Clonality of large regenerative nodules in liver cirrhosis

Hit-And-Run Mechanism of HBV-Mediated Progression to Hepatocellular Carcinoma

Aim and background

Hepatitis B virus is implicated in the development of hepatocellular caracinoma. No oncogenes have been identified within the viral genome. Furthermore, it frequently fragments after integration into the hepatocyte genome. Simultaneous investigations of hepatitis B virus integration patterns and genetic changes in precancerous tissues are important to understand the role played by hepatitis B virus integration in hepatocellular caracinoma.

Method

We used a combination approach of dual characterization of highly polymorphic loci and the change in hepatitis B virus-DNA integration pattern. Large regenerative nodules were dissected from 6 explanted hepatitis B virus infected cirrhotic livers. Nodules within each liver segment were schematically mapped and histopathologically analyzed. Genomic DNA from each nodule was analyzed for hepatitis B virus integration and the genetic stability of 12 microsatellite loci including D3S2321, D8S1022, D17S1159, D4S2281, D5S1/2, D16S675, D16S685, D16S490, D16S526, D16S673, D16S677 and D16S690.

Results

Data from different liver segments revealed few viral integrations and average allele loss. The most exciting results came from a segment containing a set of clonally and spatially related nodules having similar histologic features, a progressive lineage of allele loss, HBV integration and loss of integration.

Conclusions

This model portrait, a scenario of genetic events that precede tumor formation where the acquisition and loss of hepatitis B virus integrations in clonally related regenerative nodules, might explain how the virus acts as a hit-and-run mutagen.

Decoding multifocal hepatocellular carcinoma: an opportune pursuit

Hepatocellular carcinoma (HCC) is a malignancy with major worldwide prevalence and a poor overall prognosis. About 75% of all HCC cases are initially diagnosed as multiple tumors, presenting a particular challenge for aggressive surgical therapy. Multiple HCC may result from multicentric occurrence (MO-HCC) or intrahepatic metastases (IM-HCC), corresponding to highly dissimilar clinical outcomes. Reliable distinction of these two mechanisms is therefore paramount in optimizing the management of multiple HCC. In a recent work, Miao et al. adopted a multi-omics approach to find key parameters of different clonality in MO-HCC vs. IM-HCC and link these data to tumor behavior and prognosis in a cohort of patients with HBV-related HCC. The mitotic checkpoint regulator TTK has emerged from this analysis as a novel biomarker that may predict aggressive behavior and early postoperative recurrence of HCC.

Clonality of nodular lesions in liver cirrhosis and chromosomal abnormalities in monoclonal nodules of altered hepatocytes

AIMS

To investigate the clonality and chromosome abnormalities of nodules of altered hepatocytes (NAH) in liver cirrhosis and determine whether there is a genetic link between monoclonal NAH and hepatocellular carcinoma (HCC).

METHODS AND RESULTS

First, 93 nodules from nine hepatitis B virus (HBV)-related liver cirrhosis patients were dissected by laser microdissection. Next, genomic DNA was extracted, pretreated with Hpa II or Hha I, and amplified via nested polymerase chain reaction for the phosphoglycerate kinase and androgen receptor genes. Finally, the chromosomal aberrations of 12 monoclonal NAH were studied using array-based comparative genomic hybridization (array-CGH). Loss of X chromosomal inactivation mosaicism was demonstrated in three large regenerative nodules and 12 NAH with small cell change (SCC), indicating their neoplastic nature. Among the 60 NAH without SCC, 29 (48.33%) were shown to be monoclonal, whereas four glycogen-storing foci and 14 regenerative nodules were found to be polyclonal. Array-CGH analysis revealed chromosomal abnormalities in one NAH with SCC. Moreover, a part of chromosomal abnormalities in the NAH with SCC coincided with those in HCC.

CONCLUSIONS

Some (48.33%) NAH in HBV-associated cirrhosis, particularly all those with SCC, are already neoplastic lesions. Occurrence of SCC is a late event during NAH progression, suggesting a premalignant phenotype.

