HLiver cancer, mainly represented by hepatocellular carcinoma (HCC) represents one of the main, constitutes the current third leading causes of cancer-rel of tumor-associated death worldwide. The transcription factor frefore, finding new molecules that improve early HCC diagnosis, prognosis and patient outcomes is crucial. Forkhead box O3 (FOXO3) has , an essential transcription factor expressed by hepatocytes, has been related to hepaticliver diseases and tumo and cancer progression, but the exact . However, the role played by FOXO3 on HCC still remains unclear. Recently, a novelThis study constitutes the first systematic review with meta-analysis revealedaimed to explore the potential diagnostic and prognostic value ofassociation of FOXO3 expression with HCC pathogenesis, survival rate and clinicopathological features (PROSPERO registration code: CRD42021237321). Based on five studies involving a total of 1059 HCC cases, we demonstrated that enhanced FOXO3 in this primary liver cancer typeexpression correlates with tumor development, shorter overall survival and high probability of invasion. Hence, FOXO3 could function as a novel diagnostic and prognostic biomarker in HCC.
Liver cancer iranks as the sixth most commonfrequently diagnosed cancer and the third leading cause of tumocancer-associated death[1]. Abmout 85% of ng primary liver cancertumors, approximately 85% of cases correspond to hepatocellular carcinoma (HCC)[1][2], an aggressive tumoralignancy with high incidence and mortality rates[3][4][5]. USinfortunatelyce the majority of HCC cases are detected at advanced stages[3][4], only a slight percentage of patients are eligible for curative thereatmentapeutical approaches[2][3][4]. Despite the latest advances in diagnostic and therapeutic strategies, the prognosis of HCC remains very poor, with an overall 5-year survival rate lower than 18%[6]. Thus, therefore, finding new functiona is an imperative need to identify novel biomarkers coulable to optimize early diagnosis, guide treatment application and improve HCC patient outcomess’ survival.
The forkhead box (FO subgroup (FOXO) X) family is organized into 19 different sub-families of transcription factors is that share a highly conserved DNA-binding domain named forkhead box or winged-helix domain. In mammals, the O subgroup (FOXO) is composed of FOXO1, FOXO3, FOXO4 and FOXO6[7][8][9]. Specifically, FOXO3 has shown to exertplay physiological and pathological functionroles by controlling the transcription of key target genes involved in multiple cellular processes[9][10][11]. Nonetheless, contradictoryhere are opposing reports about the role of FOXO3 expression in cancer are found in literatur, finding that FOXO3 upregulation can act either as a tumor-suppressive or an oncogenic mechanism, depending on the tumor type or specific circumstances[7][10].
Hepatocytes Iusually exhibit high FOXO3 levels[7], and this regard to HCC,transcription factor seems to be implicated in the pathogenesis of clivert disease[12]. Regardin articlg liver cancer, several studies sustain that abnormal FOXO3 overexpression could constituterepresent an unfavorable hallmark in HCC, being linked to more aggressive phenotypes and a worse long-term prognosis[12][13][14][15][16][17]. OthConverwisesely, other studieinvestigations defend the associcorrelation of low levels of FOXO3 expression with poorer HCC patient outcomes[18][19][20].
W Thus, existh the aim of clarifyinging HCC articles analyzing the relationship of FOXO3 levels with survival parameters and clinicopathological factors show controversial results, being necessary to clarify the role played by FOXO3 on HCCin HCC.
The apres well as of investigatingent research constitutes the first systematic review with meta-analysis aimed to explore the potential value of correlation between FOXO3 as a new biomarker in HCC, a recent systematic review with meta-analysis (PROSPERO regexpression and HCC pathogenesis, clinicopathological features and patient outcomes. Thus, we sought to contribute to a deeper understanding of HCC and provide a novel molecule with diagnostic and prognostic value, enabling better diagnosis and patient surveillance.
The aim of this investrigation code: CRD42021237321) was to evaluated the cdiagnorrelation stic and prognostic value of FOXO3 expression in patients with HCC pathogenesis,, focusing on the association of FOXO3 expression with tumor development and survival parameters and clinicopathological factors, as well as with several tumor and patient characteristics.
The It curreneeds to be mentioned that the studyt meta-analysis was performed followeding the PRISMA guidelines[21],. determining the quality of the selected investigationMoreover, the study protocol was registered in PROSPERO, being assigned the CRD42021237321 registration code.
An exhaustive with the Newcastle-Ottawa scale (NOS) criteriliterature search was performed in the databases Cochrane, Embase, PubMed, Scopus and Web of Science (WOS), establishing 30th April 2021 as the fina[22],l inclusion dand performte. The eligible studies were identified by using the statitiscal anearch strategies indicated in Table 1.
Table 1. Sealysisrch using previously reported methodology[23][24]strategy for each database.
