This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Yang, S. Articles by Diehl, A. M. Search for Related Content PubMed PubMed Citation Articles by Yang, S. Articles by Diehl, A. M.

Hepatic Hyperplasia in Noncirrhotic Fatty Livers

Is Obesity-related Hepatic Steatosis a Premalignant Condition?

Departments of Medicine [S. Y., H. Z. L., J. H., A. M. D.] and Radiology [V. P. C.], The Johns Hopkins University, Baltimore, Maryland 21205

	ABSTRACT

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
It is not known whether obesity increases the risk for hepatocellular carcinoma (HCC) simply because it promotes cirrhosis, a general risk factor for HCC, or via some other mechanism that operates independently of cirrhosis. If the latter occurs, then hepatocyte hyperplasia, an early event during the neoplastic process, might begin before liver cirrhosis develops. Genetically obese, leptin-deficient ob/ob mice are models for nonalcoholic fatty liver disease (NAFLD), a type of liver disease that is strongly associated with obesity and type 2 diabetes. Similar to obese, diabetic patients, ob/ob mice have an increased incidence of HCC. However, unlike humans with NAFLD, they rarely, if ever, develop cirrhosis spontaneously. To determine whether the noncirrhotic livers of ob/ob mice with NAFLD exhibit hepatocyte hyperplasia, parameters of proliferation and apoptosis were compared in adult ob/ob mice and their healthy litter mates. Adult ob/ob mice have an increase in liver mass relative to body mass. This hepatomegaly cannot be explained solely by lipid accumulation and is accompanied by significant increases in hepatocyte proliferative activity (as evidenced by increased Erk activation, cell-cycle related gene expression, bromodeoxyuridine incorporation, and hepatic DNA content) with concomitant inhibition of hepatocyte apoptosis (as evidenced by decreased numbers of apoptotic hepatocytes, induction of several antiapoptotic mechanisms, and decreased activation of procaspase 3). Thus, liver hyperplasia is evident at the earliest stage of NAFLD in ob/ob mice, which supports the concept that obesity-related metabolic abnormalities, rather than cirrhosis, initiate the hepatic neoplastic process during obesity.

	INTRODUCTION

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Obesity is associated with an increased risk for cancer of the liver and other epithelial organs including the uterus, colon, and pancreas (1, 2, 3) . The mechanisms responsible for this association are unknown. Cirrhosis is generally considered to be most important risk factor for HCC,² because almost all HCCs are diagnosed after cirrhosis has developed, regardless of the original cause of liver damage (4 , 5) . Obesity is associated with an increased risk of cirrhosis (6 , 7) , and this may explain why the prevalence of liver cancer is increased in obesity. On the other hand, a growing body of epidemiological evidence from large, population-based studies is beginning to implicate obesity-related hyperinsulinemia and insulin resistance in the pathogenesis of other obesity-related malignancies, such as nonhereditary colon cancer and postmenopausal breast cancer (1, 2, 3 , 8, 9, 10) .

During the neoplastic process, epithelial hyperplasia and dysplasia generally precede cancer by many years. For example, systematic analyses of colonic or breast epithelia during the various stages of neoplasia demonstrate the progressive accumulation of defects that increase cellular survival, disrupting normal tissue homeostatic mechanisms that balance apoptosis and proliferation (11) . A similar process occurs during virally mediated or toxin-related hepatic carcinogenesis (12 , 13) . Hence, it is reasonable to suspect that hepatic hyperplasia (i.e., increased hepatocyte proliferation relative to apoptosis) also antedates the appearance of liver cancer during insulin-resistant states, such as obesity. However, to our knowledge, there is no information about whether or not hepatocyte hyperplasia occurs during obesity per se. If it does, then it is important to learn whether this potentially premalignant condition begins before the liver becomes fibrotic, because obesity-related hepatic steatosis (fatty liver) is very common, occurring in at least 20% of American adults (14) , whereas, only a small minority of these individuals will ever develop significant hepatic fibrosis or cirrhosis (15) .

To determine whether, and when, hepatic hyperplasia might occur during obesity, we assessed hepatocyte proliferative and apoptotic activities in the livers of genetically obese, ob/ob mice. ob/ob mice have a naturally occurring mutation in the ob gene that prevents the synthesis of leptin, an adipocyte hormone that regulates satiety and energy balance (16 , 17) . Consequently, these mice become obese at an early age. Similar to many other murine models of obesity, including those that result from diabetes (db) and fatty (fa) loss-of-function mutations in the ob (leptin) receptor, young ob/ob mice develop insulin resistance, hyperinsulinemia, and eventually become hyperglycemic (i.e., type 2 diabetic; Refs. 18, 19, 20 ). An increased incidence of HCC has been demonstrated in old mice that are homozygous for the ob mutation, even when this defect is present in C57BL-6J strains that are generally resistant to malignancy (21) . Interestingly, from a very young age, ob/ob C57BL-6J mice have enlarged, fatty livers (22) . Although such mice are unusually vulnerable to toxic and ischemic liver injury and have been used as models for the early stages of human NAFLD (23) , they do not develop cirrhosis spontaneously (24) . Thus, despite the strong association between cirrhosis and HCC in humans, it is unlikely that cirrhosis accounts for the increased prevalence of HCC in ob/ob mice. Hence, these mice are relatively "pure" models of obesity-related hepatic insulin resistance and liver cancer that can be studied at a premalignant stage to determine whether, and when, hepatic hyperplasia develops. Our results demonstrate that, in the absence of any overt, exogenous insult, young adult male ob/ob mice have increased hepatocyte proliferation relative to apoptosis and suggest that this imbalance promotes increased liver mass. Given the general temporal relationship between epithelial hyperplasia and eventual neoplasia, these data support the possibility that cellular survival advantages develop in the liver during insulin-resistant states and contribute to obesity-related hepatic neoplasia.

