Differential alterations in metabolic pattern of the six major UsnRNAs during development

The uridylic acid rich nuclear RNAs (U1-U6 snRNAs) are involved mainly in the processing of pre-mRNA and pre-rRNA. So, any control of cell growth through pre-mRNA/pre-rRNA processing may have some regulation through altered UsnRNAs metabolism. With this idea, attempts have been made to see how the metabolism of the six major UsnRNAs' changed during the normal process of cellular proliferation associated with differentiation from pluripotent/totipotent stem cells of early embryonic stage to much more differentiated state of different cell/tissue lineages in different tissues/organs during the fetal and neonatal stages of growth. It has been seen that the levels of the six major UsnRNAs were high in day 8 embryo when the cells were mainly pluripotent/totipotent in nature, and during the progression of embryonic development the levels of these UsnRNAs gradually decreased (35-65%) up to the midgestational period (day 13) with some exception, when the organogenesis has already been started. However in the fetal life, the levels of these UsnRNAs were maximum or comparable around 18 ± 2 days of gestation in comparison to that in day 8 embryo when the kinetics of the maturational status of the different organs were quite high. But, the levels of these UsnRNAs' became low during day 21 of fetal life or in day 0 of birth (perturation period) in all the tissues/organs except high UsnRNAs' level in spleen. In the neonatal life, around 3 ± 1 days of birth these UsnRNAs' levels again became maximum in all the tissues/organs (except in thymus) followed by decrease up to 5/6 days, and to become steady with slight increase within one to two weeks, when the kinetics of the organ maturation reached to a steady state. In case of thymus, the levels of the U3-U6 snRNAs were high on day 0 of birth followed by decrease in their level on day 1/2 and then increased to become steady within 2-4 weeks; whereas the U1 and U2 snRNAs' levels were high on day 3 of birth and the subsequent changes were similar to that in other tissues/organs.Thus the different UsnRNAs' metabolism in the perturation period and in the early stages of neonatal life has indicated the differential cellular functions in these two stages of development. These alterations in the metabolism of these UsnRNAs might be due to the differential changes in the rate of synthesis of these UsnRNAs and/or with their differential turnover rate in the different stages of development. Also, the differential variations of these UsnRNAs' levels have been observed among the different tissues/organs at the respective stages of development indicating the differences in the UsnRNAs' metabolism among the different cell/tissue lineages. Thus, it can be concluded that the metabolism of these UsnRNAs were developmentally regulated with some cell/tissue lineage variations, which might have some role in the developmentally regulated cellular process of proliferation and differentiation, through altered RNA splicing and processing.     

Redistribution and fate of colchicine-induced alkaline phosphatase in rat hepatocytes: possible formation of autophagosomes whose membrane is derived from excess plasma membrane

The redistribution and fate of colchicine-induced alkaline phosphatase (ALPase) in rat hepatocytes were investigated by electron microscopic enzyme cytochemistry and biochemistry. ALPase activity markedly increased in rat hepatocytes after colchicine treatment (2.0 mg/kg body weight, intraperitoneal injection). At 20–24 h after colchicine treatment, the liver showed the highest activity of ALPase. Thereafter, ALPase activity decreased and returned to normal levels at 48 h. In normal hepatocytes from control rats, ALPase activity was seen only on the bile canalicular membrane. However, at 20–24 h after colchicine treatment, colchicine-induced ALPase was redistributed in the sinusoidal and lateral (basolateral) membranes as well as in the bile canalicular membrane. At 30–36 h after colchicine treatment, ALPase activity on the basolateral membrane gradually decreased. In contrast, ALPase in the bile canalicular membrane increased along with the enlargement of bile canaliculi, suggesting that ALPase in the basolateral membrane had been transported to the bile canalicular membrane. Furthermore, ALPase-positive vesicles, cisternae and autophagosome-like structures were frequently seen in the cytoplasm. ALPase was also positive in some lysosomal membranes. ALPase in hepatocytes at 48 h after colchicine treatment returned to almost the same location as in control hepatocytes. Altogether, it is suggested that excessively induced ALPase is at least partially retrieved by invagination of the bile canalicular membrane and then transported to lysosomes for degradation. In addition, this study indicates that excess plasma membrane might be a possible origin of autophagosomal membrane.     

