This article describes a video imaging technique and high-resolution spatiotemporal mapping to identify changes in the neural regulation of colonic motility in adult mice. Subtle effects on gastrointestinal (GI) function can be detected using this approach in isolated tissue preparations to advance our understanding of GI disease.
The enteric nervous system (ENS) plays an important role in regulating gastrointestinal (GI) motility and can function independently of the central nervous system. Changes in ENS function are a major cause of GI symptoms and disease and may contribute to GI symptoms reported in neuropsychiatric disorders including autism. It is well established that isolated colon segments generate spontaneous, rhythmic contractions known as Colonic Migrating Motor Complexes (CMMCs). A procedure to analyze the enteric neural regulation of CMMCs in ex vivo preparations of mouse colon is described. The colon is dissected from the animal and flushed to remove fecal content prior to being cannulated in an organ bath. Data is acquired via a video camera positioned above the organ bath and converted to high-resolution spatiotemporal maps via an in-house software package. Using this technique, baseline contractile patterns and pharmacological effects on ENS function in colon segments can be compared over 3-4 hr. In addition, propagation length and speed of CMMCs can be recorded as well as changes in gut diameter and contraction frequency. This technique is useful for characterizing gastrointestinal motility patterns in transgenic mouse models (and in other species including rat and guinea pig). In this way, pharmacologically induced changes in CMMCs are recorded in wild type mice and in the Neuroligin-3R451C mouse model of autism. Furthermore, this technique can be applied to other regions of the GI tract including the duodenum, jejunum and ileum and at different developmental ages in mice.
The enteric nervous system (ENS) is the intrinsic neuronal network of the gastrointestinal tract and modulates various functions such as digestion of intestinal content, absorption of nutrients and the secretion and reabsorption of fluid. Neurons of the ENS are located in the myenteric and submucosal plexuses. The myenteric plexus plays a major role in regulating gastrointestinal motility1 whereas the submucosal plexus is primarily involved in the control of secretion2,3. The myenteric plexus is situated between the longitudinal and circular muscle layers of the gastrointestinal wall. The contractile activity of the smooth muscle layers of the intestinal wall facilitates the primary functions of the gastrointestinal tract by mixing and propelling intestinal content along the length of the intestine3. Although the extrinsic nerve supply to the gastrointestinal tract from the CNS contributes to gastrointestinal function in vivo, the ENS is capable of regulating gastrointestinal function independently. This unique characteristic enables the functional investigation of enteric neuronal circuits and their contribution to gastrointestinal motility ex vivo.
Colonic migrating motor complexes (CMMCs) are spontaneous, neurogenic events that are the predominant motor pattern observed in isolated mouse colon in the absence of fecal pellets4-9. CMMCs are defined as rhythmic contractions that propagate along a horizontal distance that is at least half the total length of the colon (i.e., from the cecum to the rectum)10. The relationship between CMMCs and the contractile patterns that propel fecal pellets is yet to be clearly established, however some pharmacological differences have been reported11. Nevertheless, the ability of the ENS to function independently of the CNS and the existence of neural-mediated motor patterns in the isolated colon provides an ideal assay system to examine disturbances in motility resulting from underlying ENS dysfunction. The spontaneity of gastrointestinal motor patterns allows functional changes in response to pharmacological stimuli to be evaluated.
The use of video imaging and spatiotemporal mapping was first developed to quantitatively examine small intestinal peristalsis in guinea pigs12. Here, an ex vivo technique is described that enables the study of mouse colonic motility patterns using video imaging and analysis of these recordings to construct high-resolution (~100 µm, 33 msec) maps of colonic diameter as a function of position along the colon and of time (spatiotemporal maps). Using in-house edge detection software (Analyse2; available on request), data from full length colonic segments contracting in real time are processed to generate spatiotemporal maps for each experiment. In this step, video (AVI) files are summarized and converted to spatiotemporal maps using Analyse2. Spatiotemporal maps (Figure 2) depict contractility over time and enable the measurement of multiple parameters including propagation speed, magnitude, length and duration. Gut diameter is also recorded throughout the duration of the experiment as a measure of the overall contractility of the tissue segment. This method can be applied to identify differences in the point of initiation of contractile complexes which could indicate altered enteric neural connectivity.
A similar video imaging protocol designed to assess pellet propulsion in guinea pigs has been reported13 however here we outline the application of the video imaging approach for quantification of spontaneous colonic motility (i.e., in the absence of pellets). We also provide detailed information to assist in the dissection and preparation of gastrointestinal tissue for the video imaging approach. This protocol provides researchers with an accessible and easily replicated tool for analyzing enteric neural control of gastrointestinal function in animal models of disease including genetic mouse models.
