All procedures were approved by the Victoria University Animal Experimentation Ethics Committee and performed in accordance with the guidelines of the National Health and Medical Research Council (NHMRC) Australian Code of Practice for the Care and Use of Animals for Scientific Purposes.

Male Balb/c mice aged 6–8 weeks (18–25 g) supplied from the Animal Resources Centre (Perth, Australia) were used for the experiments. Mice had free access to food and water and were kept under a 12 h light/dark cycle in a well-ventilated room at an approximate temperature of 22°C. Mice acclimatized for a minimum of 5 days prior to the commencement of in vivo intraperitoneal injections. Mice were euthanized via cervical dislocation. A total of 56 mice were used for this study.

Mice received intraperitoneal injections of IRI (30 mg/kg⁻¹) (Sigma-Aldrich, Australia)via a 26 gauge needle, once a day, 3 times a week over a 14 day period to a total of 6 injections. Injections began at Day 0 and continued on Day 2, Day 4, Day 7, and Day 9, the final injection was given on Day 11. IRI was dissolved in sterile water to make 10⁻¹ M L⁻¹ stock solutions refrigerated at −20°C. The stock was then defrosted and diluted with sterile water to make 10⁻² M L⁻¹ solutions for intraperitoneal injections via a 26 gauge needle. The dose of IRI was calculated to reach a cumulative dose equivalent to a standard human dose in combination therapy, 180 mg/m² per body surface area (Reagan-Shaw et al., 2008; Köhne et al., 2012). Sham-treated mice received sterile water via intraperitoneal injections 3 times a week. The injected volumes were calculated to the body weight; the maximum volume of injected IRI or vehicle did not exceed 200 μL per injection. Mice were euthanized via cervical dislocation at Day 3 (after receiving 2 treatments), Day 7 (after receiving 3 treatments), and Day 14 (after receiving 6 treatments). Post-treatment group mice were euthanized 7 days after the final injection (6 treatments). Colons from all groups were collected for in vitro experiments.

A separate cohort of mice was used for food consumption experiments. IRI was dissolved in 0.1% dimethyl sulfoxide (DMSO) (Sigma-Aldrich, Australia) in sterile water to make 10⁻² M L⁻¹ solutions for intraperitoneal injections. Sham-treated mice received 0.1% DMSO in sterile water.

Gastrointestinal transit was studied by X-ray prior to first treatment (day 0) and at 3, 7, and 14 days and 7 days post-treatment of IRI treatment (n = 5 mice/group) as described previously (McQuade R. et al., 2016; McQuade R. M. et al., 2016). Briefly, the contrast agent, 0.4 mL of suspended barium sulfate (X-OPAQUE-HD, 2.5 g/mL), was administered via oral gavage. Prior to performing X-ray imaging, animals were trained/conditioned for oral gavage using either 0.9% w/v saline or sterile water (volume 0.1–0.4 ml); this was repeated at least 3 times for each animal with at least 24 h between each training session. Radiographs of the gastrointestinal tract were taken using a HiRay Plus Porta610HF X-ray apparatus (JOC Corp, Kanagawa, Japan; 50 kV, 0.3 mAs, exposure time 60 ms). Mice were immobilized in the prone position by placing them inside a transparent plastic restraint tube with partly open front side for breathing, this comfortably restrains animal movement for a maximum of 1–2 min which is essential for successful X-ray imaging. The training/conditioning with restraint was done by placing the restrainer into the mouse cages at least 24 h prior to the X-ray procedure. X-rays were captured using Fujifilm cassettes (24 × 30 cm) immediately after administration of barium sulfate (T0), every 5 min for the first hour, every 10 min for the second hour, then every 20 min through to 360 min (T360). Animals were closely monitored during and after all procedures. Images were developed via a Fujifilm FCR Capsula XLII and analyzed using eFilm 4.0.2 software. Speed of gastrointestinal transit was calculated as time in min taken to reach each region of the gastrointestinal tract (stomach, small intestines, caecum, and colon). Organ emptying was calculated as the time taken for complete barium emptying from specific gastrointestinal regions (stomach, small intestines) (Cabezos et al., 2008, 2010; Girón et al., 2015).

