Abstract
Background
Perineural invasion (PNI) is associated with metastasis in malignancies, including intrahepatic cholangiocarcinoma (ICC), and is correlated with poor prognosis.
Methods
The study included three large cohorts: ZS-ICC and TMA cohorts from our team, MSK cohort from a public database, and a small cohort named cohort 4. Prognostic implications of PNI were investigated in MSK cohort and TMA cohort. PNI-related genomic and transcriptomic profiles were analyzed in MSK and ZS-ICC cohorts. GO, KEGG, and ssGSEA analyses were performed. Immunohistochemistry was used to investigate the relationship between PNI and markers of neurons, hydrolases, and immune cells. The efficacy of adjuvant therapy in ICC patients with PNI was also assessed.
Results
A total of 30.6% and 20.7% ICC patients had PNI in MSK and TMA cohorts respectively. Patients with PNI presented with malignant phenotypes such as high CA19-9, the large bile duct type, lymph node invasion, and shortened overall survival (OS) and relapse-free survival (RFS). Nerves involved in PNI positively express tyrosine hydroxylase (TH), a marker of sympathetic nerves. Patients with PNI showed high mutation frequency of KRAS and an immune suppressive metastasis prone niche of decreased NK cell, increased neutrophil, and elevated PD-L1, CD80, and CD86 expression. Patients with PNI had an extended OS after adjuvant therapy with TEGIO, GEMOX, or capecitabine.
Conclusion
Our study deciphered the genomic features and the immune suppressive metastasis-prone niche in ICC with PNI. Patients with PNI showed a poor prognosis after surgery but a good response to adjuvant chemotherapy.
Graphical abstract
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Background
Intrahepatic cholangiocarcinoma (ICC) is the second most common primary liver cancer, originating from the secondary and higher intrahepatic bile duct branches [1]. The prognosis of patients with ICC remains poor owing to early metastasis and lack of effective treatment strategies [2].
Perineural invasion (PNI) in cancer was first reported in the nineteenth century [3]. PNI is defined as the appearance of tumor cells along the nerves and/or within the epineural, perineural, and endoneuria regions of the neuronal sheath, with cancer cells surrounding at least one-third of the nerves [3]. Recently, the clinical significance of PNI in malignancies has been noticed. PNI was observed in over 80% of pancreatic ductal adenocarcinoma (PDAC) cases and was found to be an early event of tumorigenesis in preclinical and clinical models [4, 5], reprogramming the immune microenvironment with decreased CD8+ T and Th1 cells, and elevated Th2 cells [6]. In addition, PNI has been considered as an independent prognostic factor in several cancers, including gastric cancer [7], cervical cancer [8], gallbladder cancer [9], breast cancer [10], prostate cancer [11], hepatocellular carcinoma (HCC) [12], and ICC [13]. Considering the significant implications of the prognosis of cancers, the molecular characteristics of PNI and its potential targets are of great significance. In particular, recent evidence has established a link between the nervous system and the immune microenvironment, wherein the nerve fibers were observed to colocalize with subclones of lymphocytes in PDAC, including CD20+ B cells, CD4+, CD8+ T cells, and CD21+ follicular dendritic cells [14]. The colocalization of nerve fibers with immune cells provides direct evidence for neuroimmunomodulation in malignancies [15]. Preliminary evidence has shown that PNI can reprogram the immune microenvironment through cholinergic signaling in PDAC [6]. Unfortunately, the molecular profile of PNI and the relationship between PNI and the immune microenvironment in ICC remain unclear.
In this study, we investigated the role of PNI in two independent cohorts of patients with ICC and confirmed the contribution of PNI as an unfavorable prognostic factor post-surgery in these patients. We found that the PNI in case of ICC is mainly derived from the sympathetic nerve (SNS). We also demonstrated that patients with PNI presented with an immune suppressive metastasis prone niche, high frequency of KRAS mutation, and better survival after adjuvant therapy.
Materials and methods
Patients and clinical samples
Study participants included four cohorts. Cohort 1: 255 ICC patients with RNA-seq and genomic data from our group (named as ZS-ICC cohort) [16]. Cohort 2: 186 ICC patients with genomic data, PNI and clinical information from MSK cohort [17]. Cohort 3: 309 patients with ICC who underwent curative resection between 2013 and 2017 at Zhongshan Hospital, Fudan University (named as TMA cohort). Enrolled patients met the following criteria [18]: (1) pathologically confirmed ICC; (2) ≥ 3 months of relapse-free survival (RFS) after resection; (3) had not undergone anti-tumor treatment before surgery; and (4) had complete medical records and follow-up data available. Patients were stratified by a tumor-node-metastases (TNM) stage system according to the American Joint Committee on Cancer (AJCC) 8th edition. The histological grade of ICC was based on World Health Organization Criteria. Tumor samples and adjacent liver tissue samples were collected, formalin-fixed, and paraffin-embedded. The last follow-up was on December 31, 2020. Cohort 4: 19 pathologically confirmed patients with ICC who underwent curative resection from March 2016 to May 2016 at Zhongshan Hospital, Fudan University.
