• OPEN ACCESS

Paclitaxel-induced Immune Dysfunction and Activation of Transcription Factor AP-1 Facilitate Hepatitis B Virus Replication

  • Shi Chen1,#,
  • Benhua Li1,#,
  • Wei Luo2,
  • Adeel ur Rehman1,
  • Miao He3,
  • Qian Yang1,
  • Shunyao Wang1,
  • Jinjun Guo4,
  • Ling Chen5,*  and
  • Xiaosong Li1,* 
 Author information
Journal of Clinical and Translational Hepatology 2024;12(5):457-468

DOI: 10.14218/JCTH.2023.00537

Abstract

Background and Aims

Hepatitis B virus (HBV) reactivation is commonly observed in individuals with chronic HBV infection undergoing antineoplastic drug therapy. Paclitaxel (PTX) treatment has been identified as a potential trigger for HBV reactivation. This study aimed to uncover the mechanisms of PTX-induced HBV reactivation in vitro and in vivo, which may inform new strategies for HBV antiviral treatment.

Methods

The impact of PTX on HBV replication was assessed through various methods including enzyme-linked immunosorbent assay, dual-luciferase reporter assay, quantitative real-time PCR, chromatin immunoprecipitation, and immunohistochemical staining. Transcriptome sequencing and 16S rRNA sequencing were employed to assess alterations in the transcriptome and microbial diversity in PTX-treated HBV transgenic mice.

Results

PTX enhanced the levels of HBV 3.5-kb mRNA, HBV DNA, HBeAg, and HBsAg both in vitro and in vivo. PTX also promoted the activity of the HBV core promoter and transcription factor AP-1. Inhibition of AP-1 gene expression markedly suppressed PTX-induced HBV reactivation. Transcriptome sequencing revealed that PTX activated the immune-related signaling networks such as IL-17, NF-κB, and MAPK signaling pathways, with the pivotal common key molecule being AP-1. The 16S rRNA sequencing revealed that PTX induced dysbiosis of gut microbiota.

Conclusions

PTX-induced HBV reactivation was likely a synergistic outcome of immune suppression and direct stimulation of HBV replication through the enhancement of HBV core promoter activity mediated by the transcription factor AP-1. These findings propose a novel molecular mechanism, underscoring the critical role of AP-1 in PTX-induced HBV reactivation.

Keywords

Paclitaxel, HBV reactivation, Transcription factor, AP-1, Immune system, Gut microbiota

Introduction

The continuing high prevalence of chronic hepatitis B virus (CHB) infection is a global public health concern, particularly in China and other countries in the Asia-Pacific region. Approximately 296 million people globally are believed to have CHB, and hepatitis B virus (HBV) infection-related illnesses led to approximately 820,000 fatalities in 2019.1,2 HBV infection can cause varying degrees of liver inflammation and fibrosis. In the absence of antiviral treatment, persistent CHB infection can lead to cirrhosis and hepatocellular carcinoma. HBV infection is amenable to early diagnosis and effective treatment, but the current diagnosis and treatment rates of HBV in China are only 22% and 15%, respectively.3 Despite the widespread implementation of hepatitis B vaccination and other interventions, the prevention and treatment of HBV still pose significant challenges.

HBV is transported to the liver through bloodstream transmission and infects hepatocytes. After attaching to its functional receptor, sodium taurocholate cotransporting polypeptide (NTCP), the virus enters the host cell cytoplasm through endocytosis. Covalently closed circular DNA (cccDNA) is formed in the nucleoplasm by the release of relaxed circular DNA (rcDNA) from the nuclear capsid.4 HBV cccDNA is the primary source of sustained viral replication and transcription. It exists in a microchromosomal form for an extended period and is highly stable, acting as the persistent reservoir of the virus and a significant cause of HBV reactivation during immunosuppression.5 Even after HBV infection clearance and serologic conversion of HBsAg, the presence of HBV cccDNA can still be observed within the liver.6

The definition of HBV reactivation may vary slightly among different guidelines, but the underlying concept remains the same. It refers to the activation of HBV in individuals with quiescent infection or those having low levels of viral replication. HBV reactivation is a frequent complication of immunosuppressive or antineoplastic therapy in individuals with chronic HBV infection leading to liver damage.7 The main underlying mechanism of HBV reactivation is the disruption of the balance between the virus and the host’s immune function. Treatment with chemotherapeutic drugs or immunosuppressants can compromise the immune function of patients, leading to a significant increase in viral replication within the host. Subsequently, when these drugs are discontinued and the immune function is restored, an overly strong immune response can occur, resulting in hepatocyte injury.8 Of note, the likelihood of HBV reactivation is particularly high among individuals treated with B-cell depleting agents such as rituximab.9 However, in more than half of all cases, HBV reactivation occurs early in the course of chemotherapy, rather than during the interval after the completion of chemotherapy.10 This suggests that immune dysfunction alone cannot explain all the clinical phenomena, and it is possible that certain chemotherapeutic agents directly stimulate HBV replication.

Paclitaxel (PTX) is a widely utilized first-line therapeutic agent for various types of cancers. Its primary mechanism of action is to stabilize and enhance the polymerization of microtubule proteins, leading to the prevention of microtubule depolymerization and the inhibition of cell mitosis. However, clinical trials have reported cases of severe HBV reactivation leading to liver damage in breast cancer patients following PTX treatment.11

While previous clinical studies have documented the reactivation of HBV in individuals concurrently diagnosed with HBV infection and tumors following PTX treatment, the direct impact of PTX on HBV itself remains a subject of controversy. Furthermore, there is a paucity of comprehensive investigations elucidating the molecular mechanisms underlying chemotherapeutic drug-induced HBV reactivation. Therefore, in this study, we conducted a series of in vitro and in vivo experiments to examine the relationship between PTX and HBV replication. The objective was to shed light on the potential mechanisms of PTX-induced HBV reactivation.