Fresh fecal pellets were collected from both sham and IRI-treated mice (n = 10 mice/group). Individual mice were placed in holding cages for a period of 15–30 min, the first 5 fresh pellets expelled were collected and weighed immediately to calculate average fresh wet weight. Pellets were then dehydrated for 72 h at room temperature prior to measurement of the dry weight. Water content was calculated as the difference between the wet weight and dry weight. Pellet length was measured in arbitrary units and converted to μm in all X-ray images displaying discernible pellets in the distal colon using an Image J measurement tool. X-ray images were converted to TIFF format and set to 800 × 800 pixels.

The entire colon was removed from day 14 and post-treatment sham and IRI-treated mice (n = 5 mice/group) and set up in organ-bath chambers to record motor patterns ex vivo (Wafai et al., 2013). Briefly, the colon was placed into warmed (35°C), oxygenated physiological saline until the fecal pellets were expelled. The empty colon was cannulated at both ends and arranged horizontally in an organ-bath chamber. The proximal end of the colon was connected to a reservoir containing oxygenated physiological saline to maintain intraluminal pressure. The distal end was attached to an outflow tube that provided a maximum of 2 cm H₂O back-pressure. Organ baths were continuously superfused with oxygenated physiological saline and preparations were left to equilibrate for 30 min. Contractile activity of each segment was recorded with a Logitech Quickcam Pro camera positioned 7–8 cm above the preparation. Videos (2 × 20 min) of each test condition were captured and saved in avi format using VirtualDub software (version 1.9.11).

Recordings were used to construct spatiotemporal maps using in-house edge detection software (Gwynne et al., 2004). Spatiotemporal maps plot the diameter of the colon at all points during the recording allowing contractile motor patterns to be analyzed with Matlab software (version 12). Colonic migrating motor complexes (CMMCs) were defined as propagating contractions directed from the proximal to the distal end of the colon which traveled more than 50% of the colon length (Spencer and Bywater, 2002; Roberts et al., 2007, 2008). Contractions that propagated less than 50% of the colonic length were considered to be short contractions (SCs). Incomplete contractions occurring synchronously at different parts of the colon rather than propagating over the length of the colon were defined as fragmented contractions (FCs) (McQuade R. et al., 2016).

The colon was harvested and placed in a 10% formalin solution overnight and then transferred into 70% ethanol the following day. Paraffin embedded colon sections were cut 5 μm thick and deparaffinized, cleared, and rehydrated in graded ethanol concentrations.). To examine the morphological changes to the colon, standard Haematoxylin, and Eosin (H&E) staining protocol was followed (McQuade R. et al., 2016). Ten randomly selected sections per preparation were analyzed and scored on the following parameters: changes in crypt architecture (0–5), reduction in crypt length (0–5), mucosal ulceration (0–5), and immune cell infiltration (0–5) (total score 20) (Rahman et al., 2016). All images were analyzed blindly.

Colon samples were cut open along the mesenteric border, cleared of their contents, and pinned mucosa up without stretching (n = 5 mice/group). Tissues were fixed with Zamboni's fixative overnight at 4°C. Preparations were cleared of fixative by washing 3 × 10 min with DMSO (Sigma-Aldrich, Australia) followed by 3 × 10 min washes with PBS. After washing, tissues were embedded in 100% OCT and frozen using liquid nitrogen (LN₂) and isopentane (2-methyl butane) and stored in −80°C freezer. Tissues were cut at 20 μm section thickness using a Leica CM1950 cryostat (Leica Biosystems, Germany), adhered to slides and allowed to rest for 30 min at room temperature before processing.

Cross section preparations were incubated with 10% normal donkey serum (Chemicon, USA) for 1 h at room temperature. Tissues were then washed (2 × 5 min) with PBS and incubated with primary antibodies against CD45 (rat, 1:500, BioLegend, Australia), overnight at 4°C. Sections were then washed in PBS (3 × 10 min) before incubation with secondary antibodies labeled with fluorophore donkey anti-rat Alexa 488 (1:200, Jackson Immunoresearch Laboratories, PA, USA) for 2 h at room temperature. The sections were given 3 × 10 min final washes in PBS and then cover slipped using fluorescence mounting medium (DAKO, Australia).

