Radiol Oncol 2004; 38(3): 205-16.
review
Use of preneoplastic lesions in colon and liver in experimental
oncology
Veronika A. Ehrlich, Wolfgang Huber, Bettina Grasl-Kraupp, Armen Nersesyan,
Siegfried Knasmüller
Institute of Cancer Research, Medical University of Vienna, Austria
The present article gives a brief overview on the use of altered hepatic foci (AHF) and aberrant crypt foci (ACF) in the colon in experimental cancer research. These foci are easily detectable preneoplastic lesions, which have been discovered approximately 30 years ago. AHF and ACF are valuable tools for the detection of cancer - initiating and promoting compounds, and for the detection of chemoprotective agents. They were also successfully used in numerous studies aimed at elucidating the molecular mechanisms of early neoplasia, such as alterations of the expressions of oncogene and tumor suppressor genes, and changes in the activities of cancer associated enzymes.
Key words: preneoplastic lesions; liver neoplasms; colonic neoplasms
Introduction
Preneoplastic lesions are used in experimental research since more than thirty years. They consist of morphologically or functionally altered populations of cells that are precursors of neoplasms. In contrast to long term experiments in which tumor formation is used as an endpoint, they have the advantage that they can be detected after compara-Received 9 July 2004 Accepted 25 July 2004
Correspondence to: Siegfried Knasmüller Institute of Cancer Research, Medical University of Vienna, Borschkegasse 8a, 1090 Vienna, Austria. This paper was presented at the “3rd Conference on Experimental and Translational Oncology”, Kranjska gora, Slovenia, March 18-21, 2004.
tively short time periods (after 2-5 months) and that the number of animals, which are required are relatively small (usually 8-10 animals are used per experimental group). Preneoplastic lesions have been identified in a number of organs, for example in the skin (epidermal dysplasia and hyperplasia, epithelial papillomas), lung (alveolar and focal hy-perplasia, nodular lesions), pancreas (atypical acinar foci), kidney (tubules with irregular epithelium), mammary gland (hyperplastic alveolar nodules) and also in liver and colon (for overview see2). The present article is focused on hepatic altered foci (AHF) and aberrant crypt foci (ACF) in the colon, which have been used extensively in the last years for the detection of carcinogens, for the identification of chemoprotective agents and also in mechanistic studies. It describes their mor-
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A
potential initiator (1x) + partial hepatectomy
known promoter: Phenobarbital/AAF-CCl4
5 months
evaluation
B
known initiator (DENA, NNM, AFB1)
potential promoter
5 months
evaluation
Figure 2A,B. Different treatment schedules for the detection of initiating and promoting carcinogens for experiments in which AHF are used as biological endpoint.
phology and molecular characteristics and their use in the identification of initiating, promoting and protective agents and the development of new techniques.
Altered hepatic foci – morphology and phenotypes
The use of altered hepatic foci started in the 1970’s. In the early years, a classification system was developed, which was based on the staining behaviour and included clear, aci-dophilic, intermediate, tigroid, basophilic and
also mixed cells of AHF.2 In subsequent years, it was shown that the expression of a variety of enzymes of AHF differs from that of the normal tissue, and based on this observations, his-tochemical methods were developed which enable the detection of enzymatically altered AHF (for review see 1). An overview on the different markers is given in the article of Pitot.3 At present, the most widely used endpoint is the expression of the placental form of glu-tathione-S-transferase (GSTp+), which can be detected by immunohistochemistry. About 80% of all foci stained positive for GSTp+.3 Another frequently used marker is ?-glutamyl-transpeptidase. Figure 1 depicts a GSTp+ foci.
Methodological aspects
AHF can be used to detect tumor initiating (Figure 2A) and promoting properties (Figure 2B) of chemicals. To distinguish between these characteristics, the test animals are treated with the compounds according to different schedules.4
Figure 1. A GSTp+ focus. Radiol Oncol 2004; 38(3): 205-16.
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Initiators and promoters of AHF Numerous synthetic and natural compounds have been identified, which either initiate or promote the formation of AHF.4 Typical examples for initiators are nitrosamines (which are the most frequently used carcinogens in mechanistic studies), urethane, aflatoxin B1, heterocyclic aromatic amines, and haloe-thans.5 Also polycyclic aromatic hydrocarbons such as benzo(a)pyrene cause formation of AHF in rats, although the liver is not a target organ for tumor induction of this compound.
