d-glucose uptake in human liver cell cultures

Summary The kinetic parameters ford-glucose uptake were studied in human liver cell cultures under strictly defined experimental conditions. Using a wide concentration range (0.005 to 30 mmol/l), the kinetic data obtained suggested strongly thatd-glucose in human liver cell cultures can be transported by two separate systems. For the high-affinity system, the apparentK _m was 0.645±0.21 mmol/l and the V_max, 12.49±3.74 nmol/mg protein per min. For the low-affinity system, the apparentK _m was 6.91±0.58 mmol/l and the V_max, 79.90±5.27 nmol/mg protein per min. At a concentration of 2.1×10⁻⁷ mol/l, cytochalasin B preferentially inhibited the high-affinityd-glucose site or transport system. The time course ofd-glucose uptake, studied in two cell lines from patients with hereditary fructose intolerance, was significantly higher than for the control lines. This work was supported by Grant I.N.S.E.R.M. CRL 77-5-210-4.     

SEPTUM FORMATION IN THE DESMID XANTHIDIUM (CHLOROPHYTA): EFFECTS OF CYTOCHALASIN D AND LATRUNCULIN B SUGGEST THE INVOLVEMENT OF ACTIN MICROFILAMENTS

Septum formation and mitosis were investigated by light and electron microscopical techniques as well as through the completion of inhibitor experiments in the unicellular desmid Xanthidium armatum (Bréb.) Rabenh. In untreated cells, numerous endoplasmic reticulum (ER) cisternae permeated the mitotic apparatus and secretory vesicles, and ER formed a band in front of the linearly growing septum, indicating the predetermined direction of septum growth. Under the influence of cytochalasin D (CD), the vesicle/ER band lost its proper orientation, which led to a malformed septum wall; moreover, abnormal septum branches could potentially have developed. Whereas the septum of an untreated cell only grew at its edge, the CD-induced branches (also with a vesicle/ER band in front) represented additional growing zones. These observations indicated that actin filaments were involved in establishing, maintaining, and orienting the "preforming" vesicle/ER band and, thus, the later septum. Latrunculin B (LB) had more severe effects on septum formation than did CD. Only small accumulations of septum material were found at the septum edge, and no aberrant growth of the septum occurred in LB-treated as in CD-treated cells. This could be explained by the more rapid disturbance of all actin-driven processes after LB treatment, which was assumed, because even low concentrations of the drug rapidly inhibited cytoplasmic streaming.     

Effect of cytochalasin B on glucose uptake, utilization, oxidation and insulinotropic action in tumoral insulin-producing cells

Cytochalasin B (17-3 microM) virtually abolished 3-O-methyl-D-[U-14C]glucose uptake and D-[5-3H]glucose utilization in tumoral insulin-producing cells of the RINm5F line. This coincided with a marked decrease in D-[U-14C]glucose oxidation and suppression of the stimulant action of D-glucose upon insulin release. Cytochalasin B, however, augmented basal insulin release by the tumoral cells. The RINm5F cells appeared much more sensitive than normal islet cells to cytochalasin B, as judged by the relative magnitude of inhibition in either hexose uptake or utilization. In both cell types, the inhibitory action of cytochalasin B upon glucose metabolism seemed to be competitive, being more marked at low than high glucose concentration. These results are interpreted in support of the view that a decreased efficiency of hexose transport across the plasma membrane represents an essential deficiency of the RINm5F cells.     

Schistosoma mansoni egg-induced hepatic granulomas in mice deficient for the interferon-gamma receptor have altered populations of macrophages, lymphocytes and connective tissue cells