Clonal expansion of normal-appearing human hepatocytes during chronic hepatitis B virus infection

Chronic hepatitis B virus (HBV) infections are associated with persistent immune killing of infected hepatocytes. Hepatocytes constitute a largely self-renewing population. Thus, immune killing may exert selective pressure on the population, leading it to evolve in order to survive. A gradual course of hepatocyte evolution toward an HBV-resistant state is suggested by the substantial decline in the fraction of infected hepatocytes that occurs during the course of chronic infections. Consistent with hepatocyte evolution, clones of >1,000 hepatocytes develop postinfection in the noncirrhotic livers of chimpanzees chronically infected with HBV and of woodchucks infected with woodchuck hepatitis virus (W. S. Mason, A. R. Jilbert, and J. Summers, Proc. Natl. Acad. Sci. U. S. A. 102:1139-1144, 2005; W. S. Mason et al., J. Virol. 83:8396-8408, 2009). The present study was carried out to determine (i) if extensive clonal expansion of hepatocytes also occurred in human HBV carriers, particularly in the noncirrhotic liver, and (ii) if clonal expansion included normal-appearing hepatocytes, not just hepatocytes that appear premalignant. Host DNA extracted from fragments of noncancerous liver, collected during surgical resection of hepatocellular carcinoma (HCC), was analyzed by inverse PCR for randomly integrated HBV DNA as a marker of expanding hepatocyte lineages. This analysis detected extensive clonal expansion of hepatocytes, as previously found in chronically infected chimpanzees and woodchucks. Tissue sections were stained with hematoxylin and eosin (H&E), and DNA was extracted from the adjacent section for inverse PCR to detect integrated HBV DNA. This analysis revealed that clonal expansion can occur among normal-appearing human hepatocytes.

Detection of clonally expanded hepatocytes in chimpanzees with chronic hepatitis B virus infection

During a hepadnavirus infection, viral DNA integrates at a low rate into random sites in the host DNA, producing unique virus-cell junctions detectable by inverse nested PCR (invPCR). These junctions serve as genetic markers of individual hepatocytes, providing a means to detect their subsequent proliferation into clones of two or more hepatocytes. A previous study suggested that the livers of 2.4-year-old woodchucks (Marmota monax) chronically infected with woodchuck hepatitis virus contained at least 100,000 clones of >1,000 hepatocytes (W. S. Mason, A. R. Jilbert, and J. Summers, Proc. Natl. Acad. Sci. USA 102:1139-1144, 2005). However, possible correlations between sites of viral-DNA integration and clonal expansion could not be explored because the woodchuck genome has not yet been sequenced. In order to further investigate this issue, we looked for similar clonal expansion of hepatocytes in the livers of chimpanzees chronically infected with hepatitis B virus (HBV). Liver samples for invPCR were collected from eight chimpanzees chronically infected with HBV for at least 20 years. Fifty clones ranging in size from approximately 35 to 10,000 hepatocytes were detected using invPCR in 32 liver biopsy fragments (approximately 1 mg) containing, in total, approximately 3 x 10(7) liver cells. Based on searching the analogous human genome, integration sites were found on all chromosomes except Y, approximately 30% in known or predicted genes. However, no obvious association between the extent of clonal expansion and the integration site was apparent. This suggests that the integration site per se is not responsible for the outgrowth of large clones of hepatocytes.

Genetics of hepatocellular tumors

Numerous genetic alterations are accumulated during the process of hepatocarcinogenesis. These genetic alterations can be divided into two groups. The first set of genetic alterations is specific of hepatocellular tumor risk factors. It includes integration of hepatitis B virus (HBV) DNA, R249S TP53 (tumor protein p53) mutation in aflatoxin B1-exposed patients, KRAS mutations related to vinyl chloride exposure, hepatocyte nuclear factor 1alpha (HNF1alpha) mutations associated to hepatocellular adenomas and adenomatosis polyposis coli (APC) germline mutations predisposing to hepatoblastomas. The second set of genetic alterations are etiological nonspecific, it includes recurrent gains and losses of chromosomes, alteration of TP53 gene, activation of WNT/beta-catenin pathway through CTNNB1/beta-catenin and AXIN (axis inhibition protein) mutations, inactivation of retinoblastoma and IGF2R (insulin-like growth factor 2 receptor) pathways through inactivation of RB1 (retinoblastoma 1), P16 and IGF2R. Comprehensive analyses of these genetic alterations have defined two pathways of hepatocarcinogenesis according to the presence or the absence of chromosomal instability. Hepatitis B virus and poorly differentiated tumors are related to chromosome instable tumors associated with frequent TP53 mutations, whereas non-HBV and well-differentiated tumors are related to chromosomal stable samples that are frequently beta-catenin activated. These classifications have clinical relevance as genetic alterations may also be related to prognosis.

