Over-expression of Id-1 induces cell proliferation in hepatocellular carcinoma through inactivation of p16INK4a/RB pathway
Terence Kin-Wah Lee1,
Kwan Man1,
Ming-Tat Ling2,
Xiang-Hong Wang2,
Yong-Chuan Wong2,
Chung-Mau Lo1,
Ronnie Tung-Ping Poon1,
Irene Oi-Lin Ng3 and
Sheung-Tat Fan1,4
Centre for the Study of Liver Disease and 1 Department of Surgery, 2 Department of Anatomy and 3 Department of Pathology, The University of Hong Kong, Pokfulam, Hong Kong, China
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Abstract
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Inhibitors of differentiation and DNA binding-1 (Id-1) have been demonstrated to oppose Ets-mediated activation of p16INK4a. As p16INK4a protein is inactivated in hepatocellular carcinoma (HCC), we aimed to investigate the role of Id-1 in regulating p16INK4a expression during the development of HCC in HCC patients and direct ectopic Id-1 introduction into the PLC/PRF/5 HCC cell line. Sixty-two HCC samples were recruited for evaluation of Id-1 and proliferating cell nuclear antigen (PCNA) protein expression. The messenger RNA (mRNA) expression of Id-1 and p16INK4a was detected by quantitative reverse transcriptionpolymerase chain reaction. For in vitro Id-1 transfection, five Id-1 transfected clones were isolated and the effect of ectopic Id-1 introduction was investigated by 3-(4,5-cimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide assay, flow cytometry, immunostaining and western blot. Our results showed that Id-1 was over-expressed in HCC specimens both at mRNA and protein levels. Over-expression of Id-1 protein was correlated with PCNA (r = 0.334, P = 0.033). HCC samples showing low Id-1 protein expression had a lower Id-1 mRNA level (340.2 versus 1467%, P = 0.039) and higher p16INK4a expression (195 versus -78.6%, P = 0.039) than samples with high Id-1 protein expression. In the PLC/PRF/5 HCC cell line study, ectopic Id-1 expression resulted in proliferation of HCC cells and an increased percentage of S phase cells and PCNA expression. The results showed that over-expression of Id-1 induces cell proliferation in HCC through inactivation of p16INK4a/retinoblastoma pathway. In conclusion, the results provided an insight for the understanding of the role of Id-1 in functional inactivation of p16INK4a in HCC.
Abbreviations: FBS, fetal bovine serum; HCC, hepatocellular carcinoma; Id, inhibitors of differentiation and DNA binding; mRNA, messenger RNA; MTT, 3-(4,5-cimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide; PCNA, proliferating cell nuclear antigen; PCR, polymerase chain reaction; RB, retinoblastoma; RTPCR, reverse transcription-polymerase chain reaction
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Introduction
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Inhibitor of differentiation and DNA binding (Id) proteins are transcription factors that belong to a group of helixloophelix proteins lacking the DNA binding domain. Therefore, these proteins act as dominant inhibitors of basic helixloophelix transcription factors by forming transcriptionally inactive heterodimers. Four Id genes (Id-1 through Id-4) are important for cell fate decisions of growth and differentiation. Their expression is typically high in actively proliferating cells and is down-regulated as a prerequisite for exit from cell cycle and differentiation (13). The Id family member Id-1 has been implicated in regulating cellular life span, immortalization and delayed senescence in mammalian cells (46). Over-expression of Id-1 has been reported in several types of primary tumors including breast (7), pancreatic (8), prostate (9), cervical (10) and colorectal adenocarcinoma (11). Previous findings showed that ectopic expression of Id-1 induced aggressiveness and metastasis in breast cancer cells (7), and up-regulation of Id-1 has been correlated with tumor stage in squamous cell carcinoma (12). Most recently, over-expression of Id-1 protein has been correlated with patients' poor clinical outcome and mitotic index in several human cancers (10,11). This evidence strongly supports that Id-1 plays an important role not only in tumorigenesis, but also in tumor progression. However, Id-1 expression in hepatocellular carcinoma (HCC) has not been studied and its role remains unknown.