	MATERIALS AND METHODS

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Animals.
Eight-week-old ob/ob C57BL-6J mice (n = 12) and their lean (heterozygote) litter mates (n = 12) were purchased from Jackson laboratories (Bar Harbor, ME). The mice were maintained in a temperature- and light-controlled animal facility and permitted ad libitum access to water and standard pellet-type chow for 2 weeks. At the end of this period, one mouse was randomly selected from each group, anesthetized with phenobarbital and evaluated by ¹H-NMR-spectroscopy to quantify fat accumulation in the liver (25) . Subsequently, all of the mice were weighed, given injections of BrdUrd i.p., and killed 2 h later by cervical dislocation. The livers were removed from the carcasses and weighed, and then a small biopsy was obtained from each organ. This tissue was placed in buffered formalin for subsequent evaluation of hepatic histology and nuclear BrdUrd incorporation. The remaining liver tissues were used immediately to isolate either fresh nuclei (n = 4 mice/group) or fresh mitochondria (n = 4 mice/group). Others (n = 4 mice/group) were snap-frozen in liquid nitrogen, stored at -80°C and processed subsequently to obtain whole liver extracts of RNA, DNA, and protein.

Evaluation of Hepatocyte Proliferative Activity.
This was assessed by counting BrdUrd (+) hepatocyte nuclei on coded liver sections that were counterstained with hematoxylin. Two sections from each mouse were evaluated independently by two observers (S. Y., J. H.). In each section, 10 x400 were examined and the total number of hepatocytes with and without BrdUrd (+) nuclei were recorded. An average proliferative index (number of BrdUrd (+) hepatocytes ÷ total number of hepatocytes) was calculated for each mouse; then the figures from the 12 mice in each group were totaled to obtain the mean (± SE) proliferative index for each group. In addition, freshly isolated liver cell nuclei from four mice/group were stained with propidium iodide, and nuclear ploidy was evaluated by flow cytometry.

Analysis of MAPKs.
Members of the MAPK family, Erk-1 and Erk-2, become phosphorylated (i.e., activated) during the prereplicative phase of hepatocyte proliferation. Hence, steady-state levels of phospho-Erk-1 and -Erk-2 are useful measures of hepatocyte proliferative activity. The content of total and phosphorylated Erk-1 and Erk-2 were evaluated in whole liver homogenates from four mice/group using immunoblot analysis with specific antisera from Santa Cruz Biotechnology, Inc (Santa Cruz, CA) as described previously (26) .

RNA Analysis of Growth-related Genes.
Total hepatic RNA was isolated from the livers of four mice/group using a minor modification (27) of Chomcznski and Sacchi’s method (28) . RNase protection analysis of this RNA was performed using reagents from PharMingen as we have described previously (29) . This assay permits the concurrent evaluation of several immediate early genes, such as c-jun, delayed-early genes, such as cyclin-D1, and S-phase-associated genes, such as cyclin A, as well as housekeeping genes, such as GAPDH, in the same RNA sample, facilitating standardization that controls for slight variability in RNA content that might occur among different samples.

DNA Quantitation.
Hepatic DNA was extracted and quantitated as described by Blin and Stafford (30) . Results are expressed as mg/g liver and also as mg/total liver.

Evaluation of Apoptosis.
The optimal technique for assessing apoptosis in the liver remains hotly contested. Standard approaches, including TUNEL staining and evaluation of DNA fragmentation by agarose gel electrophoresis, have been criticized because these assays may also become positive in necrotic livers (31) . Detection of apoptotic hepatocytes on H&E-stained tissue sections is generally acknowledged to be reliable. Thus, we used the latter approach to screen for differences in basal apoptotic rates between ob/ob and lean mice. Coded sections were reviewed by an experienced hepatologist (A. M. D.) who counted the numbers of apoptotic hepatocytes (characterized as shrunken, hypereosinophilic cells with pyknotic or absent nuclei) in 10 randomly selected x200 microscope fields on each of two sections/mouse. The mean (± SE) number of apoptotic hepatocytes/10 microscope fields was calculated from 12 mice in each group. However, because this approach risks underestimating apoptosis in the severely fatty livers of ob/ob mice, alternative measures of apoptosis were also assessed.

Caspase 3 Activation.
Whole liver homogenates from four mice/group were evaluated for evidence of caspase 3 activation. Equal amounts (40 µg/lane) of liver protein from ob/ob and lean mice were separated by SDS-PAGE, transferred to nylon membranes and probed for total caspase 3 and its cleavage products using antisera from PharMingen (San Diego, CA). The cleavage of procaspase 3 to caspase 3 activates the enzyme during hepatocyte apoptosis. Moreover, caspase 3 is the major effector of apoptosis in hepatocytes. Thus, the ratio of caspase 3 cleavage products (i.e., active caspase 3):procaspase 3 is a good measure of hepatocyte apoptotic activity (32) . The contents of pro- and active-caspase 3 were determined in each sample of liver protein by densitometric analysis of the immunoblots and were expressed as a ratio of activated caspase 3:total caspase 3 in each sample. Mean (±SE) results were derived from 4 mice/group.

Evaluation of Antiapoptotic Responses.
The basal rate of apoptosis is extremely low in normal adult livers (33) , challenging the sensitivity and reliability of assays that attempt to detect and quantitate further reductions in apoptotic activity (31) . However, if basal apoptotic activity is truly inhibited, then it is reasonable to assume that antiapoptotic mechanisms might be induced. The latter include increased DNA binding activity of NFB (34) , accumulation of bfl-1 and bcl-xL, antiapoptotic bcl-2 family members (35) , and activated antioxidant defenses, such as mitochondrial MnSOD (36) . According to previously published methods (27) , nuclear protein extracts (8 µg of protein/assay) from four mice/group were analyzed individually by EMSAs using ³²P-labeled, double-stranded oligonucleotide fragments that contain the B binding site in the immunoglobulin enhancer element (37) . In some assays, 1 µl of antisera specific for NFB p65 or p50 subunits was added to verify that the complexes contained NFB. In four other mice/group, the activity of a NFB target gene, MnSOD (34) , was evaluated in hepatic mitochondrial extracts and normalized per microgram of total mitochondrial protein as described previously (38) . Finally, RNase protection analysis was done using a 10-µg sample of total liver RNA from the final four mice in each group (29) . Reagents from PharMingen were used to assess the expression of bfl-1, bcl-xL, and GAPDH in each sample.