Tissue microarrays, immunohistochemistry and hematoxylin–eosin (H&E) staining
The tissue microarrays (TMAs) were constructed as previously described and immunohistochemistry (IHC) was performed as our previous study [19]. Anti-human rabbit monoclonal antibodies for monoamine oxidase A (MAO-A) (1:200; #ab126751, Abcam, Cambridge, UK), anti-human mouse monoclonal antibodies for beta-tubulin III (1:100; #4466S, CST, Massachusetts, USA), anti-human rabbit monoclonal antibodies for tyrosine hydroxylase (TH) (1:300; #58844S, CST, Massachusetts, USA), anti-human mouse monoclonal antibodies for vesicular acetylcholine transporter (VACHT) (1:100; #MA5-27,662, ThermoFisher, Waltham, USA) and anti-human rabbit monoclonal antibodies for CD56 (1:200; #99746S, CST, Massachusetts, USA) were used as primary antibodies to detect the expression of MAO-A, TH, VACHT and CD56, respectively. Automated digital pathological slice scanner, KF-PRO-120 (KONFOONG biotech international CO.LTD., Ningbo, China) and NanoZoomer S360 (Hamamatsu Photonics CO.LTD., Beijing, China), were used to scan images of IHC slides, and slides were photographed by Digital slices view software K-Viewer (KONFOONG biotech international CO.LTD., Ningbo, China) and NDP-viewer (Hamamatsu Photonics CO.LTD., Beijing, China).
Evaluation of MAO-A and CD56 expression
TMAs of cohort 3 consisting of two paired spots of tumor tissue and peri-tumor tissue from one patient were used to investigate the expression of MAO-A. For each spot, five represent visions were randomly chosen and the optical density (OD) and area for each vision were calculated by Image-Pro Plus (version 6.0, Media Cybernetics, Inc., China). MAO-A staining score was counted as OD/area and defined the average score of total ten visions as the expression of MAO-A of each patient. Cut off values were calculated through X-tile [20]. Cohort 4 was used to investigate the expression of CD56 as followed. Five representative spots were chosen for each patient and the number of CD56 positive cells were counted. The average number of positive cells of five spots was considered as the CD56 expression level of each patient. The score was defined as numbers of CD56 positive cells: (1) 0 or 1: 1 point; (2) 2 or 3: 2 points; (3) 4 to 10: 3 points; (4) more than 10: 4 points.
Statistical and bioinformatic analysis
Statistical analyses were performed with SPSS 25.0 (Chicago, IL, USA), and GraphPad Prism 8 software (La Jolla, CA, USA). Values are presented as median (range) or mean ± standard deviation (SD). Unpaired Student’s t-test, Fisher’s exact test, Chi-square test and the Wilcoxon rank-sum test were used to compare differences between groups. The Kaplan–Meier method was used to construct the survival and recurrence curves. Cox proportional hazards model analysis was used to analyzing the correlation between variables and ICC patient prognosis. Statistical tests were two-tailed, and p-value < 0.05 was considered significant. Differentially expressed gene analysis was operated in R (version 4.1.2, R foundation for statistical, Vienna, Austria). Codes used are available on request. Gene Ontology (GO), Kyoto Encyclopedia of Genes and Genomes (KEGG) were operated on https://www.xiantao.love/products/apply/. Single sample Gene Set Enrichment Analysis (ssGSEA) was performed on ImmuCellAI [21].
Results
PNI is an unfavorable prognostic factor for patients with ICC post-operation
The MSK cohort (n = 186) and the TMA cohort (n = 309) were used to investigate the role of PNI in ICC (Fig. 1a, Table S3). PNI was evaluated by H&E staining and further confirmed by IHC of beta-tubulin III in TMA cohort (Fig. 1b) and was observed in 30.6% and 20.7% of patients in the MSK and TMA cohorts, respectively (Fig. 1c. f). The overall survival (OS) of patients with PNI was evidently shorter than that of patients without PNI (HR = 1.61, p = 0.013; HR = 2.33, p < 0.001, respectively) (Fig. 1d, g). Similarly, the relapse-free survival (RFS) of patients with PNI was conspicuously lower than that of those without PNI (HR = 1.95, log-rank p < 0.001; HR = 1.59, log-rank p = 0.017, respectively) (Fig. 1e, h). We also analyzed the relationship between PNI and other clinicopathological features and found that PNI positivity was significantly correlated with high CA19-9 level, the large duct type ICC and lymph node invasion in two independent cohorts. (Tables 1, S1). Recently, a multicenter study reported that PNI is a powerful and independent predictor of recurrence and survival in ICC [22]. Consistently, univariate and multivariate analyses of TMA cohort revealed that PNI (HR = 1.781, p = 0.002), microvascular invasion (HR = 2.033, p < 0.001), lymph node invasion (HR = 1.874, p = 0.038), and CA19-9 level (HR = 1.673, p = 0.003) are independent risk factors for OS in ICC patients (Fig. 1i). According to the 5th WHO classification, the large duct type ICC exhibited poorer prognosis than those with the small type, and PNI is usually observed in the large duct type ICC. To rule out the influence of duct type, multivariate analyses was performed and confirmed PNI was a negative risk factor (HR = 2.391, p < 0.001) independent of the duct type (Fig. S1a). Similarly, K-M analyses confirmed patients with PNI showed poorer prognosis either in the large duct type group (HR = 4.25, P < 0.001) or the small duct type group (HR = 1.72, p = 0.015) (Fig. S1b, c).
