Abstract
Treatment for chronic constipation in older people is challenging and the condition has a major impact on quality of life. A lack of understanding about the causes of this condition has hampered the development of effective treatments. 5-HT is an important pro-kinetic agent in the colon. We examined whether alterations in colonic 5-HT signalling underlie age–related changes in faecal output in mice and whether these changes were due to an increase in TNF-α. Components of the 5-HT signalling system (5-HT, 5-HIAA, SERT) and TNF-α expression were examined in the distal colon of 3, 12, 18 and 24-month old mice and faecal output and water content monitored under control conditions and following the administration of etanercept (TNF-α inhibitor; 1 mg Kg−1). Faecal output and water content were reduced in aged animals. Age increased mucosal 5-HT availability and TNF-α expression and decreased mucosal SERT expression and 5-HIAA. Etanercept treatment of old mice reversed these changes, suggesting that age-related changes in TNFα expression are an important regulator of mucosal 5-HT signalling and pellet output and water content in old mice. These data point to “anti-TNFα” drugs as potential treatments for age-related chronic constipation.
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Introduction
The incidence of chronic constipation (CC) and faecal impaction increases with age, with a prevalence of 50% in community dwelling older people rising to 74% in those that are institutionalized1. The treatment of CC is challenging for both the patient and clinicians and living with CC results in a reduced quality of life which may lead to a loss of independence2,3. Treatment of CC in the elderly is hampered by a lack of recruitment of older people to clinical trials and knowledge of the causes of the condition in this patient group. Previous studies have demonstrated age-related changes in colonic motility in both humans and animal models4,5,6,7,8, although the precise causes of these changes are currently unknown.
Changes in 5-hydroxytryptamine (5-HT) signalling can dramatically affect colonic motility and faecal output in several species9, although it is not clear how 5-HT signalling is affected by age. There are two main sources of 5-HT in the colon, namely the enterochromaffin (EC) cells located in the mucosa and a subpopulation of the myenteric neurons. A growing body of evidence suggests that mucosal 5-HT can act to modulate colonic motor patterns and faecal output in rodents, for review see10. Specifically, mucosal 5-HT can be released by both chemical and mechanical stimuli (properties of the luminal contents of the bowel), and propulsion can be attenuated by 5-HT antagonists and enhanced by 5-HT3/5-HT4 agonists applied to the mucosa or perfused intra-luminally. More recent work has exploited the observation that mucosal 5-HT is synthesized using tryptophan hydroxylase 1 (TPH1), an isoenzyme of tryptophan hydroxylase11 while myenteric 5-HT uses tryptophan hydroxylase 2 (TPH2)12. Ex vivo colonic motility assays from TPH1KO (TPH1 knock out) mice showed that pellet motility was slower than in wildtype mice but was overcome by increasing pellet size13.
In addition to impaired colonic motility, TPH1KO mice had elongated colons, reduced pellet output, increased pellet size and weight and reduced pellet water content, changes that were consistent with those we have reported previously in old mice6 and those observed in humans with CC14. Together these data strongly suggest that alterations in mucosal 5-HT can modulate colonic motility.
The strength and duration of the extracellular 5-HT signal can be exquisitely controlled by alterations in the level and activity of the serotonin transporter (SERT) which acts to clear 5-HT from the extracellular space into surrounding enterocytes where it is metabolized15. Altered 5-HT signalling underlies a range of GI disorders in which colonic motility is altered16,17. In many cases, these changes have been linked to changes in the expression of SERT16,17. Many of these disorders also share an inflammatory phenotype and a range of pro-inflammatory mediators e.g. tumor necrosis factor alpha (TNF-α), have been shown to down-regulate SERT expression in the colonic mucosa18. The ageing process is also associated with a chronic low level background inflammation in the colon of both humans19,20 and animals21. In the gastrointestinal (GI) tract, the causes of this low grade inflammation are unclear although changes in the gut microbiota22 and oxidative stress23,24 have been proposed as contributory factors. Nevertheless, the link between inflammation and changes to 5-HT signalling raises the potential for anti-inflammatory drugs to also have beneficial effects on 5-HT signalling and colonic motility.
Our study focused on an examination of the distal colon of the mice as we had previously shown that this region of the lower bowel contributed significantly to the reduced colonic motility in aged animals6. The current study tested the hypothesis that treatment of aged mice with the TNF-α antagonist, etanercept could attenuate the age-related decrease in pellet output and water content in mice and examined whether these changes could be explained by alterations in colonic 5-HT signalling processes.
Results
Age-related changes in 5-HT content and availability in the distal colon
A combination of immunohistochemistry and high performance liquid chromatography (HPLC) were used to examine the effects of age on the intracellular 5-HT content of the distal colon. Numbers of EC cells increased steadily between 3 and 18 months and then decreased significantly between 18 and 24 months (Fig. 1A,B). There was no significant difference between the numbers of EC cells in the 3 and 24 month groups. Age-related changes in mucosal 5-HT content showed a similar trend to the change in EC cell number (Fig. 1C) consistent with the EC cells being the main source of 5-HT in the mucosa. Myenteric 5-HT levels were significantly decreased at 24-months compared to 3 months (Fig. 1D).
5-HT has to be released in order to affect the function of its targets in the colon. We were therefore interested in examining the extracellular level of 5-HT (5-HT availability) and how this changed with age. We chose to utilize constant potential amperometry to measure extracellular 5-HT as this technique provides a method to observe real time changes in the levels of oxidizable substances such as 5-HT. Our initial study focused on mucosal 5-HT. Differential pulse voltammetry performed on 3 month distal colon demonstrated a clear oxidation peak at +600 mV that was consistent with the oxidation of 5-HT (see supplementary Fig. S1). Previous studies have demonstrated that 5-HT is the only substance released from the mucosa that is oxidized at +650 mV25,26,27, indicating that the oxidation signals presented in this paper are solely due to the oxidation of 5-HT.