Methods

Cell culture

HepAD38 (HB-8065, ATCC, Manassas, VA, USA) cells were obtained from the American Type Culture Collection, while HepG2-NTCP cells were generously provided by Prof. Ningshao Xia (Xiamen University, Fujian, China). HepG2.2.15 cells were stored in our laboratory. HepAD38 cells were cultured in a growth medium comprising Dulbecco’s modified Eagle’s medium (DMEM, HyClone, Logan, UT, USA) with the addition of 10% fetal bovine serum (FBS, Gibco, Rockville, MD, USA), 1 µg/mL tetracycline, 500 µg/mL G418, 100 units/mL penicillin (HyClone, Logan, UT, USA), and 100 µg/mL streptomycin (HyClone, Logan, UT, USA) as previously described.12 To boost NTCP receptor expression in HepG2-NTCP, an additional 2 µg/mL of doxycycline was added to the growth medium.13

Antibodies and reagents

The following antibodies were used for immunoblot analysis: anti-hepatitis B core antigen (HBcAg) (B0586) from Dako (Glostrup, Denmark) and anti-GAPDH (Cat. no. 60004-1) from Proteintech (Rosemont, IL, USA). Anti-Rabbit-HRP (ab6721) from Abcam (Cambridge, UK) and anti-c-Jun (Cat. no. 9165S) from Cell Signaling Technology (Danvers, MA, USA). Paclitaxel (PTX, Cat#HY-B0015) was obtained from MedChemExpress (Monmouth Junction, USA). Sangon Biotech (Shanghai, China) provided G418, tetracycline (A100422), and doxycycline (DOX).

Animal studies

HBV transgenic mice (HBV-Tg, C57BL/6), a gift from Xiamen University, were housed in the SPF of the Animal Centre of Chongqing Medical University. A total of 8 HBV-Tg mice, aged 6–8 weeks, were included in each group. Animal administration used in this study has been described in the previous study.12 The mice were administered intraperitoneal injections of phosphate-buffered saline (PBS, control) or PTX (10 mg/kg body weight) every other day for a total of seven injections. Half of the mice were sacrificed after the injection on the 14th day, and the remaining mice were kept under observation until one week after drug withdrawal. The liver tissue samples were harvested and quickly frozen in liquid nitrogen and stored at −80°C, together with the colon contents samples for sequencing purposes.

Western blot analysis

Total proteins were extracted from the cells using RIPA lysis buffer (Cat. no. C0005; Beyotime Biotechnology, Shanghai, China) with 1 mM phenylmethanesulfonyl fluoride (Beyotime Biotechnology, Shanghai, China). The protein samples were subjected to electrophoresis on a 10% sodium dodecyl sulfate-polyacrylamide gel (SDS-PAGE) and then electrically transferred onto a PVDF membrane (IPVH00010, Merck Millipore, Billerica, MA, USA). The protein bands were detected using an enhanced chemiluminescence (ECL) detection kit (Beyotime Biotechnology, Shanghai, China).

RNA isolation and RT-qPCR

Total RNA was extracted using TRizol reagent (Invitrogen, Carlsbad, CA, USA) according to the manufacturer’s protocol. All operations were carried out under enzyme-free conditions. For RT-qPCR detection, cDNA synthesis was performed using modified Moloney murine leukemia virus reverse transcriptase (RR047A, TaKaRa, Tokyo, Japan). The SYBR Green qPCR Master Mix with special primers was utilized for RT-qPCR analysis on a Bio-Rad CFX Connect Real-time PCR Detection System (Bio-Rad). The fold change was examined using the 2−ΔΔCt method with β-actin serving as the internal control (Supplementary File 1). All primers used in the study are listed in Supplementary Table 1.

Immunohistochemistry

Immunohistochemistry was performed as described.14 After fixation of liver tissues with 4% paraformaldehyde, paraffin-embedded sections were prepared according to the standard procedure and stored at room temperature. The tissue sections were incubated overnight with primary antibodies at 4 °C, followed by coating with biotin-labelled sheep anti-mouse/-rabbit IgG polymer (ZSGB-BIO, Beijing, China) at room temperature for 30 minutes. Diaminobenzidine solution (ZLI-9019, ZSGB-BIO, Beijing, China) was applied for colour development at the end. The Pannoramic Scan 250 Flash or MIDI system was used to scan the stained slides, and the Pannoramic Viewer 1.15.2 (3DHistech, Budapest, Hungary) was employed for image acquisition.

Dual-Luciferase reporter assay

Briefly, dual-Luciferase reporter assay was performed as previously described.15 A luciferase reporter plasmid containing the HBV core promoter Cp, X gene promoter Xp, and surface antigen promoters Sp1 and Sp2 was constructed using pGL3-Basic as a vector (constructed and preserved by the laboratory). Cells were co-transfected with plasmids pcDNA3.1, TK-RL, and the corresponding HBV promoter plasmids (pGL3-Cp, pGL3-Xp, pGL3-Sp1, pGL3-Sp2). After 48 hours of incubation, the luciferase activity was quantified using the Dual-Luciferase Reporter Gene Assay Kit (Promega, Madison, WI, USA) according to the manufacturer’s guidelines.

RNA sequencing

Mouse liver tissues harvested from PTX and CON groups were snap-frozen in liquid nitrogen and used for transcriptome sequencing. RNA sequencing analysis was conducted at Shanghai Majorbio Bio-pharm Technology Co. Ltd. (Shanghai, China) following the manufacturer’s descriptions. Total RNA was extracted using TRIzol® Reagent and the mRNA was purified using oligo (dT) beads for library construction. The paired-end RNA sequencing library was subjected to sequencing using the Illumina NovaSeq 6000 sequencer, with a read length of 2×150 bp, to generate the sequencing data.

16S rRNA sequencing

Samples of intestinal contents were collected and total DNA was extracted. PCR was employed to amplify the 16S rRNA of bacteria present in the samples. The resulting PCR products were detected by agarose gel electrophoresis. Based on the initial quantitative analysis of the electrophoresis results, the PCR products were measured using the fluorescence-based quantification method. Subsequently, high-throughput sequencing was conducted using the Illumina platform. The sequence of 338F was 5′-ACTC CTACGGGAGGCAGCAG-3′, and the sequence of 806R was 5′-GGACTACHVGGGTWTCT AAT-3′. The primer sequences have been previously reported.16

Statistical analysis

GraphPad Prism 8.0 was used for statistical analyses. For continuous variables, mean (±standard deviation) values from three independent experiments are presented. Inter-group comparisons were conducted using the t-test, while one-way ANOVA was used for multi-group comparisons. P values <0.05 were considered indicative of statistical significance.

Results

Paclitaxel directly stimulates HBV replication in vitro

We utilized the stable HBV-expression hepatocellular carcinoma (HCC) cell line (HepAD38, HepG2.2.15) and the HBV naturally infected cell model (HepG2-NTCP) to investigate whether PTX has a direct effect on HBV replication in vitro. Initially, we assessed the cytotoxicity of PTX within a specific concentration range (0–4 µM) and found that it had a low cytotoxic effect, with cell viability >80% (Supplementary Fig. 1A). Furthermore, the IC50 value of PTX was determined using the CCK8 assay kit. The IC50 value of PTX in HepAD38, HepG2-NTCP, and HepG2.2.15 was 4.468 µM, 5.562 µM, and 6.489 µM, respectively (Supplementary Fig. 1B). To assess the impact of PTX on HBV replication within a secure range, we incubated HepAD38 and HepG2-NTCP cells with PTX at concentrations ranging from 0 to 4 µM.

