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1. The Macro- and Micro-Mechanics of the Colon and Rectum II: Theoretical and Computational Methods

   https://doi.org/10.3390/bioengineering7040152  

   Zhao, Yunmei; Siri, Saeed; Feng, Bin; Pierce, David M. (December 2020, Bioengineering)

   Abnormal colorectal biomechanics and mechanotransduction associate with an array of gastrointestinal diseases, including inflammatory bowel disease, irritable bowel syndrome, diverticula disease, anorectal disorders, ileus, and chronic constipation. Visceral pain, principally evoked from mechanical distension, has a unique biomechanical component that plays a critical role in mechanotransduction, the process of encoding mechanical stimuli to the colorectum by sensory afferents. To fully understand the underlying mechanisms of visceral mechanical neural encoding demands focused attention on the macro- and micro-mechanics of colon tissue. Motivated by biomechanical experiments on the colon and rectum, increasing efforts focus on developing constitutive frameworks to interpret and predict the anisotropic and nonlinear biomechanical behaviors of the multilayered colorectum. We will review the current literature on computational modeling of the colon and rectum as well as the mechanical neural encoding by stretch sensitive afferent endings, and then highlight our recent advances in these areas. Current models provide insight into organ- and tissue-level biomechanics as well as the stretch-sensitive afferent endings of colorectal tissues yet an important challenge in modeling theory remains. The research community has not connected the biomechanical models to those of mechanosensitive nerve endings to create a cohesive multiscale framework for predicting mechanotransduction from organ-level biomechanics. 

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2. Genetic regulation of enteric nervous system development in zebrafish

   https://doi.org/10.1042/BST20230343  

   Uribe, Rosa A. (January 2024, Biochemical Society Transactions)

   The enteric nervous system (ENS) is a complex series of interconnected neurons and glia that reside within and along the entire length of the gastrointestinal tract. ENS functions are vital to gut homeostasis and digestion, including local control of peristalsis, water balance, and intestinal cell barrier function. How the ENS develops during embryological development is a topic of great concern, as defects in ENS development can result in various diseases, the most common being Hirschsprung disease, in which variable regions of the infant gut lack ENS, with the distal colon most affected. Deciphering how the ENS forms from its progenitor cells, enteric neural crest cells, is an active area of research across various animal models. The vertebrate animal model, zebrafish, has been increasingly leveraged to understand early ENS formation, and over the past 20 years has contributed to our knowledge of the genetic regulation that underlies enteric development. In this review, I summarize our knowledge regarding the genetic regulation of zebrafish enteric neuronal development, and based on the most current literature, present a gene regulatory network inferred to underlie its construction. I also provide perspectives on areas for future zebrafish ENS research. 

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3. The load-bearing function of the colorectal submucosa and its relevance to visceral nociception elicited by mechanical stretch

   https://doi.org/10.1152/ajpgi.00127.2019  

   Siri, Saeed; Maier, Franz; Santos, Stephany; Pierce, David M; Feng, Bin (July 2019, American Journal of Physiology-Gastrointestinal and Liver Physiology)

   Mechanical distension beyond a particular threshold evokes visceral pain from distal colon and rectum (colorectum) and thus biomechanics plays a central role in visceral nociception. In this study we focused on the layered structure of the colorectum through the wall thickness and determined the biomechanical properties of layer-separated colorectal tissue. We harvested the distal 30 mm of mouse colorectum and dissected into inner and outer composite layers. The inner composite consists of the mucosa and submucosa while the outer composite includes the muscular layers and serosa. We divided each composite axially into three 10 mm-long segments and conducted biaxial mechanical extension tests and opening-angle measurements for each tissue segment. In addition, we quantified the thickness of the rich collagen network in the submucosa by nonlinear imaging via second harmonic generation (SHG). Our results reveal the inner composite is slightly stiffer in the axial direction while the outer composite is stiffer circumferentially. The stiffness of the inner composite in the axial direction is about twice that in the circumferential direction, consistent with the orientations of collagen fibers in the submucosa approximately ±30 degrees to the axial direction. Submucosal thickness measured by SHG showed no difference from proximal to distal colorectum under load-free condition, which likely contributes to the comparable tension stiffness of the inner composite along the colorectum. This, in turn, strongly indicates the submucosa as the load-bearing structure of the colorectum. This further implies nociceptive roles for the colorectal afferent endings in the submucosa that likely encode tissue-injurious mechanical distension. 

