Widespread expression of arginase I in mouse tissues. Biochemical and physiological implications.

Arginase I (AI), the fifth and final enzyme of the urea cycle, detoxifies ammonia as part of the urea cycle. In previous studies from others, AI was not found in extrahepatic tissues except in primate blood cells, and its roles outside the urea cycle have not been well recognized. In this study we undertook an extensive analysis of arginase expression in postnatal mouse tissues by in situ hybridization (ISH) and RT-PCR. We also compared arginase expression patterns with those of ornithine decarboxylase (ODC) and ornithine aminotransferase (OAT). We found that, outside of liver, AI was expressed in many tissues and cells such as the salivary gland, esophagus, stomach, pancreas, thymus, leukocytes, skin, preputial gland, uterus and sympathetic ganglia. The expression was much wider than that of arginase II, which was highly expressed only in the intestine and kidney. Several co-localization patterns of AI, ODC, and OAT have been found: (a) AI was co-localized with ODC alone in some tissues; (b) AI was co-localized with both OAT and ODC in a few tissues; (c) AI was not co-localized with OAT alone in any of the tissues examined; and (d) AI was not co-localized with either ODC or OAT in some tissues. In contrast, AII was not co-localized with either ODC or OAT alone in any of the tissues studied, and co-localization of AII with ODC and OAT was found only in the small intestine. The co-localization patterns of arginase, ODC, and OAT suggested that AI plays different roles in different tissues. The main roles of AI are regulation of arginine concentration by degrading arginine and production of ornithine for polyamine biosynthesis, but AI may not be the principal enzyme for regulating glutamate biosynthesis in tissues and cells.     

Polyamine homeostasis in arginase knockout mice

The role of ornithine decarboxylase (ODC) in polyamine metabolism has long been established, but the exact source of ornithine has always been unclear. The arginase enzymes are capable of producing ornithine for the production of polyamines and may hold important regulatory functions in the maintenance of this pathway. Utilizing our unique set of arginase single and double knockout mice, we analyzed polyamine levels in the livers, brains, kidneys, and small intestines of the mice at 2 wk of age, the latest timepoint at which all of them are still alive, to determine whether tissue polyamine levels were altered in response to a disruption of arginase I (AI) and II (AII) enzymatic activity. Whereas putrescine was minimally increased in the liver and kidneys from the AII knockout mice, spermidine and spermine were maintained. ODC activity was not greatly altered in the knockout animals and did not correlate with the fluctuations in putrescine. mRNA levels of ornithine aminotransferase (OAT), antizyme 1 (AZ1), and spermidine/spermine-N¹-acetyltransferase (SSAT) were also measured and only minor alterations were seen, most notably an increase in OAT expression seen in the liver of AI knockout and double knockout mice. It appears that putrescine catabolism may be affected in the liver when AI is disrupted and ornithine levels are highly reduced. These results suggest that endogenous arginase-derived ornithine may not directly contribute to polyamine homeostasis in mice. Alternate sources such as diet may provide sufficient polyamines for maintenance in mammalian tissues. ornithine; putrescine; spermidine; spermine; decarboxylase     

CRP2 transcript expression pattern in embryonic chick limb

We are using the model of the developing mouse embryo to elucidate the pattern of arginase expression in mammalian cells in normal animals and in arginase I (AI) deficiency during development by digoxigenin-labeled RNA in situ hybridization. Our goal is to understand the regulation of these isozymes, with the expectation that this knowledge will help patients suffering from AI deficiency. We found that AI mRNA was widely and strongly expressed in the normal developing mouse embryo; in contrast, a relatively strong AII mRNA signal was found only in the intestine. In the AI knockout mouse embryo, no AII overexpression was found. These results indicated that arginases are needed in mouse embryonic development and AI is the principal form required. The strong AI expression in the peripheral nervous system suggests that the pathogenesis of the neurological retardation in AI deficiency may be conditioned by AI deficiency in the nervous system during embryonic development.     

