Cell senescence induced by histone deacetylase inhibitor sodium butyrate in rodent transformed cells resistant to apoptosis

The capacity of HDAC inhibitor sodium butyrate to induce senescence in cells derived from rat embryonic fibroblasts transformed by E1A+E1B19 kDa oncogenes has been studied. These transformants are resistant to apoptosis in response to gamma-irradiation and growth factor deprivation. The process of cell senescence was investigated by the analysis of cell growth curves, G1/S and G2/M cell cycle arrest, and senescent associated beta-galactosidase expression. The irreversibility of sodium butyrate antiproliferative activity was analyzed by clonogenic assay. We show that sodium butyrate suppresses proliferation and induces senescence in the E1A+E1B19 kDa transformed cells. Interestingly, NaB induces growth arrest due to accumulation of cells in G2/M phase, these cells are not tetraploid but mainly binuclear. Thus, in case of NaB induced senescence in E1A+E1B19 kDa transformed fibroblasts, the observed suppression of cell proliferation may be the result of cytokinesis failure leading to formation of binuclear and multinuclear cells incapable to proliferate.     

Induction of premature senescence program by an inhibitor of histone deacetylase sodium butyrate in normal and transformed rat fibroblasts

We investigated a possibility to induce the premature cell senescence in rat embryo fibroblasts and E1A + cHa-ras transformants. We found that after the treatment with sodium butyrate, an inhibitor of histone deacetylases, both normal and transformed cells completely stopped to proliferate and accumulated at G1/S and G2/M phases of the cell cycle. The cloning efficiency data show that the cell cycle arrest induced by sodium butyrate is irreversible and correlates with the accumulation of active phosphorylated form of stress kinase p38, and with the expression of marker of senescence--beta-galactosidase activity (SA beta-Gal). The program resembling the premature senescence after sodium butyrate treatment is supposed to develop both in normal and transformed cells. The irreversible block of proliferation in E1A + cHa-ras transformants may be regarded as an example of activation of anticancer program like that of premature senescence in the tumor rodent cells.     

Role of p38alpha kinase in activation of premature senescence program in transformed mouse fibroblasts

We investigated the role of p38alpha stress-kinase in regulation of premature senescence program, stimulated by histone deacetylase inhibitor--sodium butyrate (NaB)--after application to rodent transformed cell lines. Investigation was performed on the E1A + cHa-ras transformants selected from mice embryonic fibroblasts null at the p38alpha kinase gene or null fibroblasts at the PPM1D gene, which encoded phosphatase Wip1. Absence of Wip1 led to constitutive activation of p38alpha kinase. It was revealed that after NaB treatment both cell lines completely stopped proliferation due to irreversible cell cycle arrest in G1/S phase. In both cell lines sodium butyrate induced sustained block of prolifaration due to irreversible cell cycle arrest in G1/S phase. Following sodium butyrate treatment cells expressed marker of senescence--beta-galactosidase activity (SA-beta-Gal). Long-term (during several days) NaB treatment of cells led to partial restoration of actin cytoskeleton, focal adhesion contacts and heterochromatin focus formation (SAHF) in the nucleus of senescent cells. Obtained data allow us to suppose that irreversible process of cellular senescence activated by sodium butyrate can occur in the absence of functionally active p38 kinase by means of other ways of cell cycle suppression.     

Inhibition of cell cycle progression by sodium butyrate in normal rat kidney fibroblasts is altered by expression of the adenovirus 5 early 1A gene

The effect of sodium butyrate (NaBut) on cell growth was studied in normal rat kidney (NRK) fibroblasts, and in NRK cells stably transfected with either the adenoviral gene E1A (wild-type), or mutated E1A (E1A^mut; with a deletion in the CR1 domain), or with the transforming Ha-ras (EJ) gene. The growth of all these cell lines was inhibited by milimolar concentrations of sodium butyrate (NaBut). However, whereas the NRK cells as well as the NRK-E1A^mut and NRK-ras cells were arrested in the G1 phase of the cell cycle, the NRK-E1A cells progressively accumulated in the G2 phase, suggesting that the E1A gene expression caused a leaky inhibition of G1 phase progression. The expression of late cell cycle-related genes cdc2 and PCNA (proliferating cell nuclear antigen) was not affected by NaBut in the NRK-E1A cells while it was totally suppressed in the other NRK-derived cell lines.     

