The "direct mitogen" lead nitrate causes an intensification in lipid peroxidation and Ito cell activation in the rat liver]

We have used biochemical and immunohistochemical methods to study lipid peroxidation and activation of Ito cells in rat liver after a single administration of lead nitrate, a "direct mitogen". Lead nitrate was shown to injure hepatocytes through an increased lipid peroxidation. Response to the injury included increase in the proliferative activity of parenchymal and sinusoidal liver cells. In addition, activation of Ito cells has been noted, which manifested as increased expression of desmin and increased proliferation. However, no transformation of Ito cells into myofibroblasts has been observed. We discuss the possible role of Ito cell activation in creating conditions for the proliferation of liver parenchymal cells after the injury by lead nitrate.     

Desmin and actin in the identification of Ito cells and in monitoring their evolution to myofibroblasts in experimental liver fibrosis

It has been reported that myofibroblasts contain actin and that Ito cells are positive for desmin. The distribution of desmin and actin detected by immunofluorescence, of vitamin A autofluorescence and of Sudan III staining of lipid droplets has been evaluated in sequential stages of experimental liver fibrosis induced in rats by intraperitoneal injections of swine serum. In the normal rat liver Ito cells were positive for desmin and weakly positive for actin. Prior to the development of hepatic fibrosis a clearcut increase in number and desmin staining of lobular Ito cells was observed in treated rats, but the overall actin pattern was unchanged. In the fibrotic rat livers, highly cellular septa contained large numbers of strongly desmin-positive, actin-weakly positive Ito cells and strongly desmin- and actin-positive myofibroblasts. These observations indicate that both Ito cells and myofibroblasts are positive for desmin, but only myofibroblasts contain large amounts of actin. Visualization of actin and desmin using relatively simple techniques, allows the monitoring of Ito cells proliferation, the accumulation of these cells in fibrous septa and their evolution into myofibroblasts as characterized by their increased desmin and actin content; it also allows an indirect evaluation of the process of fibrogenesis.     

Cellular organization of normal mouse liver: a histological,quantitative immunocytochemical,and fine structural analysis

The cellular organization of normal mouse liver was studied using light and electron microscopy and quantitative immunocytochemical techniques. The general histological organization of the mouse liver is similar to livers of other mammalian species, with a lobular organization based on the distributions of portal areas and central venules. The parenchymal hepatocytes were detected with immunocytochemical techniques to recognize albumin or biotin containing cells. The macrophage Kupffer cells were identified with F4-80 immunocytochemistry, Ito stellate cells were identified with GFAP immunocytochemistry, and endothelial cells were labeled with the CD-34 antibody. Kupffer cells were labeled with intravascularly administered fluorescently labeled latex microspheres of both large (0.5 μm) and small (0.03 μm) diameters, while endothelial cells were labeled only with small diameter microspheres. Neither hepatocytes nor Ito stellate cells were labeled by intravascularly administered latex microspheres. The principal fine structural features of hepatocytes and non-parenchymal cells of mouse liver are similar to those reported for rat. Counts of immunocytochemically labeled cells with stained nuclei indicated that hepatocytes constituted approximately 52% of all labeled cells, Kupffer cells about 18%, Ito cells about 8%, and endothelial cells about 22% of all labeled cells. Approximately, 35% of the hepatocytes contained two nuclei; none of the Kupffer or Ito cells were double nucleated. The presence of canaliculi and a bile duct system appear similar to that reported for other species. The cellular organization of the mouse liver is quite similar to that of other mammalian species, confirming that the mouse presents a useful animal model for studies of liver structure and function.     

Ito Cell Morphology, α-smooth Muscle Actin and Collagen Type IV Expression in the Liver of Patients with Gastric and Colorectal Tumors