Rat Mammary Arginase: Isolation and Characterization

The extrahepatic arginase, AII, from rat mammary gland was isolated and its properties investigated and compared with those of the hepatic arginase, AI. Mammary arginase activity increased 300% at mid-lactation, an increase unaccompanied by an increase in liver arginase activity. Mammary gland contained two isozymes, separable by ion exchange chromatography. The major form, AII, was purified 103-fold and antisera were raised against it. A 1300-fold purification was achieved temporarily but the enzyme was unstable. Arginase AII was kinetically similar to AI: both had pH optima of 10 and K_ms for L-arginine of 12-14 mM. Arginase AII differed from AI in having a near-neutral pI and a slightly larger subunit size (39,800 Da compared to 38,900 Da by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)). Solution immunoprecipitation studies revealed that virtually all of the arginase present in liver was type AI, whereas kidney and mammary gland contained both isozymes. Western immunoblotting showed that the amount of immunoreactive mammary arginase AII protein increased at mid-lactation in parallel with the increase in activity. This suggests that the elevated arginase activity is due to de novo protein synthesis and/or reduced protein degradation, rather than activation of arginase.     

Diabetes-induced vascular dysfunction involves arginase I

Arginase can cause vascular dysfunction by competing with nitric oxide synthase for l-arginine and by increasing cell proliferation and collagen formation, which promote vascular fibrosis/stiffening. We have shown that increased arginase expression/activity contribute to vascular endothelial cell (EC) dysfunction. Here, we examined the roles of the two arginase isoforms, arginase I and II (AI and AII, respectively), in this process. Experiments were performed using streptozotocin-induced diabetic mice: wild-type (WT) mice and knockout mice lacking the AII isoform alone (AI(+/+)AII(-/-)) or in combination with partial deletion of AI (AI(+/-)AII (-/-)). EC-dependent vasorelaxation of aortic rings and arterial fibrosis and stiffness were assessed in relation to arginase activity and expression. Diabetes reduced mean EC-dependent vasorelaxation markedly in diabetic WT and AI(+/+)AII(-/-) aortas (53% and 44% vs. controls, respectively) compared with a 27% decrease in AI(+/-)AII (-/-) vessels. Coronary fibrosis was also increased in diabetic WT and AI(+/+)AII(-/-) mice (1.9- and 1.7-fold vs. controls, respectively) but was not altered in AI(+/-)AII (-/-) diabetic mice. Carotid stiffness was increased by 142% in WT diabetic mice compared with 51% in AI(+/+)AII(-/-) mice and 19% in AI(+/-)AII (-/-) mice. In diabetic WT and AI(+/+)AII(-/-) mice, aortic arginase activity and AI expression were significantly increased compared with control mice, but neither parameter was altered in AI(+/-)AII (-/-) mice. In summary, AI(+/-)AII (-/-) mice exhibit better EC-dependent vasodilation and less vascular stiffness and coronary fibrosis compared with diabetic WT and AI(+/+)AII(-/-) mice. These data indicate a major involvement of AI in diabetes-induced vascular dysfunction.     

Effects of arginase isoforms on NO Production by nNOS.

Both arginase isoforms (AI and AII) regulate high-level NO production by the inducible NOS, but whether the arginase isoforms also regulate low-level NO production by neuronal NOS (nNOS) is not known. In this study, 293 cells that stably overexpress nNOS gene (293nNOS cells) were transfected with rat AI (pEGFP-AI) or AII (pcDNA-AII) plasmids, and nitrite production was measured with or without supplemental L-arginine. Transfection with pEGFP-AI increased AI expression and activity 10-fold and decreased intracellular l-arginine by 50%. Nitrite production was inhibited by >80% when no l-arginine was supplemented but not when 1 mM L-arginine was present. The inhibition was reversed by an arginase inhibitor, N(omega)-hydroxy-L-arginine. Transfection with pcDNA-AII increased AII expression and activity but had little effect on nitrite production even if no l-arginine was added. These results suggest that, in 293nNOS cells, AI was more effective in regulating NO production by nNOS, most likely by competing for L-arginine.     