Following treatment of cells with PTX at various concentrations (0–4 µM) for 120 hours, the intracellular HBV 3.5-kb mRNA levels (Fig. 1A), HBV DNA levels (Fig. 1B), and HBV cccDNA levels (Fig. 1C) were significantly increased in a concentration-dependent manner. The intracellular HBcAg expression was similarly increased (Fig. 1D–E). Enzyme-linked immunosorbent assay (ELISA) of cell culture supernatants showed that PTX treatment enhanced HBeAg and HBsAg secretion levels (Fig. 1F and Supplementary Fig. 2A) in a concentration-dependent manner. Similar findings were observed in HepG2.2.15 cells (Supplementary Fig. 2B–F). These findings indicated that PTX may potentially enhance HBV replication in vitro.

PTX enhances HBV replication <italic>in vitro</italic>.
Fig. 1  PTX enhances HBV replication in vitro.

(A–C) qPCR assay was employed to quantify the levels of HBV 3.5-Kb mRNA, HBV DNA, and HBV cccDNA in both HepAD38 cells and HepG2-NTCP cells following PTX treatment. (D–E) Immunoblot analysis of HBcAg expression levels in HepAD38 cells and HepG2-NTCP cells. Densitometry analysis was used to measure the relative levels of HBcAg. (F) Results of ELISA showing HBeAg levels in the culture medium supernatants of HepAD38 cells and HepG2-NTCP cells. Mean±SD values from three independent experiments are presented. Statistical significance was assessed using the t-test. *p<0.05, **p<0.01, ***p<0.001. HBV, hepatitis B virus; PTX, paclitaxel; HBV cccDNA, HBV covalently closed circular DNA; HBcAg, hepatitis B core antigen; HBeAg, hepatitis B e-antigen; GAPDH, glyceraldehyde-3-phosphate dehydrogenase.

Paclitaxel can promote HBV replication in vivo

The impact of PTX on HBV replication in vivo was investigated using HBV-Tg mice. HBV-Tg mice were divided into 2 groups (n=8). Intraperitoneal injection of PTX (10 mg/kg) was administered in the PTX group while PBS was administered in the control group (Con). The injections were administered every other day for a total of seven injections (Fig. 2A). The observation time was extended to one week after the withdrawal of the drug. Serum samples of the mice were collected on the 7th, 14th, and 21st day, respectively. PTX administration resulted in a significant increase in serum HBV DNA levels, along with increased levels of HBeAg and HBsAg (Figure. 2B–D), but their secretion levels showed a slight decrease one week after drug withdrawal. HBV 3.5-kb mRNA, HBV DNA, and HBV cccDNA levels in the liver were also significantly increased (Fig. 2E–G). Immunohistochemical staining showed a significant increase in HBcAg and HBsAg protein expression in hepatocytes (Fig. 2H), which was correlated with the duration of drug action, and the replication levels were slightly decreased after drug withdrawal. In conclusion, PTX treatment significantly enhanced HBV replication levels in HBV-Tg mice. We also detected serum levels of alanine aminotransferase (ALT) and aspartate aminotransferase (AST) levels to explore whether PTX-mediated HBV reactivation would induce liver injury. Our findings suggested no significant damaging effect of PTX on the liver of HBV transgenic mice (Supplementary Fig. 2G–H). We speculated that the time point of our observations may be in the active phase of HBV replication, which has not yet progressed to the phase of hepatic impairment.

PTX administration promotes viral biosynthesis <italic>in vivo</italic>.
Fig. 2  PTX administration promotes viral biosynthesis in vivo.

(A) Schematic illustration of the PTX treatment regimen in HBV transgenic mice. (B) HBV DNA levels in mouse serum were quantified using qPCR. (C–D) HBeAg and HBsAg levels in mouse serum were measured using ELISA. (E–G) The levels of HBV 3.5-Kb mRNA, HBV DNA, and HBV cccDNA in liver tissues were determined using qPCR. (H) Immunohistochemistry analysis of HBcAg and HBsAg expression in liver tissues (scale bar: 60 µm). Mean±SD values from three independent experiments are presented. *p<0.05, **p<0.01, and ***p<0.001 vs. PBS control. HBV, hepatitis B virus; HBV-Tg mice, HBV-transgenic mice; PTX, paclitaxel; HBcAg, hepatitis B core antigen; HBeAg, hepatitis B e-antigen; HBsAg, hepatitis B surface antigen; HBV cccDNA, HBV covalently closed circular DNA.

Paclitaxel treatment induces altered gene expression in HBV-Tg mice

We performed liver transcriptome analysis to further explore the molecular mechanism of PTX-induced HBV reactivation. The PCA plot (Fig. 3A) showed clustering of samples in the Con and PTX groups with a clear separation of samples in each group. This indicated the repeatability of samples in each group. Using the criteria of adjusted P value <0.05 and Fold change ≥2, we found significant up-regulation of 453 genes and significant down-regulation of 259 genes in the PTX group compared to the Con group (Fig. 3B). KEGG enrichment analysis of differentially expressed genes (DEGs) revealed notable enrichment of various biological processes, including cancer:overview, infectious disease:viral, immune system and signal transduction (Fig. 3C–D). Further analysis revealed that PTX upregulates immune response-related pathways such as the IL-17 signaling pathway, NF-Kappa B signaling pathway, and MAPK signaling pathway (Fig. 3E). The heatmaps depicting the enrichment of the DEGs in the three immune response pathways are presented in Figure 3F–H. Transcription factor family statistics were also performed on the DEGs. The results showed that they could be clustered in the Fos related Jun related transcription factor family (Fig. 3I), including Jun, Fosl2, and Jund. Jun is a member of the AP-1 family, and AP-1 has been reported to have a significant impact on HBV replication.17

Differentially expressed genes (DEGs) in the liver tissues of PTX-treated (PTX) mice and control (Con) mice.
Fig. 3  Differentially expressed genes (DEGs) in the liver tissues of PTX-treated (PTX) mice and control (Con) mice.

