Monovalent cation dependence of tissue plasminogen activator synthesis by HeLa cells

HeLa cells synthesize and secrete increased levels of tissue plasminogen activator (tPA) when incubated for 18 h with 10-20 nM phorbol myristate acetate. This response was inhibited by a number of conditions which affect intracellular Na+ and K+ concentrations. Removing extracellular Na+, while maintaining isotonicity with choline+, reduced the secretion of both functional and antigenic tPA in a linear fashion. A series of cardiac glycosides and related compounds strongly inhibited tPA secretion with the following rank order of potency: digitoxin = ouabain greater than digoxin greater than digitoxigenin greater than digoxigenin greater than digitoxose greater than digitonin. These compounds also inhibited cellular Na+/K+-ATPase activity over an identical concentration range. Two compounds which selectively increase cellular permeability to K+, valinomycin, and nigericin, strongly inhibited tPA secretion, with IC50 values of approximately 50 nM. In contrast, monensin, which selectively increases cellular permeability to Na+, was much less active. Valinomycin, but not nigericin, also inhibited cellular Na+/K+-ATPase activity. Phorbol myristate acetate, 5-20 nM, increased Na+/K+-ATPase activity up to 2-fold and tPA secretion up to 15-fold. We conclude that the secretion of tPA by HeLa cells treated with phorbol myristate acetate proceeds via a mechanism which requires extracellular Na+ and a functional Na+/K+-ATPase ("sodium pump") enzyme.     

Guanidine-sensitive Na+ accumulation by poliovirus-infected HeLa cells.

The Na+ content of poliovirus-infected HeLa S3 cells increased during the late phase of virus replication, after virus inhibition of host cell protein synthesis and in coincidence with late viral functions. Guanidine hydrochloride blocked the rise in Na+ content, whereas the antiguanidine agent choline fully reversed the guanidine block. Expression of one or more late viral functions was essential for Na+ accumulation to occur because accumulation was inhibited by cycloheximide or guanidine added to the infected culture during the late phase. Increased adenosine triphosphatase activity appears to be primarily responsible for Na+ accumulation by virus-infected cells.     

Translation of capped viral mRNAs in poliovirus-infected HeLa cells.

HeLa cells doubly infected with Semliki Forest virus (SFV) and poliovirus synthesize either more poliovirus proteins or more SFV late proteins depending on the time of super-infection with poliovirus. Under some conditions, the infected cells translate uncapped poliovirus mRNA and capped 26S mRNA from SFV simultaneously, even though host protein synthesis has been shut down. Vesicular stomatitis virus (VSV) protein synthesis is depressed drastically when VSV-infected cells are super-infected with poliovirus. In cells doubly infected with VSV and encephalomyocarditis (EMC) virus or with VSV and SFV, dominance of one of the viruses depends on the time of addition of the challenge virus. The influence of external conditions on the relative translation of capped or uncapped viral mRNA in doubly infected cells has also been analysed.     

Isolation and structural characterization of cap-binding proteins from poliovirus-infected HeLa cells.

In poliovirus-infected HeLa cells, poliovirus RNA is translated at times when cellular mRNA translation is strongly inhibited. It is thought that this translational control mechanism is mediated by inactivation of a cap-binding protein complex (comprising polypeptides of 24 [24-kilodalton cap-binding protein], 50, and approximately 220 kilodaltons). This complex can restore the translation of capped mRNAs in extracts from poliovirus-infected cells. We have previously shown that the virally induced defect prevents interaction between cap recognition factors and mRNA. Here, we show that the cap-binding protein complex (and not the 24-kilodalton cap-binding protein) has activity that restores the cap-specific mRNA-protein interaction when added to initiation factors from poliovirus-infected cells. Thus, the activity that restores the cap-specific mRNA-protein interaction and that which restores the translation of capped mRNAs in extracts from poliovirus-infected cells, copurify. The results also indicate, by an alternative assay, that the cap-binding protein complex is the only factor inactivated by poliovirus. We also purified cap-binding proteins from uninfected and poliovirus-infected HeLa cells. By various criteria, the 24-kilodalton cap-binding protein is not structurally modified as a result of infection. However, the 220-kilodalton polypeptide of the cap-binding protein complex is apparently cleaved by a putative viral (or induced) protease. By in vivo labeling and m7GDP affinity chromatography, we isolated a modified cap-binding protein complex from poliovirus-infected cells, containing proteolytic cleavage fragments of the 220-kilodalton polypeptide.     

Monovalent cation effects on intermolecular purine-purine-pyrimidine triple-helix formation.