Using constant potential amperometry we demonstrated that increasing age increased mucosal 5-HT availability (Fig. 1E,F). Post-hoc analysis demonstrated a significant increase in 5-HT availability in both the 18-month and 24-month tissue compared to 3-month controls. 5-HT availability at the electrochemical sensor is dictated by a combination of the amount of 5-HT released from the tissue, its rate of re-uptake via the serotonin transporter (SERT) and also by diffusion. There were no clear changes in release with increasing age (data not shown) so subsequent figures have focused on the involvement of age-related changes in re-uptake via SERT. In order to examine the involvement of SERT in the age-related increase in 5-HT availability, we utilized fluoxetine, a potent inhibitor of SERT. If SERT was functional, then blockade with fluoxetine would inhibit re-uptake increasing the 5-HT signal at the sensor. Application of fluoxetine caused a significant increase in 5-HT availability in 3, 12 and 18-month colon but failed to alter 5-HT availability in 24-month colon (Fig. 1F). These data are consistent with SERT being functional in the three younger groups, but not in the 24-month colon.
We were unable to measure 5-HT availability in the myenteric plexus. This does not appear to be due to dramatic differences in the levels of 5-HT (compare Fig. 1C,D) or SERT (compare Fig. 2B,E) in this tissue, which are comparable to those in the mucosa, but most likely represents the location of the release sites in the myenteric preparation which lie deep within the muscle inhibiting 5-HT diffusion to the sensor.
Effects of age on SERT expression and 5-hydroxyindoleacetic acid (5-HIAA) levels in mouse distal colon
To further quantify how the expression of SERT was altered with age we analysed colonic samples from the four age groups of mice with Western blot. Using a SERT-specific antibody a single major protein band with a molecular weight of approximately 67 kDa was identified in all age groups in both the mucosa (Fig. 2A) and the myenteric preparations (Fig. 2D), equivalent to the molecular weight of SERT identified previously in the mouse28. In the mucosa, the intensity of the normalised band decreased with increasing age (Fig. 2A,B), confirming a reduction in the expression of SERT with increasing age. 5-HIAA is the major metabolite of 5-HT and is formed following the re-uptake of 5-HT into enterocytes via SERT. The ratio of mucosal 5-HIAA:5-HT, was significantly decreased in 24-month mucosa compared to both 3 and 12-month groups, consistent with the reduction in SERT expression (Fig. 2C).
In the myenteric samples, SERT expression was unaffected by age (Fig. 2D,E). However, the 5-HIAA:5-HT ratio was increased in the 24 month group (Fig. 2F). This was not due to a change in the level of 5-HIAA (consistent with the lack of change in SERT, data not shown) but was due to the age-related decrease in myenteric 5-HT (Fig. 1D).
Effects of age on TNFα levels in the distal colon
Increasing age is associated with low-level chronic inflammation in many tissues including the colon, and pro-inflammatory mediators such as TNF-α have been shown to down-regulate SERT expression in the colonic mucosa18. We therefore examined if TNF-α levels in the distal colon changed with age in the mouse using an ELISA based assay and focused our attentions on the extremes of age (3 and 24 months). TNF-α levels were significantly higher in the distal colon mucosa of 24-month animals compared to 3-month controls (Fig. 3A). Distal colonic myenteric levels of TNF-α were unaffected by age but overall were approximately 8 fold higher than in the mucosa (Fig. 3B).
Effects of age and the TNFα inhibitor etanercept on pellet output and water content
To understand if the observed increase in mucosal TNF-α was responsible for the age-related changes in faecal output in mice, we treated 3 and 24-month old mice with the TNF-α antagonist, etanercept. In untreated mice, the number of faecal pellets (Fig. 4A) and their water content (Fig. 4B) were significantly reduced in mice aged 24-months compared to 3-month controls. Strikingly, 24-month old animals treated with etanercept demonstrated a doubling of pellet number compared to age matched controls and a significant increase in the water content of the faecal pellets (Fig. 4A,B). Furthermore, pellet number and water content in the etanercept treated 24-month old animals were not significantly different to 3-month controls demonstrating the ability of entanercept to reverse the age-related functional changes.
Effects of etanercept on 5-HT signalling in distal colon
As age affected components of both mucosal and myenteric 5-HT signalling and because both components have previously been shown to be important in regulating colonic motility, we were interested to examine which component of 5-HT signalling was affected by etanercept. Etanercept increased the mucosal 5-HIAA:5-HT ratio (Fig. 5A) and SERT expression in the 24-month old distal colon (Fig. 5B,C), consistent with it reversing the effects of increased age. However, etanercept had no direct effect on mucosal 5-HT levels (Fig. 5D).
We next examined whether etanercept treatment could alter 5-HT signalling in the myenteric preparation, as we had previously demonstrated that increasing age reduced myenteric 5-HT levels and that myenteric TNF-α levels were much higher than those in the mucosa. Interestingly, levels of 5-HT in 24 month myenteric preparations were unaffected by etanercept (see supplementary Fig. S2A). However, etanercept did reduce the 5-HIAA:5-HT ratio in the 24 month myenteric preparation (see supplementary Fig. S2B), consistent with it reversing the effects of age. However, these changes occurred in the absence of any changes in SERT expression and 5-HT levels, suggesting that etanercept is most likely reducing 5-HIAA levels either though an increase in the function of SERT or through an increase in the activity of monoamine oxidase A.
In order to determine whether the effects of etanercept were specific to its ability to bind TNF-α we examined whether etanercept affected 5-HT signalling in the distal colon of 3-month control mice that had negligible levels of TNF-α. Etanercept had no effect on mucosal (Fig. 5E,F) or myenteric (see supplementary Fig. S2C,D) 5-HT levels or the 5-HIAA:5-HT ratio in 3-month treated animals.