Recently, Id-1 has been demonstrated to oppose Ets-mediated activation of p16INK4a via Ras-Raf-MEK signaling (13). The p16INK4a/retinoblastoma (RB) pathway has been shown to be down-regulated in various human tumors including HCC, either through loss of p16INK4a or RB function, or through down-regulated expression of cyclin D or cdk4 (1416). Several mechanisms of inactivation of p16INK4a/RB pathway have been proposed including promoter methylation, protein sequestration and post-translational modification (17). However, little is known about the direct transcriptional control of genes within the p16INK4a/RB family and their role in HCC tumorigenesis. Therefore, we first examined the Id-1 expression in messenger RNA (mRNA) and protein levels in HCC and then investigated whether Id-1 may play a role in regulating p16INK4a expression during the development of HCC.
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Materials and methods
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Patient samples
Samples were obtained with informed consent from 10 healthy liver transplant donors and 62 patients undergoing hepatectomy for HCC from 1997 to 1999 in the Department of Surgery, University of Hong Kong Medical Centre, Queen Mary Hospital, Hong Kong.
Id-1 and proliferating cell nuclear antigen (PCNA) immunostaining
Formalin-fixed and paraffin-embedded liver sections with a thickness of 4-µm were dewaxed in xylene and graded alcohols, hydrated and washed in phosphate-buffered saline. After pre-treatment in a microwave oven [16 min in sodium citrate buffer (pH 6)], the endogenous peroxidase was inhibited by 0.3% H2O2 for 30 min, and the sections were incubated with 10% normal goat serum for 30 min. A 1:100 diluted polyclonal antibody to Id-1 (Santa Cruz Biotechnology, Santa Cruz, CA) and PCNA (Oncogene Research Products, San Diego, CA) were applied overnight in a moist chamber at 4°C. For negative control, immunohistochemistry was carried out on a HCC specimen with strong Id-1 expression after blocking the antigen-binding site of the primary antibody using corresponding blocking peptide (SC-488p, Santa Cruz Biotechnology) (Figure 1G). A standard avidinbiotin peroxidase technique (DAKO, Carpinteria, CA) was applied. Briefly, biotinylated goat anti-mouse Ig or goat anti-rabbit Ig and avidinbiotin peroxidase complex were applied for 30 min each, with 15-min washes in phosphate-buffered saline. The reaction was finally developed by Dako Liquid DAB+ Substrate-chromogen System (DAKO).

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Fig. 1. Expression of Id-1 in normal liver, non-tumor liver and HCC. Immunostaining analysis showing no Id-1 expression in (A) normal liver, weak Id-1 expression in (B) non-tumorous liver. Differential expression of Id-1 is observed in HCC with (C) absent, (D) weak expression and (E) high expression. Cytoplasmic Id-1 expression at the margin between non-tumor liver and HCC is shown in (F). Negative control of immunohistochemistry for Id-1 on HCC specimen with known strong Id-1 expression. The antigen-binding site of the antibody has been blocked by a specific blocking peptide (G). HCC specimens with absent expression of Id-1 with strong Id-1 expression in tumor vascular endothelia (arrows) (H) (x200 magnification).
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Cytoplasmic expression of Id-1 and nuclear staining of PCNA were determined by two independent observers who assessed semi-quantitatively the percentage of stained tumor cells as well as staining intensity. The percentage of positive cells was rated as follows: 2 points, 1150% positive tumor cells; 3 points, 5180% positive cells; and 4 points, >81% positive cells. Staining intensity was rated as follows (18): 1 point, weak intensity; 2 points, moderate intensity; and 3 points, strong intensity. Points for expression and percentage of positive cells were added, and specimens were attributed to four groups according to their overall scores: negative,
10% of cells stained positive, regardless of intensity; weak expression, 3 points; moderate expression, 45 points; and strong expression, 67 points. Negative to weak Id-1 expression was graded as group 1, which represented low Id-1 expression; whereas moderate to strong Id-1 expression was graded as group 2, which represented high Id-1 expression. Expression of PCNA was also graded as above.