Differential Alterations in Metabolic Pattern of the Spliceosomal UsnRNAs during Pre-Malignant Lung Lesions Induced by Benzo(a)pyrene: Modulation by Tea Polyphenols

The differential alterations of the spliceosomal UsnRNAs (U1, U2, U4, U5, and U6) were reported to be associated with cellular proliferation and development. The attempt was made in this study to analyze the metabolic pattern of the spliceosomal UsnRNAs during the development of pre-malignant lung lesions induced in experimental mice model system by benzo(a)pyrene (BP) and also to see how tea polyphenols, epigallocatechin gallate (EGCG) and epicatechin gallate (ECG), modulate the metabolism of these UsnRNAs during the lung carcinogenesis. No significant changes in the level of the UsnRNAs were seen in the inflammatory lung lesions at 9th week due to treatment of BP. However, there was significant increase in the level of U1 (∼2.5 fold) and U5 (∼47%) in the hyperplastic lung lesions at 17th week. But in the mild dysplastic lung lesions at 26th week, the level of UsnRNAs did not change significantly. Whereas, in the dysplastic lung lesions at 36th week there was significant increase in the level of the U2 (∼2 fold), U4 (∼2.5 fold) and U5 (∼2 fold). Due to the EGCG and ECG treatment the lung lesions at 9th week appeared normal and in the 17th, 26th, and 36th week it appeared as hyperplasia. The level of the UsnRNAs was significantly low in the lung lesions at 9th week (only U2 and U4 by EGCG), at 17th week (only U1 by EGCG/ECG), at 26th week (U1 by ECG; U2, U4 and U5 by EGCG/ECG) and at 36th week (U1 by ECG, U2 and U4 by EGCG/ECG). Whereas, there was significant increase in the level of U5 (by EGCG/ECG) and U6 (by EGCG only) in the lung lesions at 36th and 26th week respectively. This indicates that the metabolism of the spliceosomal UsnRNAs differentially altered during the development of pre-malignant lung lesions by BP as well as during the modulation of the lung lesions by the tea polyphenols.     

Transforming growth factor beta inhibits DNA synthesis in hepatocytes isolated from normal and regenerating rat liver

The inhibitory action of transforming growth factor beta (TGF beta) on DNA synthesis in hepatocytes isolated from the liver of normal rats or from the liver remnant of rats 18 h following partial hepatectomy was compared. Continuous exposure to TGF beta inhibited DNA synthesis of cultured hepatocytes to a similar degree in both groups when labelled with 3H thymidine from 24-48 h or 48-72 h. At 20 pM TGF beta, 3H-thymidine incorporation was reduced by 64-78% in hepatocytes from normal liver and by 60-73% in cells from 18 h regenerating liver. The nuclear labelling index was reduced by 70-80% in all cells. Exposure to TGF beta at concentrations up to 500 pM from 0-24 h had no effect on 3H-thymidine incorporation, but exposure at 20 pM for 24 h periods thereafter was uniformally effective. These results indicate that there is no change in sensitivity of hepatocytes from 18 h regenerating liver to TGF beta, compared with normal cells, and that TGF beta may act at some point in the G1 phase of the cell cycle to inhibit hepatocyte growth.     

Telocytes in liver regeneration: possible roles

Telocytes (TCs) are a novel type of interstitial cells which are potentially involved in tissue regeneration and repair ( www.telocytes.com ). Previously, we documented the presence of TCs in liver. However, the possible roles of TCs in liver regeneration remain unknown. In this study, a murine model of partial hepatectomy (PH) was used to induce liver regeneration. The number of TCs detected by double labelling immunofluorescence methods (CD34/PDGFR‐α, CD34/PDGFR‐ß and CD34/Vimentin) was significantly increased when a high level of hepatic cell proliferation rate (almost doubled) as shown by 5‐ethynyl‐2′‐deoxyuridine (EdU) immunostaining and Western Blot of Proliferating cell nuclear antigen (PCNA) was found at 48 and 72 hrs post‐PH. Meanwhile, the number of CK‐19 positive‐hepatic stem cells peaked at 72 hrs post‐PH, co‐ordinating with the same time‐point, when the number of TCs was most significantly increased. Taken together, the results indicate a close relationship between TCs and the cells essentially involved in liver regeneration: hepatocytes and stem cells. It remains to be determined how TCs affect hepatocytes proliferation and/or hepatic stem cell differentiation in liver regeneration. Besides intercellular junctions, we may speculate a paracrine effect via ectovesicles.     

