Ultrastructural aspects of the reversible nature of sclerotic changes in the liver

Experiments on mice have demonstrated ultrastructural changes in collagen and hepatocytes during reverse development of liver cirrhosis. Progressive lysis of collagenous fibers has been noted. Changes in hepatocytes point to a rise in the synthetic and endocytosis activity in these cells. It is suggested that exocellular lysis of collagen in the process under consideration is initiated by collagenase whereas subsequently it takes place under the action of lysosomal enzymes secreted by hepatocytes to the exocellular space.     

Collagenase of hepatocytes and sinusoidal liver cells in the reversibility of experimental cirrhosis of the liver

In order to explore the cellular source(s) and the behaviour of the collagenolytic activity previously described in rat liver homogenates, in the reversibility of experimental cirrhosis of the liver, enriched suspensions of hepatocytes and of sinusoidal liver cells were obtained by a procedure which employs low EDTA concentrations and no bacterial collagenase. Cell suspensions were prepared from three different groups of animals: 1) normal controls, 2) rats with CCl4-induced cirrhosis of the liver, and 3) rats with swine serum-induced cirrhosis of the liver. Animals were sacrificed in each group upon completion of treatment and also after 3, 6 and 12 months. In each liver wet weight and collagen concentration were determined, and collagenolytic activity of both enriched cell suspensions was measured separately. In addition, histological studies of liver tissue and ultrastructural examination of cell suspensions were performed by standard procedures. Enriched suspensions of both normal hepatocytes and sinusoidal liver cells display Ca2(+)-dependent collagenolytic activities. Both cell suspensions obtained from each of the two types of cirrhotic livers show normal or slightly increased average levels of collagenase activity at the time of treatment discontinuation, when average liver collagen content ranges from 6 to 10-fold over normal, suggesting that the normal collagenase/collagen ratio is disturbed and that collagenolytic activity is deeply decreased in relation to the actual liver collagen load.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mouse liver cell culture. I. Hepatocyte isolation

A method for isolation of mouse liver cells by a two-step perfusion with calcium and magnesium-free Hanks' salt solution followed by a medium containing collagenase is described. Several variations of the commonly used procedure for rat liver cell isolation were quantitatively compared with respect to cell yield and viability. The optimal isolation technique involved perfusion through the hepatic portal vein and routinely produced an average of 2.3 x 10(6) viable liver cells/g body weight. Optimal perfusate collagenase concentration was found to be 100 U of enzyme activity per milliliter of perfusate. Light and electron microscopic evaluation of liver morphology after several steps of the isolation showed distinct morphologic changes in hepatocytes and other liver cells during perfusion. After perfusion with Hanks' calcium- and magnesium-free solution, many hepatocytes exhibited early reversible cell injury. These changes included vesiculation and slight swelling of the endoplasmic reticulum as well as mitochondrial matrix condensation. Subsequent to perfusion with collagenase, the majority of hepatocytes appeared connected to one another only by tight junctional complexes at the bile canaliculi. Multiple evaginations were seen on the outer membrane resembling microville and probably represented the remains of cell-to-cell interdigitations between hepatocytes and sinusoidal lining cells from the space of Disse. The cytoplasmic injury seen after Hanks' perfusion was reversed after collagenase perfusion. After mechanical dispersion, isolated mouse hepatocytes were spherical in shape and existed as individual cells; many (80 to 85%) were binucleated under hase contrast light microscopy. By electron microscopy, cells appeared morphologically similar in cytoplasmic constitution to that seen in intact nonaltered liver cells.     

Different appearance of hepatic collagenase and lysosomal enzymes in recovery of experimental hepatic fibrosis.