	RESULTS

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Hepatomegaly in Obese, ob/ob Mice.
ob/ob mice have hepatomegaly. Because ob/ob mice weigh about twice as much as their lean litter mates, it is not unexpected that their livers are larger than those of lean controls. However, normalization of liver weight by body weight demonstrates that the mass of ob/ob livers is greater than predicted solely on the basis of generalized obesity (Table 1) . Given that ob/ob mice have fatty livers (Fig. 1a) , it is conceivable that the tremendous accumulation of lipid within individual hepatocytes increases the liver:body weight ratio. However, analysis of the liver and entire body of a typical ob/ob mouse by ¹H-NMR spectroscopy demonstrates that there is actually less accumulation of fat in the liver (about 15% of the total ¹H signal) than there is in the rest of the body (in which fat accounts for almost 60% of the ¹H signal); therefore, this explanation seems unlikely (Fig. 1b) . In ob/ob mice of this age, there is no overt histological evidence for the hepatic accumulation of inflammatory cells or fibrous tissue (Fig. 1a) . Hence, a comparison of the total DNA content of fatty and normal livers should provide information about hepatocyte number and should help to determine whether increases in hepatocyte number contribute to ob/ob hepatomegaly. Consistent with evidence that ob/ob hepatocytes contain more fat than normal hepatocytes, the hepatic DNA content normalized per gram of liver wet weight is about 50% lower than normal. However, ob/ob livers weigh almost four times more than normal. Hence, the total DNA content of an ob/ob liver is, on average, significantly greater than that of an age- and gender-matched lean litter mate (Table 1) , which suggests that increases in hepatocyte number contribute to the increased liver mass of fatty livers.

View larger version (65K): [in this window] [in a new window]   Fig. 1. Differences in hepatic fat content in lean and ob/ob livers. a, H&E-stained section of liver tissue from a representative lean (?/ob) and obese (ob/ob) mouse (x200). b, 1H-NMR spectra derived from the livers and entire bodies of the same mice.

To compare the basal proliferative activities of normal and ob/ob livers, several approaches were used. First, we looked for evidence of activation of the MAPK cascade in the two groups. The content of phosphorylated MAPK isoforms (p42 Erk-1 and p44 Erk-2) is more than 4-fold greater in fatty, ob/ob livers than in normal livers despite similar content of total Erk-1 and Erk-2 in the two groups (Fig. 2) . MAPK activation typically occurs within minutes after hepatocytes are exposed to growth factors (33) . Another early event that heralds the reentry of hepatocytes into proliferative phases of the cell cycle is the accumulation of mRNAs that encode immediate-early genes, such as c-jun (42 , 43) . RNase protection analysis of liver RNA from normal and fatty livers demonstrates that c-jun mRNAs are increased in fatty livers (Fig. 3) . Moreover, transcripts for cyclin D₁ and cyclin A, genes that are up-regulated at the time of transition from G₁ into S-phase (44 , 45) , are also increased in fatty livers (Fig. 3) . The induction of cell cycle-associated genes in fatty livers suggests that hepatocyte DNA synthesis might be increased in ob/ob mice. To evaluate that possibility more directly, liver nuclei were isolated; stained with propidium iodide, and evaluated for DNA content by flow cytometry (46) . An increased proportion of nuclei with hyperdiploid DNA content were demonstrated in fatty livers (Fig. 4 ; Table 2 ). Consistent with these results, BrdUrd incorporation into hepatocyte nuclei is increased in tissue sections prepared from fatty livers (Table 2) .

View larger version (37K): [in this window] [in a new window]   Fig. 2. Hepatic activity of the MAPKs, Erk-1 (p42) and Erk-2 (p44), in lean and ob/ob mice. Western blots of whole liver homogenates were probed with antisera that are specific for either activated (i.e., phosphorylated) Erk-1 and Erk-2 or total (i.e., phosphorylated + nonphosphorylated) Erk-1 and Erk-2. An immunoblot demonstrating the hepatic content of activated erks (top panel) and total erks (bottom panel) in two mice from each group is shown. These findings were reproduced on another immunoblot that contained liver homogenates from two other mice from each group. Both immunoblots were analyzed by densitometry and on each blot, the content of activated MAPK (p42 + p44) in ob/ob homogenates was normalized to that in homogenates from the lean controls. Results from all four ob/ob and four lean control mice are graphed.

View larger version (39K): [in this window] [in a new window]   Fig. 3. Cell cycle-related gene expression in the livers of lean and ob/ob mice. Total hepatic RNA was analyzed by RNase protection assays using commercially available reagents that permit the concurrent evaluation of multiple cell-cycle-regulated genes and GAPDH, a housekeeping gene, in each of the same 10-µg RNA samples. The autoradiographs demonstrate the expression of c-jun, a gene that is induced early during G1, cyclin D-1, a gene that is induced at the time of G1-S phase transition, cyclin A, a gene that is induced during S phase, and GAPDH in two lean and two ob/ob mice. This experiment was repeated with liver RNA from another two mice from each group. After phosphoimager analysis of both membranes, data (mean ± SE) from all four lean and four ob/ob mice are graphed.

View larger version (14K): [in this window] [in a new window]   Fig. 4. Cell cycle distribution of liver nuclei for lean and ob/ob mice. Nuclei were isolated from livers, stained with propidium iodide, and analyzed by flow cytometry. The distribution of nuclei with various DNA contents are shown for one representative lean and one typical ob/ob mouse. DNA content of 40 = 2n (G1), 80 = 4n (G2-M), 160 = 8n (octaploid). The cumulative flow cytometry results from four lean (a) and four ob/ob (b) mice are summarized in Table 2 .