Database |
Search Strategy |
Cochrane Library |
(foxo3 OR foxo3a OR fkhrl1 OR Forkhead box protein O3 OR Forkhead box O3 OR forkhead box O-3 OR AF6q21 OR Forkhead in rhabdomyosarcoma-like 1 OR fkhrl1p2 OR foxo2a) AND (hepatocellular carcinoma OR hepatocarcinoma OR HCC):ti,ab,kw |
Embase |
('foxo3' OR 'foxo3a' OR 'fkhrl1' OR 'forkhead box protein o3' OR 'forkhead box o3' OR 'forkhead box o-3' OR 'af6q21' OR 'forkhead in rhabdomyosarcoma-like 1' OR 'fkhrl1p2' OR 'foxo2a') AND ('hepatocellular carcinoma' OR 'hepatocarcinoma' OR 'hcc') |
PubMed |
("foxo3"[All Fields] OR "foxo3a"[All Fields] OR "fkhrl1"[All Fields] OR "Forkhead box protein O3"[All Fields] OR "Forkhead box O3"[All Fields] OR "forkhead box O-3"[All Fields] OR "AF6q21"[All Fields] OR "Forkhead in rhabdomyosarcoma-like 1"[All Fields] OR "fkhrl1p2"[All Fields] OR "foxo2a"[All Fields]) AND ("hepatocellular carcinoma"[All Fields] OR "hepatocarcinoma"[All Fields] OR "HCC"[All Fields]) |
Scopus |
TITLE-ABS-KEY ( ( "foxo3" OR "foxo3a" OR "fkhrl1" OR "Forkhead box protein O3" OR "Forkhead box O3" OR "forkhead box O-3" OR "AF6q21" OR "Forkhead in rhabdomyosarcoma-like 1" OR "fkhrl1p2" OR "foxo2a" ) AND ( "hepatocellular carcinoma" OR "hepatocarcinoma" OR "HCC" ) ) |
WOS Core Collection |
TS=(("foxo3" OR "foxo3a" OR "fkhrl1" OR "Forkhead box protein O3" OR "Forkhead box O3" OR "forkhead box O-3" OR "AF6q21" OR “Forkhead in rhabdomyosarcoma-like 1" OR "fkhrl1p2" OR "foxo2a") AND ("hepatocellular carcinoma" OR "hepatocarcinoma" OR "HCC")) Indexes = SCI-EXPANDED, SSCI, A&HCI, CPCI-S, CPCI-SSH, BKCI-S, BKCI-SSH, ESCI, CCR-EXPANDED, IC Timespan = All years |
WOS, Web of Science
The articles satisfying the following criteria were selected: (1) studies involving patients diagnosed with HCC; (2) determination of FOXO3 expression at translational or transcriptional level in tumor tissue; (3) relationship of FOXO3 levels with tumor presence/absence, survival data or clinicopathological features reported.
Studies complying with the following criteria were excluded: (1) studies exclusively accomplished with pre-clinical models; (2) reviews, book chapters, meeting communications and similar articles; (3) studies without mandatory data directly provided or in which it cannot be estimated; (4) articles with no available full-text in English.
PooArticled resultss screening, as well as data extraction and quality assessment from the comparison of FOXO3 expression between tumor tissues and each included study, was independently performed by four researchers. Discrepancies were solved by discussion and final consensus.
The qualthy normal liver samples proved that elevated levels ofity of selected articles was determined using the Newcastle–Ottawa scale (NOS), which scores studies from 0 to 9[22]. FOXO3 significantly correlate with HCCnly high-quality studies (NOS score ≥ 5) were included in the quantitative synthesis. The baseline pcharathogenesicteristics of selected studies (OR, 15.98; 95% CI, 1.96–130.02; p = 0.01) (Figur are shown in Table 1a, 2.
Table 1).
2. Baseline characteristics of selected articles.
Study |
Lu et al.[20] |
Chen et al.[19] |
Ahn et al.[16] |
Song et al.[12] |
Zhou et al.[15] |
Year |
2009 |
2017 |
2018 |
2020 |
2020 |
Tumor sample size |
91 (74)* |
102 |
187 |
314 |
365 |
Tumor sample size (M/F) |
71/20 (61/13)* |
62/40 |
NR |
255/59 |
NR |
Patients' origin |
China |
China |
Korea |
China |
NR |
Intervention |
Surgical resection |
Surgical resection |
Surgical resection |
Surgical resection |
NR |
Pre- or post-surgery treatment |
None |
None |
NR |
NR |
NR |
Age range |
32-72 |
NR |
NR |
NR |
NR |
Mean/median age |
51.37 ± 10.50 |
NR |
NR |
NR |
NR |
Study quality |
7/9 |
7/9 |
6/9 |
7/9 |
5/9 |
FOXO3 levels measurement |
IHC |
IHC |
IHC |
IHC |
RNA-Seq** |
Survival analysis |
CS |
OS |
OS/DFS |
OS |
OS |
HR |
Reported |
Reported |
Reported |
Estimated |
Estimated |
Healthy liver sample size |
NR |
NR |
21 |
150 |
NR |
Definition of "high" FOXO3 expression |
>0.40 |
>4¹ |
≥1² |
≥33 |
NR |
Number of tumor samples with "high" FOXO3 expression |
45 (37)* |
42 |
121 |
238 |
91 |
Number of healthy liver samples with "high" FOXO3 expression |
NR |
NR |
0 |
43 |
NR |
Figure 1. Assessment of the correlation of FOXO3 high expression with (a) tumor pathogenesis and (b) overall survival (OS) in HCC patients. CIS, confidence intervalumulative survival; DFS, disease-free survival; F, female; FOXO3, forkhead box O3; HR, hazard ratio; IHC, immunohistochemistry; M, male; NR, not reported; OS, overall survival; REML, Restricted Maxim. * Tumor samples included for survival analysis. ** From UALCAN database. ¹ Final scores were calculated by multiplying the score obtained for percentage of positive cells (0, ≤5%; 1, 5–25%; 2, 26–50%; 3, 51–75%; 4, >75%) by the score registered for staining intensity (0, no signal; 1, weak; 2, moderate; 3, strong). ² Final scores were calculated by multiplying the score obtained for percentage of positively stained tumor cells (0, 0–10%; 1, 11–25%; 2, 26–50%; 3, 51–75%; 4, 76–100%) by the score registered for staining intensity (0, negative; 1, weak; 2, intermediate; 3, strong). 3 Final scores were calculated by m Likelihoodultiplying the score obtained for percentage of positive cells stained (0, no staining; 1, 1 ≤ 1 < 25%; 2, 25% ≤ 2 < 50%; 3, 50% ≤ 3 < 75%; 4, ≥75%) by the score registered for staining intensity (0, negative; 1, weak; 2, moderate; 3, strong).