PNI derived from sympathetic nerves in ICC
Sympathetic nerve system (SNS) or parasympathetic nerve system (PNS)-derived nerve fibers have been reported to participate in the progress of tumors [23] (Fig. 2a), thereby propelling the search for the origin of PNI in ICC. We investigated the expression of representative pan-neural, SNS, and PNS markers in ZS-ICC cohort at the mRNA level. Among the five markers, significant upregulation of TH (p = 0.005), a biomarker of SNS [24], was observed in patients with PNI from the ZS-ICC cohort compared to those in patients without PNI, whereas no difference in pan-neural markers such as ubiquitin carboxyl-terminal hydrolase isozyme L1 (UCHL1/PGP9.5) [25] (p = 0.292), beta-tubulin III (TUBB3) [26] (p = 0.656), synapsin (SYN) [27] (p = 0.612), and PNS biomarker vesicular acetylcholine transporter (VACHT) [28] (p = 0.266) was detected (Fig. 2b, c). Meanwhile, IHC staining consistently revealed that PNI exhibited positive staining for TH in TMA cohort (Fig. 2d), indicating that PNI originated from the SNS. As previously reported, neural transmitters such as, norepinephrine (NE) and acetylcholine (ACH) released from automatic nerves are transmitted and combined with corresponding receptors such as adrenergic receptors (ADRs), muscarinic acetylcholine receptors (CHRMs), and nicotinic acetylcholine receptors (CHRNs) in tumor cells or normal cells [23] (Fig. 2a). To detect the receptors involved in PNI, we analyzed the mRNA expression levels of ADRs in the ZS-ICC cohort. Surprisingly, significant upregulation of ADRB1 (p = 0.002) and ADRB3 (p = 0.029) expression and downregulation of ADRA2C (p = 0.006) expression were detected in patients with PNI, while no difference was found in other ADRs. (Fig. 2e). Furthermore, K–M analysis showed that ADRA2C (HR = 0.37, p < 0.001) played a protective role in the OS of patients with ICC after surgery, while ADRB1 (HR = 1.81, p = 0005) showed an adverse effect (Fig. S2a–c). In addition, as the main hydrolase of NE, MAO-A [29, 30] secreted from tumor cells was highly enriched in patients without PNI in TMA Cohort (p = 0.005) (Figs. 2f, g; S2d). Patients with high MAO-A level demonstrated improved OS and RFS (HR = 0.61, HR = 0.72, respectively) compared to those with low level of MAO-A (Fig. 2h, i).
ICC patients with PNI were characterized by immune suppressive metastasis niche.
RNA-seq data from the ZS-ICC cohort showed a distinct gene expression pattern in patients with PNI (Fig. S3a, b). GO and KEGG analyses showed that upregulated genes in patients with PNI were majorly enriched in immune-associated pathways, such as neutrophil-mediated immunity, neutrophil degranulation, and leukocyte migration, while genes highly expressed in patients without PNI mostly focused on the regulation of neuron project development (Fig. S3c). To further elucidate the immune microenvironment in PNI-positive patients, ssGSEA was performed. Significantly decreased infiltration of NK cells (p < 0.001) and γδT cells (p = 0.001) and increased infiltration of B cells (p < 0.001) and neutrophils (p = 0.002) were found in patients with PNI in ZS-ICC cohort (Fig. 3a). Among these immune cells, the levels of NK cells and γδ T cells were positively correlated with the OS of ICC patients, whereas the levels of neutrophils and B cells were adversely correlated with OS (Fig. 3b). We further investigated the influence of these immune cells on the prognosis of patients with and without PNI. The results showed that patients with high level of NK cells had longer OS in either the PNI-positive group (HR = 0.29, p = 0.001) or the PNI-negative group (HR = 0.47, p = 0.006) (Fig. 3c). However, neutrophil levels only influenced the OS of patients with PNI (HR = 1.67, p = 0.1) (Fig. 3d). No statistical differences in B cells and γδT cells were found between patients with PNI (HR = 1.28, p = 0.535; HR = 0.53, p = 0.094) and those without PNI (HR = 1.43, p = 0.134; HR = 1.10, p = 0.693) (Fig. S3d, e). Similarly, decreased infiltration of NK cells (p = 0.017) was found in patients with PNI in cohort 4 (n = 19) (Fig. 3e, f), and patients with less infiltration of NK cells showed a worse prognosis (HR = 0.21; p = 0.027) (Fig. 3g). In addition, we also analyzed the expression of immune checkpoint molecules in the ZS-ICC cohort and found that the mRNA expression of PD-L1/CD274 (p = 0.015), CD80 (p = 0.005), and CD86 (p = 0.045) was distinctly elevated in patients with PNI (Fig. 3h). These data showed that ICC patients with PNI were accompanied with immune suppressive metastasis prone niche.
