Ultrastructural localization of the ROMK potassium channel in rat liver and heart

The intracellular localization and distribution of the ROMK protein in rat liver and heart was studied by the electron microscopy of ultrathin sections using the antibodies against the ROMK channel protein, one of the contenders for the role of mitochondrial ATP-dependent potassium channel. In rat heart and liver tissues, the ROMK protein is localized on the membranes of mitochondrial cristae but differently distributed in hepatocytes and cardiomyocytes. In hepatocytes, colloidal gold particles were rather evenly distributed on the membranes of mitochondrial cristae. In cardiomyocytes, the number of granules was considerably lower than in hepatocytes, and they were also localized on the membranes of mitochondrial cristae and confined only by the center of these organelles.     

Localization of a nuclear envelope-associated protein by indirect immunofluorescence microscopy using antibodies against a major polypeptide from rat liver fractions enriched in nuclear envelope-associated material.

The location of a specific major polypeptide present in nuclear pore complex-enriched fractions from rat liver was examined by indirect immunofluorescence microscopy using chicken antibodies against this polypeptide. In both whole cell preparations of cultured cells grown on cover slips (mouse 3 T 3, rat kangaroo PtK2) and in frozen sections through liver and mammary gland tissue a strongly preferential, if not exclusive, binding to the nuclear periphery of interphase cells was observed. The specificity of this localization was demonstrated in these cells by the decoration of chromatin with antibodies against histones and of elements of the endoplasmic reticulum--outer mitochondrial membrane--system with antibodies to cytochrome b5. In addition, the localization was examined by electron microscopy using frozen sections and "immunoperoxidase" techniques. The results suggest that this polypeptide is contained in a protein specific for the nuclear periphery, probably closely associated with the peripheral chromatin.     

Detection of KIR6 family protein in rat heart and liver mitochondria by immunoelectron microscopy

The electron microscopic study of thin sections of rat liver and heart using commercial specific antibodies against KIR.6.2 and secondary antibodies conjugated with colloidal gold was performed. It was found that the gold-labeled protein is localized in mitochondria of cardiomyocytes and hepatocytes but not in rough and smooth endoplasmic reticulum of hepatic cells and myofibrils of myocardium. In rat heart and liver mitochondria, the gold label was mainly located in mitochondrial cristae and was not found in mitochondrial matrix and intermembrane space. The data indicate that in heart and liver mitochondria there exists a protein similar in structure to the channel-forming subunit of a cytoplasmic potassium channel, KIR6.2. This is also supported by the presence of common modulators of cytoplasmic and mitochondrial ATP-dependent potassium channels. A possible role of the protein as a subunit of the mitochondrial ATP-dependent potassium channel is discussed.     

Cell of origin of distinct cultured rat liver epithelial cells, as typed by cytokeratin and surface component selective expression

The cell of origin of the nonparenchymal epithelioid cells that emerge in liver cell cultures is unknown. Cultures of rat hepatocytes and several types of nonparenchymal cells obtained by selective tissue dispersion procedures were typed with monoclonal antibodies to rat liver cytokeratin and vimentin, polyvalent antibodies to cow hoof cytokeratins and porcine lens vimentin, and monoclonal antibodies to surface membrane components of ductular oval cells and hepatocytes. Immunoblot analysis revealed that, in cultured rat liver nonparenchymal epithelial cells, the anti-rat hepatocyte cytokeratin antibody recognized a cytokeratin of relative mass (Mr) 55,000 and the anti-cow hoof cytokeratin antibody reacted with a cytokeratin of Mr 52,000, while the anti-vimentin antibodies detected vimentin in both cultured rat fibroblasts and nonparenchymal epithelial cells. Analyses on the specificity of anti-cytokeratin and anti-vimentin antibodies toward the various cellular structures of liver by double immunofluorescence staining of frozen tissue sections revealed unique reactivity patterns. For example, hepatocytes were only stained with anti-Mr 55,000 cytokeratin antibody, while the sinusoidal cells reacted only with the anti-vimentin antibodies. In contrast, epithelial cells of the bile ductular structures and mesothelial cells of the Glisson capsula reacted with all the anti-cytokeratin and anti-vimentin antibodies. It should be stressed, however, that the reaction of the anti-vimentin antibodies on bile ductular cells was weak. The same analysis on tissue sections using the anti-ductular oval cell antibody revealed that it reacted with bile duct structures but not with the Glisson capsula. The anti-hepatocyte antibody reacted only with the parenchymal cells. The differential reactivity of the anti-cytokeratin and anti-vimentin antibodies with the various liver cell compartments was confirmed in primary cultures of hepatocytes, sinusoidal cells, and bile ductular cells, indicating that the present panel of antibodies to intermediate filament constituants allowed a clear-cut distinction between cultured nonparenchymal epithelial cells, hepatocytes, and sinusoidal cells. Indirect immunofluorescence microscopy on nonfixed and paraformaldehyde-fixed cultured hepatocytes and bile ductular cells further confirmed that both anti-hepatocyte and anti-ductular oval cell antibodies recognized surface-exposed components on the respective cell types.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immunoperoxidase localization of albumin and fibrinogen in rat liver fixed by perfusion or immersion: effect of saponin on the intracellular penetration of labeled antibodies