The binding of a 19-mer guanosine-rich oligodeoxyribonucleotide, TG3TG4TG4TG3T (ODN 1), to a complementary polypurine DNA target was investigated by DNase I footprinting and restriction endonuclease protection assays. Monovalent cations inhibited intermolecular purine-purine-pyrimidine triple-helical DNA formation, with K+ and Rb+ being most effective, followed by NH4+ and Na+. Li+ and Cs+ had little to no effect. Similar results were observed with the G/A-rich oligonucleotide AG3AG4AG4AG3AGCT. Kinetic studies indicated that monovalent cations interfered with oligonucleotide-duplex DNA association but did not significantly promote triplex dissociation. The observed order of monovalent cation inhibition of triplex formation is reminiscent of their effect on tetraplex formation with G/T-rich oligonucleotides. However, using electrophoretic mobility shift assays we found that the oligonucleotide ODN 1 did not appear to form a four-stranded species under conditions promoting tetraplex formation. Taken together, our data suggest that processes other than the self-association of oligonucleotides into tetraplexes might be involved in the inhibitory effect of monovalent cations on purine-pyrimidine-purine triplex formation.     

Variations in cap-binding complexes from uninfected and poliovirus-infected HeLa cells

Poliovirus infection of HeLa cells results in cleavage of the p220 subunit of eukaryotic initiation factor eIF-4F and inhibits cap-dependent initiation of protein synthesis. To examine the effect of virus-induced inhibition on the structure of initiation factor complexes involved in cap binding, the polypeptide compositions of cap affinity-purified complexes from uninfected and poliovirus-infected HeLa cells were analyzed. Monoclonal antibodies directed against p220 and an eIF-3 subunit, p170, were utilized to locate eIF-3 and eIF-4F on sucrose gradients and in fractions eluting from cap analog columns. This approach resulted in the purification of several different cap-binding complexes from different cellular subfractions and revealed significant differences in their composition after infection. The results indicate that eIF-3 and eIF-4F bind to the cap structure, possibly in the form of a complex, and that a modified form of eIF-3 alone has some cap-binding activity in the complete absence of p220, eIF-4A, and eIF-4E. Ribosome-derived complexes containing cleaved p220 are no longer associated with eIF-3 or eIF-4A, and a significant amount of cleaved p220 is associated with a unique cytoplasmic cap-binding complex. The cytoplasmic complex also contains Mr = 170,000 and 80,000 polypeptides, neither of which are major components of eIF-4F. These results demonstrate significant variation in the composition of cap-binding complexes from both infected and uninfected cells. They indicate that eIF-3 might play a direct role in cap binding and suggest that poliovirus-induced cleavage of p220 results in the release of the eIF-4A subunit from eIF-4F and abolishes an association between eIF-4F and eIF-3 which may function during the multifactor steps involved in initiation of cap-mediated translation.     

The cap-binding protein complex in uninfected and poliovirus-infected HeLa cells

In poliovirus-infected HeLa cells, the mechanism of protein synthesis initiation factor recognition of m7G cap groups on mRNA is impaired. Translation of capped host cell mRNAs is inhibited, whereas translation of uncapped poliovirus mRNA proceeds exclusively. The site of this defect has been localized to the cap-binding protein complex (CBPC). To elucidate the specific structural and functional defects of the CBPC following poliovirus infection, the CBPC and/or its polypeptide components were purified from uninfected and poliovirus-infected HeLa cells. The CBPC from uninfected cells consisted of tightly associated 24- and 220-kDa polypeptides; minor amounts of polypeptides of 40, 44, and 80 kDa also consistently co-purified with the p24/p220 cores. No evidence of a 50-kDa, eIF-4A-related polypeptide subunit of the CBPC was obtained. The CBPC from poliovirus-infected cells had undergone major structural alterations. The 220-kDa component was absent; antigenically related (100-130 kDa) degradation products were present instead. The 24-kDa component co-purified with the p220 degradation products, but other components were missing. The association of the infected cell CBPC components was quite labile compared with that demonstrated by the components of CBPC from uninfected cells. Differential stimulation of capped, but not uncapped mRNAs in a cell-free translation assay was demonstrated by unmodified CBPC. Conversely, modified CBPC from poliovirus-infected cells differentially stimulated in vitro translation of uncapped poliovirus mRNA but not capped mRNAs. The implications of these results for the mechanism of cap-independent translation are briefly discussed.     

Monovalent cation activation of tryptophanase.

The interaction of monovalent cations with holotryptophanase has been examined by spectral and kinetic methods. Using S-orthonitrophenyl-L-cysteine as a substrate, activation by the following monovalent cations was demonstrated; values of KA (mM, in italics) and Vmax (mumol min-1 mg) aare given in parentheses: Li+ (54 +/- 11.6, 4.3 +/- 0.28), Na+ (40 +/- 0.03, 18) K+ (1.44 +/- 0.06, 41.1 +/- 3.5), Tl+ (0.95 +/- 0.1, 39 +/- 4.4), NH4+ (0.23 +/- 0.01, 57.9 +/- 2.6), Rb+ (3.5 +/- 0.3, 33.5 +/- 1.8), Cs+ (14.6 +/- 2.6, 21 +/- 2.3). It was demonstrated by circular dichroic spectra that the competitive inhibitor, ethionine, interacts with the holoenzyme in the absence of activating monovalent cations, although it does not undergo labilization of the alpha proton. On addition of monovalent cation to the holoenzyme-ethionine complex, a marked increase occurs in absorption of 508 nm resulting from labilization of the alpha proton with formation of the quinoid form of the pyridoxal phosphate moiety of the enzyme-substrate complex at the catalytic center (Morino, Y., and Snell, E.E. (1967) J. Biol. Chem; 242, 2800-2809. The extent of formation of this quinoid intermediate was linearly related to the maximum velocity observed with each cation except NH4+, which was anomalously active. When measured at 500 nm, the change in absorption ranged from deltaA = 0.45 mg-1 of tryptophanase for NH4+ to 0.06 mg-1 for Li+. Two moles of thallium (I) were bound per mole of subunit. The data are most consistent with the interaction of monovalent cation at or near the catalytic center in such a way that it either participates directly in the reaction or is required for the critical alignment of one or more functional groups necessary for catalysis.     