ICC patients with PNI exhibited higher frequency of KRAS mutations.
By comparing the genomic data of the MSK and ZS-ICC cohorts, a high alteration frequency of KRAS (p = 0.003; p = 0.003 respectively) and RAD51C (p = 0.028, p = 0.02 respectively) was observed in patients with PNI in both cohorts (Fig. 4a). K–M analysis revealed that patients with KRAS mutations also exhibited poor prognosis (HR = 3.39, p < 0.001; HR = 2.36, p < 0.001, respectively) (Fig. 4b, c), consistent with our previous report [31].
ICC patients with PNI well responded to adjuvant therapy
We divided the TMA cohort into six subgroups according to different postoperative therapeutic strategies (Table 2). K–M analysis was used to compare the OS of patients with or without adjuvant therapy. No statistical difference in OS was observed between the patients who received adjuvant therapy and those who did not (Fig. 5a). We further investigated the role of adjuvant therapy in patients with PNI and found that these patients gained significant OS benefits from adjuvant chemotherapy, such as capecitabine (p = 0.037), GEMOX (p = 0.005), and TEGIO (p = 0.008), while patients without PNI did not (p > 0.05) (Fig. 5b, c).
Discussion
Our study revealed that PNI could be considered an unfavorable prognostic factor for patients with ICC post-surgery, and an indicator of well response to adjuvant therapy. Furthermore, our results showed that PNI in patients with ICC was mainly from SNS. Moreover, our study is the first to decipher the immune suppressive metastasis prone niche of ICC patients with PNI, which was characterized by decreased infiltration of NK cells, increased infiltration of neutrophils and elevated expression of immune check points' ligands. In addition, PNI positive ICC patients are accompanied with higher frequency of KRAS mutation. These data indicate that ICC with PNI exhibits special microenvironment, potentially causing the invasion and metastasis of ICC.
PNI is considered as a mechanistic feature associated to tumor metastasis and a marker of poor prognosis in several cancers [7,8,9,10,11,12]. In the present study, our results provide sufficient evidence to support the notion that PNI is a reliable marker for predicting the prognosis of patients with ICC, based on two independent cohorts. Recent studies have demonstrated that neuromodulation plays an important role in several pathological processes, including tumor metastasis and remodeling of the immune microenvironment [3, 6, 14, 32]. Nerve domination largely depends on the context of the type of tumor. For example, PNI reprograms the immune microenvironment through cholinergic signaling in PDAC [6], while PNI in head and neck cancer is associated with the adrenergic nerve [33, 34]. In the present study, PNI in patients with ICC exhibited positive staining for TH, indicating that it originated from the SNS. ADRs have been widely reported to be involved in cancers recently [35]. As the main neural transmitter released from SNS, NE can bind with ADRs on the surface of tumor cells, immune cells, and other stromal cells, and exert biological action [23]. In our study, the expression of ADRA2C, ADRB1, and ADRB3 in patients with PNI evidently differed from that in patients without PNI, and patients with increased ADRA2C and decreased ADRB1 showed better prognosis. ADRB1 expressed on tumor cells has been identified as a biomarker for breast cancer [36]. ADRA2C, mainly expressed on the pre-synapse neurons, is thought to act as an inhibitory modulator of the sympathetic nervous system [37]. The overexpression of ADRB1 and downregulation of ADRA2C probably hyperactivate SNS signaling in ICC patients with PNI, resulting in PNI-mediated poor prognosis. Additionally, as the main hydrolase of NE [29], MAO-A was enriched in PNI-negative patients, indicating that it inhibited SNS in PNI. A recent study reported that MAO-A suppressed HCC metastasis by inhibiting adrenergic signaling [38]. Interestingly, MAO-A promotes prostate cancer cell PNI through SEMA3C/PlexinA2/NRP1-cMET signaling [39]. This contradictory conclusion largely resulted from the fact that SNS was not the main constituent of PNI in prostate cancer [40]. Altogether, NE from SNS might activate multiple ADRs in ICC patients with PNI, and cancer cell-derived MAO-A might inactivate NE from SNS, synergistically involved in PNI-mediated tumor progression.
