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Murine Hepatocytes (murine + hepatocyte)

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Medical Sciences100%

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Manganese cell labeling of murine hepatocytes using manganese(III)-transferrin,

CONTRAST MEDIA & MOLECULAR IMAGING, Issue 3 2008
Christopher H. Sotak
Abstract Manganese(III)-transferrin [Mn(III),Tf] was investigated as a way to accomplish manganese-labeling of murine hepatocytes for MRI contrast. It is postulated that Mn(III),Tf can exploit the same transferrin-receptor-dependent and -independent metabolic pathways used by hepatocytes to transport the iron analog Fe(III),Tf. More specifically, it was investigated whether manganese delivered by transferrin could give MRI contrast in hepatocytes. Comparison of the T1 and T2 relaxation times of Mn(III),Tf and Fe(III),Tf over the same concentration range showed that the r1 relaxivities of the two metalloproteins are the same in vitro, with little contribution from paramagnetic enhancement. The degree of manganese cell labeling following incubation for 2,7,h in 31.5,µm Mn(III),Tf was comparable to that of hepatocytes incubated in 500,µm Mn2+ for 1,h. The intrinsic manganese tissue relaxivity between Mn(III),Tf-labeled and Mn2+ -labeled cells was found to be the same, consistent with Mn(III) being released from transferrin and reduced to Mn2+. For both treatment regimens, manganese uptake by hepatocytes appeared to saturate in the first 1,2,h of the incubation period and may explain why the efficiency of hepatocyte cell labeling by the two methods appeared to be comparable in spite of the ,16-fold difference in effective manganese concentration. Hepatocytes continuously released manganese, as detected by MRI, and this was the same for both Mn2+ - and Mn(III),Tf-labeled cells. Manganese release may be the result of normal hepatocyte function, much in the same way that hepatocytes excrete manganese into the bile in vivo. This approach exploits a biological process,namely receptor binding, endocytosis and endosomal acidification,to initiate the release of an MRI contrast agent, potentially conferring more specificity to the labeling process. The ubiquitous expression of transferrin receptors by eukaryotic cells should make Mn(III),Tf particularly useful for manganese labeling of a wide variety of cells both in culture and in vivo. Published in 2008 by John Wiley & Sons, Ltd. [source]

Expression of a cyclin E1 isoform in mice is correlated with the quiescent cell cycle status of hepatocytes in vivo,

HEPATOLOGY, Issue 1 2006
Nils-Holger Zschemisch
Cyclin E1 controls G1/S phase transition of the eukaryotic cell cycle. We report the impact of alternative spliced cyclin E1 isoforms on cell cycle regulation in hepatocytes. We show that expression of new cyclin E1 mRNA variants IN3, ,4, and ,5 is associated with retarded proliferation in murine hepatocellular carcinoma. Additionally, we demonstrate that a new cyclin E1 isoform ,3/8 lacking the central part of wild-type mRNA is expressed predominantly in nonproliferating murine hepatocytes. Following partial hepatectomy, ,3/8 is downregulated when hepatocytes enter the cell cycle from quiescence. The ,3/8 protein does not exhibit any cyclin box motif but binds cyclin-dependent kinase 2 without stimulating kinase activity. We demonstrate that ,3/8 lacks any nuclear localization signal and is exclusively located in the cytoplasm. Overexpression of ,3/8 in cultured cells leads to a delayed G0-G1 transition, indicating that this splice variant helps to maintain a quiescent state of hepatocytes. In conclusion, we identified an isoform of cyclin E1 involved in G0 maintenance and suggest an additional mechanism for cell cycle control. (HEPATOLOGY 2006;44:164,173.) [source]

Bid-dependent generation of oxygen radicals promotes death receptor activation,induced apoptosis in murine hepatocytes

HEPATOLOGY, Issue 2 2004
Wen-Xing Ding
Activation of tumor necrosis factor receptor 1 or Fas leads to the generation of reactive oxygen species, which are important to the cytotoxic effects of tumor necrosis factor , (TNF-,) or Fas ligand. However, how these radicals are generated following receptor ligation is not clear. Using primary hepatocytes, we found that TNF-, or anti,Fas antibody,induced burst of oxygen radicals was mainly derived from the mitochondria. We discovered that Bid,a pro-death Bcl-2 family protein activated by ligated death receptors,was the main intracellular molecule signaling the generation of the radicals by targeting to the mitochondria and that the majority of oxygen radical production was dependent on Bid. Reactive oxygen species contributed to cell death and caspase activation by promoting FLICE-inhibitory protein degradation and mitochondrial release of cytochrome c. For the latter part, the oxygen radicals did not affect Bak oligomerization but instead promoted mitochondrial cristae reorganization and membrane lipid peroxidation. Antioxidants could reverse these changes and therefore protect against TNF-, or anti,Fas-induced apoptosis. In conclusion, our studies established the signaling pathway from death receptor engagement to oxygen radical generation and determined the mechanism by which reactive oxygen species contributed to hepatocyte apoptosis following death receptor activation. (HEPATOLOGY 2004;40:403,413.) [source]

Mechanisms for sensitization to TNF-induced apoptosis by acute glutathione depletion in murine hepatocytes

HEPATOLOGY, Issue 6 2003
Katsuhiko Matsumaru
We previously reported that depletion of glutathione in murine hepatocytes by diethylmaleate (DEM) or acetaminophen (APAP) leads to oxidative stress,dependent necrosis and sensitizes to tumor necrosis factor (TNF)-induced apoptosis in an oxidative stress,independent fashion, which could not be explained by interference with nuclear factor ,B (NF-,B) nuclear translocation. The present report explores the mechanisms of these effects. We observed that DEM led to necrosis when both mitochondrial and cytosol glutathione were depleted profoundly but sensitized to TNF-induced apoptosis when cytosol glutathione was depleted selectively. DEM and APAP lead to a significant decrease in reduced glutathione (GSH)/glutathione disulfide (GSSG) ratio. Glutathione depletion by DEM or APAP was associated with inhibition of TNF-induced NF-,B transactivation of anti-apoptotic genes, including inducible nitric oxide synthase (i-NOS). Provision of exogenous NO partially abrogated the sensitization to TNF in response to glutathione depletion. Glutathione depletion alone led to sustained increase in phospho-jun levels and c-Jun-N-terminal kinase (JNK) activity. JNK inhibitor partially blocked the sensitization to TNF-induced apoptosis accompanying glutathione depletion. In conclusion, these findings suggest that extramitochondrial glutathione depletion alters the thiol-disulfide redox state, leading to inhibition of NF-,B transactivation of survival genes and to sustained activation of JNK, both of which contribute to the sensitization to TNF-induced apoptosis. [source]