmunity, abnormal T cell proliferative disorders and accelerated ageing occur between MRL/Mp-lpr/lpr(lpr/lpr) and MRL/Mp-+/+(+/+) mice as a consequence of one gene. The present study was designed to assess the effect of these differences in genotype and diet on the composition and function of the liver nuclear envelope. Mice of both strains were fed nutritionally adequate diets differing only in fatty acid composition for 4 weeks. Phospholipid fatty acid composition of the liver nuclear envelope was determined and the effect of altering the lipid composition of the nuclear membrane on nucleoside-triphosphatase (NTPase) activity, ribonucleic acid (RNA) efflux and binding of L-triiodothyronine (L-T3) was determined. Strain of mouse and level of dietary linoleic acid exhibited significant effects on the phospholipid fatty acid composition of the nuclear envelope. Levels of 18:1(n - 9) and 18:2(n - 6) were lower and 20:4(n - 6) content was higher in nuclear envelope phospholipids of lpr/lpr mice compared with mice of the +/+ strain. Mice fed the high linoleic acid diet exhibited higher levels of 18:0, 18:2(n - 6) and 20:4(n - 6) and lower levels of 16:0 and 18:1(n - 9) in liver nuclear envelope phospholipids, compared with mice fed the low linoleic acid diet. These changes in membrane composition were reflected in alteration of NTPase activity and efflux of RNA from isolated mouse liver nuclei. Nucleoside triphosphatase activity and efflux of ribonucleic acid from isolated nuclei were significantly higher in livers of the lpr/lpr strain. NTPase activity and RNA efflux from isolated nuclei were higher in the high linoleic acid fed group compared with the low linoleic acid group. A single class of binding sites for L-T3 was present in liver nuclear envelopes of these mice and Kd values were not influenced by strain or dietary linoleic acid levels. Nuclear envelopes prepared from +/+ animals exhibited a significantly higher number of binding sites for L-T3 compared with the lpr/lpr group. These observations indicate that the single gene difference characterizing lpr/lpr mice from +/+ mice results in alterations in the composition and function of the nuclear envelope. This genetic difference also alters the response of this membrane to dietary factors known to modulate characteristics and functions of the nuclear envelope.     

Diet fat alters the structure and function of the nuclear envelope: modulation of membrane fatty acid composition, NTPase activity and binding of triiodothyronine

Mice were fed a diet either high or low in P/S ratio to determine the effect of altering dietary lipid on the fatty acid composition of liver nuclear envelopes and thereby on functions of the nuclear envelope. Mice fed the high P/S diet exhibited higher levels of C18:2 omega 6 and unsaturates in liver nuclear envelopes, higher specific activity of NTPase and specific binding for L-triiodothyronine at 15 degrees C and 22 degrees C compared with the low P/S diet fed group. These observations indicate that diet-induced differences in the fatty acid composition of nuclear envelope lipid affects functions of the nuclear envelope.     

缺血／再灌注损伤对心肌细胞核膜NTPase活性和mRNA出核转运的影响

目的：观察家兔心肌缺血／再灌注（I／R）损伤对心肌细胞核膜核苷三磷酸酶（NTPase）动力学及mRNA出核转运的变化。方法：制备家兔离体心脏I／R模型,密度梯度离心法制备心肌细胞核膜,按Tiffany等的方法测定NTPase活性及mRNA的转运率。结果：心肌细胞核膜NTPase在以ATP或GTP为底物时,与对照组比较,I／R组最大反应速率（Vmax)分别降低26％及22％（P＜0．01）。Km值分别升高54％及72％（P＜0．01）;而缺血组Vmax及Km值较对照组无明显差异。以ATP或GTP启动反应时I／R组10min内心肌细胞核mRNA转出率分别较对照组降低27％及32％（P＜0．01）;而缺血组与对照组相比并无显著性差异（P＞0．05）。结论：心肌缺血／再灌注损伤时,心肌细胞核膜受损,核膜上NTPase活性降低,导致细胞核膜mRNA出核受阻,从而可能影响蛋白质的合成表达。     

Phospholipase A2 inhibits nuclear nucleoside triphosphatase activity and mRNA export in isolated nuclei from rat liver