BMeta-anased on the results of tlysis synthesis was conducted using the STATA software version 16 (Stata Corporation, College Station, TX, USA). The trotal of the included articles,le of FOXO3 expression on HCC was examined in two steps. In the first step, we pooled data demonstrated that the overall survival (OS) data by hazard ratio (HR) and 95% confidence interval (CI) to unravel the correlation between FOXO3 high levels significantly correlateand HCC patients’ life expectancy. OS was established as the time from the intervention date until the day of decease or the last follow-up visit. Parmar method[23] was employed to estith lower OS rates (mate these data when no explicit information was reported in the primary study. HR,s and 1.79;respective 95% CI, 1.11–2.89;s were combined pthroughout =the 0.02) (Figure 1b, Table 1).
studies. Ini the second stially, although all available data on ep, the power of the association of FOXO3 overexpression with tumor existence or clinicopathological factors were pooled and analyzed, the investigators did not observe any eatures was estimated by odds ratio (OR) with 95% CI. It needs to be mentioned that specific thresholds or cut-off values were established to calculate the possible correlation of enhancedbetween FOXO3 expression with different high levels and certain clinicopathological factors such as : alpha-fetoprotein (AFP) levels, cirrhosis, gender, hepat, 50 ng/ml; tumor-node-metastasis (TNM) staging, I-II/III-IV; tumor size, 5 cm. Combined HR > 1 and OR > 1 denoted an upper risk of poor prognosis and a higher incidence of the tested feature when high expression of FOXO3, respectively, considering significant when p < 0.05.
Heterogeneity was evaluatis Bed by chi-square-based Q-test and I2 vstatistirus (HBV) infectionc. The Restricted Maximum Likelihood (REML) method was used as the random-effect model in cases where heterogeneity was detected (Q-test p-value < 0.10 and/or I2 ≥ 50%). Otherwise, the invasfixed-effects model with Inverse Variance (IV) method was employed[24]. To examine the heteron, metastasis, tumor-node-megeneity sources, we performed subgroup analyses based on sample size, patients’ origin, NOS score or follow-up time.
Publication biastasis (TNM) staging, was explored through the evaluation of funnel plot asymmetry and Egger’s test. When Egger’s tp-valumore < 0.05 nodularity and tumor and funnel plot was asymmetric, significant publication bias existed. In this case, trim-and-fill method was used to estimate a corrected effect size (Figure 2, Table 1).after adjustment, However, certain phich helped determine whether the publication bias substantially affected the robustness of the pooled results.
A total of 441 applicable rameters such as invasion showed an elevated heterogeneity among dataecords were identified through a database search, but 268 studies were duplicates, and after scanning titles and abstracts, another additional 56 non-original articles were excluded. The full-text of 117 articles was checked for eligibility, finding 69 articles without patient samples, one without English full-text, 10 without HCC patients and 32 without FOXO3-related tumor pathogenesis, survival or clinicopathological features evaluation. Therefore, subgroup analysithese 112 papers were also removed from the study. Finally, five articles[12][15][16][19][20] were was subsequently conducted in orssessed for quality and data extraction. All these studies reached the quality threshold according to NOS score (Table 2) and wer to inve included for quantitative meta-analysis (Figure 1).
Figure 1. PRISMA flow diagram of study selectigon. FOXO3, forkhead box O3; HCC, hepatocellular carcinoma; WOS, Web of Science.
As indicated in Table 2, the articles included in theterogeneity causes ae present meta-analysis were published from 2009 to 2020, and involved a total of 1059 HCC cases. Zhou et al.[15] did not d potentially find a significant correlationirectly report sample collection procedure or patient information. The rest of the samples were obtained by surgical resection, and the enrolled patients did not receive any pre- or post-operative treatment.
Figure 2. A The number of tumor salysis omples across studies ranged from 91 to 365, and 537 of the associtotals (50.71%) exhibited FOXO3 overexpression. All included studies[12][15][16][19][20] provided data relating FOXO3 expression bwith OS, four articles[12][16][19][20] with clinicopathological features and tweo investigations[12][16] also comparend FOXO3 hilevels between tumoral and healthy liver tissues.
Aside from Zhou et al.[15], which did not inform about the patients’ orighin, all expression reported patients came from Asia, mainly from China (73.05%)[12][19][20] and the serest from Korea (26.95%)[16]. Although Ahn et al.[16] and Zhou et al.[15] did not provide geral clinicnder data, the reported population was predominantly male (76.53%). Regarding risk factors, within the five papers included, three evaluated hepatitis B infection[16][19][20], and only one assessed hepathologitis C and alcoholic condition[16]. Likewise, two researches[19][20] also validated the presence features in HCCof cirrhosis in HCC patients. In summary, considering the total number of patients for whom the corresponding information is known, 73.28% of patients. suffered from hepatitis B, 31.35% AFP, alpha-fetoprotein; from hepatitis C, 32.64% from cirrhosis, 34.05% from alcoholism and 26.49% from hepatitis B, C and alcoholism simultaneously.
Two out of the five studies included in this meta-analysis compared FOXO3 levels between HCC samples and normal liver tissues. Pooled results showed that enhanced FOXO3 expression is significantly related to HCC development (OR, 15.98; 95% CI, 1.96–130.02; p = 0.01), finding an elevated heterogeneity (I2 = 60.30%, Q-test p = 0.11) (Figure 2a, Table 3).
Figure 2. Forest plots of the studies assessing the relationship between FOXO3 overexpression and (a) tumor pathogenesis or (b) OS in HCC patients.
