Prognostic Model for the Risk Stratification of Early and Late Recurrence in Hepatitis B Virus-Related Small Hepatocellular Carcinoma Patients with Global Histone Modifications.

BACKGROUND AND AIM: To assess the profile of global histone modifications in small hepatocellular carcinoma (small HCC) and identify its prognostic value in predicting recurrence.
METHODS: The expression profiles of global histone modifications, including H2AK5AC, H2BK20AC, H3K4me2, H3K9AC, H3K18AC, H4K12AC, and H4R3me2, were evaluated with immunohistochemistry in 335 HBV related small HCC patients. Two histone signature classifiers were then developed using least absolute shrinkage and selection operator Cox regression. A nomogram was built using the classifier and independent risk factors. The performances of the classifier and nomogram were assessed by receiver operating characteristic curves.
RESULTS: Histone modifications were more pronounced in tumor tissues than in adjacent liver tissues. In tumor tissues, the risk score built based on the seven-histone signature exhibited satisfactory prediction efficiency, with an AUC = 0.71 (0.63-0.79) for 2-year survival in the training cohort. Patients with a high risk score had shorter recurrence-free survival than those with a low risk score (HR: 1.96, 95% CI: 1.24-3.08, p = 0.004; HR: 1.95, 95% CI: 1.12-3.42, p = 0.019; and HR: 1.97, 95% CI: 1.39-2.80, p < 0.001 for the training, validation and total cohorts, respectively). Furthermore, the statistical nomogram built using the histone classifier for early recurrence had a C-index = 0.68. In non-neoplastic liver tissues, the hepatic signature based on H3K4me2 and H4R3me2 was related to late recurrence (HR: 2.00, 95% CI: 1.15-3.48, p = 0.01).
CONCLUSION: Global histone modifications in tumor and adjacent liver tissues are novel predictors of early and late recurrence, respectively, in HBV-related small HCC patients.

Introduction

Hepatocellular carcinoma (HCC) is the fourth most common cause of cancer-related death worldwide, with an incidence of approximately 850,000 new cases per year.1,2 Chronic HBV and HCV infections are the most important causes of HCC and account for 80% of HCC cases globally.3 Over the past decades, the surveillance of at-risk populations along with the development of imaging techniques has contributed to the stably increasing detection of early-stage HCC, particularly small HCC (≤ 3 cm).4 The diagnosis of small HCC allows patients to undergo potentially curative treatments, such as surgical resection and ablation.5 Unfortunately, the surgical outcomes of small HCC patients remain unsatisfactory because of the high rates of tumor recurrence, including early recurrence (≤ 2 years after resection) and late recurrence (> 2 years after resection). At present, for small HCC, 25–30% of patients experience early recurrence,6–8 and the 10-year recurrence-free survival (RFS) rate is only 22%, which is the main contributor to the 35% 10-year overall survival rate.9 Therefore, it is necessary to identify small HCC patients with a high risk of recurrence to provide earlier intervention.

Over the last two decades, various prognostic systems have been proposed to address the inter-relationship of prognostic factors among HCC patients and the complexity of HCC. The Barcelona Clinic Liver Cancer (BCLC) staging system is a crucial prognostic system for HCC patients and is widely used in clinical practice. However, the outcomes vary within the same stage, suggesting that the current systems, which mainly depend on clinicopathologic factors, inadequately reflect the biological heterogeneity of HCC, particularly small HCC. Thus, the development of a novel comprehensive prognostic system that combines biomarkers for clinical practice is crucial.