mRNA levels of Id-1 and p16INK4a in HCC by quantitative reverse transcriptionpolymerase chain reaction (RTPCR)
The liver specimen was stored at -80°C until total RNA extraction. The total RNA was extracted using Rneasy Midi Kit (Qiagen Company, GmbH, Germany) and the quality of the total RNA was detected by the spectrophotometer (DU-65, BECKAM, Germany). About 0.5 µg total RNA from each sample was used to perform reverse transcription reaction. Taqman Reverse Transcription Reagents (Applied Biosystem, Foster City, CA) were used according to the manufacturer's instruction (25°C x 10 min, 48°C x 30 min, 95°C x 5 min). Reverse transcription product (1 µl) was used to perform real-time quantitative polymerase chain reaction (PCR) with a reaction volume of 50 µl (TaqMan PCR Core Reagent Kit, Applied Biosystem) by the ABI PRISM 7700 Sequence Detection System (Applied Biosystem). Probes and primers of Id-1 and p16INK4a were designed under the Primer Express software (Applied Biosystem) according to the criteria for real-time PCR. The sequences are listed in Table I. The Taqman Ribosomal RNA Control Reagent [18S RNA probe (VIC) and primers; PE Applied Biosystem] was used for internal control in the same PCR plate well to normalize the target genes amplification copies. The PCR protocol was according to the manufacturer's recommendation [50°C x 2 min, 95°C x 10 min (95°C x 15 s, 60°C x 1 min) x50 cycles]. All the samples were detected in triplicate and the readings from each sample and its internal control were used to calculate the gene expression level. After normalization with the internal control, the gene expression levels in HCC were calculated as the percentage of the levels in normal liver tissue and non-tumor tissue.
Cell line transfection
PLC/PRF/5 was obtained from the Japanese Cancer Research Bank (Tokyo, Japan). The cells were transfected with 2 µg of plasmid DNA of either Id-1 or pcDNA3.1() (kindly provided by Prof. Y.C.Wong of the University of Hong Kong) containing the entire coding of Id-1 or expression vector pcDNA3.1() alone using FuGENE 6 according to the manufacturer's protocol (Boehringer, Mannhein, GmbH, Germany). After 48 h, the medium was replaced with fresh Dulbecco's modified Eagle minimal essential medium with Geneticin (G418) at 1 mg/ml. After 2 weeks of clonal selection, all the clones were grown in the presence of G418 at 0.4 mg/ml to ensure stable transfection. Isolated clones were expanded to 25 cm2 flasks. All the transfected cells used in this experiment were in early passages (passages 48).
3-(4,5-Cimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) assay
PLC/PRF/5 were seeded into 96-well plates in medium containing 10% fetal bovine serum (FBS) and serum free medium replaced the FCS containing medium 24 h after plating. After 48 h, MTT dye, at a concentration of 5 mg/ml (Sigma, St Louis, MO) was added every day and the plates were incubated for 12 h in a moist chamber at 37°C. Optical density was determined by eluting the dye with dimethyl sulfoxide (Sigma), and the absorbance was measured at 570 nm. Three independent experiments were performed.
Cell cycle analysis
Cells (5 x 105) were trypsinized and washed once in PBS. They were then fixed in cold 70% ethanol and stored at 4°C. Before testing, the ethanol was removed and the cells were resuspended in PBS. The fixed cells were then washed with PBS and treated with RNase (1 µg/ml) and stained with propidium iodide (50 µg/ml) for 30 min at 37°C. Cell cycle analysis was performed on an EPICS profile analyzer and analyzed using the ModFit LT2.0 software (Coulter Electronics, Hialeah, FL).
Western blotting
The cells were lysed and protein extraction was performed. The samples were separated in 10% sodium dodecylsulfate acrylamide gel and electrophoretically transferred to PVDF membrane (Amersham, Buckinghamshire, UK). The membrane was blotted with 10% non-fat milk, washed and then probed with Id-1 (1:500, Santa Cruz Biotechnology), CDK4 (1:500, Calbiochem, La Jolla, CA), p16Ink4a (1:500, Santa Cruz Biotechnology) and pRB (1:200, Santa Cruz Biotechnology). After washing, the membrane was then incubated with horseradish peroxidase-conjugated rabbit anti-mouse antibody (Amersham) and then visualized by enhanced chemiluminescense plus according to the manufacturer's protocol.
Statistical analysis
Continuous variables were expressed as median and range. The Mann Whitney U test was used for statistical comparison. The Pearson test was used for bivariate correlation comparison. Significance was defined as P < 0.05. Calculations were made with the help of SPSS computer software (SPSS, Chicago, IL).