CI, confidence interval; HBVR, hepatitis B virusazard ratio; OS, overall survival; REML, Restricted Maximum Likelihood; TNM, tumor-node-metastasis.
Table 13. EvAnaluationysis of the association of enhanced FOXO3 levelshigh expression with HCC pathogenesistumor development, survival and clinicopathological featureactors.
3b5c, Table 25).
Figure 35. SPubgroup analysis for lication bias evaluation of the potential correlation of FOXO3 overexpression with (a) tumor pathogenesis, (b) OS and (bc) the invasionassessed clinicopathological features by funnel plots asymmetry. AFP, alpha-fetoprotein; CI, confidence interval; HBV, hepatitis B virus; HR, hazard ratio; NOS, Newcastle–Ottawa scalIV, Inverse Variance; OS, overall survival; REML, Restricted Maximum Likelihood.
Table 2. Subgroup analysis.
Subgroups |
Number of Studies (n) |
Number of Cases (n) |
Samples with High FOXO3 Expression (n) |
High FOXO3 Expression (%) |
Pooled OR or HR |
Test for Heterogeneity |
Model Used |
||
95% CI |
p-Value |
I2 |
Q-Test p-Value |
||||||
OS |
|||||||||
Sample size (n) |
|||||||||
n > 100 |
4 |
968 |
492 |
50.83% |
2.13 (1.37–3.33) |
0.00 |
74.73% |
0.01 |
REM |
n ≤ 100 |
1 |
74 |
37 |
50.00% |
0.97 (0.95–0.99) |
- |
- |
- |
- |
n > 200/300 |
2 |
679 |
329 |
48.45% |
2.44 (1.21–4.94) |
0.01 |
81.20% |
0.02 |
REM |
n ≤ 200/300 |
3 |
363 |
200 |
55.10% |
1.45 (0.80–2.65) |
0.22 |
88.89% |
0.00 |
REM |
NOS score (threshold 5) |
|||||||||
NOS > 5 |
4 |
677 |
438 |
64.70% |
1.83 (0.98–3.42) |
0.06 |
91.83% |
0.00 |
REM |
NOS ≤ 5 |
1 |
365 |
91 |
24.93% |
1.76 (1.29–2.40) |
- |
- |
- |
- |
NOS score (threshold 6) |
|||||||||
NOS > 6 |
3 |
490 |
317 |
64.69% |
2.08 (0.90–4.81) |
0.09 |
92.03% |
0.00 |
REM |
NOS ≤ 6 |
2 |
552 |
212 |
38.41% |
1.58 (1.24–2.02) |
0.00 |
15.43% |
0.28 |
FEM |
Follow-up (months) |
|||||||||
>60 |
2 |
552 |
212 |
38.41% |
1.58 (1.24–2.02) |
0.00 |
15.43% |
0.28 |
FEM |
≤60 |
3 |
490 |
317 |
64.69% |
2.08 (0.90–4.81) |
0.09 |
92.03% |
0.00 |
REM |
>120/240 |
1 |
187 |
121 |
64.71% |
1.33 (0.89–1.98) |
- |
- |
- |
- |
≤120/240 |
4 |
855 |
408 |
47.72% |
1.96 (1.08–3.55) |
0.03 |
93.12% |
0.00 |
REM |
Invasion |
|||||||||
Sample size (n) |
|||||||||
n > 200 |
1 |
227 |
92 |
40.53% |
1.59 (0.93–2.73) |
- |
- |
- |
- |
n ≤ 200 |
4 |
663 |
405 |
61.09% |
1.52 (0.42–5.56) |
0.53 |
81.85% |
0.00 |
REM |
NOS score |
|||||||||
NOS = 6 |
3 |
561 |
363 |
64.71% |
2.95 (1.67–5.21) |
0.00 |
0.00% |
0.39 |
FEM |
NOS = 7 |
2 |
329 |
134 |
40.73% |
0.73 (0.15–3.65) |
0.70 |
88.95% |
0.00 |
REM |
Patients’ origin |
|||||||||
China |
2 |
329 |
134 |
40.73% |
0.73 (0.15–3.65) |
0.70 |
88.95% |
0.00 |
REM |
Korea |
3 |
561 |
363 |
64.71% |
2.95 (1.67–5.21) |
0.00 |
0.00% |
0.39 |
FEM |
Without Chen et al.[19] |
|||||||||
|
4 |
788 |
455 |
57.74% |
2.13 (1.44–3.16) |
0.00 |
29.99% |
0.23 |
FEM |
Parameter |
Number of Studies (n) |
Number of Cases (n) |
Samples with High FOXO3 Expression (n) |
High FOXO3 Expression (%) |
Pooled OR or HR |
Test for Heterogeneity |
Model Used |
|||
95% CI |
p-Value |
I2 |
Q-Test p-Value |
|||||||
HCC pathogenesis |
||||||||||
Tumoral tissue vs. Healthy tissue |
2 |
672 |
402 |
59.82% |
15.98 (1.96–130.02) |
0.01 |
60.30% |
0.11 |
REM |
|
OS |
5 |
1042 |
529 |
50.77% |
1.79 (1.11–2.89) |
0.02 |
91.66% |
0.00 |
REM |
|
Clinicopathological features |
||||||||||
AFP |
2 |
346 |
153 |
44.22% |
2.78 (0.74–10.43) |
0.13 |
86.14% |
0.01 |
REM |
|
Cirrhosis |
2 |
193 |
87 |
45.08% |
0.87 (0.14–5.43) |
0.88 |
87.81% |
0.00 |
REM |
|
Gender |
3 |
507 |
211 |
41.62% |
0.94 (0.61–1.43) |
0.76 |
0.00% |
0.38 |
FEM |
|
HBV infection |
3 |
378 |
207 |
54.76% |
1.36 (0.80–2.33) |
0.26 |
0.00% |
0.62 |
FEM |
|
Invasion |
5 |
890 |
497 |
55.84% |
1.51 (0.59–3.87) |
0.39 |
80.92% |
0.00 |
REM |
|
Metastasis |
2 |
400 |
168 |
42.00% |
1.67 (0.94–3.00) |
0.08 |
34.94% |
0.22 |
FEM |
|
TNM staging |
2 |
414 |
166 |
40.10% |
0.98 (0.08–11.41) |
0.99 |
95.72% |
0.00 |
REM |
|
Tumor nodularity |
3 |
603 |
287 |
47.60% |
0.67 (0.44–1.01) |
0.054 |
0.00% |
0.72 |
FEM |
|
Tumor size |
4 |
687 |
318 |
46.29% |
1.19 (0.87–1.64) |
0.28 |
0.00% |
0.41 |
FEM |
AFP, alpha-fetoprotein; CI, confidence interval; FEM, fixed-effects model; FOXO3, forkhead box O3; HBV, hepatitis B virus; HCC, hepatocellular carcinoma; HR, hazard ratio; OR, odds ratio; OS, overall survival; REM, random-effects model; TNM, tumor-node-metastasis.