Immunohistochemical expression of pi class glutathione S-transferase and alpha-fetoprotein in hepatocellular carcinoma and chronic liver disease

OBJECTIVE: To determine whether tumor marker pi glutathione transferase (GST-pi) is expressed in hepatocellular carcinoma (HCC) and other chronic liver diseases and to compare its expression with that of alpha-fetoprotein (AFP). STUDY DESIGN: Samples used were formalin-fixed, paraffin-embedded liver tissues: normal (n = 3), chronic hepatitis B (n = 15), cirrhosis (n = 15) and HCC (n = 30). The expression of AFP and GST-pi was detected by using immunohistochemistry with the peroxidase-antiperoxidase method. AFP immunoreactivity was based on the cytoplasm of the hepatocytes, while GST-pi immunoreactivity was based on the nuclei of hepatocytes. RESULTS: In normal liver tissues, AFP was not expressed. However, there was strong staining of GST-pi in bile duct epithelium cells and weak staining in hepatocytes. Our results showed higher AFP immunoreactivity in cases of HCC (36.7%) as compared to cirrhosis (6.7%) and hepatitis B (0%), whereas GST-pi immunoreactivity was lower in cases of HCC (53.3%) as compared to cases of cirrhosis (100.0%) and hepatitis B (93.3%). Percent sensitivity of AFP determination for HCC was 36.7% as compared to 53.3% for GST-pi, thus making GST-pi a more sensitive marker for detection of HCC. This study showed a significant relationship between the intensity and percentage of cells stained in hepatitis B, cirrhosis and HCC for GST-pi immunoreactivity (P < .001, .001 and .05, respectively) but not for AFP (P > .05). Statistical analysis showed that there was no significant relationship between expression of AFP and GST-pi in cirrhosis and HCC cases. Hepatitis B virus infection in HCC cases showed a positive rate of 46.7%, with AFP staining positively in 42.9% of tissues and GST-pi staining positively in 57.1% of tissues. CONCLUSION: AFP is a diagnostic but rather insensitive tissue marker for HCC. However, the absence of AFP in benign chronic liver disease makes this marker useful in differentiating between HCC and other chronic liver diseases, whereas GST-pi can be used as a diagnostic marker for HCC as well as in detecting other chronic liver diseases.     

Arginase expression and modulation of IL-1β-induced nitric oxide generation in rat and human islets of Langerhans

Proinflammatory cytokine induction of NO synthesis may contribute to the destruction of pancreatic beta cells leading to type 1 diabetes. The NO synthase substrate arginine can also be metabolized to ornithine and urea in a reaction catalyzed by cytosolic (AI) or mitochondrial (AII) isoforms of arginase. Recent evidence suggests that the rate of NO generation is dependent on the relative activities of NO synthase and arginase. The objectives of this study were (i) to identify the arginase isoforms expressed in rat and human islets of Langerhans and a rat beta cell line, RINm5F and (ii) to investigate the competition for arginine between NO synthase and arginase in IL-1β-treated rat islets. Arginase activity was detected in rat islets (fresh tissue, 346 mU/mg protein; cultured, 587 mU/mg), cultured human islets (56 mU/mg), RINm5F cells (376 mU/mg), rat kidney (238 mU/mg), and rat liver (6119 mU/mg). Using Western blots, AI was shown to be the predominant isoform expressed in rat islets and in RINm5F cells while human islets expressed far more AII than AI. Rat islets were cultured in medium containing 1.14, 0.1, and 0.01 mM arginine and treated with IL-1β and the arginase inhibitor 2(S)-amino-6-boronohexanoic acid (ABH). IL-1β-induced NO generation was unaffected by ABH at 1.14 mM arginine, but significantly increased at 0.1 and 0.01 mM arginine. These findings suggest that the level of islet arginase activity can regulate the rate of induced NO generation and this may be relevant to the insulitis process leading to beta cell destruction in type 1 diabetes.     