Butyrate blocks the accumulation of CDC2 mRNA in late G1 phase but inhibits both the early and late G1 progression in chemically transformed mouse fibroblasts BP-A31

Sodium butyrate (6 mM) blocks the resumption of the cell division cycle in serum-deprived chemically transformed Balb/c-3T3 mouse fibroblasts (BP-A31). The inhibition of G1 progression by sodium butyrate is not restricted to a specific mitogenic signaling pathway and is equally effective when tetradecanoyl phorbol acetate (TPA), insulin, or fetal calf serum (FCS) is used as inducer. The inhibitor acts in early as well as late G1 phase as indicated by experiments in which inhibitor was added and withdrawn at different times after restimulation of quiescent cells by FCS. At the gene expression level, sodium butyrate does not affect the inducibility of early cell cycle-related genes (c-myc, c-jun) while blocking the induction of cdc 2 mRNA, a late G1 marker. We conclude that sodium butyrate does not interfere with the growth factor signaling pathways regulating the (early) cell cycle-related gene expression. However, the presence of sodium butyrate early in G1 phase inhibits the cascade of events leading eventually to the expression of late G1-characteristic genes such as cdc2. The antimitogenic activity of sodium butyrate may be related to its interference with an (unknown) process involved in the "mitogenic" cascade.     

Effect of sodium butyrate on cell proliferation and cell cycle in porcine intestinal epithelial (IPEC-J2) cells

Conflicting results have been reported that butyrate in normal piglets leads either to an increase or to a decrease of jejunal villus length, implying a possible effect on the proliferation of enterocytes. No definitive study was found for the biological effects of butyrate in porcine jejunal epithelial cells. The present study used IPEC-J2 cells, a non-transformed jejunal epithelial line to evaluate the direct effects of sodium butyrate on cell proliferation, cell cycle regulation, and apoptosis. Low concentrations (0.5 and 1 mM) of butyrate had no effect on cell proliferation. However, at 5 and 10 mM, sodium butyrate significantly decreased cell viability, accompanied by reduced levels of p-mTOR and PCNA protein. Sodium butyrate, in a dose-dependent manner, induced cell cycle arrest in G0/G1 phase and reduced the numbers of cells in S phase. In addition, relative expression of p21, p27, and pro-apoptosis bak genes, and protein levels of p21Waf1/Cip1, p27Kip1, cyclinD3, CDK4, and Cleave-caspase3 were increased by higher concentrations of sodium butyrate (1, 5, 10 mM), and the levels of cyclinD1 and CDK6 were reduced by 5 and 10 mM butyrate. Butyrate increased the phosphorylated form of the signaling molecule p38 and phosphorylated JNK. In conclusion, the present in vitro study indicated that sodium butyrate inhibited the proliferation of IPEC-J2 cells by inducing cell cycle arrest in the G0/G1 phase of cell cycles and by increasing apoptosis at high concentrations.     

Lack of effect of butyrate on S phase DNA synthesis despite presence of histone hyperacetylation

The effects of sodium butyrate on [³H]thymidine incorporation and cell growth characteristics in randomly growing and synchronized HeLa S₃ cells have been examined in an attempt to determine what effects, if any, butyrate has on S phase cells. Whereas 5 mM sodium butyrate rapidly inhibits [⁵H]thymidine incorporation in a randomly growing cell populations, it has no effect on incorporation during the S phase in cells synchronized by double thymidine block techniques. This lack of effect does not result from an impaired ability of the S phase cells to take up butyrate, since butyrate administration during this period leads to histone hyperacetylation that is identical with that seen with butyrate treatment of randomly growing cells. Furthermore, the ability to induce such hyperacetylation with butyrate during an apparently normal progression through S phase indicates that histone hyperacetylation probably has no effect on the overall process of DNA replication. Temporal patterns of [³H]thymidine incorporation and cell growth following release from a 24-h exposure to butyrate confirm blockage of cell growth in the G1 phase of the cell cycle. Thus, the inhibition by butyrate of [³H]thymidine incorporation in randomly growing HeLa S₃ cell populations can be accounted for solely on the basis of a G1 phase block, with no inhibitory effects on cells already engaged in DNA synthesis or cells beyond the G1 phase block at the time of butyrate administration.     

