key: cord-0816287-3ptpgbkj
authors: Weber, Susanne N.; Nowak, Irina; Grünhage, Frank; Lammert, Frank
title: Effects of blocking chemokine receptor CCR1 with BX471 in two models of fibrosis prevention and rescue in mice
date: 2021-07-15
journal: Biochem Biophys Rep
DOI: 10.1016/j.bbrep.2021.101077
sha: 4c89f17cf58d8237330e6fd7987430a12d24ce48
doc_id: 816287
cord_uid: 3ptpgbkj

BACKGROUND: The induction, progression and resolution of liver fibrosis are influenced by multiple chemokines. The inhibition of CCR1 signalling by a specific non-peptide inhibitor (BX471) reduces kidney fibrosis after unilateral ureteral obstruction via suppression of leukocyte recruitment in mice. However, it remains unclear whether selective CCR1 inhibition also affects hepatic fibrogenesis. Therefore we aimed to study the effect of this intervention on liver fibrosis in prevention (CCl(4) administration) and rescue (ABCB4-deficient mice) mouse models. METHODS: In the prevention model, hepatic fibrosis was induced by repeated injections of CCl(4). Additionally, the verum group was treated with subcutaneous injections of BX471, while controls received vehicle only. ABCB4 deficient mice (on the BALB/c-background) with sclerosing cholangitis and biliary fibrosis received BX471 or vehicle, respectively (rescue model). Liver histopathology was assessed after Sirius red staining of collagen, and hepatic collagen contents were measured. In addition, we performed gene expression analyses of fibrosis-related genes. RESULTS: BX471 injections were tolerated moderately well by all mice, and all mice developed hepatic fibrosis. Significant differences were neither observed in serum aminotransferase activities after 6 weeks of treatment between the two groups in the prevention nor in the rescue model. Interestingly, hepatic collagen contents were significantly higher in mice treated with BX471 in the prevention model as compared to controls but histological stages of liver sections did not differ. Of note, we observed only moderate effects on liver fibrosis in the ABCB4 knock-out model. CONCLUSIONS: Our data indicate that BX471 treatment did neither affect serum and tissue markers of liver injury and fibrosis in the CCl(4) model and only moderately in the Abcb4(-/-) model of biliary fibrosis. The animal models indicate that treatment with BX471 alone is unlikely to exert major beneficial effects in chronic liver disease.

Hepatic fibrosis is a response to chronic liver injury resulting in enhanced production of extracellular matrix (ECM) proteins. During this process, functional parenchyma is replaced by scar tissue leading to diminished liver function and distorted liver architecture [1] . The ECM proteins are produced by hepatic stellate cells (HSC), which become activated upon liver damage and express a variety of inflammatory mediators including chemokines [2] . Chemokines are small chemotactic molecules with cytokine-like functions that mediate inflammatory responses. Depending on their cysteine residues they are classified in C, CC, CXC and CX3C chemokines. They bind to distinct receptors on the cell surface, induce signalling cascades inside the cell and are involved in a number of biological processes, including growth regulation, embryonic development, and angiogenesis [3] . It was shown that chemokines play an important role during hepatic fibrosis. CXCL9 attenuates liver fibrosis associated angiogenesis in mice [4] , and CXCL10 exerts proapoptotic effects mediated by the non-cognate receptor TLR4 in hepatocytes [5] . The chemokine receptors CCR1 and CCR5 promote hepatic fibrosis in knockout mouse models [6] , indicating that the blockade of CCR1 might be beneficial for fibrosis treatment. CCR1 is a universal chemokine receptor that binds various ligands with high affinity and is involved in many inflammatory diseases, including rheumatoid arthritis, atherosclerosis, psoriasis, and multiple myeloma [7] .

Also, it has recently been shown that CCR1 expression is increased in immune hyperactivation in patients with critical COVID-19 [8] .