The alteration in sinusoidal collagen type IV occurrence, and myofibroblastic (α-SMA-positive) Ito cellular transformation are described in the liver of patients with malignant gastric and colorectal tumors, using electron microscopy as well as light microscopical and ultrastructural immunohistochemistry. The ultrastructural finding revealed transformation of Ito cells mostly into transitional cells in highly differentiated primary tumors and into transitional and myofibroblast-like cells with expressed changes in the other sinusoidal cells in poorly differentiated tumors. Ito cell numbers increased significantly in the livers of cancer patients. A highly significant statistical association was obtained between Ito cell numbers on the one hand and collagen type IV and α-SMA immunoreactivity on the other hand in the pericentral zone of the liver lobule. Ultrastructural immunohistochemistry showed increased collagen IV immune deposits in the space of Disse, assembled for the most part around and inside transitional cells. α-SMA immunoreactivity was detected in activated Ito cells diffuse in the lobule, with stronger expression in the intermediate and pericentral zones. It is suggested that stimuli which can influence Ito cell transformation are produced by tumor cells from the primary tumor (TGF-β1, TNF-α, PDGF-β etc.) and from the metastasizing gastric or colorectal tumor cells – matrix metalloproteinase-2 (MMP-2). It is suggested that sinusoidal extracellular matrix deterioration creates a barrier for cancer invasion on the one hand, or possibly facilitates metastasizing by ensurance of matrix for adhesion on the other hand.     

Cultured Ito cells of rat liver express the alpha 2-macroglobulin gene

Ito cells were isolated from rat liver and kept in culture for up to 13 days. The capability of the Ito cells to synthesize alpha 2-macroglobulin was analyzed at different times after isolation and by pulse-chase experiments. Newly synthesized alpha 2-macroglobulin was determined by immunoprecipitation followed by sodium dodecyl sulfate/polyacrylamide gel electrophoresis and fluorography. alpha 2-Macroglobulin synthesis was hardly detectable in Ito cells and their media 3 days after plating. However, 5-11 days after the isolation of the cells, increasing amounts of alpha 2-macroglobulin were synthesized. The results of pulse-chase experiments performed on day 7 showed that radioactively labeled alpha 2-macroglobulin decreased in the intracellular compartment and increased in the culture medium. alpha 2-Macroglobulin was identified by immunoprecipitation and sodium dodecyl sulfate/polyacrylamide gel electrophoresis under reducing and non-reducing conditions. Furthermore, when unlabeled alpha 2-macroglobulin was added during the immunoprecipitation, a competition was observed. Incubation of pancreatic elastase with culture medium of rat Ito cells or rat hepatocytes led to the same cleavage products as found with alpha 2-macroglobulin. alpha 2-Macroglobulin-specific mRNA could be demonstrated by Northern blot analysis of total RNA extracted from rat Ito cells. Under the conditions where alpha 2-macroglobulin was synthesized in Ito cells, no synthesis of alpha 1-macroglobulin, alpha 1-inhibitor 3, alpha 1-proteinase inhibitor, alpha 1-acid glycoprotein, alpha 1-acute-phase globulin (T-kininogen) and albumin could be demonstrated. It is concluded that alpha 2-macroglobulin is a true secretory protein of rat Ito cells in culture. This could be of importance for collagen metabolism in liver diseases.     

Fine-structural characteristics of the liver of the cod (Gadus morhua macrocephalus), with special regard to the concept of a hepatoskeletal system formed by Ito cells

Summary The liver of the adult cod (teleost, Gadus morhua macrocephalus) was observed with transmission and scanning electron microscopy. Hepatocytes of this animal are extremely large (about 50–70 m in diameter) and characterized by numerous large lipid droplets (5–15 m in diameter) showing fluorescence for vitamin A, though weaker than that of Ito cells. No Kupffer cells were recognized in the endothelial lining. Collagen fibrils are sparse in the perisinusoidal space, while Ito cells stretching their long cytoplasmic processes to the perisinusoidal as well as interparenchymatous spaces are frequent. There are a number of large desmosomes between the cytoplasmic processes, and all Ito cells seem to be interconnected by these junctions. The cytoplasm in the cell bodies and cell processes is occupied by bundles of intermediate filaments, while organelles are poorly developed. Small vesicles and caveolae are arranged along the plasma membrane. Scanning electron microscopy shows distinct three-dimensional networks consisting of Ito cells and their processes, which might be supporting elements of the liver tissue. We wish to emphasize the concept of this hepatoskeletal system.     