Program of premature senescence is not induced by sodium butyrate in transformants with JNK1,2 knockout

The role of JNK1,2 stress kinases in the regulation of premature senescence stimulated by sodium butyrate (NaB), a histone deacetylase inhibitor, has been studied. It was found that NaB did not block the cell cycle in E1A+cHa-ras transformants selected from embryonic mouse fibroblasts with jnk1,2 stress-kinase gene knockout (mERasJNK^?/? cells). Even long-term (five days) NaB treatment did not block cell cycle distribution or cell proliferation, nor did it induce cellular hypertrophy or activate SA-β-galactosidase activity, a senescence marker. The data show that JNK stress kinases are involved in senescence induced in E1A+cHa-ras mouse transformants by NaB. It is possible to suggest that JNK1,2 have tumor suppressor properties because the process of senescence, which prevents tumor cell proliferation, does not occur if they are absent.     

Involvement of MAP-kinase cascades in regulation of sodium-butyrate-induced premature senescence

We have studied the role of the stress kinases p38 and JNK1,2 in premature senescence induced by sodium butyrate (NaBut), a histone deacetylase inhibitor, in mouse embryonic fibroblasts transformed by E1A+cHa-Ras oncogenes. It was found that transformants from p38 knockout cells are able to implement NaBut-induced senescence exhibited by cell cycle arrest, inhibition of proliferation, hypertrophic changes associated with mTORC1 activation and SA-β-galactosidase activity. In jnk1,2 knockouts, the NaButinduced senescence program was inhibited. NaBut-induced senescence in p38 knockouts closely correlates with mTORC1 activation shown by inhibiting mTORC1 with rapamycin. In jnk1,2 knockouts, mTORC1 complex is not activated. We believe that JNK1,2 kinases are required for mTORC1 activation and exhibition of premature senescence markers induced by NaBut in E1A+cHa-Ras transformants.     

Histone deacetylase inhibitor blocks proliferation of cells transformed with oncogenes E1A and cHa-ras

Rat embryonic fibroblasts, transformed with E1A and cHa-ras oncogenes, are unable to stop in the cell cycle checkpoints under growth factor withdrawal and genotoxic stresses (Bulavin et al., 1999). In the present paper, we showed that sodium butyrate, an inhibitor of histone deacetyase activity, decreased the share of cells being in S-phase, and caused G1/S and G2/M blocks of the cell cycle in the transformants. By means of RT-PCR and immunoblotting, we found that NaB significantly changed the expression of genes involved in proliferation: cyclins D1, A, E and cyclin-dependent kinases Cdk2 and Cdk4, whereas the amount of p21Waf1 and p27Kip1 inhibitors greatly increased. Along with accumulation of p21Waf1 protein content, that of Cdk2-bound p21 increases. Taken together, these data allow to suggest that NaB treatment does evidently restore the capability of p21Waf1 to inhibit cyclin-kinase activity. One may suppose that inhibition of HDAC activity by sodium butyrate leads to activation of yet unknown HDAC-dependent genes, which is followed by restoration of p21Waf1 function in spite of the E1A oncogene expression.     

Effect of sodium butyrate on mammalian cells in culture: A review

Summary Sodium butyrate produces reversible changes in morphology, growth rate, and enzyme activities of several mammalian cell types in culture. Some of these changes are similar to those produced by agents which increase the intracellular level of adenosine 3′,5′-cyclic monophosphate (cAMP) or by analogs of cAMP. Sodium butyrate increases the intracellular level of cAMP by about two fold in neuroblastoma cells; therefore, some of the effects of sodium butyrate on these cells may in part be mediated by cAMP. Sodium butyrate appears to have properties of a good chemotherapeutic agent for neuroblastoma tumors because the treatment of neuroblastoma cells in culture causes cell death and “differentiation”; however, it is either innocuous or produces reversible morphological and biochemical alterations in other cell types.     

