Disruption of hepatic adipogenesis is associated with impaired liver regeneration in mice

The liver responds to injury with regulated tissue regeneration. During early regeneration, the liver accumulates fat. Neither the mechanisms responsible for nor the functional significance of this transient steatosis have been determined. In this study, we examined patterns of gene expression associated with hepatic fat accumulation in regenerating liver and tested the hypothesis that disruption of hepatic fat accumulation would be associated with impaired hepatic regeneration. First, microarray-based gene expression analysis revealed that several genes typically induced during adipocyte differentiation were specifically upregulated in the regenerating liver prior to peak hepatocellular fat accumulation. These observations suggest that hepatic fat accumulation is specifically regulated during liver regeneration. Next, 2 methods were employed to disrupt hepatocellular fat accumulation in the regenerating liver. Because exogenous leptin supplementation reverses hepatic steatosis in leptin-deficient mice, the effects of leptin supplementation on liver regeneration in wild-type mice were examined. The data showed that leptin supplementation resulted in suppression of hepatocellular fat accumulation and impairment of hepatocellular proliferation during liver regeneration. Second, because glucocorticoids regulate cellular fat accumulation during adipocyte differentiation, the effects of hepatocyte-specific disruption of the glucocorticoid receptor were similarly evaluated. The results showed that hepatic fat accumulation and hepatocellular proliferation were also suppressed in mice with liver specific disruption of glucocorticoid receptor. In conclusion, suppression of hepatocellular fat accumulation is associated with impaired hepatocellular proliferation following partial hepatectomy, indicating that hepatocellular fat accumulation is specifically regulated during and may be essential for normal liver regeneration.     

Altered hepatic triglyceride content after partial hepatectomy without impaired liver regeneration in multiple murine genetic models

Liver regeneration is impaired following partial hepatectomy (PH) in mice with genetic obesity and hepatic steatosis and also in wild-type mice fed a high-fat diet. These findings contrast with other data showing that liver regeneration is impaired in mice in which hepatic lipid accumulation is suppressed by either pharmacologic leptin administration or by disrupted glucocorticoid signaling. These latter findings suggest that hepatic steatosis may actually be required for normal liver regeneration. We have reexamined this relationship using several murine models of altered hepatic lipid metabolism. Liver fatty acid (FA) binding protein knockout mice manifested reduced hepatic triglyceride (TG) content compared to controls, with no effect on liver regeneration or hepatocyte proliferation. Examination of early adipogenic messenger RNAs revealed comparable induction in liver from both genotypes despite reduced hepatic steatosis. Following PH, hepatic TG was reduced in intestine-specific microsomal TG transfer protein deleter mice, which fail to absorb dietary fat, increased in peroxisome proliferator activated receptor alpha knockout mice, which exhibit defective FA oxidation, and unchanged (from wild-type mice) in liver-specific FA synthase knockout mice in which endogenous hepatic FA synthesis is impaired. Hepatic TG increased in the regenerating liver in all models, even in animals in which lipid accumulation is genetically constrained. However, in no model -- and over a >90-fold range of hepatic TG content -- was liver regeneration significantly impaired following PH. CONCLUSION: Although hepatic TG content is widely variable and increases during liver regeneration, alterations in neither exogenous or endogenous lipid metabolic pathways, demonstrated to promote or diminish hepatic steatosis, influence hepatocyte proliferation.     