Typical examples for compounds which promote the growth of AHF in the liver are barbiturates (phenobarbital etc.), steroid hormones such as dexomethazone and testosterone, hypolipidemic drugs and polychlori-nated biphenyls (for review see4).
Inhibition of foci formation Numerous investigations have been conducted to identify compounds, which prevent the formation of liver foci. These agents were either protective at the initiation level (i.e. when administered before and/or simultaneously with the carcinogen) or at the promotion level (after carcinogen treatment). Examples for anti-initiators are food additives such as buty-lated hydroxyanisole, which protects against AFB16 and butylated hydroxytoluene, which inhibited the foci formation caused by 2-acetyl-aminofluorene.7 Also glucosinolates, contained in cruciferous vegetables were found protective towards AFB1 and cruciferous plants themselves inhibited foci formation induced by the heterocyclic aromatic amine (HAA) IQ.8-13
A number of compounds were identified which prevent the development of foci when administered after the carcinogen treatment. For example acetaminophen and aminophe-nol were protective against formation of foci that had been induced by a nitrosamine in the liver4 and flavonone reduced significantly areas of placental GSTp+ foci induced by afla-
toxin B1 during the phenobarbital- induced promotion step.14
A very interesting observation was made in experiments with rats in which the restriction of dietary calories reduced the number and volume of AHF by 85% in 3 month; food restriction lowered DNA replication but increased apoptosis. When treated with a tumor promoter (nafenopin) after food restriction, only half as many hepatocellular adenomas were found as in animals fed ad libitum throughout their lifetime. The authors concluded that restricted calorie intake preferentially enhances apoptosis of preneoplastic
cells.15
Mechanistic aspects
It is well documented that AHF increase in number and size with continued exposure to both, genotoxic and non-genotoxic carcino-gens.16-18 Some of the phenotypical abnormalities of AHF are stable, however under specific conditions some phenotypical characteristics are lost ("phenotypic reversion").19 In rats, it is well documented that AHF develop by the clonal expansion of individual cells.19 As a result of sustained growth, AHF develop into nodular lesions.20,21 If these nodules are neoplasms, as suggested by some studies,22 AHF truly represent preneoplastic lesions.
A number of studies have been conducted in which the ratio between cell division and programmed cell death during development of liver cancer was investigated. It was shown, that the cell division rates are increased in AHF compared to normal tissue; in adenomas and carcinomas even higher division rates were observed. Also the death rates (apoptosis) increased gradually from normal to preneoplastic to adenoma and carcinoma tissue.23 Further studies showed, that the prenoplastic tissue is more susceptible to stimulation of cell replication and cell death;24,25 and that tumor promoters evidently act as survival factors by inhibiting apoptosis in
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preneoplastic liver cells, thereby stimulating growth of preneoplastic lesions. Interestingly, withdrawal of tumor promoters led to excessive elimination of preneoplastic lesions, whereas normal tissue was less affec-ted.24
New developments
Grasl-Kraupp and coworkers25 developed recently an ex vivo cell culture model, with initiated rat hepatocytes. Following treatment of the rats with a nitrosamine (N-nitrosomor-pholine), hepatocytes were isolated after 22 days (maximal occurrence of GSTp+-cells) and cultivated in vitro. Then the cells were either treated with the mitogen cypoterone acetate or with transforming growth factor (TGF-ß) for 1-3 days. In culture, the rate of DNA-repli-cation of GSTp+-cells was compared to that of normal hepatocytes. It was found, that GSTp+-cells show an inherent growth advantage and a preferential response towards the
effects of TGF-ß and cypoterone acetate as in the in vivo situation. Based on these results, the authors stress that this ex vivo system may provide a useful tool to elucidate biological and molecular changes during the initiation stage of carcinogenesis.
