Functional dissimilarity of melanomacrophage centres in the liver and spleen from females of the teleost fish <Emphasis Type="Italic">Prochilodus argenteus</Emphasis>

Melanomacrophage centres (MMCs) are formed by macrophage aggregates containing pigments such as hemosiderin, melanin and lipofuscin. MMCs are found in animals such as reptiles, amphibians and, mainly, fishes, in organs such as the kidney, spleen, thymus and liver. In teleost fish, several functions have been attributed to MMCs, including the capture and storage of cations, the phagocytosis of cellular debris and immunological reactions. As the use of MMCs has been suggested as a tool for the assessment of environmental impacts, our aim has been to describe the various metabolic processes performed by MMCs in diverse organs (liver and spleen) by using the teleost Prochilodus argenteus as an animal model. MMCs from the liver and spleen were assessed by histochemistry, transmission electron microscopy, scanning electron microscopy, X-ray microanalysis techniques and biochemical assay for N-acetylglucosaminidase activity. The data showed metabolic differences in MMCs between the liver and spleen of P. argenteus in their morphometric characteristics and biochemical and elemental composition. The implications of these findings are discussed, focusing on their role in organ metabolism.     

Morphofunctional Differentiation in the Liver

The purpose of these experiments was to determine whether materials physically present in, and modifying the activity of, the reticuloendothelial (RE) cells could influence selected metabolic functions in hepatic parenchyma, and modify the overall regenerative growth in partially resected livers. Induction of tyrosine transaminase by endotoxin or cortisone, and repression, of either endogenous or hormonally induced glyconeogenesis by the toxin, progressed as well in partially hepatectomized animals as in normal mice. The uptake, binding and association of ³H-cortisone with its receptors was largely uninfluenced by partial hepatectomy.
In doses that stimulate the RE function, administration of either bacterial endotoxin or cortisone resulted in a delayed burst of ³H-thymidine incorporation in regenerating livers. In, higher doses, cortisone lowered DNA synthesis associated with regeneration. Celite or bentonite also retarded the onset of DNA formation after partial hepatectomy. Moreover, the regenerative growth was almost completely eliminated in animals which had been rendered tolerant to bacterial endotoxin prior to surgery. Post-operative administration of bovine somatotropin, or phagocytosis of latex particles, however, did not influence the increased ³H-thymidine incorporation associated with the regenerative growth. These results are discussed as a model to explore possible intercellular co-operation regulating a variety of cellular responses.     

Levels of prostaglandin E1 and F2 alpha in the dynamics of toxic-infectious shock induced by Yersinia pestis

Murine toxin of Yersinia pestis when injected in the rat tail vein (LD50) caused pronounced alterations in PGE1 and PGF2 alpha content in different tissues (lung, heart, spleen, liver, kidney, small intestine) and blood. Heat-inactivated toxin has been shown to have the same effects as the intact toxin preparation. The changes in PG content are, probably, due to the lipopolysaccharide component of both preparations. The differences in metabolic effects between Yersinia pestis endotoxin and lipopolysaccharides of other Gram-negative bacteria are discussed.     

Morphofunctional Differentiation in the Liver

The influence of endotoxin and cortisone on the function of hepatic cells was studied in relation to the effect of partial hepatectomy on their activity. The overall rate of clearance of carbon (K) suffered a diminution within the first few hours after surgery but carbon uptake per unit weight tissue was elevated as a result of hepatic resection. The K values were increased by endotoxin (100°g i.p.) alone or together with cortisone (1 mg i.p.) but the hormone alone lowered the clearance rates in high doses (5 mg i.p.). Treatment with either substance increased liver weight over and above the control level in early phases of regeneration and lowered it in the later phases. The actions of cortisone and endotoxin were not additive on either process. As regards the influence of cellular cycle on hormonally modified gene activity, refractoriness to the hypertrophic effect of cortisone (5 mg i.p. a dose which lowered the K value at all times) developed soon after hepatic resection and continued for at least 36 h after surgery. These and other results indicate that the RE cells remain susceptible to external influences throughout the regenerative cycle and do not passively follow the behaviour pattern of parenchyma. An active contribution of RE cells is further supported by the observation that regeneration was accompanied by a progressive increase in spleen weight. Furthermore, because uptake and binding of cortisone to 'specific' receptors progressed at least as well as in control mice at all these time periods, the refractoriness to cortisone action must lie at some stage beyond uptake, processing or association of steroid with the appropriate receptor. These data indicate the necessity to consider the behaviour of individual cell types in order to comprehend the integrated responses observed during growth, development and differentiation in the liver.     