The present study is undertaken to investigate whether the phospholipase A(2) (PLA(2)) influences mRNA nucleocytoplasmic transport evaluated by nucleoside triphosphatase (NTPase) activity and mRNA export in isolated hepatic nuclear envelope. Isolated hepatic nuclei from rat liver were exposed to PLA(2) (10(-5) approximately 10(-2)/ml) with or without incorporation of nuclei with phosphatidylcholine (PC) liposome. Messenger RNA exports and NTPase activities of nuclear membrane were assayed using ATP and GTP as substrates. We found that the RNA efflux, evaluated by [3H] uridine, was potently decreased in a concentration-dependent manner, by incubation of hepatic nuclei with PLA(2), regardless using ATP or GTP as substrates. The PC content in nuclear membrane was also decreased by PLA(2)-treatment. The PC was incorporated into the nuclear membrane by addition of phospholipid liposomes into the incubation mixture. PC incorporation into the nuclear membrane did not alter mRNA export. However this resulted in a significant increase in mRNA export rate in PLA(2)-treated group. Messenger RNA export rate in PLA(2) (10(-3) unit/mL)- treated nuclear membrane was positively correlated with level of PC incorporation, both using ATP and GTP as substrates. The activity of nucleoside triphosphatase, a nuclear membrane-associated enzyme, showed parallel variations with mRNA transport. It is concluded that nuclear PLA(2) plays a regulatory role in RNA transport, which can be antagonized by exogenous PC. These might be pathophysiologically significance, although the mechanisms by which this effect takes place remain to be clarified.     

Nuclear disintegration induced by cytotoxic T lymphocytes. Evidence against damage to the nuclear envelope of the target cell

CTL and NK cells induce nuclear disintegration in their target cells. This phenomenon, which is seen as extensive fragmentation and solubilization of target cell DNA, is not seen with most other means of inducing cytolysis, including antibody- and complement-mediated cytolysis. We have previously shown that the degree of DNA solubilization is dependent upon the nature of the target cell. We here investigate the possibility that CTL induce, in all targets, damage to the nuclear envelope, which in turn leads to nuclear disintegration in only some of them. We reasoned that damage to the nuclear envelope would render nuclear DNA more accessible to exogenous DNase. Therefore, we determined the susceptibility of target DNA to exogenous DNase I after cytolysis by various means. We found no difference in DNA susceptibility for cells lysed by CTL vs methods (such as complement-mediated lysis or nonionic detergent) incapable of inducing nuclear disintegration. As a positive control, freezing and thawing dramatically enhanced susceptibility of the DNA. In conclusion, we found no evidence that the nuclear envelope is damaged by CTL in target cell types (or in the subpopulation of nuclei) that do not undergo nuclear disintegration.     

Limited expression of nuclear pore membrane glycoprotein 210 in cell lines and tissues suggests cell-type specific nuclear pores in metazoans

The nuclear pore complex (NPC) is the only known gateway for nucleocytoplasmic traffic. The nuclear pore membrane glycoprotein 210 (POM210/gp210) is considered to be important for the assembly and structure of pore complexes in metazoan cells. However, here we demonstrate cell-type specific expression of the gp210 protein during mouse organogenesis. As shown previously for its mRNA, distinct expression of the gp210 was seen in developing epithelia and some other cell types, whereas it was undetectable in nuclei of several other embryonic tissue compartments. In sharp contrast, monoclonal antibody 414 recognizing four non-membrane nucleoporins, stained the nuclear envelope of all cell types. In four cultured mouse cell lines, gp210 mRNA and protein were below detection levels, in contrast to some other nucleoporins tested. Distinct expression of gp210 mRNA and protein was seen in cultured mouse embryonic stem (ES) cells. These findings support the view of cell-type specific NPCs in metazoans and that the gp210 gene is regulated by cell-type specific control elements not shared by other nucleoporins. Although it cannot be excluded that very low expression levels of gp210 are sufficient to allow attachment of NPCs, a more likely alternative is that it has cell-type specific functions.     

RNA metabolism in isolated nuclei: processing and transport of immunoglobulin light chain sequences

Transport of prelabeled RNA from isolated myeloma nuclei is studied using conditions that permit RNA synthesis. Cytosol and spermidine are not required to maintain nuclear stability and inhibited RNA release. Omission of ATP or GTP decreased release 25 to 40%. The stimulatory effect of ATP or GTP is not due to hydrolysis of the triphosphates by the nuclear envelope NTPase, since addition of quercetin (an inhibitor of this NTPase) has no effect on the quantity of RNA released. The size distribution and percentage of poly A-containing species released from nuclei incubated with or without ATP or the other rNTPs are identical. Hybridization analysis of nuclear RNA before the transport assay revealed mature and precursor k light chain mRNA sequences. Following the transport assay, a significant fraction of k mRNA precursors is chased into mature k mRNA which is found both in nuclear-retained and released RNA.     

Photoaffinity labelling of a nuclear matrix nucleoside triphosphatase and its modulation in the acute-phase response

Photoaffinity labelling has been used to identify the major nuclear matrix nucleoside triphosphatase (NTPase) as a 46 kD polypeptide, which appears to represent the same polypeptide photolabelled in nuclear envelope. Nuclear matrix NTPase and its photolabelling were selectively decreased in the acute phase response of rat liver, which also encompasses decreases (30%) in RNA transport in vitro and nuclear envelope NTPase. These results, and quantitative considerations suggest that the NTPase correlatively linked to RNA transport is not solubilized by detergents; it appears to represent a nuclear matrix component.     