Immunoperoxidase localization of albumin and fibrinogen in rat liver was tested with perfusion or immersion fixation and saponin as a membrane permeabilizing agent. The distribution of albumin- or fibrinogen-containing hepatocytes was examined by light microscopy. Labeled antibody penetration was assessed by electron microscopy on transversely cut cryostat sections. Paraformaldehyde liver fixation by perfusion, followed by incubation of the sections with labeled antibodies together with saponin, demonstrated that albumin and fibrinogen were present in all hepatocytes; mainly in the Golgi apparatus and rarely in the endoplasmic reticulum, the ultrathin sections being labeled throughout their entire thickness. A constant labeling of the endoplasmic reticulum was obtained when saponin was added from the beginning of fixation. In the absence of saponin, albumin was seen in most of the hepatocytes but only at the periphery of the transverse sections, in a few Golgi apparatus, and in some parts of the endoplasmic reticulum; under this condition, fibrinogen was not visualized in the hepatocytes. Paraformaldehyde liver fixation by immersion showed the presence of albumin or fibrinogen in a few hepatocytes only, with irregular labeled antibody penetration. The use of saponin did not improve albumin and fibrinogen localization, except when the liver was poorly fixed. These results show that liver fixation by perfusion gives a homogeneous labeling of all the hepatocytes, whereas fixation by immersion leads to a heterogeneous labeling. Satisfactory results are obtained with saponin, which must be used to improve the penetration of labeled antibodies when the liver is fixed by perfusion. Saponin does not work when immersion is employed, at least under the conditions tested.     

Purification and immunoelectron microscopic localization of cellular glutathione peroxidase in rat hepatocytes: quantitative analysis by postembedding method

To measure quantitatively the intracellular distribution of cellular glutathione peroxidase (GPX) in rat hepatocytes, ultrathin sections were stained by a postembedding immunogold technique. GPX had a specific activity of 1670 Units/mg protein, and was purified 2050-fold from rat liver by means of heat denaturation, ammonium sulfate fractionation, and a series of chromatographic procedures including thiol-Sepharose 4B. The purified GPX was shown to be electrophoretically pure, and was a homotetramer of 22 kDa subunits. Monospecific polyclonal antibodies were raised in rabbits by immunization. By immunoblot analysis, both the light mitochondrial the and cytosolic fractions of rat liver homogenate gave a single band with an identical mobility to that of the purified enzyme. Under the light microscope, hepatocytes showed nuclear staining and granular cytoplasmic staining, corresponding to certain intracellular structures. The labeling density (number of gold particles/m²) for GPX obtained by immunoelectron microscopy was 11.9 in the nuclei, 19.6 in mitochondria, 3.32 in peroxisomes, 1.95 in lysosomes, and 9.81 in the cytoplasmic matrix. These results suggest that cellular GPX is present in various compartments of rat hepatocytes, and that the GPX occurs in relatively higher amounts in mitochondria.     