Discussion
The main findings of this study are 1) TNF-α expression is elevated in the distal colon of 24 month old mice and this change is associated with a decrease in faecal pellet output and pellet water content; 2) Treatment of 24-month old mice with etanercept, a TNF-α antagonist, reversed the age-related decreases in pellet output and water content; 3) Etanercept reversed the age-related increase in mucosal 5-HT availability and decrease in SERT expression suggesting that the age-related increase in TNF-α observed in this tissue is responsible for the changes in SERT expression.
Work in this and a previous study6 has demonstrated that aged mice develop a phenotype that has some of the characteristics of human constipation (reduced faecal output and water content). We have extended our previous study to understand further the underlying causes of these changes.
As 5-HT is a major regulator of colonic motility and therefore faecal output we examined how mucosal and myenteric 5-HT signalling changed with age. Age increased distal colonic mucosal 5-HT availability through a reduction in SERT expression. Consistent with this, was the observation that the mucosal 5-HIAA:5-HT ratio was also reduced with age, as the metabolism of 5-HT to 5-HIAA requires the re-uptake of 5-HT into the cytoplasm via SERT (Fig. 6). There is a paucity of data examining how mucosal 5-HT signalling changes in older humans with chronic constipation. Lincoln et al.29 showed a significant increase in mucosal 5-HT in patients with idiopathic constipation29. In a more recent study, Costedio et al.30 demonstrated an increase in mucosal 5-HT availability that was shown to be due to an increase in EC cell number, 5-HT content and 5-HT release in the absence of changes in SERT expression30. Both studies in humans are consistent with the increased 5-HT availability reported in this current study. However, the increased EC cell number and 5-HT content observed in both the human studies is more representative of the changes we observed in the 18-month colon samples rather than the oldest 24-month group. One possible explanation for this discrepancy is that the observed changes may be reflective of the relatively low mean age of the participants in the study by Costedio et al. (24–74 years, mean age 42 years). Indeed, Mawe and Hoffmann have recently suggested that the increased EC cell numbers and mucosal 5-HT content associated with coeliac disease, compared to the reduced numbers of EC cells and 5-HT content observed in inflammatory bowel disease (IBD) was a function of the duration of the inflammatory condition with IBD being longer than coeliac disease10. These suggestions are interesting and might provide an explanation for our observed increase in EC cells number and mucosal 5-HT content in mice between 3–18 months and the subsequent decrease in both parameters between 18 and 24 months. Age-related increases in both distal colon EC cell number and expression of the isoform of tryptophan hydroxylase present in the EC cells (TPH1) have also been reported by Keating et al.31. However, their changes were observed at 24 months compared to 18 months in our current study31. This time discrepancy may reflect differing levels of inflammation in the colon due to different housing conditions or differences in the backgrounds of the two strains of C57BL/6 mice. Inflammatory mediators have previously been shown to post-translationally regulate SERT expression32 and this could explain why Keating et al. saw no difference in SERT mRNA expression with age but we observed clear decreases in SERT protein expression at both 18 and 24 months.
The most interesting finding from this study was that treatment of mice with etanercept for 2 weeks was capable of attenuating the age-related changes in pellet output and water content, mucosal SERT expression and 5-HIAA:5-HT ratio. Previous studies have shown that pro-inflammatory mediators such as TNF-α can reduce SERT expression in the colonic mucosa in rodent models of inflammatory bowel conditions18,33,34,35,36,37 observations that are consistent with our findings. Despite the clear reversal of the aged phenotype in the distal colon mucosa, etanercept failed to reverse the age-related decrease in myenteric 5-HT.
If age-related changes in pellet output and water content can be reversed by etanercept and etenercept binds free TNF-α, then what are the main drivers for the increase in mucosal TNF-α? Previous studies using acute applications of dextran sulfate sodium or Trinitrobenzenesulfonic acid to the colon of young mice have demonstrated an increase in mucosal TNF-α and this increase is inhibited in TPH1KO mice or by drugs that selectively inhibit mucosal 5-HT synthesis38,39. These observations suggest that the age-related increase in 5-HT overflow could be driving the increase in TNF-α. However, as TNF-α has been shown to decrease mucosal SERT expression18, and would therefore increase mucosal 5-HT overflow, it is possible that the increase in mucosal TNF-α could occur independently of 5-HT. Interrupting this pathway using etanercept to block TNF-α signalling increased mucosal SERT expression and the 5-HIAA:5-HT ratio, without altering mucosal 5-HT, suggesting that this pathway was at least partially responsible for the age-related changes in mucosal 5-HT overflow. Together these findings suggest that while mucosal 5-HT may contribute to the increase in mucosal TNF-α with age other age-related changes in the colon may also be involved. These alternative causes of the increase in mucosal TNF-α are currently unknown but are under investigation. Potential contributing factors include an increase in replicative senescence and the development of a pro-inflammatory senescence associated secretory phenotype (SASP)40. Alternatively, inflammation due to activation of the immune system21,41, reduced colonic polyamine levels42, as a consequence of altered gut microbiota22 may also contribute43,44. Most recently, vitamin D deficiency, a common hallmark associated with ageing, has been demonstrated to induce colonic inflammation through the secretion of senescence-associated inflammatory cytokines45.