The cleavage of procaspase 3 activates this enzyme, which functions as the predominant terminal effector of hepatocyte apoptosis (48) . Thus, the ratio of procaspase 3 cleavage products (i.e., activated caspase 3) to total caspase 3 content provides a measure of apoptotic activity (32) . To compare the degree of caspase 3 activation in ob/ob and normal livers, equal amounts of whole liver protein from fatty and lean livers were separated by SDS-PAGE and exposed to commercially available antisera that recognize both procaspase 3 and its cleavage products. Consistent with the histological evidence for decreased apoptosis in ob/ob livers, the immunoblot assays demonstrated a significantly reduced ratio of activated:total caspase 3 in livers from ob/ob mice compared with livers from their lean litter mates (Fig. 5a) . To validate this approach, a separate group of lean C57BL-6 mice were given injections i.p. of a small dose (10 µg/mouse) of bacterial LPS, which is known to cause a slight increase in hepatocyte apoptosis (49) . Whole liver homogenates were analyzed for procaspase 3 and its cleavage products by immunoblot (Fig. 5b) . As expected, LPS treatment increases the ratio of activated caspase 3:total caspase 3 in normal mice, which confirms that this assay is a useful measure of hepatocyte apoptosis.

View larger version (32K): [in this window] [in a new window]   Fig. 5. Hepatic content of total and active caspase 3. Liver homogenates (40 µg of protein/mouse) from four lean and four ob/ob mice were separated by SDS-PAGE and probed with antisera that recognize both procaspase 3 (Mr 32,000) and its activated cleavage products (Mr 17,000 and 11,000). This experiment was repeated two more times. All three blots were analyzed by densitometry. On each blot, the expression of activated caspase 3 (Mr 17,000 + 11,000) was normalized to the total caspase 3 expression (Mr 32,000 + 17,000 + 11,000) in each homogenate. Results are the mean (+ SE) from four mice/group (a). A group of wild-type C57BL-6 mice (n = 4) were given injections i.p. of 10 µg of LPS to induce hepatocyte apoptosis. Liver homogenates were prepared from one mouse at each time point (0, 0.5, 1, or 6 h after LPS treatment). Caspase 3 activation was evaluated by immunoblot analysis as described in a. This immunoblot demonstrates the hepatic content of procaspase 3 and caspase 3 cleavage products in normal mice before and after the stimulation of apoptosis. Each lane contains 40 µg of liver protein (b).

View larger version (58K): [in this window] [in a new window]   Fig. 6. NFB-DNA binding activity. Hepatic nuclear extracts were prepared from the livers of two lean and two ob/ob mice. The binding activity of NFB was evaluated by gel mobility shift assay (8 µg of protein/lane) using 32P-labeled, double-stranded oligonucleotide fragments with the B binding site in the immunoglobulin enhancer element (left panel). Similar results (i.e., a 2- to 3-fold increase in NFB binding activity in ob/ob mice) were obtained when the experiment was repeated with nuclear extracts from another two mice from each group. To demonstrate the nature of the binding complexes, the assay was repeated using 8 µg of nuclear protein from one of the ob/ob mice. In this case, extract was preincubated with either preimmune serum (-) or with antisera to NFB p50 or p65 (right panel). The results indicate that the upper, slower-migrating complex contains a mixture of NFB p50 and p65, whereas the lower, faster-migrating complex contains predominately NFB p50.

View larger version (19K): [in this window] [in a new window]   Fig. 7. Mitochondrial MnSOD activity. Mitochondria were isolated from the livers of four lean and four ob/ob mice immediately after sacrifice. MnSOD activity was determined and expressed per mg of mitochondrial protein. Results are shown as mean ± SE.

View larger version (40K): [in this window] [in a new window]   Fig. 8. Antiapoptotic gene expression. Total liver RNA from two lean and two ob/ob mice were evaluated by RNase protection assay as described in the legend to Fig. 3 . A representative autoradiograph demonstrates the results in these four mice (10 µg RNA/mouse). The experiment was repeated with liver RNA from another two mice from each group. Both blots were analyzed by phosphoimager and data (mean ± SE) obtained from four ob/ob mice and four lean mice are graphed.

	DISCUSSION

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Although the mechanisms for the association between obesity and liver cancer are unknown, cellular survival advantages that occur during insulin resistance may contribute to hepatocarcinogenesis because obesity-related insulin resistance correlates with an increased risk for cancers in other organs, such as the breast and colon (2 , 3) . In general, most cases of HCC are diagnosed in patients who have had cirrhosis for many years (4 , 5) . However, it is not clear whether the neoplastic process begins during cirrhosis or starts at earlier stages of liver disease. If HCC begins during cirrhosis, then it is reasonable to speculate that hepatic insulin resistance might be involved, because advanced liver disease is generally associated with insulin resistance, and the association between cirrhosis and diabetes is particularly strong in obese individuals (7) . On the other hand, it has been difficult to determine whether insulin resistance plays an independent role in the pathogenesis of obesity-related hepatic neoplasia or is merely an associated abnormality that, like HCC, develops during cirrhosis.

Obesity is strongly associated with a spectrum of liver diseases that have been dubbed NAFLDs because they resemble alcohol-induced fatty liver diseases (6 , 62 , 63) . Fatty liver (hepatic steatosis) is the earliest and most common stage of NAFLD, afflicting almost 20% of American adults (14) , whereas cirrhosis, the most advanced stage of NAFLD, develops over decades in only a minority of these individuals (15) . Some degree of insulin resistance is present in most NAFLD patients with hepatic steatosis (64) , and, as with other types of liver disease, the severity of hyperinsulinemia and insulin resistance increase as cirrhosis becomes established (64, 65, 66) . However, because insulin resistance clearly antedates cirrhosis in many patients with NAFLD, livers could be evaluated during the early stages of NAFLD to determine whether hepatocyte hyperplasia occurs during insulin resistance when the liver is not cirrhotic. Genetically obese ob/ob mice with fatty livers have many of the features of the insulin-resistance syndrome in humans (18 , 22) . Hence, the livers of these mice can be analyzed to determine whether the process of hepatocyte neoplasia begins during the early stages of obesity-related fatty liver disease, when there is insulin resistance but not cirrhosis.