Localization of the ecto-ATPase (ecto-nucleotidase) in the rat hepatocyte plasma membrane. Implications for the functions of the ecto-ATPase

The surface distribution of the plasma membrane Ca2+ (Mg2+)-ATPase (ecto-ATPase) in rat hepatocytes was determined by several methods. 1) Two polyclonal antibodies specific for the ecto-ATPase were used to examine the distribution of the enzyme in frozen sections of rat liver by immunofluorescence. Fluorescent staining was observed at the bile canalicular region of hepatocytes. 2) Plasma membranes were isolated from the canalicular and sinusoidal regions of rat liver. The specific activity of ecto-ATPase in the canalicular membranes was 22 times higher than that of sinusoidal membranes. The enrichment of the ecto-ATPase activity in the canalicular membrane is closely parallel to that of two other canalicular membrane markers, gamma-glutamyltranspeptidase and leucine aminopeptidase. 3) By immunoblots with polyclonal antibodies against the ecto-ATPase and the Na+,K+-ATPase, it was found that the ecto-ATPase protein was only detected in canalicular membranes and not in sinusoidal membranes, while the Na+,K+-ATPase protein was only detected in sinusoidal membranes and not in canalicular membranes. These results indicate that the ecto-ATPase is enriched in the canalicular membranes of rat hepatocytes.     

The riddle of mitochondrial caspase-3 from liver

Caspase-3 is one of the main executors of apoptosis. Its zymogen procaspase-3 was localized to cytosol, mitochondria and nuclei. The subcellular location of procaspase-3 in liver was reported by several studies to be either cytosolic or cytosolic and mitochondrial. Our aim was to investigate these separate procaspase-3 pools to differentiate the pathways of their activation. By cell fractionation, immunocytochemistry, and confocal microscopy we report that there is a single procaspase-3 pool located to the cytosol in primary hepatocytes and in fractions of rat liver. In contrast, it depends on the isolation purity whether procaspase-3 is located in mitochondria of non-parenchymal liver cells, or not. All preparations with mitochondrial procaspase-3 fractions contain traces of haemoglobin, indicating the presence of some erythrocytes, which are the source of mitochondrial procaspase-3. Since erythrocytes migrate with mitochondria in subcellular fractionations, it is important to check for haemoglobin, before localizing the protein to mitochondria.     

Innermembrane association of three mitochondrial beta-oxidation enzymes revealed by immunoelectron microscopic technique

Ultrastructural localization of three mitochondrial beta-oxidation enzymes, enoyl-CoA hydratase, 3-hydroxyacyl-CoA dehydrogenase, and 3-ketoacyl-CoA thiolase in rat liver was studied by a post-embedding immunocytochemical technique. Rat liver was fixed by perfusion. Vibratome sections (100 micron thick) were embedded in Lowicryl K4M. Ultrathin sections were separately incubated with antibody to each enzyme, followed by protein A-gold complex. Gold particles representing the antigenic sites for all enzymes examined were confined exclusively to mitochondria of hepatocytes and other sinus-lining cells. Peroxisomes were consistently negative for the immunolabelling. In the mitochondria the gold particles were localized in the matrical side of inner membrane. The control experiments confirmed the specificity of the immunolabelling. The results firstly indicate that the mitochondrial beta-oxidation enzymes are present in the matrix of mitochondria and associated with the inner membrane.     

Presence of Chromatium vinosum chaperonins 10 and 60 in mitochondria and peroxisomes of rat hepatocytes

Summary— In the present study we report the occurrence of chaperonins, cpn 10 and cpn60, in Chromatium vinosum and rat hepatocytes, using specific polyclonal antibodies in conjunction with the protein A-gold immunocytochemical technique. As demonstrated by quantitative evaluations, the immunolabeling for cpn10 and cpn60 in C vinosum cells was associated primarily with the bacterial cell envelope. In rat liver homogenates, Western immunoblotting analysis has shown that antibodies to cpn10 from C vinosum recognize an unique 25-kDa protein that remains to be further characterized. On the other hand, the antibody to cpn60 from C vinosum revealed the presence of a 60-kDa protein in the rat liver homogenates. Immunofluorescence on rat liver tissue revealed an intracellular granular labeling for both chaperonins. On the other hand, using the post-embedding immunoelectron microscopy technique cpn10 and cpn60 were localized specifically in liver mitochondria and peroxisomes. Interestingly, further analysis of the labeling distribution confirmed the association of both proteins with the mitochondrial inner membrane whereas in the peroxisomes the chaperonins appeared to be located in the matrix, away from the limiting peroxisomal membrane. The colocalization of both chaperonins suggests that, as in other bacteria as well as eukaryotic cells, they may act in tandem for the proper folding of particular proteins.     