If 5-HT is a pro-kinetic agent, then why does an increase in mucosal 5-HT availability impair faecal output? Previous studies have demonstrated that pharmacological blockade of mucosal SERT and a consequential increase in 5-HT availability impairs colonic motility and faecal output in both humans and rodent models46,47. The authors proposed that this was due to the high levels of mucosal 5-HT which lead to desensitization of 5-HT3 receptors on intrinsic primary afferent neurons impairing the peristaltic reflex. Treatment with etanercept was able to reverse the effects of age on both mucosal 5-HT availability and faecal output, strongly suggesting that the age-related change in mucosal 5-HT availability was a major contributor to impaired faecal output in aged mice. Indeed TPH1KO mice, in which mucosal 5-HT levels are dramatically reduced, also show impaired colonic motility in ex vivo assays confirming a role for mucosal 5-HT in regulating colonic motility13. Interestingly, this model also demonstrated other features in common with our aged phenotype namely an elongated colon and faecal impaction6 further supporting a role for disrupted mucosal 5-HT signalling in the aged phenotype. However, earlier studies comparing both TPH1KO and TPH2KO mouse showed that colonic motility was only impaired in the TPH2KO mouse in which myenteric 5-HT was significantly reduced48. The discrepancy between these two studies most likely represents the different methods used to assess colonic motility and it is likely that a combination of both mucosal and myenteric 5-HT release are required for appropriate colonic motility in young animals49. While our aged phenotype could be explained by an impairment in mucosal 5-HT signalling, we did observe a reduction in myenteric 5-HT suggesting that neuronal signalling was also altered with age. However, myenteric TNF-α expression was not altered with age and the effects of age were not reversed by etanercept suggesting that this is not the main mechanism by which age or etanercept have their effects on motility. Although there were no age-related changes in myenteric TNF-α levels, it was interesting to note that treatment with the TNF-α antagonist etanercept decreased myenteric 5-HIAA:5-HT ratio potentially providing a compensatory increase in myenteric 5-HT. Based on these findings we cannot exclude the possibility that a component of the ability of etanercept to rescue the aged-phenotype is through its actions on neuronal 5-HT signalling.
Previous studies have also shown that TNF-α can have a range of direct effects on colonic tissue providing the possibility that etanercept can directly influence faecal output and water content. However, TNF-α suppresses fluid absorption and favours secretion of fluid into the lumen of the bowel50,51. Therefore etanercept treatment would be predicted to reduce pellet water content and this would not explain the increase we observed. However, fluid absorption from the colon is also affected by colonic transit time, with slower transit times increasing fluid absorption. TNF-α has been shown to reduce the strength of smooth muscle contractions in mice52,53, through a mechanism that involves a decrease in C-kinase-activated protein phosphatase-1 (PP1) inhibitor, 17 kDa (CPI-17) levels. This would be expected to slow colonic transit and increase fluid absorption. However, the lack of change in TNF-α in the myenteric/muscle preparation with age suggests that the ability of TNF-α to inhibit colonic muscle contractions is likely to have only a minimal effect on colonic motility in our aged animals.
The data presented here suggest that etanercept and related TNF-α antagonists could be useful treatments for age-related CC. However, work on higher organisms is inconclusive as to whether colonic TNF-α levels increase with age. A study in baboons >18 years old, showed that TNF-α levels are not increased with age54. However, baboons can live to 45 years old in captivity, suggesting that a number of these animals had barely reached middle age. Studies on humans are also inconclusive; with some documenting age-related increases in TNF-α55 while others do not56. Interestingly, mild diarhoea is a common side effect of patients taking etanercept for their rheumatoid arthritis although how much of this is due to a concomitant reduction in the use of opioid based pain killers is unclear.
The potential to utilize TNFα antagonists to treat age-related constipation in humans is not without its problems. First, the cost of the drugs is likely to make treatment prohibitively expensive, making it important to elucidate the optimum dose and dosing frequency in animal models before trialing the treatment in humans. There is also the potential issue that anti-inflammatory drugs, like etanercept, that suppress the immune system may increase the incidence of infections in older people whose immune system is suppressed. However, in a study of the long term safety of etanercept in the elderly population the incidence of adverse events, serious adverse events, infectious events, medically important infections, and malignancies was not significantly raised in elderly subjects in comparison with subjects less than 65 years old57. Finally, etanercept and all other clinically available TNF-α antagonists are administered by injection, which may well reduce compliance. Should these drugs prove efficacious in humans for the treatment of age-related constipation, then industry should be encouraged to develop orally active TNF-α antagonists that do not cross into the systemic circulation.
Finally, given the results from this and other studies that have examined the role of colonic 5-HT signalling on motility, it is tempting to infer that the effects of etanercept are through its ability to restore age-related changes in both mucosal and myenteric 5-HT signalling. Given the complexity of colonic 5-HT signalling processes and the changes we have observed with age, directly demonstrating the link between etanercept treatment, 5-HT signalling and improved bowel movements is at best difficult. Our main finding is that mucosal SERT expression is down-regulated with age. Attempts to mimic this change by administering the SERT antagonist, fluoxetine, to young animals may well inhibit faecal output and water content but whether these effects are due to changes in mucosal 5-HT signalling or changes in myenteric or CNS 5-HT signalling processes will be unclear. Additionally, analyzing the effects of increasing TNF-α levels in young animals to try to mimic the effects of age on this pro-inflammatory mediator would also be unclear because the changes we have observed in TNF-α expression are very region specific and whole animal dosing will not generate similar region specific changes. Therefore in the absence of a conclusive set of experiments the link between etanercept treatments, alterations in mucosal/myenteric 5-HT signalling and age-related changes in pellet output remain inconclusive.
These data demonstrate the reversal of an age-related functional phenotype in the lower bowel with an anti-inflammatory drug. This work provides an exciting insight into one of the potential causes of age-related colonic dysfunction in mice. The observation that the TNF-α antagonist etanercept can reverse age-related changes in mucosal SERT expression, 5-HIAA levels and the decrease in faecal pellet output and water content highlights the potential for “anti-TNFα” drugs to alleviate age-related colonic dysfunction. In the short term, efficacy in humans may be established using existing drugs, but longer-term this provides an opportunity to develop GI tract specific analogues of etanercept to treat colonic dysfunction.
Methods
Ethical approval
All procedures were carried out according to U.K. Home Office regulations and the Animal [Scientific Procedures] Act 1986) and were approved by the University of Brighton Ethics Committee. The manuscript was prepared according to the ARRIVE guidelines.