An in vitro approach to the study of target organ toxicity of drugs and chemicals

Summary A major goal of our laboratory has been the development of primary culture systems that retain differentiated fucntions and responses characteristic of intact tissues in vivo. Specifically, we have developed cellular models of primary cultures of rat heart, liver, and kidney cells to explore the mechanisms by which drugs or chemicals may be toxic to key organs of the body and to develop new techniques by which xenobiotics may be evaluated or identified as potential toxicants to living systems. The purpose of this paper is to describe our rationale and approach to the study of target organ toxicology with in vitro cellular systems.     

Biochemical characterization of digestive membrane‐associated alkaline phosphatase from the velvet bean caterpillar Anticarsia gemmatalis

In Brazil, the use of transgenic plants expressing the insect‐toxic Bacillus thuringiensis endotoxin has been successfully used as pest control management since 2013 in transgenic soybean lineages against pest caterpillars such as Helicoverpa armigera. These toxins, endogenously expressed by the plants or sprayed over the crops, are ingested by the insect and bind to receptors in the midgut of these animals, resulting in disruption of digestion and lower insect survival rates. Here, we identified and characterized a membrane‐associated alkaline phosphatase (ALP) in the midgut of Anticarsia gemmatalis, the main soybean defoliator pest in Brazil, and data suggested that it binds to Cry1Ac toxin in vitro. Our data showed a peak of ALP activity in homogenate samples of the midgut dissected from the 4th and 5th instars larvae. The brush border membrane vesicles obtained from the midgut of these larvae were used to purify a 60 kDa ALP, as detected by in‐gel activity and in vitro biochemical characterization using pharmacological inhibitors and mass spectrometry. When Cry1Ac toxin was supplied to the diet, it was efficient in decreasing larval weight gain and survival. Indeed, in vitro incubation of Cry1Ac toxin with the purified ALP resulted in a 43% decrease in ALP specific activity and enzyme‐linked immunosorbent assay showed that ALP interacts with Cry1Ac toxin in vitro, thus suggesting that ALP could function as a Cry toxin ligand. This is a first report characterizing an ALP in A. gemmatalis.     

The hepatic role in carcinogenesis and its early detection--the vinyl chloride model

The liver''s role in vinyl chloride toxicity and carcinogenicity is providing a better understanding of the chemical carcinogenesis mechanism. A variety of both malignant and benign hepatic tumors has been demonstrated with prolonged exposure to vinyl chloride. The multi-system involvment of this carcinogen and toxin has provided a model for the study of chemical carcinogenesis common to both man and animal. Clinical studies have shown the usefulness of biochemical, radioisotopic, and radiological studies in the detection of toxic and carcinogenic lesions. Animal studies have demonstrated the biochemical metabolism by the liver of vinyl chloride-produced intermediates which are mutagenic in bacterial systems and may be the ultimate carcinogens. Hepatic subcellular enzyme studies prove preliminary evidence of cellular adaptation and increased detoxification. Disruption of this oxidization and detoxification balance may be the key to the malignant transformation of cells. A working hypothesis is presented which may explain the metabolism of vinyl chloride into mutagenic intermediates by the liver cell and the development of malignant transformation by extra hepatic sinusoidal lining cells, lung cells, and brain tissue.     