In Furthermorder to find the heterogeneity sources for everye, we assessed the prognostic value of FOXO3 expression using the total of the enrolled articles. Pooled results showed a significant correlation between high FOXO3 expression and OS (HR, 1.79; 95% CI, 1.11–2.89; p = 0.02), and a great heterogeneity acrous ss studies was detected (I2 = 91.66%, Q-test p = 0.00) (Figure 2b, Table 3).
We pooled the avariable analyzed, subgroup analysis was carried out for parameters involving morlable data from the selected five papers to determine the hypothetical correlation between high FOXO3 expression and several clinicopathological characteristics. However, enhanced FOXO3 expression was not statistically correlated with the evaluated features, which included: AFP, cirrhosis, gender , hepatitis B virus (HBV) infection, invasion, metastasis, TNM staging, tumor nodularity and tumor size (Figure 3, Table 3).
Moreover, heterogeneity tests revealed that heterogeneity was substantial in the following cases: AFP (I2 = 86.14%, Q-test p = 0.01), cirrhosis (I2 = 87.81%, Q-test p = 0.00), invasion (I2 = 80.92%, Q-test p = 0.00) and TNM staging (I2 = 95.72%, Q-test p = 0.00). Otherwise, assumable heterogeneity was found in gender, HBV infection, metastasis, tumor nodularity and tumor size (Figure 3, Table 3).
Figure 3. Forest plots of than two original ste studies assessing the relationship between FOXO3 overexpression and specific clinicopathological features in HCC patients. AFP, alpha-fetoprotein; CI, confidence interval; HBV, hepatitis B virus; REML, Restricted Maximum Likelihood; TNM, tumor-node-metastasis.
Sudbgroup analysies as for heterogeneous parameters was performed according to sample size, NOS score, patients’ origin or follow-up time, in order to evaluate the possible heterogeneity sources. Subgroups composed of only one report were not considered.
RIn regarding OS parame to OS, a correlation was shown with high FOXO3 expression when subgroups were based on sample size n > 100 (HR, 2.13; 95% CI, 1.37–3.33; p = 0.00) and n > 200/300 (HR, 2.44; 95% CI, 1.21–4.94; p = 0.01), as well as on follow-up months (≤120/240) (HR, 1.96; 95% CI, 1.08–3.55; p = 0.03). However, heterogeneity was succstill continued to be high in all of these previous subgroups: sample size n > 100 (I2 = 74.73% and Q-test p = 0.01), n > 200/300 (I2 = 81.20% and Q-test p = 0.02) and fuollyow-up months (≤120/240) (I2 = 93.12% and Q-test p = 0.00) (Figure 4a, Table 4). Otherwise, FOXO3 overesolved xpression was significantly associated to OS when NOS ≤ 6 or follow-up > 60 months (HR, 1.58; 95% CI, 1.24–2.02; p = 0.00), and heterogeneity was successfully solved, as shown by I2 = 15.43% and Q-test p = 0.28), (Figure 4a, Table 4).
Figure 4. Forest aplso finding a significant corots after subgroup analysis of the studies assessing the relationship between high FOXO3 levels and poverexpression and (a) OS or (b) invasiorn in HCC patients. OS (Figure 3a, CI, confidence interval; HR, hazard ratio; NOS, Newcastle–Ottawa scale; OS, overall survival; REML, Restricted Maximum Likelihood.
Table 2).4. MSubgroreup analysis.