(A) Principal component analysis (PCA) of transcriptional analysis of liver tissue of mice in Con and PTX groups. (B) Statistical chart of significantly up- and down-regulated genes (P-value < 0.05 and at least twofold change) in Con vs PTX. (C–D) The distribution of Kyoto Encyclopedia of Genes and Genomes (KEGG) terms for different pathways assigned to significantly up-regulated and down-regulated genes. (E) The top 20 significantly changed pathways analyzed by KEGG pathway enrichment. (F–H) Heatmap of three immune-related pathways enriched in the DEGs. (I) Statistical chart of transcription factor family among the Con and PTX groups. PCA, Principal component analysis; KEGG, Kyoto Encyclopedia of Genes and Genomes.

AP-1 activation can stimulate HBV replication

HBV replication is known to be finely regulated by a wide range of liver-enriched transcription factors. Therefore, we screened the transcription factors involved in the regulation of HBV expression and analyzed their expression levels after PTX treatment. We observed a remarkable increase in the mRNA levels of transcription factors AP-1 and CREB1 (Fig. 4A, Fig. 3A). Notably, AP-1 exhibited a greater increase, which was consistent with the results of transcriptome sequencing (Fig. 3I). Additionally, the protein expression of the c-Jun subunit of AP-1 was also significantly increased (Fig. 4B, Supplementary Fig. 3B). Previous in vitro investigations have shown that PTX induces upregulation of AP-1 mRNA and protein levels, and we verified whether PTX promotes the enhancement of AP-1 activity in HBV-Tg mice. Immunohistochemistry showed a significant increase in AP-1 protein levels in the liver tissues of mice on the 14th day of PTX administration and one week after withdrawal of the drug (day 21) as compared to the PBS control (Fig. 4C). Based on these findings, we selected AP-1 as the target for further investigation in subsequent experiments. To validate the role of AP-1 in HBV replication, we employed siRNA targeting to silence AP-1 expression (Fig. 4D–E, Supplementary Fig. 3C–D). Silencing of AP-1 led to downregulation of the expression levels of HBV 3.5-kb mRNA, HBV DNA, and HBV cccDNA (Fig. 4F–H). The protein expression of HBcAg was decreased, while the levels of HBeAg and HBsAg in the supernatant were reduced (Fig. 4I–K), suggesting that silencing AP-1 significantly inhibited the replication levels of HBV-expressing cells.

Effect of AP-1 on HBV replication.
Fig. 4  Effect of AP-1 on HBV replication.

(A) Gene expression of HBV replication-associated transcription factors in HepAD38 cells analyzed by qPCR. (B) Immunoblot analysis of c-Jun expression levels in HepAD38 cells after PTX treatment. Relative levels of c-Jun were measured by densitometry. (C) Immunohistochemical staining of c-Jun in the liver tissue (scale bar: 60 µm). (D–E) Transcription and protein expression of AP-1 in HepAD38 cells following AP-1 silencing. (F–H) qPCR analysis of 3.5-kb mRNA, HBV DNA, and HBV cccDNA expression levels following AP-1 silencing. (I–J) Quantitative analysis of ELISA for HBeAg and HBsAg levels in HepAD38 cells following AP-1 silencing. (K) Immunoblot analysis of HBcAg expression levels in HepAD38 and HepG2-NTCP following AP-1 silencing. Mean ± SD values from 3 independent experiments are presented. *p<0.05, **p<0.01, ***p<0.001. PTX, paclitaxel; AP-1, activator protein 1; HBV, hepatitis B virus; HBeAg, hepatitis B e-antigen; HBsAg, hepatitis B surface antigen; HBV cccDNA, HBV covalently closed circular DNA; GAPDH, glyceraldehyde-3-phosphate dehydrogenase.

PTX enhances viral HBV replication by activating the binding of AP-1 to HBV core promoter

Numerous transcription factors can bind to HBV promoter/enhancer elements to regulate HBV transcription and replication. We found that PTX induced AP-1 activation to promote HBV transcription and replication, but the specific mechanism by which AP-1 regulates HBV transcription and replication is not clear. We initially assessed the impact of PTX on the activity of four HBV promoters: HBV Cp, HBV Xp, HBV Sp1, and HBV Sp2. The findings indicated a notable enhancement in the activity of the core promoter (Fig. 5A, Supplementary Fig. 3E). Silencing of AP-1 affected the activity of the HBV core promoter (Fig. 5B, Supplementary Fig. 3F), while CHIP assays suggested an interaction between AP-1 and the HBV core promoter (Fig. 5C, Supplementary Fig. 3G). Because silencing of AP-1 inhibited HBV replication, we further explored whether PTX promotes HBV replication by modulating AP-1 activity and thereby promoting HBV replication. The promotion of HBV 3.5-kb mRNA, HBV DNA, and HBV cccDNA was significantly attenuated after targeted silencing of AP-1 (Fig. 5D–F, Supplementary Fig. 3H–J). The increased HBeAg and HBsAg secretion levels and HBcAg protein expression levels were also significantly ameliorated (Fig. 5G–I, Supplementary Fig. 3K–M). Moreover, we used pGEM-HBV1.3MUT plasmid containing mutated AP-1 binding site and found that mutation of the AP-1 binding site in the HBV core promoter abrogated PTX-induced elevation of HBV replication level (Fig. 5J–O). These findings suggested that PTX may enhance viral replication by activating the binding of AP-1 to the HBV core promoter.

PTX enhances viral HBV replication by activating the binding of AP-1 to HBV core promoter.
Fig. 5  PTX enhances viral HBV replication by activating the binding of AP-1 to HBV core promoter.

(A) HepG2-NTCP cells treated with 4 µM PTX for 48 h after 12 h of transfection with HBV core, PreS1, PreS2, or X promoter luciferase reporter vectors. (B) Dual-luciferase reporter assays for detecting the effect of silencing AP-1 on HBV promoter activity. (C) CHIP-qPCR assay was used to detect the interaction between AP-1 and HBV core promoter. (D–F) Quantitative analysis of qPCR results showing the effect of silencing AP-1 on the PTX regulation of 3.5-kb mRNA, HBV DNA, and HBV cccDNA levels in HepAD38 cells. (G–H) ELISA analysis of the effect of silencing AP-1 in HepAD38 cells on PTX regulation of HBeAg and HBsAg levels. (I) Immunoblot analysis of HBcAg expression levels in AP-1 silenced HepAD38 cells. +, siAP-1 or PTX; – , siControl or DMSO. (J–L) HepG2 cells were transfected with pGEM-HBV1.3 or pGEM-HBV1.3MUT, and then treated with 4 µM PTX. qPCR assay was employed to quantify the levels of HBV 3.5-Kb mRNA, HBV DNA, and HBV cccDNA. (M–O) ELISA assays were used to detect HBeAg and HBsAg levels in the culture medium supernatant. (O) Immunoblot analysis of HBcAg expression levels in HepG2 cells. Mean±SD values from three independent experiments are presented. *p<0.05, **p<0.01, ***p<0.001. PTX, paclitaxel; HBV Cp, HBV core promoter; HBV Xp, HBV X promoter; HBV Sp1, HBV pre S1 promoter; HBV Sp2, HBV pre S2 promoter; AP-1, activator protein 1; HBV, hepatitis B virus; WT, wild type; Mut, mutant; HBcAg, hepatitis B core antigen; HbeAg, hepatitis B e-antigen; HbsAg, hepatitis B surface antigen; GAPDH, glyceraldehyde-3-phosphate dehydrogenase.

