Correction: Enteric Neuronal Damage, Intramuscular Denervation and Smooth Muscle Phenotype Changes as Mechanisms of Chagasic Megacolon: Evidence from a Long-Term Murine Model of Tripanosoma cruzi Infection (original) (raw)
Related papers
PLOS ONE, 2016
We developed a novel murine model of long-term infection with Trypanosoma cruzi with the aim to elucidate the pathogenesis of megacolon and the associated adaptive and neuromuscular intestinal disorders. Our intent was to produce a chronic stage of the disease since the early treatment should avoid 100% mortality of untreated animals at acute phase. Treatment allowed animals to be kept infected and alive in order to develop the chronic phase of infection with low parasitism as in human disease. A group of Swiss mice was infected with the Y strain of T. cruzi. At the 11 th day after infection, a subgroup was euthanized (acute-phase group) and another subgroup was treated with benznidazole and euthanized 15 months after infection (chronic-phase group). Whole colon samples were harvested and used for studying the histopathology of the intestinal smooth muscle and the plasticity of the enteric nerves. In the acute phase, all animals presented inflammatory lesions associated with intense and diffuse parasitism of the muscular and submucosa layers, which were enlarged when compared with the controls. The occurrence of intense degenerative inflammatory changes and increased reticular fibers suggests inflammatoryinduced necrosis of muscle cells. In the chronic phase, parasitism was insignificant; however, the architecture of Aüerbach plexuses was focally affected in the inflamed areas, and a significant decrease in the number of neurons and in the density of intramuscular nerve bundles was detected. Other changes observed included increased thickness of the colon wall, diffuse muscle cell hypertrophy, and increased collagen deposition, indicating early fibrosis in the damaged areas. Mast cell count significantly increased in the muscular layers. We propose a model for studying the long-term (15 months) pathogenesis of Chagasic PLOS ONE |
Frontiers in Cellular and Infection Microbiology, 2020
There is a growing consensus that the balance between the persistence of infection and the host immune response is crucial for chronification of Chagas heart disease. Extrapolation for chagasic megacolon is hampered because research in humans and animal models that reproduce intestinal pathology is lacking. The parasite-host relationship and its consequence to the disease are not well-known. Our model describes the temporal changes in the mice intestine wall throughout the infection, parasitism, and the development of megacolon. It also presents the consequence of the infection of primary myenteric neurons in culture with Trypanosoma cruzi (T. cruzi). Oxidative neuronal damage, involving reactive nitrogen species induced by parasite infection and cytokine production, results in the denervation of the myenteric ganglia in the acute phase. The long-term inflammation induced by the parasite's DNA causes intramuscular axonal damage, smooth muscle hypertrophy, and inconsistent innervation, affecting contractility. Acute phase neuronal loss may be irreversible. However, the dynamics of the damages revealed herein indicate that neuroprotection interventions in acute and chronic phases may help to eradicate the parasite and control the inflammatory-induced increase of the intestinal wall thickness and axonal loss. Our model is a powerful approach to integrate the acute and chronic events triggered by T. cruzi, leading to megacolon.
Nitrergic Myenteric Neurons are Spared in Experimental Chagasic Megacolon
Journal of Neuroinfectious Diseases, 2016
Chagas disease is a chronic disorder caused by the Trypanosoma cruzi protozoan. The infection causes alterations to the enteric nervous system such as megaesophagus and megacolon. There is evidence of denervation of myenteric ganglia. The intense parasitism of acute phase affects neuronal integrity but contrasts with the absence of parasites and the discreet inflammatory process of chronic phase, indicating a progressive injury mechanism that needs to be better understood in the megacolons. The potential selectivity of enteric neurons classes affected by the progression of the disease is not yet clear. Nitrergic neurons which co-localize other neurotransmitters represent the most common inhibitory neuron of the ENS. Recently a chronic stage of the Chagas disease was reproduced experimentally in a suitable murine model of megacolon. Considering the limitation of studying human intestine and the controversy on the pattern of nNOS involvement in chagasic megacolon, we decided to assess the nitrergic neurons in the myenteric plexus of mice. We used antibodies against structural protein gene product 9.5 (PGP 9.5) and functional neuronal nitric oxide synthase (n-NOS) at the acute and chronic phase of the disease to quantify myenteric ganglionar neurons in the colon of infected and non-infected mice. We found a reduction in the ganglionar number of neurons detected by anti-protein gene product 9.5 antibodies in colon from mice at the chronic stage. However, the number of nitrergic neurons per ganglia remained unchanged along the acute to phase chronic of the disease. Our findings indicate a long-term preservation of nitregic neurons detrimental to other classes of enteric in our model of experimental Chagas disease. We propose that differential loss of enteric neurons is at least one of the structural substrate for the development of the longterm morphfunctional changes that lead to the megacolon.
Mechanisms of pathogenesis in Chagas disease
Chagas disease, caused by the obligate unicellular parasite Trypanosoma cruzi, presents itself in a diverse collection of clinical manifestations, ranging from severe, fatal heart and digestive tract pathologies to unapparent or minor alterations that do not compromise survival. Over the years, a number of mechanisms have been proposed to explain the pathogenesis of chagasic tissue lesions, all of which have faced some criticism or been received with skepticism. This article excludes the autoimmunity hypothesis for Chagas disease because it has been extensively reviewed elsewhere, and summarizes the various alternative hypotheses that have been advanced over the years. For each of these hypotheses, an outline of its main tenets and key findings that support them is presented. This is followed by the results and comments that have challenged them and the caveats that stand on their way to wider acceptance. It is hoped that this writing will draw attention to our shortcomings in understanding the pathogenesis of Chagas disease, which, unfortunately, continues to figure among the most serious health problems of the American continent.
Gastrointestinal involvement in Chagas disease
NeuroGastroLATAM Reviews
Achalasia and megacolon are the second most common manifestations of chronic Chagas disease (ChD) in endemic areas of Central and South America. Twenty or even more years after the initial infection, approximately one-third of infected people develop cardiac and/ or gastrointestinal abnormalities as typical chronic damages of ChD. The chronic phase of ChD is characterized by the damage of myenteric (intrinsic) and autonomic (extrinsic) neurons. A decreased density of enteric glial cells can be detected in patients with megaesophagus and megacolon and a loss of interstitial cells of Cajal. These lesions affect the complex mechanisms of neural, molecular, and cellular interactions that modulate the motor activity and other specific functions of the alimentary tract. Evidence for serum antibodies with the ability to recognize similar epitopes in both Trypanosoma cruzi and host antigens suggested that molecular mimicry could play a substantial role in the pathophysiology of chronic ChD. In fact, a high prevalence of circulating antibodies against M2 acetylcholine muscarinic receptor (M2R) in ChD patients with achalasia and megacolon has been found. These antibodies bind to and activate M2R, exhibiting agonist-like activity. Anti-M2R antibodies can both enhance tonic contraction in lower esophagus and distal colon by direct stimulation and also by counteracting the relaxant effect of drugs that increase cAMP accumulation (i.e. beta-adrenergic agonists). The biochemical and functional effects of these antibodies on esophageal and colon smooth muscle could play an important role in the pathophysiology of achalasia and megacolon secondary to ChD.
The enigmatic role of cholinergic reflex in the pathogenesis of Chagas disease
Parasitology Research, 2014
This study evaluated the inflammatory process in the colons of mice infected with Trypanosoma cruzi QM2 strain, through the analysis of muscle reactivity and the measurement of butyrylcholinesterase (BuChE) in plasma. "Swiss" mice were infected with T. cruzi QM2 strain and after 15 (G15), 30 (G30), 60 (G60), 90 (G90), and 210 (G210) days, each group had blood collected for the measurement of butyrylcholinesterase plasma concentrations ([BuChE]), a measure which functioned as an indicator of plasmatic Ach levels. All groups, except G15, had a segment of proximal colon removed to assess muscle reactivity to acetylcholine (Ach) and noradrenaline (NA) stimulation. After reactivity tests, the tissues were then fixed and stained with hematoxylin and eosin (HE) for histological evaluation of inflammatory response. The QM2 strain did induce inflammatory process in mice colon, and demonstrated differences in muscular contraction between the G60 and G210 groups, with p<0.05. Plasma [BuChE] increased during the acute phase of infection (p<0.05) with subsequent heterogeneous decline in the late chronic phase. These results show that the QM2 strain has tropism to the colon of mice and causes damage characteristic of megacolon; also, Ach has an enigmatic importance in the antiinflammatory reflex over the course of T. cruzi infection.
Journal of Neurogastroenterology and Motility
Background/Aims Chagasic megacolon is caused by Trypanosoma cruzi, which promotes in several cases, irreversible segmental colonic dilation. This alteration is the major anatomic-clinical disorder, characterized by the enteric nervous system and muscle wall structural damage. Herein, we investigate how T. cruzi-induced progressive colonic structural changes modulate the colonic contractile pattern activity. Methods We developed a murine model of T. cruzi-infection that reproduced long-term modifications of the enlarged colon. We evaluated colonic and total intestinal transit time in animals. The patterns of motor response at several time intervals between the acute and chronic phases were evaluated using the organ bath assays. Enteric motor neurons were stimulated by electric field stimulation. The responses were analyzed in the presence of the nicotinic and muscarinic acetylcholine receptor antagonists. Western blot was performed to evaluate the expression of nicotinic and muscarinic receptors. The neurotransmitter expression was analyzed by real-time polymerase chain reaction. Results In the chronic phase of infection, there was decreased intestinal motility associated with decreased amplitude and rhythmicity of intestinal contractility. Pharmacological tests suggested a defective response mediated by acetylcholine receptors. The contractile response induced by acetylcholine was decreased by atropine in the acute phase while the lack of its action in the chronic phase was associated with tissue damage, and decreased expression of choline acetyltransferase, nicotinic subunits of acetylcholine receptors, and neurotransmitters. Conclusions T. cruzi-induced damage of smooth muscles was accompanied by motility disorders such as decreased intestinal peristalsis and cholinergic system response impairment. This study allows integration of the natural history of Chagasic megacolon motility disorders and opens new perspectives for the design of effective therapeutic.
Chagasic megacolon: enteric neurons and related structures
Histochemistry and Cell Biology, 2014
Springerlink.com neuron loss. Neurons co-immunoreactive for vIP and calretinin survived disproportionately. As a consequence, these neurons may have contributed to maintain the epithelial barrier and allowed the chagasic patients to survive for decades, despite their severe disturbance of colonic motility. Due to its neuroprotective and neuroeffectory functions, vIP may play a key role in the development and duration of chagasic megacolon. Keywords Chagas • enteric nervous system • Hirschsprung • Megacolon • vasoactive intestinal peptide Structural components of the human enteric nervous system The overwhelming majority of enteric neuronal cell bodies lie, together with enteric glial cells, in ganglionated nerve networks, the myenteric and the submucosal plexus. These differ in location and network architecture (Fig. 1) as well as in neuronal composition (see below). Situated between the longitudinal and the circular muscle layer is the myenteric plexus (Auerbach 1862). Its main, primary network is commonly monolayered and extends from the upper oesophageal to the internal anal sphincter. Most human myenteric neurons are either nitrergic or cholinergic (Murphy et al. 2007; Beck et al. 2009). Like in other species (best known from the guinea pig, Furness 2006), human nitrergic myenteric neurons are suggested to be either descending inter-and/or inhibitory motor neurons (Grider 1993). They are uniaxonal with spiny shaped dendrites (spiny type I morphology; Brehmer et al. 2004a; Lindig et al. 2009). Besides their reactivity for the nitrergic marker neuronal nitric oxide synthase (nNOS), some of them co-stain immunohistochemically for vasoactive Abstract Megacolon, the irreversible dilation of a colonic segment, is a structural sign associated with various gastrointestinal disorders. In its hereditary, secondary form (e.g. in Hirschsprung's disease), dilation occurs in an originally healthy colonic segment due to an anally located, aganglionic zone. In contrast, in chronic Chagas' disease, the dilated segment itself displays pathohistological changes, and the earliest and most prominent being found was massive loss of myenteric neurons. This neuron loss was partial and selective, i.e. some neurons containing neuronal nitric oxide synthase and/or vasoactive intestinal peptide (vIP) were spared from neuron death. This disproportionate survival of inhibitory neurons, however, did not completely correlate with the calibre change along the surgically removed, megacolonic segments. A better correlation was observed as to potentially contractile muscle tissue elements and the interstitial cells of Cajal. Therefore, the decreased densities of α-smooth muscle actin-and c-kitimmunoreactive profiles were estimated along resected megacolonic segments. Their lowest values were observed in the megacolonic zones itself, whereas less pronounced decreases were found in the non-dilated, transitional zones (oral and anal to dilation). In contrast to the myenteric plexus, the submucosal plexus displayed only a moderate