Arginase expression and modulation of IL-1beta-induced nitric oxide generation in rat and human islets of Langerhans.

Proinflammatory cytokine induction of NO synthesis may contribute to the destruction of pancreatic beta cells leading to type 1 diabetes. The NO synthase substrate arginine can also be metabolized to ornithine and urea in a reaction catalyzed by cytosolic (AI) or mitochondrial (AII) isoforms of arginase. Recent evidence suggests that the rate of NO generation is dependent on the relative activities of NO synthase and arginase. The objectives of this study were (i). to identify the arginase isoforms expressed in rat and human islets of Langerhans and a rat beta cell line, RINm5F and (ii). to investigate the competition for arginine between NO synthase and arginase in IL-1beta-treated rat islets. Arginase activity was detected in rat islets (fresh tissue, 346 mU/mg protein; cultured, 587 mU/mg), cultured human islets (56 mU/mg), RINm5F cells (376 mU/mg), rat kidney (238 mU/mg), and rat liver (6119 mU/mg). Using Western blots, AI was shown to be the predominant isoform expressed in rat islets and in RINm5F cells while human islets expressed far more AII than AI. Rat islets were cultured in medium containing 1.14, 0.1, and 0.01 mM arginine and treated with IL-1beta and the arginase inhibitor 2(S)-amino-6-boronohexanoic acid (ABH). IL-1beta-induced NO generation was unaffected by ABH at 1.14 mM arginine, but significantly increased at 0.1 and 0.01 mM arginine. These findings suggest that the level of islet arginase activity can regulate the rate of induced NO generation and this may be relevant to the insulitis process leading to beta cell destruction in type 1 diabetes.     

Granulocytic myeloid‐derived suppressor cell population increases with the severity of alcoholic liver disease

Alcoholic liver disease (ALD) is a progressive liver disease that can cause a series of complications, including cirrhosis, liver failure and hepatocellular carcinoma. Granulocytic myeloid‐derived suppressor cell (gMDSC) populations have been observed to expand in various liver diseases and to inhibit innate and adaptive immunity in patients with liver disease. However, the characteristics of gMDSCs in patients with ALD have not been studied. We studied 24 healthy controls (HCs) and 107 patients with ALD and found an accumulation of gMDSCs in the peripheral blood of patients with alcoholic liver cirrhosis (ALC). Furthermore, ALC patients with a poor prognosis displayed a significant increase in peripheral gMDSCs and showed an increased capacity for arginase I production compared to HCs. In contrast, plasma arginase I levels in ALC patients were negatively correlated with total bilirubin and international normalized ratio, two key parameters of liver damage. Importantly, gMDSCs accumulated in the livers of ALC patients, and the frequency of liver gMDSCs significantly correlated with that of peripheral gMDSCs. In addition, gMDSC enrichment in vitro significantly inhibited the function of natural killer (NK) cells, perhaps preventing the NK‐induced apoptosis of hepatic stellate cells. In summary, increased peripheral and intrahepatic gMDSC populations are present in patients with ALC and may contribute to enhancing the severity of liver cirrhosis.     