Dysbiosis of gut microbiota induced by PTX treatment

To assess the effects of PTX administration on the gut microbiota, we performed 16S rRNA sequencing. The results of the rarefaction curve of the Sobs index at the ASV level showed a leveling-off of the rarefaction curves of both the Con and PTX groups, with sufficient sequencing volume to cover the microbial communities in all samples (Fig. 6A). The analysis of α-diversity, as measured by the Chao1 index and Shannon index, showed no significant differences between the groups (Fig. 6B–C). The results of the hierarchical clustering tree at the ASV level showed significant clustering of the colony structure in both Con and PTX groups (Fig. 6D). The PCoA plot (Fig. 6E), also built from the heterogeneity matrix using the Bray-Curtis index to explain the β-diversity, showed individual clustering between the groups, showing significant differences at the ASV level. These results indicated that PTX treatment altered the composition of the gut microbiota in HBV-Tg mice. A total of 354 ASVs were shared in both groups, while 213 and 239 ASVs were exclusively found in Con and PTX groups, respectively (Fig. 6F). The relative abundance of bacteria was assessed at both the phylum and genus levels (Fig. 6G–H). Using the Kruskal-Wallis rank-sum test, we observed a significant increase in the relative abundance of Campilobacterota and Deferribacterota at the phylum level in the PTX group compared to the Con group. Conversely, the relative abundance of Actinobacteriota was significantly lower in the PTX group (Fig. 6I). At the genus level, the proportional representation of detrimental bacteria such as Escherichia-Shigella, Helicobacter, and unclassified_o__Oscillospirales was remarkably elevated in the PTX group, while the proportional representation of advantageous bacteria such as norank_f__Muribaculaceae, Dubosiella, Allobaculum, norank_f__Lachnospiraceae, and Enterorhabdus were considerably reduced.

Changes in the gut microbiota of HBV-Tg mice following treatment with PTX.
Fig. 6  Changes in the gut microbiota of HBV-Tg mice following treatment with PTX.

(A) Rarefaction curve at the ASV level; (B–C) Chao index and Shannon index calculated at the ASV level; (D–E) The β-diversity of ASV-level microbial community was evaluated using hierarchical clustering (D) and principal coordinate analysis (PcoA) I. (F) Venn diagram of common and peculiar ASVs in the two groups. (G–H) The relative occurrence of bacteria at the phylum (G) and genus (H) levels. (I–J) Comparative analysis at the phylum level (I) and genus level (J). *p<0.05, **p<0.01. PCoA, principal coordinate analysis; Con, control; PTX, paclitaxel.

Discussion

The persistence of HBV cccDNA within the nucleus of infected hepatocytes provides the virological foundation for HBV reactivation. Disruptions in the balance between viral replication and host immune control, resulting from alterations in either the virus or the immune system, can lead to HBV reactivation. Immunosuppression induced by antineoplastic drugs may impair control of HBV replication. It may also directly promote HBV replication, leading to HBV reactivation.18 Immunomodulators, such as corticosteroids, not only inhibit the function of cytotoxic T-cells but also activate regulatory elements within the HBV gene in cultured human HCC cells, thereby promoting HBV replication.19 Cisplatin-induced autophagy was found to enhance HBV replication by triggering the ROS/JNK pathway and inhibiting the Akt/mTOR signaling pathway.20 The present study demonstrates that PTX may activate HBV core promoter activity, thereby enhancing HBV replication through the activation of the transcription factor AP-1. Furthermore, we conducted transcriptome sequencing and 16S rRNA sequencing to perform a comprehensive quantitative analysis of the changes in the transcriptome and microbial diversity of HBV-Tg mice following PTX treatment, which may reduce host resistance to HBV infection.

PTX is a class of cytotoxic drugs commonly used in the management of diverse cancer types, including advanced ovarian cancer, metastatic breast cancer, and non-small cell lung cancer.21 It is often used in combination with other chemotherapeutic agents or hormones. PTX has been reported as one of the chemotherapeutic agents associated with HBV reactivation.22 Trastuzumab in combination with PTX was found to increase the risk of HBV reactivation.23 A case report documented PTX-induced HBV reactivation in a breast cancer patient who eventually died due to severe liver and kidney failure.11 However, there is no clear consensus on whether HBV reactivation occurs as a result of the underlying disease itself, the PTX treatment, or the interaction between the two factors.4 In the present study, PTX was found to directly promote HBV replication in vitro in a concentration-dependent manner. The in vivo study using HBV-Tg mice also suggested that PTX promotes HBV reactivation.

In the present study, PTX treatment increased the activity of the HBV core promoter. Further investigation identified AP-1 as a potential regulator of the HBV core promoter in response to PTX. The AP-1 transcription factor is composed of Jun proteins (c-Jun, JunB, and JunD), Fos proteins (c-Fos, FosB, Fra-1, and Fra-2), as well as ATF and MAF proteins, forming a dimeric complex.24 Activation of AP-1 has been linked to different aspects of cancer biology, such as apoptosis, metastasis, cell growth, angiogenesis, invasion, and drug resistance.25 The transcription factor AP-1 plays a crucial role in many aspects of liver biology. For instance, treatment with nitidine chloride was shown to induce mitochondrial damage and apoptosis in hepatocytes through the activation of the JNK/c-Jun signaling pathway.26 Additionally, the histone methyltransferase SETD2 was found to induce the activation of c-Jun/AP-1 in the liver by promoting the accumulation of lipids, thereby contributing to hepatocellular carcinogenesis.27 AP-1 has also been implicated in the pathogenesis of viral hepatitis,28 as HBX interacts with Jab1 to enhance AP-1 activation.29 AP-1 has been shown to bind to the Enh II/Xp region of the HBV genome.17 Additionally, AP-1 binding motifs have been identified in the Enh II/Cp region of HBV.30 In the present study, PTX-mediated activation of AP-1 had no significant effect on HBV X promoter activity. PTX-mediated HBV reactivation is a complex process, and the activity of the HBV X promoter may also be regulated by multiple factors, possibly by transcription factors other than AP-1. Our results offer additional support for the role of AP-1 in controlling HBV replication and its involvement in modulating the activity of the HBV core promoter upon PTX treatment.