Carbohydrate and oxygen metabolism during hepatocellular proliferation: a study in perfused livers from mirex-treated rats

Liver regeneration after partial hepatectomy is accompanied by altered hepatic intermediary metabolism. Because the organochlorine compound mirex also causes liver cell growth, the purpose of this study was to investigate hepatic carbohydrate and oxygen metabolism in perfused livers from mirex-treated rats and to localize cell proliferation in this model. Pretreatment with mirex (100 mg/kg, intragastrically) increased liver/body weight ratios and DNA synthesis in livers of fed rats, effects that were markedly diminished in livers of fasted rats. This finding shows that liver growth caused by mirex, as is the case after partial hepatectomy, is hindered when animals are deprived of food. Furthermore, perfused livers from mirex-treated rats had depleted glycogen stores but significantly elevated oxygen uptake compared with livers from control rats. Increases in oxygen uptake and hepatocellular proliferation were observed mostly in periportal regions of the liver lobule. In regenerating livers, most DNA synthesis was reported to also occur in these regions of the liver lobule. Taken together, these data show that liver cell growth caused by mirex is accompanied by changes in hepatic intermediary metabolism and sublobular proliferation similar to those observed after partial hepatectomy.     

Natural killer cell may impair liver regeneration in fulminant hepatic failure

The authors established a new experimental model of fulminant hepatic failure (FHF) with prolonged hepatocellular necrosis and impaired liver regeneration, and evaluated the immunological mechanisms related to the impaired liver regeneration in this model. A novel lipid A analogue, FS-112, was injected intravenously into male Balb/c mice, followed by a 70% partial hepatectomy 2 days later. Serum levels of T.Bil. and ALT rose 7 days after the partial hepatectomy, as compared with controls. In mice pretreated with FS-112, labeling indices of both BrdU and PCNA 36 hrs after the partial hepatectomy were significantly lower than those in the controls. Splenic lymphocytes harvested from the FHF mice 1–5 days after the partial hepatectomy showed a cytotoxic activity against regenerating hepatocytes with a peak effect on day 5. Cytotoxic activity against YAC-1 cells was also found up to 5 days after the partial hepatectomy, and resembled that directed against the regenerating hepatocytes. On the 5th day of FS-112 administration, there was a marked rise in the production of IFN-γ from splenocytes. When FK-506, an immunosuppressive agent, was given intracutaneously daily for 7 days, serum levels of T.Bil. and ALT significantly decreased, as compared with controls. Furthermore, the PCNA-labeling index 36 hrs after the partial hepatectomy was enhanced by the administration with FK-506 in the FHF mice. These results strongly suggest that the NK cells activated by IFN-y may be involved in killing the regenerating liver cells, and thus play a role in the pathogenesis of the impaired liver regeneration in FHF. Furthermore, it has been suggested that FK-506 may be beneficial for recovery from the impaired liver regeneration in FHF. This work was supported in part by grant (01-03-3) from the Research Group of Intractable Hepatitis sponsored by the Ministry of Health and Welfare of Japan, and by Grant-in-Aid for Co-operative Research (A) (01304038) from the Ministry of Education, Science and Culture of Japan.     

Impairment of liver regeneration correlates with activated hepatic NKT cells in HBV transgenic mice

A fraction of HBV carriers have a risk to develop liver cancer. Because liver possesses a strong regeneration capability, surgical resection of cancerous liver or transplantation with healthy liver is an alternate choice for HBV-caused hepatocarcinoma therapy. How HBV infection affects the regeneration of hepatectomized or transplanted liver remains elusive. We report that partial hepatectomy (PHx)-induced liver regeneration was reduced in HBV transgenic (HBV-tg) mice, a model of human HBV infection. PHx markedly triggered natural killer T (NKT) cell accumulation in the hepatectomized livers of HBV-tg mice, simultaneously with enhanced interferon gamma (IFN-gamma) production and CD69 expression on hepatic NKT cells at the early stage of liver regeneration. The impairment of liver regeneration in HBV-tg mice was largely ameliorated by NKT cell depletion, but not by natural killer (NK) cell depletion. Blockage of CD1d-NKT cell interaction considerably alleviated NKT cell activation and their inhibitory effect on regenerating hepatocytes. Neutralization of IFN-gamma enhanced bromodeoxyuridine incorporation in HBV-tg mice after PHx, and IFN-gamma mainly induced hepatocyte cell cycle arrest. Adoptive transfer of NKT cells from regenerating HBV-tg liver, but not from normal mice, could inhibit liver regeneration in recipient mice. CONCLUSION: Activated NKT cells negatively regulate liver regeneration of HBV-tg mice in the PHx model.     