The video imaging technique enables the analysis of colonic motility in response to various pharmacological agents. Drugs can be administered via the gut lumen or the organ bath external to the colonic preparation. Different regions of the mouse gastrointestinal tract exhibit specific motility patterns such as small intestinal segmentation and CMMCs in the colon.
This technique has been used to identify strain differences in small intestinal function; differential sensitivity to 5-HT3 and 5-HT4 antagonists were observed in the jejunum of Balb/c and C57/Bl6 mice due to the polymorphic nature of the tph2 gene expressed in the two strains6. The effect of 5-HT inhibition on motility remains controversial, as conflicting data has been reported on the importance of endogenous 5-HT on colonic peristalsis and CMMCs14,15. Alterations in motility pre- and postnatally during development7, and the effects of gene mutations on gastrointestinal motility in animal models of disease10 can also be examined by utilizing video imaging. Here we illustrate use of the method for a study of colonic motility in the NL3R451C mouse model of autism, which expresses a missense mutation in the Nlgn3 gene encoding the synaptic adhesion protein Neuroligin-316. This mutation was first identified in patients diagnosed with Autism spectrum disorder (ASD)17, which is strongly associated with GI dysfunction18-22. We investigated whether the NL3 R451C synaptic mutation affects neural outputs in the ENS using the video imaging technique. We present data characterizing CMMCs at baseline and in response to the serotonergic 5HT3/4 receptor antagonist tropisetron in the NL3R451C mouse model of autism.
Animal handling and cervical dislocation of animals prior to all experiments were performed strictly according to protocols approved by the Animal Experimentation Committee for the University of Melbourne (Ethics ID: 1212494.7)
1. Tissue Collection and Dissection
2. Preparation of Colonic Tissue and Experimental Set Up for Video Imaging
3. Image Capture and Experimental Protocol
4. Data Processing and Generation of Spatiotemporal Maps
5. Analysis of Spatiotemporal Maps
Up to 90% of patients with ASD experience an array of gastrointestinal disorders, including diarrhea and constipation18,24,25. However, the underlying causes of these gastrointestinal issues are unknown. Many mutations identified in patients with ASD are associated with synaptic proteins contributing to alterations and disturbances in synaptic transmission or function. One such mutation, in the gene coding for the cell adhesion molecule neuroligin-3 (NL3 R451C), was identified in two brothers with ASD17. This mutation results in an arginine residue at position 451 of the Neuroligin protein being replaced with a Cysteine. NL3R451C mice expressing this mutation show increased GABA mediated transmission in the somatosensory cortex16,26 alongside increased AMPA and NMDA receptor mediated activity within the hippocampus25,27.
Neuroligin proteins are present in enteric neurons28-30. As the enteric nervous system plays a major role in regulating gastrointestinal function, we postulated that the R451C mutation would affect motility. Therefore, in order to investigate possible alterations in gastrointestinal functions due to synaptic abnormalities we sought to examine the effects of the R451C mutation on CMMC frequency in these mice.
Because serotonin (5-HT) acts on the ENS to modulate gastrointestinal function in mice6 we analyzed motility patterns in response to the 5-HT3/4 receptor antagonist tropisetron in colonic preparations from WT and NL3R451C mice.
To assess whether the synaptic mutation alters CMMCs when the enteric nervous system is pharmacologically perturbed, the 5HT3/4 receptor antagonist Tropisetron (Trop; 10 µM, which blocks both 5HT3 and 5HT4 receptors) was added to the bath containing the colon preparations (Figure 2). Colonic tissue from nineteen age matched male mice (11 WT and 8 NL3R451C) was used. In the presence of tropisetron, NL3R451C mice showed a decrease in CMMC frequency compared to WT littermates. Representative examples of spatiotemporal maps showing CMMCs and contractile activity in WT and NL3R451C colon preparations are shown in Figures 2A para 2E respectively. Although no difference was observed between WT and NL3R451C during control conditions, tropisetron significantly reduced CMMC frequency in both WT and NL3R451C mice (Figure 2C, 2F). In WT mice, the median number of CMMCs was 23 in control conditions compared to 15 in tropisetron (p = 0.023). In NL3 mice, the median number of CMMCs in control conditions was 19.5 compared with 2 in the presence of tropisetron (p = 0.022). In addition, tropisetron had a larger effect on the frequency of CMMCs in NL3R451C mice compared to WT (p = 0.047).