Ito cell morphology, alpha-smooth muscle actin and collagen type IV expression in the liver of patients with gastric and colorectal tumors

The alteration in sinusoidal collagen type IV occurrence, and myofibroblastic (-SMA-positive) Ito cellular transformation are described in the liver of patients with malignant gastric and colorectal tumors, using electron microscopy as well as light microscopical and ultrastructural immunohistochemistry. The ultrastructural finding revealed transformation of Ito cells mostly into transitional cells in highly differentiated primary tumors and into transitional and myofibroblast-like cells with expressed changes in the other sinusoidal cells in poorly differentiated tumors. Ito cell numbers increased significantly in the livers of cancer patients. A highly significant statistical association was obtained between Ito cell numbers on the one hand and collagen type IV and -SMA immunoreactivity on the other hand in the pericentral zone of the liver lobule.Ultrastructural immunohistochemistry showed increased collagen IV immune deposits in the space of Disse, assembled for the most part around and inside transitional cells. -SMA immunoreactivity was detected in activated Ito cells diffuse in the lobule, with stronger expression in the intermediate and pericentral zones. It is suggested that stimuli which can influence Ito cell transformation are produced by tumor cells from the primary tumor (TGF-1, TNF-, PDGF- etc.) and from the metastasizing gastric or colorectal tumor cells – matrix metalloproteinase-2 (MMP-2). It is suggested that sinusoidal extracellular matrix deterioration creates a barrier for cancer invasion on the one hand, or possibly facilitates metastasizing by ensurance of matrix for adhesion on the other hand.     

Cellular composition and regulatory function of fetal liver stroma

Hematopoietic differentiation and formation of hepatic tissue both take place in mammalian liver during its prenatal development. Hematopoietic and hepatic stem cells self-renew, proliferate and differentiate within specific microenvironment that is organized by stromal elements. Stroma of developing liver consists of different cell populations such as mesenchymal stromal cells, Ito cells, portal fibroblasts and myofibroblasts, vascular endothelial and smooth muscle cells, cells undergoing epithelial-to-mesenchymal transition. In this review, their phenotypical and functional properties, possible derivation and role in the regulation of hematopoiesis and hepatogenesis are discussed.     

Four kinetically distinct depolarization-activated K+ currents in adult mouse ventricular myocytes

In the experiments here, the time- and voltage-dependent properties of the Ca2+-independent, depolarization-activated K+ currents in adult mouse ventricular myocytes were characterized in detail. In the majority (65 of 72, approximately 90%) of cells dispersed from the ventricles, analysis of the decay phases of the outward currents revealed three distinct K+ current components: a rapidly inactivating, transient outward K+ current, Ito,f (mean +/- SEM taudecay = 85 +/- 2 ms); a slowly (mean +/- SEM taudecay = 1,162 +/- 29 ms) inactivating K+ current, IK,slow; and a non inactivating, steady state current, Iss. In a small subset (7 of 72, approximately 10%) of cells, Ito,f was absent and a slowly inactivating (mean +/- SEM taudecay = 196 +/- 7 ms) transient outward current, referred to as Ito,s, was identified; the densities and properties of IK,slow and Iss in Ito,s-expressing cells are indistinguishable from the corresponding currents in cells with Ito,f. Microdissection techniques were used to remove tissue pieces from the left ventricular apex and from the ventricular septum to allow the hypothesis that there are regional differences in Ito,f and Ito,s expression to be tested directly. Electrophysiological recordings revealed that all cells isolated from the apex express Ito,f (n = 35); Ito,s is not detected in these cells (n = 35). In the septum, by contrast, all of the cells express Ito,s (n = 28) and in the majority (22 of 28, 80%) of cells, Ito,f is also present. The density of Ito,f (mean +/- SEM at +40 mV = 6.8 +/- 0.5 pA/pF, n = 22) in septum cells, however, is significantly (P < 0.001) lower than Ito,f density in cells from the apex (mean +/- SEM at +40 mV = 34.6 +/- 2.6 pA/pF, n = 35). In addition to differences in inactivation kinetics, Ito,f, Ito,s, and IK,slow display distinct rates of recovery (from inactivation), as well as differential sensitivities to 4-aminopyridine (4-AP), tetraethylammonium (TEA), and Heteropoda toxin-3. IK,slow, for example, is blocked selectively by low (10-50 microM) concentrations of 4-AP and by (>/=25 mM) TEA. Although both Ito,f and Ito,s are blocked by high (>100 microM) 4-AP concentrations and are relatively insensitive to TEA, Ito,f is selectively blocked by nanomolar concentrations of Heteropoda toxin-3, and Ito,s (as well as IK,slow and Iss) is unaffected. Iss is partially blocked by high concentrations of 4-AP or TEA. The functional implications of the distinct properties and expression patterns of Ito,f and Ito,s, as well as the likely molecular correlates of these (and the IK,slow and Iss) currents, are discussed.     