Delayed liver regeneration in peroxisome proliferator-activated receptor-alpha-null mice

Peroxisome proliferator chemicals, acting via the peroxisome proliferator-activated receptor-alpha (Pparalpha), are potent hepatic mitogens and carcinogens in mice and rats. To test whether Pparalpha is required for hepatic growth in response to other stimuli, we studied liver regeneration and hepatic gene expression following partial hepatectomy (PH) of wild-type and Pparalpha-null mice. Pparalpha-null mice had a 12- to 24-hour delay in liver regeneration associated with a delayed onset and lower peak magnitude of hepatocellular DNA synthesis. Furthermore, these mice had a 24-hour lag in the hepatic expression of the G(1)/S checkpoint regulator genes Ccnd1 and cMyc and increased expression of the IL-1beta cytokine gene. Hepatic expression of Ccnd1, cMyc, IL-1r1, and IL-6r was induced in wild-type mice, but not Pparalpha-null mice, after acute exposure to the potent Pparalpha agonist Wy-14,643, indicating a role for Pparalpha in regulating the expression of these genes. Expression of the fatty acid omega-hydroxylase gene Cyp4a14, a commonly used indicator gene for Pparalpha activation, was strongly induced in wild-type mice after hepatectomy, suggesting that altered hepatocyte lipid processing may also contribute to the impaired regeneration in mice lacking the Pparalpha gene. In conclusion, liver regeneration in Pparalpha-null mice is transiently impaired and is associated with altered expression of genes involved in cell cycle control, cytokine signaling, and fat metabolism.     

Sex hormone-related functions in regenerating male rat liver

Sex hormone receptors were quantitated in normal male rat liver and in regenerating liver at several different times after partial (70%) hepatectomy. Both estrogen and androgen receptor content were altered dramatically by partial hepatectomy. Total hepatic content and nuclear retention of estrogen receptors increased, with the zenith evident 2 days after partial hepatectomy, corresponding to the zenith of mitotic index. Serum estradiol increased after 1 day, and reached a maximum at 3 days after surgery. In contrast, total and nuclear androgen receptor content demonstrated a massive decline at 1, 2, and 3 days after resection. Serum testosterone displayed a parallel decline. In addition, hepatic content of two androgen-responsive proteins was reduced to 15% and 13% of normal values during this period. The activity of these various proteins during regeneration of male rat liver is comparable to that observed in the liver of normal female rats. Taken together, these results indicate that partial hepatectomy induces a feminization of certain sexually dimorphic aspects of liver function in male rats. Furthermore, these data provide evidence that estrogens, but not androgens, may have an important role in the process of liver regeneration.     

Hepatic regeneration in insulin-like growth factor binding protein-1 transgenic mice

BACKGROUND/AIMS: Partial hepatectomy results in activation of genes in the residual liver tissue which serve to restore glucose homeostasis and regenerate liver mass. Expression of insulin-like growth factor binding protein-1 (IGFBP-1) is up-regulated following partial hepatectomy and IGFBP-1 can modulate both the metabolic and mitogenic effects of insulin-like growth factor-1 (IGF-I). The aim of the study was to compare the effects of partial hepatectomy on blood glucose levels and hepatic regeneration in wild-type and transgenic mice which constitutively overexpress IGFBP-1. METHODS: Hepatic IGFBP-1 mRNA, blood glucose concentrations, liver mass and hepatic DNA synthesis were compared in sham-operated and partially hepatectomized transgenic and wild-type mice. RESULTS: Hepatic IGFBP-1 mRNA was higher in sham-operated transgenic than wild-type mice, but in both groups of mice, partial hepatectomy was associated with a significant rise in IGFBP-1 mRNA. The absolute decline in blood glucose levels following partial hepatectomy was greater in transgenic mice. Basal DNA synthesis and the response to IGF-I in isolated hepatocytes from both groups of mice were similar, and DNA synthesis in the regenerating liver in vivo was not significantly different in transgenic as compared to wild-type mice: 449.3 +/- 63.9 vs. 321.6 +/- 52.3 cpm/microgram DNA. Hepatic regeneration as measured by liver weight after hepatectomy was not different between transgenic and wild-type mice. CONCLUSIONS: Constitutive overexpression of IGFBP-1 does not enhance hepatic regeneration and does not prevent the decline in blood glucose following partial hepatectomy.     