Antibodies to hepatic endosomes. Identification of two endosome antigens

Endosome fractions were prepared from rat liver homogenates, and antibodies were raised in rabbits against the integral membrane proteins. Immunofluorescent studies showed that these antibodies identified primarily intracellular structures in liver sections, isolated hepatocytes and HepG-2 cells. Immunoelectron microscopy using protein A-gold confirmed that endocytic multivesicular structures, especially those located at the biliary pole of the hepatocyte, were labeled. Biochemical analysis showed that approximately 12 endosome antigens were present. A major 43 kDa glycosylated antigen corresponded to the asialoglycoprotein receptor subunit. A further antigen identified in endosomes was a 115 kDa polypeptide pI 4.3 previously identified as a major calmodulin-binding protein. The antigens identified in rat liver endosomes were different to those previously shown by other studies to be present in the Golgi apparatus and lysosomes.     

Localization of mitochondrial DNA encoded cytochrome <Emphasis Type="Italic">c</Emphasis> oxidase subunits I and II in rat pancreatic zymogen granules and pituitary growth hormone granules

Cytochrome c oxidase (COX) complex is an integral part of the electron transport chain. Three subunits of this complex (COX I, COX II and COX III) are encoded by mitochondrial (mit-) DNA. High-resolution immunogold electron microscopy has been used to study the subcellular localization of COX I and COX II in rat tissue sections, embedded in LR Gold resin, using monoclonal antibodies for these proteins. Immunofluorescence labeling of BS-C-1 monkey kidney cells with these antibodies showed characteristic mitochondrial labeling. In immunogold labeling studies, the COX I and COX II antibodies showed strong and specific mitochondrial labeling in the liver, kidney, heart and pancreas. However, in rat pancreatic acinar tissue, in addition to mitochondrial labeling, strong and specific labeling was also observed in the zymogen granules (ZGs). In the anterior pituitary, strong labeling with these antibodies was seen in the growth hormone secretory granules. In contrast to these compartments, the COX I or COX II antibodies showed only minimal labeling (five- to tenfold lower) of the cytoplasm, endoplasmic reticulum and the nucleus. Strong labeling with the COX I or COX II antibodies was also observed in highly purified ZGs from bovine pancreas. The observed labeling, in all cases, was completely abolished upon omission of the primary antibodies. These results provide evidence that, similar to a number of other recently studied mit-proteins, COX I and COX II are also present outside the mitochondria. The presence of mit-DNA encoded COX I and COX II in extramitochondrial compartments, provides strong evidence that proteins can exit, or are exported, from the mitochondria. Although the mechanisms responsible for protein exit/export remain to be elucidated, these results raise fundamental questions concerning the roles of mitochondria and mitochondrial proteins in diverse cellular processes in different compartments.     

Innermembrane association of three mitochondrial β-oxidation enzymes revealed by immunoelectron microscopic technique

Summary Ultrastructural localization of three mitochondrial β-oxidation enzymes, enoyl-CoA hydratase, 3-hydroxyacyl-CoA dehydrogenase, and 3-ketoacyl-CoA thiolase in rat liver was studied by a post-embedding immunocytochemical technique. Rat liver was fixed by perfusion. Vibratome sections (100 μm thick) were embedded in Lowicryl K4M. Ultrathin sections were separately incubated with antibody to each enzyme, followed by protein A-gold complex. Gold particles representing the antigenic sites for all enzymes examined were confined exclusively to mitochondria of hepatocytes and other sinus-lining cells. Peroxisomes were consistently negative for the immunolabelling. In the mitochondria the gold particles were localized in the matrical side of inner membrane. The control experiments confirmed the specificity of the immunolabelling. The results firstly indicate that the mitochondrial β-oxidation enzymes are present in the matrix of mitochondria and associated with the inner membrane.     