For an in-depth characterization of the mechanism underlying the regulation of HBV by PTX, we performed additional investigations by integrating transcriptome and gut microbiota sequencing. Transcriptome sequencing results revealed significant changes in biological processes such as viral infectious diseases, immune system, and signal transduction after PTX treatment. We detected enrichment of immune response-related DEGs in the liver, such as the IL-17 signaling pathway, NF-KappaB signaling pathway, and MAPK signaling pathway,31–33 which are critical modulators of the immune response. Previous studies have indicated that immunosuppressive agents or chemotherapy drugs can induce immune system dysregulation, leading to HBV reactivation. Transcriptome sequencing suggested that PTX not only directly promotes HBV replication but also enhances HBV replication by inducing immune dysfunction and inflammatory responses. PTX-induced HBV reactivation may be a combined result of immunosuppression and direct enhancement of HBV replication. Additionally, our analysis of transcription factor families in liver DEGs revealed a concentration of Fos related::Jun related transcription factor families, which were consistent with our in vitro results. The gut microbiota has a pivotal influence on the maintenance of intestinal homeostasis and liver health via the intricate interplay of the gut–liver axis,34 and dysbiosis of the gut microbiota is associated with immune imbalance.35 Emerging research has revealed a correlation between dyshomeostasis of gut microbiota and the onset and progression of viral hepatitis.36 We observed significant differences between the PTX and Con groups with respect to the microbial structure and composition within the colon. The relative occurrence of harmful bacteria was significantly increased in the PTX group, while the relative occurrence of beneficial bacteria was significantly decreased. This suggested that PTX-induced dysbiosis of the gut microbiota may be one of the reasons for immune imbalance, ultimately leading to enhanced HBV replication.

Conclusion

In this study, PTX treatment was found to directly promote HBV replication and transcription, leading to HBV reactivation in HBV stable expression cell models, HBV natural infection cell models, and HBV transgenic mouse models. Further molecular analysis indicated that PTX may enhance HBV replication and transcription through the promotion of HBV core promoter activity mediated by the transcription factor AP-1. Furthermore, PTX treatment was found to induce immune system dysregulation and dysbiosis of the gut microbiota, which may potentially contribute to the induction of HBV reactivation. However, it is important to acknowledge that our experimental models may not fully replicate the complex dynamics of HBV infection and reactivation observed in clinical patients. Therefore, more comprehensive and in-depth research is required to provide references for the development of prevention and treatment strategies for clinical HBV reactivation.

Supporting information

Supplementary File 1

Supplementary materials and methods.

(DOCX)

Supplementary Tabel 1

siRNA target sequences and primer sequences.

(DOCX)

Supplementary Fig. 1

Effect of PTX on cell viability.

HBV-expression HCC cell line (HepAD38, HepG2.2.15) and HBV naturally infected cell model (HepG2-NTCP) were incubated with various concentrations of PTX for a duration of 120 hours. (A) Effect of PTX on the cell viability of HepAD38, HepG2-NTCP and HepG2.2.15 by Trypan blue staining. (B) The half-maximal inhibitory concentration (IC50) of PTX in HepAD38, HepG2-NTCP and HepG2.2.15 using the CCK-8 assay. Mean ± SD values from 3 independent experiments are presented. *p < 0.05 and **p < 0.01. PTX, paclitaxel; IC50, half-maximal inhibitory concentration.

(TIF)

Supplementary Fig. 2

PTX enhances HBV replication in HBV-expressing hepatoma cells.

(A) ELISA-detected HBsAg secretion levels in the supernatants of culture medium of HepAD38 cells and HepG2-NTCP cells. (B–D) Quantification of HBV 3.5-Kb mRNA, HBV DNA and HBV cccDNA levels by qPCR assay in HepG2.2.15 cells treated with PTX. (E–F) ELISA-detected HBeAg and HBsAg secretion levels in the supernatants of culture medium of HepG2.2.15 cells. (G–H) ALT and AST levels of HBV Tg mice after PTX treatment. Mean ± SD values from 3 independent experiments are presented. *p < 0.05 and **p < 0.01. HBV, hepatitis B virus; PTX, paclitaxel; HBV cccDNA, HBV covalently closed circular DNA; HBcAg, hepatitis B core antigen; HBeAg, hepatitis B e-antigen. ALT/AST, alanine and aspartic aminotransferase

(TIF)

Supplementary Fig. 3

Effect of AP-1 on the HBV genome transcription and replication in HBV-expressing hepatoma cells.

(A) qPCR analysis of gene expression of various transcription factors related to HBV replication in HepG2-NTCP cells. (B) Immunoblot analysis of c-Jun expressing levels in HepG2-NTCP cells after PTX treatment. Relative levels of c-Jun were measured by densitometry. (C–D) mRNA and protein levels of AP-1 expression in HepG2-NTCP cells following AP-1 silencing. (E) Effect of PTX on four HBV promoters in Huh7 cells. (F) Dual-luciferase reporter assays for detecting the effect of silencing AP-1 on HBV promoter activity in Huh7 cells. (G) CHIP-qPCR assays were used to detect the interaction between AP-1 and HBV core promoter in HepG2-NTCP cells. (H–J) qPCR analysis of the effect of silencing AP-1 on PTX regulation of 3.5-kb mRNA, HBV DNA and HBV cccDNA levels in HepG2-NTCP cells. (K–L) ELISA analysis of the effect of silencing AP-1 in HepAD38 cells on PTX regulation of HBeAg and HBsAg levels in HepG2-NTCP cells. (M) Immunoblot analysis of HBcAg expression levels in AP-1 silencing HepG2-NTCP cells. Data were presented as the mean ± SD of three independent experiments. *p < 0.05 and **p < 0.01. HBV, hepatitis B virus; HBcAg, hepatitis B core antigen; HBeAg, hepatitis B e-antigen; HBsAg, hepatitis B surface antigen; HBV cccDNA, HBV covalently closed circular DNA; HBV Cp, HBV core promoter; HBV Xp, HBV X promoter; HBV Sp1, HBV pre S1 promoter; HBV Sp2, HBV pre S2 promoter; GAPDH, glyceraldehyde-3-phosphate dehydrogenase.