Systemic production and mobilization of inflammatory cells and formation of hepatic periovular granulomas were studied in Schistosoma mansoni-infected mice with deficient interferon gamma (IFN-gamma) receptor (IFN-gammaR(o/o)). The impaired IFN-gamma signaling did not cause a significant modification of the overall kinetics of inflammatory cells, but mutant mice developed smaller hepatic periovular granulomas with a two-fold reduction in all the cell lineages. In granulomas of normal mice, the fully differentiated macrophages were progressively predominant, whilst in IFN-gammaR(o/o) mice, the granulomas contained a higher percentage of immature and proliferating monocytes. Granulomas of IFN-gammaR(o/o) mice had an enhanced and accelerated fibrotic reaction, corresponding to an increased content of proliferative and activated connective tissue cells. Simultaneously, their granulomas had an increased ratio of T over B cells, with an increase in CD8(+) and a reduction in CD4(+) T cells. The functional IFN-gamma receptor was not required for initial recruitment of monocytes and lymphocytes into granulomas, but it was necessary for the maturation of macrophages, upregulation of major histocompatibility class 2 (MHC-II) expression and consequent stimulation of lymphocyte subpopulations depending upon the MHC-II-mediated antigen presentation.     

Binding of cytochalasin B to platelets

The binding of cytochalasin B (CB) to human platelets and to isolated platelet cytosol and membranes has been analyzed with [3H]CB. High- and low affinity classes of saturable binding sites were associated with intact platelets. Binding at very low concentrations of CB (i.e., high-affinity binding) was partially prevented by 100 mM D-galactose or D-glucose and to a much lesser extent by L-glucose. Binding to platelet cytosol also involved two classes of sites with affinities and capacities similar to those observed with the whole cells. None of this binding, however, was affected by 100 mM D-galactose. Saturable binding to platelet membranes occurred at sites with a uniform binding affinity. Approximately 52% of this binding was prevented by 1 M D-galactose and another 15% by cytochalasin E (CE). We hypothesize that binding in the cytosol is to monomeric (low-affinity) and polymerized (high-affinity) actin, whereas membrane binding (high-affinity only) occurs primarily at sites involved with galactose transport.     

The role of the innate immune system of the liver in the control of HBV and HCV

Hepatitis B virus (HBV) and Hepatitis C virus (HCV) infection are among the most frequent causes of chronic liver disease worldwide. As recent studies suggested that Toll like receptor (TLR)-based therapies may represent a promising approach in the treatment of HBV infection, we have studied the role of the local innate immune system of the liver as possible mediator of this effect. Murine non-parenchymal liver cells (NPC; Kupffer cells, KC; sinusoidal endothelial cells, LSEC) were isolated from C57/BL6 and stimulated by TLR 1-9 agonists. Supernatants were harvested and assayed for their antiviral activity against HBV in HBV-Met cells and HCV in the murine HCV replicon cell line MH1. Only supernatants from TLR 3 and -4 stimulated KC and TLR 3 stimulated LSEC were able to potently suppress HBV and HCV replication. By using neutralizing antibodies we could demonstrate that the TLR 3- but not the TLR 4 mediated effect is exclusively mediated through IFN-β. Our data indicate that TLR 3 and -4 mediated stimulation of NPC leads to production of IFN-β which can potently suppress HBV and HCV replication. This is of relevance for the local control of viral hepatitis infection by the innate immune system of the liver, the development of novel TLR-based therapeutic approaches and sheds new light on the viral crosstalk between HCV (TLR 3 stimulator) and HBV.     

Non-parenchymal cells as mediators of physiological responses in liver

Parenchymal cells (hepatocytes) are the sites at which the principal metabolic functions of the liver are located. In the perfused liver, responses (e.g. vasoconstriction and glycogenolysis) to stimulating agents such as zymosan, platelet-activating factor and arachidonic acid, are inhibited by indomethacin and bromophenacyl bromide, inhibitors of cyclo-oxygenase and phospholipase A₂, respectively. Since cultured Kupffer and endothelial cells but not hepatocytes, produce eicosanoids, and since eicosanoids and especially prostaglandins induce similar patterns of responses when added directly to the perfused liver, an involvement of these nonparenchymal cells in mediating the above responses is considered likely. We propose that in most situations the responses induced by these stimulating agents are mediated through a combination of pathways that include interaction of the agents directly with hepatocytes or with vasoactive cells (endothelial and/or smooth muscle cells), or interaction of agents initially with non-parenchymal cells to produce and release eicosanoids, which then subsequently interact with hepatocytes or with vasoactive cells.     