Initiation of protein synthesis in vivo in poliovirus-infected HeLa cells

Initiation of protein synthesis in vivo in poliovirus-infected HeLa cells has been studied. When these cells are synchronized for initiation by fluoride treatment and then double labeled with [³⁵S]methionine and either tritiated proline, phenylalanine, or valine for short pulses, the percentage of N-terminal methionine incorporated in the nascent peptides compared to total incorporation is significantly higher than that of the tritiated amino acids tested. The data indicate that methionine is the initiator amino acid for the synthesis of poliovirus-specific proteins.     

Presence of the cap-binding protein in initiation factor preparations from poliovirus-infected HeLa cells.

Crude preparations of initiation factors from mock-infected and poliovirus-infected HeLa cells were analyzed for the presence of proteins which could be cross-linked to the 5' cap group of mRNA. A protein having an apparent molecular weight of 26,000, similar to the cap-binding protein in rabbit reticulocytes described by Sonenberg and Shatkin (Proc. Natl. Acad. Sci. U.S.A. 75:4843-4847, 1978), was found in the ribosomal salt wash from both uninfected and infected cells. Cross-linking of this polypeptide was inhibited by the cap analog m7GMP. In addition, cross-linking of a protein having an approximate molecular weight of 60,000 was similarly inhibited by cap analog. The smaller cap-binding protein fractionated in a 0 to 40% ammonium sulfate precipitate of ribosomal salt wash; the larger protein was found in the 40 to 70% ammonium sulfate fraction. Although the cap-binding proteins were present in both mock-infected and poliovirus-infected ribosomal salt wash, only preparations from uninfected HeLa cells were able to restore translation of capped vesicular stomatitis virus mRNA by extracts prepared from poliovirus-infected cells.     

Monovalent cation binding to cubic insulin crystals.

Two localized monovalent cation binding sites have been identified in cubic insulin from 2.8 A-resolution difference electron density maps comparing crystals in which the Na+ ions have been replaced by Tl+. One cation is buried in a closed cavity between insulin dimers and is stabilized by interaction with protein carbonyl dipoles in two juxtaposed alternate positions related by the crystal dyad. The second cation binding site, which also involves ligation with carbonyl dipoles, is competitively occupied by one position of two alternate His B10 side chain conformations. The cation occupancy in both sites depends on the net charge on the protein which was varied by equilibrating crystals in the pH range 7-10. Detailed structures of the cation binding sites were inferred from the refined 2-A resolution map of the sodium-insulin crystal at pH 9. At pH 9, the localized monovalent cations account for less than one of the three to four positive counterion charges necessary to neutralize the negative charge on each protein molecule. The majority of the monovalent counterions are too mobile to show up in the electron density maps calculated using data only at resolution higher than 10 A. Monovalent cations of ionic radius less than 1.5 A are required for crystal stability. Replacing Na+ with Cs+, Mg++, Ca++ or La+++ disrupts the lattice order, but crystals at pH 9 with 0.1 M Li+, K+, NH4+, Rb+ or Tl+ diffract to at least 2.8 A resolution.     

Calcium metabolism in HeLa cells and the effects of parathyroid hormone

Calcium metabolism was investigated in HeLa cells. 90% of the calcium of the cell monolayer is bound to an extracellular cell coat and can be removed by trypsin-EDTA. The calcium concentration of the naked cell, freed from its coat, is 0.47 mM. The calcium concentration of the medium does not affect the concentration of the naked cell calcium. However, the calcium of the cell coat is proportional to the calcium concentration in the medium. Calcium uptake into the cell coat increases with increasing calcium concentration of the medium, whereas uptake by the naked cell is independent of the calcium of the medium. Anaerobic conditions and metabolic inhibitors do not inhibit calcium uptake by the cell, a fact suggesting that this transfer is a passive phenomenon. The calcium in the extracellular cell coat, was not affected by parathyroid hormone. In contrast, the hormone increased the cellular calcium concentration by stimulating calcium uptake or by enhancing calcium binding to some cell components. These results suggest that, contrary to current thinking, parathyroid hormone influences the cellular calcium balance by mobilizing calcium from the extracellular fluids in order to increase its concentration in some cellular compartment. It is proposed that these effects can enhance calcium transport.