BX471 is a non-peptide antagonist that binds to CCR1 and thereby blocks its function. BX471 has been shown to reduce renal fibrosis when applied to unilateral ureteral obstructed mice [9] . Furthermore, BX471 protects mice against acute pancreatitis-associated lung injury [10] , ventilator-induced lung injury [11] , and it has been shown that this antagonist attenuates the systemic inflammatory response syndrome during sepsis [12] . Here, the authors could also show that BX471 led to reduced activity of myeloperoxidase, a marker of neutrophil infiltration in liver, indicating protection against liver injury. Therefore, BX471 provides a promising therapeutic approach for the treatment of hepatic inflammation and fibrosis.

ABCB4-deficient mice lack the hepatocanalicular phospholipid translocase and develop sclerosing cholangitis and biliary fibrosis [13] [14] [15] . These mice represent a model for progressive familial intrahepatic cholestasis (PFIC type 3) in patients with severe mutations of the orthologous human gene, which may lead to biliary cirrhosis in children, and resemble primary sclerosing cholangitis in humans [16, 17] . Thus, they are used as a model to study fibrogenesis, since no intoxication with chemicals like carbon tetrachloride (CCl 4 ) is needed. Based on these studies our aim was to block CCR1 with BX471 in prevention (wild-type mice treated with CCl 4 ) and rescue (ABCB4-deficient mice) fibrosis models to investigate the role of CCR1 in hepatic fibrogenesis and to assess its potential effects in these preclinical models.

Mice were hosted under standard conditions (12L:12D photo period) and received water and a standard rodent diet ad libitum. All animal experiments were approved by the local government agency (Landesamt für Verbraucherschutz, Saarbrücken, Germany, TV42/08) and were carried out in accordance with Directive 2010/63/EU. All methods were carried out in accordance with the approved guidelines. BALB/c wildtype inbred mice were obtained from Charles River (Sulzfeld, Germany). Abcb4 knock-out mice were generated by crossing mice with the FVB/NJ background (The Jackson Laboratory, Bar Harbor, USA) onto the BALB/c background for more than 10 generations [14] .

For carbon tetrachloride (CCl 4 ) experiments, mice were injected intraperitoneally with CCl 4 (0.7 ml/kg body weight) in mineral oil twice a week for six weeks (12 injections). BX471 and vehicle solution were prepared as described previously [9] . Mice were injected subcutaneously with a dose of 50 mg/kg body weight [18] twice a day during the week and once a day on the weekends or vehicle solution for six weeks (total of 68 injections per mouse), respectively.

For BALB/c wild-type mice (n = 32; 8 males and 8 females BX471; 8 males and 8 females vehicle), CCl 4 and BX471 treatment started at the age of seven weeks (Fig. 1A , prevention model). For ABCB4 deficient mice (n = 24; 6 male, 6 female BX471; 6 male 6 female vehicle), BX471 treatment started at the age of 10 weeks and was carried out for six weeks as described above (Fig. 1B, rescue model) .

After six weeks of treatment mice were sacrificed and livers were harvested in 4% neutral buffered formalin for preparation of paraffin sections or snap-frozen in liquid nitrogen and stored at -80 • C for molecular analyses.

For comparison without any treatment, untreated BALB/c wild-type mice (n = 6; 3 females and 3 males) and ABCB4 deficient mice (n = 6; 3 females and 3 males) were sacrificed at the age of 16 weeks and served as controls.

For determination of plasma alanine aminotransferase (ALT) activities, blood was taken prior to the first injection and after sacrifice. After centrifugation, plasma ALT activities were measured with an Olympus AU400 chemistry analyzer, using adapted reagents provided by Olympus [14] .

The quantification of hepatic collagen contents was performed in liver hydrolysates via photometric measurement of the specific amino acid hydroxyproline as described [19, 20] .