Tumors are not only genetic diseases but also epigenetic diseases.10 Epigenetic alterations in cancer comprise genome-wide and locus-specific changes in DNA methylation and posttranslational histone modifications, which influence chromatin accessibility and gene activity without changing the DNA sequence.11,12 The reversible posttranslational modifications of histones, such as lysine acetylation, lysine methylation, and arginine methylation, are modified by chromatin-modifying enzymes. Previous studies have shown that overexpression of the writer EZH2, the protein that catalyzes repressive histone H3 lysine 27 trimethylation (H3K27me3), is significantly related to an aggressive biology and unfavorable prognosis in HCC.13–16 Global histone modifications have been a focus on biomarker development as effective predictors of clinical prognosis and treatment strategies in prostate, intestinal, pancreatic, and lung cancers.17–20 Seligson et al first reported that, in combination with histone 3 lysine 18 acetylation (H3K18AC), histone 3 lysine 9 acetylation (H3K9AC), histone 3 lysine 4 dimethylation (H3K4me2), histone 4 lysine 12 acetylation (H4K12AC) and histone 4 arginine 3 dimethylation (H4R3me2), these changes indicated the risk of tumor recurrence in patients with low-grade prostate cancer.17 Multiple histones, H3K4me2, histone 2A lysine 5 acetylation (H2AK5AC), histone 2B lysine 12 acetylation (H2BK12AC), H3K9AC, and histone 4 lysine 8 acetylation (H4K8AC), were further analyzed by Barlési et al, who found that evaluating selected changes may help to select early-stage NSCLC patients for adjuvant treatment.18 However, the implication of these global histone modifications in HCC, particularly HBV related small HCC, is poorly understood.

In the present study, we used immunohistochemistry to evaluate the levels of the abovementioned factors (H2AK5AC, H3K4me2, H3K9AC, H3K18AC, H4K12AC, and H4R3me2) in addition to histone 2B lysine 20 acetylation (H2BK20AC) to clarify the prognostic value of global histone modifications in predicting recurrence in HBV related small HCC patients and to establish an effective prognostic classifier for predicting relapse with a practical and quantitative nomogram.

Methods

Study Population

The Institutional Medical Ethics Committee of Sun Yat-Sen University Cancer Center (SYSUCC) approved the present retrospective study (approval number: YB2017-026) and the study was informed in accordance with Declaration of Helsinki. Written informed consent was obtained from the patients before the study began. Pathologically confirmed, nonmetastatic small HCC samples were collected from the SYSUCC between 1998 and 2010. The inclusion criteria were as follows: (1) solitary small HCC (≤3 cm); (2) the presence of HBV surface antigens; (3) primary and curative resection; (4) no metastatic or residual disease; (5) no preoperative adjuvant therapy; and (6) complete clinical information and follow-up data. All the cases included in this study were diagnosed by experienced pathologists. Tumor grades were determined following the criteria of the Edmondson-Steiner grading system. Patients with unknown causes of death were excluded.

Follow-Up and Outcomes

The evaluation and management approaches employed before surgical resection were previously described. After curative partial hepatectomy, the patients were examined using abdominal ultrasonography, chest radiography, laboratory tests and serum AFP analysis. These assessments were performed 1 month after resection and then generally in 3-month intervals in the first 2 years and every 3–6 months in subsequent years until tumor recurrence was documented. For patients in whom tumor recurrence was suspected, further tests, including computed tomography (CT) and magnetic resonance imaging (MRI), were performed, and biopsies were employed if necessary. Patients with confirmed recurrence underwent appropriate further treatment.

RFS was defined as the time from the date of surgery to the date of first tumor recurrence (local or distant metastasis identified by imaging and pathology). Cancer-specific overall survival (OS) was defined as the time from the date of surgery to the date of death as a result of HCC.

Tissue Microarray and Immunohistochemistry

Tissue microarrays (TMAs) were assembled in accordance with our previous methodology.21 Triplicate 0.6-mm diameter cylindrical areas were punched from representative regions of an individual donor tissue block and re-embedded into a recipient paraffin block in a defined position using a tissue arraying instrument (Beecher Instruments, Silver Spring, MD).