Kupffer cell prostaglandin-E2 production is amplified during hepatic regeneration.

Prostaglandin-E2 increases in liver tissue after partial hepatectomy and stimulates DNA synthesis in primary cultures of hepatocytes. This study evaluated the capacity of Kupffer cells isolated at various intervals after partial hepatectomy to produce prostaglandin E2 in response to bacterial endotoxin. This stimulator of Kupffer cells is a normal endogenous component of portal venous blood. After partial hepatectomy (6 to 48 hr), when hepatic regeneration rates were greatest, regenerating liver Kupffer cells demonstrated a significantly greater capacity to produce prostaglandin E2 in response to bacterial endotoxin than did equal numbers of Kupffer cells from time-matched, sham-operated control animals. However, by 12 days after partial hepatectomy, when liver mass had been more than 83% restored, regenerating liver Kupffer cell prostaglandin E2 production had decreased to levels produced by sham KC. We postulate that high levels of Kupffer cell-derived prostaglandin E2 provide a critical paracrine signal fundamental to the initiation and control of growth by neighboring hepatocytes during liver regeneration.     

Decreased expression of peroxisome proliferator-activated receptor alpha and liver fatty acid binding protein after partial hepatectomy of rats and mice.

BACKGROUND AIMS: Marked changes in metabolism, including liver steatosis and hypoglycemia, occur after partial hepatectomy. Peroxisome proliferator-activated receptor alpha (PPAR alpha) is a nuclear hormone receptor that is activated by fatty acids and involved in hepatic fatty acid metabolism and regeneration. Liver fatty acid binding protein (LFABP) is an abundant protein in liver cytosol whose expression is regulated by PPAR alpha. It is involved in fatty acid uptake and diffusion and in PPAR alpha signaling. The aim of this study was to investigate the expression of PPAR alpha and LFABP during liver regeneration. METHODS: Male Sprague-Dawley rats and male C57 Bl/6 mice were subjected to 2/3 hepatectomy and LFABP and PPAR alpha mRNA and protein levels were measured at different time points after surgery. The effect of partial hepatectomy was followed during 48 h in rats and 72 h in mice. RESULTS: PPAR alpha mRNA and protein levels were decreased 26 h after hepatectomy of rats. The LFABP mRNA and protein levels paralleled those of PPAR alpha and were also decreased 26 h after hepatectomy. In mice, the mRNA level was decreased after 36 and 72 h after hepatectomy. In this case, LFABP mRNA levels decreased more slowly after partial hepatectomy than in rats. CONCLUSIONS: A marked decrease in PPAR alpha expression may be important for changed gene expression, e.g. LFABP, and metabolic changes, such as hypoglycemia, during liver regeneration.     

Relationship between expression of cyclin D1 and impaired liver regeneration observed in fibrotic or cirrhotic rats