The association between SNS and the immune system has been documented over the last several decades [41]. Recent studies have shown complicated but important interactions between immune cells and neurons in tumor tissues, called ‘neuro-immune unit’ [15]. In this study, patients with PNI showed an immune suppressive metastasis prone niche with increased infiltration of B cells and neutrophils and decreased infiltration of NK cells and γδ T cells. The protective role of NK cells was confirmed in both PNI-negative and PNI-positive groups. In mammary adenocarcinoma, acute stress could activate SNS, resulting in the suppression of NK cell activity and tumor metastasis [42]. SNS also induces the suppression of NK cell cytotoxicity in rats [43]. Thus, we hypothesized that the involvement of SNS in ICC with PNI inhibits the infiltration of NK cells, partly contributing to the poor prognosis of patients. In cancers, tumor-associated neutrophils (TANs) have emerged as an important component of the tumor microenvironment, which can not only be a part of tumor-promoting inflammation by driving angiogenesis, extracellular matrix remodeling, metastasis, and immunosuppression, but can also mediate antitumor responses by directly killing tumor cells and participating in cellular networks that mediate antitumor resistance [44]. Zhou. et al. reported that TANs and macrophage interactions contribute to ICC progression by activating STAT3 [45]. Consistently, we observed an adverse relationship between neutrophils and the prognosis of ICC patients with PNI. Interestingly, we did not detect any influence of neutrophils on the survival of patients without PNI. As reported previously, local SNS signaling promotes neutrophil infiltration during acute inflammation [46]. A recent study also demonstrated that stress hormones such as NE and adrenaline cause rapid release of proinflammatory S100A8/A9 proteins by neutrophils, leading to early relapse in lung cancer and ovarian cancer post operation [47]. In this study, we observed an increased infiltration of neutrophils in ICC patients with PNI. These indicate an interaction between PNI and neutrophils. Elevated expression of PD-L1, CD80, and CD86 was observed in patients with PNI. Our previous study showed that PD-L1 was a predictive marker for immunotherapy in ICC [48], implying that ICC patients with PNI might benefit more from anti-PD1/PD-L1 therapy. Meanwhile, the interaction of CTLA-4 with CD80 or CD86 could inhibit human T-cell activation [49], indicating that the inhibition of CD80 and CD86 in PNI-positive patients might activate T cells and restore antitumor immune reactions. Surprisingly, targeting the CD80/CD86 costimulatory pathway also directs microglia towards a repair phenotype and promotes axonal outgrowth [50]. In conclusion, neurons can release neural transmitters and other cytokines to bind the receptors on immune cells and tumor cells, regulating their functions, while immune cells and tumor cells could release several neurotrophic factors to promote the axons extension. The interaction among neurons, immune cells and malignancies synthetically cause the occurrence of PNI and the immune suppressive metastasis prone niche. Thus, further research is needed to define whether PNI or immune regulation is the cause or result in such a complex microenvironment.
Consistent with a retrospective study of 86 ICC patients [51], we found that the alteration frequency of KRAS in the PNI-positive group was higher than that in the PNI-negative group, partly contributing to the poor prognosis of patients with PNI. Li. et al. also reported that KRAS mutations are associated with PNI in colon cancer [52]. KRAS, a Kirsten ras oncogene homolog from the mammalian ras gene family, encodes a protein that is a member of the small GTPase superfamily [53]. Ras proteins bind GDP/GTP and possess intrinsic GTPase activity, playing an important role in GPCR (G-protein combined receptors) mediated pathways like adrenergic signaling [53]. We hypothesized that the mutation of KRAS hyperactive the downstream pathways of ADRs, contributing to the development of PNI. Additionally, syndecan-2 (SDC-2) promotes perineural invasion and cooperates with K-ras to induce an invasive pancreatic cancer cell phenotype [54]. What’s more, the M2 splice isoform of PK (PKM2) was found to regulate neural invasion of hilar cholangiocarcinoma (HC) via regulation of SDC2 [55]. These indicate SDC-2 may be an intermediator between KRAS mutation and PNI in ICC. This may provide valuable information for the curation of treatment strategies of ICC patients with PNI. However, additional evidence is needed to illustrate direct interactions between KRAS mutations and PNI.
Clinical trials have demonstrated that adjuvant chemotherapy, including TEGIO and capecitabine, is beneficial for patients with biliary tract cancers, including ICC [56]. In this study, we retrospectively observed that patients with PNI gained OS benefits from adjuvant chemotherapy, while no improvement in OS was found in PNI-negative patients. The same phenomenon has been reported in colon [57], rectal [58], prostate [59], and oral cancers [60]. This result suggests that PNI could be a credible predictor for adjuvant therapy in ICC. Regrettably, the mechanism underlying the relationship between PNI and adjuvant therapy remains unclear.
Conclusion
Our study deciphered that patients with PNI showed a poor prognosis after surgery but a good response to adjuvant chemotherapy. In addition, we illustrated that ICC patients with PNI were accompanied with higher frequency of KRAS mutation and an immune suppressive metastasis prone niche characterized by decreased NK cell, increased neutrophil and elevated expression of immune check points’ ligands. However, further investigations are needed to explore the molecular mechanisms of PNI in ICC.
Data sharing statement
Data are available from the authors upon reasonable request.
Availability of data and materials
Data and materials are available on request.