Livers were fixed in 4% neutral buffered formalin at 4 • C overnight, embedded in paraffin, and cut into 1-3 μm sections. Sections were stained with Sirius red. In brief, sections were rehydrated in a descending alcohol series, stained 3 min with Weigert, were differentiated with HCl-alcohol and stained 30 min with Sirius red solution (0.1%). After staining, sections were dehydrated in an ascending alcohol series and covered with mounting medium. The amount of Sirius red stained tissue was evaluated using LAS software (Leica, Wetzlar, Germany). Additionally, mice received BX471 (n = 16) or vehicle solution (n = 16) subcutaneously twice a day during the week and once at weekends (total of 68 injections; grey arrows). (B) Rescue model: ABCB4-deficient mice on the BALB/c background (n = 24) were treated with BX471 (n = 12) or vehicle solution (n = 12; grey arrows). Treatment was carried out for six weeks.

Total RNA from snap-frozen livers was extracted using Qiagen RNeasy Kit (Qiagen, Germany). One μg RNA was transcribed to cDNA with the High Capacity cDNA reverse transcription kit (Thermo Scientific, Germany) and quality was checked by common β-actin PCR. For quantitative gene expression analyses TaqMan® assays for α-Sma

and Tgfβ (Mm03024053_m1; all Thermo Scientific, Germany) were used and results were normalized to 18S rRNA. All assays were run on a TaqMan® 7500 Fast real-time PCR system (Life Technologies, Germany). Relative gene expression results were normalized to untreated samples using the ΔΔC t method.

Data are presented as means ± SEM. Statistical analyses were carried out using GraphPad Prism 9.1.2 (GraphPad Software, La Jolla, CA, USA). Non-parametric Kruskal-Wallis tests were used and p values < 0.05 were considered as statistically significant.

To assess the effect of BX471 for the treatment of hepatic fibrosis and to exclude a toxic effect in the combination with CCl 4 , two different mouse models were used. On the one hand, BALB/c wild-type mice were injected with CCl 4 and BX471 or vehicle, respectively (Fig. 1A , prevention model, no fibrosis at the start of treatment). ABCB4 deficient mice were injected with BX471 or vehicle (Fig. 1B, The effect of BX471 was analysed by immunohistochemical staining and quantification of infiltrating macrophages (CD11b + ; Supplementary  Figure 2 ). BX471 administration led to markedly reduced CD11b + cells as compared to vehicle-treatment except for male mice treated with CCl 4 , indicating a sex-dependent toxic effect of BX471 and CCl 4 .

As we observed sex differences when analysing the results, all data were stratified for male and female mice. As a marker of liver injury, serum alanine aminotransferase (ALT) activities were measured ( Fig. 2A-D) . As expected, ALT increased upon treatment in both models. Interestingly, male mice treated with CCl 4 and BX471 showed highest ALT levels ( Fig. 2A) but there were neither significant differences between BX471-and vehicle-treated mice in female mice in the prevention model (Fig. 2B) nor in male or female Abcb4 -/mice with persistent fibrosis (Fig. 2C and D) .

To quantify the amount of fibrotic tissue in the livers accurately, the collagen-specific amino acid hydroxyproline was measured (Fig. 2E-H) . Compared to non-treated mice hydroxyproline levels were significantly increased after BX471-treatment but showed only a slight increase compared to vehicle-treated mice in the prevention model in both sexes ( Fig. 2E and F ). Interestingly the opposite was shown for the rescue model as hydroxyproline levels were decreased in BX471-treated mice compared with non-treated animals. This decrease was significant in female mice but again, no difference was observed when comparing BX471-and vehicle-treated mice of both sexes (Fig. 2G and H) .

Hepatic fibrosis in the different models was also assessed by quantifying Sirius red stained collagen in liver sections (Fig. 3 ). It appears that the treatment with BX471 and vehicle solution increases fibrosis in the prevention model and decreases fibrosis in the rescue model, as reflected by hepatic collagen contents. Significant differences were only observed for vehicle controls, but a trend was also visible for BX471 treatment.

To analyse the amount of hepatic damage and fibrosis, different parameters were assessed. Plasma alanine aminotransferase activities were measured in the prevention (A, B) and the rescue model (C, D) before and after treatment. Hepatic hydroxyproline contents in the prevention (E, F) and the rescue model (G, H) were quantified. *, p < 0.05.

