Kaltsa, Bamias, Siakavellas, Goukos, Karagiannakis, Zampeli, Vlachogiannakos, Michopoulos, Vafiadi, Daikos, and Ladas:

Introduction

Bacterial translocation (BT) is a major component of the pathophysiology of cirrhosis [1,2]. It is directly or indirectly involved in the pathogenesis of spontaneous bacterial peritonitis, hepatic encephalopathy, and hepatorenal syndrome [3]. All of these cirrhosis-related complications carry high morbidity and mortality; hence, BT may be considered as an adverse outcome and bad prognostic factor in the natural history of cirrhosis [4]. Therefore, recognition of BT in the individual patient may allow for timely intervention and improvement of the outcome [5]. It follows that discovery of surrogate markers for BT, especially soluble factors that can be easily detected in biological fluids, will be of great significance in this clinical setting. One such marker that has been found to be increased in patients with cirrhosis is the soluble form of CD14 (sCD14) [6].

The pathophysiology of BT still remains largely unknown. Small intestinal bacterial overgrowth [7], alterations in gut microbiota [8,9], and defective epithelial barrier function with increased intestinal permeability have all been pointed out as the responsible factors alone or in combination. Recently, attention was also drawn to deficits in innate immunity that may occur in patients with cirrhosis [10]. As a large proportion of microorganisms implicated in cirrhosis-related infections are inhabitants of the gut microflora, focus has been placed on gut defensive mechanisms and their dysregulation in cirrhosis. An integral component of this intestinal antimicrobial barrier is the system of the natural antimicrobial peptides (AMPs). These are endogenous molecules, which are produced in all eukaryotic organisms and demonstrate activity against any type of microorganism [11]. Several classes of intestinal AMPs have been described, including defensins, cathelicidin, and lysozyme [12].

Human defensins are cationic peptides that are further subdivided in α- and β-defensins [13]. The first group constitutes of human neutrophil peptides (HNP1-4), which are produced by neutrophils, and the Paneth cell specific human defensin-5 and -6 (HD-5, -6) in the small intestine [14,15]. Beta defensins consist of human defensins β1-β4 (hBD-1-4); these are produced by epithelial cells in several tissues, including the colon [16]. Specifically, hBD-1 is produced in a constitutive manner, whereas hBD-2 is inducible upon infectious and/or inflammatory stimulation [16]. During the latter conditions, both hBD-1 and -2 have been reported to be detectable in the systemic circulation, raising the possibility that these may serve as biomarkers for the presence of inflammation [17]. Previous work has reported various associations between the expression of defensins and liver disease. These include increased HNPs in patients with hepatitis C virus (HCV)-associated chronic liver disease, correlation with hepatic fibrosis, and several studies in patients with biliary disease [18,19]. Regarding the association with cirrhosis, recently, Teltschik et al provided evidence for decreased expression of HD-5 and HD-6 in the small intestine of rats with experimental cirrhosis [20]. Previously, a role for Paneth cell defensins was proposed in the inhibition of BT in mice [21]. In contrast, very few studies have examined the local and systemic patterns of defensin expression in patients with cirrhosis.

In the present study we aimed to examine the local and systemic expression of hBD-1 in patients with various stages of liver disease. We also tested whether the expression of hBD-1 is affected by the specific etiology of liver disease. Finally, we aimed to discover whether hBD-1 and sCD14 correlate with and may be used as surrogate markers of BT in patients with cirrhosis.

Patients and methods

Patients

Patients with chronic viral hepatitis and cirrhosis were recruited from the patient population of the Academic Department of Gastroenterology at Laikon Hospital, Athens, Greece. Demographic and clinical information are shown in Table 1. Diagnosis of chronic hepatitis was confirmed by standard criteria (HBsAg or anti-HCV positivity with viremia for more than 6 months and persistent or intermittent aspartate aminotransferase or alanine aminotransferase elevations). When liver biopsy was available, all patients with chronic viral hepatitis had minimal liver fibrosis and mild-to-moderate inflammation (stage=0-1, grade=2-6, Ishak score).

Table 1 Clinical and demographic patient characteristics

Decompensated cirrhosis was defined by the presence of at least one major complication (variceal bleeding, ascites, hepatic encephalopathy, or jaundice). Four patients had compensated cirrhosis, detected via liver biopsy and/or elastography, using a cutoff of 12 kPa.