Cellular tumorigenicity in nude mice. Role of susceptibility to natural killer cells

The athymic nude mouse is a useful animal model for assaying the neoplastic growth potential in vivo of animal cells transformed in vitro. Despite the demonstrated absence of thymus-dependent immunological functions, however, the nude mouse has now been shown to reject transplants of certain highly malignant heterologous tumors. In addition, a few transformed mammalian cell lines that exhibit all or most of the cellular phenotypes usually associated with malignancy fail to grow as tumors when injected into nude mice. In a continuing study to identify the in vitro phenotypes associated with tumor-forming ability in vivo, we investigated the role of cellular susceptibility to the naturally occurring, thymus-independent lymphocytes (natural killer or NK cells) in determining tumor induction by animal cells in nude mice. A representative collection of animal cells (ranging from normal human diploid cell strains to highly tumorigenic clonal cell lines, either transformed in vitro or derived from experimental tumors) was tested to see if the ability of cells to form tumors is consistently correlated with their susceptibility to NK cell-mediated lysis measured in vitro with splenic leukocytes from nude mice. If the physiological role of the NK cells in vivo were to recognize, and possibly to destroy, incipient tumor cells in situ, a direct association between cellular tumorigenicity and susceptibility to NK activity, might be expected. If, on the other hand, the formation of growing tumors by animal cells in nude mice depended on their ability to escape the cytolytic activity of NK cells, cellular tumorigenicity would be associated with cellular resistance to NK cells. Results obtained in this study failed to confirm either of these associations. Thus, cellular suscepbibility to NK cells, at least as determined by direct cytotoxicity assay in vitro, is not a useful predictive indicator of cellular tumorigenicity in nude mice.     

Hepatic tissue engineering: from transplantation to customized cell-based liver directed therapies from the laboratory

Today, liver transplantation is still the only curative treatment for liver failure due to end-stages liver diseases. Donor organ shortage, high cost and the need of immunosuppressive medications are still the major limitations in the field of liver transplantation. Thus, alternative innovative cell-based liver directed therapies, e.g. liver tissue engineering, are under investigation with the aim, that in future an artificial liver tissue could be created and be used for the replacement of the liver function in patients. Using cells instead of organs in this setting should permit (i) expansion of cells in an in vitro phase, (ii) genetic or immunological manipulation of cells for transplantation, (iii) tissue typing and cryopreservation in a cell bank, and (iv) the ex vivo genetic modification of patient's own cells prior re-implantation. Function and differentiation of liver cells are influenced by the three-dimensional organ architecture. The use of polymeric matrices permits the three dimensional formation of a neo-tissue and specific stimulation by adequate modification of the matrix-surface which might be essential for appropriate differentiation of transplanted cells. Additionally, culturing hepatocytes on three dimensional matrices permits culture in a flow bioreactor system with increased function and survival of the cultured cells. Based on bioreactor technology, bioartificial liver devices (BAL) are developed for extracorporeal liver support. Although BALs improved clinical and metabolic conditions, increased patient survival rates have not been proven yet. For intra-corporeal liver replacement, a concept which combines Tissue Engineering using three-dimensional, highly porous matrices with cell transplantation could be useful. In such a concept, whole liver mass transplantation, long term engraftment and function as well as correction of a metabolic defect in animal models could be achieved with a principally reversible procedure. Future studies have to investigate, which environmental conditions and transplantation system would be most suitable for the development of artificial functional liver tissue including blood supply for a potential use in a clinical setting.     

Telomere shortening impairs organ regeneration by inhibiting cell cycle re-entry of a subpopulation of cells

Telomere shortening limits the regenerative capacity of primary cells in vitro by inducing cellular senescence characterized by a permanent growth arrest of cells with critically short telomeres. To test whether this in vitro model of cellular senescence applies to impaired organ regeneration induced by telomere shortening in vivo, we monitored liver regeneration after partial hepatectomy in telomerase-deficient mice. Our study shows that telomere shortening is heterogeneous at the cellular level and inhibits a subpopulation of cells with critically short telomeres from entering the cell cycle. This subpopulation of cells with impaired proliferative capacity shows senescence-associated beta-galactosidase activity, while organ regeneration is accomplished by cells with sufficient telomere reserves that are capable of additional rounds of cell division. This study provides experimental evidence for the existence of an in vivo process of cellular senescence induced by critical telomere shortening that has functional impact on organ regeneration.     

