Modulation of alkaline phosphatases in LoVo, a human colon carcinoma cell line

LoVo, a continuous cell line derived from a human colon carcinoma produces two alkaline phosphatases: the heat-labile, L-homoarginine-insensitive, intestinal form, characteristic of its tissue of origin and the heat-stable, term-placental form, ectopically produced by a variety of tumors. Under basal conditions the activity levels of both enzymes are similar. Hyperosmolality and sodium butyrate induce increased levels of activity of the two alkaline phosphatases in a disparate fashion; whereas hyperosmolality augments the activity of both to the same extent, the effect of butyrate is more pronounced on the activity of the intestinal enzyme. When the two inducers are combined, induction of term-placental alkaline phosphatase is additive and that of the intestinal enzyme is synergistic. The effect of hyperosmolality is blocked by cycloheximide, and induction by sodium butyrate is inhibited by thymidine, cordycepin and cycloheximide. The known alkaline phosphatase inducer, prednisolone, has no effect on the enzymes of LoVo cells. Our results suggest that in these tumor cells the activity levels of the closely homologous term-placental and intestinal alkaline phosphatases appear to be independently controlled.     

Preferential alkaline phosphatase isoenzyme induction by sodium butyrate

SW-620, a continuous cell line derived from a poorly differentiated human colon carcinoma, produces two alkaline phosphatases. Under basal conditions the heat-stable, term-placental is the major isoenzyme and the heat-labile, liver/bone/kidney form represents a minor component. Exposing SW-620 cells to sodium butyrate causes induction of increased levels of activity accompanied by a striking shift in isoenzyme distribution not observed heretofore. The activity increase is accounted for entirely by augmentation of the liver/bone/kidney isoenzyme, with the term-placental form not being affected. Two other known alkaline phosphatase inducers, prednisolone and hyperosmolality, do not influence specific activity and isoenzyme distribution. The preferential induction of the liver/bone/kidney form of alkaline phosphatase in SW-620 cells may reflect a butyrate-elicited expression of a more differentiated state.     

Spectroscopic and kinetic evidence for a cyclic geminal diamine intermediate in the reaction of O-aminoserine with pyridoxal 5'-phosphate in alkali

HT-29, a cell line derived from a human colon carcinoma, exhibits very low alkaline phosphatase activity. The enzyme is thermolabile and is of the intestinal type. Hyperosmolality and/or sodium butyrate induce increased levels of activity. The increase is most pronounced with HT-29 cells growing in hyperosmolar medium containing sodium butyrate. Under these conditions specific activity rises over 1000-fold. The effect of hyperosmolality is blocked by cycloheximide and that of sodium butyrate by thymidine, cordycepin, and cycloheximide. By contrast to other human cancer cell lines, the enzyme of HT-29 is not influenced by cell density and glucocorticoid hormones. 5-Bromo-2′-deoxyuridine and inhibitors of DNA synthesis cause a slight increase in specific activity.     

Alkaline phosphatase protein increases in response to prednisolone in HeLa cells.

Quantification of term-placental alkaline phosphatase isoenzyme protein in HeLa TCRC-1 cells grown in the presence and absence of prednisolone indicates that there is a net increase in amount of enzyme-specific protein in prednisolone-stimulated cells. In a similar analysis of HeLa D98AH2 cells, prednisolone treatment causes the appearance of term-placental alkaline phosphatase protein and the loss of the intestinal isoenzyme protein. These results support the interpretation that the response of these cells to corticosteroids is the net accumulation of alkaline phosphatase protein rather than the modification of pre-existing enzyme to a more active state.     

Effect of pyrimidine deoxynucleosides and sodium butyrate on expression of the glycoprotein hormone alpha-subunit and placental alkaline phosphatase in HeLa cells