Subgroups |
Number of Studies (n) |
Number of Cases (n) |
Samples with High FOXO3 Expression (n) |
High FOXO3 Expression (%) |
Pooled OR or HR |
Test for Heterogeneity |
Model Used |
||
95% CI |
p-Value |
I2 |
Q-Test p-Value |
||||||
OS |
|||||||||
Sample size (n) |
|||||||||
n > 100 |
4 |
968 |
492 |
50.83% |
2.13 (1.37–3.33) |
0.00 |
74.73% |
0.01 |
REM |
n ≤ 100 |
1 |
74 |
37 |
50.00% |
0.97 (0.95–0.99) |
- |
- |
- |
- |
n > 200/300 |
2 |
679 |
329 |
48.45% |
2.44 (1.21–4.94) |
0.01 |
81.20% |
0.02 |
REM |
n ≤ 200/300 |
3 |
363 |
200 |
55.10% |
1.45 (0.80–2.65) |
0.22 |
88.89% |
0.00 |
REM |
NOS score (threshold 5) |
|||||||||
NOS > 5 |
4 |
677 |
438 |
64.70% |
1.83 (0.98–3.42) |
0.06 |
91.83% |
0.00 |
REM |
NOS ≤ 5 |
1 |
365 |
91 |
24.93% |
1.76 (1.29–2.40) |
- |
- |
- |
- |
NOS score (threshold 6) |
|||||||||
NOS > 6 |
3 |
490 |
317 |
64.69% |
2.08 (0.90–4.81) |
0.09 |
92.03% |
0.00 |
REM |
NOS ≤ 6 |
2 |
552 |
212 |
38.41% |
1.58 (1.24–2.02) |
0.00 |
15.43% |
0.28 |
FEM |
Follow-up (months) |
|||||||||
>60 |
2 |
552 |
212 |
38.41% |
1.58 (1.24–2.02) |
0.00 |
15.43% |
0.28 |
FEM |
≤60 |
3 |
490 |
317 |
64.69% |
2.08 (0.90–4.81) |
0.09 |
92.03% |
0.00 |
REM |
>120/240 |
1 |
187 |
121 |
64.71% |
1.33 (0.89–1.98) |
- |
- |
- |
- |
≤120/240 |
4 |
855 |
408 |
47.72% |
1.96 (1.08–3.55) |
0.03 |
93.12% |
0.00 |
REM |
Invasion |
|||||||||
Sample size (n) |
|||||||||
n > 200 |
1 |
227 |
92 |
40.53% |
1.59 (0.93–2.73) |
- |
- |
- |
- |
n ≤ 200 |
4 |
663 |
405 |
61.09% |
1.52 (0.42–5.56) |
0.53 |
81.85% |
0.00 |
REM |
NOS score |
|||||||||
NOS = 6 |
3 |
561 |
363 |
64.71% |
2.95 (1.67–5.21) |
0.00 |
0.00% |
0.39 |
FEM |
NOS = 7 |
2 |
329 |
134 |
40.73% |
0.73 (0.15–3.65) |
0.70 |
88.95% |
0.00 |
REM |
Patients’ origin |
|||||||||
China |
2 |
329 |
134 |
40.73% |
0.73 (0.15–3.65) |
0.70 |
88.95% |
0.00 |
REM |
Korea |
3 |
561 |
363 |
64.71% |
2.95 (1.67–5.21) |
0.00 |
0.00% |
0.39 |
FEM |
Without Chen et al.[19] |
|||||||||
|
4 |
788 |
455 |
57.74% |
2.13 (1.44–3.16) |
0.00 |
29.99% |
0.23 |
FEM |
CI, confidence interval; FEM, fixed-effects model; FOXO3, forkhead box O3; HR, hazard ratio; NOS, Newcastle–Ottawa scale; OR, odds ratio; OS, overall survival; REM, random-effects model.
Additiovernally, heterogeneity in invasion was resolved in the subgroupbased on NOS = 6 and Korean provenance (I2 = 0.00% and Q-test p = 0.39), shobservwing also for the first time a significant correlata strong association with high levels of FOXO3 (OR, 2.95; 95% CI, 1.67–5.21; p = 0.00). AdditCurionallusly, the elimination of Chen et al.[19] also led to an assumable heterogeneity (I2=29.99% and Q-test p = 0.23) and a significant assocrelation with FOXO3 overexpression (OR, 2.13; 95% CI, 1.44–3.16; p = 0.00) (Figure 4b, Table 4).
The rest of the subgroups exhibited ation between n elevated heterogeneity and did not follow a correlation with FOXO3 oexpression (Figure 4, Table 4). However, ovexpressionrall, subgroup analysis helped disclose that sample size, follow-up time, NOS score and patients’ origin contribute, at least in part, to the reported heterogeneity.
Although an Egger’s test could hinot be accomplished for the comparison of HCC tumor vs. non-tumor samples (Table 5), funnel plot analysis likely showed a slight pasymmetry (Figure 5a). In regard to OS, asymmetry was observed (Figure 5b) and a significant result was obitained in the Egger’s test (p = 0.00) (Table 5), which denoted publication bias. Hence, the trim-and-fill mety of inhod was performed, but no “missing” studies were imputed, and the global effect size remained unchanged (Table 5). Conversely, publicasiontion bias was not detected for all the assessed clinicopathological characteristics (Figure
CI, confidence interval; FETNM, fixed-effects model; FOXO3, forkhead box O3; HR, hazard ratio; NOS, Newcastle–Ottawa scale; OR, odds ratio; OS, overall survival; REM, random-effects modeltumor-node-metastasis.
Table 5. Evaluation of publication bias.
Parameter |
Number of Studies (n) |
Egger’s Test p-Value |
Model Used |
Trim-and-Fill OR or HR (95% CI) |
Imputed Studies (n) |
HCC pathogenesis |
|||||
Tumoral tissue vs. Healthy tissue |
2 |
* |
REM |
- |
- |
OS |
5 |
0.00 |
REM |
1.79 (1.11–2.89) |
0 |
Clinicopathological features |
|||||
AFP |
2 |
* |
REM |
- |
- |
Cirrhosis |
2 |
* |
REM |
- |
- |
Gender |
3 |
0.59 |
FEM |
- |
- |
HBV infection |
3 |
0.33 |
FEM |
- |
- |
Invasion |
5 |
0.57 |
REM |
- |
- |
Metastasis |
2 |
0.22 |
FEM |
- |
- |
TNM staging |
2 |
* |
REM |
- |
- |
Tumor nodularity |
3 |
0.67 |
FEM |
- |
- |
Tumor size |
4 |
0.43 |
FEM |
- |
- |
Primary liver cancer, mainly represented by HCC[2][6][25], remains a global unsolved health challenge[1][2]. Asymptomatic presentation at early stages, deficient diagnostic metechniqueshodology and post-therapy recurrence are common features of HCC, a this lethal primary liver tumor with disappointinga remarkably poor prognosis[2][6][15][16][19][25]. EMoreoven r, although increasing efforts are being put into HCC biomarker discovery[24][25][26][27], effective molecules thable to improve HCC t assist tumor detection and predict therapy response are still lacking.