Human fibroblast commitment to a senescence-like state in response to histone deacetylase inhibitors is cell cycle dependent.

Human diploid fibroblasts (HDF) complete a limited number of cell divisions before entering a growth arrest state that is termed replicative senescence. Two histone deacetylase inhibitors, sodium butyrate and trichostatin A, dramatically reduce the HDF proliferative life span in a manner that is dependent on one or more cell doublings in the presence of these agents. Cells arrested and subsequently released from histone deacetylase inhibitors display markers of senescence and exhibit a persistent G1 block but remain competent to initiate a round of DNA synthesis in response to simian virus 40 T antigen. Average telomere length in prematurely arrested cells is greater than in senescent cells, reflecting a lower number of population doublings completed by the former. Taken together, these results support the view that one component of HDF senescence mimics a cell cycle-dependent drift in differentiation state and that propagation of HDF in histone deacetylase inhibitors accentuates this component.     

Butyrate metabolism upstream and downstream acetyl-CoA synthesis and growth control of human colon carcinoma cells.

Butyrate is a short chain fatty acid (SCFA) produced by bacterial fermentation of dietary fibers in the colon lumen which severely affects the proliferation of colon cancer cells in in vitro experiments. Although butyrate is able to interfere with numerous cellular targets including cell cycle regulator expression, little is known about butyrate metabolism and its possible involvement in its effect upon colon carcinoma cell growth. In this study, we found that HT-29 Glc-/+ cells strongly accumulated and oxidized sodium butyrate without producing ketone bodies, nor modifying oxygen consumption nor mitochondrial ATP synthesis. HT-29 cells accumulated and oxidized sodium acetate at a higher level than butyrate. However, sodium butyrate, but not sodium acetate, reduced cell growth and increased the expression of the cell cycle effector cyclin D3 and the inhibitor of the G1/S cdk-cyclin complexes p21/WAF1/Cip1, demonstrating that butyrate metabolism downstream of acetyl-CoA synthesis is not required for the growth-restraining effect of this SCFA. Furthermore, HT-29 cells modestly incorporated the 14C-labelled carbon from sodium butyrate into cellular triacylglycerols and phospholipids. This incorporation was greatly increased when D-glucose was present in the incubation medium, corresponding to the capacity of hexose to circulate in the pentose phosphate pathway allowing NADPH synthesis required for lipogenesis. Interestingly, when HT-29 cells were cultured in the presence of sodium butyrate, their capacity to incorporate 14C-labelled sodium butyrate into triacylglycerols and phospholipids was increased more than twofold. In such experimental conditions, HT-29 cells when observed under an electronic microscope, were found to be characterized by an accumulation of lipid droplets in the cytosol. Our data strongly suggest that butyrate acts upon colon carcinoma cells upstream of acetyl-CoA synthesis. In contrast, the metabolism downstream of acetyl-CoA [i.e. oxidation in the tricarboxylic acid (TCA) cycle and lipid synthesis] likely acts as a regulator of butyrate intracellular concentration.     

Effects of cyclic AMP and butyrate on cell cycle,DNA, RNA,and purine synthesis of cultured astrocytes

Dibutyryl cyclic monophosphate (dBcAMP) has been shown to inhibit growth, and alter the morphology of astrocytes. However, the potential contribution of its hydrolytic product, butyrate, in inducing some of the changes that have been attributed to dBcAMP, is not clear. DNA, RNA, and purine synthesis were therefore studied in primary astrocyte cultures after 24 hours of exposure to varying concentrations of butyrate, dBcAMP, and agents that increase intracellular cAMP levels. Progression of cells through cell cycle was also studied by flow cytometry. Dibutyryl cAMP partially arrested cells in Go/G1 phase of cell cycle while sodium butyrate increased the percentage population of cells in G2/M phase. DNA synthesis and de novo purine synthesis were inhibited after treatment with dBcAMP, sodium butyrate, and various drugs that increase intracellular cAMP levels. RNA synthesis was increased with cAMP but was not affected by sodium butyrate. Our study shows that at millimolar concentrations, butyrate is capable of altering the cell cycle and inhibiting DNA synthesis in primary astrocyte cultures, in a manner that is similar although not identical to the effects of dBcAMP.     