The present results demonstrate clearly that hepatocyte hyperplasia occurs at the fatty liver stage of NAFLD. However, as will be discussed subsequently, whether or not insulin resistance has any direct role in this process remains uncertain. The fatty hepatocytes of ob/ob mice exhibit many similarities to liver cells that have been transformed experimentally with the ras or raf proto-oncogenes. For example, both fatty livers and ras transformation result in MAPK activation, NFB induction, and the up-regulation of antiapoptotic bcl-2-related genes (67) , that are transcriptional targets for NFB (68) . Others have demonstrated that NFB is a downstream target of the MAPK cascade (69) and have shown that NFB induction required for raf- or ras-neoplastic transformation of rat liver epithelial cells (67) , which suggests that the induction of NFB and MAPK might contribute to the hepatocyte hyperplasia and hepatomegaly that occur in obesity-related fatty livers. However, if so, then it is paradoxical that hepatic NFB induction occurs in insulin-resistant ob/ob mice, because there is compelling evidence that insulin itself activates NFB through a Raf-1-mediated pathway in other mammalian cells (70) . Indeed, the ability of insulin to induce NFB is required for the antiapoptotic actions of the hormone in several cell culture models (71) .

Hence, it is conceivable that, rather than insulin resistance per se, one of the other hormonal, immunological, and metabolic abnormalities in obese, ob/ob mice might mediate hepatocyte hyperplasia. Given the association between type-2 diabetes, obesity, and malignancy in humans (8 , 9) and experimental animals (21 , 60 , 61) , the role of hyperinsulinemia (as opposed to insulin resistance) in the neoplastic process certainly merits investigation. In light of the recent demonstration that reactive oxygen species are required for hepatocarcinogenesis in c-myc/TGF transgenic mice (72) , the possibility that obesity-related increases in hepatic oxidative stress contribute to hepatic hyperplasia should also be considered. Hepatic mitochondrial production of reactive oxygen species is increased significantly in ob/ob mice (38) . Thus, the possibility that oxidant stress might be one of the mechanisms driving hepatic hyperplasia in these animals is a particularly intriguing hypothesis. Although the mechanisms driving increased reactive oxygen species release from ob/ob liver mitochondria are unknown, leptin deficiency and secondary changes in cytokine production (29 , 73 , 74) might be involved. If the latter is true, then additional work is necessary before data from our studies with leptin-deficient ob/ob mice can be extrapolated to obese humans with fatty livers, because hyperleptinemia (rather than leptin deficiency) is the rule in human obesity (75) .

Despite leaving many questions unanswered, our work is important because it demonstrates that some of the mechanisms that promote HCC in NAFLD, one of the most common types of liver disease, become operative "spontaneously," i.e., without an obvious requirement for comorbidity factors, such as viral infection or hepatotoxin exposure. Moreover, this hyperproliferative response begins long before cirrhosis occurs. Indeed, given evidence that ob/ob mice are resistant to cirrhosis (24) , but eventually develop HCC (21) , our observations raise the intriguing possibility that obesity-related fatty liver, itself, is a premalignant condition. If this possibility is confirmed by others, then our recent findings extend other data (7 , 47 , 76) that indicate that NAFLD is not always a benign process.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ To whom requests for reprints should be addressed, at The Johns Hopkins University School of Medicine, 912 Ross Building, 720 Rutland Street, Baltimore, MD 21205. Phone: (410) 955-7316; Fax: (410) 955-9677; E-mail: amdiehl{at}welch.jhu.edu

² The abbreviations used are: HCC, hepatocellular carcinoma; NAFLD, nonalcoholic fatty liver disease; NMR, nuclear magnetic resonance; BrdUrd, bromodeoxyuridine; MnSOD, manganese superoxide dismutase; MAPK, mitogen-activated protein kinase; LPS, lipopolysaccharide; EMSA, electrophoretic mobility shift assay; NFB, nuclear factor B; Erk, extracellular regulated kinase.

Received 2/ 1/01. Accepted 4/27/01.