不同肝病变组织中CD34、CD31、Ki-67的表达及意义

目的比较正常肝组织、慢性肝炎、肝硬化、肝细胞肝癌组织及肝转移腺癌中CD34、CD31、Ki-67不同表达,寻找有助于鉴别不同性质病变的生物学标记物.方法正常肝及病变肝组织标本共104例;其中,正常肝组织10例;慢生C型肝炎组织73例;肝硬化组织7例;肝细胞肝癌7例;结肠癌肝转移5例;乳腺癌肝转移2例.73例慢性C型肝炎组织全部为肝穿活检标本,其余组织均为手术切除标本.所有病例标本分别行CD34、CD31、Ki-67免疫组织化学染色,半定量评分系统评价染色结果.统计学分析结果数据.结果在非肿瘤组织,抗CD34阳性染色主要存在于汇管区,亦可见于汇管区周围的肝实质内血窦.阳性染色内皮细胞呈点状、线状、半环状及环状,散在或簇状分布.肿瘤组织内抗CD34阳性染色特征与非肿瘤组织相似,阳性染色血管在肿瘤组织内散布分布.CD34指数在各病变组中的表达排列顺序依次为:肝细胞肝癌>乳腺癌肝转移>结肠癌肝转移>肝硬化>慢性C型肝炎>正常肝组织,从正常肝组织至慢性肝炎至肝细胞肝癌,CD34表达明显增强.组织中,抗CD31阳性染色分布、定位、形态特征与CD34相似.CD31在慢性肝炎、肝硬化、肝细胞肝癌、结肠癌肝转移及乳腺癌肝转移组织中阳性表达率分别为:6.8%(5/73)、100%(7/7)、100%(7/7)、100%(5/5)、100%(2/2);肝癌组织中CD31染色强度明显大于非癌组织中,组间比较具有显著差异(P<0.05).Ki-67阳性染色细胞呈棕黄色核着色,散在分布于肝实质内.阳性染色细胞无形态特殊性,亦无分布上的特殊性.Ki-67在各病变组间的阳性表达率分别为:64.4%(47/73)、28.6%(2/7)、100%(7/7)、100%(5/5)、100%(2/2),其中以在结肠癌肝转移组织中表达最明显;组间比较具有非常显著差异(P<0.05).在正常肝脏、慢性C型肝炎、肝硬化、肝细胞肝癌CD34、CD31、Ki-67三种生物学标记物在同一标本同时表达的阳性率分别为:0%(0/0)、4.1%(3/73)、28.6%(2/7)、100%(7/7),CD34、CD31、Ki-67其中任两种同时表达的阳性率分别为0%(0/10)、63.0%(46/73)、100%(7/7)、100%(7/7).结论 CD34是慢性肝病、肝癌临床病理评价的指标之一,CD34与CD31、Ki-67同时分析有助于建立可靠的诊断.     

Bmi1在肝癌组织中的表达及其与细胞增殖和凋亡的关系

目的：探讨Bmi1在肝细胞肝癌（HCC）中的表达及与增殖和凋亡的关系。方法：收集HCC标本54例及相应的癌旁组织,10例正常肝组织标本,采用免疫组织化学EnVision二步法显示Bmi1的表达并结合增殖与凋亡特征进行分析。结果：在肝癌组织、癌旁组织细胞中Bmi1表达定位于胞核中,阳性表达率分别为79.6%（43/54）,31.2%（17/54）,10例正常肝组织未见表达,3组差异有统计学意义（P〈0.005）。HCC中Bmi1的高表达与年龄、性别、肿瘤大小、肿瘤数目、临床TNM分期、是否有肝硬化及是否有HBsAg感染无显著相关（P〉0.05）,但与组织学分级有关,高、中分化组Bmi1表达率显著高于低分化组（P〈0.05）。肝癌Bmi1阳性组增殖指数（PI）（50.3±21.4）%显著高于阴性表达组（17.3±7.1）%（P〈0.05）,凋亡指数（AI）无明显差异（P〉0.05）。结论：Bmi1在HCC中高表达,其表达增高可能与HCC的进展相关。     

Proteome analysis of hepatocellular carcinoma

Development of hepatocellular carcinoma (HCC) is a complex process involving multiple changes in gene expression and usually occurs in the presence of liver cirrhosis. In this research, we observed proteome alterations of three tissue types isolated from livers of HCC patients: normal, cirrhotic, and tumorous tissue. Proteome alterations were observed using two-dimensional polyacrylamide gel electrophoresis and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. Comparing the tissue types with each other, a significant change in expression level was found in 21 proteins. Of these proteins, sarcosine dehydrogenase, liver carboxylesterase, peptidyl-prolyl isomerase A, and lamin B1 are considered novel HCC marker candidates. In particular, lamin B1 may be considered as a marker for cirrhosis, because its expression level changes considerably in cirrhotic tissue compared with normal tissue. The proteins revealed in this experiment can be used in the future for studies pertaining to hepatocarcinogenesis, or as diagnostic markers and therapeutic targets for HCC.     

