Thiazolidinedione toxicity to isolated hepatocytes revealed by coherent multiprobe fluorescence microscopy and correlated with multiparameter flow cytometry of peripheral leukocytes.

Thiazolidinediones (TZDs) are effective for the treatment of adult-onset insulin-resistant diabetes. Unfortunately, TZDs are associated with sporadic hepatic dysfunction that is not predictable from experimental animal studies. We investigated the response of isolated rat and human hepatocytes to various TZDs using biochemical assays, coherent multiprobe fluorescence microscopy and flow cytometric analyses. The results identified direct effects of TZD on mitochondria from live human and rodent hepatocytes. The multiprobe fluorescence assays showed disruption of mitochondrial activity as an initiating event followed by increased membrane permeability, calcium influx and nuclear condensation. Other TZD-related cellular effects were increased hepatic enzyme leakage, decreased reductive metabolism and cytoplasmic adenosine triphosphate depletion. Mitochondrial effects were similar in cryopreserved hepatocytes from diabetic or non-diabetic donors. Peripheral blood mononuclear cells (PBMCs) had baseline mitochondrial energetics and metabolism comparable with isolated hepatocytes. Mitochondrial effects in isolated hepatocytes were found in human PBMCs exposed to the TZDs. The relative potency of TZDs for causing hepatocyte and PBMC effects was troglitazone > pioglitazone > rosiglitazone. These studies clearly demonstrated that hepatic alterations in vitro are characteristic of TZDs, with only quantitative differences in subcellular organelle dysfunction. Monitoring mitochondrial function in isolated PBMCs may be beneficial in diabetics undergoing TZD therapy.

Troglitazone-induced heart and adipose tissue cell proliferation in mice.

Troglitazone, a thiazolidinedione, is a novel agent for the oral treatment of non-insulin-dependent (Type II) diabetes mellitus; it works by increasing cell sensitivity to available insulin. Previous studies have shown that rodents treated with high doses of troglitazone develop increased heart weight and increased interscapular brown fat. This study investigated cellular proliferation in heart and brown fat of troglitazone-treated mice as well as possible interactions with an angiotensin-converting enzyme inhibitor (quinipril). B6C3F1 female mice were treated daily with either vehicle control, 125 mg/kg quinipril, 1,200 mg/kg troglitazone, or troglitazone/quinipril combination per os for up to 14 days. Four days before necropsy, mice were dosed with bromodeoxyuridine (BrdU) using osmotic pumps. Cell proliferation in heart, brown fat, and retroperitoneal white fat was investigated by means of light microscopic anti-BrdU immunolabeling techniques. Immunoelectron microscopy was used to determine the cell phenotypes and cellular distribution of BrdU label in heart and brown fat. Treatment with troglitazone for 2 wk resulted in increased heart and brown fat weights but in decreased white fat weight. Combination treatment with troglitazone and quinipril also resulted in decreased white fat weight compared with controls. Histologically, brown fat adipocytes in troglitazone- and troglitazone/quinipril-treated mice had coalescent lipid vacuoles and increased eosinophilia of the cytoplasm. White fat adipocytes in troglitazone- and troglitazone/quinipril-treated mice had decreased cell size and increased cytoplasmic eosinophilia. BrdU labeling revealed increased cell proliferation in troglitazone-treated hearts after 1 wk but did not reveal increased cell proliferation in quinipril- or troglitazone/quinipril-treated animals. Brown fat BrdU labeling after 1 wk was increased in troglitazone- and troglitazone/quinipril-treated mice. Ultrastructural anti-BrdU immunogold labeling demonstrated that troglitazone-treated heart and brown fat had greater populations of BrdU-labeled cells that were identified as endothelial cells. These results demonstrated that troglitazone-induced increased cardiac weight in mice can be prevented by quinipril and that increased cardiac weight coincides with early increased endothelial cell proliferation.

Functional and subcellular organelle changes in isolated rat and human hepatocytes induced by tetrahydroaminoacridine.