Genetic evaluation of the dysplasia-carcinoma sequence in chronic viral liver disease: a detailed analysis of two cases and a review of the literature

Hepatocellular carcinoma (HCC) is one of the most frequent human malignancies, especially in Asia and Africa, but also in the Western world its incidence is increasing. HCC is a complication of chronic liver disease with cirrhosis as the most important risk factor. Viral co-pathogenesis due to hepatitis B virus (HBV) and hepatitis C virus (HCV) infection seems to be an important factor in the development of HCC. Curative therapy is often not possible due to the late detection of HCC. Thus, it is attractive to find parameters which predict malignant transformation in HBV- and HCV-infected livers. In the past decade, preneoplastic lesions, i.e. dysplastic foci or nodules, have gained interest as possible markers for imminent malignancy. Noteworthy, dysplastic liver lesions are increasingly detected by imaging techniques. We describe here two cases of chronic viral liver disease, one HBV-and one HCV-related, in which dysplastic lesions were present adjacent to HCC. In the HBV case, a (smaller) satellite of HCC was present as well. The neoplastic specimens were investigated by comparative genomic hybridization (CGH) and in situ hybridization (ISH). Both methods revealed multiple genetic alterations in the HCCs. The genetic patterns of the HBV-related HCC and the satellite tumor showed many shared alterations suggesting a clonal relationship. A subset of genetic changes were already present in dysplasias illustrating their preneoplastic nature. Surrounding liver cirrhosis samples did not display chromosomal aberrations. A literature survey illustrates the relative paucity of information concerning genetic alterations in preneoplastic liver lesions. However, all the data strongly suggests a role for liver cell dysplasia as a precursor condition of liver cell cancer.

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Diagnosis of hepatocellular carcinoma: fine needle aspiration cytology or needle core biopsy

Needle core biopsy (NCB) has been the standard procedure for histopathologic diagnosis of hepatic lesions for more than 50 years. In recent years fine needle aspiration cytology (FNAC) has emerged as a minimally invasive, relatively inexpensive and a rapid method of pathologic evaluation of primary or metastatic hepatic masses. The specificity and the positive predictive value of FNAC is very high however, the sensitivity of the procedure widely ranges between 67% to 93%. The two major areas of diagnostic difficulties are differentiation of benign and non-neoplastic hepatic nodules from well differentiated HCC and identification of obviously malignant cells as HCC, cholangiocarcinoma, or metastasis. Preparation of cell blocks, immunohistochemical stains and application of other ancillary techniques are often helpful in difficult cases. In presence of characteristic features a diagnosis of HCC can be established on FNAC however, a negative result does not exclude malignancy. The role of pathologic diagnosis in the assessment of large hepatic masses is well established however, its role in the evaluation of small hepatic nodules (<3 cm) detected during surveillance of high risk patients is still evolving. Considering the overall advantages and cost-analysis, FNAC can be suggested as the initial method of choice for evaluation of hepatic masses in most clinical settings. However, the final choice of the diagnostic procedure should be decided on the basis of working clinical diagnosis and the institutional experience.

Hepatocellular carcinoma: predisposing conditions and precursor lesions

The global incidence of HCC is rising; in the United States, its rise is in parallel to that of cirrhosis due to the HCV and obesity epidemics. The lack of adequate treatment for advanced HCC mandates both prevention and early detection of these lesions. The limitations of currently available histopathologic evaluations, serologic markers, and radiographic imaging modalities in detecting HCC and its precursors have been outlined in this review. Refinements of all of these may lead to better HCC detection, earlier intervention, and successful treatment. Randomized controlled trials are necessary to evaluate the most efficacious and cost-effective approach to screening.