Angiotensin II stimulates phosphorylation of nuclear lamins via a protein kinase C-dependent mechanism in cultured vascular smooth muscle cells

Angiotensin II (ang II) induces c-fos gene expression in part via a protein kinase C-dependent mechanism in cultured vascular smooth muscle cells (VSMC). However, little is known about the mechanisms by which protein kinase C regulates nuclear functions. We examined the ability of ang II to phosphorylate nuclear lamina proteins in VSMC and the possibility that protein kinase C is involved in these putative phosphorylation events. Ang II stimulated the phosphorylation of Triton X-100- and high salt-insoluble nuclear envelope proteins with molecular weights of 70,000, 67,000, and 60,000. These proteins were identified as lamins A, B, and C, respectively, based on their mobilities on two-dimensional gel electrophoresis and interaction with antibodies to lamins as detected by immunoblot analyses. After a 2-min delay, phosphorylation levels of lamins increased, peaked at 20-30 min, and were sustained for at least 60 min after ang II stimulation. The threshold, half-maximal, and maximal concentrations of ang II which induced phosphorylation of lamins were 0.1, 0.5-1, and 100 nM, respectively. Phorbol 12-myristate 13-acetate also induced these reactions, whereas ionomycin did not. Down-regulation of protein kinase C by prolonged treatment with phorbol 12,13-dibutyrate attenuated ang II-induced phosphorylation of lamins. In vitro phosphorylation of nuclear envelope proteins by protein kinase C revealed that lamins served as substrates for this enzyme. These results indicate that ang II induces phosphorylation of lamins in cultured VSMC and suggest that protein kinase C is either directly or indirectly involved in these reactions. The results raise the possibility that phosphorylation of nuclear proteins is one of the important steps by which the protein kinase C signaling pathway regulates agonist-induced nuclear events.     

Energy requirement and kinetics of transport of poly(A)-free histone mRNA compared to poly(A)-rich mRNA from isolated L-cell nuclei

ATP-promoted efflux of poly(A)-rich RNA from isolated nuclei of prelabeled mouse lymphoma L5178y cells has an activation energy of 51.5 kJ/mol, similar to that found for the nuclear envelope nucleoside triphosphatase (48.1 kJ/mol) assumed to be involved in mediating nucleocytoplasmic transport of at least some RNA. Here we show that efflux of two specific poly(A)-rich mRNAs (actin and beta-tubulin) from isolated L-cell nuclei is almost totally dependent on the presence of ATP, while efflux of poly(A)-free histone mRNA (H4, H2B, and H1) also occurs to a marked extent in the absence of this nucleotide. Measurements of temperature dependence of transport rate revealed an activation energy of 56.1 kJ/mol for actin mRNA, while the activation energy for histone-H4-mRNA efflux was in the same range as that found for ATP-induced release of RNA from demembranated nuclei (about 15-20 kJ/mol). Addition of nonhydrolyzable nucleotide analogs of ATP to the in vitro system used for measurement of RNA transport did not result in release of nonhistone mRNA (actin), but enhanced the efflux of H4 mRNA to approximately the same extent as ATP. Although not absolutely required, addition of ATP stimulated the rate of export of histone mRNA about twofold. Only the poly(A)-rich RNA, but not the poly(A)-free RNA, released from isolated nuclei was found to compete with poly(A) for the nuclear envelope mRNA-binding site, indicating the mechanism of transport for both RNA classes to be distinct. Export of both nonhistone and histone mRNA was found to be inhibited by a monoclonal antibody against a p60 nuclear-pore-complex antigen. This antibody had no effect on the nucleoside triphosphatase, mediating transport of poly(A)-rich mRNA.     

Nuclear cholesterol content and nucleoside triphosphatase activity are altered in the JCR:LA-cp corpulent rat

A nuclear pore complex-associated nucleoside triphosphatase (NTPase) activity is believed to provide energy for nuclear export of poly(A)+ mRNA. This study was initiated to determine if nuclear membrane lipid composition is altered during chronic hyperlipidemia, and what effect this has on NTPase activity. The JCR:LA-cp corpulent rat model is characterized by severe hypertriglyceridemia and moderate hypercholesterolemia, and thus represents an ideal animal model in which to study nuclear cholesterol and NTPase activity. NTPase activity was markedly increased in purified hepatic nuclei from corpulent female JCR:LA-cp rats in comparison to lean control rats as a function of assay time, [GTP], [ATP], and [Mg²⁺]. Nuclear membrane cholesterol and phospholipid content were significantly elevated in the corpulent animals. Nuclei of corpulent animals were less resistant to salt-induced lysis than nuclei of lean animals, suggesting a change in relative membrane integrity. Together, these results indicate that altered lipid metabolism in a genetic corpulent animal model can lead to changes in nuclear membrane lipid composition, which in turn may alter nuclear membrane NTPase activity and integrity. © 1996 Wiley-Liss, Inc.