Two sites of intracellular localization of rhodaminyl-phalloidin in hepatocytes

The uptake of a fluorescent phallotoxin (tetramethylrhodaminyl-phalloidin) into rat hepatocytes has been studied. The experiments were performed in vitro, using freshly isolated hepatocyte suspensions or monolayers of hepatocytes cultured for up to 5 days, as well as in vivo, by investigating cryostat sections of a liver from an animal injected with the labelled toxin. In vitro, in freshly isolated hepatocytes, a staining of actin was observed. On the contrary, if the hepatocytes were cultured, only fluorescent endocytotic vesicles were found accumulated around the nucleus, and remaining in the cells unchanged for several days. In vivo, both fluorescent patterns were observed, often in one and the same cell. The endocytotic vesicles of rhodaminylphalloidin looked very similar to those obtained with fluoresceinyl-concanavalin A. navalin A. We conclude that in all systems the fluorescent phallotoxin enters the hepatocytes by endocytosis. However, in the freshly isolated cells the endocytotic vesicles apparently undergo some kind of processing with release of the toxin and subsequent staining of cellular actin, while in cultured hepatocytes the endocytotic vesicles persist unprocessed.     

Binding of enterotoxin from Clostridium perfringens type A to liver cells in vivo and in vitro. The enterotoxin causes membrane leakage

Enterotoxin from Clostridium perfringens was shown to retain its biological activity after labelling with 125I. When injected intravenously into mice and rats, most of the radioactivity in the organs was present in the form of intact toxin. Studies of the tissue distribution of labelled enterotoxin showed the largest amounts in the liver, where the activity reached a maximum 10--15 min after administration. The highest concentration per g tissue was found in liver and kidneys. The radioactivity was excreted in the urine as a mixture of intact labelled toxin and low molecular weight degradation products. In vitro studies with purified parenchymal liver cells showed rapid release of lactate dehydrogenase (LDH) during treatment with enterotoxin, thus indicating severe membrane damage.     

Cholera toxin increases the rate of antigen-stimulated calcium influx in rat basophilic leukemia cells

Cholera toxin pretreatment has been found to cause a 3-fold increase in the initial rate of antigen-stimulated secretion of serotonin from rat basophilic leukemia (RBL) cells. Under similar conditions, cholera toxin enhances the antigen-stimulated rise in cytoplasmic free ionized calcium levels and causes a 2-3-fold increase in the rate of antigen-stimulated influx of 45Ca. In intact RBL cells cholera toxin pretreatment potentiates the antigen-stimulated production of inositol phosphates, but in permeabilized cells, with strongly buffered free calcium levels, no effect of cholera toxin pretreatment on the antigen-stimulated activation of cellular phospholipase activities is observed. In addition, pretreatment of cells with tetradecanoylphorbol acetate inhibits antigen-stimulated production of inositol phosphates by greater than 95%, while the stimulated influx of 45Ca remains unaffected. These data indicate that the antigen-stimulated influx of calcium into RBL cells can be dissociated from the production of inositol phosphates in these cells. The observed effects of cholera toxin on exocytosis and Ca2+ influx in RBL cells are not due to the elevation of cellular cyclic AMP levels since a variety of agents capable of elevating cellular cyclic AMP levels do not mimic these effects. Together, these data suggest that a cholera toxin-sensitive guanine nucleotide-binding protein is involved in the pathway responsible for the antigen-stimulated influx of calcium into RBL cells.     

In Vivo Interaction of Endotoxin with a Plasma Lipoprotein Having Esterase Activity

Circulating endotoxin was specifically precipitated from plasma samples withdrawn from three different animal species subsequent to parenteral injection of the toxin. Lipoprotein-positive staining and esterase activity were demonstrated on the precipitation lines formed in immunodiffusion, thus establishing the in vivo interaction of endotoxin with a plasma lipoprotein having esterase activity. Evidence was given to show that the intensity of this interaction in circulating plasma increased gradually with time. The concordance of this in vivo inter-action with the in vitro degradation and inactivation of endotoxin by plasma esterases is discussed.     