A standard, two-step, indirect immunohistochemical staining method was used as previously described.14 The histone modification markers employed in this report were selected based on previous studies showing that the modifications were applicable in other carcinomas.17,18 The following primary antibodies were applied for 60 minutes at room temperature: rabbit anti-histone polyclonal antibodies against H2AK5AC, H2BK20AC, H3K4me2, H3K9AC, H3K18AC, and H4K12AC (Cell Signaling Technology, Beverly, MA, USA; 1:100 dilution) and a rabbit monoclonal anti-H4R3me2 antibody (Abcam, Cambridge, MA; 1:200 dilution). Positive and negative control samples were included on each slide. All antibody-related information is shown in . Semiquantitative assessments for histone modifications were scored by the percentage of tumor cells with positive nuclear staining over the total number of tumor cells from three cylinders (0.6 mm diameter/cylinder) of each case. Scores were assigned by using 5% increments (0%, 5%, 10% … 100%). The evaluations were performed independently by two experienced pathologists (M-Y Cai and R.-Z. Luo), who were blinded to all clinicopathologic and outcome variables. Individual scores were averaged; in cases of a difference of more than 20%, a third pathologist (D Xie) was consulted and provided a score. The final score was determined by the average based on the assessments of the three pathologists.

Histone Modification Risk-Score Classifier and Nomogram

A stratified randomization approach via the “resample” package was used to divide the small HCC dataset into training and validation cohorts at a ratio of 6:4 to construct and validate the histone risk score. After overviewing the density distribution of each histone modification, further relative stratification into high expression and low expression revealed two subgroups of patients within each modification. The cut-off value of each histone modification marker to predict survival was determined with the “survminer” package. The cut-off scores generated with the training cohort were applied to the validation and total cohorts.

The Cox proportional hazards model with LASSO regression (“glmnet” package) was applied to construct the histone risk score, which was broadly applied for high-dimensional and sample-limited data.22,23 The optimal values of the penalty parameter λ were determined by 200-fold cross-validation using the minimum criteria on the training dataset. Time-dependent receiver operating characteristic (tdROC) curves and areas under the curves (AUCs) were generated using the “survivalROC” package to assess prognostic accuracy.24 Patients were grouped into high-risk-score and low-risk-score groups based on the cut-off, which was the median value of the training cohort.

The visual nomogram for recurrence was formulated by using the independent risk factors identified in the multivariate Cox regression analysis. Calibration was evaluated with the calibration plot. The discrimination ability of the nomogram was assessed by tdROC analysis. Moreover, decision curve analysis (DCA) with the stdca function was performed to evaluate the improvement in clinical decision making.

Statistical Analysis

One-way ANOVA and chi-square tests were used to assess differences in continuous and categorical variables, respectively. Pearson’s correlation test was applied to quantify linear correlations among the histone modifications. The Kaplan–Meier method with the Log rank test was employed to estimate the survival rates. The Cox regression model was utilized for multivariate survival analysis. All statistical analyses were performed using R version 3.6.1 (R Foundation for Statistical Computing, Vienna, Austria, ). All statistical tests were two-sided, and p values less than 0.05 were considered significant. All data in our study have been recorded at Sun Yat-sen University Cancer Center with a Research Data Deposit (RDD) number of RDDB2021001160.

Results

Characteristics of the Small HCC Cohort and Global Histone Modifications

The baseline characteristics of the small HCC patients in this study are summarized in Table 1. A total of 335 patients were enrolled in our study, including 295 males and 40 females, with a median age of 49 years (range, 26–78 years). With a median follow-up time of 49 months (interquartile range, 36–67 months), 131 (39.1%) patients developed recurrence, and 62 (18.5%) died. The 1-, 2-, and 5-year OS and RFS rates in the total cohort were 97.9%, 93.9% and 77.7%, and 89.3%, 76.4% and 59.9%, respectively.