Animals
8 week old male C57BL/6 J mice (Harlan UK) were aged in individual ventilated cages under barrier-reared conditions. Animals were maintained at 19.0 ± 1 °C, 55% humidity and fed on a maintenance diet (RM1 (E) 801002 (Special Diet Services) chow). Initial studies were performed on 3, 12, 18 and 24 month old animals to characterize the time course of changes in 5-HT signalling. Later experiments focused on 3 and 24 month old mice to understand whether inflammation was a cause of the observed functional and biochemical changes.
Administration of Etanercept
Etanercept (1 mg Kg−1) was administered intraperitoneally (i.p.) twice a week for 2 weeks. Control animals were injected i.p. with sterile water.
Monitoring of faecal pellet output
Faecal pellet output was performed in an arena divided into three equal sized sections (14 × 25 cm) by perforated Perspex dividers. Individual mice were placed in each section so they could visualise and smell their cage mates. Pellets were collected for 1 hour and their number and total wet weight determined. Pellets were dried overnight at 50 °C and their dry weight and water content determined.
Intestinal preparation
Animals were asphyxiated with CO2 and exsanguinated following cervical dislocation. The whole colon was harvested 1 cm proximal to the anus and placed in oxygenated (95% O2 and 5% CO2) Krebs buffer solution, pH 7.4 (117 mM NaCl, 4.7 mM KCl, 2.5 mM CaCl2, 1.2 mM MgCl2, 1.2 mM NaH2PO4, 25 mM NaHCO3 and 11 mM glucose). Based on our previous findings that ex vivo colonic motility was impaired with age and that this impairment was due solely to a reduction in motility in the distal colon6 we have focused our investigations in this current study on 5-HT signalling in the distal colon. The distal colon was identified as the distal most half of the colon and used for the experiments described below.
Amperometric monitoring of 5-HT availability
Amperometric measurements were made using a boron-doped diamond (BDD) microelectrode as previously described58. Tissue samples were perfused with warm (37 °C) Krebs solution at a flow rate of 2 mL/min. Continuous amperometric recordings of 5-HT overflow were carried out using a BioStat™ multi-channel potentiostat (ESA Biosciences, Inc, USA) with the electrode potential held at +650 mV vs Ag|AgCl. Briefly, using a micromanipulator, the BDD electrode was positioned several centimetres away from the mucosa for several seconds to obtain a baseline reading. To record mucosal 5-HT availability, the electrode was advanced and positioned 0.1 mm from mucosal surface for 40 s; at this distance 5-HT oxidation currents were reproducibly recorded. This procedure was repeated 5 times for each tissue. In a number of experiments the effects of the SERT antagonist, fluoxetine on 5-HT overflow was determined in all four age groups. Briefly, following a set on control readings in Krebs buffer solution the tissue was perfused for 20 minutes with 1 μM fluoxetine and 5-HT availability determined as described above.
HPLC measurements of distal colonic 5-HT and 5-HIAA levels
The mucosa was removed from 1 cm2 segments of the distal colon from 3, 12, 18 and 24 month old animals using a sharp scalpel and this and the remaining tissue, consisting of the longitudinal and circular muscle layers and the myenteric plexus (subsequently called the myenteric sample) were placed separately in 500 μl of ice cold 0.1 M perchloric acid. Samples were homogenised and centrifuged at 14,600 g for 10 minutes prior to chromatographic analysis. HPLC analysis of 5-HIAA and 5-HT was then carried out according to the method of Parmer et al.59.
SERT Western Blot Analysis
The mucosa/myenteric samples from 2 cm segments of distal colon were isolated and snap frozen in liquid N2 for storage. Tissue was homogenized on ice in lysis buffer (10 mM HEPES, 150 mM NaCl, 1 mM EDTA, 0.2% Nonidet P40, protease inhibitor cocktail P8340, Sigma-Aldrich Inc.). Lysates were centrifuged and supernatants were removed and their protein content assessed using Quick Start Bradford Dye reagent (Bio-Rad)60. 15 μg of protein from each sample was separated using SDS-PAGE. Antibodies were diluted in Tris-buffered saline + 0.1% Tween (TBST). Membranes were incubated overnight at 4 °C with a rabbit anti-SERT antibody (#24330, Immunostar Inc; 1:1500 in TBST) followed by a goat anti-rabbit HRP-conjugated secondary antibody (1:2000 in TBST, SC-2005, Santa Cruz Biotechnology) for 1 hr at room temperature. Protein bands were detected using ECL plus western blotting detection system (GE Healthcare). The relative intensity of each SERT band was normalised to the total protein load determined by staining the PVDF membrane with Coomassie Brilliant Blue (Bio-Rad). This normalisation process was chosen as a number of the commonly used housekeeping genes have previously been shown to change expression with age in other tissues61,62 and there is currently a lack of proteomic data detailing the effects that age has on protein expression in the mouse colon.
Immunofluorescence labeling of EC cells
Immunofluorescence labelling was performed on 10 μm transverse sections of distal colon. Tissues were fixed in 4% paraformaldehyde in PBS and then embedded in paraffin. Sections were deparaffinised in Histoclear and rehydrated in graded ethanol solutions. The slides were then incubated for 30 min in 2 N HCl for antigen retrieval. The sections were then incubated with 10% goat serum (S-1000; Vector lab, Peterborough, UK) for 2 hours at room temperature. Rabbit anti-serotonin primary antibody (1:8000; 20080; ImmunoStar, UK) was applied overnight at 4 °C, and then slides were washed three times with PBS (10 min each wash). Sections were incubated for 2 hours with Alexa 488 goat anti-rabbit secondary antibody (1:200, A-11034; Invitrogen, UK). After washing with PBS, sections were mounted with Fluoroshield DAPI (F6057; Sigma, UK). Sections were viewed and images were acquired using an Olympus BX-UCB microscope.