The control group included healthy volunteers who underwent endoscopy for screening reasons in our department and were age and gender matched to the chronic hepatitis and cirrhosis groups. As expected, patients with viral hepatitis were younger than cirrhotics. To match both groups, our control population varied from 32 to 81 years of age.

Patients with diseases known to affect the expression of the molecules under study, such as chronic obstructive pulmonary disease, inflammatory bowel disease, psoriasis and other immunological disorders, were excluded from the study.

The study protocol was approved by the Laikon Hospital Ethics Committee and all subjects gave written informed consent.

Collection of serum and plasma

Blood was collected from peripheral veins of patients and controls and centrifuged at 3000 rpm. In a subset of patients, blood was collected from the hepatic veins of cirrhotic patients (Seldinger technique-transdermal catheterization of femoral vein, inferior vena cava and right hepatic vein). Serum and plasma were separated, aliquoted, and stored at -80°C until use.

Measurement of soluble hBD-1 and soluble human CD14

Concentration of hBD-1 in the plasma and sCD14 in the serum was measured by enzyme-linked immunosorbent assay (ELISA). For hBD-1, primary and secondary (biotinylated) anti-hBD-1 antibodies were purchased from Peprotech, Inc, UK. Briefly, 0.5 μg/mL of rabbit anti-human anti-BD-1 antibody (capture) was coated to flat-bottomed microplates and incubated overnight at room temperature. Non-specific binding was prevented by adding blocking solution (1% BSA in PBS) for 2 h. Wells were washed and 100 μL of diluted patient’s plasma was added at a dilution of 1:50 and incubated for 2 h. After further washing, 0.5 μg/mL of biotinylated rabbit anti-human anti-BD-1 antibody (detection) was added and incubated for the next 2 h. Finally, after washing, avidin-HRP Conjugate (Peprotech, UK) was added for 30 min in dark, the excess was washed off, and 100 μL of ABTS Liquid Substrate Solution (Sigma, USA) was added. Absorbance was measured at 405 nm and corrected at 650 nm. Absorbance of each sample was plotted against a standard curve produced by serial dilutions of recombinant human h-BD-1 (Peprotech, UK).

For sCD14, human CD14 ELISA Development kit (R&D Systems, Abingdon, UK) was used following manufacturer’s instructions. Briefly, 2 μg/mL of mouse anti-human anti-CD14 antibody (capture) was coated to flat-bottomed microplates and incubated overnight at room temperature. Non-specific binding was prevented by adding blocking solution (1% BSA in PBS) for 2 h. Wells were washed and 100 μL of diluted patient’s serum was added at a dilution of 1:10000 and incubated for 2 h. After further washing, 200 ng/mL of biotinylated sheep anti-human anti-CD14 antibody (detection) was added and incubated for the next 2 h. After washing, streptavidin-HRP was incubated for 20 min in dark and then H₂O₂ and Tetramethylbenzidine (R&D Systems) were added, and after 30 min optical absorbance was measured at 450 nm and corrected at 570 nm. Absorbance of each sample was plotted against a standard curve produced by serial dilutions of recombinant human CD14 (R&D Systems).

For both hBD-1 and sCD14, concentrations were calculated via logarithmic analysis. All samples with an absorbance of less than the average of the zero standards + 2 SD were considered as non-detectable. In addition, to avoid any inter-assay variability, in each individual ELISA assay, similar numbers of samples from patients with chronic hepatitis B and C, cirrhosis and healthy controls were run in parallel.

Lipopolysaccharide binding protein (LBP) was measured by a commercially available ELISA kit (USCN), according to manufacturer’s instructions.