Table 1

Characteristics of Small HCC Patients in the Training, Validation and Total Cohorts

Characteristic	Training Cohort N = 202 (%)	Validation Cohort N = 133 (%)	Total Cohort N = 335 (%)
Gender
Male	172 (85.1)	123 (92.5)	295 (88.1)
Female	30 (14.9)	10 (7.5)	40 (11.9)
Age, years
<60	173 (85.6)	108 (81.2)	281 (83.9)
≥60	29 (14.4)	25 (18.8)	54 (16.1)
ALT, U/L
<41	117 (57.9)	80 (60.2)	197 (58.8)
≥41	85 (42.1)	53 (39.8)	138 (41.2)
AFP, ng/mL
<400	146 (72.3)	95 (71.4)	241 (71.9)
≥400	56 (27.7)	38 (28.6)	94 (28.1)
Tumor size, cm
<2	108 (53.5)	80 (60.2)	188 (56.1)
≥2	94 (46.5)	53 (39.8)	147 (43.9)
Edmonson grade
I	38 (18.8)	18 (13.5)	56 (16.7)
II	120 (59.4)	88 (66.2)	208 (62.1)
III	38 (18.8)	25 (18.8)	63 (18.8)
IV	6 (3.0)	2 (1.5)	8 (2.4)
Vascular invasion
No	158 (78.2)	97 (72.9)	255 (76.1)
Yes	44 (21.8)	36 (27.1)	80 (23.9)
Cirrhosis
No	130 (64.4)	71 (53.4)	201 (60.0)
Yes	72 (35.6)	62 (46.6)	134 (40.0)
Envelope
No	126 (62.4)	88 (66.2)	214 (63.9)
Yes	76 (37.6)	45 (33.8)	121 (36.1)
Necrosis
No	104 (51.5)	74 (55.6)	178 (53.1)
Yes	98 (48.5)	59 (44.4)	157 (46.9)
HBeAg
Negative	164 (81.2)	113 (85.0)	277 (82.7)
Positive	38 (18.8)	20 (15.0)	58 (17.3)
HBV DNA, copies/mL
<1000	72 (35.6)	44 (33.1)	116 (34.6)
≥1000	101 (50.0)	71 (53.4)	172 (51.4)
Unmeasured	29 (14.4)	18 (13.5)	47 (14.0)
Recurrence
No	123 (60.9)	81 (60.9)	204 (60.9)
Yes	79 (39.1)	52 (39.1)	131 (39.1)
RFS, % (95% CI)
1-year	90.6 (86.5–94.7)	86.5 (80.6–92.4)	89.3 (86.0–92.6)
2-year	76.7 (70.8–82.6)	75.9 (68.6–83.2)	76.4 (71.9–80.9)
5-year	60.3 (52.7–67.9)	59.3 (50.1–68.5)	59.9 (54.0–65.8)
OS, % (95% CI)
1-year	99.0 (97.6–100.0)	96.2 (92.9–99.5)	97.9 (96.3–99.5)
2-year	94.0 (90.7–97.3)	93.9 (89.8–98.0)	93.9 (91.4–96.4)
5-year	77.8 (70.7–84.9)	77.7 (68.7–86.7)	77.7 (72.0–83.4)

Abbreviations: ALT, glutamic pyruvic transaminase; AFP, alpha-fetoprotein; CI, confidence interval; OS, overall survival; RFS, recurrence-free survival.

To determine the global levels of histone modifications, we referred to previous studies and selected H2AK5AC, H2BK20AC, H3K4me2, H3K9AC, H3K18AC, H4K12AC and H4R3me2 to further investigate in small HCC. Both primary small HCC and paired non-neoplastic liver tissues were stained with specific antibodies. Semiquantitative assessments of the percentage of tumor cells with positive nuclear staining over total tumor cells (range, 0% to 100% using 5% increments) in three fields were performed, and individual scores were averaged. Representative images of staining for these markers showed clear and distinguishable brown staining of histones in the nucleus (Figure 1A), and the density distribution of each histone modification is shown in . Compared to those in paired non-neoplastic liver tissues, all modifications except for H4R3me2 showed significantly stronger staining in tumor tissues (Figure 1B, all for p < 0.01). Interestingly, different histone modifications were found to correlate within tumor (r, 0.16–0.56) or non-neoplastic liver tissues (r, 0.19–0.51), which might be consistent with the existence of combinatorial patterns of histone modifications.25 However, only weak correlations were found between clinicopathologic characteristics and histone modifications (Figure 1C).