Content of dolichol and retinol in isolated rat non-parenchymal liver cells

The liver sinusoids, that are considered as a functional unit, harbour four types of sinusoidal cells (Ito, Kupffer, endothelial and pit cells). Dolichol content has been determined in many tissues and subcellular compartments, alteration has been reported in many types of liver injury, but until now no data are available on its content in every type of sinusoidal non-parenchymal liver cells. Dolichol and retinol metabolism might intersect in their traffic in biological membranes. Intercellular as well as intracellular exchange of retinoids is an essential element of important processes occurring in liver cells. It has been suggested that the role of dolichol, besides being a carrier of oligosaccharides in the biosynthesis of N-linked glycoproteins, may be to modify membrane fluidity and permeability, and facilitate fusion of membranes. Dolichol in the membrane is intercalated between the two halves of the phospholipid bilayer, but its exact disposition is not known and the movement and distribution of retinoid in membranes may vary with the geometry of the membranes. Therefore the aim of this study is to obtain a global understanding of the sinusoidal system regarding dolichol and retinol content in each type of isolated rat liver sinusoidal cell, in normal conditions and after vitamin A administration. The information that can be drawn from the present results is that with normal vitamin A status of the animal, the dolichol content is almost uniform in all liver cells. After vitamin A supplementation, a great increase of dolichol, together with the known increase of retinol, can be measured only in a subpopulation of the Ito cells, the Ito-1 subfraction. Therefore in the cells that are present in the hepatic sinusoid, different pools of dolichol may have separate functions. Because retinol traffic among cells, membranes and plasma still remains to be fully understood, roles of dolichol in the exchange of vitamin A among sinusoidal liver cells are discussed. © 1998 John Wiley & Sons, Ltd.     

Chronic ethanol treatment: dolichol and retinol distribution in isolated rat liver cells

The aim of this study was to use chronic ethanol intoxication for 2 and 4 months as a means of studying the distribution of dolichol and retinol in isolated rat liver parenchymal cells, Kupffer cells, sinusoidal endothelial cells, and two subfractions of hepatic stellate cells: Ito 1 and Ito 2. Dolichol and retinol were studied in two batches of rats: on normal nutrition and after a load of vitamin A given 3 d before sacrifice. New observations reported are: (i) on normal nutrition, after 2 months of treatment, dolichol in HC seems to be the first target of chronic ethanol, while retinol is the first target in hepatic stellate cells; (ii) the various types of liver cells are differently affected by chronic ethanol, which highlights the importance of studying each type of sinusoidal cell; (iii) a load of vitamin A given when the damage has already occurred restores dolichol content in HC while retinol decreases; and, (iv) a link between dolichol and vitamin A metabolism might be supposed after the load of vitamin A: the percentage distribution of dolichol with 18 isoprene units (Dolichol -18) increases in all the control cells but decreases after chronic ethanol treatment. A different role of this dolichol and/or a different compartmentalization within the cell need to be further investigated.     

Intracellular and extracellular activity of cathepsin D in the liver in cirrhosis and its involution

The distribution of cathepsin D in liver with CCl4 induced cirrhosis and its involution in rats was investigated by ultrastructural cytochemistry. Besides intracellular, it was revealed the extracellular activity of cathepsin D. The reaction product was on collagen fibers near the hepatocytes and connective tissue cells as well as on the hepatocytes microvilli and on the outside part of cellular membrane of connective tissue cells (macrophage, fibroblast, Ito cells). Hence the source of extracellular cathepsin D in liver are the parenchymatous as well as nonparenchymal cell elements. The results testify that under the cirrhosis and its involution, the cathepsin D takes part in intracellular proteolysis and is secreted by hepatocytes and connective tissue cells in the intracellular space; it also takes part in extracellular catabolism of connective tissue.     