Real-time reverse transcription polymerase chain reaction (RT-PCR)

For mRNA studies, intestinal biopsies were obtained from terminal ileum and colon during colonoscopy, which were performed for diagnostic and/or therapeutic reasons. Biopsy specimens were directly immersed into RNA stabilization solution (RNAlater® AmbionInc., CA), kept for 1-2 days at 4°C, and then stored at -80°C until further use. Samples were homogenized using a rotor-stator homogenizer and total RNA was isolated by using Purelink RNA extraction kit (Ambion, Carlsbad, Ca, USA), according to manufacturer’s instructions. To diminish possible genomic DNA contamination total RNA was treated with DNase I, Amplification grade (Invitrogen, Carlsbad, Ca, USA). Next, 250 ng of total RNA were converted to complementary DNA (cDNA) with the aid of the Transcriptor High Fidelity cDNA Synthesis Kit (Roche Diagnostics GmBH, Mannheim, Germany). Relative gene expression in each sample was measured by quantitative PCR using Kapa SYBR Fast enzyme (Kapa Biosystems, Boston, MA, USA) on a CFX96 Thermocycler (Biorad, USA). Amplification of the target genes was performed by primers that spun an exon-exon junction (shown Table 2). Thermal cycling conditions for all genes were as follows: 95°C for 3 min, then 40 cycles of 95°C for 3 sec and 63°C for 30 sec, followed by melting curve analysis, from 70°C to 95°C with measurements taken every 0.5°C. The measurements for every target gene were normalized to those of the reference gene ribosomal phosphoprotein P0 (RPLP0) [22]. All samples were assayed in duplicates. Quantification of relative gene expression was calculated by the ΔΔCt method.

Table 2 Sequences of oligonucleotides used in real-time PCR

Statistical analysis

Kolmogorov–Smirnov tests were performed to determine if the variables (hBD-1, sCD14) under study followed a normal distribution. Both hBD-1 and sCD14 concentrations were found to present with highly skewed distributions. Thus, non-parametric tests were used for statistical analysis. Comparison between groups was performed by Mann-Whitney (2-groups compared) and Kruskal-Wallis (more than 2 groups compared) tests. Spearman’s r-test was used to assess correlations between variables. In all cases an alpha level of <0.05 was considered significant.

Results

Patient characteristics

In the present study, we included 47 patients with chronic viral hepatitis [age 41±12.4 (27-70), median ± SD, range, male/female 34/13, 22 HBV-related, 25 HCV-related], 51 patients with cirrhosis, [age 66±13 (35-89, median ± SD), male/female 34/17, 5 HBV-related, 15 HCV-related, 20 alcoholic, compensated/decompensated 4/47]. Median values of the viral loads were: HBV DNA (3181, 56.6-990000, IU/mL, median, range) and HCV RNA (1.399 × 106, 0.0138-9.585*106, IU/mL, median, range). The control group consisted of 40 healthy controls [age 48±15.29 (32-81, median ± SD), male/female 25/15].

Soluble hBD-1 is increased in cirrhotic patients

We first measured the concentration of hBD-1 in the plasma of patients with cirrhosis in comparison to patients with chronic viral hepatitis or healthy controls. We found that plasma concentration of hBD-1 was significantly higher in cirrhosis (18.26 ng/mL, 16.65-21.94, median, 95%CI) in comparison to healthy controls (8.85 ng/mL, 7.46-9.69, P<0.001), and to patients with chronic viral hepatitis (8.87 ng/mL, 9.09-12.88, P<0.001) (Fig. 1A). No significant difference was observed between chronic viral hepatitis and healthy controls. Moreover, we compared cirrhotic and non-cirrhotic viral hepatitis (Fig. 1B) as shown, plasma concentration of hBD-1 is statistical significantly elevated in cirrhotic viral hepatitis (20.46 ng/mL, 15.65-26.51, median, 95%CI) in comparison to non-cirrhotic cohorts (8.87 ng/mL, 9.09-12.88, P<0.0001).

Figure 1 Increased levels of human beta defensin-1 (hBD-1) in cirrhotic patients. Plasma concentration of hBD-1 was measured as described in Patients and Methods. (A) Concentration of hBD-1 compared in various groups of controls (n=40) and patients with liver disease [chronic viral hepatitis (n=47), cirrhosis (n=51)]. Results are shown as Whisker box-plots. (B) Concentration of hBD-1 compared in cirrhotic (n=20) and non-cirrhotic (n=47) viral hepatitis patients

We also examined whether the increase in hBD-1 in the plasma was associated with a specific etiology of cirrhosis or the latter was the reason for the elevated concentration. To test this, we divided cirrhotic patients into groups according to the underlying cause and compared hBD-1 concentrations between groups (Fig. 2). As shown, there were no statistically significant differences for any comparison. We also compared patients with chronic viral hepatitis B or C. Again, no statistical significant difference in the levels of hBD-1 was seen (Fig. 2). In contrast, when the groups of HBV- or HCV-related liver disease were analyzed separately, in both cases there was a significant increase of plasma hBD-1 concentration in cirrhotic patients as compared to those with chronic hepatitis.