Figure 1

Expression of histone modifications in small HCC and construction of the histone risk score model. (A) Representative images of histone modifications at 40x or 20x (inset) in small HCC tissues with clear and brown staining in the nucleus. (B) Bar charts of histone modification levels in tumor and paired non-neoplastic liver tissues. (C) Hierarchical clustering presented the correlations among variables. The color intensity and size of the circle are proportional to the correlation coefficients (R value). The correlations of variables only with statistical significance (p≤0.05) were showed as circle. (D) LASSO coefficient of the histone modifications in tumor tissues. A vertical line was drawn at the value chosen by 200-fold cross-validation. (E) Cross-validation for variable selection with LASSO regression. ***p<0.001.

Risk Score Classifier Based on Global Histone Modifications in Small HCC

To eliminate collinearity among factors, Cox regression with the LASSO model was performed to construct a histone modification classifier: the histone risk score (Figure 1D and E). The formula of the classifier was derived based on the histone modification features in the training cohort with small HCC, and seven modifications were included after filtering. The histone risk score was generated as follows: (0.195 × scales of H2AK5AC) + (0.167 × scales of H2BK20AC) – (0.733 × scales of H3K4me2) + (0.086 × scales of H3K9AC) + (0.155 × scales of H3K18AC) + (0.403 × scales of H4K12AC) – (0.298 × scales of H4R3me2).

To assess the predictive value of the histone risk score, a tdROC curve was created. As shown in Figure 2A, the AUCs of the risk score in the training cohort at 1 year, 2 years and 3 years were 0.65 (0.52–0.77), 0.71 (0.63–0.79) and 0.68 (0.60–0.77), respectively. The AUCs in the validation cohort were 0.69 (0.57–0.81), 0.58 (0.5–0.68) and 0.63 (0.52–0.73), and those in the total cohort were 0.67 (0.58–0.75), 0.66 (0.59–0.72) and 0.66 (0.60–0.73), respectively.

Figure 2

Relationship between the histone risk score and recurrence-free survival of small HCC patients. (A) tdROC curve according to the histone risk score in the training, validation and total cohorts. (B) RFS of the high risk score and low risk score subgroups in the training, validation and total cohorts. The HR and p-value were calculated with univariate Cox regression analysis and the Log rank test, and all statistical tests were two-sided.

High- and low-risk-score groups were divided by the median risk score from the training cohort, and the distribution of clinical characteristics did not vary significantly between the two subgroups (). In the training cohort, the high-risk group showed a worse RFS than the low-risk group (HR: 1.96; 95% CI: 1.24–3.08; p = 0.004; Figure 2B). Similar results were obtained in the validation cohort (HR: 1.95; 95% CI: 1.12–3.42; p = 0.019; Figure 2B) and the total cohort (HR: 1.97; 95% CI: 1.39–2.80; p < 0.001; Figure 2B). Additionally, a high risk score indicated significantly worse overall survival in the three cohorts ().

Intriguingly, compared with the low-score group, the high-score group had more early recurrences (Figure 3A). The two-year RFS rates of the high-score group and low-score group were 84.5% vs 67.2% (p = 0.001) in the training cohort, 79.6% vs 71.9% in the validation cohort (p = 0.21), and 82.7% vs 69.2% in the total cohort (p < 0.001) (Figure 3B). Furthermore, the histone risk score of those with early recurrence was evidently higher than that of those without recurrence (; p < 0.01 for the total cohort). The prognostic value of the classifier for early recurrence was evaluated by ROC curve analysis (). These results indicated that the histone risk score could effectively predict recurrence and even early recurrence in patients with small HCC.