1. Both activities of hepatic collagenase and lysosomal enzymes (acid phosphatase, beta-glucuronidase and N-acetyl-beta-D-glucosaminidase) have been observed in the recovery from experimental hepatic fibrosis in rats treated with carbon tetrachloride for 6 to 20 weeks, and compared with the disappearance of newly formed collagen fibers in the recovery process. 2. In the process of experimental hepatic fibrosis, collagenase activity reached maximum on sethe accumulation of collagen fibers in reversible hepatic fibrosis, but decreased to the same level as that of non-treated rat liver in cirrhotic stage. In the reocvery from reversible hepatic fibrosis, collagenase activity reached maximum on second day after the discontinuation of carbon tetrachloride, and decreased to the same extent of that of non-treated rat liver on seventh day. 3. Lysosomal enzyme activity was parallel to the activity of hepatic collagenase and to the accumulation of collagen fibers in the process of hepatic fibrosis. In the recovery stage, lysosomal enzyme activity in mesenchymal cells within the septa increased markedly on second day after the discontinuation of toxic agent but turned to the same level of that of non-treated rat liver seven days later, which was consistent with the appearance and disappearance of collagenase activity. On the other hand the appearance of lysosomal enzymes activities in Kupffer cells and hepatocytes was different from that of collagenase activity. That is lysosomal enzyme activity in Kupffer cells decreased in early days but increased five days later, and the enzyme activity in hepatocytes markedly decreased but gradually recovered to normal level seven days later. 4. The appearance of collagenase was observed at the beginning of the recovery stage. It indicates that mammalian collagenase initiates the collagen degradation and lysosomal enzymes might have a role in the subsequent degradation of collagen.     

A simple non-enzymatic method for the isolation of high yields of functional rat hepatocytes

A method for isolation of rat hepatocytes using liver perfusion by ethylenediamine tetra-acetic acid (EDTA)-containing sucrose solution and mechanical tissue disaggregation by controlled vibration (MVD) is described. The yields of hepatocytes produced by this method were similar to those obtained using collagenase perfusion. The cells had well preserved membrane integrity as judged by the trypan blue staining test (91 +/- 4%), ATP contents, rates of endogenous respiration and enzyme leakage that indicated they were functional cells. There was little evidence of expression of latent damage when the cells were stored either at 37 degrees C (by pre-incubation) or at 4 degrees C. This method can be used to isolate high yields of functional cells from rat liver if the collagenase perfusion technique is not available.     

Dispersion of viable pig liver cells with collagenase.

Viable suspended hepatocytes were prepared from surgical biopsy specimens of pig and human liver by digestion with collagenase. Initial perfusion of the tissue through cannulated blood vessels with 0.5 mM EGTA followed by 0.2% collagenase gave the best results. 20−870 × 10⁶ cells of which 60–95 % excluded trypan blue were obtained from 5–30 g pig liver pieces, while results with human liver specimens were usually less satisfactory. In some experiments, however, viable cells, as judged by vital stain exclusion and ability to synthesize lipids were obtained in sufficient yield. In the pig hepatocytes glycerolipid synthesis from [³H] glycerol and oxidation and esterification of [¹⁴C] oleic acid had the same characteristics as those observed earlier in rat hepatocytes.     

Type V collagen distribution in liver is reconstructed in coculture system of hepatocytes and stellate cells; the possible functions of type V collagen in liver under normal and pathological conditions

The contents of type I, type III and type V collagen and the collagen type specific distributions in liver under normal and cirrhotic conditions were examined. In CCl4 injected rat, the increasing amount of type V collagen was a specific event during the progression of cirrhosis. In normal liver, immunohistochemical observation showed that type V collagen was localized on the fine fibrils, while type I was localized on the thick fibril. Type V collagen was partially colocalized with type IV collagen. In the cirrhotic liver, type V collagen was localized on the margin of the thick fibrous septa along with type IV collagen. Type I collagen existed in the core region of fibrous septa where the stellate cells were prominent. To elucidate the mechanism of the type specific deposition of collagen in the liver, we constructed a coculture system using both stellate cells and hepatocytes. In this system, type V collagen was mainly deposited on hepatocyte colonies not on stellate cells, while type I collagen fibrils were localized on stellate cells. The spatial positioning of type I and type V collagens in vitro was similar to that in the liver. In the cell adhesion assay, the adhesion of stellate cells to type V collagen was poorer than that of the hepatocytes. The collagen type-specific affinity of the stellate cells and hepatocytes may explain the specific localization of type V collagen in the liver and coculture system. These results suggested that the functions of type V collagen are not only to connect type IV collagen with type I collagen fibril, but also to protect the parenchyma from excess type I collagen deposition produced by stellate cells under pathological conditions.     

