Cancer-induced cachexia, characterized by systemic inflammation, body weight loss, adipose tissue (AT) remodeling and muscle wasting, is a malignant metabolic syndrome with undefined etiology. Here, we show that both genetic ablation and pharmacological inhibition of TLR4 were able to attenuate the main clinical markers of cachexia in mice bearing Lewis lung carcinoma (LLC). AT remodelling was not found in LLC tumor-bearing (TB) TLR4−/− mice due to reduced macrophage infiltration and adipocyte atrophy. TLR4−/− mice were also resistant to cold-induced browning of subcutaneous AT (scAT). Importantly, pharmacological inhibition of TLR4 (Atorvastatin) reproduced the main protective effect against AT remodeling found in TLR4−/− TB mice. Moreover, the treatment was effective in prolonging survival and attenuating tumor mass growth when compared to non-treated-TB animals. Furthermore, tumor-induced elevation of circulating pro-inflammatory cytokines was similarly abolished in both genetic ablation and pharmacological inhibition of TLR4. These data suggest that TLR4 is a critical mediator and a promising target for novel anti-cachexia therapies.
Cancer cachexia syndrome is characterized by systemic inflammation, body weight loss, remodeling of adipose tissue (AT), and skeletal muscle wasting1. Consequently, it results in reduced quality of life, decreased survival, and increased complications due to cancer treatment. Cachexia is the main cause of death in approximately 20% to 30% of all patients with cancer2. In cancer cachexia patients, impairment of AT lipid metabolism has been demonstrated and longitudinal studies have established that AT loss precedes muscular atrophy3. The changes that characterize AT remodeling comprise: an increase in infiltrated inflammatory cells4,5, extracellular matrix rearrangement4,6 and the appearance of beige cells7 in subcutaneous AT (scAT). The physiological role and consequences of cachexia-induced browning are not known. The current consensus is that multiple factors contribute to cancer cachexia, and therapy requires combinational strategies8. Interestingly, pharmacological intervention aimed at attenuating the AT remodeling in cachexia have shown satisfactory results, particularly in mitigating tumor growth and increasing animal survival9.
A plethora of evidence from both patients and animal studies suggest a compelling link between activation of the inflammatory pathways and development of cancer cachexia10,11. In fact, systemic inflammation has been proposed as a critical feature of cancer cachexia, and anti-inflammatory strategies are considered central to the therapy10. It is likely that pathways responding to similar pro-inflammatory cytokines that mediate both sterile and infectious inflammation are critical in cancer cachexia. The toll-like receptor (TLR) system is potentially one such pathway. TLRs are required for pathogen recognition by the innate immune system12. Among TLRs, TLR4 acts as a receptor for lipopolysaccharides (LPS), and associates with the myeloid differentiation protein 2 (MD2) to form a complex to interact with LPS13. The stimulation of TLR4 by LPS induces the release of critical proinflammatory cytokines that are necessary to activate potent immune responses12,13.
In a cancer cachexia animal model, genetic ablation of TLR4 elicited a less severe cachexia with an accompanying lower body weight loss, greater lean body and fat mass, and clinical evidence of reduced wasting compared with the age and weight-matched WT mice11. More recently, an elegant study showed that TLR4 is a crucial mediator of cancer-induced muscle wasting due to its integration of catabolic signaling by directly activating muscle protein degradation and indirectly increasing cytokine release10. Thus, TLR4 may be a critical therapeutic target for cancer cachexia. The role of the TLR4 pathway in AT remodeling during cancer cachexia development remains unexplored.
Based on these considerations, the present study was designed to further investigate the role of TLR4 on AT remodeling and cachexia development. Using a genetic ablation and pharmacological inhibition of TLR4 we demonstrate that the TLR4 pathway plays an essential role in modulating both thermogenic and pro-inflammatory pathways in fat. Suppression of TLR4 signaling results in a robust resistance to AT remodeling, reduced cachexia, and increased survival. Our study sheds light on TLR4 pathway as a promising target for therapeutic intervention for cachexia.
TLR4 deletion attenuates AT remodeling induced by cancer cachexia in TB-mice
During the development of cancer cachexia, AT remodeling arises from morphofunctional and inflammatory changes that result in AT dysfunction. Consistent with these observations, we used the Lewis Lung Carcinoma (LLC) cell line to induce cancer-associated cachexia in vivo10,11. Additionally, we also determined whether LLC tumor induces AT remodeling through activation of TLR4-mediated AT immunometabolism changes. Thus, we utilized the existing TLR4−/− mice14 to examine the role of TLR4 in cancer cachexia. 28 days after LLC cell inoculation a 12% reduction in body weight was measured in tumor-bearing wild-type (WT TB) mice, a classic sign of cachexia (Fig. 1A). However, in the TLR4−/− TB mice there was no weight loss, without any differences in tumor growth (Fig. S1). No pulmonary metastasis was detected in any of the evaluated TB groups.
Adipocyte atrophy in scAT, demonstrated by a marked reduction in adipocyte size (58.2%), and significantly increased fibrosis, demonstrated by total collagen content in the extracellular matrix (Fig. 1B,C), were also observed in WT TB mice. Furthermore, the presence of CD68 and TNF-α positive staining in scAT was found, while no significant difference in CD3 positive cells in scAT was observed (Fig. 1B). On the other hand, tumor-bearing TLR4−/− TB mice presented less adipocyte atrophy and a reduction in the number of TNF-α and CD-68 positive cells in scAT when compared to WT TB group (Fig. 1A–C). Taken together, the effects of cachexia on inducing AT remodeling were attenuated in TLR4−/− TB mice.