Production of the glycoprotein hormone common alpha-subunit and placental alkaline phosphatase activity can be modulated in HeLa cells by a variety of deoxynucleosides. Dose response curves for thymidine (Thd), fluorodeoxyuridine (FdUrd), bromodeoxyuridine (BrdUrd) and iododeoxyuridine (IdUrd) demonstrate that, in general, alkaline phosphatase was increased by lower concentrations of inducer than was alpha-subunit. The deoxynucleosides were not as effective as sodium butyrate as inducers of either protein. Whereas Thd and the halogenated dUrd derivatives enhanced protein expression, deoxycytidine (dCyd) had negative effects. Induction by deoxynucleosides of both alkaline phosphatase and alpha-subunit was inhibited by dCyd, but induction of alkaline phosphatase by butyrate was more sensitive to dCyd inhibition than was the butyrate-mediated induction of alpha-subunit. These results suggest that the two proteins are not regulated in a coordinate manner. Reversal of alkaline phosphatase induction by dCyd was not observed in cells preincubated with sodium butyrate for 6-24 h before the addition of dCyd, indicating that the deoxynucleoside interferes with an early event in the butyrate-mediated response. Combinations of butyrate with Thd, BrdUrd or IdUrd were synergistic with respect to the induction of HeLa-alpha. It is concluded that incorporation of the deoxynucleosides into DNA may not be required for the synergistic response since 2',5'-dideoxythymidine was an effective as Thd. Cytoplasmic dot hybridizations demonstrate that a primary effect of the various effectors is to increase the steady-state levels of alpha-subunit mRNA. There was a good correlation between alpha-subunit accumulation and corresponding levels of alpha-mRNA, suggesting that regulation occurs at a pretranslational site. Although the mechanism(s) is not understood, these data provide evidence that nucleosides or their derivatives can significantly affect gene expression.     

Increased alkaline phophatase activity in HeLa cells mediated by aliphatic monocarboxylates and inhibitors of DNA synthesis

Alkaline phosphatese activity of HeLa cells is increased from 3- to 8-fold during growth in medium with certain aliphatic monocarboxylates. The four-carbon fatty acid salt, sodium butyrate, is the most effective “inducer” with propionate (C₃), pentanoate (C₅) and hexanoate (C₆) having lesser effects. Other straight-chain aliphatic monocarboxylates, branched-chain analogues of inducers, hydroxylated derivatives, and metabolytes structurally related to butyrate are ineffective in mediating an increase in enzyme activity, indicating stringent structural requirements for inducers. The kinetics of increase in alkaline phosphatase activity in HeLa cells shows a 20–30 h lag period after adding the aliphatic acid followed by a rapid linear increase of enzyme activity. Protein synthesis is required for “induction”. The isozyme of HeLa alkaline phosphatase induced by monocarboxylates is the carcinoplacental form of the enzyme as determined by stereospecific inhibition by the l-enantiomorphs of phenylalanine and tryptophan, heat stability, and immunoreactivity with antibody against the human placental enzyme.Monocarboxylates that mediate increased alkaline phosphatase activity inhibit HeLa cell multiplication. Inhibition of HeLa cell growth may be necessary for induction and this hypothesis is supported by the findings that three different inhibitors of DNA synthesis, i.e. hydroxyurea, 1-β-d-arabinfuranosyl cytosine and methotrexate, also increase alkaline phosphatase activity. These inhibitors are synergistic with butyrate in causing HeLa cells to assume a more spindle-like shape and in producing an up-to 25-fold increase of enzyme activity. Studies on the modulation of carcinoplacental alkaline phosphatase by monocarboxylates commonly used as antimicrobial food additives and by anti-neoplastic agents may provide methods to evoke “tumor markers” of human occult malignancies. These drug-induced elevations of fetal isozyme activity may further our understanding of gene expression in human cells.     

Effect of pyrimidine deoxynucleosides and sodium butyrate on expression of the glycoprotein hormone α-subunit and placental alkaline phosphatase in HeLa cells

Production of the glycoprotein hormone common α-subunit and placental alkaline phosphatase activity can be modulated in HeLa cells by a variety of deoxynucleosides. Dose response curves for thymidine (Thd), fluorodeoxyuridine (FdUrd), bromodeoxyuridine (BrdUrd) and iododeoxyuridine (IdUrd) demonstrate that, in general, alkaline phosphatase was increased by lower concentrations of inducer than was α-subunit. The deoxynucleosides were not as effective as sodium butyrate as inducers of either protein. Whereas Thd and the halogenated dUrd derivatives enhanced protein expression, deoxycytidine (dCyd) had negative effects. Induction by deoxynucleosides of both alkaline phosphatase and α-subunit was inhibited by dCyd, but induction of alkaline phosphatase by butyrate was more sensitive to dCyd inhibition than was the buryrate-mediated induction of α-subunit. These results suggest that the two proteins are not regulated in a coordinate manner. Reversal of alkaline phosphatase induction by dCyd was not observed in cells preincubated with sodium butyrate for 6–24 h before the addition of dCyd, indicating that the deoxynucleoside interferes with an early event in the butyrate-mediated response. Combinations of butyrate with Thd, BrdUrd or IdUrd were synergistic with respect to the induction of HeLa-α. It is concluded that incorporation of the deoxynucleosides into DNA may not be required for the synergistic response since 2′,5′-dideoxythymidine was an effective as Thd. Cytoplasmic dot hybridizations demonstrate that a primary effect of the various effectors is to increase the steady-state levels of α-subunit mRNA. There was a good correlation between α-subunit accumulation and corresponding levels of α-mRNA, suggesting that regulation occurs at a pretranslational site. Although the mechanism(s) is not understood, these data provide evidence that nucleosides or their derivatives can significantly affect gene expression.     