Engineering organ perfusion protocols: NMR analysis of hepatocyte isolation from perfused rat liver

The development and use of an extracorporeal liver support device depends upon the isolation of a large number of viable, functioning hepatocytes from whole or partial livers. Current practice, however, produces nonoptimal yields, given that a large percentage of hepatocytes initially present are not successfully isolated. The normal hepatocyte isolation protocol consists of sequential perfusion with calcium chelating and collagenase buffers, and then separation of viable hepatocytes from non-viable and nonparenchymal cells, usually on the basis of cell density. In order to improve understanding regarding the metabolic and perfusion state of the liver during this perfusion protocol, ATP, pH, and tissue perfusion were evaluated using nuclear magnetic resonance (NMR). Perfusion with calcium chelating buffer was found to have minimal effect on the metabolic and perfusion parameters, whereas subsequent perfusion with collagenase buffer produced large declines in ATP, pH, and homogeneity of perfusion within 3 min. Perfusion with calcium-chelating buffer alone, or perfusion with calcium chelating buffer followed by a short period of ischemia to mimic the perfusion disruption of collagenase, did not produce the same decline in metabolic parameters. This NMR data suggested that enhancing the early perfusion and penetration of collagenase or prolonging the nontoxic calcium-chelation step may improve the yield and/or functionality of isolated cells. Therefore, several altered perfusion protocols were evaluated in terms of yield of viable parenchymal hepatocytes and hepatocyte albumin production. Although increasing the perfusion flow rate and initial perfusion with inactive (cold) collagenase did not produce significant improvements when compared with the control protocol (control cell yield 226 +/- 42 x 10(6) viable hepatocytes for 10- to 14-week-old female Lewis rat), prolonging and enhancing the calcium-chelating perfusion step or increasing the collagenase concentration did yield a significantly great number of viable parenchymal hepatocytes (393 +/- 44 and 328 +/- 39 x 10(6) viable hepatocytes, respectively) with no change in albumin production per seeded viable cell. (c) 1994 John Wiley & Sons, Inc.     

Development of an Improved Method for the Isolation and Culture of Newborn Sheep Primary Hepatocytes

The liver plays a crucial role in metabolism, synthesis, biotransformation, secretion, and excretion. Hepatocytes are the main cells of the liver and can be used as a cell model to study liver function. The classic method of collagenase perfusion to isolate hepatocytes is a two-step technique that is time-consuming, labor-intensive, and has high technical requirements. Therefore, in this study, we compared different methods for isolating and culturing primary hepatocytes. We found that the 0.25% trypsin and 0.1 mg/mL type IV collagenase mixture at a 1:1 ratio showed the most efficient cell digestion, and William’s Medium E complete medium showed the best growth and proliferation. The isolated cells showed the typical irregular polygonal morphology of hepatocytes. Periodic acid–Schiff staining and immunofluorescence confirmed that the isolated cells were positive for glycogen and hepatocyte-specific markers cytokeratin 18, AFP, and albumin. On subculturing, stable cell lines were obtained. Therefore, we optimized the isolation and in vitro culture method to obtain highly pure (>95%) sheep primary hepatocytes from newborn sheep liver tissue.     

Extracellular breakdown of collagen as affected by lysosomal enzymes during the involution of liver cirrhosis

Electron microscopy and electron histochemistry (exposure to acid phosphatase) were used to study the mechanisms of extracellular degradation of collagen in the liver during involution of experimental cirrhosis. The following results were obtained: extracellular secretion of lysosomal enzymes from hepatocytes and connective tissue cells takes place in liver cirrhosis and its involution; partial hepatectomy during liver cirrhosis stimulates the activity of acid phosphatase in the liver cells; the lysosomal enzymes, excreted from hepatocytes and connective tissue cells by means of exocytosis take an active part in collagen extracellular degradation in vivo; at initial stages of cirrhosis involution extracellular degradation of collagen in the liver occurs at the expense of lysosomal enzymes from hepatocytes and connective tissue cells. Subsequently, as cirrhosis regresses, the principal role in the lysis of collagen gradually passes to lysosomal enzymes of hepatocytes.     