KIAA1363 affects retinyl ester turnover in cultured murine and human hepatic stellate cells

Large quantities of vitamin A are stored as retinyl esters (REs) in specialized liver cells, the hepatic stellate cells (HSCs). To date, the enzymes controlling RE degradation in HSCs are poorly understood. In this study, we identified KIAA1363 (also annotated as arylacetamide deacetylase 1 or neutral cholesterol ester hydrolase 1) as a novel RE hydrolase. We show that KIAA1363 is expressed in the liver, mainly in HSCs, and exhibits RE hydrolase activity at neutral pH. Accordingly, addition of the KIAA1363-specific inhibitor JW480 largely reduced RE hydrolase activity in lysates of cultured murine and human HSCs. Furthermore, cell fractionation experiments and confocal microscopy studies showed that KIAA1363 localizes to the endoplasmic reticulum. We demonstrate that overexpression of KIAA1363 in cells led to lower cellular RE content after a retinol loading period. Conversely, pharmacological inhibition or shRNA-mediated silencing of KIAA1363 expression in cultured murine and human HSCs attenuated RE degradation. Together, our data suggest that KIAA1363 affects vitamin A metabolism of HSCs by hydrolyzing REs at the endoplasmic reticulum, thereby counteracting retinol esterification and RE storage in lipid droplets.     

Organ slices for the evaluation of human drug toxicity

Human organ slices, an in vitro model representing the multicellular and functional features of in vivo tissue, is a promising model for characterizing mechanisms of drug-induced organ injury and for identifying biomarkers of organ injury. Target organ injury is a significant clinical issue. In vitro models, which compare human and animal tissue to improve the extrapolation of animal in vivo studies for predicting human outcome, will contribute to improving drug candidate selection and to defining species susceptibilities in drug discovery and development programs. A critical aspect to the performance and outcome of human organ slice studies is the use of high quality tissue, and the use of culture conditions that support optimum organ slice survivability, in order to accurately reproduce mechanisms of organ injury in vitro. The attribute of organ slices possessing various cell types and interactions contributes to the overall biotransformation, inflammatory response and assessment of injury. Regional differences and changes in morphology can be readily evaluated by histology and special stains, similar to tissue obtained from in vivo studies. The liver is the major organ of which slice studies have been performed, however the utility of extra-hepatic derived slices, as well as co-cultures is increasing. Recent application of integrating gene expression, with human organ slice function and morphology demonstrate the increased potential of this model for defining the molecular and biochemical pathways leading to drug-induced tissue changes. By gaining a more detailed understanding of the mechanisms of drug-induced organ injury, and by correlating clinical measurements with drug-induced effects in the in vitro models, the vision of human in vitro models to identify more sensitive and discriminating markers of organ damage is attainable.     

Characterization of the simultaneous binding of Escherichia coli endotoxin to Kupffer and endothelial liver cells by flow cytometry.

BACKGROUND: The triggering of cellular responses during endotoxic shock is initiated for the binding of endotoxin (lipopolysaccharide; LPS) to the cell surface. Kupffer and endothelial liver cells, involved in the removal of endotoxin from blood circulation, show in vitro a rapid response to LPS in the absence of serum. METHODS: A double-labeling fluorescent assay was designed to evaluate the binding properties of Escherichia coli O111:B4 LPS to individual endothelial and Kupffer cells in suspension, where both populations occurred in the same relative proportion as in liver. After immunolabeling of the Kupffer cell population with the monoclonal antibody ED1 conjugated to R. phycoerythrin, the binding characteristics of LPS labeled with fluorescein to both endothelial and Kupffer cells were simultaneously studied by flow cytometry in serum-free conditions. RESULTS: Specific and saturable binding of endotoxin was observed with both populations, showing properties of a receptor-mediated process. The Kupffer cell population showed a faster capacity and a higher affinity for LPS binding. The Hill coefficients indicated positive cooperativity in the LPS interaction with both populations. CONCLUSIONS: Specific endotoxin binding to liver sinusoidal cells occurs in a serum-independent manner, particularly at high LPS concentrations. Flow cytometry is a fast, precise, and efficient technique to evaluate the simultaneous interaction of a ligand with two different cell types.     