Figure 2 Increased levels of human beta defensin-1 (hBD-1) in cirrhotic patients are independent of the etiology of liver disease. Concentration of hBD-1 according to specific etiology of liver disease [chronic hepatitis B (Hep B) (n=22), chronic hepatitis C (Hep C) (n=25), HBV cirrhosis (n=5), HCV cirrhosis (n=15), alcoholic cirrhosis (n=20), other etiology of cirrhosis (n=11)]. Results are shown as Whisker box-plots

Taken together, these results indicate that the increased levels of hBD-1 are in direct association with the presence of cirrhosis itself, irrespectively of its etiology.

Plasma hBD-1 correlates with the levels of sCD14, a marker of BT in cirrhosis

We next asked whether the increased plasma hBD-1 concentration in cirrhotic patients may reflect the presence of BT. To examine this possibility, we first measured the levels of sCD14 in the same populations of patients. As already mentioned, sCD14 is a marker of lipopolysaccharide (LPS) bioactivity as its secretion follows LPS-induced activation of myeloid cells; hence its presence is an indicator of bacteremia due to BT. Our results are shown in Fig. 3. Similar to hBD-1, the concentration of CD14 in the systemic circulation was significantly higher in patients with cirrhosis (2777 ng/mL, 2701-3133, median, 95%CI) as compared to healthy controls (1671 ng/mL, 1574-2026, median, 95%CI) (P<0.001). In contrast to results for hBD-1, patients with chronic viral hepatitis also showed higher concentrations than healthy controls (Fig. 3). Similar to hBD-1, the levels of sCD14 were not affected by the specific etiology of cirrhosis (data not shown).

Figure 3 Elevated soluble CD14 (sCD14) concentration in the serum of cirrhotic patients. Concentration of sCD14 was measured in healthy controls (n=31), patients with chronic viral hepatitis (n=26) and patients with cirrhosis (n=50) as described in patients and methods. Data is presented graphically as Whisker box-plots

Next, we presumed that if the elevations of hBD-1 and sCD14 in cirrhotic patients are indeed a reflection of BT, there should be a significant correlation between the two, when values in individual patients were analyzed. Our study confirmed that this was indeed the case in our population of cirrhotic patients. More importantly, the correlation was stronger when the concentrations of these two molecules were measured in blood isolated from hepatic veins (Spearman r=0.6, P=0.0045) (Fig. 4B). The correlation became borderline significant, when values in blood obtained from a peripheral vein were tested (P=0.0528) (Fig. 4A). Finally, to further test the association of the tested markers with BT, we tested whether there was a correlation between sCD14 and LBP. The latter is frequently used as an indirect marker of BT. Our analysis in a subgroup of our study population revealed a highly significant correlation between the two markers (Suppl. Fig. 1).

Figure 4 High correlation between the levels of human beta defensin-1 (hBD-1) and soluble CD14 (sCD14) in the hepatic veins of cirrhotic patients (Fig. 4B). Concentrations of hBD-1 and sCD14 were measured as described in patients and methods. Each dot corresponds to individual patients with cirrhosis (n=45). Analysis was performed in samples collected from peripheral veins (n=25, Fig. 4A) and from hepatic veins (n=20, Fig. 4B)

Suppl. Figure 1 Soluble CD14 (sCD14) and lipopolysaccharide binding protein (LBP) strongly correlate in serum of patients with cirrhosis. Concentrations of sCD14 were measured as described in Patients and Methods. Concentrations of LBP were measured by a commercially available ELISA, according to manufacturer’s instructions. Each dot corresponds to individual patients with cirrhosis (n=36). Analysis was performed in samples collected from peripheral veins

Collectively, these results may indicate that the elevation of hBD-1 in cirrhosis may take place as a response to BT.