Aberrant crypts in the colon – morphology
In 198727, Bird discovered that the treatment of rats with a colon carcinogen (dimethylhy-drazine, DMH) leads to formation of morphologically aberrant foci, which can be visualized with methylene blue stain. ACF consist of altered cells, which exhibit cytoplasmic ba-sophilia, a high nuclear to cytoplasmic ratio, prominent nucleoli, loss of globlet cells, loss of polarity, and in the upper part of the crypt they exhibit increased proliferative activity.28 Figure 3A and 3B depict typical aberrant crypts, which are abnormally large, darkly
Table 1. Biochemical and immunohistochemical alterations of ACF.30,33-42
Endpoint	Comment	Reference
Hexosaminidase increased	gene closely located to the APC gene	Boland et al., 1992
	95% of ACF in rats stain positive,	Pretlow et al., 1993
	not a marker for human ACF	
Carcinoembryonic antigen	intracellular adhesion molecule in human ACF	Pretlow et al., 1994
(CEA)	altered (93%) but not a marker for dysplasia	
P-Cadherin	cell adhesion molecules P-c expressed in ACF	Hardy et al., 2002
E-Cadherin	prior to and independent from E-c and ß-catenin	
ß-Catenin	transcriptional activator in ACF nuclear expression increased (see also chapter: development for new markers)	Hao et al., 2001
Inducible nitric oxide	increased in dysplastic but not in	Takahashi et al., 2000
synthase (iNOS)	hyperplastic ACF	
Cyclooxygenase 2 (COX-2)	overexpression in ACF	Takahashi et al., 2000
Cell proliferation markers	several studies show altered patterns in ACF	Renehan et al., 2002
Ki-67, proliferating cell		Cheng et al., 2003
nuclear antigen (PNCA)		
P16INK4a		
Placental form of GST	might be associated in humans with K-ras expression, induced in human ACF and CRC	Miyanishi et al., 2001
Changes in mucin production	alteration of mucin-patterns seen in ACF in	Uchida et al., 2001
	rats and in humans	Bara et al., 2003
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Figure 3A,B. A- An aberrant crypt focus with a high level of dysplasia , which is microscopically elevated with a slit-shaped luminal opening. B- A crypt with oval openings. A GSTp+ focus.
staining and slightly elevated. Dysplastic crypts with a slit-shaped luminal opening are shown in Figure 3A; Figure 3B depicts non-dysplastic crypts with a larger pericryptical
zone.29
ACF show variable features – ranking from mild hyperplasia to dysplasia, and are generally divided into three groups, namely dys-plastic, non-dysplastic (atypic) and mixed type (for details see30). In ACF without dys-plasia, the crypts are enlarged (up to 1,5-fold) and have slightly enhanced nuclei, no mucin depletion and crypt cells staining positive for PNCA and Ki-67 remain in the lower part of the crypts. In ACF with dysplasia, crypts are more elongated, and the nuclei enlarged. PN-CA and Ki-67 stain is extended to the upper
Table 2. Epigenetic and genetic alterations in ACF.43-50
part of the crypts. Mixed type ACF show combinations of the features of pure adenomatous pattern (with dysplasia) and hyperplastic characteristics.
In humans, ACF were first described in 1991.31,32 They resemble those seen in rodents induced by carcinogens27 and several lines of evidence support the assumption that they are precursors of colorectal tumors (for details see Cheng et al.).30
Biochemical and immunohistochemical alterations of ACF
A number of biochemical alterations are typical for ACF. The most important features are listed in Table 1.