Figure 3

Predictive value of the histone risk score for the early recurrence of small HCC. (A) Waterfall plots for the distribution of the risk score and status of early recurrence. (B) Kaplan–Meier analysis of early recurrence based on the histone risk score in the training, validation and total cohorts.

Histone Modification Risk Score as an Independent Prognostic Factor

In the unadjusted analysis, the following were revealed as prognostic factors for poor RFS: advanced pathologic grade, tumor size larger than 2 cm, the presence of vascular invasion, tumor necrosis, and a high histone modification risk score (Table 2). The 1-, 2-, and 5-year RFS rates of the high- and low-risk groups were 84.6% vs 92.7%, 69.2% vs 82.7%, and 50.6% vs 68.0% (HR: 1.97; 95% CI: 1.39–2.80; p < 0.001).

Table 2

Univariate and Multivariate Analyses for Recurrence-Free Survival

Covariate	Univariate Analysis		Multivariate Analysis
	HR (95% CI)	p-value	HR (95% CI)	p-value
H2AK5AC	1.50 (1.05–2.13)	0.025	–	–
H2BK20AC	1.37 (0.93–2.01)	0.108	–	–
H3K4me2	0.52 (0.34–0.81)	0.004	–	–
H3K9AC	1.23 (0.86–1.78)	0.259	–	–
H3K18AC	1.25 (0.89–1.76)	0.201	–	–
H4K12AC	1.28 (0.89–1.85)	0.184	–	–
H4R3me2	0.74 (0.52–1.04)	0.084	–
Gender	0.66 (0.37–1.20)	0.176	–	–
Pathologic Grade	1.42 (1.11–1.81)	0.005	1.47 (1.15–1.88)	0.002
Size ≥2	1.71 (1.21–2.42)	0.002	1.52 (1.07–2.16)	0.020
AFP ≥400	0.80 (0.54–1.19)	0.277	–	–
ALT ≥41	1.31 (0.93–1.84)	0.129	–	–
Age ≥60	0.92 (0.57–1.49)	0.742	–	–
Vascular Invasion	1.79 (1.24–2.60)	0.002	–	–
Envelope	0.96 (0.67–1.38)	0.816	–	–
Cirrhosis	1.33 (0.94–1.88)	0.108	–	–
Necrosis	1.99 (1.40–2.82)	<0.001	1.79 (1.25–2.55)	0.001
HBeAg	1.17 (0.73–1.90)	0.514
HBV DNA*	1.10 (0.74–1.65)	0.640
Risk score	1.97 (1.39–2.80)	<0.001	1.95 (1.37–2.77)	<0.001

Notes: p-values were calculated with the two-sided Log rank test. *The HR was calculated based on available data of HBV DNA loads, excluding unmeasured cases.

Abbreviations: ALT, glutamic pyruvic transaminase; AFP, alpha-fetoprotein; HR, hazard ratio; CI, confidence interval.

The results of the multivariate Cox proportional hazards model are shown in Table 2. After adjusting for other factors, the analysis revealed that the histone risk score was an independent adverse prognostic risk factor for HBV related small HCC patients regarding RFS (HR: 1.95; 95% CI: 1.37–2.77; p < 0.001; Table 2), with similar results observed for OS (HR: 2.11; 95% CI: 1.22–3.63; p = 0.007; ). An advanced pathologic grade (HR: 1.47; 95% CI: 1.15–1.88; p = 0.002), a tumor size larger than 2 cm (HR: 1.52; 95% CI: 1.07–2.16; p = 0.020) and tumor necrosis (HR: 1.79; 95% CI: 1.25–2.55; p = 0.001) were also revealed as independent predictors for small HCC recurrence.