Immunohistochemical study of cell phenotypes in organ culture of the rat embryo liver

The organ culture of the liver of a 14 day old rat embryo was used for immunohistochemical recognition of the available cell types. This culture contains the tissue explant, confluent monolayer cells and a zone of single cells (ZSC). At the start of cultivation a monolayer is formed at the expense of cells slipping down together from the explant, and later these cells were seen to migrate actively from the explant and to proliferate. ZSC is formed by cells migrating from the monolayer. Desmin-containing cells (hepatoblasts, Ito cells and myofibroblasts) migrate from the explant to the monolayer and ZSC. In the monolayer hepatoblasts lose gradually desmin and are converted into cytokeratin 18 (CK-18) expressing hepatocytes. In ZSC, hepatoblasts lose desmin, but no CK-18 synthesis occurs in them. The Ito cells (hypothetical progenitor cells) are spreading over the whole culture, and desmin expression in them does not change. The embryonal Ito cells may transform presumably into myofibrils. Myofibroblasts lie flat on the periphery of ZSC. Besides, desmin myofibroblasts express alpha-actin from smooth muscles. Expression of CK-18 in cells depends on the pattern of intercellular interactions. In the monolayer, CK-18 expression extends successively via the adjacent cells towards the explant. In hepatocytes, migrating into ZSC, CK-18 expression stops. In ZSC, CK-18 expression reappears in compact clusters of stopped cells. It supposed that during formation of close contacts in the monolayer the cells-predecessors may be differentiated into hepatocytes, whereas in the case of disturbance of intercellular connections in ZSC the cells-progenitors may be converted into myofibroblasts. However, on the reconstruction of cell contacts in motionless dense clusters the cells in ZSC are differentiated into hepatocytes.     

An ultrastructural study on a new type of hepatic perisinusoidal cell in fish

Summary A new type of perisinusoidal cell containing numerous microfilaments is described for the first time. It is found in abundance in the livers of both marine and freshwater fish. These perisinusoidal cells are situated within the space of Disse and adhere firmly through desmosomes both to sinusoidal endothelial cells and to hepatocytes. The cytoplasmic microfilaments are striking and make these cells readily distinguishable from the perisinusoidal fat-storing cells of Ito. Although the function of these cells is not known, the observations presented here suggest that they may provide a supportive framework within the liver.Supported in part by Grants # GM92 and # ES07017     

Chronic atrial fibrillation does not further decrease outward currents. It increases them

Rapid atrial pacing causes electrical remodeling that leads to atrial fibrillation (AF). AF can further remodel atrial electrophysiology to maintain AF. Our previous studies showed that there was a marked difference in the duration of AF in dogs that have been atrial paced at 400 beats/min for 6 wk. We hypothesized that this difference is based on the changes in the degree of electrical remodeling caused by rapid atrial pacing versus that by AF. Right atrial cells were isolated from control dogs (Con, N = 28), from dogs with chronic AF (cAF dogs, N = 13, episodes lasting at least 6 days), or from dogs with nonsustained or brief episodes of AF (nAF dogs, N = 10, episodes lasting minutes to hours). Both transient outward (Ito) and sustained outward K+ current (Isus) densities/functions were determined using whole cell voltage-clamp techniques. In nAF cells, Ito density was reduced by 69% at +40 mV: from 7.1 +/- 0.5 pA/pF (Con, n = 59) to 2.2 +/- 0.2 pA/pF (nAF, n = 24) (P < 0.05). The voltage dependence of inactivation of Ito was shifted positively and decay kinetics were changed; however, recovery from inactivation was not altered in nAF cells. In contrast, Ito density in cAF cells was both significantly different from Con cells and larger than that in nAF cells [at +40 mV, 3.5 +/- 0.3 pA/pF (cAF, n = 29), P < 0.05]. In cAF cells, recovery from inactivation and decay of Ito were both slow; yet, voltage dependence inactivation of Ito approached that of Con cells. Furthermore, "recovered" Ito of cAF cells was more sensitive to tetraethylammonium than currents of Con and nAF cells. Isus densities of nAF and cAF cells did not differ. Both nAF and cAF cells have reduced Ito versus Con cells, but Ito remodeling of nAF cells differed from that of cAF cells. Ito in cAF dogs was likely remodeled by AF per se, whereas that in nAF dogs was likely the consequence of the rapid rate in the absence of sustained AF.     