Ileal or colonic mRNA expression of natural AMPs is not altered in patients with cirrhosis

Finally, we tested whether the presence of cirrhosis is associated with differences in the mucosal expression of natural AMPs in the small or large intestines in comparison with healthy controls. To answer this question we compared the relative mRNA expression for several AMPs in total RNA from endoscopically-obtained intestinal biopsies (Suppl. Fig. 2). In line with previous publications, we found significantly increased mRNA expression of A5 defensin in the terminal ileum compared to the colon. However, no differences were found between healthy controls and cirrhotics for any of the AMPs tested in either location (terminal ileum, colon). These results show that a quantitative defect in the production of AMPs does not take place in cirrhosis.

Suppl. Figure 2 No significant differences in the intestinal mRNA expression of antimicrobial peptides (AMPs) between cirrhosis and healthy controls (HC). The mRNA expression for (A) defa5, (B) defa6, (C) defb1, and (D) reg3a was calculated in total RNA extracted from endoscopically-obtained intestinal biopsies from cirrhotics and healthy controls. Relative expression of the target genes was calculated by the 2^-(ΔΔct) method using RPLPO as the reference gene. No differences were found between healthy controls and cirrhotics for any of the AMPs tested in terminal ileum or the colon

Discussion

In the present study, we report that patients with cirrhosis have increased systemic levels of the antimicrobial peptide hBD-1. We demonstrated that this elevation is driven by the presence of cirrhosis per se and is not associated with any specific etiology. We also report a significant elevation in the levels of sCD14, an indicator of circulating LPS and gram-negative bacteremia in patients with cirrhosis. Finally, we showed that hBD-1 concentration significantly correlated with that of sCD14 in hepatic veins and borderline significant in the peripheral blood, raising the possibility that elevations of hBD-1 may also represent a response to and be a surrogate marker for BT in cirrhosis.

Herein, we confirmed a significant elevation of sCD14 in the peripheral blood of patients with chronic liver diseases, as it was reported in previous works [6,23]. CD14 is a glycoprotein that exists both in membrane (mCD14) and soluble forms (sCD14). It is expressed on monocytes and binds to the LPS-LBP complex, thus participating in immune responses against gram-negative, LPS-producing bacteria [24]. CD14-mediated signaling leads to nuclear translocation of the transcription factor nuclear factor (NF)-κB and promotes cytokine production [25]. This pathway may result in acceleration of fibrogenesis in the liver [26]. The expression of sCD14 is induced by circulating LPS; therefore, sCD14 serves as an indicator of the presence of LPS in the serum and, in extension, of gram-negative bacteremia. Thus, its use as a marker of BT has been proposed.

In our study, we also demonstrated that the natural antimicrobial peptide hBD-1 is highly elevated in the circulation of patients with cirrhosis. Our findings clearly support the notion that this upregulation is a cirrhosis-associated phenomenon. First, cirrhotic patients had significantly higher plasma concentrations of hBD-1 compared to healthy controls as well as to patients with chronic hepatitis. Second, elevation of hBD-1 occurred independently of the etiology of cirrhosis. In fact, within the populations of patients with HBV- or HCV-related liver disease, only patients with cirrhosis (and not those with chronic hepatitis) had elevations of hBD-1. To our knowledge, this is the first report of elevated expression of an antimicrobial peptide in the cirrhotic population. In addition, elevated plasma concentration of hBD-1 has not been previously reported in relation to a specific condition. Taken together, our current findings and previous studies clearly show that several bacteria-inducible factors are upregulated in cirrhosis and their concentration increases or becomes detectable in the systemic circulation of patients. This provides an indirect evidence for the presence of BT in this patient population. Previous studies have pointed out the role of portal hypertension in the pathogenesis of BT. Experiments in mice with experimental portal hypertension demonstrated increased BT [27], partly as a result of increased epithelial permeability [28]. In humans, portal hypertension is associated with altered immune responses [29] as well as bacterial overgrowth, increased intestinal permeability and altered gut motility resulting in BT [30]. On the other hand, the presence of LPS (a vasodilatory factor) along with activation of fibrogenic factors like NF-κB, as previously mentioned, lead to the deterioration of portal hypertension.