Serum ficolin-2 concentrations are significantly changed in patients with hepatitis B virus infection and liver diseases

Human ficolin-2 is an important lectin complement pathway activator that is secreted from liver cells and has been implicated as an anti-infection innate immune molecule. However, the role of ficolin-2 protein and its dynamic changes over the course of and in the prognosis of chronic hepatitis B(CHB) and hepatocellular carcinoma(HCC) remain unclear. In this study, we analyzed ficolin-2 protein expression in a cohort of individuals with CHB infection, HCC and cirrhosis. A sandwich enzyme-linked immunosorbent assay(ELISA) method was used to measure serum ficolin-2 concentrations. Ficolin-2 expression in liver tissues was detected by immunohistochemical staining. Serum ficolin-2 concentrations in CHB patients were significantly higher than in healthy controls and HBV carriers. After 48 weeks of routine amelioration liver function treatment, serum ficolin-2 concentrations decreased and were positively correlated with favorable alanine aminotransferase(ALT), HBV DNA and HBe Ag-seroconversion outcomes. Interestingly, we observed much lower expression of serum and intrahepatic ficolin-2 in HCC and cirrhosis compared with healthy controls. Our findings suggest that serum and intrahepatic ficolin-2 levels may be considered one of the indicators for the response of chronic HBV infection, HCC and cirrhosis.     

RNA干扰肝细胞肝癌中PECAM-1的表达对肿瘤细胞侵袭及增殖的影响

目的:探讨PECAM-1在肝细胞肝癌(Hepatocellular carcinoma,HCC)组织中的表达及意义。方法:选择2013年5月-2015年6月在我院接受治疗的HCC患者100例,收集肝癌患者HCC组织及癌旁组织,另选取100例正常肝脏组织作为对照组。应用免疫组织化学法检测PECAM-1在肝癌组织、癌旁组织以及正常肝脏组织中的阳性表达。利用小分子干扰RNA技术(si RNA)构建低表达的PECAM-1,并转染至肝癌细胞中抑制PECAM-1的表达。应用Transwell小室法检测肝癌细胞的侵袭能力,CCK-8法检测肝癌细胞的增殖能力。结果:PECAM-1在肝癌组织、癌旁组织及正常肝脏组织中呈不同程度阳性表达(P0.05);PECAM-1在肝癌组织及癌旁组织中的表达显著高于正常肝脏组织,差异具有统计学意义(P0.05);PECAM-1在肝癌组织中的表达显著高于癌旁组织,差异具有统计学意义(P0.05);转染si RNA PECAM-1后,肝癌细胞中PECAM-1 m RNA的表达水平明显下降,PECAM-1蛋白表达也明显降低,差异具有统计学意义(P0.05);转染si RNA PECAM-1后,肝癌细胞侵袭及增殖能力明显降低,差异具有统计学意义(P0.001)。结论:PECAM-1在肝癌患者血清中高表达,PECAM-1 si RNA能够抑制肝癌细胞的侵袭及增殖能力,提示PECAM-1可作为预测肝癌发生及发展的临床指标。     