Immunolocalization of proliferating perisinusoidal cells in rat liver

Summary There is now substantial evidence that perisinusoidal (Ito or fat-storing) cells are the principal source of extracellular matrix proteins during hepatic fibrogenesis. In rat liver these cells express the intermediate fiament protein desmin; this is now widely used as an immunohistochemical marker for these cells. It has been shown that in experimental models of acute and chronic liver injury there is an increase in the number of desmin-positive perisinusoidal cells prior to the deposition of matrix proteins; however, these studies have failed to establish whether local proliferation is involved in this expansion of the desmin-positive perisinusoidal cell population.In order to investigate the kinetics of the perisinusoidal cell response, we have developed a novel double-labelling immunohistochemical technique for the simultaneous demonstration of desmin and incorporated bromodeoxyuridine in proliferating perisinusoidal cells in sections of fixed paraffiin-embedded rat liver. Application of this technique to a model of acute liver injury (single dose carbon tetrachloride by gavage) has shown that expansion of the perisinusoidal cell population is contributed to by local proliferation, with a labelling index of 18.7% 2 days following injury.     

A simple method for the simultaneous isolation of stellate cells and hepatocytes from rat liver tissue

Hepatic stellate cells (HSCs), also referred to as Ito cells, perisinusiodal cells and fat-storing cells, have numerous vital functions. They are the main extracellular matrix-producing cells within the liver and are involved in the storage of retinol. HSCs are also known to secrete a number of liver mitogens. Current isolation techniques are cumbersome and most require a pronase digestion step, which destroys any hepatocytes present. We present a simple method for isolation and culture of hepatic stellate cells from the normally discarded washings from a two-step collagenase hepatocyte isolation, which has shown a yield of more than 1.5 × 10⁶ viable HSCs after 5 days in culture. The cells were positively identified as HSCs by staining for two intermediate filaments (desmin and GFAP) and observing their distinct morphology from other liver cell types. This efficient method allows rapid and consistent isolation of stellate cells to give a culture that may be passaged several times.     

Transforming growth factor beta responsiveness is modulated by the extracellular collagen matrix during hepatic ito cell culture

Hepatic sinusoidal Ito cells have the capacity to produce interstitial collagen types I and III as well as other matrix proteins and may be involved in hepatic fibrogenesis. Transforming growth factor beta (TGF beta) responsiveness was evaluated during in vitro cell culture, since increasing evidence suggests that this ubiquitous polypeptide can stimulate the production of collagenous proteins in a variety of cell types. TGF beta induced marked inhibition of Ito cell proliferation for cells grown on either a type I or a type IV collagen matrix. In marked contrast, the collagen synthetic response was considerably different for cells grown on a type I versus a type IV collagen matrix. When cells were grown on a type I collagen matrix, TGF beta caused a significant increase in the accumulation of collagen type I and III. When Ito cells were grown on a type IV collagen matrix, there was no stimulation of collagen production. TGF beta responsiveness was also evaluated in the setting of altered vitamin A concentrations. Freshly isolated Ito cells are engorged with vitamin A, the usual physiologic storage site for hepatic vitamin A. During in vitro culture and during in vivo fibrogenesis, Ito cells lose their vitamin A stores coincident with a transformation to a collagen-producing myofibroblast-like cell. When cultured Ito cells were grown on a type I collagen matrix and re-exposed to an increased concentration of vitamin A, the production of interstitial collagen was reduced. However, when the vitamin A-enriched Ito cells were exposed to TGF beta, the production of interstitial collagen was increased, similar to cells that had not received vitamin A.     

In vitro induction of the fat-storing phenotype in a liver connective tissue cell line-GRX

Summary Liver connective tissue cells have been characterized as perisinusoidal myofibroblasts and hepatic lipocytes (Ito cells, fat-storing cells). A concept of a single mesenchymal cell population that may be modulated between these two phenotypes has been postulated. We have previously established a continuous murine cell line, GRX, obtained from fibrotic granulomatous lesions induced by schistosomal infection in mouse liver. This cell line is considered to represent liver myofibroblasts. In the present study we have induced the conversion of these cells into lipocyte (fat storing) phenotype by treatment with insulin and indomethacin. We have quantified the lipid synthesis and the increase of activity of involved enzymes during the induction of the fat-storing phenotype and described modifications of cell organization along this modulation of cell functions. This work was supported by FINEP and CNPq (Brazil).