HDAC inhibitor-induced activation of NF-κB prevents apoptotic response of E1A + Ras-transformed cells to proapoptotic stimuli

HDAC inhibitors (HDACIs) are capable of suppressing the cell growth of tumour cells due to the induction of apoptosis and/or cell cycle arrest. This allows of considering HDACIs as promising agents for tumour therapy. The final outcome – apoptotic cell death or cell cycle arrest – depends on the type of tumour and cellular context. In this report, we addressed the issue by analysing effects produced in E1A + Ras-transformed MEF cells by HDAC inhibitors sodium butyrate (NaB), Trichostatin A (TSA) and some others. It has been shown that the HDACIs induced cell cycle arrest in E1A + Ras-transformed cells but not apoptosis. The antiapoptotic effect of HDACIs is likely to be a result of NF-κB-dependent signaling pathway activation. HDACI-induced activation of NF-κB takes place in spite of a deregulated PI3K/Akt pathway in E1A + Ras cells, suggesting an alternative mechanism for the activation of NF-κB based on acetylation. HDACI-dependent activation of NF-κB prevents the induction of apoptosis by cytostatic agent adriamycin and serum deprivation. Accordingly, suppression of NF-κB activity in HDACI-arrested cells by the chemical inhibitor CAPE or RelA-siRNA resulted in the induction of an apoptotic programme. Thus, our findings suggest that the activation of the NF-κB pathway in HDACI-treated E1A + Ras-transformed cells blocks apoptosis and may thereby play a role in triggering the programme of cell cycle arrest and cellular senescence.     

Sodium butyrate induces apoptosis and cell cycle arrest in primary effusion lymphoma cells independently of oxidative stress and p21CIP1/WAF1 induction

Primary effusion lymphoma, a peculiar type of B cell non-Hodgkin lymphoma, preferentially develops in immunodeficient individuals and its pathogenesis is closely linked with human herpesvirus 8 (HHV-8). HHV-8 is present primarily persistence in primary effusion lymphoma cells, and the lytic cycle of HHV-8 can be induced by sodium butyrate (NaB) treatment. HHV-8 gene expression is affected by NaB in BCBL-1 cells, but the cellular response of BCBL-1 cells upon NaB treatment has not been investigated to date. Using BCBL-1 cells, a HHV-8 harboring cell line, we demonstrated that sodium butyrate could induce the reactive oxygen species generation, apoptosis and cell cycle arrest in BCBL-1 cells. The sodium butyrate-induce cell cycle arrest was associated with the decrease of Cdc2, Cdk4 and cyclin A in BCBL-1 cells without altering the protein levels of p21^CIP1/WAF1. The apoptosis induced by sodium butyrate in BCBL-1 cells was independent of oxidative stress. (Mol Cell Biochem xxx: 1–9, 2005)     

Sodium pump localization in epithelia

In epithelial cells, the sodium pump, in coordination with several other ion transporting proteins and channels, acts to regulate directional water and ion flux across the epithelial barrier. This function is dependant on the polarized localization of the sodium pump to a single plasma membrane domain. In most epithelial cell types the sodium pump is found in an exclusively basolateral position. Despite the clear importance of maintaining a polarized distribution of the sodium pump, surprisingly littleis known about the specific mechanisms responsible for the targeting and trafficking of the sodium pump to the basolateral surface. We briefly discuss our current understanding of factors which may act to regulate the cellular distribution of the sodium pump, including the potential role of the sodium pump β-subunit. Several previous, studies have suggested that the expression of the β2 isoform (instead of β1) may cause the apical localization of the sodium pump. This appeared to be confirmed by Wilson et al. Am J Pathol, 156: 253–268, 2000 who found that MDCK cells stably transfected with the β2 subunit express the sodium pump at the apical surface. However, careful examination by Laughery et al.,Am J Physiol, 292: F1718–F1725, 2007, showed that the apical targeting of the pump was caused by the presence of butyrate in the cell growth media and was not due to the presence of the β2 isoform. These findings are discussed below, along with potential explanations as to how butyrate may influence the polarity of the sodium pump in epithelial cells.