To better understand AT inflammation and the role of macrophage polarization during cancer-associated cachexia, we evaluated AT macrophage (ATMϕs) profiles in scAT from WT and TLR4−/− mice during development of the cachexia syndrome. In this case, scAT demonstrated an increase in ATMϕs (6.0-fold) (Fig. 1D,E) with an enhancement in M1 (7.0-fold) and a decrease in M2 ATMϕs in the WT TB mice (Fig. 1D). In contrast, the TLR4−/− TB mice presented a consistent attenuation in ATMϕs infiltration (55.3%) and a decrease in the ratio of M1/M2 macrophages (93.2%) in the scAT when compared to WT TB mice (Fig. 1D,E). In models of LLC-induced cachexia, ATMϕs polarization tends to be directed towards an M1 phenotype, making these results even more significant. In addition to the macrophage polarization, the proportion of M2 macrophage was higher in the TLR4−/− (4.5-fold) and TLR4−/− TB (8-fold) mice when we compared with their respective controls (Fig. 1D). Therefore, the attenuation of TLR4 was associated with a reduction in the recruitment process of ATMϕs, thus playing an interesting role in the development of cancer cachexia syndrome.
Triglyceride turnover is not affected during cachexia in TLR4−/− TB-mice
Considering the attenuation of the AT remodeling seen in the TLR4−/− TB mice in response to cachexia, the next step was to evaluate the cachectic response of primary adipocytes (scAT) after isoproterenol (ISO)-stimulus, to evaluate the lipolytic response. During the development of cachexia, an increase in glycerol release (1.2- fold) was observed in the WT TB group compared to the WT group (Fig. 2A). On the contrary, adipocytes in the TLR4−/− TB mice showed lower lipolytic response when compared to the WT TB group (Fig. 2A).
Once the attenuation of cachexia-induced lipolysis was shown in the TLR4−/− TB mice, serum concentrations of non-esterified fatty acids (NEFA) and palmitic acid levels from the scAT in the different experimental groups were evaluated (Fig. 2B,C). A significant increase was found in NEFA serum concentrations after the cachexia induction in WT TB mice. However, the serum concentration of NEFA was reduced by 36.3% in the TLR4−/− TB mice (Fig. 2B) when compared to the WT TB mice. Palmitic acid levels in scAT were reduced by 18.9% in the WT TB mice when compared with the WT mice (Fig. 2C). Interestingly, the TLR4−/− group had lower levels of palmitic acid in the scAT when compared to the WT group and no difference was observed between the TLR4−/− and TLR4−/− TB mice (Fig. 2C).
The main lipolytic enzymes were also evaluated. Hormone-sensitive lipase (HSL) showed an increased phosphorylation at ser-660 in the WT TB group, without any alteration in the TLR4−/− TB group (Fig. 2D,E). In this scenario, since triglyceride (TG) turnover is affected by cachexia and partially diminished by TLR4 deletion, we evaluated genes involved in fatty acid metabolism in adipocytes. In general, the effect of cachexia on the expression of scAT metabolic markers was reduced in the absence of TLR4. In particular, cachexia reduced expression of Pck1, Acsl1, Acads and Me3 in the WT TB, but not in the TLR−/− TB mice (Fig. 2F).
TLR4 deletion reduces AT browning and p38MAPK signaling in TB mice
To assess whether TLR4 mediates AT energy expenditure, thermogenic markers were measured in scAT. We found that UCP1 staining was increased (1.3-fold) in TB mice (Fig. 3A,B). Surprisingly, TLR4−/− and TLR4−/− TB mice showed a significant reduction in UCP1 staining (Fig. 3A,B). Corroborating this data, the gene profile of the browning “signature” from scAT showed a marked upregulation of Ucp1 levels in the WT TB mice, but in the TLR4−/− TB mice there was a significant attenuation in the browning profile, as illustrated in Fig. 3C.
Adaptive thermogenesis and UCP1 expression are mainly regulated by sympathetic tone through β-adrenergic signaling and cAMP levels, which can be directly sensed by protein kinase A (PKA) and thus lead to direct or indirect activation of p38 MAPK. Although cachexia induced phosphorylation of p38 MAPK in the WT TB group, there was no change in the TLR4−/− TB group. (Fig. 3D,E). There were also no changes in phosphorylation of AMPK (Fig. 3D,E) and PKA substrates in any of the experimental conditions evaluated (Fig. S2) in the TLR4−/− TB mice.
TLR4 is required for cold-induced browning of inguinal white adipose tissue
Having shown that TLR4 is required for full browning of scAT during cancer-associated cachexia, we subjected WT and TLR4−/− mice to chronic cold (6 °C) challenge to see if TLR4 is required for general adaptive thermogenesis. There was a marked reduction in cold-induced browning in the TLR4−/− mice compared to the WT mice (Fig. 4A,B). Interestingly, expression of proteins linked to the lipolytic pathway (Phospho HSL and ATGL) were the same across both groups (WT 6 °C and TLR4−/− 6 °C), when compared to WT at 22 °C (Fig. 4C,D). Therefore, we did not see any UCP1 protein enhancement in the TLR4−/− mice after cold exposure. We observed a statistically significance decrease in UCP1 expression in the TLR4−/− 6 °C group when compared to WT 6 °C group (Fig. 4C,D). Although oxidative metabolism (TCA cycle) was stimulated by chronic cold exposure in both groups (WT and TLR4−/−), an increase in Cpt1b gene expression was evidenced only in the WT group, with no change in the TLR4−/− mice (Fig. 4E).
Atorvastatin treatment increases survival and attenuates browning
In order to propose a translational approach and to correlate the data with the genetic model, WT TB mice were treated with a 3-hydroxy-3-methyl-glutaryl-CoA (HMG-CoA) reductase enzyme inhibitor, atorvastatin (ATOR). In recent years15,16,17, the anti-inflammatory and pleiotropic effects of this drug have been described, such as inhibition of NFκB activation and downregulation of Tlr4 and Myd88 gene expression. We also confirmed the downregulation of Tlr4 after ATOR treatment in scAT, as illustrated in Fig. S3.