Shiga toxin-2 enhances heat-shock-induced apoptotic cell death in cultured and primary glial cells

The blood–brain barrier (BBB) selectively controls the homeostasis of the central nervous system (CNS) environment using specific structural and biochemical features of the endothelial cells, pericytes, and glial limitans. Glial cells, which represent the cellular components of the mature BBB, are the most numerous cells in the brain and are indispensable for neuronal functioning. We investigated the effects of Shiga toxin on glial cells in vitro. Shiga toxin failed to inhibit cell proliferation but attenuated expression of heat shock protein 70, which is one of the chaperone proteins, in cultured and primary glial cells. Furthermore, the combination of Shiga toxin and a heat shock procedure induced cell apoptosis and decreased cell proliferation in both cells. Thus, we speculate that glial cell death in response to the combination of Shiga toxin and heat shock might weaken the BBB and induce central nervous system complications.     

New insights into the mode of action of the actin ADP-ribosylating virulence factors Salmonella enterica SpvB and Clostridium botulinum C2 toxin

The C2 toxin from Clostridium botulinum represents the prototype of the family of binary actin-ADP-ribosylating toxins. These toxins covalently transfer ADP-ribose from nicotinamide adenine dinucleotide (NAD(+)) onto arginine-177 of actin in the cytosol of eukaryotic cells resulting in depolymerization of actin filaments and cell rounding. The C2 toxin consists of two non-linked proteins, the enzyme component C2I and the binding and translocation component C2II, which delivers C2I into host cells. The ADP-ribosyltransferase SpvB from Salmonella enterica also modifies actin, but is delivered into the host cell cytosol from intracellular growing Salmonella, most likely via type-III-secretion. We characterized the mode of action of SpvB in comparison to C2 toxin in vitro and in intact cells. We identified arginine-177 as the target for SpvB-catalyzed mono-ADP-ribosylation of actin. To compare the cellular responses following modification of actin by SpvB or by the binary toxins without the influence of other Salmonella virulence factors, we constructed a cell-permeable fusion toxin to deliver the catalytic domain of SpvB (C/SpvB) into the cytosol of target cells. This review summarizes recent findings of research on the actin ADP-ribosylating toxins regarding their cellular uptake, molecular mode of action and the cellular consequences following ADP-ribosylation of actin.     

Influence of endotoxin on experimental post-alcoholic liver injury.

The morphological and biochemical changes of the liver after endotoxin intake were analyzed in rats receiving 20% ethanol during 60 days. Besides morphological changes, concentration of serotonin and histamine in liver homogenates, the activity of asparagine and alanine aminotransferases (AspAT, ALAT), gamma-glutamyltranspeptidase (GGTP) and alcohol dehydrogenase (ADH) in blood serum were determined, too. The most extensive morphologic changes of the liver were seen in group of animals intoxicated with 20% ethanol during 60 days and single dose of endotoxin E. coli 0127:B8 intraperitoneally. These changes included necrosis most hepatocytes, focal steatosis of liver parenchyma, considerable hyperemia and parenchymatous degeneration of the liver cells. The cells lining liver sinuses showed considerable swelling as well as necrotic changes. Figures of cell division and haemorrhagic focuses were seen, too. The clusters of mononuclear cells, surrounding necrotically changed hepatocytes were seen in the central part of the liver lobule. Among the inflammatory mediators estimated in liver homogenate only serotonin reached a high level in the group of experimental animals receiving only endotoxin. Increased activity of aminotransferases AspAt and ALAT were associated with these morphologic and biochemical changes in liver tissue observed in animals receiving ethanol and endotoxin.