BACKGROUND AND AIM: The mechanisms responsible for impaired regenerative ability after hepatic resection observed in chronic liver disease are not fully understood. We have examined the relationships between an altered expression of cell cycle-related proteins in regenerating liver after partial hepatectomy and the impaired regenerative process observed in fibrotic and cirrhotic rats. METHODS: We performed 70% partial hepatectomy in both control and porcine serum-induced fibrotic rats, and 45% partial hepatectomy in thioacetamide-induced cirrhotic rats because of the high mortality associated with 70% partial hepatectomy. Liver regeneration was monitored by proliferating cell nuclear antigen labeling index and the expression of G1 regulatory cell cycle-related proteins was determined by immunoblot analysis. RESULTS: Compared with controls, hepatocyte DNA synthesis, and induction of cyclin D1 and p21(CIP1) proteins were delayed but not suppressed in porcine serum-induced fibrotic rats and markedly inhibited in thioacetamide-induced cirrhotic rats. p27(KIP1) protein levels were unaffected by partial hepatectomy and did not differ among all three groups. CONCLUSION: Two distinct rat models of liver fibrosis and cirrhosis showed markedly different proliferative responses after partial hepatectomy. The delay or failure of cyclin D1 induction, but not the increase of p21(CIP1) or p27(KIP1) might be responsible for their impaired liver regeneration.     

Lipid overloading during liver regeneration causes delayed hepatocyte DNA replication by increasing ER stress in mice with simple hepatic steatosis

Background and aim

Impaired fatty liver regeneration has already been reported in many genetic modification models. However, in diet-induced simple hepatic steatosis, which showed similar phenotype with clinical pathology, whether liver regeneration is impaired or not remains unclear. In this study, we evaluated liver regeneration in mice with diet-induced simple hepatic steatosis, and focused on excess lipid accumulation occurring during liver regeneration.

Methods

Mice were fed high fat diet (HFD) or control diet for 9–10 weeks. We analyzed intrahepatic lipid accumulation, DNA replication, and various signaling pathways including cell proliferation and ER stress during liver regeneration after partial hepatectomy. In addition, some of mice were pretreated with tauroursodeoxycholic acid (TUDCA), a chemical chaperone which alleviates ER stress, and then we estimated TUDCA effects on liver regeneration.

Results

The peak of hepatocyte BrdU incorporation, the expression of proliferation cell nuclear antigen (PCNA) protein, and the expressions of cell cycle-related genes were observed in delayed time in HFD mice. The expression of phosphorylated Erk1/2 was also delayed in HFD mice. The amounts of liver triglyceride were at least twofold higher in HFD mice at each time point. Intrahepatic palmitic acid was increased especially in HFD mice. ER stress induced during liver regeneration was significantly higher in HFD mice. In HFD mice, pretreatment with TUDCA reduced ER stress and resulted in improvement of delayed liver regeneration.

Conclusion

In simple hepatic steatosis, lipid overloading occurring during liver regeneration might be caused ER stress and results in delayed hepatocyte DNA replication.     

Down-regulation of liver regeneration by LAK cells--a study for effect of neuraminidase treated LAK cells on liver regeneration]

Both effect of LAK cells and neuraminidase treated LAK (N-LAK) cells on liver regeneration were investigated after 70% partial hepatectomy in mice. Intravenous transfusion of LAK cells suppressed the liver regeneration depending on cell numbers injected. N-LAK cells accumulated into regenerating liver 1.7 times in cell number compared with LAK cells. Injection of 5 x 10(7) LAK cells and N-LAK cells into hepatectomized mice suppressed the liver regeneration by 16.5% and 53.8% respectively. These results indicated that suppression of the liver regeneration by LAK cells was dependent upon the number of injected LAK cells and the degree of accumulation of LAK cells into the liver, namely, LAK cells down-regulate the regeneration of liver cells in the micro-milieu.     

ICAM-1 triggers liver regeneration through leukocyte recruitment and Kupffer cell-dependent release of TNF-alpha/IL-6 in mice