Figure 1. Organ bath set up and generation of spatiotemporal maps. (A) A freshly dissected gastrointestinal segment is placed in an organ bath (cross sectional view) containing physiological saline and cannulated at oral and anal ends. The oral cannula is connected to an inflow reservoir filled with physiological saline and the anal cannula connected to an outflow tube. A video camera is positioned above the organ bath in order to record contractile activity of the colon. (B) motility is converted to high resolution spatiotemporal maps labeling regions of the colon that are dilated in blue and constricted regions in red. (C) A spatiotemporal map showing colonic motility (CMMCs) from an adult WT mouse. Individual CMMCs are indicated as red vertical regions within the map. The X axis shows time increasing (0-15 min). The Y axis represents the spatial location along the colon segment (anal at base, oral at top). Please click here to view a larger version of this figure.
Figure 2. Spatiotemporal maps show increased sensitivity to Tropisetron in NL3R451C mouse colon. Spatiotemporal maps showing CMMC frequency in colon segments from WT controls (A) and in the presence of Tropisetron (Trop; B). Trop reduced CMMC frequency in WT colon (C). Spatiotemporal maps from NL3 colon under control conditions (D) and in the presence of Trop (E). Trop caused a strong reduction in CMMC frequency in NL3 colon (F). CMMC frequency in response to Trop was significantly reduced in NL3 compared with WT colon (p = 0.047, not shown). Gut width (pixel color) is indicated on the Y axis (arbitrary units, range 1-6). Scale bar in E applies to all maps. Trop; Tropisetron. Please click here to view a larger version of this figure.
Figure 3. Schematic of organ bath. (A) Top view, (B) Underside, (C) Front view, (D) Side view, of a two chambered organ bath set up. Dimensions in mm. Please click here to view a larger version of this figure.
Using this video imaging technique, CMMC frequency was measured as an indication of colonic motility in wild type and NL3R451C mice, a mouse model of autism spectrum disorder17. Our results indicate a reduction in the number of CMMCs in mutant NL3R451C mice compared to wild type mice in the presence of the 5HT3/4 receptor antagonist Tropisetron suggesting that NL3R451C mice exhibit an increased sensitivity to Tropisetron. Accordingly, we propose that the neuroligin-3 R451C mutation alters the serotonin pathway, potentially by modulating either 5HT3 or 5HT4 receptor function in enteric neurons, the mucosa or both. This highlights the method's value for identification of phenotypic differences between genotypes and for identification of specific targets for subsequent studies.
This method can be modified to enhance spatial resolution by acquiring videos via a stereo-microscope fitted with a camera mount. This approach enables recordings to be made from small preparations of the gastrointestinal tract at embryonic time points as early as E12.531. Neuromodulators can be applied via the lumen or in the organ bath external to the colonic preparation. Furthermore, this method is useful for assessing both large and small gastrointestinal motility in a range of species including mice, rats and guinea pig.
Common troubleshooting steps for this method include verifying the flow of solution via the tubing, viability of the tissue preparation, maintenance of constant luminal pressure and ensuring that colon segments are located away from the walls of the organ bath. Blockages within the tubing can alter luminal pressure and prevent contractions from occurring; therefore all tubes must be cleaned thoroughly to remove salt crystals or debris/fecal matter before cannulation. Air must be removed from tubing lines directly associated with the cannula prior to experiments (i.e., by priming the tubes with saline). In addition, tissue preparations must be handled with care in order to prevent damage resulting in immobility of the colon. To avoid tissue damage, ensure that the colon is firmly (but not tightly) attached to the cannula during the recording process and maintain a constant temperature and a continuous supply of CO2 + O2 to the bath. Also ensure that the luminal pressure is kept constant and that no contractions are manually initiated by adjusting inflow reservoirs during the recording period. Ensure that the colon tissue does not contact the wall of the organ bath during contractions as this will prevent edge detection analysis of the relevant spatiotemporal maps. This can be avoided by monitoring the contractions during the equilibration period and adjusting the position of the colon to prevent this from occurring during the experiment.
Several limitations associated with this technique should be taken in to consideration when analyzing and interpreting the data including the low throughput nature of this approach. While the method is effective in identifying changes in migrating motor patterns, it cannot determine whether dilations occurring during the progression of a CMMC are neurally mediated or simply passive responses to the contractile activity (i.e., resulting from the movement of fluid). The concentration gradients for diffusion across the colonic wall allow the effects of luminally applied drugs to be ascribed to actions within the mucosa, but in prolonged experiments mucosal degeneration may occur thereby altering the sites of action of these drugs over the recording period. Furthermore, whether drugs have distinct effects in the myenteric and submucosal plexuses cannot be determined using this method. In contrast, this approach enables a collective evaluation of effects on the enteric nervous system by measuring an overall change in motility patterns. Further considerations include the need to take into account the nature of the data (i.e., count data for CMMC frequency, requiring non-parametric analysis) and the low frequency of CMMCs, when designing experiments and appropriate data analysis strategies.