Segments of the distal colon (2–3 cm) were placed in oxygenated phosphate-buffered saline (PBS) (pH 7.2) containing nicardipine (3 μM) (Sigma-Aldrich, Australia) for 20 min to inhibit smooth muscle contractions (n = 5 mice/group). Samples were cut open along the mesenteric border, cleared of their contents, maximally stretched and pinned mucosa down. Tissues were fixed with Zamboni's fixative (2% formaldehyde, 0.2% picric acid) overnight at 4°C. Preparations were cleared of fixative by washing 3 × 10 min with DMSO (Sigma-Aldrich, Australia) followed by 3 × 10 min washes with PBS. Once washed, tissues were dissected mucosa up to expose the myenteric plexus. Fixed tissues were stored at 4°C in PBS for a maximum of 5 days.

Wholemount preparations were incubated with 10% normal donkey serum (Chemicon, USA) for 1 h at room temperature. Tissues were then washed (2 × 5 min) with PBS and incubated with primary antibodies against Protein Gene Product 9.5 (PGP9.5) (chicken, 1:500, Abcam, MA, USA), choline acetyltransferase (ChAT) (goat, 1:500, Abcam, MA, USA) or vesicular acetylcholine transporter (VAChT) (goat, 1:500, Abcam, MA, USA) overnight at 4°C. Tissues were then washed in PBS (3 × 10 min) before incubation with species-specific secondary antibodies labeled with different fluorophores: donkey anti-chicken Alexa 594 (1:200, Jackson Immunoresearch Laboratories, PA, USA) and donkey anti-goat Alexa 488 (1:200, Jackson Immunoresearch Laboratories, PA, USA) for 2 h at room temperature. Wholemount preparations were given 3 × 10 min final washes in PBS and then mounted on glass slides using fluorescent mounting medium (DAKO, Australia).

Wholemount preparations and cross sections were viewed under a Nikon Eclipse Ti laser scanning microscope. Eight randomly chosen three dimensional (z-series) images from each preparation were captured with a x20 objective and processed using NIS Elements software (Nikon, Japan). Fluorophores were visualized using excitation filters for Alexa 594 Red (excitation wavelength 559 nm), Alexa 488 (excitation wavelength 473 nm), and Alexa 405 (excitation wavelength 405 nm). Z-series images were taken at step size of 1.75 μm (1,600 × 1,200 pixels). The number of PGP9.5 and ChAT immunoreactive (IR) neurons was quantified in the myenteric ganglia and CD45-IR cells in cross sections were quantified within a 2 mm² area of each preparation. Quantitative analyses were conducted blindly. The density of VAChT-IR fibers in cross sections of the colon was measured from 8 images per preparation at x20 magnification (total area 2 mm²). All images were captured at the same distance from the tissue edges, at identical acquisition exposure-time conditions, calibrated to standardized minimum baseline fluorescence. Minimum baseline fluorescence was determined from the sham-treated tissue, these acquisition settings were used as the acquisition exposure-time for all samples. All images were converted to binary, set to identical thresholds and changes in fluorescence from baseline were measured as mean gray value using Image J software (NIH, MD, USA). All images were analyzed blindly. The density of immunoreactive fibers was then expressed in arbitrary units.

A one-way analysis of variance (ANOVA) with Tukey Kramer post hoc test was performed to compare neurochemical and gastrointestinal transit data between multiple groups. Student's unpaired two-tailed t-test was used to compare motility, pellet length and fecal water content data. Analyses were performed using Graph Pad Prism (Graph Pad Software Inc., CA, USA). Data are presented as mean ± standard error of the mean (SEM). Value differences were considered statistically significant at P < 0.05.

To determine the effects of IRI administration on gastrointestinal transit, a series of radiographic images were used to track the movement of barium sulfate through the gastrointestinal tract before the first injection (day 0), after 2 injections (day 3), 3 injections (day 7), 6 injections (day 14 and 7 days post-treatment) (Figure 1). Speed of barium movement was calculated by tracing barium entry from one part of the gastrointestinal tract to the next. Pellet formation time was calculated as the time taken (in minutes) for the first pellet to form. After 3 days of IRI administration, transit was significantly faster to the caecum and colon and pellet formation was significantly quicker (Figure 2A, Table 1). No differences in transit time to the caecum or colon were found at days 7, 14 or post-treatment when compared to day 0 (Figure 2A, Table 1).