Immunocytochemical localization of delta 3, delta 2-enoyl-CoA isomerase in rat liver. The effects of di-(2-ethylhexyl)phthalate, a peroxisome proliferator

Immunocytochemical localization of delta 3, delta 2-enoyl-CoA isomerase (isomerase) was investigated in rat liver. Livers of di-(2-ethylhexyl)phthalate (DEHP)-treated or untreated rats were perfusion-fixed and embedded in Epon or Lowicryl K4M. By light microscopy, reaction deposits for the enzyme were present in the cytoplasmic granules of hepatocytes and interlobular bile duct epithelium. Weak staining was noted in sinus-lining cells. After administration of DEHP, the granular staining of the hepatocytes was markedly enhanced, whereas the staining reaction of the sinus-lining cells decreased. The isomerase staining pattern was quite similar to that of long-chain acyl-CoA dehydrogenase (a mitochondrial marker), but different from that of catalase (a peroxisomal marker). Under electron microscopy, gold particles for isomerase were seen to be confined mainly to mitochondria of the hepatocytes, the bile duct epithelial cells and sinus-lining cells. Peroxisomes were weakly labeled. After DEHP administration, the peroxisomes were markedly induced, but the mitochondria were not. Quantitative analysis showed that the induction of the peroxisomal isomerase was only 2-fold whereas the mitochondrial isomerase was enhanced about 5-fold, 40 times as high as the peroxisomal enzyme. The results show that the mitochondria are the main intracellular site for isomerase and the peroxisomes a minor site. The mitochondrial isomerase of the rat liver is markedly induced by peroxisome proliferators, DEHP and clofibrate.     

Comparison of the effects of a preliminary hepatic washing and of saponin on the intracellular penetration of peroxidase-labeled anti-rat albumin antibodies in hepatocytes

Summary The effects of a preliminary hepatic washing with saline before liver fixation either by perfusion or immersion was compared to the effect of saponin, a membrane-permeabilizing agent, in order to ascertain which procedure is best to obtain a homogeneous distribution of albumincontaining hepatocytes in the hepatic lobule. Albumin was located in the hepatocytes by peroxidase-labeled antibodies using light and electron microscopy. The efficacy of the two procedures on the intracellular penetration of labeled antibodies in liver sections was judged by preparing transverse ultrathin sections. Both procedures yielded similar results. Liver fixation by perfusion with saponin and without a preliminary washing, however, distributes albumin-containing hepatocytes more homogeneously in the hepatic lobule and enables labeled antibodies to penetrate more satisfactorily. In contrast, when the liver is fixed by immersion, the preliminary washing is the only way to obtain an even distribution of albumin-containing hepatocytes, as saponin is not effective under these conditions. In conclusion, the localization of albumin in the hepatocytes must be adapted according to the technique used to fix the liver.     

Localization of transforming growth factor-beta 1 in mitochondria of murine heart and liver.

Using both electron microscopic immunohistochemistry and cell fractionation techniques, we show that transforming growth factor-beta 1 (TGF-beta 1) is found in mitochondria of rat and mouse cardiac myocytes and rat hepatocytes. Four different polyclonal antibodies, raised against various epitopes encompassing the mature portion of the TGF-beta 1 molecule as well as the pro-region of its precursor, were used for the electron microscopy studies. The localization of TGF-beta 1 in mitochondria was confirmed by detection of the native peptide in mitochondria isolated from rat heart and liver; the majority of native TGF-beta 1 found in liver homogenates was recovered in highly pure mitochondrial fractions. The functional role of TGF-beta in the mitochondrion is unknown at present.     

Immunological characterization of rat kininogens with monoclonal antibodies to T-kininogen. Distinction between the different domains of T-kininogen and the multiple rat kininogens.

A panel of 16 monoclonal antibodies (mAb) were produced against rat T-kininogen to characterize this family of proteins. These mAbs bound 125I-T-kininogen by radioimmunoassay as well as reacting strongly with immobilized T-kininogen in an enzyme-linked immunosorbent assay (ELISA). The reactivity of these antibodies with proteolytic fragments of T-kininogen demonstrated the recognition of several different epitopes. One antibody was specific for the domain 1 of the heavy chain and/or the light chain, twelve antibodies were specific for domain 2 and three antibodies were specific for domain 3. All monoclonal antibodies recognized the two forms of T-kininogen encoded by the two different T-kininogen genes, TI and TII kininogen, except antibody TK 16-3.1 which uniquely reacted with TII kininogen. Two antibodies recognizing domain 2 cross-reacted with the high-molecular-mass kininogen (H-kininogen), whereas all the other monoclonal antibodies were specific to T-kininogen and did not recognize the heavy chain of H-kininogen. None of the antibodies tested altered the thiol protease inhibitory activity of T-kininogen, its partial proteolysis by rat mast cell chymase or the hydrolysis of H-kininogen by rat urinary kallikrein. The use of these antibodies in the development of sensitive ELISA to measure T-kininogen levels in plasma, urine, liver microsomes and hepatocytes is described. Two different forms of T-kininogen were distinguished by these monoclonal antibodies in Western blotting using rat plasma. The localization of T-kininogen was defined using these monoclonal antibodies by immunohistochemistry in rat liver hepatocytes and rat kidney.     