Recently, Barnes and colleagues proposed that colonic tissue requires stimulation in order to observe CMMCs32, however published findings from our lab demonstrate that spontaneous CMMCs can be observed by simply pinning the tissue to the organ bath via the mesentery7. The presence of CMMCs under these conditions not only demonstrates the spontaneity of CMMCs, but further elaborates on the usefulness of this technique to establish changes in colonic motility. Although this approach is applicable to extra-colonic regions of the gastrointestinal tract, the complexity of small intestinal motility requires more detailed analysis strategies than those used for quantifying CMMCs33.
This experimental approach has very high spatial and temporal resolution and includes the option of drug delivery both external to and inside the lumen for investigating the effects of varying concentration gradients on the enteric nervous system. Furthermore, this method is suitable for analyzing small intestinal segmentation during the fed state6,23. The ex vivo nature of this method enables the role of the enteric nervous system to be assessed in the absence of central nervous system inputs and is therefore an ideal way to investigate gastrointestinal motility in a variety of models, including genetic models of disease (see Figure 2)6,34.
This method can also be used to compare physiological data to computer simulations of motor activity23,33,35. Such simulations can predict motor patterns in the form of spatiotemporal maps for direct comparisons with physiological experiments33,35. Using Fast Fourier Transform and wavelet analysis36, the contribution of smooth muscle pacemakers (generated by interstitial cells of Cajal) to motility can also be extracted. Furthermore, this video imaging technique can be combined with extracellular recording of electrical activity in the muscle3 to allow contributions of neural and myogenic pattern generators to be distinguished. Note, the extracellular recording method resolves inhibitory junction potentials in the absence of smooth muscle contractions or relaxations.
While this technique is well established for the analysis of gastrointestinal motility in a wide range of preparations and species, it also has the potential to be used in other systems such as the study of vasoconstriction in the mesentery (previously analyzed via a simpler diameter tracking system37) and in skeletal muscle.
The authors have nothing to disclose.
JCB and ELH-Y were supported by the US Department of Defense CDMRP Autism Research Program (AR11034). NHMRC (1047674) to ELH-Y.The May Stewart Bursary-University of Melbourne trust funded scholarship to MS. We thank Ali Taher, Fátima Ramalhosa and Gracia Seger for technical contributions.
Reagents | |||
NaCl (MW: 58.44) | Sigma-Aldrich | S7653-250G | |
KCl (MW: 74.55) | Sigma-Aldrich | P9333-500G | |
NaH2PO4.2H2O (MW: 156.01) | Chem Supply | 471-500G | |
MgSO4.7H20 (MW: 246.48) | Chem Supply | MA048 | |
CaCl2.2H2O (MW: 147.02) | Chem Supply | CA033 | |
D-Glucose anhydrous (MW: 180.16) | Chem Supply | GA018-500G | |
NaHCO3 (MW: 84.01) | Chem Supply | GA018-500G | |
Name | Company | Catalog Number | Comments |
Materials | |||
Two chambered organ bath Dimentions: 14 cm x 8 cm x 3 cm |
Custom Made | Contact Laboratory Directly | |
732 MULTI -PURPOSE SEALANT CLEAR | Dow Corning Australia Pty Ltd | 1890573 | |
SYLGARD 184 SILICONE ELASTOMER KIT | Dow Corning Australia Pty Ltd | 1064291 | |
STOPCOCK 3 WAY FEM-ML L/LOCK S | Terumo Medical Corporation | 0912-2006 | |
SYRINGES with Luer Lock Tips 50mL, 20 mL, 10 mL | Terumo Medical Corporation | N/A | |
1.57 mm (ID) x 3.16 mm (OD) – Silastic Tubing | Masterflex | 508-008 | |
1.02 mm (ID) x 2.16 mm (OD) – Silastic Tubing | Masterflex | 508-005 | |
1.50 mm (ID) x 2.50 mm (OD) – Silastic Tubing | Masterflex | 508-007 | |
1.60 mm (ID) – Platinum cured silicone tubing | Masterflex | 96410 – 14 | |
4.40 mm (ID) – Platinum cured silicone tubing | Masterflex | 96410 – 15 | |
3.10 mm (ID) – Platinum cured silicone tubing | Masterflex | 96410 -16 | |
Graduated Laboratory Glass Bottles – 500 ml | Thermofisher Scientific | 100-400 | |
CHEMICAL RUBBER STOPPER 57 x 65mm | |||
CHEMICAL RUBBER STOPPER 29 x 32mm | |||
Water heater (thermo regulator) | Ratek | TH7000 | |
Logitech Webcam | Logitech | ||
Name | Company | Catalog Number | Comments |
Software | |||
Virtual Dub – 1.9 11 | virtualdub.org | ||
MATLAB R2012a | Graph Pad | ||
Logitech Webcam Software | Logitech |