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Results
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Expression of Id-1 protein in normal, non-tumor and tumor tissue from human HCC by immunostaining
In order to determine the significance of Id-1 expression in HCC, we evaluated 62 samples of HCC and their corresponding non-tumor tissues by immunostaining. In normal liver, no cytoplasmic expression of Id-1 in hepatocytes was observed (Figure 1A). However, in non-tumor liver (cirrhotic liver or chronic hepatitis), absent to weak cytoplasmic expression of Id-1 was observed (Figure 1B). In HCC samples, cytoplasmic expression of Id-1 was not found in eight cases (12.9%) (Figure 1C), weak in 16 cases (25.8%) (Figure 1D), moderate in 25 cases (40.3%), and strong in 13 cases (20%) (Figure 1E). The margin between non-tumor liver and tumor was shown in Figure 1F. Twenty-four cases were graded as group 1, which represented low Id-1 expression, whereas 38 cases were graded as group 2, which represented high Id-1 expression.
mRNA levels of Id-1 and p16INK4a in normal, non-tumor and tumor tissues by quantitative RTPCR
The mRNA level of Id-1 and its correlation to p16INK4a were examined by quantitative RTPCR. The Id-1mRNA expression in non-tumor and tumor tissues showed higher levels when compared with the normal liver from healthy liver transplant donors. For non-tumor liver, the median level was 192% (range 12.8562%) of normal liver level (100%). There was no significant difference in Id-1 at mRNA level in non-tumor liver between groups 1 and 2 [182.3 (12.8473%) versus 198.7% (74.2562%); P = 0.78]. There was significant difference in Id-1 at mRNA level in tumors between group 1 and group 2 [260 (-828171) versus 1467% (1417313%); P = 0.022] (Figure 2A). As for the mRNA levels of p16INK4a, there was significantly less expression in patients of group 2 than patients of group 1 [194 (-99.946480%) versus -78.6 (-98.964.28%); P = 0.039)] (Figure 2B).

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Fig. 2. Id-1 mRNA level in HCC relative to non-tumor in group 1 (n = 24) and group 2 (n = 38) is shown in (A) while p16INK4a mRNA level in HCC relative to non-tumor liver in group 1 and group 2 is shown in (B).
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Correlation of Id-1 and PCNA in HCC tissues
Id-1 was suggested to play an important role in proliferation. To determine whether over-expression of Id-1 will be correlated with increased proliferation in HCC, we evaluated the expression of Id-1 and a proliferative marker PCNA by immunostaining. All cases showed PCNA immunoreactivity in which it was strong in nine cases (15%), moderate in 31 cases (50%) and weak in 22 cases (35%). Id-1 protein was found to significantly and positively correlate with PCNA expression (r = 0.334, P = 0.033) (Figure 3A and B).

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Fig. 3. Expression of Id-1 and PCNA in samples of HCC patients and PLC/PRF/5 harboring empty vector and Id-1 transfectants. Some HCC specimens show strong cytoplasmic expression of Id-1 (A), and also strongly positive for PCNA (B) in the same specimens. Id-1 expression is positively correlated with PCNA (r = 0.334, P = 0.033) (x200 magnification). In in vitro cell culture model, strong Id-1 expression is observed in (C) Id-1 transfectant (clone 3) when compared with (D) PLC/PRF/5 harboring empty vector. Increased PCNA expression is also observed in (E) Id-1 transfectant (clone 3) when compared with (F) PLC/PRF/5 harboring empty vector.
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Correlation of Id-1 and PCNA in HCC cell line
The effect of Id-1 expression in proliferation was also studied by directly transfecting Id-1 or pCDNA3.1 into PLC/PRF/5. After clonal selection, five clones were isolated. From the in vitro result, clone 3 showed high Id-1 expression when compared with PLC/PRF/5 harboring empty vector (Figure 3C and D). Clone 3 showed increased PCNA expression when compared with PLC/PRF/5 harboring empty vector (Figure 3E and F).