Abbreviations
- PNI:
-
Perineural invasion
- ICC:
-
Intrahepatic cholangiocarcinoma
- GO:
-
Gene ontology
- KEGG:
-
Kyoto Encyclopedia of Genes and Genomes
- ssGSEA:
-
Single sample Gene Set Enrichment Analysis
- TMA:
-
Tissue microarray
- HCC:
-
Hepatocellular carcinoma
- PDAC:
-
Pancreatic ductal adenocarcinoma
- OS:
-
Overall survival
- RFS:
-
Relapse-free survival
- TNM:
-
Tumor-node-metastases
- AJCC:
-
American Joint Committee on Cancer
- IHC:
-
Immunohistochemistry
- H&E:
-
Hematoxylin–eosin
- MAO-A:
-
Monoamine oxidase A
- TH:
-
Tyrosine hydroxylase
- OD:
-
Optical density
- SNS:
-
Sympathetic nerve system
- PNS:
-
Parasympathetic nerve system
- UCHL1:
-
Ubiquitin carboxyl-terminal hydrolase isozyme L1
- TUBB3:
-
Tubulin beta-3 chain
- SYN:
-
Synapsin
- VACHT:
-
Vesicular acetylcholine transporter
- NE:
-
Norepinephrine
- ACH:
-
Acetylcholine
- ADRs:
-
Adrenergic receptors
- CHRMs:
-
Muscarinic acetylcholine receptors
- CHRNs:
-
Nicotinic acetylcholine receptors
- TME:
-
Tumor microenvironment
- NK:
-
Natural killer
- TEGIO:
-
Tegafur, Gimeracil and Oteracil potassium capsules
- GEMOX:
-
Gemcitabine + Oxaliplatin
- ICBs:
-
Immune check point blockers
- PD1:
-
Programmed death 1
- PD-L1:
-
Programmed death ligand-1
- CTLA-4:
-
Cytotoxic T-lymphocyte associated protein 4
- TIGIT:
-
T cell immunoreceptor with Ig and ITIM domains
- PVR:
-
Poliovirus receptor
- TIM3:
-
T cell immunoglobulin domain and mucin domain-3
- FGL-1:
-
Fibrinogen-like protein-1
- LAG-3:
-
Lymphocyte-activation gene 3
- DC:
-
Dendrite cell
- Treg:
-
Regulatory T cell
- TPM:
-
Transcripts Per Kilobase of exon model per Million mapped reads
References
Massarweh NN, El-Serag HB. Epidemiology of hepatocellular carcinoma and intrahepatic cholangiocarcinoma. Cancer Control 2017;24(3):1073274817729245
Fu J, Li Y, Li Z, Li N. Clinical utility of decarboxylation prothrombin combined with α-fetoprotein for diagnosing primary hepatocellular carcinoma. Biosci Rep 2018;38(5):BSR20180044
Demir IE, Ceyhan OG, Liebl F, et al. Neural invasion in pancreatic cancer: the past, present and future. Cancers (Basel) 2010;2(3):1513–1527
Demir IE, Friess H, Ceyhan GO. Neural plasticity in pancreatitis and pancreatic cancer. Nat Rev Gastroenterol Hepatol 2015;12(11):649–659
Stopczynski RE, Normolle DP, Hartman DP, et al. Neuroplastic changes occur early in the development of pancreatic ductal adenocarcinoma. Cancer Res 2014;74(6):1718–1727
Yang MW, Tao LY, Jiang YS, et al. Perineural invasion reprograms the immune microenvironment through cholinergic signaling in pancreatic ductal adenocarcinoma. Cancer Res 2020;80(10):1991–2003
Zhao B, Lv W, Mei D, Luo R, et al. Perineural invasion as a predictive factor for survival outcome in gastric cancer patients: a systematic review and meta-analysis. J Clin Pathol 2020;73(9):544–551
Cui L, Shi Y, Zhang GN. Perineural invasion as a prognostic factor for cervical cancer: a systematic review and meta-analysis. Arch Gynecol Obstet 2015;292(1):13–19
Madhusudhan KS. Perineural invasion in gallbladder cancer. Radiographics 2021; 41(5):E161-E162
Narayan P, et al. Perineural invasion as a risk factor for locoregional recurrence of invasive breast cancer. Sci Rep. 2021;11:12781. https://doi.org/10.1038/s41598-021-92343-4
Lubig S, et al. Quantitative perineural invasion is a prognostic marker in prostate cancer. Pathology 2018;50(3):298–304
Wang X, et al. Perineural invasion: a potential reason of hepatocellular carcinoma bone metastasis. Int J Clin Exp Med 2015;8(4):5839–5846
Zhang Z, et al. Perineural invasion as a prognostic factor for intrahepatic cholangiocarcinoma after curative resection and a potential indication for postoperative chemotherapy: a retrospective cohort study. BMC Cancer 2020;20(1):270
Tan X, et al. Nerve fibers in the tumor microenvironment in neurotropic cancer-pancreatic cancer and cholangiocarcinoma. Oncogene 2021;40(5):899–908
Godinho-Silva C, Cardoso F, Veiga-Fernandes H. Neuro-immune cell units: a new paradigm in physiology. Annu Rev Immunol 2019;37:19–46
Dong L, et al. Proteogenomic characterization identifies clinically relevant subgroups of intrahepatic cholangiocarcinoma. Cancer Cell 2022;40(1):70-87.e15
Boerner T, et al. Genetic determinants of outcome in intrahepatic cholangiocarcinoma. Hepatology 2021;74(3):1429–1444
Guo XJ, et al. CTLA-4 synergizes with PD1/PD-L1 in the inhibitory tumor microenvironment of intrahepatic cholangiocarcinoma. Front Immunol 2021;12: 705378