Alteration	Remarks	Reference
K-ras mutation	in ACF in rats, identified in many studies	Stopera et al., 1992
	also in humans	Losi et al., 1996
APC mutation	deleted in human ACF – but lower rates as in	Smith et al., 1994
	adenomas/carcinomas	Nascimbeni et al., 1999
hMSH2 mutation	mismatch repair gene alteration in ACF in mice colons	Reitmair et al., 1996
CpG island methylation	in 53% of ACF of humans with sporadic CRC but only in 11% of FAP patients	Chan et al., 2002
Microsatellite instability	detected in animal models and in humans in ACF	Augenlicht et al., 1996
Fragile histidine triad	lost in CRC (40%) – only few ACF showed	Hao et al., 2000
(FHIT) candidate tumor	reduced expression; the loss correlated with	
suppressor gene	the extent of dysplasia	
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Table 3. Compounds, which act as tumor promotors in the colon and cause increased formation of ACF.58-66
Compound                                 Result                                                                           Reference
Thermolysed protein                 increasing thermolysis of casein                                Zhang et al., 1992
increases AOM induced foci numbers and size Thermolysed sucrose                increases the size of AOM induced foci                     Zhang et al., 1993
(5-hydroxymethyl-                     weakly initiating carcinogens
2-furaldehyde) Fat (beef tallow)                        AOM experiments with mice:increases 3-5 times     Corpet et al., 1990
the size of chemically induced foci Refined sugars                           increased formation of AOM induced foci                Stamp et al., 1993
(sucrose, fructose, dextrin)       sucrose and dextrin enhance no. of AOM                 Poulsen et al., 2001
induced foci in rats Progastrin (PG)                          ACF significantly more common in AOM                 Cobb et al., 2004
treated mice overexpressing PG Haemoglobin, haemin               especially haemin but also haemoglobin were          Pierre et al., 2003
potent ACF promoters in AOM treated rats,
when fed a low-calcium diet Chenodeoxycholic                     AOM induced foci as well as crypt multiplicity        Ghia et al., 1996
acid (CDCA)                              significantly increased in rats                                     Sutherland et al.,1994
Genetic and epigenetic alterations Different genetic alterations have been identified in ACF in humans and also in chemically induced ACF in rats; a detailed overview is given in the article of Cheng et al.30 Many genes, which are considered to be involved in colon carcinogenesis, were found to be altered in ACF; this supports the assumption that they (ACF or specific subpopulations) represent indeed preneoplastic lesions. Table 2 lists up different alterations which were identified in ACF.
Methodological aspects
As in AHF-experiments, ACF-studies allow to discriminate between initiating and promoting compounds. The treatment schedule is more or less identical as that used for the detection of liver foci, but other model chemicals are used.
Only a few compounds have been detected, which are initiators of colon cancer and aberrant crypts. The most frequently used agents are DMH and its metabolite azoxy-methane (AOM).51 Both compounds lead to DNA methylation and to formation of ACF,
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which become apparent5-7 weeks after the ad-ministration.52 Also heterocyclic aromatic amines (HAs), which are found in fried meat cause formation of ACF28,53,54 and were used in a number of chemoprevention studies (for review see Dashwood55 and Schwab et al.56). Other agents which cause ACF are N-methyl-N-nitrosurea (MNU) and 3,2-dimethyl-4-aminobiphenyl (DMABP), but these compounds were hardly ever used in mechanistic and chemoprevention studies.57
Use of the ACF-model to detect factors which act as tumor promoters in the colon The ACF-model was intensely used in studies aimed at detecting dietary factors which cause tumor promotion in the colon. Table 3 lists up a number of studies.
Use of the ACF-model for the detection of chemo-protective compounds
Numerous studies have been conducted aimed at identifying compounds which are protective towards colon cancer with the ACF model. Recently, Corpet and Tache57 have published a review on this topic. They
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found in total 137 articles and results for about 186 complex mixtures and individual compounds are available (the data can be downloaded from: http://www.inra.fr/re-seau-nacre/sci-memb/corpet/indexan.html). The establishment of a ranking order of protective potency showed, that the most potent were pluronic, polyethylene glycol, perilla oil containing ß-carotene and indole-3-carbinol (for details see57). In addition, many other dietary constituents were found protective, for example vitamins, lactobacilli in fermented foods, different glucosinolates in Brassica vegetables, carotinoids and fibers to name only a few.57
In most of the studies, DMH or AOM were used to cause foci formation and the putative protective compounds were added either before or after administration of the carcinogen. The prevention during the foci “initiation” phase might be either due to inactivation of DNA-reactive molecules, inhibition of metabolic activation or induction of DNA-repair processes67 and is compound specific. Since humans are not exposed to DMH and its metabolite AOM, chemoprotective effects seen in such experiments cannot be extrapolated to the human situation. On the other hand, it is assumed that the further development of preneoplastic cells (promotion, progression) is triggered by molecular processes which are independent from the chemical carcinogen used.68 Therefore antipromoting effects seen in the AOM/DMH ACF model might be considered relevant for humans.
HAs are formed during cooking of meats.69 They cause cancer in the colon of rodents, and in other organs as well70 and evidence is accumulating that HAs are involved in the etiology of colon cancer in humans.71 HAs were used in a number of chemopreven-tion studies in which inhibition of ACF formation was used as an endpoint55,56, and a number of dietary components such as fibers, chlorophyllins, Brassica vegetables and lacto-bacilli were found protective. In this context
it is interesting that epidemiological studies indicate that consumption of these factors is also inversely related with the incidence of colon cancer in humans.