The effect of cytochalasin B on chondrogenesis in chick limb-bud mesoderm cells grown in vitro

Summary Cytochalasin B (CB) has been shown to have many biological effects on cultured cells. We report that an initial 48-hr treatment of freshly plated chick embryo limb mesoderm cells with CB irreversibly inhibits chondrogenesis. A slight inhibition in the amount of matrix is seen when limb cells are allowed to grow in culture for 24 hr prior to treatment for the second 24 hr of culture. If the cells are allowed to plate-out and grow for 48 hr or longer prior to being treated with CB for 24 hr, the amount of matrix produced is essentially the same as that seen in the controls. However, if the initial 48-hr culture period is followed by a 48- or 72-hr treatment, chondrogenesis is reduced, but not to the same extent as that seen in cultures treated for the first 48 or 72 hr. The irreversible inhibition of chrondrogenesis does not appear to be due to irreversible inhibition of protein synthesis or hexose uptake because, although these are reduced during treatment, they return to control levels within 48 hr following the removal of the drug. We cannot mimic the effect of CB treatment using glucose-deficient medium, thereby eliminating the possiblity that a critical glucose level is necessary to permit chondrogenesis. Multinucleation of limb cells treated with CB is reversed within 4 to 7 days following the removal of the drug. Therefore multinucleation alone is probably not responsible for the CB effect on chondrogenesis. However, other subtle permanent changes may occur during the period of multinucleation which result in the irreversible inhibition of chondrogenesis. This work was supported in part by a grant to R. A. F. from the North Carolina United Way and a grant to C. L. P. from the General Research Support Grant RR-5404 from the National Institutes of Health. A portion of these results were presented at the 28th Annual Meeting of the Tissue Culture Association, New Orleans, Louisiana, 1977.     

Retention of insulin-stimulated D-glucose transport activity by adipocyte plasma membranes following extraction of extrinsic proteins

Plasma membrane vesicles prepared from adipocytes incubated with insulin exhibited accelerated D-glucose transport activity characteristic of insulin action on intact fat cells. Both control and insulin-stimulated D-glucose transport activities were inhibited by cytochalasin B and thiol reagents. Extraction of plasma membranes with dimethylmaleic anhydride eluted 80% of the protein from plasma membrane vesicles. The two major glycoprotein bands (94,000 and 78,000 daltons) and small amounts of a 56,000-dalton band were retained in dodecyl sulfate gels of the extracted membranes. Both control and insulin-activated D-glucose transport activities were retained by plasma membrane vesicles extracted with dimethylmaleic anhydride. Cytochalasin B binding activity was also retained by extracted membrane vescles and D-glucose uptake into extracted vescles derived from untreated or insulin-treated fat cells was inhibited by cytochalasin B. These results suggest that the modification of the adipocyte hexose transport system elicited by insulin action is not altered by a major purification step which involves quantitative extraction of extrinsic membrane proteins.     

Superoxide Generation by Kupffer Cells and Priming of Neutrophils During Reperfusion After Hepatic Ischemia

The objective of this study was to identify the cellular source of the vascular oxidant stress in hepatic ischemia-reperfusion injury in male Fischer rats. Nonparenchymal cells (Kupffer cells, endothelial cells) and neutrophils were isolated from postischemic liver lobes by collagenase-pronase digestion followed by centrifugal elutriation. The spontaneous and stimulated generation of superoxide by these cells were subsequently quantified in vitro. Large Kupffer cells from the postischemic lobes spontaneously generated 300% more superoxide than similar cells from control animals. No difference in spontaneous superoxide formation was found when the small Kupffer cells were compared. No other cells isolated from the postischemic lobes or control liver including neutrophils released any detectable superoxide spontaneously. In contrast, small Kupffer cells and neutrophils from the postischemic liver generated significantly more superoxide after stimulation with phorbol ester or opsonized zymosan than the controls. The considerably higher response with zymosan stimulation compared to phorbol ester indicates a particular priming for a receptor-mediated signal transduction pathway during reperfusion. These studies demonstrate that Kupffer cells are the principal source of the oxidant stress during the initial reperfusion phase after hepatic ischcmia. The priming of neutrophils during this time may be an important factor for the later neutrophil-induced injury phase.