To evaluate if pharmacological attenuation of TLR4 would have an impact on the clinical features of cachexia, WT TB mice were treated with ATOR (Fig. 5). The treatment was effective in prolonging the mice survival (Fig. 5A) and also in attenuating scAT atrophy (2.0-fold) and tumor mass growth (49.7%) when compared to a TB untreated group (Fig. 5B). Other markers of the cachexia syndrome evolution in the animal model were attenuated in those treated with ATOR. Body weight (BW) plateau, which represents the highest value of body weight observed in the experimental period, showed an increase of 32% in the treated animal when compared to the WT TB group. The tumor of ATOR-treated animals appeared later than the tumor of the non-treated animals (Table S1). Lipolysis was also evaluated in 3T3-L1 cells. Cells that were stimulated with lipopolysaccharide (LPS) and treated with ATOR showed a reduced lipolytic response to the LPS stimulation when compared with untreated cells, showing a significant reduction at 6 hours (41.3%) and 24 hours (45.6%) as illustrated in Fig. 5C.
Interestingly, ATOR was also able to reduce cachexia-induced browning and atrophy of scAT (Fig. 5D,E). Furthermore, the profile of the signature browning genes from scAT showed marked downregulation of Ucp1 (85.5%), Prdm16 (91.7%) and Cidec (98.3%) after ATOR treatment in TB mice, as shown in Fig. 5E. In respect of ATMϕs polarization, we analyzed the classical markers for M1 (Nos2 and CD11c) and M2 (Arg1 and CD301) in the scAT. No significant difference was observed in mRNA for M1 markers (despite a strong trend). However, Arg1 expression increased 5.8-fold in the TB + ATOR mice. This suggests that ATOR treatment appeared to reverse the previously described M1 ATMϕs polarization, a similar effect to that which we found in the TLR4−/− mice (Fig. 5F).
During cancer cachexia syndrome, systemic inflammation plays a key role in the scAT remodeling, directly influencing the composition of the immune system present in AT, and, consequently, the patient’s immune response. In the present study, we demonstrated that WT TB mice present high plasma concentrations of proinflammatory cytokines in response to cancer-associated cachexia (Fig. 5G). However, after pharmacological treatment with ATOR, it was possible to see a significant decrease in almost all these cytokines, returning the plasma concentration levels to a degree comparable with the WT group (Control group - without cachexia). These results demonstrate that treatment with ATOR improved the inflammatory profile of the tumor-bearing mice and ameliorated some general cachexia parameters after ATOR treatment similarly to the values found in the TLR4−/− TB mice (Table S1).
Cancer-associated cachexia is a complex metabolic state accompanied by poor quality of life, high mortality and also resistance to chemotherapy18,19,20. Several clinical interventions have sought to improve cachexia through anti-inflammatory drugs and insulin sensitizers but studies have shown limited results21,22. Circulating factors produced by the tumor and/or host itself may play an important role in therapeutic treatment for cachexia. Once the factors are identified, they can be targeted for therapeutic intervention.
During the development of cancer cachexia, AT remodeling occurs predominantly through morphofunctional rearrangement that is an endpoint process associated with immune-metabolic dysfunction of such tissue4,5,9,18,23. In WT TB mice, body weight loss and AT mass wasting were detected, as well as a set of features related to AT remodeling. Interestingly, the TLR4−/− TB animals were shown to be protected against the effects of cachexia, particularly in relation to an absence of weight loss and AT wasting. In obesity (in humans and in mice models)24,25,26 a close link between inflammation, over-production of extracellular matrix (ECM) components, the development of fibrosis and consequent tissue remodeling has been demonstrated in the liver and kidneys. In these organs, there is mounting evidence that TLR4 acts as a key regulator in fibrogenesis27,28,29, a condition that may or may not be related to TLR4−/− ATMϕs response. However, the possible involvement of TLR4 and ECM remodeling in cancer cachexia was not a focus of this study and needs further analysis.
Another important aspect of cancer cachexia-induced AT remodeling is the establishment of AT inflammation that was recently shown to be characterized by increased recruitment of ATMϕs, including activated M1 and M2 macrophages5. In fact, ATMϕ infiltration of scAT has consistently been demonstrated in different experimental models30. This scenario has also been demonstrated in patients with cancer and cachexia4,5. However, the polarization of ATMϕs in scAT has only recently been addressed5,7. In this regard, we extended these findings by presenting in greater detail that in cachexia induced by LLC cells, ATMϕs polarization tends to be directed to an M1 phenotype. On the other hand, the TLR4−/− TB mice presented a consistent attenuation in ATMϕs infiltration in scAT, but in this phenotype, the polarization tended towards an M2 phenotype. The exact mechanism by which TLR4 deficiency affects AT inflammation remains to be explored and would require the generation of an adipose tissue-specific knockout mouse model for TLR4.
Regarding the morphological and inflammatory dysfunction that results in AT remodeling in response to cachexia, TG turnover is the most well-characterized metabolic disorder associated with this condition4,5,31, with increased lipolysis being the mechanism best described in the literature23,32. Higher adipocyte lipolysis was observed in the cachectic WT mice, which is in line with recent studies demonstrating that AT lipolysis represents a key factor involved in weight loss in cancer cachexia in both animals23,32 and human patients33. However, adipocytes from the TLR4−/− mice were less affected by cachexia and showed a very attenuated response to ISO-stimulation.
As TLR4−/− TB mice were found to be resistant to the lipolytic effects induced by cachexia, we also evaluated some parameters related to the cycle of NEFA release from the breakdown of stored TG and re-esterified to TG (TG turnover). In human patients with cachexia, enhanced TG turnover activity in AT has been shown, as determined by a metabolic labeling assay20. In our study, WT TB animals showed a reduction of palmitic acid level in the scAT, corroborating the other results regarding the increase in fatty acids associated with cachexia. Interestingly, this process showed less intensity in TLR4−/− TB mice, including in respect of AT morphofunctional preservation. These data substantiate those found in some recent studies that demonstrated an impairment of TG turnover by cachexia5,32. However, it should be noted that the TLR4−/− animals already had lower levels of palmitic acid in the scAT compared to the WT animals. Thus, whether or not this fact is associated with metabolic repercussions requires further investigation.