As BT predisposes to serious complications of cirrhosis, its early recognition with the use of easily identifiable and measured biomarkers in biological fluids becomes of paramount importance. This is particularly significant as it is known that BT may exist at a preclinical state, and that, often no microorganism is isolated by microbiological methods [31,32]. Bacterial DNA has been proposed as definitive marker of BT [4,33]; nevertheless, its use is complicated by technical difficulties and inter-laboratory variations [34]. Fecal calprotectin also suffers from validation problems between different laboratories and assays [35]. The high correlation of hBD-1 with sCD14 reported herein makes the former a potential candidate surrogate marker of BT as well. Interestingly, a combination of polymorphisms in the genes encoding for these two proteins, hBD-1 and sCD14 has been found to confer risk for periodontitis [36]. This result indicates that an association between these two markers may take place.

The particular reasons for the elevation of hBD-1 in cirrhosis and its cellular source(s) are not clear. The significant correlation between hBD-1 and sCD14 supports the notion that bacterial stimuli drive their upregulation. Microbial products present in the intestinal lumen may induce the expression of both proteins; hence their significantly higher correlation in hepatic veins than in the systemic circulation. Intestinal epithelial cells produce hBD-1 upon stimulation with bacteria-derived factors [14,16]. Nevertheless, our mRNA expression study failed to detect a significant difference in the intestinal mucosal expression of hBD-1 (or any other AMP) between cirrhotic patients and healthy controls. This, however, does not exclude the possibility that defects in the secretion of proteins or the antimicrobial capacity of excreted defensins may take place in cirrhosis. Such defects were recently shown to take place during intestinal inflammation [37]. Compartmentalization of expression may also be a confounding factor. Recently, Teltschik et al reported upregulation of BD-1 RNA in the cecum but downregulation in the colon of rats with experimental cirrhosis [20]. It is possible that hBD-1 may also be expressed differently in various parts of the large intestine of cirrhotics. Furthermore, we did not detect altered expression of human defensin A5 in the terminal ileum of cirrhotics, whereas, in the aforementioned study, downregulation of α-cryptidin 5 and 7, the rat homolog for human Paneth cells α-defensins, in rats with liver cirrhosis and BT was reported [20].

Additional cellular sources of circulating hBD-1 may also exist. First, monocytes were shown to highly upregulate hBD-1 expression upon stimulation with bacterial factors. In particular, stimulation with muramyl-dipeptide (MDP) that binds to the intracellular bacterial sensor NOD2, upregulated miRNA129-5p, which then induced the expression of hBD-1/DEFB1 [38]. Second, it was shown recently that platelets produce and store hBD-1, which can be released only after stimulation by microbial products that induce cell permeabilization [39]. Therefore, the elevated systemic levels of hBD-1 in cirrhotic patients may also be derived from monocytes and/or platelets in response to the process of BT and the release of pathogen-associated molecular patterns, such as LPS or MDP.

We are aware that our study has certain limitations. First, the number of patients is relatively low; thus our results should be replicated in a larger sample. Second, there is under-representation of important cirrhotic subgroups, most importantly, of patients with non-alcoholic fatty liver disease-associated cirrhosis. Finally, due to the lack of a definitive marker of BT in cirrhotic patients, a direct association between hBD-1 and sCD14 cannot be firmly established.

Summary Box

What is already known:

Bacterial translocation (BT) often occurs in cirrhosis and predisposes to serious complications
Soluble CD14 (sCD14) is increased in liver fibrosis and correlates with BT
Defensins are natural antimicrobial peptides that participate in intestinal antimicrobial defense

What the new findings are:

Circulating levels of human beta defensin-1 (hBD-1) are elevated in patients with cirrhosis, independently of its etiology
hBD-1 and sCD14 levels correlate with each other in cirrhotic patients
hBD-1 may be a surrogate marker for BT

In conclusion, we herein provide evidence for increased systemic levels of hBD-1 and sCD14 in cirrhosis, irrespectively of the etiology of liver disease. We propose that hBD-1 may represent another possible marker of BT, with the advantage of being easily measured in peripheral blood. Larger studies are required to validate the present findings and further delineate the role of hBD-1 in cirrhosis and its applicability as a biomarker for BT.