Although tracing barium movement allowed for the analysis of real time transit speed (the time for barium to reach various parts of the gastrointestinal tract), gastrointestinal organ filling and emptying does not happen simultaneously, therefore we further analyzed the time taken for complete barium emptying from specific gastrointestinal regions (indicative of the gastrointestinal propulsive activity). Significant delays in gastric emptying were found at all time points following IRI treatment and post-treatment (Figure 2B, Table 1). No differences in intestinal emptying were found following 3 or 7 days of IRI administration, but intestinal emptying was significantly delayed following 14 days of IRI treatment, as well as post-treatment, compared to day 0 (Figure 2C, Table 1).

To define the clinical symptoms resulting from the altered patterns of colonic motor activity, pellet length in X-ray images and fecal water content in freshly collected fecal pellets were analyzed. Pellet length significantly increased after 7 and 14 days of IRI treatment (P < 0.01 for both), as well as post-treatment (P < 0.05), but no significant differences in pellet length were found following 3 days of IRI treatment when compared to day 0 (Figure 3).

Fecal water content was calculated as the difference between wet and dry pellet weight. The average wet weight of fresh pellets from IRI-treated mice was significantly greater than that of pellets from sham-treated mice at all time points (day 3 sham: 54 ± 3.4 mg, IRI: 67 ± 2.8 mg, P < 0.01: day 7 sham: 57 ± 4.5 mg, IRI: 74 ± 2.0 mg, P < 0.01; day 14 sham: 51 ± 2.9 mg, IRI: 74 ± 2.9 mg, P < 0.0001; (post-treatment sham: 52 ± 1.9 mg, IRI: 95 ± 3.9 mg, P < 0.0001) (Figure 4A). After dehydration, the average dry weight of pellets from IRI-treated mice at day 3 was significantly less than those from sham-treated mice (sham: 26 ± 1.5 mg, IRI: 19 ± 2.7 mg, P < 0.05) (n = 10 mice/group) (Figure 4B). However, the average dry weight from IRI-treated mice was significantly greater than for pellets from sham-treated mice at day 7 (sham: 25 ± 2.3 mg, IRI: 34 ± 0.9 mg, P < 0.01), day 14 (sham: 25 ± 1.4 mg, IRI: 39 ± 2.3 mg, P < 0.0001) and post-treatment (sham: 25 ± 1.3 mg, IRI: 41 ± 2.3 mg, P < 0.0001) (n = 10 mice/group) (Figure 4B). The water content was significantly higher in pellets collected from IRI-treated mice than pellets collected from sham-treated mice at day 3 (sham: 52 ± 1.7%, IRI: 72 ± 3.2%, P < 0.0001), day 14 (sham: 51 ± 1.8%, IRI: 57 ± 1.2%, P < 0.05) and post-treatment (53 ± 1.3 v, IRI: 57 ± 1.6%, P < 0.05) (n = 10 mice/group) (Figure 4C). No difference in water content between sham-treated (56 ± 2.7%) and IRI-treated mice (54 ± 1.5%) was found at day 7.

To investigate the effects of IRI on colonic motility controlled by intrinsic innervation, excised colons were studied in organ bath experiments at day 14 of IRI treatment and post-treatment (Figure 5A). The total number of contractions (including all types of motor activity in the colon: CMMCs, short and fragmented contractions) was increased in the colons from day 14 IRI-treated (P < 0.01) and post-treatment (P < 0.0001) animals compared to sham-treated mice (Figure 5B, Table 2). To determine if this was due to changes in a specific type of motor activity, the frequency and proportion were analyzed for each type of motor contractions.

A decrease in the frequency and proportion of CMMCs was observed in the colons from day 14 IRI-treated compared to sham-treated animals (P < 0.0001 for both) (Figures 5B,C, Table 2). The decrease in frequency (P < 0.001) and proportion (P < 0.0001) of CMMCs persisted in the colons from post-treatment mice compared to sham-treated animals (Figures 5B,C, Table 2).

Following 14 days treatment with IRI, the frequency of SCs in the colon was greater compared to sham-treated colon (P < 0.05) (Figure 5B, Table 2), but no significant difference in the proportion of SCs was found in day 14 IRI-treated compared to sham-treated mice (Figure 5C). Similarly, the frequency of SCs in the colon increased in post-treatment mice compared to sham-treated mice (P < 0.01) (Figure 5B, Table 2), but without a change in the proportion of SCs in post-treatment mice when compared to sham-treated mice (Figure 5C).