Hemodynamic and metabolic effects of angiotensin II on the liver

To ascertain the mechanism of interaction between angiotensins (AI and AII) and the liver, an angiotensin-converting enzyme inhibitor (captopril) and a receptor antagonist (losartan) were used. Monovascular or bivascular liver perfusion was used to assess both hemodynamic (portal and arterial hypertensive responses) and metabolic (glucose production and oxygen consumption) effects. Microphysiometry was used for isolated liver cell assays to assess AII or losartan membrane receptor-mediated interaction. Captopril abolishes portal hypertensive response (PHR) to AI but not the AII effect. AII infused via the portal pathway promotes calcium-dependent PHR but not a hypertensive response in the arterial pathway (AHR); when infused into the arterial pathway AII promotes calcium-dependent PHR and AHR. Losartan infused into the portal vein abolishes PHR to AII but not the metabolic response; when infused via both pathways it abolishes the hypertensive responses and inhibits the metabolic effects. Isolated liver cells specifically respond to AII. Sinusoidal cells, but not hepatocytes, respond to 10 nM losartan. We conclude that AI has to be converted to AII to produce PHR. Quiescent stellate cells interacts in vitro with AII and losartan. Hemodynamic responses to AII are losartan-dependent but metabolic responses are partially losartan-independent. AII hemodynamic actions are mainly presinusoidal.     

Specific gene expression patterns in liver cirrhosis

Liver cirrhosis (LC) is a complex disease that can develop into hepatocellular carcinoma (HCC). In an effort to investigate genetic differences between LC and HCC, we used cDNA microarray analysis to characterize the gene expression profiles in LC and HCC tissues. Consistent differences were observed among the expression patterns in LC, HCC, and normal liver tissues. Interestingly, the expression patterns of LC without tumor association (LCT) were also readily distinguished from those of LC tissues near hepatic tumor tissues (near-tumor tissue, NTT). Moreover, 25 cirrhosis-specific genes could be used to divide the NTT samples into two groups: inflammatory active cirrhosis (NTTa) and inflammatory inactive cirrhosis (NTTi). We found that NTTa samples showed gene expression patterns similar to those of the LCT and HCC groups, whereas the expression patterns of the NTTi group were significantly different from those of the LCT, NTTa, and HCC groups. Finally, we selected two of the 25 LC-specific genes and showed that these markers could be used to successfully discriminate among the different LC subtypes. Collectively, these novel results allow the identification of new genetic subgroups of LC and provide new candidate genes for use as early markers for active cirrhosis and HCC.     

Global Gene Expression Profiling Reveals SPINK1 as a Potential Hepatocellular Carcinoma Marker

Background

Liver cirrhosis is the most important risk factor for hepatocellular carcinoma (HCC) but the role of liver disease aetiology in cancer development remains under-explored. We investigated global gene expression profiles from HCC arising in different liver diseases to test whether HCC development is driven by expression of common or different genes, which could provide new diagnostic markers or therapeutic targets.

Methodology and Principal Findings

Global gene expression profiling was performed for 4 normal (control) livers as well as 8 background liver and 7 HCC from 3 patients with hereditary haemochromatosis (HH) undergoing surgery. In order to investigate different disease phenotypes causing HCC, the data were compared with public microarray repositories for gene expression in normal liver, hepatitis C virus (HCV) cirrhosis, HCV-related HCC (HCV-HCC), hepatitis B virus (HBV) cirrhosis and HBV-related HCC (HBV-HCC). Principal component analysis and differential gene expression analysis were carried out using R Bioconductor. Liver disease-specific and shared gene lists were created and genes identified as highly expressed in hereditary haemochromatosis HCC (HH-HCC) were validated using quantitative RT-PCR. Selected genes were investigated further using immunohistochemistry in 86 HCC arising in liver disorders with varied aetiology. Using a 2-fold cut-off, 9 genes were highly expressed in all HCC, 11 in HH-HCC, 270 in HBV-HCC and 9 in HCV-HCC. Six genes identified by microarray as highly expressed in HH-HCC were confirmed by RT qPCR. Serine peptidase inhibitor, Kazal type 1 (SPINK1) mRNA was very highly expressed in HH-HCC (median fold change 2291, p = 0.0072) and was detected by immunohistochemistry in 91% of HH-HCC, 0% of HH-related cirrhotic or dysplastic nodules and 79% of mixed-aetiology HCC.

Conclusion

HCC, arising from diverse backgrounds, uniformly over-express a small set of genes. SPINK1, a secretory trypsin inhibitor, demonstrated potential as a diagnostic HCC marker and should be evaluated in future studies.