Induction of alkaline phosphatase activity in HeLa cells by sodium butyrate.

The induction of HeLa cell alkaline phosphatase activity by sodium butyrate could be inhibited by the coadministration of caffeine or theophylline. The inhibitions were dose dependent, and at any given concentration the potency was theophylline greater than caffeine. Although the induction by sodium butyrate was more sensitive to the inhibition by the xanthines than was that produced by 5-iodo-2'-deoxyuridine, the magnitudes of the increases in cyclic AMP concentrations after treatment with the xanthines were similar in the inhibition of both types of induction. The induction of alkaline phosphatase activity by sodium butyrate also produced a shift in the thermostability pattern of the enzyme, with a proportionately greater increase in the heat-labile, rather than heat-stable, form of the activity.     

Alkaline phosphatase activity in cultured urinary bladder cancer cells.

Established cell lines derived from human urinary bladder carcinomas produce heat-stable alkaline phosphatase [orthophosphoric-monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1] which resembles the oncofetal enzyme of HeLa S3. Rat bladder cancer cell lines derived from chemically induced tumors produce heat-labile alkaline phosphatase. Corticosteroids and/or hyperosmolality do not influence the enzyme of rodent cells, but induce increased levels of activity in human cells. The increase is most pronounced when human cells multiply in hyperosmolar medium containing prednisolone. Under these conditions a rise of over 100-fold in specific activity is noted. This synergistic effect, not seen with other cultured heteroploid cells, may represent a specific characteristic of cells derived from human bladder tumors.     

Induction of alkaline phosphatase activity in HeLa cells by sodium butyrate

Summary The induction of HeLa cell alkaline phosphatase activity by sodium butyrate could be inhibited by the coadministration of caffeine or theophylline. The inhibitions were dose dependent, and at any given concentration the potency was theophylline > caffeine. Although the induction by sodium butyrate was more sensitive to the inhibition by the xanthines than was that produced by 5-iodo-2′-deoxyuridine, the magnitudes of the increases in cyclic AMP concentrations after treatment with the xanthines were similar in the inhibition of both types of induction. The induction of alkaline phosphatase activity by sodium butyrate also produced a shift in the thermostability pattern of the enzyme, with a proportionately greater increase in the heat-labile, rather than heat-stable, from of the activity. Supported by National Cancer Institute Grant CA16460.     

Induction of alkaline phosphatase activity by synergistic action of dibutyryl cyclic adenosine monophosphate, prednisolone, butyrate and sodium chloride in cultured cells

Human urinary bladder carcinoma cells (JTC-32) retain a low alkaline phosphatase activity. Prednisolone or a hypertonic concentration of NaCl caused a moderate increase in the activity (10- to 15-fold of control), but dibutyryl cAMP or butyrate did not. Examination of the combined effect of these four agents revealed that they acted synergistically in any combination. When the cells were incubated with the four agents together, the enzyme activity increased 60- to 250-fold. Serum also contributed to this synergistic increase. These agents slightly inhibited cell growth and protein synthesis. The enzyme induction was completely inhibited by cycloheximide or actinomycin D. The synergistic effect of the four agents on the enzyme activity was also observed in other strains of carcinoma cells, human urinary bladder carcinoma cells (JTC-30) and monkey hepatocarcinoma cells (NCLP-6E). Thus, it is concluded that the coexistence of the four agents provides general and superior conditions for the induction of alkaline phosphatase in cultured carcinoma cells.     