Impaired hepatic regeneration in metallothionein-I/II knockout mice after partial hepatectomy

Although the translocation of metallothionein (MT) from cytoplasm to nucleus has been demonstrated in liver during times of high requirement for zinc (fetal development and the neonatal period), the role of MT in cellular growth is not well understood. In this study, a potential role of MT in liver regeneration was investigated in wild type (WT) and MT-I and MT-II gene knockout (MT-null) mice after 35% partial hepatectomy (PH) or sham laparotomy. Hepatic MT levels and proliferation index were measured at 0, 5, 15, 24, 36, 48, and 60 hrs after PH and 48 hrs after sham laparotomy (control). MT levels were increased in WT mice (peak at 24 hrs after PH) and declined to normal levels by 60 hrs after PH. Immunohistochemical staining for MT in WT mice indicated the presence of MT in both nucleus and cytoplasm of hepatocytes at 24 hrs after PH, whereas MT was present mainly in the cytoplasm at 36-60 hrs after PH and 48 hrs after sham laparotomy. Hepatic proliferation index in both WT and MT-null mice, as determined by argyrophilic nucleolar organizing region staining and proliferating cell nuclear antigen immunohistochemical staining, reached a peak at 48 hrs and declined by 60 hrs after PH. Cell proliferation was significantly less in MT-null mice as compared to WT mice during liver regeneration after PH. These results suggest that MT may play a positive role in hepatic regeneration after PH.     

Cell proliferation in skeletal muscle following denervation or tenotomy

Summary Autoradiographic experiments using ³H-thymidine were designed to analyse cell proliferation which occurs in skeletal muscle after denervation and after tenotomy. In mouse tibialis anterior and tongue muscles during the first 24 h after denervation or tenotomy labelling levels were low and did not differ significantly from sham operated control muscles. By 48 h after denervation and tenotomy of tibialis anterior muscles, increased levels of labelling occurred in both muscle and connective tissue nuclei. Daily pulse labelling for 7 days after denervation produced a labelling level which was 8 times that of sham operated controls, 25–30% of the total nuclear population being labelled. Denervated muscles had twice the level of labelling compared to tenotomised muscles. These results provide conclusive evidence that both denervation and tenotomy stimulate cell proliferation in skeletal muscle and it is suggested that the increased numbers of labelled muscle nuclei are likely to be the result of mitotic activity in muscle satellite cells.     

Methylation of nicotinamide in rat liver cytosol and its correlation with hepatocellular proliferation

The changes in the activity of nicotinamide: S-adenosylmethionine methyltransferase (nicotinamide methylase) were studied in rat liver which was subjected to different rates of cellular proliferation. The cytosolic enzyme activity increased 3–4-fold in the first 24–48 h after partial hepatectomy and decreased again to the basal levels until 4 days post-operatively, whereas it remained unchanged in the livers of sham-operated animals. A single administration of thioacetamide at a dose of 50–250 mg/kg body weight, a treatment which induces hepatocellular proliferation as well, also enhanced the enzyme activity 2–3-fold 24 h after drug administration. This activity increase was associated with a marked lowering of intracellular NAD content of as much as 50% of the control levels. d-Galactosamine, a known hepatotoxic agent causing acute hepatitis in experimental animals and preventing DNA synthesis in regenerating liver, blocked the activity increase in regenerating rat liver. The rate of 1-methylnicotinamide synthesis, as measured by incubating liver slices in the culture medium supplemented with [¹⁴C]nicotinamide as a precursor, was found to be 2–4 times higher in the slices from regenerating liver and thioacetamide-treated rat liver than those from non-proliferating control liver. These results, together with our previous finding on the enhancement by 1-methylnicotinamide of the growth of cultured rat liver cells (Hoshino, J., Kühne, U. and Kröger, H. (1982) Biochem. Biophys. Res. Commun. 105, 1446–1452), support the view that nicotinamide methylase and its product, 1-methylnicotinamide, are involved in the control of hepatocellular DNA synthesis and proliferation.     