(TIF)

Abbreviations

AP-1: 

activator protein 1

ALT/AST: 

alanine and aspartic aminotransferase

CCK-8: 

cell counting kit-8

COUP-TF1: 

Chicken ovalbumin upstream promoter 1

CREB1: 

cAMP responsive element binding protein 1

DEGs: 

differentially expressed genes

ELISA: 

Enzyme-linked immunosorbent assay

HBV: 

hepatitis B virus

HBcAg: 

hepatitis B core antigen

HBeAg: 

hepatitis B e-antigen

HBsAg: 

hepatitis B surface antigen

HBV cccDNA: 

HBV covalently closed circular DNA

HBV rcDNA: 

HBV released relaxed circular DNA

HBV-Tg mice: 

HBV-transgenic mice

HBV Cp: 

HBV core promoter

HBV Xp: 

HBV X promoter

HBV Sp1: 

HBV pre S1 promoter

HBV Sp2: 

HBV pre S2 promoter

HCC: 

hepatocellular carcinoma

HNF-4α: 

hepatocyte nuclear factor 4 alpha

MAPK: 

mitogen-activated protein kinase

NF-κB: 

nuclear factor kappa-B

NTCP: 

sodium taurocholate cotransporting polypeptide

PBS: 

phosphate buffered saline

PGC-1α: 

peroxisome proliferator-activated receptor-γ coactivator-1α

PPARα: 

peroxisome proliferator-activated receptor alpha

PTX: 

paclitaxel

Declarations

Ethical statement

The animal study conducted in this research was subjected to a thorough review and approval process by the Laboratory Animal Center of Chongqing Medical University (IACUC-CQMU-2023-0342). The study followed the prescribed national protocols and regulations in China regarding the utilization of experimental animals and their well-being.

Data sharing statement

The raw data presented in the study have been deposited in the NCBI Sequence Read Archive (Bioproject ID:PRJNA1081780 and PRJNA1081628 ). All other data used in the study are available from the corresponding author upon reasonable request.

Funding

This research received financial support from various sources including the Innovation and Development Joint Fund of Chongqing Natural Science Foundation (Grant number CSTB2023NSCQ-LZX0099), Chongqing Science and Health Joint Medical High-end Talent Project (Grant No. 2022GDRC012), Chongqing Biomedical R&D Major Special Project (Grant No. CSTB2022TIAD-STX0013), Science and Technology Research Program of Chongqing Municipal Education Commission (Grant No. KJZD-K202100402), CQMU Program for Youth Innovation in Future Medicine (Grant No. W0073), and the Southwest Medical University and Affiliated Traditional Chinese Medicine Hospital of Southwest Medical University Joint Project(Grant No. 2020XYLH- 021).

Conflict of interest

The authors have no conflict of interests related to this publication.

Authors’ contributions

Conceptualization and study design were conducted by JG, LC, and XL. AR was responsible for developing the methodology structure. Data acquisition was performed by SC, BL, and QY. SC, BL, and WL were also involved in data processing and interpretation. The manuscript was drafted by SC, MH, and SW. JG, LC, and XL provided materials and technical support. SC, WL, and QY critically revised the manuscript for important intellectual content. SC and SW supervised the study. All authors have made significant contributions to the article and have provided their consent for the publication of the final version.