TNFα analysis in colonic samples
TNF-α levels from mucosa/myenteric samples were determined using a R&D systems Mouse TNF-α Quantikine ELISA kit according to the manufacturer’s instructions. Levels of TNF-α were normalized to the protein content of the tissue.
Data Analysis
For amperometic responses, current amplitudes were recorded and converted to 5-HT concentrations using calibration responses. Population means were compared using a one-way ANOVA (GraphPad Prism) and significant differences determined using post-hoc Tukey tests. In amperometric experiments where the effects of both age and fluoxetine treatment were compared, the data was analysed using a 2-way ANOVA followed by a post-hoc Tukey test. HPLC peak areas for the analytes of interest were recorded using CHI potentiostat 1050 software and converted to concentrations using calibration responses. For both these data and those comparing TNF-α expression data from 2 age groups were compared with an unpaired t-test while those comparing more than two groups were analysed using a one way ANOVA followed by a post-hoc Tukey test. Quantitative evaluation of the number of serotonin-positive cells per ten microscopic fields (x40) was assessed in four age groups. Age-related differences were determined using a one-way ANOVA (GraphPad Prism). For Western blots the ratios of the intensity of each SERT- labelled band to the Coomassie stained PVDF membrane were compared using a Kruskall Wallis ANOVA followed by a post hoc Tukey test. In experiments where the effects of age and etanercept were examined on pellet output and water content data were compared using a two-way ANOVA and Tukey post-hoc test. All analysis was carried out using GraphPad Prism Vs 6.
Additional Information
How to cite this article: Patel, B. A. et al. The TNF-α antagonist etanercept reverses age-related decreases in colonic SERT expression and faecal output in mice. Sci. Rep. 7, 42754; doi: 10.1038/srep42754 (2017).
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References
Rao, S. S. C. & Go, J. T. Update on the management of constipation in the elderly: new treatment options. Clinical Interventions in Aging 5, 163–171 (2010).
Camilleri, M., Cowen, T. & Koch, T. R. Enteric neurodegeneration in ageing. Neurogastroenterology & Motility 20, 418–429, doi: 10.1111/j.1365-2982.2008.01134.x (2008).
Zarate, N. & Spencer, N. J. Chronic constipation: Lessons from animal studies. Best Practice & Research Clinical Gastroenterology 25, 59–71 (2011).
McDougal, J. N., Miller, M. S., Burks, T. F. & Kreulen, D. L. Age-related changes in colonic function in rats. American Journal of Physiology - Gastrointestinal and Liver Physiology 247, G542–G546 (1984).
Smits, G. J. M. & Lefebvre, R. A. Influence of aging on gastric emptying of liquids, small intestine transit, and fecal output in rats. Experimental Gerontology 31, 589–596 (1996).
Patel, B. A. et al. Impaired colonic motility and reduction in tachykinin signalling in the aged mouse. Experimental Gerontology 53, 24–30, 10.1016/j.exger. 2014.02.007 (2014).
Madsen, J. L. & Graff, J. Effects of ageing on gastrointestinal motor function. Age and Ageing 33, 154–159, doi: 10.1093/ageing/afh040 (2004).
O’Mahony, D., O’Leary, P. & Quigley, E. M. M. Aging and Intestinal Motility. Drugs & Aging 19, 515–527, doi: 10.2165/00002512-200219070-00005 (2002).
Kendig, D. M. & Grider, J. R. Serotonin and colonic motility. Neurogastroenterology & Motility 27, 899–905, doi: 10.1111/nmo.12617 (2015).
Mawe, G. M. & Hoffman, J. M. Serotonin signalling in the gut: functions, dysfunctions and therapeutic targets. Nat Rev Gastroenterol Hepatol 10, 473–486, doi: 10.1038/nrgastro.2013.105 (2013).
Côté, F. et al. Disruption of the nonneuronal tph1 gene demonstrates the importance of peripheral serotonin in cardiac function. Proceedings of the National Academy of Sciences of the United States of America 100, 13525–13530, doi: 10.1073/pnas.2233056100 (2003).
Walther, D. J. et al. Synthesis of Serotonin by a Second Tryptophan Hydroxylase Isoform. Science 299, 76–76, doi: 10.1126/science.1078197 (2003).
Heredia, D. J. et al. Important role of mucosal serotonin in colonic propulsion and peristaltic reflexes: in vitro analyses in mice lacking tryptophan hydroxylase 1. The Journal of Physiology 591, 5939–5957, doi: 10.1113/jphysiol.2013.256230 (2013).
Longstreth, G. F. et al. Functional Bowel Disorders. Gastroenterology 130, 1480–1491, 10.1053/j.gastro.2005.11.061 (2006).
Wade, P. R. et al. Localization and Function of a 5-HT Transporter in Crypt Epithelia of the Gastrointestinal Tract. The Journal of Neuroscience 16, 2352–2364 (1996).
Coates, M. D. et al. Molecular defects in mucosal serotonin content and decreased serotonin reuptake transporter in ulcerative colitis and irritable bowel syndrome. Gastroenterology 126, 1657–1664, 10.1053/j.gastro.2004.03.013 (2004).
Mawe, G. M., Coates, M. D. & Moses, P. L. Review article: intestinal serotonin signalling in irritable bowel syndrome. Alimentary Pharmacology & Therapeutics 23, 1067–1076, doi: 10.1111/j.1365-2036.2006.02858.x (2006).
Foley, K. F., Pantano, C., Ciolino, A. & Mawe, G. M. IFN-γ and TNF-α decrease serotonin transporter function and expression in Caco2 cells. Vol. 292 (2007).
Britton, E. & McLaughlin, J. T. Ageing and the gut. Proceedings of the Nutrition Society 72, 173–177, doi: 10.1017/S0029665112002807 (2013).
Sipos, F., Leiszter, K. & Tulassay, Z. Effect of ageing on colonic mucosal regeneration. World Journal of Gastroenterology: WJG 17, 2981–2986, doi: 10.3748/wjg.v17.i25.2981 (2011).