Acknowlegments

This research has been co-financed by the European Union (European Social Fund - ESF) and Greek national funds through the Operational Program “Education and Lifelong Learning” of the National Strategic Reference Framework (NSRF) - Research Funding Program: Heracleitus II. Investing in knowledge society through the European Social Fund, of which Dr. Kaltsa was a recipient.

References

1. Thalheimer U, Triantos CK, Samonakis DN, Patch D, Burroughs AK, Infection, coagulation, and variceal bleeding in cirrhosisGut 2005; 54: 556-563.

2. Bellot P, Frances R, Such J, Pathological bacterial translocation in cirrhosis: pathophysiology, diagnosis and clinical implicationsLiver Int 2013; 33: 31-39.

3. Wiest R, Garcia-Tsao G, Bacterial translocation (BT) in cirrhosisHepatology 2005; 41: 422-433.

4. Bellot P, Garcia-Pagan JC, Frances R, Bacterial DNA translocation is associated with systemic circulatory abnormalities and intrahepatic endothelial dysfunction in patients with cirrhosisHepatology 2010; 52: 2044-2052.

5. Fernandez J, Navasa M, Planas R, Primary prophylaxis of spontaneous bacterial peritonitis delays hepatorenal syndrome and improves survival in cirrhosisGastroenterology 2007; 133: 818-824.

6. Sandler NG, Koh C, Roque A, Host response to translocated microbial products predicts outcomes of patients with HBV or HCV infectionGastroenterology 2011; 141: 1220-1230.

7. Morencos FC, de las Heras Castano G, Martin Ramos L, Lopez Arias MJ, Ledesma F, Pons Romero F, Small bowel bacterial overgrowth in patients with alcoholic cirrhosisDig Dis Sci 1995; 40: 1252-1256.

8. Schnabl B, Brenner DA, Interactions between the intestinal microbiome and liver diseasesGastroenterology 2014; 146: 1513-1524.

9. Gomez-Hurtado I, Santacruz A, Peiro G, Gut microbiota dysbiosis is associated with inflammation and bacterial translocation in mice with CCl4-induced fibrosisPLoS One 2011; 6: e23037

10. Wiest R, Lawson M, Geuking M, Pathological bacterial translocation in liver cirrhosisJ Hepatol 2014; 60: 197-209.

11. Zasloff M, Antimicrobial peptides of multicellular organismsNature 2002; 415: 389-395.

12. Hancock RE, Diamond G, The role of cationic antimicrobial peptides in innate host defencesTrends Microbiol 2000; 8: 402-410.

13. Ganz T, Defensins: antimicrobial peptides of innate immunityNat Rev Immunol 2003; 3: 710-720.

14. Cunliffe RN, Mahida YR, Expression and regulation of antimicrobial peptides in the gastrointestinal tractJ Leukoc Biol 2004; 75: 49-58.

15. Ayabe T, Satchell DP, Wilson CL, Parks WC, Selsted ME, Ouellette AJ, Secretion of microbicidal alpha-defensins by intestinal Paneth cells in response to bacteriaNat Immunol 2000; 1: 113-118.

16. O’Neil DA, Porter EM, Elewaut D, Expression and regulation of the human beta-defensins hBD-1 and hBD-2 in intestinal epitheliumJ Immunol 1999; 163: 6718-6724.

17. Bensch KW, Raida M, Magert HJ, Schulz-Knappe P, Forssmann WG, hBD-1: a novel beta-defensin from human plasmaFEBS Lett 1995; 368: 331-335.

18. Aceti A, Mangoni ML, Pasquazzi C, Alpha-defensin increase in peripheral blood mononuclear cells from patients with hepatitis C virus chronic infectionJ Viral Hepat 2006; 13: 821-827.

19. Harada K, Ohba K, Ozaki S, Peptide antibiotic human beta-defensin-1 and -2 contribute to antimicrobial defense of the intrahepatic biliary treeHepatology 2004; 40: 925-932.

20. Teltschik Z, Wiest R, Beisner J, Intestinal bacterial translocation in rats with cirrhosis is related to compromised Paneth cell antimicrobial host defenseHepatology 2012; 55: 1154-1163.

21. Salzman NH, Ghosh D, Huttner KM, Paterson Y, Bevins CL, Protection against enteric salmonellosis in transgenic mice expressing a human intestinal defensinNature 2003; 422: 522-526.