In general, the effect of cachexia on expression of AT metabolic markers was attenuated in the absence of TLR4, particularly in genes related to glyceroneogenesis and TG reesterification. A study by Pang et al. proposed that TLR4 might play a role as a physiological regulator of fuel metabolism34. In their study, TLR4−/− mice showed lipid abnormalities during fasting that might result from increased TG mobilization, possibly through increased fatty acid reesterification in scAT, decreased fatty acid oxidation, and/or increased de novo lipogenesis in key metabolic tissues. These results corroborate those presented in this study, demonstrating that, in addition to reduced lipolysis, TLR4 deletion may also be involved the avoidance of the deleterious modifications in fatty acid reesterification, induced by cachexia.
It has recently been shown that cachexia induces AT browning in addition to changes in immune-modulatory activity. In this scenario, chronic inflammation and β-adrenergic activation of thermogenesis functionally cooperate in the pathogenesis of cachexia3,7. In the present study, LLC-induced cachexia resulted in a consistent browning phenotype (morphology) of scAT followed by a marked upregulation of Ucp1 levels. These results are in line with those presented in other studies with the same experimental model35.
Interestingly, TLR4−/− TB mice showed a significant reduction in AT browning, as well as in the levels of phosphorylation of p38 MAPK, both induced by cachexia. The browning phenotype induced by cancer cachexia might, therefore, be activated indirectly by p38 MAPK, and the presence of TLR4 appears to be important in this process. Recently, it was demonstrated that phosphorylation of p38 MAPK activity was higher in the UCP1 positive axillary AT of cachectic (K5-SOS) animals7. Adaptive thermogenesis and UCP1 expression are mainly regulated by sympathetic tone through β-adrenergic signaling and cAMP levels, which can be directly sensed by protein kinase A (PKA) and thus lead to direct or indirect activation of p38 MAPK36,37. However, a well-designed recent study using experimental models demonstrated that full activation of adipose browning, including Ucp1 expression, in mouse and human cachexia seems to be variable, and the functional contribution to overall energy coats needs to be determined23.
The reduction of browning induced by cachexia has been demonstrated in different studies, through treatment with cyclooxygenase-2 inhibitor (Sulindac), β3-adrenergic receptor antagonist (SR59230A)7 and a knockout model for parathyroid hormone-related protein (PTHrP)38. However, none of these studies have shown results on survival, which is a key parameter to verify the pre-clinical efficacy of pharmacological intervention.
Taking into account the beneficial effects found in the genetic model (TLR4−/− TB), and to take a translational (preclinical) approach that would include evidence on survival, we chose to treat the animals with an already well-established drug with a well-characterized TLR4 antagonist effect (ATOR). Some elegant studies have consistently shown that ATOR has an inhibitory effect on the TLR4 pathway15,39,40,41,42,43. Another important criterion for drug choice was its direct effect on the down-regulation of this receptor39,40,41 as well as regulation of downstream pathways15 and target cytokines42,43. Additionally, the fact that it is already well-established in the market, in addition to presenting a very favorable toxicity profile, was also considered44,45.
We demonstrated that ATOR treatment was effective in increasing the survival of the cachectic mice, in addition to attenuating the main signs of cachexia syndrome, an effect also observed in the genetic TLR4−/− model. In cachexia, systemic inflammation is highly dependent on the patient’s immune response46 and, at least in experimental models, IL-6, TNF-α, and IL-1β are major contributors to the wasting syndrome6,47. The major inflammatory cytokines were abrogated in the same way, both in TLR4−/− and pharmacological inhibition of TLR4 in TB mice. In fact, systemic activation of TLR4 increases cytokine synthesis and release from various host cells as an innate immune response10. Moreover, a recent study showed the presence of elevated levels of TNF-α and IL-6 in animals bearing-LLC tumor, which was attenuated in TLR4−/− mice in the same experimental condition (cachexia)10, corroborating the findings of our study.
Moreover, in addition to the anti-inflammatory and protective effects of skeletal muscle mass previously demonstrated10, we have shown that TLR4 activation is “directly” involved in metabolic disorders in AT such as increased TG turnover and browning phenotype, both relevant parameters involved in the remodeling and dysfunction of AT induced by cachexia. We showed in the present study that TLR4 disruption attenuated AT remodeling and metabolic dysfunction during the syndrome, thus suggesting a possible therapeutic target for cancer-induced cachexia.
Some limitations of this study should be acknowledged. First, most of our findings are based on the data obtained from TLR4 whole-body knockout mice. Global TLR4 targeting extends our knowledge of the role of this receptor in AT remodeling caused by cancer cachexia. The TLR4 null mouse model has a significant advantage compared with other knockouts since it has prolonged survival from cachexia. The global knockout, however, did not allow us to track TLR4 function at specific developmental stages of cachexia. Second, although some well-designed studies have also demonstrated the direct effects of ATOR on modulating the various steps of the TLR4 signaling pathway, other classic drug effects, such as cholesterol-lowering or alternative anti-inflammatory may have beneficial effects related to the development of cachexia syndrome. Having additional orthogonal approaches to modulate TLR4 signaling would be advantageous in validating our findings. However, statins have been reported to have some possible side effects including myopathy, which should be taken into account when considering their use in relation to the cachexia. Moreover, the exact mechanism of action of statins on Tlr4 expression remains unknown. Although several papers show a downregulation in Tlr4 using statins, further studies are needed to explore the exact molecular mechanisms underlying the regulation of statin-dependent Tlr4 downregulation. Therefore, from a comprehensive and translational point of view, the effectiveness of pharmacologic inhibition of TLR4 by ATOR and other agents on the onset and progression of cancer cachexia, in particular the attenuation of the kinetics of tumor growth, still needs further study, especially in a clinical setting.