Steegenga, W. T. et al. Structural, functional and molecular analysis of the effects of aging in the small intestine and colon of C57BL/6J mice. BMC Medical Genomics 5, 38–38, doi: 10.1186/1755-8794-5-38 (2012).
Duncan, S. H. & Flint, H. J. Probiotics and prebiotics and health in ageing populations. Maturitas 75, 44–50, 10.1016/j.maturitas.2013.02.004 (2013).
Pascua, P. et al. Melatonin, and to a lesser extent growth hormone, restores colonic smooth muscle physiology in old rats. Journal of Pineal Research 51, 405–415, doi: 10.1111/j.1600-079X.2011.00904.x (2011).
Pozo, M. J. et al. Melatonin, a Potential Therapeutic Agent for Smooth Muscle-Related Pathological Conditions and Aging Current Medicinal Chemistry 17, 4150–4165 (2010).
Patel, B. A. Continuous amperometric detection of co-released serotonin and melatonin from the mucosa in the ileum. The Analyst 133, 516–524 (2008).
Bertrand, P. P. Real-time measurement of serotonin release and motility in guinea pig ileum. J Physiol 577, 689–704, doi: 10.1113/jphysiol.2006.117804 (2006).
Parmar, L., Morgan, L. D. & Patel, B. A. Intracellular and extracellular sampling to monitor the neurotransmission process using a chromatographic method. Analytical Methods 3, 2770–2776 (2011).
Esmaili, A. et al. Enteropathogenic Escherichia coli Infection Inhibits Intestinal Serotonin Transporter Function and Expression. Gastroenterology 137, 2074–2083 (2009).
Lincoln, J., Kamm, C. R., Burnstock, M. A. & Lennard-Jones, G. J. E. Serotonin and 5-hydroxyindoleacetic acid are increased in the sigmoid colon in severe idiopathic constipation. Gastroenterology 98, 1219–1225 (1990).
Costedio, M. M. et al. Mucosal serotonin signaling is altered in chronic constipation, but not in opiate-induced constipation. The American journal of gastroenterology 105, 1173–1180, doi: 10.1038/ajg.2009.683 (2010).
Keating, C., Nocchi, L., Yu, Y., Donovan, J. & Grundy, D. Ageing and gastrointestinal sensory function: altered colonic mechanosensory and chemosensory function in the aged mouse. The Journal of Physiology. n/a–n/a, doi: 10.1113/jp271403 (2016).
Mendoza, C., Matheus, N., Iceta, R., Mesonero, J. E. & Alcalde, A. I. Lipopolysaccharide induces alteration of serotonin transporter in human intestinal epithelial cells. Innate Immunity 15, 243–250, doi: 10.1177/1753425909104781 (2009).
O’Hara, J. R., Ho, W., Linden, D. R., Mawe, G. M. & Sharkey, K. A. Enteroendocrine cells and 5-HT availability are altered in mucosa of guinea pigs with TNBS ileitis. American Journal of Physiology - Gastrointestinal and Liver Physiology 287, G998–G1007, doi: 10.1152/ajpgi.00090.2004 (2004).
Linden, D. R., Chen, J.-X., Gershon, M. D., Sharkey, K. A. & Mawe, G. M. Serotonin availability is increased in mucosa of guinea pigs with TNBS-induced colitis 10.1152/ajpgi.00488.2002. Am J Physiol Gastrointest Liver Physiol 285, G207–216 (2003).
Coates, M. D. et al. Molecular defects in mucosal serotonin content and decreased serotonin reuptake transporter in ulcerative colitis and irritable bowel syndrome. Gastroenterology 126, 1657–1664 (2004).
Linden, D. R. et al. Serotonin transporter function and expression are reduced in mice with TNBS-induced colitis. Neurogastroenterology & Motility 17, 565–574, doi: 10.1111/j.1365-2982.2005.00673.x (2005).
O’Hara, J. R., Skinn, A. C., MacNaughton, W. K., Sherman, P. M. & Sharkey, K. A. Consequences of Citrobacter rodentium infection on enteroendocrine cells and the enteric nervous system in the mouse colon. Cellular Microbiology 8, 646–660, doi: 10.1111/j.1462-5822.2005.00657.x (2006).
Margolis, K. G. et al. Pharmacological reduction of mucosal but not neuronal serotonin opposes inflammation in mouse intestine. Gut 63, 928–937, doi: 10.1136/gutjnl-2013-304901 (2014).
Ghia, J. E. et al. Serotonin Has a Key Role in Pathogenesis of Experimental Colitis. Gastroenterology 137, 1649–1660, 10.1053/j.gastro.2009.08.041 (2009).
Yeoman, M., Scutt, G. & Faragher, R. Insights into CNS ageing from animal models of senescence. Nat. Rev. Neurosci. 13, 435–445, doi: 10.1038/nrn3230 (2012).
Salminen, A. et al. Activation of innate immunity system during aging: NF-kB signaling is the molecular culprit of inflamm-aging. Ageing Research Reviews 7, 83–105, 10.1016/j.arr.2007.09.002 (2008).
Minois, N., Carmona-Gutierrez, D. & Madeo, F. Polyamines in aging and disease. Aging (Albany NY) 3, 716–732 (2011).
Kibe, R. et al. Upregulation of colonic luminal polyamines produced by intestinal microbiota delays senescence in mice. Scientific Reports 4, 4548, doi: 10.1038/srep04548 http://www.nature.com/articles/srep04548#supplementary-information (2014).
Matsumoto, M., Kurihara, S., Kibe, R., Ashida, H. & Benno, Y. Longevity in Mice Is Promoted by Probiotic-Induced Suppression of Colonic Senescence Dependent on Upregulation of Gut Bacterial Polyamine Production. Plos One 6, e23652, doi: 10.1371/journal.pone.0023652 (2011).