22. Bamias G, Goukos D, Laoudi E, Comparative study of candidate housekeeping genes for quantification of target gene messenger RNA expression by real-time PCR in patients with inflammatory bowel diseaseInflamm Bowel Dis 2013; 19: 2840-2847.

23. Ogawa Y, Imajo K, Yoneda M, Soluble CD14 levels reflect liver inflammation in patients with nonalcoholic steatohepatitisPLoS One 2013; 8: e65211

24. Hailman E, Lichenstein HS, Wurfel MM, Lipopolysaccharide (LPS)-binding protein accelerates the binding of LPS to CD14J Exp Med 1994; 179: 269-277.

25. Jiang Q, Akashi S, Miyake K, Petty HR, Lipopolysaccharide induces physical proximity between CD14 and toll-like receptor 4 (TLR4) prior to nuclear translocation of NF-kappa BJ Immunol 2000; 165: 3541-3544.

26. Seki E, Schnabl B, Role of innate immunity and the microbiota in liver fibrosis: crosstalk between the liver and gutJ Physiol 2012; 590: 447-458.

27. Vauthey JN, Duda P, Wheatley AM, Gertsch P, Portal hypertension promotes bacterial translocation in rats mono- and non mono-associated with Escherichia coli C25HPB Surg 1994; 8: 95-100.

28. Yao GX, Shen ZY, Xue XB, Yang Z, Intestinal permeability in rats with CCl4-induced portal hypertensionWorld J Gastroenterol 2006; 12: 479-481.

29. Fiuza C, Salcedo M, Clemente G, Tellado JM, Granulocyte colony-stimulating factor improves deficient in vitro neutrophil transendothelial migration in patients with advanced liver diseaseClin Diagn Lab Immunol 2002; 9: 433-439.

30. Ramachandran A, Balasubramanian KA, Intestinal dysfunction in liver cirrhosis: Its role in spontaneous bacterial peritonitisJ Gastroenterol Hepatol 2001; 16: 607-612.

31. Fagan KJ, Rogers GB, Melino M, Ascites bacterial burden and immune cell profile are associated with poor clinical outcomes in the absence of overt infectionPLoS One 2015; 10: e0120642

32. Rogers GB, van der Gast CJ, Bruce KD, Ascitic microbiota composition is correlated with clinical severity in cirrhosis with portal hypertensionPLoS One 2013; 8: e74884

33. Zapater P, Frances R, Gonzalez-Navajas JM, Serum and ascitic fluid bacterial DNA: a new independent prognostic factor in noninfected patients with cirrhosisHepatology 2008; 48: 1924-1931.

34. Vlachogiannakos J, Daikos G, Thalheimer U, Burroughs AK, Ladas SD, Is bacterial DNA a better marker than endotoxin of bacterial translocation in decompensated cirrhosis?Hepatology 2011; 53: 2140-2141.author reply 2141-2142

35. Gundling F, Schmidtler F, Hapfelmeier A, Fecal calprotectin is a useful screening parameter for hepatic encephalopathy and spontaneous bacterial peritonitis in cirrhosisLiver Int 2011; 31: 1406-1415.

36. Loo WT, Bai LJ, Fan CB, Clinical application of human beta-defensin and CD14 gene polymorphism in evaluating the status of chronic inflammationJ Transl Med 2012; 10: Suppl 1S9

37. Hosomi S, Kaser A, Blumberg RS, Role of endoplasmic reticulum stress and autophagy as interlinking pathways in the pathogenesis of inflammatory bowel diseaseCurr Opin Gastroenterol 2015; 31: 81-88.

38. Hasler R, Jacobs G, Till A, Microbial pattern recognition causes distinct functional micro-RNA signatures in primary human monocytesPLoS One 2012; 7: e31151

39. Kraemer BF, Campbell RA, Schwertz H, Novel anti-bacterial activities of beta-defensin 1 in human platelets: suppression of pathogen growth and signaling of neutrophil extracellular trap formationPLoS Pathog 2011; 7: e1002355

Notes

Conflict of Interest: None

Systemic levels of human β-defensin 1 are elevated in patients with cirrhosis

Abstract