Effect of gamma irradiation on liver metallothionein synthesis and lipid peroxidation in rats.

Several studies have recently shown that metallothionein (MT), a protein characterized by a high thiol content and that binds Zn2+ and Cu+, might be involved in the protection against oxidative stress and can act as a free radical scavenger. Oxidative stresses, such as irradiation, increase lipid peroxidation (LP) and subsequent tissue damage through free radical production. The induction of hepatic MT synthesis by gamma-irradiation (20 Gy) at 8, 24, 30 and 48 hrs. post-irradiation in two different age groups of Sprague-Dawley rats (39-40 and 48-49 days old) was studied. LP measured by the thiobarbituric acid reactive substances (TBARS) assay and Cu and Zn levels in liver have also been determined. In the younger group, the gamma-irradiation induced hepatic MT synthesis and increased LP that peaked 24 hrs. after irradiation. During the first 30 hrs. post-irradiation, a positive and statistically significant correlation between hepatic MT content and LP level in liver was found. In the older group, liver MT synthesis was only increased 1.7-fold and LP levels were not altered at 24 hrs. post-irradiation compared with sham-irradiated rats.Therefore it appears that LP is not necessary for induction of MT synthesis by gamma-irradiation.     

Energy status of isolated hepatocytes after long-term cold storage in various types of media

Using of isolated hepatocytes for investigation of the effects of hypothermia, it has been demonstrated that sucrose-base solution provides of maintenance of the energetic parameters (level of ATP, glucose synthesis, rate of gluconeogenesis) within 48 hrs of storage at 4 degrees C. It efficiency was compared with effect on the energetic status of isolated hepatocytes widely used preservation solution--solution of University Wisconsin (UW). After long-term of cold storage of isolated hepatocytes (72 hrs) at 4 degrees C in both solutions, it has been shown sharp decrease of ATP level (on two time). Viability of the liver cells (in both cases) was practically without change.     

Recombination and hydroxyurea inhibition of DNA synthesis in yeast meiosis

Summary Hydroxyurea (HU) inhibits the premeiotic DNA replication and the meiotic events that follow, namely readiness, recombination commitment, haploidisation, sporulation commitment and ascus formation. Short incubations with HU (2–4 hrs) during the premeiotic replication (i.e. starting between 3 and 6.5 hrs in sporulation medium) allow the resumption of the replication at a normal rate following the removal of the drug. The other meiotic events are similarly delayed by the approximate length of the treatment. In these experiments, intragenic recombination in ade2 reached a higher level than in the controls (x1.3–2.0 in one pair of heteroalleles and x3.0–4.0 in another pair). The recombination response to short HU treatments was not observed for a pair of heteroalleles in ade2 that normally shows a high level of meiotic recombination (750 per 10⁶ cells), nor was the response observed in a pair of heteroalleles in lys2. HU treatments have almost no effect on sporulating cells from 8 hrs onwards. At 7–7.5 hrs the meiotic cells are very sensitive to the drug and even short treatments cause cell death and massive DNA degradation.     