	REFERENCES

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Gerber M., Corpet D. Energy balance and cancers. Eur. J. Cancer Prev., 8: 77-89, 1999.[Medline]
2. Schoen R. E., Tangen C. M., Kuller L. H., Burke G. I., Cushman M., Tracy R. P., Dobs A., Savage P. J. Increased blood glucose, insulin, body size and incident colorectal cancer. J. Natl. Cancer Inst. (Bethesda), 91: 1147-1154, 1999.[Abstract/Free Full Text]
3. Stoll B. A. Adiposity as a risk determinant for postmenopausal breast cancer. Int. J. Obes. Relat. Metab. Disord., 24: 527-533, 2000.[Medline]
4. Benvegnu L., Noventa F., Bernardinello E., Pontisso P., Gatta A., Albert A. Evidence for an association between the aetiology of cirrhosis and pattern of hepatocellular carcinoma development. Gut., 48: 110-115, 2001.[Abstract/Free Full Text]
5. Kubicka S., Rudolph K. L., Hanke M., Tietze M. K., Tillmann H. L., Trautwein C., Manns M. Hepatocellular carcinoma in Germany: a retrospective epidemiological study from a low-endemic area. Liver, 20: 312-318, 2000.[Medline]
6. Wanless I. R., Lentz J. S. Fatty liver hepatitis (steatohepatitis) and obesity: an autopsy study with analysis of risk factors. Hepatology, 12: 1106-1110, 1990.[Medline]
7. Caldwell S. H., Oelsner D. H., Iezzoni J. C., Hespenheide E. E., Battle E. H., Driscoll C. J. Cryptogenic cirrhosis: clinical characterization and risk factors for underlying disease. Hepatology, 29: 664-669, 1999.[Medline]
8. La Vecchia C., Negri E., Franceschi S., D’Avanzo B., Boyle P. A case-control study of diabetes mellitus and cancer risk. Br. J. Cancer, 70: 950-953, 1994.[Medline]
9. Wideroff L., Gridley G., Mellemkjaer L., Chow W. H., Linet M., Keehn S., Borch-Johnsen K., Olsen J. H. Cancer incidence in a population-based cohort of patients hospitalized with diabetes mellitus in Denmark. J. Natl. Cancer Inst. (Bethesda), 89: 1360-1365, 1997.[Abstract/Free Full Text]
10. Moore M. A., Park C. B., Tsuda H. Implications of the hyperinsulinaemia-diabetes-cancer link for preventive efforts. Eur. J. Cancer Prev., 7: 89-107, 1998.[Medline]
11. Canman C. E., Kastan M. B. Induction of apoptosis by tumor suppressor genes and oncogenes. Semin. Cancer Biol., 6: 17-25, 1995.[Medline]
12. Diez-Fernandez C., Sanz N., Alvarez A. M., Wolf A., Cascales M. The effect of non-genotoxic carcinogens, phenobarbital and clofibrate, on the relationship between reactive oxygen species, antioxidant enzyme expression and apoptosis. Carcinogenesis (Lond.), 19: 1715-1722, 1998.[Abstract/Free Full Text]
13. Moriya K., Fujie H., Shintani Y., Yotsuyanagi H., Tastsumi T., Ishibashi K., Matsuura Y., Kimura S., Miyamura T., Koike K. The core protein of hepatitis C virus induces hepatocellular carcinoma in transgenic mice. Nat. Med., 4: 1065-1067, 1998.[Medline]
14. el-Hassan A. Y., Ibrahim E. M., al-Mulhim F. A., Nabhan A. A., Chammas M. Y. Fatty infiltration of the liver: analysis of prevalence, radiological and clinical features and influence on patient management. Br. J. Radiol., 65: 774-778, 1992.[Abstract]
15. Teli M., James O. F., Burt A. D., Bennett M. K., Day C. P. A natural history of nonalcoholic fatty liver: a follow-up study. Hepatology, 22: 1714-1717, 1995.[Medline]
16. Friedman J. M., Leibel R., Siegel D. S., Walsh J., Bahary N. Molecular mapping of the mouse ob mutation. Genetics, 11: 1054-1062, 1991.
17. Halaas J. L., Gajiwala K. S., Maffei M., Cohen S. L., Cjait B. T., Rabinowitz D., Lallone R. L., Burley S. K., Friedman J. M. Weight-reducing effects of the protein encoded by the obese gene. Science (Wash. DC), 269: 544-546, 1995.
18. Campfield L. A., Smith F. J., Burn P. The OB protein (leptin) pathway—a link between adipose tissue mass and central neural networks. Horm. Metab. Res., 28: 619-632, 1996.[Medline]
19. Lee G. H., Proenca R., Montez J. M., Carroll K. M., Darvishzadeh J. G., Lee J. I., Friedman J. M. Abnormal splicing of the leptin receptor in diabetic mice. Nature (Lond.), 379: 632-635, 1996.[Medline]
20. Phillips M. S., Liu Q., Hammond H. A., Dugan V., Hey P. J., Caskey C. J., Hess J. F. Leptin receptor missense mutation in the fatty Zucker rat. Nat. Genet., 13: 18-19, 1996.[Medline]
21. Heston W., Vlhakis G. Genetic obesity and neoplasia. J. Natl. Cancer Inst. (Bethesda), 29: 197-209, 1962.
22. Pelleymounter M. A., Cullen M. F., Baker M. B., Hecht R., Winters D., Boone T., Collins F. Effects of the obese gene product on body weight regulation in ob/ob mice. Science (Wash. DC), 269: 540-543, 1995.[Abstract/Free Full Text]
23. Yang S. Q., Lin H. Z., Lane M. D., Clemens M., Diehl A. M. Obesity increases sensitivity to endotoxin liver injury: implications for pathogenesis of steatohepatitis. Proc. Natl. Acad. Sci. USA, 94: 2557-2562, 1997.[Abstract/Free Full Text]
24. Leclerq I. A., Farrell G. C. Leptin is required for the development of hepatic fibrosis. Hepatology, 32: 302A 2000.
25. Chavin K., Yang S. Q., Lin H. Z., Chatham J., Chacko V. P., Hoek J. B., Walajtyzs-Rode E., Rashid A., Chen C-H., Huang C-C., Wu T-C., Lane M. D., Diehl A. M. Obesity induces expression of uncoupling protein-2 in hepatocytes and promotes liver ATP depletion. J. Biol. Chem., 274: 5692-5700, 1999.[Abstract/Free Full Text]
26. Zeldin G., Rai R., Yang S. Q., Lin H. Z., Yin M., Diehl A. M. Effects of alcohol on cytokine-inducible transcription factors. Alcohol. Clin. Exp. Res., 20: 1639-1645, 1996.[Medline]
27. Lee F. Y. J., Li Y., Zhu H., Yang S. Q., Lin H. Z., Trush M., Diehl A. M. Tumor necrosis factor alpha increases mitochondrial oxidant production and induces expression of uncoupling protein-2 expression in the regenerating mouse liver. Hepatology, 29: 677-687, 1999.[Medline]
28. Chomczynski P., Sacchi N. Single step method of RNA isolation by acid guanidine thiocyanate-phenol-chloroform extraction. Anal. Biochem., 162: 156-161, 1987.[Medline]
29. Guebre-Xabier M., Yang S. Q., Lin H. Z., Schwenk R., Kryzch U., Diehl A. M. Altered hepatic lymphocyte subpopulations in obesity-related fatty livers. Hepatology, 31: 633-640, 1999.
30. Blin N., Stafford D. M. A general method for isolation of high molecular weight DNA from eukaryotes. Nucleic Acids Res., 3: 2303-2308, 1986.
31. Galle P. R. Apoptosis in liver disease. J. Hepatol., 27: 405-412, 1997.[Medline]
32. Inayat-Hussain S. H., Couet C., Cohen G. M., Cain K. Processing activation of CPP32-like proteases is involved in transforming growth factor ß-1-induced apoptosis in rat hepatocytes. Hepatology, 25: 1516-1526, 1997.[Medline]
33. Michalopoulos G. K., DeFrances M. C. Liver regeneration. Science (Wash. DC), 276: 60-66, 1997.[Abstract/Free Full Text]
34. Sonenshein G. E. Rel/NF-B transcription factors and the control of apoptosis. Semin. Cancer Biol., 8: 113-119, 1997.[Medline]
35. Kroemer G. The proto-oncogene Bcl-2 and its role in regulating apoptosis. Nat. Med., 3: 614-620, 1997.[Medline]
36. Manna S. K., Zhang H. J., Yan T., Oberly L. W., Aggarwal B. B. Overexpression of manganese superoxide dismutase suppresses tumor necrosis factor induced apoptosis and activation of nuclear transcription factor-B and activated protein-1. J. Biol. Chem., 273: 13245-13254, 1998.[Abstract/Free Full Text]
37. Sen R., Baltimore D. Multiple nuclear factors interact with the immunoglobulin enhancer sequences. Cell, 46: 705-716, 1986.[Medline]
38. Yang S. Q., Zhu H., Li Y., Lin H. Z., Gabrielson K., Trush M. A., Diehl A. M. Mitochondrial adaptations to obesity-related oxidant stress. Arch. Biochem. Biophys., 378: 259-268, 2000.[Medline]
39. Bursch W., Lauer B., Timmermann-Trosiener i., Barthel G., Schuppler J., Schulte-Herman R. Controlled death (apoptosis) of normal and putative preneoplastic cells in rat liver following withdrawal of tumor promoters. Carcinogenesis (Lond.), 5: 453-458, 1984.[Abstract/Free Full Text]