Tacrine (tetrahydroaminoacridine) is a reversible cholinesterase inhibitor used for the treatment of Alzheimer's disease. This drug causes an elevation of serum aminotransferases in a limited population of patients. Several in vivo studies failed to elucidate the mechanism for the enzyme elevation but previous in vitro studies have indicated defects in mitochondrial function. In this study, electron microscopic, histochemical, and confocal microscopy techniques were used with primary hepatocyte cultures from humans and rats to examine the sequence of early cellular changes after tacrine exposure. Changes included ribosome alterations as early as 1-2 h following tacrine exposure at concentrations ranging between 0.1 and 1.0 mM. Mitochondrial membrane potential was also altered as indicated by decreased rhodamine 123 uptake with time. Cellular lysosome content increased as indicated by increased staining of fluorescein isothiocyanate (FITC)-conjugated dextran. The results of acid phosphatase histochemistry correlated with the FITC-dextran findings. Additionally, tacrine-related degranulation and vesiculation of the endoplasmic reticulum paralleled the ribosomal and mitochondrial changes. These subcellular changes were reproducible in rat and human hepatocytes, showing for the first time that human hepatocytes can be altered by tacrine. The molecular mechanism of the organelle changes is unknown at this time. Also, the relationship between these subcellular changes in isolated hepatocytes and the transaminase elevation noted in human populations treated with tacrine needs to be clarified.

Increased nuclear ploidy, not cell proliferation, is sustained in the peroxisome proliferator-treated rat liver.

Peroxisome proliferators are believed to induce liver tumors in rodents due to sustained increase in cell proliferation and oxidative stress resulting from the induction of peroxisomal enzymes. The objective of this study was to conduct a sequential analysis of the early changes in cell-cycle kinetics and the dynamics of rat liver DNA synthesis after treatment with a peroxisome proliferator. Immunofluorescent detection of proliferating cell nuclear antigen (PCNA) and bromodeoxyuridine (BrdU) incorporation into DNA during S phase we used to assess rat hepatocyte proliferation in vivo during dietary administration of Wy-14,643, a known peroxisome proliferator and hepatocarcinogen in rodents. Rats were placed on diet containing 0.1% WY-14,643 and implanted subcutaneously with 5-bromo-2'deoxyuridine containing osmotic pumps 4 days prior to being sacrificed on days 4, 11, and 25 of treatment. Isolated liver nuclei labeled with fluorscein isothiocyanate (FITC)-anti-BrdU/PI and FITC-anti-PCNA/PI were analyzed for S-phase kinetics using flow cytometry. Morphometric analysis was performed to evaluate nuclear and cell size and enumeration of BrdU labeled cells, binucleated hepatocytes, and mitotic index. The BrdU labeling index increased 2-fold in livers of Wy-14,643-treated rats at day 4, but distribution of cells in G1, S phase, and G2-M did not differ significantly from controls. PCNA-positive cells decreased from 36% on day 4 to 17% on day 25, whereas the percentage of PCNA-positive cells in controls increased 2-fold from day 4 to day 11 and remained unchanged up to day 25. The differences in the number of PCNA-positive nuclei between control and Wy-14,643-treated groups were statistically significant only on day 4. Binucleated hepatocytes, determined by morphometric analysis, increased slightly on day 25 in treated rats parallel to an increase in the percentage of cells in G2-M phase. Significant shifts were noted in nuclear diameter and nuclear area after 11 and 25 days of treatment with Wy-14,643. Hepatic cell populations with nuclei > 9 microns diameter and nuclear area > 64 microns2 increased in Wy-14,643-fed rats during the treatment period compared with the control, indicating hepatic karyomegaly and hyperploidy, whereas percentage of distribution of nuclei based on diameter and area remained consistently unchanged in control animals from 4 through 25 days of sham treatment. The flow cytometric and morphometric analysis indicated an initial wave of DNA synthesis in response to Wy-14,643. The hepatomegaly was sustained over the treatment period accompanied by increase in ploidy with a significant shift toward hyperploidic hepatocytes. The increase in DNA content was almost entirely accounted for by the overall polypoidy increase rather than by an absolute increase in cells.