Effects of sodium butyrate on human colonic adenocarcinoma cells. Induction of placental-like alkaline phosphatase

We have examined the effects of the "differentiating agent," sodium butyrate, on the induction of alkaline phosphatase in human colonic tumor cell line LS174T. Culture of these cells in the presence of 2 mM butyrate caused this activity to increase from less than 0.0001 unit/mg of protein to greater than 0.7 unit/mg of protein over an 8-day period. This induction proceeded in a nonlinear fashion with a lag time of 2-3 days occurring before enzymatic activity began to rise. These increases in activity were accompanied by elevations in the content of a placental-like isozyme of alkaline phosphatase as demonstrated by "Western" immunoblots. Dome formation, indicative of differentiation in cultured cells, also required 3 days treatment with butyrate before becoming evident. The rate of biosynthesis of the enzyme, examined using metabolic labeling with L-[35S]methionine and immunoprecipitation, was found to increase continuously between days 2 and 6 of butyrate treatment. "Northern" blot analysis indicated that treatment of these cells with butyrate caused greater than 20-fold induction of a 2700-base mRNA that hybridized to a cDNA probe for placental alkaline phosphatase. The mRNA for alkaline phosphatase produced by these cells upon butyrate treatment was approximately 300-400 bases smaller than the mRNA for alkaline phosphatase found in placenta. Human small intestine also contained two mRNAs that hybridized relatively weakly with the placental alkaline phosphatase probe. These results indicate that a placental alkaline phosphatase-like protein and mRNA are induced by butyrate in LS174T cells with a time course consistent with cellular differentiation preceding induction.     

A study of adenosine 3':5'-cyclic monophosphate, sodium butyrate and cortisol as inducers of HeLa alkaline phosphatase

The role of adenosine 3′:5′-cyclic monophosphate in the cortisol-mediated induction of HeLa 65 alkaline phosphatase was investigated. Although growth of these cells with 0.5–1.0 mmN₆,O²′-dibutyryl adenosine 3′:5′-cyclic monophosphate induces a 5- to 8-fold increase in cellular phosphatase activity after 72 hr, neither cAMP nor theophylline induce at concentrations up to 1 mm. Sodium butyrate induces the enzyme as well as dibutyryl cAMP. Moreover, induction kinetics show sodium butyrate to be a more efficient inducer than dibutyryl cAMP, inducing activity as quickly as cortisol. This suggests that the butyric acid cleaved from dibutyryl cAMP by HeLa cells is the mediator of induction when the cyclic nucleotide derivative is used.     

Multiple forms of alkaline phosphatase in untreated and 5-bromo-2'-deoxyuridine-treated choriocarcinoma cells

The alkaline phosphatases present in choriocarcinoma cells, either untreated or treated with 5-bromo-2′-deoxyuridine (BrdUrd), were purified and characterized. Three forms of phosphatase [I, IIa (or IIIa), and IIb (or IIIb)]were isolated from both the untreated and BrdUrd-treated cells. Although BrdUrd induced the synthesis of all three forms of alkaline phosphatase in these cells, the synthesis of forms IIa and IIb was, however, preferentially stimulated. The forms of phosphatase in choriocarcinoma cells resembled each other in their kinetic properties and thermal lability, but differed in their molecular weights and in their electrophoretic mobilities in nondenaturing polyacrylamide gels. All three phosphatases were inactivated by antiserum to term-placental alkaline phosphatase. The alkaline phosphatases from choriocarcinoma cells differed, however, from the enzyme from term placentas in several physicochemical properties. The phosphatases from choriocarcinoma cells had a lower K_m value for p-nitrophenyl phosphate, were more sensitive to inhibition by l-leucine, levamisole, l-p-bromotetramisole, and EDTA, and were more heat-labile. Phosphatase I comigrated with term-placental alkaline phosphatase on nondenaturing polyacrylamide electrophoretic gels, but phosphatases IIa and IIb migrated more slowly. The apparent molecular weights of phosphatase forms I, IIa, and IIb were estimated by gel filtration and polyacrylamide gel electrophoresis to be 115,000, 240,000, and 510,000, respectively. Although three molecular forms of alkaline phosphatase occurred in choriocarcinoma cells, the subunit molecular weight of these phosphatases appeared to be identical to each other and to the subunit of term-placental alkaline phosphatase (63,000 MW). The alkaline phosphatase in choriocarcinoma cells therefore exists in the dimeric, tetrameric, and octameric forms.     