Liu, Y. et al. 1,25(OH)(2)D(3) Deficiency Induces Colon Inflammation via Secretion of Senescence-Associated Inflammatory Cytokines. Plos One 11, e0146426, doi: 10.1371/journal.pone.0146426 (2016).
Coates, M. D., Johnson, A. C., Greenwood-van Meerveld, B. & Mawe, G. M. Effects of serotonin transporter inhibition on gastrointestinal motility and colonic sensitivity in the mouse. Neurogastroenterology & Motility 18, 464–471, doi: 10.1111/j.1365-2982.2006.00792.x (2006).
Chial, H. J. et al. Selective effects of serotonergic psychoactive agents on gastrointestinal functions in health. American Journal of Physiology - Gastrointestinal and Liver Physiology 284, G130–G137 (2003).
Li, Z. et al. Essential Roles of Enteric Neuronal Serotonin in Gastrointestinal Motility and the Development/Survival of Enteric Dopaminergic Neurons. The Journal of Neuroscience 31, 8998–9009, doi: 10.1523/jneurosci.6684-10.2011 (2011).
Smith, T. K., Park, K. J. & Hennig, G. W. Colonic Migrating Motor Complexes, High Amplitude Propagating Contractions, Neural Reflexes and the Importance of Neuronal and Mucosal Serotonin. Journal of Neurogastroenterology and Motility 20, 423–446, doi: 10.5056/jnm14092 (2014).
Markossian, S. & Kreydiyyeh, S. I. TNF-α down-regulates the Na+–K+ ATPase and the Na+–K+–2Cl−cotransporter in the rat colon via PGE2. Cytokine 30, 319–327, 10.1016/j.cyto.2004.11.009 (2005).
Barmeyer, C. et al. IL-1β and TNFα regulate sodium absorption in rat distal colon. Biochemical and Biophysical Research Communications 317, 500–507, 10.1016/j.bbrc.2004.03.072 (2004).
Ohama, T. et al. Intestinal inflammation downregulates smooth muscle CPI-17 through induction of TNF-α and causes motility disorders. Vol. 292 (2007).
Kinoshita, K. et al. Role of TNF-α in muscularis inflammation and motility disorder in a TNBS-induced colitis model: clues from TNF-α-deficient mice. Neurogastroenterology & Motility 18, 578–588, doi: 10.1111/j.1365-2982.2006.00784.x (2006).
Tran, L. & Greenwood-Van Meerveld, B. Age-Associated Remodeling of the Intestinal Epithelial Barrier. The Journals of Gerontology Series A: Biological Sciences and Medical Sciences 68, 1045–1056, doi: 10.1093/gerona/glt106 (2013).
Rosenstiel, P. et al. Systematic expression profiling of innate immune genes defines a complex pattern of immunosenescence in peripheral and intestinal leukocytes. Genes Immun 9, 103–114, http://www.nature.com/gene/journal/v9/n2/suppinfo/6364454s1.html (2008).
Mabbott, Neil A. A breakdown in communication? Understanding the effects of aging on the human small intestine epithelium. Clinical Science (London, England: 1979) 129, 529–531, doi: 10.1042/cs20150364 (2015).
Fleischmann, R. et al. Long term safety of etanercept in elderly subjects with rheumatic diseases. Annals of the Rheumatic Diseases 65, 379–384, doi: 10.1136/ard.2005.035287 (2006).
Patel, B. A., Bian, X., Quaiserova-Mocko, V., Galligan, J. J. & Swain, G. M. In vitro continuous amperometric monitoring of 5-hydroxytryptamine release from enterochromaffin cells of the guinea pig ileum. The Analyst 132, 41–47 (2007).
Parmar, L., Morgan, L. D. & Patel, B. A. Intracellular and extracellular sampling to monitor the neurotransmission process using a chromatographic method. Analytical Methods doi: 10.1039/C1AY05520H, doi: 10.1039/C1AY05520H
Bradford, M. M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72, 248–254 (1976).
Touchberry, C. D., Wacker, M. J., Richmond, S. R., Whitman, S. A. & Godard, M. P. Age-Related Changes in Relative Expression of Real-Time PCR Housekeeping Genes in Human Skeletal Muscle. Journal of Biomolecular Techniques: JBT 17, 157–162 (2006).
Boda, E., Pini, A., Hoxha, E., Parolisi, R. & Tempia, F. Selection of Reference Genes for Quantitative Real-time RT-PCR Studies in Mouse Brain. J Mol Neurosci 37, 238–253, doi: 10.1007/s12031-008-9128-9 (2009).
Acknowledgements
MSY, BAP, MJS and RR would like to thank BBSRC for funding (grant numbers BB/GO15147/1 and BB/GO15988/1). MSY would like to acknowledge support from University of Brighton sabbatical fund. BAP acknowledges support provided by a Royal Society Research Grant. We would like to thank Dr. Brian Jones for his helpful comments on this manuscript and the staff of the University of Brighton Bioresource Centre for their help with this study.
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B.A.P. - study concept and design, acquisition, analysis and interpretation of data; critical revision of the manuscript S.F.-acquisition, analysis of data and critical revision of the manuscript C.W. and K.M. - acquisition and analysis of data. A.P. and M.S.F. - acquisition of data. L.P. - acquisition and analysis of HPLC data. J.S. - study design for the immunohistochemistry, critical revision of the manuscript and grant funding. R.R. - critical revision of the manuscript and grant funding. M.S.Y.- study concept and design; data analysis, writing the manuscript; grant funding.
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Patel, B., Fidalgo, S., Wang, C. et al. The TNF-α antagonist etanercept reverses age-related decreases in colonic SERT expression and faecal output in mice. Sci Rep 7, 42754 (2017). https://doi.org/10.1038/srep42754
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DOI: https://doi.org/10.1038/srep42754
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