FOXO3, an Mimportant member belonging to the evolutionary conserved FOXO sub-family[7][8][10], is a centranwhile,l transcription factor that governs downstream targets involved in key cellular processes[10]. It has been suggresported that FOXO3the deregulation could be iof FOXO3 expression is involved in cancer emergence[10][12][16] and progression[12][16][19]. FOXO3, bwhich is mainly expressed by liver cells[7], seems to be connected to the development of hepatic disease[12], but the exact linkage between FOXO3 expression and primary liver cancer has not been unclarifiovered yet.
Therefore, we performed the cuprrent study was carried out tesent systematic review with meta-analysis to accurately determine the relassociationship of FOXO3 high overexpression with tumor development, survival ratoutcome and clinicopathological featureactors, examining the potential usefulness of this factor as a diagnostic and prognostic biomarker for HCC monitoring.
TA total of five his systematic review withgh-quality studies, enrolling 1059 HCC cases, were selected for conducting this meta-analysis, mainly accomplished with Chinese population. Approximately half of the cases included in this investigation showed high FOXO3 expression, and most patients came from Asia, mainly from China, which is not surprising since most new HCC cas this geographical area accounts for nearly 75% of HCC incidence worldwide[6] asesnd usually come from Chinaabout 50% of new HCC patients are Chinese[28],.
The dcurretectent meta-analysis revealed a significant correlation between FOXO3 high expression and HCC pathogenesis. Interestingly, Lu et al.[29] evidenced that enhanced FOXO3FOXO3 is highly expression and activity ied and overactivated in HCC patients, which was associated with strong liver damage and overexpression of HCC-related genes, suggesting that FOXO3 overexpression is involved in tumorigenesis promotion. Additional reports from pre-clinical studies also indicated that FOXO3 upregulation is related to HCC oncogenicity via the overexpression of the long noncoding RNAs (lncRNAs) PRR34 antisense RNA 1 (PRR34-AS1)[17] and LOC554202[30], or by the circular RNA circFBXO11/miR-605 axis[13]. Contrary to all the above-mentiwise,oned results, the article by Wu et al.[31] described that reduction in FOXO3 nuclear translocation and activity could be involved in sepiapterin reductase-mediated HCC progression. Thus, thisConsidering all the previous evidence, which mostly defends a tumor-promoting action of the positive regulation of FOXO3, our meta-analysis certainly supports the findings reported by the majority of studies and suggests thatunderscores the role of FOXO3 overexpression on fostering HCC development. Hence, the upregulation of FOXO3 may constitute a suitable diagnostic factor able to complement classic techniques.
FurtMeanwhermore,ile, primary pooled results showed a significant association between FOXO3 overexpression and poor survival outcomes was registered inshorter OS of HCC patients, indic. Chen et al.[32] emphatsingzed that FOXO3 could constitute a negative prognostic factor in this tumor. Similar reports were showexpression is related to shorter survival time and cancer progression in invasive ductal breast carcinoma[32], which was also observed in glioblastoma human samples[33]. and tripleLikewise, high levels of this factor were significantly related to a shorter disease-free survival (DFS) time and an increased Ki-67 proliferation index in triple-negative breast cancer (TNBC) samplepatients[34]. Otherwise, Zhao et al.[35] observed that FOXO3 dotransactivity is impaired in HCC due to FOXO3 downregulation, which could be linked with the enhancement of cell proliferation promoted by thyroid hormone receptor-interacting protein 6 (TRIP6). However, correlation between TRIP6 and FOXO3 expression in HCC individuals and its impact on survival rate were not assessed[35]. Therefore, there is no conclusive statement about the impact of FOXO3 on HCC prognosis based on such a study.
AConsidditionally, it has been found that high ering FOXO3 as a potential biomarker in HCC constitutes a novel approach. As a consequence, there is still little research in the literature that analyzes the possible connection between FOXO3 levels and survival outcome, being all this evidence included in the current systematic review with meta-analysis. Even though our study proved the potential of FOXO3 levels may trigger HCC invasivenessas a negative prognostic factor in HCC, additional large-scale investigations should be performed in this cancer type to confirm such an encouraging result.
Regarding the Devaluated clinicopathologifferent articles also determinecal features, subgroup analysis showed that invasion statistically correlates with high levels of FOXO3 in articles with a medium–high NOS score or those harboring Korean patients, suggesting that elevated FOXO3 expression may trigger HCC invasiveness. Additionally, it has been reported that FOXO3 expression accentuates invasiveness and tumor expansion in glioblastoma[33], pancreatic cancer[36] and HeLa and melanoma MDA-MB-435 cells[37], being also correlated to perineural invasion in TNBC samples[34].
Contrariwise, FOXO3 oppositely impacted the invasive capabilities of breast tumors, depending on the estrogen receptor α (ERα) status[38]. MorBeoversides, Yang et al.[39] demonstrated the potential of bortezomib to inhibitsuppress cell migration and invasion byvia FOXO3 upregulating FOXO3 on in cholangiocarcinoma and HCC in vitro models. However, these results were not tested in vivo nor in HCC patients. Moreover, and it needs to be mentioned that bortezomib does not reis not currently approved for HCC treatment, due to it not showing enough efficacy against this tumor, and it does not represent a major chemotherapeutic drug within the HCC field.