Recombinant human epidermal growth factor1-48-induced structural changes in the digestive tract of cynomolgus monkeys (Macaca fascicularis).

To determine the cellular effects and potential toxicity of exogenously administered recombinant human epidermal growth factor1-48 (EGF1-48) in primates, intravenous bolus injections were given to 2 cynomolgus monkeys per sex at 0 (vehicle control). 10, 100, 500 (females only), and 1,000 micrograms/kg/day (males only) for up to 2 wk. Males given the suprapharmacologic dose of 1,000 micrograms/kg did not tolerate treatment and were necropsied after 5 days of dosing. All other monkeys completed the 2-wk study. Necropsy findings included enlarged, discolored, pale tan livers at 500 micrograms/kg and greater, firm, thickened pancreata in 500-micrograms/kg females, and enlarged salivary glands at all doses. Relative liver weights were increased at 500 and 1,000 micrograms/kg: mean salivary gland weights in all dose groups were greater than in controls. Histopathologic changes were primarily those of diffuse epithelial cell hypertrophy and hyperplasia in liver (hepatocytes and biliary tract), pancreas, salivary glands, tongue, esophagus, stomach, small and large intestine, and gallbladder. Alterations were dose-related in intensity and occurred in at last some tissues at the lowest dose. In gastric glands, colon crypts, pancreatic ducts, biliary tract, and salivary glands, differentiated epithelial cells were replaced by cells of less differentiated phenotype. These morphologic alterations were consistent with exuberant proliferation induced by this epithelial mitogen. The extent of the proliferative response in tissues of the digestive tract attests to the potency of this fragment of human EGF1-53 in primates. Furthermore, the epithelial proliferation was significantly greater than that reported previously in EGF-treated rodents.

Quantitative microscopy of hepatic changes induced by phenethyl isothiocyanate in Fischer-344 rats fed either a cereal-based diet or a purified diet.

Hepatic changes induced by phenethyl isothiocyanate (PEITC) in the liver of rats were determined by quantitative microscopy. Groups of male Fischer-344 rats were fed either a standard, cereal-based diet (Wayne rodent meal) or a purified diet (AIN-76A) containing PEITC at concentrations of 0.75 and 6.0 mmol/kg for 13 wk. Severe hepatic lipidosis was observed in control rats fed the purified diet. Addition of PEITC to the purified diet significantly reduced lipid content in hepatocytes. In contrast, lipid content in the liver of the rats fed the cereal-based diet containing PEITC was greater than in control rats maintained on the same diet. In addition, dose-related reductions in hepatocyte, lipid droplet, peroxisome, and mitochondrial volumes were observed in PEITC-treated rats fed the cereal-based diet. These results indicate that PEITC exerts differential effects on the liver of rats fed either the cereal-based or purified diet.

Critical subcellular targets of cisplatin and related platinum analogs in rat renal proximal tubule cells.

The clinical usefulness of chemotherapeutic agents containing the platinum moiety is often limited by their nephrotoxicity. To investigate the mechanism of nephrotoxicity, and to assess the effects of platinum analogs on specific organelles and basal protein synthesis, biochemical and ultrastructural analyses were performed in rat renal proximal tubule cells (RPTCs). Neutral red (NR) uptake was used to measure lysosomal function, and conversion of MTT to formazan used to assess mitochondrial function. Despite their differential toxicity, cisplatin, carboplatin and CI-973 caused similar progressive inhibition of specific functions, suggesting they may share a common mechanism of nephrotoxicity. Protein synthesis was the earliest indicator of toxicity, followed by NR uptake and MTT conversion. Fluorescent probes for lysosomes (acridine orange) and mitochondria (rhodamine 123) confirmed that cisplatin's toxicity to RPTCs was delayed and cumulative. Condensation of nucleolar components and fragmentation of RER were observed in RPTCs treated for as little as two hours. Since the nucleolus is the site of ribosome biogenesis, the early inhibition of protein synthesis by cisplatin may arise from disruption of this region. In contrast, mitochondrial dysfunction and swelling were late-stage events, and are therefore unlikely to be the primary targets of nephrotoxic platinum compounds.