Both the frequency and the proportion of FCs was significantly higher in IRI-treated mice when compared to sham-treated mice (P < 0.0001 for both) (Figures 5B,C, Table 2). Similarly, the frequency (P < 0.001) and proportion of FCs (P < 0.001) was significantly greater in the colon from post-treatment IRI mice than in sham-treated mice (Figures 5B,C, Table 2).

Histological structure of the colons from the sham-treated animals at days 3, 7, 14, and post-treatment appeared healthy with a visible brush border as well as uniform crypts (total histological score = 5) (Figures 6A–D,E). Severe mucosal ulceration and crypt distension was observed in the colon from the IRI-treated group at day 3 (total histological score = 17) (Figures 6A′,E). Colon sections from IRI-treated mice at days 7 (total histological score = 12) (Figures 6B′,E) and 14 (total histological score = 12) (Figures 6C′,E) displayed severe mucosal ulceration coupled with crypt hypoplasia and disorganization, which were not observed in colonic preparations from sham-treated mice. Colon sections from post-treatment IRI mice displayed crypt hypoplasia and disorganization, but the epithelial brush border was visible and appeared to be restored (total histological score = 8) (Figures 6D′,E).

To investigate if acute and chronic IRI treatment causes inflammation, immune cell infiltration in the colon was analyzed. Immune cells in colonic cross sections were labeled with a pan-leukocyte marker anti-CD45 antibody following 3, 7, 14 days and post IRI treatment compared to sham-treated mice (Figures 7A–D′). Total numbers of CD45 positive cells were counted within a 2 mm² area. A significant increase in the number of CD45 positive cells was found in the colon following 3 (sham: 45 ± 9; IRI: 109 ± 3, P < 0.0001), 7 (sham: 47 ± 3; IRI: 92 ± 5, P < 0.0001), and 14 days (sham: 42 ± 3; IRI: 98 ± 2, P < 0.0001) of IRI administration when compared to sham treatment. This increase persisted in post-treatment IRI mice (92 ± 7, P < 0.0001) compared to sham (44 ± 1) group (Figure 7E).

To investigate changes to the total number of myenteric neurons wholemount preparations were labeled with a pan-neuronal marker anti-PGP9.5 antibody (Figure 8). Repeated in vivo administration of IRI induced myenteric neuronal loss when compared to the sham-treated groups at days 7 (sham: 1,218 ± 17; IRI: 1,092 ± 2, P < 0.05) and 14 (sham: 1,262 ± 34; IRI: 1,072 ± 23, P < 0.05) (Figure 9A). This neuronal loss persisted in mice post IRI treatment (sham: 1,232 ± 32; IRI: 1,038 ± 52, P < 0.01). No significant difference in numbers of myenteric neurons was found at day 3 (sham: 1,222 ± 9; IRI: 1,171 ± 22) (Figure 9A).

To determine if IRI administration was associated with changes in a specific subpopulation of myenteric neurons, the average number and proportion of neurons immunoreactive (IR) for ChAT specific to cholinergic neurons was analyzed in both sham and IRI-treated mice (Figure 8). Repeated in vivo administration of IRI induced a significant increase in the average number of ChAT-IR neurons when compared to sham-treated group at days 3 (sham: 293 ± 9; IRI: 372 ± 6, P < 0.0001), 7 (sham: 325 ± 3; IRI: 390 ± 5, P < 0.001), 14 (sham: 320 ± 15; IRI: 390 ± 3, P < 0.0001) and post-treatment (sham: 306 ± 15; IRI: 401 ± 10, P < 0.0001) (Figure 9B). The proportion of ChAT-IR neurons significantly increased at all time points (Figure 9C).

The define whether increase in ChAT expression in neuronal cell bodies was due to the increased synthesis or decreased transport and release of acetylcholine, cholinergic fibers were labeled within myenteric ganglia in wholemount preparations of the colon using anti-VAChT antibody at day 14 and post IRI treatment (Figures 10A–B'). Repeated in vivo administration of IRI induced a significant increase in the density of VAChT-IR fibers in the myenteric plexus at day 14 (sham: 4.0 ± 0.2; IRI: 10.3 ± 0.3, P < 0.0001) and post-treatment compared to the sham-treated group (sham: 4.2 ± 0.2; IRI: 12.6 ± 0.5, P < 0.0001) (Figure 10C).

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.