Our combined data from the TLR4 knockout model and ATOR treatment clearly shows that TLR4 plays an essential role in mediating tumor-induced AT remodeling and cachexia development. Therefore, disturbing TLR4 signaling systemically may prevent scAT remodeling by abrogating, at least in part, its indirect effects. At this point, both the genetic ablation and the pharmacological inhibition of TLR4 were able to attenuate both the remodeling of the AT (atrophy and inflammation) and the metabolic dysfunction (lipolysis) induced by cachexia (Fig. 6). Also, for the first time, we have presented evidence that the TLR4 receptor may play an essential role in the browning phenotype induced by cachexia. Interestingly, TLR4−/− also showed resistance to browning, suggesting that the TLR4 receptor plays an essential role in the morphological alterations and homeostatic energy expenditure. Finally, it is clinically noteworthy that animals treated with a TLR4 inhibitor displayed general attenuation of AT remodeling and systemic inflammation (Fig. 6), presenting an increase in the mice survival, which may have a relevant role as an adjuvant treatment option, as well as being a strong candidate for novel anti-cachectic therapy development.
Eight-week-old male C57BL/6 J and TLR4−/− (Toll-like Receptor 4 - B6.B10ScN-Tlr4lps-del/JthJ - JAX stock #007227) mice were obtained from Jackson Laboratory, for validation and phenotypic characterization of TLR4−/− see Fig. S4. Mice were housed on a 12 h light/dark schedule and had free access to water and food. Mice were divided into four different groups: Wild Type (WT); WT tumor-bearing (WT TB); TLR4−/− and TLR4−/− tumor-bearing (TLR4−/− TB). For chronic cold challenge, WT and TLR4−/− mice were single-caged and housed at room temperature (23 °C) and cold exposure (6 °C) for six days (n = 5 per genotype and per condition) on a 12 h light/12 h dark cycle with access to a standard chow diet. All of the studies performed were approved by the Ethical Committee for Animal Research from the University of Mogi das Cruzes approved all the adopted procedures, which were carried out in accordance with the ethical principles stated by the Brazilian College of Animal Experimentation - Protocol n. 009/2013.
Tumor Model and Collection of Tissues
Lewis Lung Carcinoma (LLC) tumor cells were used for inducing cancer cachexia syndrome. LLC was injected subcutaneously into the right flanks (200 μl LLC cells −3.5 × 105). Non-tumor bearing control mice received Phosphate-buffered saline (PBS) only. Development of cachexia was monitored by tumor size and body weight for 28 days. The impact of tumor growth and development of cachexia on animal welfare were considered, with appropriate measures to monitor and alleviate suffering implementation according to adopted endpoint criteria9,48. Overnight-fasted mice were euthanized by decapitation without anesthesia, serum was collect and centrifuged (400 g, 15 min, 4 °C) and stored at −80 °C for later analysis. After euthanasia, subcutaneous adipose tissue (scAT) was carefully dissected and weighed. All the mice were checked if they are positive for the presence of metastasis in the lungs, as well as other visceral organs. If there is a presence of metastasis, the animals are excluded from the experimental group (exclusion criteria). Body weight was measured daily, at the same time, over the 28-day experimental period on a precision scale (Ohaus®).
For the inhibition of the TLR4 receptor via pharmacological action, Atorvastatin (Citalacor®) treatment was performed, currently described as a selective antagonist for TLR4. Only WT TB mice were used for this procedure. The animals were divided into two experimental groups: WT TB + PBS and WT TB + Atorvastatin (TB + ATOR). The animals that received Atorvastatin were treated with a concentration of 10 mg/kg/day by orogastric gavage during the 27-day of protocol. The same protocol was performed for the animals that underwent the survival experiment.
scAT was fixed in HistoChoice® MB (Amresco), pH 7.4 for 3 h. Fixed tissues were dehydrated and 8-μm sections were used. H&E and Picrosirius staining were performed according to standard procedures (Sigma-Aldrich). The sections were analyzed with a Leica microscope (DM 750). Morphometric aspects were measured by Imagen Pro-Plus 6.0.
Immunohistochemistry of scAT was carried out with sections fixed by HistoChoice® MB (Amresco) at pH 7.4 for 3 hours. Fixed tissues were dehydrated and 5-μm sections were used. Dehydrated tissue was blocked using a two different blocking buffers, a buffer solution of endogenous peroxidase activity with 0.3% H2O2 in methanol and buffer solution of free protein binding sites with 5% normal goat serum. The following primary antibodies were used: UCP1 (ab10983), TNFα (ab6671), CD68 (ab955) and CD3 (ab16669). We employed the polymer-peroxidase method, using Histofine Simple Stain MAX-PO (Nichirei Biosciences) and Sigma Fast 3,3-diaminobenzidine as substrate (Sigma-Aldrich). Sections were counter-stained with hematoxylin.
RNA isolation and qRT-PCR
Total RNA was isolated from scAT using QIAzol Lysis Reagent Protocol (QIAGEN) following the manufacturer’s instructions. cDNA was synthesized from 2 μg of total RNA using iScript cDNA Synthesis Kit (BioRad). RPL19 served as control for internal reference gene. Primer sequences used for qRT-PCR analyses were listed in Table S2. Analyses of qRT-PCR products were performed with the Prism 7500 SDS software (Thermo Fisher Scientific). Relative quantification of mRNA amount was obtained by the by 2−(ΔΔCt) method.
For protein expression analyses, tissues were homogenized in lysis buffer (20 mM HEPES, 150 mM NaCl, 2 mM EDTA, 1% Triton X-100, 0.1% SDS, 10% glycerol, 0.5% sodium deoxycholate) supplemented with Halt protease and phosphatase inhibitors (Thermo Pierce). Samples from tissue lysates were then resolved by SDS-PAGE, and immunoblots were performed using standard protocols. Membranes were blotted with the following antibodies: HSL (ab45422); phospho-HSL Ser660 (Cell Sig. #4126); ATGL (Cell Sig. #2138); P38 MAPK (Cell Sig. #8690); phospho P38 MAPK (Cell Sig. #9211); phospho-AMPK (Thr172 - Cell Sig. 2531); AMPK (Cell Sig. 2532); phospho-PKA substrate (Cell Sig. #9624); Adiponectin (ab62551) and UCP1 (ab10983), all overnight. The membranes were incubated with the goat anti-rabbit IgG conjugated to horseradish peroxidase secondary antibody (7074 - Cell Signaling Technology) for 1 h at room temperature and were detected by ECL Prime (Amersham). For the control of protein loading and transfer, we used Ponceau staining of the membranes. Quantification of the antigen–antibody complex was performed by the ImageJ Analysis Software.