Transport of pipecolic acid in adult and developing mouse brain

In an effort to develop an animal model of hyperpipecolatemia, the uptake of pipecolic acid (PA) in the brain and changes of PA levels in serum following administration ofd,l-PA were studied in the mouse using a new sensitive HPLC-EC method. Following i.p. injections (250 mg/kg) to adult male mice, the brain concentration peaks at 5–10 min (40 nmol/g). The level remains relatively stable up to 5 hrs and then declines slowly to 24 hrs. In serum, the level of PA increases rapidly to reach the maximum value at 10 min and then decreases rapidly in the first hour and continues to decline more slowly to 24 hrs. The net uptake of PA following administration of various amounts ofd,l-PA is saturable at low doses (3.9–15.6 mg/kg), and it increases linearly at higher doses in a dose-dependent manner up to the maximum dose (500 mg/kg) used in the present study. Kinetic analysis suggests the presence of two kinds of transport systems. These findings are in good agreement with the previous results usingd,l-[³H]PA in the mouse (7) andl-[¹⁴C]PA in the rat (13). There were no significant differences between uptake ofd-pipecolic acid andl-pipecolic acid (250 mg/kg, i. p., 10 min), suggesting the absence of stereospecificity for PA uptake in the mouse brain. Developmental changes in net brain uptake of PA following injections ofd,l-PA (250 mg/kg, s.c., 10 min) showed an age-dependent decrease which continues until adult levels are reached at four weeks after birth. The results suggest that the blood brain barrier (BBB) for PA is completed during the first month of life. Following administration ofd,l-PA (250 mg/kg, s.c.) to pregnant mice during the period 19–21 days of gestation, PA level increases in fetal brain to a maximum value at 2 hrs (420 nmol/g). This level is unchanged during 24 hrs. The maximum level of PA in fetal serum is reached at 30 min to 1 hr. The level gradually decreases after 1 hr over 24 hrs. These results indicate that PA taken up by the placenta and into the brain is transported from the fetal circulation. Our results also demonstrate that a higher amount of PA is taken up by the fetal than the adult brain. This finding is important in order to develop an animal model of hyperpipecolatemia in which high brain levels of PA should mimick those of human hyperpipecolatemic patients. Our results strongly support the hypothesis that high levels of PA present in brain during fetal life may exert a devastating effect on the development of the human CNS in hyperpipecolatemic children.     

The synthesis and turnover of 5'-nucleotidase in primary cultured hepatocytes

The synthesis and degradation of 5'-nucleotidase has been studied in rat hepatocytes. Primary cultures of rat hepatocytes were established with the cells showing evidence of polarity after 24-36 h in culture. After a 30 h lag period 5'-nucleotidase activity increased to a plateau level similar to the activity found in whole liver. The half life of the enzyme after reaching the plateau of activity was 22.8 h. Pulse-chase biosynthetic labelling studies of 5'-nucleotidase in the cultured hepatocytes using [35S]methionine showed that the 5'-nucleotidase monomer was synthesised as an Mr 67,000 form which was converted to the mature Mr 72,000 form. [35S]Methionine labelling studies in the presence of tunicamycin showed that the unglycosylated protein monomer was an Mr 57,000 form. The immature Mr 67,000 form of 5'-nucleotidase was sensitive to endoglycosidase H, whereas the mature form was sensitive only to endoglycosidase F. The data presented are consistent with 5'-nucleotidase in a polarised cell being synthesised and processed like other membrane glycoproteins, in contrast to earlier reports.     

The fate of carbon in pulse-labelled crops of barley and wheat

Wheat (cv. Gutha) and barley (cv. O'Connor) were grown as field crops on a shallow duplex soil (sand over clay) in Western Australia with their root systems contained within pvc columns. At four stages during growth, the shoots were pulse-labelled for 1.5h with¹⁴CO₂; immediately prior to labelling, the soil was isolated from the shoot atmosphere by pvc sheets. After labelling, the soil atmosphere was pumped through NaOH to trap respired CO₂ and after 2.5, 5, 7.5 and 24 h from the start of labelling, columns were destructively sampled to recover¹⁴C from the roots, soil and shoot.Both species showed similar patterns of¹⁴C distribution and changes in distribution through the growing season. During early tillering, 15–25% of the¹⁴C recovered after 24 h had been respired by the roots and rhizosphere, 17–27% was retained in the roots, 0.4–1.8% was recovered as water-soluble¹⁴C in the soil and the remainder (45–67%) was present in the shoot. These percentages changed during growth so that during grain filling only 2–3% of the¹⁴C recovered after 24 h was as respired CO₂, 2–6% was in the roots, 0.2% was in the soil and over 90% was in the shoot.The distribution of¹⁴C in components of the soil-plant system changed during the 24 h after labelling with the most rapid changes occurring generally during the first 7.5 h after labelling.Using growth measurements from adjacent plots, the amounts of C added to the soil were estimated for the whole season. Carbon input to the soil was about 48 gC m^–2 for wheat and 58 gC m^–2 for barley; the crops produced total shoot dry matter of 494 (wheat) and 735 g m^–2 (barley). Of the C input to the soil, 27.8% (wheat) and 40.3% (barley) was as respired C and only 3.3 (wheat) and 4.1% (barley) was collected as exudate (water-soluble material).     