References

  1. Cui F, Blach S, Manzengo Mingiedi C, Gonzalez MA, et al. Global reporting of progress towards elimination of hepatitis B and hepatitis C. Lancet Gastroenterol Hepatol 2023;8(4):332-342 View Article PubMed/NCBI
  2. Jeng WJ, Papatheodoridis GV, Lok ASF. Hepatitis B. Lancet 2023;401(10381):1039-1052 View Article PubMed/NCBI
  3. You H, Sun YM, Zhang MY, Nan YM, Xu XY, et al. Interpretation of the essential updates in guidelines for the prevention and treatment of chronic hepatitis B (Version 2022). Zhonghua Gan Zang Bing Za Zhi 2023;31(4):385-388 View Article PubMed/NCBI
  4. Shi Y, Zheng M. Hepatitis B virus persistence and reactivation. BMJ 2020;370:m2200 View Article PubMed/NCBI
  5. Nassal M. HBV cccDNA: viral persistence reservoir and key obstacle for a cure of chronic hepatitis B. Gut 2015;64(12):1972-84 View Article PubMed/NCBI
  6. Lau G, Yu ML, Wong G, Thompson A, Ghazinian H, et al. Correction to: APASL clinical practice guideline on hepatitis B reactivation related to the use of immunosuppressive therapy. Hepatol Int 2022;16(2):486-487 View Article PubMed/NCBI
  7. Lam LK, Chan TSY, Hwang YY, Mak LY, Seto WK, Kwong YL, et al. Hepatitis B virus reactivation in seronegative occult hepatitis B patient receiving ibrutinib therapy. Virol J 2023;20(1):168 View Article PubMed/NCBI
  8. Hwang JP, Lok AS. Management of patients with hepatitis B who require immunosuppressive therapy. Nat Rev Gastroenterol Hepatol 2014;11(4):209-219 View Article PubMed/NCBI
  9. Schwarz C, Morel A, Matignon M, Grimbert P, Rondeau E, Ouali N, et al. Hepatitis B Virus Reactivation in Kidney Transplant Recipients Treated With Belatacept. Kidney Int Rep 2023;8(8):1531-1541 View Article PubMed/NCBI
  10. Cheng AL, Hsiung CA, Su IJ, Chen PJ, Chang MC, Tsao CJ, et al. Steroid-free chemotherapy decreases risk of hepatitis B virus (HBV) reactivation in HBV-carriers with lymphoma. Hepatology 2003;37(6):1320-8 View Article PubMed/NCBI
  11. Remo M, Abraham I, Kankanala V, Chacra W, Danciu OC. Hepatitis B Reactivation in a Patient Receiving Chemotherapy for Breast Cancer: A Case Report. Anticancer Res 2017;37(7):3791-3793 View Article PubMed/NCBI
  12. Yang Y, Yan Y, Chen Z, Hu J, Wang K, Tang N, et al. Histone Deacetylase Inhibitors Romidepsin and Vorinostat Promote Hepatitis B Virus Replication by Inducing Cell Cycle Arrest. J Clin Transl Hepatol 2021;9(2):160-168 View Article PubMed/NCBI
  13. Yin J, Feng Z, Li Z, Hu J, Hu Y, Cai X, et al. Synthesis and evaluation of N-sulfonylpiperidine-3-carboxamide derivatives as capsid assembly modulators inhibiting HBV in vitro and in HBV-transgenic mice. Eur J Med Chem 2023;249:115141 View Article PubMed/NCBI
  14. Yin Y, Sichler A, Ecker J, Laschinger M, Liebisch G, Höring M, et al. Gut microbiota promote liver regeneration through hepatic membrane phospholipid biosynthesis. J Hepatol 2023;78(4):820-835 View Article PubMed/NCBI
  15. Chen CC, Xie XM, Zhao XK, Zuo S, Li HY. Krüppel-like Factor 13 Promotes HCC Progression by Transcriptional Regulation of HMGCS1-mediated Cholesterol Synthesis. J Clin Transl Hepatol 2022;10(6):1125-1137 View Article PubMed/NCBI
  16. Liu C, Zhao D, Ma W, Guo Y, Wang A, Wang Q, et al. Denitrifying sulfide removal process on high-salinity wastewaters in the presence of Halomonas sp. Appl Microbiol Biotechnol 2016;100(3):1421-1426 View Article PubMed/NCBI
  17. Quasdorff M, Protzer U. Control of hepatitis B virus at the level of transcription. J Viral Hepat 2010;17(8):527-36 View Article PubMed/NCBI
  18. Yeo W, Chan TC, Leung NW, Lam WY, Mo FK, Chu MT, et al. Hepatitis B virus reactivation in lymphoma patients with prior resolved hepatitis B undergoing anticancer therapy with or without rituximab. J Clin Oncol 2009;27(4):605-611 View Article PubMed/NCBI
  19. Tur-Kaspa R, Burk RD, Shaul Y, Shafritz DA. Hepatitis B virus DNA contains a glucocorticoid-responsive element. Proc Natl Acad Sci USA 1986;83(6):1627-1631 View Article PubMed/NCBI
  20. Chen X, Hu Y, Zhang W, Chen K, Hu J, Li X, et al. Cisplatin induces autophagy to enhance hepatitis B virus replication via activation of ROS/JNK and inhibition of the Akt/mTOR pathway. Free Radic Biol Med 2019;131:225-236 View Article PubMed/NCBI
  21. Zhang D, Yang R, Wang S, Dong Z. Paclitaxel: new uses for an old drug. Drug Des Devel Ther 2014;8:279-284 View Article PubMed/NCBI
  22. Yazaki S, Yamauchi T, Higashi T. High hepatitis B virus screening rate among patients receiving systemic anticancer treatment in Japan. Int J Clin Oncol 2020;25(7):1327-1333 View Article PubMed/NCBI
  23. Sanagawa A, Hotta Y, Kataoka T, Maeda Y, Kondo M, Kawade Y, et al. Hepatitis B infection reported with cancer chemotherapy: analyzing the US FDA Adverse Event Reporting System. Cancer Med 2018;7(6):2269-2279 View Article PubMed/NCBI
  24. Kappelmann M, Bosserhoff A, Kuphal S. AP-1/c-Jun transcription factors: regulation and function in malignant melanoma. Eur J Cell Biol 2014;93(1-2):76-81 View Article PubMed/NCBI
  25. Song D, Lian Y, Zhang L. The potential of activator protein 1 (AP-1) in cancer targeted therapy. Front Immunol 2023;14:1224892 View Article PubMed/NCBI
  26. Chen S, Liao Y, Lv J, Hou H, Feng J. Quantitative Proteomics Based on iTRAQ Reveal that Nitidine Chloride Induces Apoptosis by Activating JNK/c-Jun Signaling in Hepatocellular Carcinoma Cells. Planta Med 2022;88(13):1233-1244 View Article PubMed/NCBI
  27. Li XJ, Li QL, Ju LG, Zhao C, Zhao LS, Du JW, et al. Deficiency of Histone Methyltransferase SET Domain-Containing 2 in Liver Leads to Abnormal Lipid Metabolism and HCC. Hepatology 2021;73(5):1797-1815 View Article PubMed/NCBI
  28. Rzepka I, Zehetmair C, Nagy E, Kindermann D, Kölmel C, Friederich HC, et al. Psychological Burden of Refugees in Temporary Accommodations in the Rhine-Neckar Region, Baden-Wuerttemberg. Psychother Psychosom Med Psychol 2022;72(7):325-328 View Article PubMed/NCBI
  29. Tanaka Y, Kanai F, Ichimura T, Tateishi K, Asaoka Y, Guleng B, et al. The hepatitis B virus X protein enhances AP-1 activation through interaction with Jab1. Oncogene 2006;25(4):633-642 View Article PubMed/NCBI
  30. Ren JH, Tao Y, Zhang ZZ, Chen WX, Cai XF, Chen K, et al. Sirtuin 1 regulates hepatitis B virus transcription and replication by targeting transcription factor AP-1. J Virol 2014;88(5):2442-2451 View Article PubMed/NCBI
  31. McGeachy MJ, Cua DJ, Gaffen SL. The IL-17 Family of Cytokines in Health and Disease. Immunity 2019;50(4):892-906 View Article PubMed/NCBI
  32. Zheng K, Lv B, Wu L, Wang C, Xu H, Li X, et al. Protecting effect of emodin in experimental autoimmune encephalomyelitis mice by inhibiting microglia activation and inflammation via Myd88/PI3K/Akt/NF-κB signalling pathway. Bioengineered 2022;13(4):9322-9344 View Article PubMed/NCBI
  33. Armani E, Capaldi C, Bagnacani V, Saccani F, Aquino G, Puccini P, et al. Design, Synthesis, and Biological Characterization of Inhaled p38α/β MAPK Inhibitors for the Treatment of Lung Inflammatory Diseases. J Med Chem 2022;65(10):7170-7192 View Article PubMed/NCBI
  34. Lin L, Zhang J. Role of intestinal microbiota and metabolites on gut homeostasis and human diseases. BMC Immunol 2017;18(1):2 View Article PubMed/NCBI
  35. Yang W, Cong Y. Gut microbiota-derived metabolites in the regulation of host immune responses and immune-related inflammatory diseases. Cell Mol Immunol 2021;18(4):866-877 View Article PubMed/NCBI
  36. Chen Z, Xie Y, Zhou F, Zhang B, Wu J, Yang L, et al. Featured Gut Microbiomes Associated With the Progression of Chronic Hepatitis B Disease. Front Microbiol 2020;11:383 View Article PubMed/NCBI
  • Journal of Clinical and Translational Hepatology
  • pISSN 2225-0719
  • eISSN 2310-8819
  • Copyright © 2022 JCTH. All Rights Reserved.
  • Published by Xia & He Publishing Inc.
  • Address: 14090 Southwest Freeway, Suite 300, Sugar Land, Texas 77478, USA
  • Email: service@xiahepublishing.com