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4. A targeted CRISPR-Cas9 mediated F0 screen identifies genes involved in establishment of the enteric nervous system

   https://doi.org/10.1371/journal.pone.0303914  

   Moreno-Campos, Rodrigo; Singleton, Eileen W; Uribe, Rosa A (May 2024, PLOS ONE)

   Grinblat, Yevgenya (Ed.)

   The vertebrate enteric nervous system (ENS) is a crucial network of enteric neurons and glia resident within the entire gastrointestinal tract (GI). Overseeing essential GI functions such as gut motility and water balance, the ENS serves as a pivotal bidirectional link in the gut-brain axis. During early development, the ENS is primarily derived from enteric neural crest cells (ENCCs). Disruptions to ENCC development, as seen in conditions like Hirschsprung disease (HSCR), lead to the absence of ENS in the GI, particularly in the colon. In this study, using zebrafish, we devised anin vivoF0 CRISPR-based screen employing a robust, rapid pipeline integrating single-cell RNA sequencing, CRISPR reverse genetics, and high-content imaging. Our findings unveil various genes, including those encoding opioid receptors, as possible regulators of ENS establishment. In addition, we present evidence that suggests opioid receptor involvement in the neurochemical coding of the larval ENS. In summary, our work presents a novel, efficient CRISPR screen targeting ENS development, facilitating the discovery of previously unknown genes, and increasing knowledge of nervous system construction. 

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5. The Vibrio type VI secretion system induces intestinal macrophage redistribution and enhanced intestinal motility

   https://doi.org/10.1128/mbio.02419-24  

   Ngo, Julia S; Amitabh, Piyush; Sokoloff, Jonah G; Trinh, Calvin; Wiles, Travis J; Guillemin, Karen; Parthasarathy, Raghuveer (January 2025, mBio)

   Graf, Joerg (Ed.)

   Intestinal microbes, whether resident or transient, influence the physiology of their hosts, altering both the chemical and the physical characteristics of the gut. An example of the latter is the human pathogenVibrio cholerae’sability to induce strong mechanical contractions, discovered in zebrafish. The underlying mechanism has remained unknown, but the phenomenon requires the actin crosslinking domain (ACD) ofVibrio’s type VI secretion system (T6SS), a multicomponent protein syringe that pierces adjacent cells and delivers toxins. By using a zebrafish-nativeVibrioand imaging-based assays of host intestinal mechanics and immune responses, we find evidence that macrophages mediate the connection between the T6SS ACD and intestinal activity. Inoculation withVibriogives rise to strong, ACD-dependent, gut contractions whose magnitude resembles those resulting from genetic depletion of macrophages.Vibrioalso induces tissue damage and macrophage activation, both ACD-dependent, recruiting macrophages to the site of tissue damage and away from their unperturbed positions near enteric neurons that line the midgut and regulate intestinal motility. Given known crosstalk between macrophages and enteric neurons, our observations suggest that macrophage redistribution forms a key link betweenVibrioactivity and intestinal motility. In addition to illuminating host-directed actions of the widespread T6SS protein apparatus, our findings highlight how localized bacteria-induced injury can reshape neuro-immune cellular dynamics to impact whole-organ physiology. IMPORTANCEGut microbes, whether beneficial, harmful, or neutral, can have dramatic effects on host activities. The human pathogenVibrio choleraecan induce strong intestinal contractions, though how this is achieved has remained a mystery. Using a zebrafish-nativeVibrioand live imaging of larval fish, we find evidence that immune cells mediate the connection between bacteria and host mechanics. A piece ofVibrio’s type VI secretion system, a syringe-like apparatus that stabs cellular targets, induces localized tissue damage, activating macrophages and drawing them from their normal residence near neurons, whose stimulation of gut contractions they dampen, to the damage site. Our observations reveal a mechanism in which cellular rearrangements, rather than bespoke biochemical signaling, drives a dynamic neuro-immune response to bacterial activity. 

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