SeO2 induces apoptosis with down-regulation of Bcl-2 and up-regulation of P53 expression in both immortal human hepatic cell line and hepatoma cell line

An immortal human hepatic cell line HL-7702 and human hepatoma cell line SMMC-7721 were treated with 3–30 μM SeO₂. SeO₂ at 30 μM markedly inhibited cell proliferation and viability, and prompted apoptosis of both normal hepatic and hepatoma cells after 48 h treatment. SeO₂ could also down-regulate the Bcl-2 level, greatly in HL-7702 and slightly in SMMC-7721 cells, but up-regulate wild type P53 level a little in HL-7702 and significantly in SMMC-7721 cells. The Bcl-2/P53 value was closely correlated with the apoptotic rate as well as SeO₂ concentrations.     

Effect of the activation of macrophages on the course of regeneration of rat liver following partial hepatectomy

Stimulation of the Kupffer cells with E. coli endotoxin (the purified lipopolysaccharide) or with prodigiosan (a polysaccharide from Serratia marcescens) 24 h before partial hepatectomy (resection of 65-70% of the liver) stimulated and intensified the onset of liver regenerative activity (evaluated from changes in liver DNA synthesis, the H5 labelling index and the mitotic activity of the hepatocytes). Liver DNA synthesis increased together with the dose of endotoxin (i.v., from 25 to 1000 micrograms/kg body weight). If E. coli endotoxin was injected during or 3 h after partial hepatectomy, partial inhibition of liver DNA synthesis was observed. In mice stimulated with zymosan (a polysaccharide isolated from yeast), administered 5 days before performing partial hepatectomy, proliferation of the hepatocytes (evaluated from changes in the 3H labelling index and in the mitotic activity of the hepatocytes) was evaluated. The results confirm that proliferation is correlated to the state of reactivity of the Kupffer cells.     

髓过氧化物酶与大剂量顺铂所致小鼠肝功能变化关系的探讨

目的利用大剂量顺铂（Cisplatin,DDP）诱发小鼠急性肾功能衰竭的动物模型,了解大剂量DDP在引起肾损伤的同时对小鼠肝的毒性作用,探讨髓过氧化物酶（Peroxidase,MPO）与DDP所致小鼠肝功能变化的关系。方法 C57BL/6小鼠50只,雌雄各半,依体重随机分为DDP用药组和生理盐水（NS）对照组。15 mg/kg DDP单次腹腔内注射,等量NS对照。分别取对照组小鼠和DDP用药后6、12、24和48 h小鼠各10只,称重后乙醚麻醉,内眦静脉取血检测肝、肾功能;剖腹取肝、称重、计算肝系数,并取少量肝组织行HE染色、形态学观察;检测血浆和肝组织匀浆中MPO活性,统计学分析。结果大剂量DDP用药后48 h,小鼠出现急性肾功能衰竭。DDP用药后6 h血清谷丙转氨酶（ALT）含量达（91.0±11.3）IU/L,与对照组比较差异有统计学意义（P〈0.05）,随后血清ALT含量持续维持在高水平。DDP用药后各组小鼠肝系数明显升高,光镜下见肝细胞广泛变性水肿,肝小叶中可见点状坏死及炎细胞浸润。DDP用药后6 h,小鼠肝组织匀浆MPO含量显著升高,达（1.54±0.45）U/g,与对照组（0.58±0.28）U/g差异有统计学意义（P〈0.01）,随后MPO含量降至正常水平;DDP用药后小鼠外周血MPO含量缓慢增高,用药后48 h达（12.78±2.78）U/L,与对照组（8.06±1.89）U/L比较差异有统计学意义（P〈0.05）。结论大剂量DDP在诱发小鼠急性肾功能衰竭的同时还可引起小鼠急性肝细胞的破坏,其发生可能与肝组织内白细胞的激活及MPO的释放有关。     