SVF isolation and Flow cytometry analysis
Stroma vascular fraction (SVF) from scAT were excised and minced in PBS with calcium chloride and 0.5% BSA. Collagenase II (Sigma-Aldrich) was added to 1 mg/ml and incubated at 37 °C for 30 minutes with shaking. The cell suspension was filtered through a 100 μm filter and then spin down at 300 g for 5 minutes to separate floating adipocytes from the SVF pellet. Cells were incubated with Fc Block (BD Biosciences) prior to staining with conjugated antibodies for 15 minutes at 4 °C. SVF were purified and stained with the following antibody panel: ATMϕs were defined as CD68+F4/80+ subpopulations. M1 and M2 ATMϕs were defined as CD68+F4/80+CD11c+CD206− and CD68+F4/80+CD11c−CD206+, respectively. Cells were analyzed using a BD Accuri (BD biosciences). The data was analysis was performed using FlowJo.
Measurement of plasma cytokines
Plasma was collected using plasma separators (BD Biosciences). Cytokine levels were determined using a Milliplex assay kit (Milliplex MAP mouse cytokine/chemokine magnetic bead panel, #MCYTOMAG-70K - Millipore). Data were analyzed using the Bio-Plex manager software (Bio-Rad Laboratories).
Isolated adipocytes were suspended in 40 ml of Kreb’s/Ringer/phosphate buffer (pH 7.4, with 1% BSA) in 0.6 ml microtubes with 20 ml of adenosine deaminase (0.2 U/ml) and were incubated at 37 °C for 5 min to degrade endogenously released adenosine, which is a potent inhibitor of lipolysis. The cells were then incubated for 1 h at 37 °C either in the presence (stimulated) or absence (basal) of isoproterenol (10−5M, β-adrenergic agonist) in a final volume of 200 μL. At the end of incubation, the reaction mixture was blocked by moving the tubes to a cold-water bath followed by centrifugation at 3500 g for 5 min at 4 °C. The infranatant was carefully transferred to microtubes containing 150 μL of silicone oil and re-centrifuged at 3500 g for 2 min. The concentration in the medium of released glycerol (nmol/104 cells) was quantified with a commercially available reagent (Sigma-Aldrich), measured according to the manufacturer’s instructions. The lipolysis response was assessed by the ratio of glycerol released relative to the basal condition. For additional analyses of the possible effect of ATOR on inhibiting lipolysis, 3T3-L1 cells were stimulated during 1 h, 6 h and 24 h with lipopolysaccharide (LPS, 100 ng/mL). The concentration in the medium of released glycerol was quantified with a commercially available reagent (Sigma-Aldrich), measured according to the manufacturer’s instructions.
3T3-L1 pre-adipocytes were plated at 1 × 104 in 24-well culture plates and cultured in DMEM (Dulbecco’s Modified Eagle’s Medium) with 4500 mg glucose supplemented with 10% bovine serum and 2% penicillin with streptomycin at pH 7.4. The cells were maintained at 37 °C with 5% carbon dioxide (CO2) so as not to reach complete confluence until they were induced to differentiate. Preadipocytes were brought to complete confluence (day-2) and after two days of confluence, the culture medium was replaced by differentiation inducer medium, consisting of DMEM, supplemented with 10% fetal bovine serum (FBS), 1 μM dexamethasone, 0.5 mM 3-isobutyl-1-methylxanthine (IBMX) and 1.67 μM bovine insulin. From the second day of differentiation, the cells were maintained in culture medium containing only 0.83 μM insulin and 10% FBS which was changed every 48 hours for eight days.
Adipose Tissue lipid analysis
The total scAT lipids were extracted using the method of Folch49. Transesterification of the lipid extracts was performed with acetyl chloride (5% CH3COCl in methanol) and fatty acids (FAs) composition was determined as methyl esters using a Varian Model 3900 Gas Chromatograph (GC) coupled to flame ionization detection (FID). FAs were identified by comparing the retention time using three known standards of fatty acid methyl esters (FAME). The FAMEs were analyzed in a capillary column (CP Wax 52 CB), 0.25 mm in thickness, 0.25-μm inside diameter, and 30 m in length. Hydrogen was used as a carrier gas at a linear velocity of 22 cm/s. The temperature program was 170 °C for 1 min followed by a 2.5 °C/min ramp to 240 °C, and a final hold time of 5 min. Injector and FID temperatures were 250 and 260 °C, respectively. The profiles of individual FAs were calculated using an automatic integrator and presented as percentages of total FAs according to the peak areas. Data are presented as palmitic acid profile (%) of total lipids.
Non-Esterified Fatty Acids (NEFA)
50 μL of serum was collected from the different groups and the levels of NEFA was quantified using a kit following the manufacturer’s recommendations (MAK044, Sigma).
Data were analyzed in GraphPad Prism 7 (GraphPad Software). The statistical significance of the differences in the means of experimental groups was determined by Student’s t-test or and 2-way ANOVA, followed by Tukey’s post hoc comparison tests. The data are presented as means ± SEM. P values ≤ 0.05 were considered significant.
Fearon, K., Arends, J. & Baracos, V. Understanding the mechanisms and treatment options in cancer cachexia. Nat Rev Clin Oncol 10, 90–99, https://doi.org/10.1038/nrclinonc.2012.209 (2013).
Fearon, K. Cachexia: Treat wasting illness on multiple fronts. Nature 529, 156, https://doi.org/10.1038/529156b (2016).