The effect of ectopic Id-1 introduction on HCC cell growth
The effect of FBS on Id-1 expression in PLC/PRF/5 was shown in western blot. In the absence of FBS in the culture medium, the level of Id-1 protein was barely detectable when compared with the presence of FBS in the culture medium (Figure 4A). As shown in Figure 4A, in the absence of FBS, all 5 clones showed different levels of Id-1 expression.

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Fig. 4. Assessment of Id-1, p16INK4a, CDK4, RB and ß-actin (for protein level reference) by western blot in Id-1 transfectants and PLC/PRF/5 harboring empty vector. (A) Id-1 expression in control and Id-1 transfectants after 48 h FBS starving. (B) Decreased p16INK4a expression is found in Id-1 transfectants. (C) Presence of CDK4 phosphorylation in Id-1 transfectants. (D) Presence of RB phosphorylation in Id-1 transfectants but not in PLC/PRF/5-harboring empty vector.
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After transfection of Id-1, PLC/PRF/5 exhibited a relatively different morphology with flatter structure when compared with the parental cell. We evaluated the effect of ectopic Id-1 introduction by MTT assay.
Introduction of Id-1 resulted in increased cell growth when compared with the parental cell and PLC/PRF/5 harboring empty vector (Figure 5). The increase in cell growth was correlated with the level of Id-1 expression.

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Fig. 5. Growth curves of Id-1 transfectants and pCDNA3.1 by MTT assay. Each time point was derived from three independent experiments and the error bars represented standard deviation. Increased growth rate was correlated with the increased Id-1 expression.
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Effect of Id-1 introduction in cell cycle distribution
Next, we studied if Id-1 induced cell growth was a result of its ability to initiate DNA synthesis in HCC cell line in FBS free medium. Cell cycle analysis showed that there was 18% of S phase in the PLC/PRF/5 harboring pCDNA3.1 (control), but the percentage of S phase cells significantly increased (25.137%) in Id-1 transfectants. There was no significant change in the percentage of G2 phase (Figure 6).

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Fig. 6. Cell cycle distribution in cells cultured in serum-free medium for 48 h. Significant increased cell percentages in S phase are observed in Id-1 transfected clones.
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Effect of Id-1 expression in p16INK4a/RB pathway
We have shown that expression of Id-1 was negatively correlated with p16INK4a in HCC samples and positively correlated with increased growth in PLC/PRF/5 in cell culture. To examine whether the increased proliferation was through inactivation of p16INK4a/RB pathway, we evaluated the expression levels of p16INK4a, CDK4 and RB in Id-1 expressing clones and PLC/PRF/5 harboring pCDNA3.1. As shown in Figure 4B, the level of p16INK4a was weak and barely detectable in 5 Id-1 tranfectants and was inversely proportional to ectopic Id-1 expression. This in vitro result confirmed our data from the clinical samples that over-expression of Id-1 correlated with decreased p16INK4a expression. The phosphorylated form of CDK4 (upper band in Figure 4C) was also found in all five Id-1 transfectants and parental cells in the presence of FBS in the culture medium, but not in parental cells in the absence of FBS in the culture medium. Moreover, phosphorylated RB protein expression was also found in all five Id-1 transfectants (Figure 4D).
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Discussion
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In the present study, we first demonstrated that deregulation of Id-1 expression both at the mRNA and protein levels in human HCC, and level of immunohistologically detected protein correlated with levels of Id-1 mRNA. Some reports have found the difference in Id-1 expression level between the mRNA level by RTPCR and protein level by western blot in ovarian cancer tissues and the discrepancy is due to strong expression of Id-1 in tumor vascular endothelia (19). From our immunostaining result, we observed nearly all cases showing positive vascular endothelia staining in both non-tumor and tumor tissue. Some cases with absent Id-1 expression in tumor cells also show strong staining of Id-1 in tumor vascular endothelia. This result is consistent with the previous finding that Id-1 is also strongly expressed in vascular smooth muscle cells (20). However, there is no significant increase in Id-1 expression in tumor vascular endothelia. Evaluation of the whole patients' series revealed several significant associations with histopathological and other features of tumors. Of these, the correlation with mitotic index and p16INK4a were highly significant. We found a positive and significant correlation between the protein expression of Id-1 and PCNA, which indirectly suggested the role of Id-1 in the proliferation of HCC cells. This was further confirmed by our in vitro cell culture model. Increased PCNA expression in clone 3 with the highest ectopic Id-1 expression was also observed when compared with the control in the absence of FBS. Our data further confirmed the function of Id-1 as a promoter of proliferation in cancers (2124). From the RTPCR result, it was also noted that Id-1 mRNA level in the non-tumor liver is relatively high when compared with the normal liver, but it was low when compared with the tumor tissue. Since most of our non-tumor cases are cirrhotic, which has a higher proliferative rate when compared with normal liver (25), it accounts for the enhanced Id-1 expression.