BACKGROUND & AIMS: Tumor necrosis factor (TNF)-alpha and interleukin (IL)-6 mediate hepatocyte proliferation in vivo, suggesting that local and systemic inflammatory reactions may trigger hepatic regeneration after major tissue loss. METHODS: Wild-type, intercellular adhesion molecule (ICAM)-1-/-, and neutropenic-induced mice were subjected to 70% hepatectomy. Three different approaches to block and/or deplete liver macrophages (Kupffer cells) were used. RESULTS: We found that liver from ICAM-1-deficient mice exhibited impaired regeneration after partial hepatectomy. This finding is associated with dramatic decrease in leukocyte recruitment and tissue TNF-alpha and IL-6 levels. All markers of hepatocyte proliferation were restored in ICAM-/- mice by injections of recombinant IL-6. Neutropenic animals and liver macrophage (Kupffer cell) depletion resulted in similar failure of regeneration with low levels of TNF-alpha and IL-6. CONCLUSIONS: The data suggest a novel pathway in which ICAM-1 binds to leukocytes after hepatectomy, triggering hepatocyte proliferation through Kupffer cell-dependent release of TNF-alpha and IL-6.     

Paradoxical effects of glucose feeding on liver regeneration and survival after partial hepatectomy

Although glucose is regularly administered to patients after partial hepatic resection, its contribution to survival and/or liver regeneration is unclear. To examine this question fed and anesthetized rats underwent 68% or 90% hepatectomy and received either oral 20% glucose solution or tap water (controls) ad lib for 24 h. Survival was compared by life table analysis and the regeneration response measured by 3H-thymidine uptake into liver deoxyribonucleic acid (DNA). Profound hypoglycemia (60 +/- 8 mg/dl) following 90% hepatectomy in controls was corrected by glucose feeding (99 +/- 25 mg/dl) and survival was enhanced (75 +/- 0.09% vs. 42 +/- 0.1%, p less than 0.01). No deaths occurred in the 68% hepatectomy groups wherein untreated hypoglycemia was not as severe (106 +/- 6 mg/dl). However, after 68% hepatectomy glucose adversely affected the regeneration response. We conclude that glucose feeding corrected the life threatening hypoglycemia following 90% hepatectomy. Prophylactic glucose administration after 68% hepatectomy reduced the liver regeneration response. Selective glucose administration to prevent lethal hypoglycemia may provide optimal survival and conditions for regeneration.     

Thyroid hormone metabolism during liver regeneration in rats.

The metabolism of thyroid hormones was studied during the prereplicative period of liver regeneration. After partial hepatectomy, serum thyroxine (T4) and triiodothyronine (T3) levles progressively fell, and reached a nadir at 12 h proportional to the quantity of liver tissue exised. The diminution (60-80%) in serum iodothyronines was related specifically to partial hepatectomy because laparotomy, ether anesthesia, and other stressful surgical procedures did not induce similar changes. At least 3 phenomena appear to be involved: 1) increased utilization and turnover of thyroid hormone by the regenerating liver remmant. 2) diminished hormone secretion by the thyroid gland between 6-12 h after surgery, and 3) a slightly reduced concentration of serum iodothyronine carrier proteins. The results support the concept that the liver participates in the metabolic regulation of T2 and T4 which in turn, control hepatocellular growth. It is suggested, however, that additional unknown factors control increased hepatic thyroid hormone turnover after partial hepatectomy.     

Expression and activation of pro-MMP-2 and pro-MMP-9 during rat liver regeneration

Partial hepatectomy triggers a variety of biological phenomena, which culminate in regeneration of the liver mass. Hepatocyte proliferation is a major feature of the regenerating liver after partial hepatectomy. Previous studies in our laboratory suggested that hepatic matrix remodeling might be a prerequisite process for hepatocyte proliferation in the regenerating liver. In the present study we use immunohistochemical staining, Western blot analysis, and gelatin zymography to show that the inactive matrix metalloproteinases (MMPs), pro-MMP-2 and pro-MMP-9, are elevated at 30 minutes and activated at 6 to 12 hours and at 3 to 6 hours, respectively, after hepatectomy. Sham-operated livers did not show an increase in inactive pro-MMP-2 and pro-MMP-9 and did not contain active MMP-2 or MMP-9. To examine whether tissue inhibitor of matrix metalloproteinase-1 (TIMP-1) is changed to regulate the activities of MMPs after partial hepatectomy, the level of TIMP-1 protein was analyzed by both immunohistochemistry and Western blot analysis. The level of TIMP-1 protein appears to increase by 6 to 18 hours, implying that an increase in TIMP-1 regulates activities of active MMP-2 and MMP-9. Taken together, these results suggest that hepatic matrix remodeling is mediated by activated MMPs, which contribute to modulation of the environment surrounding hepatocytes during rat liver regeneration.     