Tsoli, M., Swarbrick, M. M. & Robertson, G. R. Lipolytic and thermogenic depletion of adipose tissue in cancer cachexia. Semin Cell Dev Biol 54, 68–81, https://doi.org/10.1016/j.semcdb.2015.10.039 (2016).
Batista, M. L. Jr. et al. Cachexia-associated adipose tissue morphological rearrangement in gastrointestinal cancer patients. J Cachexia Sarcopenia Muscle 7, 37–47, https://doi.org/10.1002/jcsm.12037 (2016).
Henriques, F. S. et al. Early suppression of adipocyte lipid turnover induces immunometabolic modulation in cancer cachexia syndrome. FASEB J 31, 1976–1986, https://doi.org/10.1096/fj.201601151R (2017).
Batista, M. L. Jr. et al. Adipose tissue-derived factors as potential biomarkers in cachectic cancer patients. Cytokine 61, 532–539, https://doi.org/10.1016/j.cyto.2012.10.023 (2013).
Petruzzelli, M. et al. A switch from white to brown fat increases energy expenditure in cancer-associated cachexia. Cell Metab 20, 433–447, https://doi.org/10.1016/j.cmet.2014.06.011 (2014).
Aoyagi, T., Terracina, K. P., Raza, A., Matsubara, H. & Takabe, K. Cancer cachexia, mechanism and treatment. World J Gastrointest Oncol 7, 17–29, https://doi.org/10.4251/wjgo.v7.i4.17 (2015).
Beluzi, M. et al. Pioglitazone treatment increases survival and prevents body weight loss in tumor-bearing animals: possible anti-cachectic effect. PLoS One 10, e0122660, https://doi.org/10.1371/journal.pone.0122660 (2015).
Zhang, G. et al. Toll-like receptor 4 mediates Lewis lung carcinoma-induced muscle wasting via coordinate activation of protein degradation pathways. Sci Rep 7, 2273, https://doi.org/10.1038/s41598-017-02347-2 (2017).
Cannon, T. Y. et al. The effect of altered Toll-like receptor 4 signaling on cancer cachexia. Arch Otolaryngol Head Neck Surg 133, 1263–1269, https://doi.org/10.1001/archotol.133.12.1263 (2007).
Beutler, B. A. TLRs and innate immunity. Blood 113, 1399–1407, https://doi.org/10.1182/blood-2008-07-019307 (2009).
Lu, Y. C., Yeh, W. C. & Ohashi, P. S. LPS/TLR4 signal transduction pathway. Cytokine 42, 145–151, https://doi.org/10.1016/j.cyto.2008.01.006 (2008).
Hoshino, K. et al. Cutting edge: Toll-like receptor 4 (TLR4)-deficient mice are hyporesponsive to lipopolysaccharide: evidence for TLR4 as the Lps gene product. J Immunol 162, 3749–3752 (1999).
Gao, W., Xiong, Y., Li, Q. & Yang, H. Inhibition of Toll-Like Receptor Signaling as a Promising Therapy for Inflammatory Diseases: A Journey from Molecular to Nano Therapeutics. Front Physiol 8, 508, https://doi.org/10.3389/fphys.2017.00508 (2017).
Chansrichavala, P., Chantharaksri, U., Sritara, P., Ngaosuwankul, N. & Chaiyaroj, S. C. Atorvastatin affects TLR4 clustering via lipid raft modulation. Int Immunopharmacol 10, 892–899, https://doi.org/10.1016/j.intimp.2010.04.027 (2010).
Leon, C. G., Tory, R., Jia, J., Sivak, O. & Wasan, K. M. Discovery and development of toll-like receptor 4 (TLR4) antagonists: a new paradigm for treating sepsis and other diseases. Pharm Res 25, 1751–1761, https://doi.org/10.1007/s11095-008-9571-x (2008).
Baracos, V. E., Martin, L., Korc, M., Guttridge, D. C. & Fearon, K. C. H. Cancer-associated cachexia. Nat Rev Dis Primers 4, 17105, https://doi.org/10.1038/nrdp.2017.105 (2018).
Fearon, K. et al. Definition and classification of cancer cachexia: an international consensus. Lancet Oncol 12, 489–495, https://doi.org/10.1016/S1470-2045(10)70218-7 (2011).
Porporato, P. E. Understanding cachexia as a cancer metabolism syndrome. Oncogenesis 5, e200, https://doi.org/10.1038/oncsis.2016.3 (2016).
Bossola, M. et al. Increased muscle proteasome activity correlates with disease severity in gastric cancer patients. Ann Surg 237, 384–389, https://doi.org/10.1097/01.SLA.0000055225.96357.71 (2003).
Konishi, M., Ishida, J., von Haehling, S., Anker, S. D. & Springer, J. Nutrition in cachexia: from bench to bedside. J Cachexia Sarcopenia Muscle 7, 107–109, https://doi.org/10.1002/jcsm.12111 (2016).
Rohm, M. et al. An AMP-activated protein kinase-stabilizing peptide ameliorates adipose tissue wasting in cancer cachexia in mice. Nat Med 22, 1120–1130, https://doi.org/10.1038/nm.4171 (2016).
Vila, I. K. et al. Immune cell Toll-like receptor 4 mediates the development of obesity- and endotoxemia-associated adipose tissue fibrosis. Cell Rep 7, 1116–1129, https://doi.org/10.1016/j.celrep.2014.03.062 (2014).
Cancello, R. et al. Reduction of macrophage infiltration and chemoattractant gene expression changes in white adipose tissue of morbidly obese subjects after surgery-induced weight loss. Diabetes 54, 2277–2286 (2005).
Weisberg, S. P. et al. Obesity is associated with macrophage accumulation in adipose tissue. J Clin Invest 112, 1796–1808, https://doi.org/10.1172/JCI19246 (2003).
Aoyama, T., Paik, Y. H. & Seki, E. Toll-like receptor signaling and liver fibrosis. Gastroenterol Res Pract 2010, https://doi.org/10.1155/2010/192543 (2010).