Nomogram Construction

To visualize the early recurrence prediction model, a nomogram was built based on the histone risk score and individual significant clinicopathologic predictors (including tumor size, pathologic grade and tumor necrosis) (Figure 4A). The calibration curve showed favorable agreement between the prediction and actual observation (Figure 4B). The predictive accuracy of the nomogram was excellent, with a C-index = 0.68 and an AUC = 0.70 (0.63–0.76) for predicting early recurrence and 5-year overall survival (Figure 4C; ). When the nomogram-derived merge score was used, for patients with high and low merge scores based on the median values, the 2-year RFS rates were 66.6% vs 85.5% (HR: 2.47; 95% CI: 1.72–3.55; p < 0.001) (Figure 4D). Additionally, decision curve analysis (DCA) was performed to evaluate the improvement in clinical decision making ().

Figure 4

Nomogram for early recurrence prediction and histone profiles in non-neoplastic liver tissues. (A) The nomogram was built for to predict the early recurrence of small HCC with the involved independent predictors. (B) Calibration curve of the total cohort for early recurrence prediction. (C) Comparison of the AUCs of the independent predictors to predict 2-year RFS. (D) Kaplan–Meier analysis of the merge score from the nomogram in the total cohort. HR: 2.88; 95% CI: 1.86–4.46; p < 0.001. (E) Waterfall plots for the distribution of the hepatic risk score and status of late recurrence. (F) Kaplan–Meier analysis of the hepatic risk score for late recurrence. HR: 2.00; 95% CI: 1.15–3.48; p = 0.01.

Histone Modifications in Adjacent Non-Neoplastic Hepatic Tissues

To further explore the prognostic value of histone modifications and considering that the biological signature of adjacent non-neoplastic tissues tends to be associated with late recurrence, as reported by Hoshida et al, the LASSO model was also separately applied in adjacent non-neoplastic liver tissues ().26 Two histone modifications in non-neoplastic liver tissues, H3K4me2 and H4R3me2, were selected via the LASSO model and included in the hepatic score for late recurrence (AUC = 0.62; 95% CI: 0.53–0.70) (). Notably, the hepatic score based on these histone modifications in non-neoplastic liver tissues could significantly predict the survival of patients with late recurrence (HR: 2.00; 95% CI: 1.15–3.48; p = 0.01) (Figure 4E and F). In agreement with the study by Xu et al, our study demonstrated that patients with late recurrence had shorter overall survival times than those without recurrence (p < 0.001, data not shown).27 Our preliminary investigation first proposed and suggested that histone modifications in adjacent non-neoplastic liver tissues could predict late recurrence in HBV related small HCC.

Discussion

To our best knowledge, this study was the first to focus on HBV-associated small hepatocellular carcinoma to profile the global expression of histone modifications in tumor and nontumor liver tissues. We described the development and validation of a promising recurrent risk score signature based on a panel of histone modifications, including H2AK5AC, H2BK20AC, H3K4me2, H3K9AC, H3K18AC, H4K12AC and H4R3me2, which was identified as an independent prognostic risk factor for recurrence-free survival and overall survival. A novel prognostic nomogram was further established with a combination of the histone risk score and other significant traditional predictors, showing satisfactory predictive accuracy for recurrence in patients with HBV related small HCC. More interestingly, histone modifications in non-neoplastic liver tissue might be predictors for the late recurrence of small HCC. Our findings highlight a novel method with which the levels of histone modifications may be used to predicting the early and late recurrence of small HCC with HBV.