The molecular consequences of BX471 treatment in both models were analysed at the mRNA level. Five specific transcripts were selected: Ccr1 as indicator of BX471 antagonism, Tgfβ as critical profibrogenic mediator, Col1α2 and α-SMA as markers for fibrosis, and Mmp3 as marker of extracellular matrix turnover (Fig. 4) .

BX471 administration led to a decrease of Ccr1 expression as compared to vehicle-treated mice, except for female mice in the prevention model where Ccr1 expression was induced. Interestingly, in the prevention model, Tgfβ mRNA steady-state levels were markedly increased in the BX471-treated mice of both sexes as compared to vehicle ( Fig. 4E and F) , while Col1α2 and α-Sma levels were not affected ( Fig. 4I, J, M and N) . Mmp3 was reduced in female BX471-treated mice ( Figure 4Q and R) as compared to vehicle.

In the rescue model, BX471 had no influence on gene expression of any of the markers except for Col1α2, which was markedly decreased in female BX471-treated ABCB4-deficient mice (Fig. 4H ) as compared to vehicle.

This study investigates the potential effects of BX471, a non-peptide CCR1 antagonist, in the treatment of hepatic fibrosis. To analyse its efficacy during liver fibrogenesis, two different mouse models were used, a prevention (CCl 4 challenge) and a rescue model (ABCB4-deficient mice). Mice underwent BX471 and vehicle treatment, respectively. The fibrotic process could only partly be prevented by the therapy with BX471 in the rescue model as shown by hepatic collagen contents in female ABCB4 deficient animals, and BX471 rather increased fibrosis in the prevention model. Previously BX471 has been reported to have effects on different fibrotic diseases in murine models [9, 10, 12, 18, 21] . For example, renal fibrosis could be ameliorated as shown by decreased collagen expression in ureteral obstructed mice after treatment with this CCR1 antagonist [9, 18] . The fact that this does not prove true for the liver is consistent with the notion that core but also organ-specific pathways contribute to fibrosis in different organs [22] . The determination of Sirius red stained area and collagen amount via hydroxyproline lead to mixed results, which might be explained by the fact that by Sirius red, fibrillary collagen deposits in the tissue are detected (type I and III), whereas the hydroxyproline measurement includes fragmented collagen [23] .

In contrast to our findings, it has been shown that the lack of CCR1 in CCR1-deficient mice leads to a significant decrease of liver fibrosis [6] . This was shown using toxic (CCl 4 ) and surgical (bile duct ligation, BDL) models for the induction of liver fibrosis. There might be several explanations for the contrary findings. On the one hand, the effect of a constitutive knockout is much stronger than the transient blockade of small signalling proteins, and on the other hand, there might be toxic interactions of CCl 4 and BX471, which increase liver injury, as indicated by elevated ALT levels in male mice in particular in the CCl 4 model. Also, different genetic backgrounds (CCR1-deficient mice were bred to C57BL/6J and BALB/c mice were used in this study) could explain, at least in part, the results. BX471 has been evaluated in patients with multiple sclerosis in a randomized controlled trial, but no differences in the development of new lesions could be observed, assuming that there are other regulatory mechanisms bypassing CCR1 blockade [7] . In addition, Gilchrist et al. [24] tested several CCR1 antagonists with regards to their binding efficiency and reported BX471 to be a member of the "lower binding group".

Our data suggest that the blockade of CCR1 by BX471 is not sufficient to decrease liver fibrosis in a prevention preclinical model and only had moderate effects in a rescue model of fibrosis. Although the chemokine receptor CCR1 binds multiple chemokines and is therefore involved in numerous chemokine-mediated signalling pathways, the fibrotic process in liver appears to depend predominantly on alternative factors. 

The authors declare that they have no competing financial interests. 

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The authors thank A, Nicklas for excellent technical assistance. BX471 was kindly provided by C. Haskell (Bayer Healthcare, SF, CA, USA).

Supplementary data to this article can be found online at https://doi. org/10.1016/j.bbrep.2021.101077.