One of the problems of the use of HAs in ACF studies is that the foci yield is relatively low, even when the animals are treated with high doses (up to 100 mg/d for several days). The foci frequency could be substantially increased by feeding the animals a high fat and fiber free diet, which facilitates the detection of putative protective effects.72 In contrast to AOM or DMH it is not possible to induce ACF with a single HA-dose, therefore it is not possible to distinguish clearly between anti-initiating and anti-promoting effects in these experiments.
Corpet and Pierre51 published an article on the correlation between the results of chemo-prevention studies using ACF as an endpoint, and data from experiments with the ApcMin/+ mouse model (these animals have a mutated Apc-gene and therefore highly increased rates of intestinal spontaneous tumors, and are often used as a model for human hereditary colon cancer). Comparison of the efficacy of protective agents in the ApcMin/+ mouse and in the ACF rat model showed a significant correlation (p<0,001). Furthermore, the authors also compared the results of rodent studies with clinical intervention studies. For a number of compounds, which were protective in the animal models, also chemopreven-tive properties were seen in humans.
New developments
Although numerous studies show that ACF detect colon carcinogens and have been used extensively for the identification of dietary factors enhancing or reducing the risk for colorectal cancer, some results suggest that misleading results may be obtained with certain compounds.73 For example it is well documented that cholic acid, a primary bile acid, is a strong tumor promoter in the colon, whereas it significantly decreases the number of
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ACF.74,75 A similar contradiction was seen with the xenoestrogen genistein.76-78
It was repeatedly postulated by Japanese groups79-82 that ß-catenin acculmulating crypts (BCAC), which are independent from ACF, are more reliable biomarkers for colon cancer development. They show that cholic acid increases the frequency of AOM-induced BCAC in rats. In a critical comment of Pretlow and Bird83 it is stated that BCAC represent in fact specific dysplastic ACF. In a subsequent paper of Hao et al.37, human ACF were analyzed for ß-catenin expression and in approximately 56% of dysplastic ACF, cy-toplastic ß-catenin was increased, whereas in ACF with atypia, ß-catenin in the cytoplasm was only seen in 2% of the total number.
As mentioned above, Magnuson and coworkers74 also found that the number of ACF at early time points did not predict tumor incidence in rats treated with cholic acid. Therefore the authors suggest that crypt multiplicity should be measured in future studies, due to the fact that it was a consistent predictor of tumor outcome in their study.
Another potential short-term endpoint for colon cancer might be mucin-depleted foci (MDF). In AOM-treated rats such foci could be visualised with high-iron diamine Albicon blue.84 Their frequency was lower than that of ACF and they were histological more dys-plastic than mucinous ACF. In a recent article, it was shown that the number of MDF-fo-ci declined in AOM treated rats, after piroxi-cam (a colon cancer inhibiting drug) administration, whereas their frequency increased after treatment with cholic acid.84
Conclusions
In the last years, highly effective molecular techniques (e.g. microarray based methods) have been developed, which can be employed to elucidate the mechanisms of carcinogene-sis. These approaches can be used to analyze
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gene expression patterns in vitro in cell culture models, and also in tumors and can be compared with histological endpoints related to neoplasia. The predictive values of results obtained in in vitro models is often restricted, since the indicator cells which are used lack often characteristic features which are important for the in vivo situation. Typical examples are chemoprevention studies in which metabolically incompetent cell lines may give misleading results, as they do not reflect the activation/detoxification of DNA-reactive carcinogens.85 On the other hand, the use of tumor formation in animal experiments as endpoints is hampered by the high costs and the time requirement and in case of human studies additionally by the limited availability of material. These shortcomings underline the value of preneoplastic foci models, which represent early stages of the neoplastic process. It has been shown that many compounds, considered as human carcinogens, can be detected with these models in rodents and also that protective agents which were identified in such foci experiments prevent specific forms of cancer in humans. Furthermore, the foci models are also useful to monitor the time course of biochemical and genetic alterations in neoplasia. On the basis of the important information created by the use of these foci models, it is likely that they will be also important tools in future research activities.
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