Chromosomal allelic imbalance evolving from liver cirrhosis to hepatocellular carcinoma

BACKGROUND & AIMS

Cirrhotic nodules have long been assumed to be the precancerous lesions of hepatocellular carcinoma (HCC). We thus investigated the allelic imbalance (AI) in cirrhotic nodules to define the genetic aberrations in early hepatocarcinogenesis.

METHODS

One hundred eighty cirrhotic nodules from 7 female patients with HCC were collected by microdissection. Their clonality nature was assessed by examining the X chromosome methylation pattern. AI in monoclonal cirrhotic nodules and the corresponding HCCs were analyzed with microsatellite polymorphic markers.

RESULTS

One hundred one out of 180 nodules (56.1%) were monoclonal and the average fractional AI (FAI) was 21%, lower than the 40% in HCC. Their overall AI patterns differed significantly from that in HCC (P < 0.001) with FAI on 2q, 4q, 8p, and Xq higher than the mean value. Comparison of FAI in nodules (stratified by increasing total AI events) further revealed a progressive increase of FAI on 4q, 8p, and Xq. In contrast, FAI on 1p, 13q, 16q, and 17p were low in nodules but rose above the mean only in HCC.

CONCLUSIONS

About half of the cirrhotic nodules are monoclonal and already have chromosome aberrations. AI on 4q, 8p, and Xq may be the earlier mutations, whereas AI on 1p, 13q, 16q, and 17p occurs late in hepatocarcinogenesis.

Clonal analysis of hepatocellular carcinoma and dysplastic nodule by methylation pattern of X-chromosome-linked human androgen receptor gene

To investigate the monoclonality of hepatocellular carcinoma (HCC) and dysplastic nodule (DN) and the origin of multiple lesions, patterns of inactivation of X-linked human androgen receptor gene were studied. Fourteen of 15 patients (93%) were heterozygous in the size of the target, and were informative for clonal analysis. Monoclonal composition was demonstrated in all 17 HCCs and two DNs, whereas all non-cancerous hepatic tissues were polyclonal. Of four patients with more than two lesions of HCC or DN, two patients had two lesions with different patterns of X-chromosome inactivation, indicating that the two lesions were multicentric in origin.

The clonal origin and clonal evolution of epithelial tumours

While the origin of tumours, whether from one cell or many, has been a source of fascination for experimental oncologists for some time, in recent years there has been a veritable explosion of information about the clonal architecture of tumours and their antecedents, stimulated, in the main, by the ready accessibility of new molecular techniques. While most of these new results have apparently confirmed the monoclonal origin of human epithelial (and other) tumours, there are a significant number of studies in which this conclusion just cannot be made. Moreover, analysis of many articles show that the potential impact of such considerations as patch size and clonal evolution on determinations of clonality have largely been ignored, with the result that a number of these studies are confounded. However, the clonal architecture of preneoplastic lesions provide some interesting insights --many lesions which might have been hitherto regarded as hyperplasias are apparently clonal in derivation. If this is indeed true, it calls into some question our hopeful corollary that a monoclonal origin presages a neoplastic habitus. Finally, it is clear, for many reasons, that methods of analysis which involve the disaggregation of tissues, albeit microdissected, are far from ideal and we should be putting more effort into techniques where the clonal architecture of normal tissues, preneoplastic and preinvasive lesions and their derivative tumours can be directly visualized in situ.

Field cancerization, clonality, and epithelial stem cells: the spread of mutated clones in epithelial sheets

There has been considerable debate about the origin of human tumours, whether they arise from a single cell and are clonal populations or whether there needs to be some sort of co-operativity between cells for the neoplastic process to begin. Current theories subscribe to the clonal view, where a series of mutations in one cell begins a process of selection and clonal evolution leading to the development of the malignant phenotype. This review approaches this problem by asking how mutated clones, once established, spread through tissues before becoming overtly invasive. While there is substantial evidence in favour of independent origins of each tumour from a unique mutated clone, there are instances where such clones expand and remain cohesive, often involving a large area of tissue. The main example is the movement of mutated clonal crypts through the colorectal epithelium, by the process of crypt fission. In passing, the clonal architecture of early, pre-invasive lesions is examined, often with some surprising results.