40. Columbano A., Ledda-Columbano G. M., Coni P. P., Faa G., Ligouri C., Santa Cruz G., Pani P. Occurrence of cell death (apoptosis) during the involution of liver hyperplasia. Lab. Investig., 52: 670-675, 1985.[Medline]
41. Selzner M., Clavien P. A. Failure of regeneration of the steatotic rat liver: disruption at two different levels in the regeneration pathway. Hepatology, 31: 35-42, 2000.[Medline]
42. Diehl A. M., Yin M., Fleckenstein J., Yang S. Q., Lin H. Z., Brenner D. A., Westwick J., Bagby G., Nelson S. Tumor necrosis factor induces c-jun during the regenerative response to liver injury. Am. J. Physiol., 267: G552-G561, 1994.[Abstract/Free Full Text]
43. Westwick J., Weitzel C., Leffert H. L., Brenner D. A. Activation of Jun kinase is an early event in hepatic regeneration. J. Clin. Investig., 95: 803-810, 1995.
44. Cressman D. E., Greenbaum L. E., DeAngelis R. A., Ciliberto G., Furth E. E., Poli V., Taub R. Liver failure and defective hepatocyte regeneration in interleukin-6-deficient mice. Science (Wash. DC), 274: 1379-1383, 1996.[Abstract/Free Full Text]
45. Yamada Y., Kirillova I., Peschon J. J., Fausto N. Initiation of liver growth by tumor necrosis factor: deficient liver regeneration in mice lacking type I tumor necrosis factor receptor. Proc. Natl. Acad. Sci. USA, 94: 1441-1446, 1997.[Abstract/Free Full Text]
46. Hedley D. W., Friedlander M. L., Taylor I. W., Rugg C. A., Musgrove E. A. Method for analysis of cellular DNA content of paraffin embedded pathological material using flow cytometry. J. Histochem. Cytochem., 31: 1333-1337, 1983.[Abstract]
47. Matteoni C., Younossi Z. M., McCullough A. Nonalcoholic fatty liver disease: a spectrum of clinical pathological severity. Gastroenterology, 116: 1413-1419, 1999.[Medline]
48. Jaeschke H., Fisher M. A., Lawson J. A., Simmons C. A., Faihood A., Jones D. A. Activation of caspase 3 (CPP32)-like proteases is essential for TNF -induced hepatic parenchymal cell apoptosis and neutrophil-mediated necrosis in a murine endotoxic shock model. J. Immunol., 160: 3480-3486, 1998.[Abstract/Free Full Text]
49. Shiratori Y., Kawase T., Komatsu Y., Hikiba Y., Okano K., Kamii K., Omata M. Endotoxin induced cellular communication in the liver: murine models for clarification of the role of LPS-responsive macrophages in the pathogenesis of liver diseases. J. Gastronenterol. Hepatol., 10: S97-S100, 1995.
50. Iimuro Y., Nishiura T., Hellerbrand C., Behrns K. E., Schoonhoven R., Grisham J. W., Brenner D. A. NF B prevents apoptosis and liver dysfunction during liver regeneration. J. Clin. Investig., 101: 802-811, 1998.[Medline]
51. Slater A. F. G., Nobel C. S. I., Orrenius S. The role of intracellular oxidants in apoptosis. Biochim. Biophys. Acta, 1271: 59-62, 1995.[Medline]
52. Cai J., Jones D. P. Superoxide in apoptosis: mitochondrial generation triggered by cytochrome c loss. J. Biol. Chem., 273: 11401-11404, 1998.[Abstract/Free Full Text]
53. Liou H., Baltimore D. Regulation of the NF-ß/rel transcription factor and I ß inhibitor system. Curr. Opin. Cell Biol., 5: 477-487, 1993.[Medline]
54. Zamzami N., Brenner C., Marzo I., Susin S. A., Kroemer G. Subcellular and submitochondrial mode of action of Bcl-2-like oncoproteins. Oncogene, 16: 2265-2282, 1998.[Medline]
55. Shimizu S., Eguchi Y., Kamiike W., Funahashi Y., Mignon A., Lacronique V., Matsuda H., Tsujimoto Y. Bcl-2 prevents apoptotic mitochondrial dysfunction by regulating proton flux. Proc. Natl. Acad. Sci. USA, 95: 1455-1459, 1998.[Abstract/Free Full Text]
56. Zong W. X., Edelstein L. C., Chen C., Bash J., Gelinas C. The prosurvival Bcl-2 homolog Bfl-1/A1 is a direct transcriptional target of NF-B that blocks TNF-induced apoptosis. Genes Dev., 13: 382-387, 1999.[Abstract/Free Full Text]
57. Thorgeirsson S. S., Santoni-Rugui E. Interaction of c-myc with transforming growth factor and hepatocyte growth factor in hepatocarcinogenesis. Mutat. Res., 376: 221-234, 1997.[Medline]
58. Santoni-Rugui E., Jensen M. R., Factor V. M., Thorgeirsson S. S. Acceleration of c-myc-induced hepatocarcinogenesis by co-expression of transforming growth factor (TGF)- in transgenic mice is associated with TGF ß-1 signaling disruption. Am. J. Pathol., 154: 1693-1700, 1999.[Abstract/Free Full Text]
59. Sanders S., Thorgeirsson S. S. Promotion of hepatocarcinogenesis by phenobarbital in c-myc/TGF transgenic mice. Mol Carcinogen., 28: 168-173, 2000.[Medline]
60. Hancock R. L., Dickie M. M. Biochemical, pathological, and genetic aspects of a spontaneous mouse hepatoma. J. Natl. Cancer Inst. (Bethesda), 43: 407-415, 1969.
61. Wolff G. L., Morrissey R. L., Chen J. J. Susceptible and resistant subgroups in genetically identical populations: response of mouse liver neoplasia and body weight to phenobarbital. Carcinogenesis (Lond.), 7: 1935-1937, 1986.[Abstract/Free Full Text]
62. Braillon A., Capron J. P., Herve M. A., Degott C., Quenum C. Liver in obesity. Gut, 26: 133-139, 1985.[Abstract/Free Full Text]
63. Marceau P., iron S., Hould F. S., Marceau S., Simard S., Thung S. N., Kral J. G. Liver pathology and the metabolic syndrome X in severe obesity. J. Clin. Endocrinol. Metab., 84: 1513-1517, 1999.[Abstract/Free Full Text]
64. Marchesini G., Brizi M., Morselli-Labate A. M., Bianchi G., Bugianesi E., McCullough A. J., Forlani G., Melchionda N. Association of nonalcoholic fatty liver disease with insulin resistance. Am. J. Med., 107: 450-455, 1999.[Medline]
65. Angulo P., Deach J. C., Batts K. P., Lindor K. D. Independent predictors of liver fibrosis in patients with nonalcoholic steatohepatitis. Hepatology, 30: 1999.
66. Ratziu V., Giral P., Charlotte F., Bruckert E., Thibault V., Theodorou I., Khalil L., Turpin G., Opolon P., Poynard T. Liver fibrosis in overweight patients. Gastroenterology, 118: 1117-1123, 2000.[Medline]
67. Arsura M., Mercurio F., Oliver A. L., Thorgeirsson S. S., Sonenshein G. E. Role of IB kinase complex in oncogenic ras- and raf-mediated transformation of rat liver epithelial cells. Mol. Cell. Biol., 20: 5381-5391, 2000.[Abstract/Free Full Text]
68. Tamatani M., Che Y. H., Matsuzaki H., Ogawa S., Okada H., Miyake S., Mizuno T., Tohyama M. Tumor necrosis factor induces Bcl-2 and Bcl-x expression through NF-B activation in primary hippocampal neurons. J. Biol. Chem., 274: 8531-8538, 1999.[Abstract/Free Full Text]
69. Schulze-Osthoff K., Ferrari D., Riehemann K., Wesselborg S. Regulation of NF-B activation by MAP kinase cascades. Immunobiology, 198: 35-49, 1997.[Medline]
70. Betrand F., Philippe C., Antoine P. J., Baud L., Groyer A., Capeau J., Cherqui G. Insulin activates nuclear factor B in mammalian cells through a raf-1-mediated pathway. J. Biol. Chem., 270: 24435-24441, 1995.[Abstract/Free Full Text]
71. Bertrand F., Atfi A., Cadore A., L’Allemain G., Robin H., Lascols O., Capeau J., Cherqui G. A role for nuclear factor B in the antiapoptotic function of insulin. J. Biol. Chem., 273: 2931-2938, 1998.[Abstract/Free Full Text]
72. Factor M., Kiss A., J. T., W., Wirth P. J., Thorgeirsson S. S. Disruption of redox homeostasis in the transforming growth factor /c-myc transgenic mouse model of accelerated hepatocarcinogenesis. J. Biol. Chem., 273: 15846-15853, 1998.[Abstract/Free Full Text]
73. Loffreda S., Yang S. Q., Lin H. Z., Bulkley G., Bregman M., Nobel P., Diehl A. M. Leptin regulates proinflammatory immune responses. FASEB J., 12: 57-65, 1998.[Abstract/Free Full Text]
74. Lee F-Y., Li Y., Yang E. K., Yang S. Q., Lin H. Z., Trush M. A., Dannenberg A. J., Diehl A. M. Phenotypic abnormalities in macrophages from leptin-deficient, obese mice. Am. J. Physiol., 276: C386-C394, 1999.[Abstract/Free Full Text]
75. Rosenbaum M., Leibel R. L., Hirsch J. Obesity. N. Engl. J. Med., 337: 396-407, 1997.[Free Full Text]
76. Powell E. E., Cooksley G. E., Hanson R., Searle J., Halliday R. W., Powell L. W. The natural history of nonalcoholic steatohepatitis: a follow-up study of 42 patients followed for up to 21 years. Hepatology, 11: 74-80, 1990.[Medline]