The gelatinolytic activity of rat uterus collagenase

The collagenase produced by rat uterine cells in culture has been examined for its ability to degrade denatured collagen. Acting as a gelatinase, rat uterus collagenase was able to successfully degrade the denatured chains of collagen types I through V. In addition, the enzyme produced multiple cleavages in these chains and displayed values for Km of 4-5 microM, compared to values of 1-2 microM when native collagen was used as substrate. Furthermore, rat uterus collagenase degraded the alpha 2 chain of denatured type I collagen at a significantly faster rate than the alpha 1 chain, as previously observed for human skin fibroblast collagenase. In contrast to the action of human skin collagenase, however, the rat uterus enzyme was found to be a markedly better gelatinase than a collagenase, degrading the alpha chains of denatured type I guinea pig skin collagen at rates some 7-15-fold greater than native collagen. Human skin collagenase degrades the same denatured chains at rates ranging from 13-44% of its rate on native collagen. Rat uterus collagenase, then, is approximately 50 times better a gelatinase than is human skin collagenase. In addition to its ability to cleave denatured collagen chains at greater rates than native collagen, the rat uterus collagenase also attacked a wider spectrum of peptide bonds in gelatin than does human skin collagenase. In addition to cleaving the Gly-Leu and Gly-Ile bonds characteristic of its action on native collagen, rat uterus collagenase readily catalyzed the cleavage of Gly-Phe bonds in gelatin. The rat enzyme was also capable of cleaving Gly-Ala and Gly-Val bonds, although these bonds were somewhat less preferred by the enzyme. The cleavage of peptide bonds other than Gly-Leu and Gly-Ile appears to be a property of the collagenase itself and not a contaminating protease. Thus, it appears that the collagenase responsible for the degradation of collagen during the massive involution of the uterus might also act as a gelatinase to further degrade the initial products of collagenolysis to small peptides suitable for further metabolism.     

Stimulation of growth of primary cultured adult rat hepatocytes without growth factors by coculture with nonparenchymal liver cells

DNA synthesis of adult rat parenchymal hepatocytes alone in primary culture can be stimulated only by the addition of humoral growth factors to the culture medium. However, when parenchymal hepatocytes were cocultured with nonparenchymal liver cells from adult rats, their DNA synthesis was markedly stimulated in the absence of added growth factors or calf serum. DNA synthesis of parenchymal hepatocytes was not stimulated by conditioned medium from nonparenchymal liver cells and was greatest when the parenchymal cells were plated on 24-h cultures of nonparenchymal liver cells. A dead feeder layer of nonparenchymal cells was almost as effective as a feeder layer of viable nonparenchymal cells. These results suggest that the stimulation of DNA synthesis in parenchymal hepatocytes was not due to some soluble factors secreted by nonparenchymal liver cells but to an insoluble material(s) produced by the nonparenchymal liver cells. This insoluble material(s) was collagenase- and acid-sensitive, suggesting that it was a protein containing collagen. The effect of nonparenchymal liver cells was specific: coculture with hepatoma cells, liver epithelial cells, or Swiss 3T3 cells did not stimulate DNA synthesis in parenchymal hepatocytes. Added insulin and epidermal growth factor showed additive effects with nonparenchymal cells in the cocultures. These results suggest that DNA synthesis in parenchymal hepatocytes is stimulated not only by various humoral growth factors but also by cell-cell interaction between parenchymal and nonparenchymal hepatocytes, possibly endothelial cells. This cell-cell interaction may be important in repair of liver damage and liver regeneration.     

Localization of collagen prolyl hydroxylase to the hepatocyte : Studies in primary monolayer cultures of parenchymal cells from adult rat liver

Significant levels of prolyl hydroxylase activity (prolyl-glycyl-peptide, 2-oxoglutarate: oxygen oxidoreductase; EC 1.14.11.2) have been found in freshly isolated hepatocytes prepared from normal or regenerated adult rat liver and primary non-proliferating monolayer cultures of these cells. Four days after partial hepatectomy, the intact regenerated liver contained two times the normal level of prolyl hydroxylase activity. Freshly isolated hepatocytes contained 24% of the total prolyl hydroxylase activity in normal liver and 47% of that in regenerated liver. Upon incubation of hepatocytes for 24 h in a chemically defined culture medium containing insulin, prolyl hydroxylase activity rose 2- to 3-fold, and gradually declined during the next 48 h. The rise in prolyl hydroxylase activity was blocked by addition of cycloheximide to the culture medium. The presence of prolyl hydroxylase activity in hepatocyte cultures was not likely due to contamination with non-parenchymal liver cells. The latter cells contained less than 20% of the total enzyme activity recovered in all cells isolated from the liver. Furthermore, prolyl hydroxylase was localized by immunofluorescence uniformly to the hepatocytes in culture. Cultured hepatocytes converted [¹⁴C]proline to [¹⁴C]hydroxyproline at rates comparable to those reported for whole liver. However, only a small portion of the hydroxyproline containing product was present as collagen protein, suggesting its rapid degradation in culture. We conclude that the liver parenchymal cell may actively participate in collagen synthesis and possibly in collagen degradation.     

