Chronic linaclotide treatment reduces colitis-induced neuroplasticity and reverses persistent bladder dysfunction
Luke Grundy, Andrea M. Harrington, Joel Castro, Sonia Garcia-Caraballo, Annemie Deiteren, Jessica Maddern, Grigori Y. Rychkov, Pei Ge, Stefanie Peters, Robert Feil, Paul Miller, Andre Ghetti, Gerhard Hannig, Caroline B. Kurtz, Inmaculada Silos-Santiago, Stuart M. Brierley
Luke Grundy, Andrea M. Harrington, Joel Castro, Sonia Garcia-Caraballo, Annemie Deiteren, Jessica Maddern, Grigori Y. Rychkov, Pei Ge, Stefanie Peters, Robert Feil, Paul Miller, Andre Ghetti, Gerhard Hannig, Caroline B. Kurtz, Inmaculada Silos-Santiago, Stuart M. Brierley
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Research Article Gastroenterology Neuroscience

Chronic linaclotide treatment reduces colitis-induced neuroplasticity and reverses persistent bladder dysfunction

Abstract

Irritable bowel syndrome (IBS) patients suffer from chronic abdominal pain and extraintestinal comorbidities, including overactive bladder (OAB) and interstitial cystitis/painful bladder syndrome (IC-PBS). Mechanistic understanding of the cause and time course of these comorbid symptoms is lacking, as are clinical treatments. Here, we report that colitis triggers hypersensitivity of colonic afferents, neuroplasticity of spinal cord circuits, and chronic abdominal pain, which persists after inflammation. Subsequently, and in the absence of bladder pathology, colonic hypersensitivity induces persistent hypersensitivity of bladder afferent pathways, resulting in bladder-voiding dysfunction, indicative of OAB/IC-PBS. Daily administration of linaclotide, a guanylate cyclase-C (GC-C) agonist that is restricted to and acts within the gastrointestinal tract, reverses colonic afferent hypersensitivity, reverses neuroplasticity-induced alterations in spinal circuitry, and alleviates chronic abdominal pain in mice. Intriguingly, daily linaclotide administration also reverses persistent bladder afferent hypersensitivity to mechanical and chemical stimuli and restores normal bladder voiding. Linaclotide itself does not inhibit bladder afferents, rather normalization of bladder function by daily linaclotide treatment occurs via indirect inhibition of bladder afferents via reduced nociceptive signaling from the colon. These data support the concepts that cross-organ sensitization underlies the development and maintenance of visceral comorbidities, while pharmaceutical treatments that inhibit colonic afferents may also improve urological symptoms through common sensory pathways.

Authors

Luke Grundy, Andrea M. Harrington, Joel Castro, Sonia Garcia-Caraballo, Annemie Deiteren, Jessica Maddern, Grigori Y. Rychkov, Pei Ge, Stefanie Peters, Robert Feil, Paul Miller, Andre Ghetti, Gerhard Hannig, Caroline B. Kurtz, Inmaculada Silos-Santiago, Stuart M. Brierley

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Figure 4

Exogenous cGMP inhibits colon-innervating DRG neurons via a membrane target accessed from an extracellular site.

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Exogenous cGMP inhibits colon-innervating DRG neurons via a membrane tar...
(A) Whole-cell current-clamp recordings of retrogradely traced colon-innervating DRG neurons (n = 15). Bath application of linaclotide (1,000 nM) did not affect rheobase (amount of current required to fire an action potential). (B) Representative recordings in response to 500-millisecond current injection at rheobase (top) and 2× rheobase (bottom). Recordings were from the same neuron before and after linaclotide. (C) Colon-innervating DRG neurons from CVH mice (n = 36) display a reduced rheobase compared with controls (n = 30), indicating neuronal hyperexcitability (****P < 0.0001). (D) Percentage of colon-innervating DRG neurons from control and CVH mice inhibited by exogenous cGMP (0.1–10 μM). (E) Exogenous cGMP increases the rheobase of colon-innervating DRG neurons from control mice (n = 7) at 0.1 μM cGMP (*P < 0.05) and 1 μM cGMP (*P < 0.05) and (F) CVH mice (n = 9) at 1 μM (**P < 0.01) and 10 μM cGMP (**P < 0.01). (G) Recordings from a CVH colon-innervating DRG neuron to 500-millisecond current injections, showing rheobase at baseline and in the presence of 0.1–10 μM cGMP. (H) A dissociated E12.5 DRG neuron and (I) growth cones isolated from R26-CAG-mcGi500 mice, expressing the intracellular membrane-targeted mcGi500 (YFP fluorescence). In both examples, the red circle represents the region of interest (ROI) that was chosen for the measurement shown in J and K. Scale bars: 10 μm. Fluorescence resonance energy transfer (FRET)/cGMP measurements performed with embryonic (J) DRG neurons and (K) growth cones. An increase in the CFP/YFP emission ratio, R = F480/F535, indicates increased intracellular cGMP concentrations. FRET-based cGMP imaging was performed with drug stimulations (gray bars) in the following order: C-type natriuretic peptide (CNP; 0.1 μM), uroguanylin (UG; 1 μM), and 0.1, 10, and 100 μM cGMP. CFP (cyan) and YFP (yellow) emissions were recorded and the ratio (black) built, which corresponds to the intracellular cGMP concentration. After deliberate cell permeabilization with β-escin, cells were perfused with 1 μM cGMP (positive control). Group quantification of cGMP signals, showing extracellular cGMP does not enter the (L) somata of intact dissociated DRG neurons nor (M) their growth cones (****P < 0.0001; CNP vs. uroguanylin and cGMP (0.1–100 μM. &&P < 0.01; cGMP permeabilization vs. uroguanylin and cGMP (0.1–100 μM). Data represent mean ± SEM. P values are based on paired t tests (A), unpaired t tests (C), or 1-way ANOVA with Tukey’s multiple comparison tests (E, F, L,and M).