O It is known that FOXO3 displays a dual role other hand, although no correlation was found in cancer, promoting malignant phenotypes or inhibiting cancer progression depending on the tumor type or specific tumor-related circumstances. This fact likely drives contrasting findings among different reports. Therefore, although our meta-analysis revealed for the first time a significant correlation between enhanced FOXO3 levels and any other evaluated clithe risk of invasion, further studies are required to unequivocally unravel the impact of FOXO3 on the modulation of HCC invasion capability.
In regard to clinicopathological feature, Chen et aactors evaluated other than invasion, there was not a significant association between FOXO3 overexpression and AFP l.[40]evels, cindicated thatrrhosis, gender, HBV infection, metastasis, TNM staging, tumor nodularity or tumor size. However, despite no correlation observed between FOXO3 coulevels and HBV infection, Chen et al.[40] proved that FOXO3 participates in the HBV-mediated HCC tumorigenesis. WGiven the absence of additional HCC investigations, novel studies analyzith regard to studies ang the relationship of HBV infection or other clinicopathological factors with FOXO3 expression will help unravel the potential of this central transcription factor to predict HCC-associated features and reinforce its usefulness as a novel biomarker.
With respecct tomplished in the possible association between FOXO3 expression and the aforementioned clinicopathological parameters in other tumors, an investigation conducted with nasopharyngeal carcinoma samples observed that low FOXO3 expression correlates with advanced clinical stages and higher T stages, as well as withpart from lymph node metastasis and distant metastasis[41]. Reduced FOXO3 levels in colorectal cancer[42], esophageal squamous cell carcinoma (ESCC)[43] and pancreatic ductal adenocarcinoma samples[44] h ave been also associlso correlated with more advanced disease. DMeanwhile, deregulation of FOXO3 levels has shown to differentially influence lymph node metastasis in invasive ductal carcinoma[32], TNBC[34] and bladder carcinoma[45], finding that the interplay β-catenin-FOXO3 can also be a have as a metastasis promoter in colon cancer[46]. BMoresidesover, FOXO3 downregulation in ESCC patients accounted for lymph node metastasis[43], and its low expression correlated with a larger tumor size in gastric adenocarcinoma[47].
AColltogether, these reportectively, all the available evidence concerning FOXO3 regulation and the associated cancer features highlights the double-edged action played by this crucial transcription factor, finding that deregulation of FOXO3, fi expression and activity may definitely determine tumor promotion or suppression depending on the cancer type, cellular context or genomic profile.
In summary, this studing that deregulaty is the first comprehensive, detailed and systematic meta-analysis evaluating and demonstrating the diagnostic and prognostic value of FOXO3 in HCC, thus covering an unexplored research pathway. It is worth mentioning that all published and available clinical evidence on the association of FOXO3 expression and activity may lead to cancewith HCC development, survival parameters and clinicopathological features was checked and, if appropriated, included in this work. Moreover, our meta-analysis contains important and informative analysis, such as heterogeneity assessment, subgroup analysis and publication bias evaluation. Therefore, although further studies are needed to corroborate our findings, this novel systematic review with meta-analysis constitutes the first addressing the clinical significance of FOXO3 as a biomarker in HCC, thereby setting the basis for future investigations and providing a new potential molecule that could successfully assist HCC detection and prognostic evaluation.
However, promotion or supthere are still some limitations in the current study that need to be considered. The number of articles included both in qualitative and quantitative synthesis was low, and the evaluation of the diagnostic and clinicopathological significance of FOXO3 in HCC involved even fewer reports, due to these data being missing in some of the studies. Thus, the volume of the research was relatively small, and more investigations are required to verify and complete the results obtained by this innovative meta-analysis.
On the other hand, although only one paperession depending on the cancer type, cellular context or genomic profile was excluded during the assessment of eligible articles because the full-text was not written in English, exclusion of studies published in languages other than English probably accounts for publication bias, discarding investigations with relevant results. Despite one of the five included articles not reporting the patients’ ethnicity, the rest of the studies were carried out with Asian patient samples. There is a lack of investigations performed with people from other geographical regions, which leads to a disbalance in terms of patients’ origin, likely contributing to bias apparition. Additionally, not every included report evaluated HCC-associated risk factors, such as HBV infection, thereby missing relevant information that could condition global results. In regard to studies evaluating FOXO3 levels by immunohistochemistry (IHC), they established very similar but not completely identical criteria for the definition of “high” FOXO3 expression, which could cause mild heterogeneity. HRs from two out of the five included studies had to be estimated from survival curves, as this information was not directly reported, which could slightly contribute to variability apparition among articles. Furthermore, only one of the selected articles provided DFS information, an interesting prognosis-related variable, but this fact prevented determining its potential association with FOXO3 expression.
In conclusion, our systhis study proved for the first timeematic review with meta-analysis has been the first to evaluate the potential of the transcription factor FOXO3 as a novel and functional biomarker in cancer and, more precisely, in HCC. This novel study demonstrated that an enhanced FOXO3 increased expression couldof FOXO3 may be an unfavorable clinical factor with diagnostic and prognostic significancvalue in HCC, being associated withrelated to tumor development, poor OS and high riska high probability of invasion. Thereforeus, the evaluation of FOXO3 levels could constitutes a promising approachstrategy to optimize and complement HCC detection and, specifically, to guide patient surveillance and make an accurate prognosis. However, these findings need to be confirmed by additional high-quality, well-designed and large-scale investigations.
Graphical Abstract. FOXO3, Forkhead box O3; HCC, hepatocellular carcinoma; OS, overall survival.
This entry is an adaptation from doi.org/10.3390/cancers13215349