Activation of collagen synthesis in primary culture of rat liver parenchymal cells (hepatocytes)

An increase in collagen synthesis by hepatic parenchymal cells (hepatocytes) was observed during 8 days in primary culture by the quantification of total [3H]hydroxyproline as a marker of total collagen synthesis and the ratio of [3H]hydroxyproline in the high-molecular-weight fraction to total [3H]hydroxyproline as a marker of collagen degradation after incubation of the cells with [3H]proline for 24 h. Type analysis of the collagen produced by the cells after 8 days in culture showed the presence of type I and type III collagens in addition to the components corresponding to type IV and type V (alpha A and alpha B) collagens. Only the latter two types were found in the collagens produced by the cells after 2 days in primary culture. The purity of the hepatocytes inoculated was 97%, and the majority of the contaminating small cells were erythrocytes. The rate of serum albumin synthesis, which is a typical function of the hepatocytes, was constant or increased during the culture period. Immuno-electron microscopic observation indicated the production of type I collagen by the hepatocytes after 8 days in primary culture. These results are explained only by the activation of collagen synthesis in the day-8 hepatocytes in primary culture.     

Activation of latent rheumatoid synovial collagenase by human mast cell tryptase

The functional role of mast cells in rheumatoid synovium was investigated by assessing the ability of mast cell tryptase to activate latent collagenase derived from rheumatoid synoviocytes. Tryptase, a mast cell neutral protease, was demonstrated in situ to reside in rheumatoid synovial mast cells, by an immunoperoxidase technique using a mouse mAb against tryptase, and in vitro to be released by dispersed synovial mast cells after both immunologic and nonimmunologic challenge. Each rheumatoid synovial mast cell contains an average of 6.2 pg of immunoreactive tryptase and the percent release values of this protease correlated with those of histamine (r = 0.58, p less than 0.01). The ability of purified tryptase to promote collagenolysis was demonstrated in a dose-dependent fashion using latent collagenase derived from rheumatoid synovium, synovial fluid, IL-1-stimulated cultured synoviocytes, and partially purified latent collagenase derived from conditioned media, with between 10 and 92% of the collagen substrate degraded. [3H] Collagen, treated with tryptase-activated latent collagenase, was subjected to electrophoresis on SDS polyacrylamide gels and autoradiography showed the collagen degradation pattern (A, B) characteristically produced by collagenase. Mast cell lysates also activated synovial latent collagenase yielding 24% digestion of collagen substrate. This activator in mast cell lysates could be inhibited by diisopropylflurophosphate or by immunoadsorption of tryptase. Thus, mast cells may activate metalloproteinases and play a role in the catabolism of collagen that occurs in rheumatoid synovium.     

4 in 1: Antibody‐free protocol for isolating the main hepatic cells from healthy and cirrhotic single rat livers

Liver cells isolated from pre‐clinical models are essential tools for studying liver (patho)physiology, and also for screening new therapeutic options. We aimed at developing a new antibody‐free isolation method able to obtain the four main hepatic cell types (hepatocytes, liver sinusoidal endothelial cells [LSEC], hepatic macrophages [HMΦ] and hepatic stellate cells [HSC]) from a single rat liver. Control and cirrhotic (CCl₄ and TAA) rat livers (n = 6) were perfused, digested with collagenase and mechanically disaggregated obtaining a multicellular suspension. Hepatocytes were purified by low revolution centrifugations while non‐parenchymal cells were subjected to differential centrifugation. Two different fractions were obtained: HSC and mixed LSEC + HMΦ. Further LSEC and HMΦ enrichment was achieved by selective adherence time to collagen‐coated substrates. Isolated cells showed high viability (80%‐95%) and purity (>95%) and were characterized as functional: hepatocytes synthetized albumin and urea, LSEC maintained endocytic capacity and in vivo fenestrae distribution, HMΦ increased expression of inflammatory markers in response to LPS and HSC were activated upon in vitro culture. The 4 in 1 protocol allows the simultaneous isolation of highly pure and functional hepatic cell sub‐populations from control or cirrhotic single livers without antibody selection.     