Campbell, M. T. et al. Toll-like receptor 4: a novel signaling pathway during renal fibrogenesis. J Surg Res 168, e61–69, https://doi.org/10.1016/j.jss.2009.09.053 (2011).
Seki, E. et al. TLR4 enhances TGF-beta signaling and hepatic fibrosis. Nat Med 13, 1324–1332, https://doi.org/10.1038/nm1663 (2007).
Surmi, B. K. & Hasty, A. H. Macrophage infiltration into adipose tissue: initiation, propagation and remodeling. Future Lipidol 3, 545–556, https://doi.org/10.2217/17460818.104.22.1685 (2008).
Fukawa, T. et al. Excessive fatty acid oxidation induces muscle atrophy in cancer cachexia. Nat Med 22, 666–671, https://doi.org/10.1038/nm.4093 (2016).
Arner, P. & Langin, D. Lipolysis in lipid turnover, cancer cachexia, and obesity-induced insulin resistance. Trends Endocrinol Metab 25, 255–262, https://doi.org/10.1016/j.tem.2014.03.002 (2014).
Agustsson, T. et al. Mechanism of increased lipolysis in cancer cachexia. Cancer Res 67, 5531–5537, https://doi.org/10.1158/0008-5472.CAN-06-4585 (2007).
Pang, S., Tang, H., Zhuo, S., Zang, Y. Q. & Le, Y. Regulation of fasting fuel metabolism by toll-like receptor 4. Diabetes 59, 3041–3048, https://doi.org/10.2337/db10-0418 (2010).
Kir, S. et al. Tumour-derived PTH-related protein triggers adipose tissue browning and cancer cachexia. Nature 513, 100–104, https://doi.org/10.1038/nature13528 (2014).
Cao, W., Medvedev, A. V., Daniel, K. W. & Collins, S. beta-Adrenergic activation of p38 MAP kinase in adipocytes: cAMP induction of the uncoupling protein 1 (UCP1) gene requires p38 MAP kinase. J Biol Chem 276, 27077–27082, https://doi.org/10.1074/jbc.M101049200 (2001).
Chio, C. C., Chang, Y. H., Hsu, Y. W., Chi, K. H. & Lin, W. W. PKA-dependent activation of PKC, p38 MAPK and IKK in macrophage: implication in the induction of inducible nitric oxide synthase and interleukin-6 by dibutyryl cAMP. Cell Signal 16, 565–575 (2004).
Kir, S. et al. PTH/PTHrP Receptor Mediates Cachexia in Models of Kidney Failure and Cancer. Cell Metab 23, 315–323, https://doi.org/10.1016/j.cmet.2015.11.003 (2016).
Bahrami, A., Parsamanesh, N., Atkin, S. L., Banach, M. & Sahebkar, A. Effect of statins on toll-like receptors: a new insight to pleiotropic effects. Pharmacol Res 135, 230–238, https://doi.org/10.1016/j.phrs.2018.08.014 (2018).
Chansrichavala, P., Chantharaksri, U., Sritara, P. & Chaiyaroj, S. C. Atorvastatin attenuates TLR4-mediated NF-kappaB activation in a MyD88-dependent pathway. Asian Pac J Allergy Immunol 27, 49–57 (2009).
Fang, D. et al. Atorvastatin suppresses Toll-like receptor 4 expression and NF-kappaB activation in rabbit atherosclerotic plaques. Eur Rev Med Pharmacol Sci 18, 242–246 (2014).
Hodgkinson, C. P. & Ye, S. Statins inhibit toll-like receptor 4-mediated lipopolysaccharide signaling and cytokine expression. Pharmacogenet Genomics 18, 803–813, https://doi.org/10.1097/FPC.0b013e3283050aff (2008).
Iwata, A. et al. Inhibitory effect of statins on inflammatory cytokine production from human bronchial epithelial cells. Clin Exp Immunol 168, 234–240, https://doi.org/10.1111/j.1365-2249.2012.04564.x (2012).
Chen, X. et al. Mechanistic Study of Inhibitory Effects of Atorvastatin and Docetaxel in Combination on Prostate Cancer. Cancer Genomics Proteomics 13, 151–160 (2016).
Peng, S. et al. Atorvastatin Inhibits Inflammatory Response, Attenuates Lipid Deposition, and Improves the Stability of Vulnerable Atherosclerotic Plaques by Modulating Autophagy. Front Pharmacol 9, 438, https://doi.org/10.3389/fphar.2018.00438 (2018).
Tsoli, M. & Robertson, G. Cancer cachexia: malignant inflammation, tumorkines, and metabolic mayhem. Trends Endocrinol Metab 24, 174–183, https://doi.org/10.1016/j.tem.2012.10.006 (2013).
Onesti, J. K. & Guttridge, D. C. Inflammation based regulation of cancer cachexia. Biomed Res Int 2014, 168407, https://doi.org/10.1155/2014/168407 (2014).
Paster, E. V., Villines, K. A. & Hickman, D. L. Endpoints for mouse abdominal tumor models: refinement of current criteria. Comp Med 59, 234–241 (2009).
Folch, J., Lees, M. & Sloane Stanley, G. H. A simple method for the isolation and purification of total lipides from animal tissues. J Biol Chem 226, 497–509 (1957).
We thank all members of the Laboratory of Adipose Tissue Biology for helpful discussions and critical reading of the manuscript. This work was supported by São Paulo Research Foundation (FAPESP) Grants: 2010/51078-1, 2015/19259-0 and CNPq 311966/2015-2 to M.L.B.Jr and from Instituto Serrapilheira/Serra-1708-15285 to A.B. The contents of this article are solely the responsibility of the authors and do not necessarily represent the official views of FAPESP.
The authors declare no competing interests.
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Henriques, F., Lopes, M.A., Franco, F.O. et al. Toll-Like Receptor-4 Disruption Suppresses Adipose Tissue Remodeling and Increases Survival in Cancer Cachexia Syndrome. Sci Rep 8, 18024 (2018). https://doi.org/10.1038/s41598-018-36626-3
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