p16INK4a was found to be frequently inactivated in HCC through promoter methylation (16,2628). However, few reports have demonstrated the direct transcriptional inactivation of p16INK4a in HCC. Since the transcriptional regulator Id-1 has recently been identified as a repressor of p16INK4a transcription (13,29,30), we sought to determine whether transcriptional inactivation of p16INK4a by Id-1 might play a role in the initiation and progression of HCC. Recent reports showed that high level of Id-1 expression is correlated with the loss of p16INK4a in early stage melanoma (31), but is positively correlated with the expression of p16INK4a in breast cancer samples (32). In our study, we found that high Id-1 expression was significantly correlated with decreased p16INK4a expression and the result is similar to melanoma. Hypermethylation of p16INK4a within the promoter was suggested to be one of the late events in hepatocarcinogenesis for tumor progression and metastases (33). With reference to the hypothesis by Polsky et al. (31), HCC hepatocarcinogenesis might also occur via multi-step that entails reversible Id-1 transcriptional inactivation of p16INK4a in the early growth phase that allows bypass of cellular senescence, and subsequent acquired epigenetic changes in cells such as promoter methylation for vertical growth phase for later stage. Further study on this subject is required. Conclusively, these results suggested that inactivation of p16INK4a in HCC might be, in part, through transcription control of Id-1.
In order to determine whether Id-1 plays a role in proliferation of HCC through inactivation of p16INK4a, we transfected PLC/PRF/5 by Id-1. Five Id-1 transfectants were isolated and showed differential Id-1 expression. All these five clones showed FBS-independent proliferation accompanied by increased PCNA expression and increased percentage of cell cycle S phase from G1 phase. Our in vitro results were consistent with the previous findings that ectopic Id-1 expression stimulated DNA synthesis from G1 to S phase (7,21,24,28) and resulted in down-regulation of p16INK4a in the Id-1 transfectants. This result further supported that p16INK4a inactivation was due to transcription control of Id-1. Other than p16INK4a, ectopic Id-1 expression induced RB phosphorylation in human keratinocytes (28). One of the functions of p16INK4a is to prevent cyclin-dependent kinases such as CDK4 and results in prevention of RB phosphorylation. In our study, we found that increased expression of phosphorylated CDK4 and RB was only observed in the five Id-1 transfectants but not in the control. This showed that down-regulation of p16INK4a was associated with increased expression of phosphorylated CDK4 and RB but not with CDK and RB levels. RB phosphorylation is proposed to regulate cell cycle regulation from G1 to S phase through cyclin D and CDK4/6 complex. Without the inhibition of p16INK4a, CDK4 becomes phosphorylated and can prevent the binding of E2F with RB, resulting in G1 to S phase conversion by RB phosphorylation (34). In our study, all Id-1 transfectants showed a variable degree of G1 to S phase conversion. Therefore, these results suggested that the effect of Id-1 on proliferation on HCC cells might be caused by the decreased p16INK4a, which in turn inactivated RB.
In summary, our in vitro and in vivo data provided evidence for the first time on over-expression of Id-1 and its role in HCC. Over-expression of Id-1 played a role in HCC cell proliferation. Id-1 induced HCC proliferation through inactivation of p16INK4a/pRB pathway as shown by the evidence of decreased p16INK4a expression and activation of CDK and RB in the five Id-1 transfectants. Our results provided an insight for the understanding of the role of Id-1 in functional inactivation of p16INK4a in HCC.
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Notes
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4 To whom correspondence should be addressed Email: hrmsfst{at}hkucc.hku.hk 
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Received April 25, 2003;
revised July 27, 2003;
accepted August 4, 2003.