Matrix metalloproteinase-9 is an important factor in hepatic regeneration after partial hepatectomy in mice

Partial hepatectomy triggers hepatocyte proliferation, hepatic matrix remodeling, and hepatocyte apoptosis, all of which are important processes in the regenerating liver. Previous studies have shown an increase in the levels of matrix metalloproteinases gelatinase A (MMP-2) and gelatinase B (MMP-9) after partial hepatectomy. The goal of this study was to investigate the role of MMP-9 in liver regeneration after partial hepatectomy. A 70% hepatectomy or sham laparotomy was performed in wild-type or MMP-9-deficient (MMP-9-/-) mice. Hepatic regeneration was determined by liver weight/total body weight ratios and BrdU staining, which was used to a calculate mitotic index at several times postoperatively. Cytokine and growth factor expression was evaluated by Luminex bead-based ELISA and Western blots. Finally, the effect of MMP-9 on apoptosis was measured using TUNEL and caspase expression. The MMP-9-/- animals had a delayed hepatic regenerative response when compared with wild-type controls. The MMP-9-deficient animals expressed significantly less VEGF, HGF, and TNF-alpha between days 2 and 3 post-hepatectomy. Apoptosis, as measured by TUNEL staining and caspase expression, was decreased in the MMP-9-/-. In conclusion, MMP-9 plays an important role in liver regeneration after partial hepatectomy by affecting matrix remodeling, as well as cytokine, growth factor, and caspase expression.     

Kupffer cells are mandatory for adequate liver regeneration by mediating hyperperfusion via modulation of vasoactive proteins

OBJECTIVE: Physiological liver regeneration requires adequate microvascular perfusion after partial hepatectomy. Although Kupffer cells (KCs) are known to play a key role in modulating hepatocyte proliferation, their impact on regulating hepatic microcirculation during liver regeneration has so far been disregarded. With respect to their expression and modulation of vasoactive mediators, KCs may provide important signals that regulate hepatic perfusion during liver regeneration. METHODS: Intravital fluorescence microscopy, immunohistochemistry, Western blot analysis, and RT-PCR were used to analyze livers of KC-depleted mice (liposome-encapsulated clodronate application) and KC-competent mice at days 3, 5, and 8 after 68% hepatectomy. RESULTS: Selective and long-lasting KC elimination limited the resection-associated hyperperfusion, as evidenced by an only 1.7- to 2-fold increase of sinusoidal volumetric blood flow and shear stress in contrast to a 3.5- to 5-fold increase in KC-competent mice. In accordance to that livers of KC-depleted mice showed an altered pattern of vasoregulatory gene expression. KC-depleted mice failed to show resection-induced increase of HO-1 and eNOS protein expression, but revealed a reduction of hepatic eNOS and HO-1 protein levels to 22 and 12% of the corresponding values in KC-competent mice. In addition, the eNOS inhibitory protein caveolin-1 was increased in KC-depleted animals prior to as well as after resection. Furthermore, resection-associated accumulation of ET-1 mRNA was absent in KC-depleted livers. Finally, liver mass restoration was impaired, with a regain of only 79% weight within 8 days after resection in KC-depleted mice. CONCLUSION: The present study documents a remarkable change of the vasoactive mediator profile upon KC-depletion and liver resection, limiting intrahepatic hyperperfusion. Therefore, KC-dependent molecular mechanisms seem to be mandatory in regulating vasotonus during the process of liver regeneration and therewith maintaining intrahepatic shear stress as a trigger of hepatic proliferation.