Cell surface expression by adult rat hepatocytes of a non-collagen glycoprotein present in rat liver biomatrix

A rabbit antiserum raised against ACI rat liver biomatrix was used to identify components common to biomatrix and plasma membranes of adult hepatocytes. Biomatrix was isolated from intact rat livers by reverse perfusion via the inferior vena cava with sodium deoxycholate, nucleases and lipid extracting solvents. Immunoprecipitation analysis of detergent extracts of hepatocytes surface-labeled with 125I indicated that antibodies, purified from anti- biomatrix antiserum by adsorption and desorption from intact hepatocytes, showed reactivity with a single MW 105 kD component, designated Hep 105. Indirect immunofluorescence analysis showed that Hep 105 was expressed in some regions of the perisinusoidal space and in all three domains of the hepatocyte plasma membrane and was present on some but not all of the fibrous elements in frozen sections of biomatrix . The presence of Hep 105 on biomatrix was confirmed by immunoprecipitation analysis which showed that Hep 105 was present in components solubilized from biomatrix by sequential treatment with 0.5 M acetic acid, 0.05% collagenase and 4 M urea. Further characterization using immunoprecipitation analysis in combination with immobilized lectins and two-dimensional polyacrylamide gel electrophoresis (PAGE) indicated that Hep 105 was a non-collagen glycoprotein which showed charge heterogeneity and existed on the cell surface as a disulfide-linked heterodimer of apparent MW 125 kD. Two hybridomas, constructed by fusing P3 X 63Ag8 myeloma cells with spleen cells from mice immunized with intact hepatocytes, were shown by immunodepletion and two-dimensional gel electrophoretic analysis to be secreting monoclonal antibodies (Mab) against Hep 105. Examination of frozen sections of rat liver stained by indirect immunofluorescence showed that reactivity of both Mabs was concentrated in the bile canalicular domain of the hepatocyte plasma membrane, suggesting that the reactive epitopes were not accessible in the sinusoidal and intercellular membrane domains. Taken together, these results suggest that Hep 105 may play a role in the interactions between hepatocytes and extracellular matrix.     

Subcellular localization of xanthine oxidase in rat hepatocytes: high-resolution immunoelectron microscopic study combined with biochemical analysis.

Xanthine oxidase (XO), a molybdo-flavoprotein enzyme involved in purine degradation, was localized immunocytochemically in rat hepatocytes by high-resolution immunoelectron microscopy. XO was isolated from rat liver and a 150 KD polypeptide was purified. Antibodies were raised in rabbits. Small pieces of fresh liver were quickly frozen by contact with a copper block pre-cooled with liquid helium and were freeze-substituted with either 2.5% OsO4 or 0.2% glutaraldehyde in acetone. They were then warmed and embedded in Epon-Araldite or Araldite 6005. Resin sections were treated by indirect immunostaining using anti-rat liver XO antibody and protein A-gold. The labeling pattern was clearly over the cytosol and not on cell organelles. A few gold particles were found over the mitochondrial matrix, but not over the endoplasmic reticulum, Golgi apparatus, lysosomes, or peroxisomes, including their crystalloid core. These results are consistent with those of the biochemical assay of XO in this study. The significance of the occasional immunolabeling of the mitochondrial matrix remains obscure, since biochemical determinations in this study indicate no XO activity in the mitochondrial fraction.     

Proliferation and cell death of hepatocytes in regenerating rat fetal liver

Proliferation and death of hepatocytes in regenerating liver of 17-day white rat fetuses were investigated. During 2 days after liver resection (20%), animals were sacrificed every 3 h. In experimental groups, the index of Ki67-positive hepatocytes increased sharply in 15 h after liver resection. In all experimental and control groups, the ratio of the metaphase, the longest phase of mitosis, and index to mitotic index remained unchanged, indicating identical duration of hepatocytes mitoses in regenerating liver. In the regenerating and intact liver hepatocytes labeled with antibodies to caspase 3 were not detected. Thus, resection of 20% rat fetal liver did not contribute to increased apoptosis of hepatocytes.