Shi GM, et al. CD151 modulates expression of matrix metalloproteinase 9 and promotes neoangiogenesis and progression of hepatocellular carcinoma. Hepatology 2010;52(1):183–196
Camp RL, Dolled-Filhart M, Rimm DL. X-tile: a new bio-informatics tool for biomarker assessment and outcome-based cut-point optimization. Clin Cancer Res 2004;10(21):7252–7259
Miao YR, Zhang Q, Lei Q, Luo M, Xie GY, Wang H, Guo AY. ImmuCellAI: a unique method for comprehensive T-Cell subsets abundance prediction and its application in cancer immunotherapy. Adv Sci 2020;7(7):1902880
Wei T, et al. Prognostic impact of perineural invasion in intrahepatic cholangiocarcinoma: multicentre study. Br J Surg 2022;109(7):610–616
Zahalka AH, Frenette PS. Nerves in cancer. Nat Rev Cancer 2020;20(3):143–157
Burgi K, et al. Tyrosine hydroxylase immunoreactivity as indicator of sympathetic activity: simultaneous evaluation in different tissues of hypertensive rats. Am J Physiol Regul Integr Comp Physiol 2011;300(2):R264–R271
Day IN, Thompson RJ. UCHL1 (PGP 9.5): neuronal biomarker and ubiquitin system protein. Progress Neurobiol 2010;90(3):327–362
Mariani M, et al. Class III β-tubulin in normal and cancer tissues. Gene 2015;563(2):109–114
Thiel G. Synapsin I, synapsin II, and synaptophysin: marker proteins of synaptic vesicles. Brain Pathol (Zurich, Switzerland) 1993;3(1):87–95
Ehrhardt E, Boyan G. Evidence for the cholinergic markers ChAT and vAChT in sensory cells of the developing antennal nervous system of the desert locust Schistocerca gregaria. Invertebr Neurosci 2020;20(4):19
Fergusson DM, Boden JM, Horwood LJ, Miller AL, Kennedy MA. MAOA, abuse exposure and antisocial behaviour: 30-year longitudinal study. Br J Psychiatry 2011;198(6):457–463
Lung FW, Tzeng DS, Huang MF, Lee MB. Association of the MAOA promoter uVNTR polymorphism with suicide attempts in patients with major depressive disorder. BMC Med Genet 2011;12:74
Zhou SL, et al. Association of KRAS variant subtypes with survival and recurrence in patients with surgically treated intrahepatic cholangiocarcinoma. JAMA Surg 2022;157(1):59–65
Li J, Kang R, Tang D. Cellular and molecular mechanisms of perineural invasion of pancreatic ductal adenocarcinoma. Cancer Commun (London, England). 2021;41(8):642–660
Lopes-Santos G, Bernabé DG, Miyahara GI, Tjioe KC. Beta-adrenergic pathway activation enhances aggressiveness and inhibits stemness in head and neck cancer. Transl Oncol 2021;14(8): 101117
Ma C, et al. Sympathetic innervation contributes to perineural invasion of salivary adenoid cystic carcinoma via the β2-adrenergic receptor. Onco Targets Ther. 2019;12:1475–1495
Cole SW, Sood AK. Molecular pathways: beta-adrenergic signaling in cancer. Clin Cancer Res 2012;18(5):1201–1206
Wang J, et al. ADRB1 was identified as a potential biomarker for breast cancer by the co-analysis of tumor mutational burden and immune infiltration. Aging (Albany NY) 2020;13(1):351–363
Lee KS, et al. Selection on the regulation of sympathetic nervous activity in humans and chimpanzees. PLoS Genet 2018;14(4): e1007311
Li J, et al. Monoamine oxidase A suppresses hepatocellular carcinoma metastasis by inhibiting the adrenergic system and its transactivation of EGFR signaling. J Hepatol 2014;60(6):1225–1234
Yin L, et al. MAOA promotes prostate cancer cell perineural invasion through SEMA3C/PlexinA2/NRP1-cMET signaling. Oncogene 2021;40(7):1362–1374
Sigorski D, Gulczyński J, Sejda A, Rogowski W, Iżycka-Świeszewska E. Investigation of neural microenvironment in prostate cancer in context of neural density, perineural invasion, and neuroendocrine profile of tumors. Front Oncol 2021;11: 710899
Padro CJ, Sanders VM. Neuroendocrine regulation of inflammation. Semin Immunol 2014;26(5):357–368
Ben-Eliyahu S, Shakhar G, Page GG, Stefanski V, Shakhar K. Suppression of NK cell activity and of resistance to metastasis by stress: a role for adrenal catecholamines and beta-adrenoceptors. NeuroImmunoModulation 2000;8(3):154–164
Jiang XH, et al. Sympathetic nervous system mediates cold stress-induced suppression of natural killer cytotoxicity in rats. Neurosci Lett 2004;357(1):1–4
Jaillon S, et al. Neutrophil diversity and plasticity in tumour progression and therapy. Nat Rev Cancer 2020;20(9):485–503
Zhou Z, et al. Tumor-associated neutrophils and macrophages interaction contributes to intrahepatic cholangiocarcinoma progression by activating STAT3. J Immunother Cancer 2021;9(3): e001946
Ao T, et al. Local sympathetic neurons promote neutrophil egress from the bone marrow at the onset of acute inflammation. Int Immunol 2020;32(11):727–736