Due to the complexity and heterogeneity of HCC, it is complicated and challenging to identify and apply a single molecular profile for clinical prediction. Although precision diagnosis using gene expression profiling has been developed, its high cost and unsatisfactory reproducibility restrict its application. In contrast, histone modifications offer an understandable viewpoint as transcriptional regulators reflecting the overall perspective of cells, generally via chromatin modification to promote or repress target gene expression. However, the epigenome and its regulation and dysregulation in cancer are complex, and the molecular mechanism still needs further investigation. The sum of all different histone modifications determines the chromatin structure and biological outcomes.28 Previous studies have revealed that several global histone modifications are associated with prognosis in various cancers based on overall expression by IHC staining; however, related research is lacking in HCC.17,18,20,29–31 In the present study, we first assessed a panel of global histone modifications in HBV related small HCC and found that these histone modifications (except for H4R3me2) were more pronounced in tumor tissues than in paired non-neoplastic tissues. Studies have indicated that H2AK5AC, H3K9AC, H3K18AC, H4K12AC, and H3K4me2 are associated with transcriptionally active gene promoters, and H4R3me2 is associated with gene repression.29,32–36 The less studied H2BK20AC is a good predictor of active enhancers.37 Additionally, in contrast to previous studies, we noticed that different carcinomas might have different patterns of histone modifications; for example, approximately half of the small HCC samples had less than 30% H3K9AC staining; however, in prostate cancer, more than 50% of the samples showed 90–100% staining.17 Furthermore, consistent with Seligson et al’s study in lung and kidney cancer patients, we found that a low level of H3K4me2 in small HCC contributes to a poor prognosis, which might be attributed to decreased methylation levels at repetitive DNA elements and an aggressive phenotype.38

Recurrence is a primary issue that severely impacts the survival of HCC patients. In addition to the clinical staging system, much effort has been made to identify patients with a high risk of recurrence. Increasing evidence has revealed that early recurrence is mainly associated with the nature of the primary tumor, such as tumor size and the number of nodular and vascular invasions, while the above presentations often appear in advanced stages and not early stages, such as small HCC; thus, biological markers for small HCC are still needed.39–43 We reviewed the research over the last ten years, and few studies have focused on HBV related small HCC biomarkers.44–47 In the present study, we revealed that the panel of global histone modifications in tumor tissues could be a significantly strong independent risk factor for small HCC, and patients with higher scores tended to experience more relapses, showing that histone modifications effectively predict recurrence and survival.

Additionally, we presented results for the first time that histone modifications in non-neoplastic liver tissues are related to the late recurrence of small HCC. In contrast to that of early recurrence, the mechanism of late recurrence is far from being fully understood.26 Late recurrence likely arises from a de novo tumor and is more relevant to the characterization of the field of adjacent liver tissues; however, the underlying mechanism remains to be elucidated.26 The analysis of non-neoplastic liver tissues showed that the expression of a group of genes was related to late recurrence but not early recurrence.26,48 Additional studies proposed that methylation patterns have already changed in normal tissues before carcinogenesis is detected.19,49–51 However, to the best of our knowledge, none of the histone modifications in non-neoplastic tissues have been investigated. This study highlights that histone modification levels could serve as predictive biomarkers not only for early recurrence but also for late recurrence. To further improve the survival of HBV related small HCC patients, patients with different risks must be stratified so that those with a high risk for early recurrence can receive more aggressive treatment after resection, while patients with a high risk of late recurrence, and even those who achieve 2 years of recurrence-free survival, should still receive regular surveillance to improve survival.27

We acknowledge that limitations exist in the present study. First, the study was retrospective in design and occurred at a single institute, although the present study was based on a solitary HBV-associated small HCC cohort with complete clinical information. Due to the homogeneity of resected small HCC, the number of samples was relatively small, which might have led to the observed trends for early recurrence and no statistical significance in the validation cohort. However, a trend toward significance was observed in the validation cohort. Second, although internal validation was performed to reduce overfitting of the model and improve its robustness for prediction, only 7 biomarkers were included in the present study, and no variables were discarded in the LASSO model. More importantly, external validation is still needed to generalize the use of the predictive model before it can be applied to clinical practice in the real world. Third, this clinical study did not reveal how these specific epigenetic modifications or combinations of changes affect the expression of particular genes or tumor behavior, which remains unclear, and the mechanistic basis needs to be further explored.

Conclusion

The present study is the first to assess the profiles of global histone modifications in hepatocellular carcinoma. We identified a histone risk score based on a panel of global histone modifications in tumors that could act as an independent predictor of early recurrence and survival in small HCC patients with HBV. Furthermore, we found that histone modifications in adjacent non-neoplastic liver tissues may be associated with late recurrence. This system could be useful to stratify patients according to the risk of tumor recurrence.