Spatiotemporal changes in Ha-ras p21 expression through the hepatocyte cell cycle during liver regeneration

The protein product of the ras oncogene, Ha-ras (p21), is thought to be an important regulator of cell growth. The cytoplasmic relocalization of p21 in the cell during the cell cycle suggests a transient signaling role for this protein in association with its signal transduction function. Because of the importance of this role we examined spatial patterns in vivo of p21 expression at the protein and mRNA levels in hepatocytes during compensatory growth in rat liver following partial hepatectomy. A low level of p21 was immunolocalized on the cytoplasmic membrane of nonregenerating hepatocytes. The level of hepatic p21 increased significantly and without spatial restriction within the liver from 36 to 60 hr after partial hepatectomy (PH). p21 was localized in the cytoplasm of dividing hepatocytes and on the hepatic cytoplasmic membrane. The elevated p21 level decreased and was found mainly on hepatocyte plasma membranes by 96 hr after PH. Immunogold electron microscopy showed p21 localized over mitochondrial membranes and nuclei in nondividing regenerating hepatocytes. Approximately 50% of nonregenerating hepatocytes show nuclear localization of p21. This percentage changes with time following PH. The decrease in nuclear localization was accompanied with an increase in the low number of hepatocytes which demonstrated cytoplasmic localization in nondividing hepatocytes in regenerating liver. Flow cytometric analysis revealed a significant increase of p21 at 36 hr after PH which was 12 hr after the initial induction of ras mRNA. ras mRNA level increased 1.5-fold at 24 hr after PH and a maximum twofold induction was observed at 48 hr. Cell-cycle analysis of regenerating hepatocytes indicated a synchronized first peak of cell division 36–40 hr after PH. Dual parameter flow cytometry revealed that the level of p21 in hepatocytes in S phase and G₂/M phase of the cell cycle was significantly higher than that in G₀/G₁ phase during regeneration. These findings suggest that p21 is important for the progression of regenerating hepatocytes to S phase and then to G₂/M phase.     

Dual role of chloroquine in liver ischemia reperfusion injury: reduction of liver damage in early phase,but aggravation in late phase

The anti-malaria drug chloroquine is well known as autophagy inhibitor. Chloroquine has also been used as anti-inflammatory drugs to treat inflammatory diseases. We hypothesized that chloroquine could have a dual effect in liver ischemia/reperfusion (I/R) injury: chloroquine on the one hand could protect the liver against I/R injury via inhibition of inflammatory response, but on the other hand could aggravate liver I/R injury through inhibition of autophagy. Rats (n=6 per group) were pre-treated with chloroquine (60 mg/kg, i.p.) 1 h before warm ischemia, and they were continuously subjected to a daily chloroquine injection for up to 2 days. Rats were killed 0.5, 6, 24 and 48 h after reperfusion. At the early phase (i.e., 0–6 h after reperfusion), chloroquine treatment ameliorated liver I/R injury, as indicated by lower serum aminotransferase levels, lower hepatic inflammatory cytokines and fewer histopathologic changes. In contrast, chloroquine worsened liver injury at the late phase of reperfusion (i.e., 24–48 h after reperfusion). The mechanism of protective action of chloroquine appeared to involve its ability to modulate mitogen-activated protein kinase activation, reduce high-mobility group box 1 release and inflammatory cytokines production, whereas chloroquine worsened liver injury via inhibition of autophagy and induction of hepatic apoptosis at the late phase. In conclusion, chloroquine prevents ischemic liver damage at the early phase, but aggravates liver damage at the late phase in liver I/R injury. This dual role of chloroquine should be considered when using chloroquine as an inhibitor of inflammation or autophagy in I/R injury.