Maintenance of differentiated phenotype of cultured rat hepatic lipocytes by basement membrane matrix

This study examined the role of extracellular matrix in regulating matrix phenotype of hepatic lipocytes, the major source of matrix in liver. Lipocytes (Ito, stellate, or fat-storing cells) were purified from normal rat liver and established in primary culture on either uncoated plastic, plastic coated with individual matrix proteins, or a "complete" gel matrix, a basement membrane-like matrix derived from the Engelbreth-Holm-Swarm (EHS) murine tumor. The ultrastructure of lipocytes cultured on the gel matrix resembled that of cells in normal liver, whereas lipocytes on plastic had dispersed nuclear chromatin and expanded rough endoplasmic reticulum, consistent with active proliferation and secretion. Lipocytes on the gel matrix exhibited no proliferative activity; cells maintained on plastic proliferated and produced type I collagen predominantly. Total collagen secretion by lipocytes on the gel matrix was 29% of that of cells on plastic, and consisted of type III collagen only. This difference extended to proteoglycan production, which was less than 5% of the amount produced by cells in conventional culture on plastic. The effects of the EHS gel were not reproduced by the individual components of the gel (laminin, type IV collagen, and heparan sulfate proteoglycan) or by a type I collagen gel. They were also reversible upon transfer of the cells to conventional culture. In contrast to lipocytes, collagen synthesis by hepatocytes was similar whether cultured on EHS gel or on plastic. These results show that the extracellular matrix can modulate matrix protein production by lipocytes and imply that, in early hepatic inflammation, changes in the hepatic subendothelial matrix may underlie stimulation of lipocyte matrix production and progression of the fibrotic process.     

Transformation of isolated rat hepatocytes with simian virus 40

Rat hepatocytes were transformed by simian virus 40 (SV40). Hepatocytes from two different strains of rats and a temperature-sensitive mutant (SV40tsA 1609), as well as wild-type virus were used. In all cases, transformed cells arose from approximately 50% of the cultures containing hepatocytes on collagen gels or a collagen gel-nylon mesh substratum. Cells did not proliferate in mock-infected cultures. SV40-transformed hepatocytes were epithelial in morphology, retained large numbers of mitochondria, acquired an increased nucleus to cytoplasm ratio, and contained cytoplasmic vacuoles. Evidence that these cells were transformed by SV40 came from the findings that transformants were 100% positive for SV40 tumor antigen expression, and that SV40 was rescued when transformed hepatocytes were fused with monkey cells. All SV40-transformed cell lines tested formed clones in soft agarose. Several cell lines transformed by SV40tsA 1609 were temperature dependent for colony formation on plastic dishes. Transformants were diverse in the expression of characteristic liver gene functions. Of eight cell lines tested, one secreted 24% of total protein as albumin, which was comparable to albumin production by freshly plated hepatocytes; two other cell lines produced 4.2 and 5.7%, respectively. Tyrosine aminotransferase activity was present in five cell lines tested but was inducible by dexamethasone treatment in only two. We conclude from these studies that adult, nonproliferating rat hepatocytes are competent for virus transformation.     

Production of procollagenase by cultured human keratinocytes

Using a collagen film assay utilizing 14C-labeled type I collagen, we demonstrated that cultured human keratinocytes produced a procollagenase after treatment with the tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA). Production of collagenase paralleled alterations in cellular morphology induced by TPA. When procollagenase was immunoprecipitated with antibody to human fibroblast collagenase and analyzed on sodium dodecyl sulfate-polyacrylamide gels, the zymogen was revealed as a 56- and 51-kDa doublet. The keratinocyte-derived collagenase was a neutral metalloprotease, required activation with trypsin for detection in the collagenase assay and produced the characteristic three-quarter and one-quarter length collagen cleavage products when incubated with type I collagen at 25 degrees C. The enzyme was inhibited by serum and cysteine and was largely unaffected by serine, thiol, and carboxyl protease inhibitors. Cycloheximide inhibited the TPA-induced production of collagenase, suggesting that the procollagenase was not stored preformed in the keratinocytes. Keratinocytes treated with a tumor-promoting analogue of TPA also produced collagenase, but cells treated with cytochalasin B, interleukin-1, or two non-tumor promoting phorbol esters did not. Keratinocyte-derived collagenase may play a role in wound healing and morphogenesis.     

The preparation of highly enriched fractions of binucleated rat hepatocytes by centrifugal elutriation and flow cytometry.

A procedure is described for the isolation of highly enriched fractions of binucleated hepatocytes from rat liver. Liver cells isolated by EGTA and collagenase perfusion were initially subjected to centrifugal elutriation and second to flow cytometry coupled with Hoechst 33342 staining. The elutriation step yielded hepatocyte fractions which contained almost entirely mononuclear diploid cells and fractions enriched in binucleate hepatocytes. The fractions with the highest proportion of binucleated hepatocytes contained between 50 and 56% of these cells. Subsequent flow cytometric cell sorting yielded fractions which contained greater than 80% binucleated cells. These cells were viable in culture as demonstrated by the immunohistochemical detection of bromodeoxyuridine incorporation.