Requirement of serum pretreatment for induction of alkaline phosphatase activity with prednisolone, butyrate, dibutyryl cyclic adenosine monophosphate and NaCl in human liver cells continuously cultured in serum-free medium

A cell line (HuL-1) derived from normal fetal human liver was adapted to grow continuously in a modified Eagle's minimum essential medium without serum or hormones. The population doubling time of this adapted cell line (HuL-1-317) was about 72 h and the modal number of chromosomes was 54. The morphology of HuL-1-317 cells was round in the absence of serum, but at 37 degrees C with the addition of serum (1-10%), the cells flattened. HuL-1-317 cells had a low level of alkaline phosphatase activity. However the enzyme activity was slightly enhanced by the combination of prednisolone, butyrate, dibutyryl cyclic adenosine monophosphate and a hypertonic concentration of NaCl after 3 days of incubation at 37 degrees C. The increase in alkaline phosphatase activity with the four agents was further amplified dose-dependently by the pretreatment of the cells with serum. The stimulatory effect of the serum was evident at concentrations as low as 1%, and was maximal at 20%. The half life of the effect of serum on alkaline phosphatase induction was 48 h at 37 degrees C. Serum alone could not enhance the enzyme activity without the four agents. The present results indicate that serum contributes to the regulation of alkaline phosphatase induction by the combination of prednisolone, butyrate, dibutyryl cyclic adenosine monophosphate and NaCl in fetal human liver cells (HuL-1-317).     

Alkaline phosphatase biosynthesis in the endoplasmic reticulum and its transport through the Golgi apparatus to the plasma membrane: cytochemical evidence

Enzyme induction of HeLa cell placental alkaline phosphatase with various agents such as prednisolone, sodium butyrate, hyperosmolality (NaCl), or combination of these inducers resulted in the appearance of enzyme activity in the rough endoplasmic reticulum, nuclear envelope, Golgi apparatus, and plasma membrane. In the Golgi apparatus, intense reaction product deposits tended to be concentrated on its trans side, with small vesicles and granules also being positively stained. Inhibition of protein synthesis with cycloheximide was followed by the disappearance of enzyme activity from these cytoplasmic organelles but not from the plasma membrane. Treatment with monensin, a secretory protein transport inhibitor, uniformly increased activity in the rough endoplasmic reticulum while causing marked dilatation of the intensely positive Golgi cisternae. These results suggest that intracellular alkaline phosphatase is newly synthesized in the endoplasmic reticulum and then passes en route through the Golgi apparatus to the plasma membrane. Accordingly, the present system could represent the biosynthesis, transport, and incorporation of the model cell surface enzyme protein to add to the vesicular stomatitus virus glyco-1 (VSV-G) protein and acetylcholine receptor model systems for studying the dynamics of cell surface protein genesis, transport, and membrane integration.     

Induction of alkaline phosphatase in choriocarcinoma cells by 1-beta-D-arabinofuranosyl-cytosine, mitomycin C, phleomycin, and cyclic nucleotides.

Alkaline phosphatase is induced in cultured human choriocarcinoma cells by three inhibitors of DNA synthesis which alter DNA structure: 1-β-D-arabinofuranosyl-cytosine, mitomycin C, and phleomycin. No induction is observed with the inhibitors, hydroxyurea and thymidine, which do not alter DNA structure. Cyclic AMP, analogs of cyclic nucleotides, and sodium butyrate also induce alkaline phosphatase in these cells. Among the cyclic nucleotides tested, dibutyryl cyclic AMP is the best inducer, whereas dibutyryl cyclic GMP is a poor inducer. Induction of alkaline phosphatase by inhibitors of DNA synthesis or by exposure to dibutyryl cyclic AMP appears to utilize different mechanisms. Maximum induction is observed after simultaneous addition of both types of inducers at the concentrations found to be optimal for each inducer alone. Under these conditions, the induced activity is equal to or greater than the sum of the activities induced by each inducer. RNA synthesis and protein synthesis are required for induction. Dibutyryl cyclic AMP added to cultures of choriocarcinoma cells is not degraded in the culture medium, but is extensively degraded in the cells. Nevertheless, significant amounts of dibutyryl and monobutyryl cyclic AMP are found intracellularly throughout the experiment. Since the cellular uptake of dibutyryl cyclic AMP is extremely slow, the amount of butyrate released by intracellular degradation cannot account for the observed induction. Neither the rate of uptake nor the stability of dibutyryl cyclic AMP are changed by the addition of 1-β-D-arabinofuranosyl-cytosine to the culture medium. Furthermore, 1-β-D-arabinofuranosyl-cytosine inhibits the induction by sodium butyrate. The results indicate that butyrate is not the major mediator of induction by dibutyryl cyclic AMP.