Perego M, et al. Reactivation of dormant tumor cells by modified lipids derived from stress-activated neutrophils. Sci Transl Med 2020;12(572):eabb5817
Lu JC, et al. Distinct PD-L1/PD1 profiles and clinical implications in intrahepatic cholangiocarcinoma patients with different risk factors. Theranostics 2019;9(16):4678–4687
Vandenborre K, et al. Interaction of CTLA-4 (CD152) with CD80 or CD86 inhibits human T-cell activation. Immunology 1999;98(3):413–421
Louveau A, et al. Targeting the CD80/CD86 costimulatory pathway with CTLA4-Ig directs microglia toward a repair phenotype and promotes axonal outgrowth. Glia 2015;63(12):2298–2312
Chen TC, Jan YY, Yeh TS. K-ras mutation is strongly associated with perineural invasion and represents an independent prognostic factor of intrahepatic cholangiocarcinoma after hepatectomy. Ann Surg Oncol 2012;19(Suppl 3):S675–S681
Li Y, et al. Preoperative prediction of perineural invasion and KRAS mutation in colon cancer using machine learning. J Cancer Res Clin Oncol 2020;146(12):3165–3174
Lothar G, et al. Germline KRAS mutations cause aberrant biochemical and physical properties leading to developmental disorders. Hum Mutat 2011;32(1):33–43
Tiago DO, et al. Syndecan-2 promotes perineural invasion and cooperates with K-ras to induce an invasive pancreatic cancer cell phenotype. Mol Cancer 2012;11:19
Yu GZ, et al. PKM2 regulates neural invasion of and predicts poor prognosis for human hilar cholangiocarcinoma. Mol Cancer 2015;14(14):193
Rizvi S, Khan SA, Hallemeier CL, Kelley RK, Gores GJ. Cholangiocarcinoma—evolving concepts and therapeutic strategies. Nat Rev Clin Oncol 2018;15(2):95–111
Cienfuegos JA, et al. Perineural invasion is a major prognostic and predictive factor of response to adjuvant chemotherapy in stage I-II colon cancer. Ann Surg Oncol 2017;24(4):1077–1084
Song JH, et al. Significance of perineural and lymphovascular invasion in locally advanced rectal cancer treated by preoperative chemoradiotherapy and radical surgery: can perineural invasion be an indication of adjuvant chemotherapy? Radiother Oncol 2019;133:125–131
Sun G, et al. The impact of multifocal perineural invasion on biochemical recurrence and timing of adjuvant androgen-deprivation therapy in high-risk prostate cancer following radical prostatectomy. Prostate 2017;77(12):1279–1287
Nair D, et al. Perineural invasion: independent prognostic factor in oral cancer that warrants adjuvant treatment. Head Neck 2018;40(8):1780–1787
Acknowledgements
Not applicable.
Funding
This study was supported by the Clinical Research Plan of SHDC (SHDC‑2020CR1003A), the Key Disease Joint Research Program of Xuhui District (XHLHGG202103), the National Key Research and Development Program of China (2019YFC1316000), the National Natural Science Foundation of China (81972232), the Clinical Medicine Research Pilot Project of Shanghai Medical School of Fudan University, the Shanghai Municipal Natural Science Foundation (20JC1419103), Beijing Mutual Care Public Welfare Foundation (GDXZ-08–05), Sanming Project of Medicine in Shenzhen (No. SZSM202003009) and the National Innovation and Entrepreneurship Training Program for College Students (202210246001S).
Author information
Authors and Affiliations
Contributions
Concept and design: G-MS, X-YH; Data collection: X-LM, J-CL, LZ, X-JG, CG, Y-ZP, S-YH, MY; Q-MS, G-HY, J-BC, Y-HS, A-WK, JZ, JF, LY; Experiments: X-LM, J-CL, H-YZ, ZC; Data analysis and visualization: X-LM, J-CL; Writing article: G-MS, X-LM, J-CL.
Corresponding authors
Ethics declarations
Conflict of interest
Xian-Long Meng, Jia-Cheng Lu, Hai-Ying Zeng, Zhen Chen, Xiao-Jun Guo, Chao Gao, Yan-Zi Pei, Shu-Yang Hu, Mu Ye, Qi-Man Sun, Guo-Huang Yang, Jia-Bin Cai, Pei-Xin Huang, Lei Yv, Lv Zhang, Ying-Hong Shi, Ai-Wu Ke, Jian Zhou, Jia Fan, Yi Chen, Xiao-Yong Huang, Guo-Ming Shi have declared that no competing interest exists.
Ethics approval
The study was approved by the Institutional Review Board of Zhongshan Hospital (Y2019-366), and all related procedures conformed to the Declaration of Helsinki.
Consent to participate
Not applicable.
Consent for publication
Not applicable.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Meng, XL., Lu, JC., Zeng, HY. et al. The clinical implications and molecular features of intrahepatic cholangiocarcinoma with perineural invasion. Hepatol Int 17, 63–76 (2023). https://doi.org/10.1007/s12072-022-10445-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12072-022-10445-1