This article has been cited by other articles:

				R. A. Jolly, R. Ciurlionis, D. Morfitt, M. Helgren, R. Patterson, R. G. Ulrich, and J. F. Waring Microvesicular Steatosis Induced by a Short Chain Fatty Acid: Effects on Mitochondrial Function and Correlation with Gene Expression Toxicol Pathol, February 1, 2004; 32(2_suppl): 19 - 25. [Abstract] [PDF]

				M L. Martinez-Chantar, E. R Garcia-Trevijano, M U. Latasa, I. Perez-Mato, M. M Sanchez del Pino, F. J Corrales, M. A Avila, and J. M Mato Importance of a deficiency in S-adenosyl-L-methionine synthesis in the pathogenesis of liver injury Am. J. Clinical Nutrition, November 1, 2002; 76 (5): 1177S - 1182S. [Abstract] [Full Text] [PDF]

				M. Torbenson, S. Q. Yang, H. Z. Liu, J. Huang, W. Gage, and A. M. Diehl STAT-3 Overexpression and p21 Up-Regulation Accompany Impaired Regeneration of Fatty Livers Am. J. Pathol., July 1, 2002; 161(1): 155 - 161. [Abstract] [Full Text] [PDF]

				J. M. MATO, F. J. CORRALES, S. C. LU, and M. A. AVILA S-Adenosylmethionine: a control switch that regulates liver function FASEB J, January 1, 2002; 16(1): 15 - 26. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles