Perivascular Interstitial Cells of Cajal in Human Colon

Liu, Yuan An; Chung, Yuan Chiang; Shen, Ming Yin; Pan, Shien Tung; Kuo, Chun Wei; Peng, Shih-Jung; Pasricha, Pankaj J.; Tang, Shiue–Cheng

doi:10.1016/j.jcmgh.2014.11.003

Cited by 13 publications

(9 citation statements)

References 51 publications

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“…The tdT+ c‐kit cells interacting with the myenteric ganglia and blood vessels may represent a distinct Cajal cell population. The presence of perivascular interstitial cells of Cajal was recently shown in the human colon (Liu et al, ). The functional role of these cells for gut physiology remains to be elucidated.…”

Section: Introductionmentioning

confidence: 80%

Enteric Glia: S100, GFAP, and Beyond

Grundmann

Loris

Maas-Omlor

et al. 2019

The Anatomical Record

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Since several years, the enteric nervous system (ENS) is getting more and more in the focus of gastrointestinal research. While the main interest was credited for years to the enteric neurons and their functional properties, less attention has been paid on the enteric glial cells (EGCs). Although the similarity of EGCs to central nervous system (CNS) astrocytes has been demonstrated a long time ago, EGCs were investigated in more detail only recently. Similar to the CNS, there is not "the" EGC, but also a broad range of diversity. Based on morphology and protein expression, such as glial fibrillary acidic protein (GFAP), S100, or Proteolipid-protein-1 (PLP1), several distinct glial types can be differentiated. Their heterogeneity in morphology, localization, and transcription as well as interaction with surrounding cells indicate versatile functional properties of these cells for gut function in health and disease. Although NG2 is found in a subset of CNS glial cells, it did not colocalize with the glial marker S100 or GFAP in the ENS. Instead, it in part colocalize with PDGFRα, as it does in the CNS, which do stain fibroblast-like cells in the gastrointestinal tract. Moreover, there seem to be species dependent differences. While GFAP is always found in the rodent ENS, this is completely different for the human gut.Only the compromised human ENS shows a significant amount of GFAPpositive glial cells. So, in general we can conclude that the EGC population is species specific and as complex as CNS glia. Anat Rec, 302:1333Rec, 302: -1344Rec, 302: , 2019.

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Section: Introductionmentioning

confidence: 80%

Enteric Glia: S100, GFAP, and Beyond

Grundmann

Loris

Maas-Omlor

et al. 2019

The Anatomical Record

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“…The technical advance of tissue clearing of mouse and human gastrointestinal tissues [10,37,[41][42][43] has enabled us to develop 3D histology for visualisation of the pancreatic neuroinsular network. Using the transparent specimens, we applied both fluorescence and transmitted light microscopy (a dualoptical approach) to examine the pancreatic microstructure and neurovascular network.…”

Section: Discussionmentioning

confidence: 99%

Human pancreatic neuro-insular network in health and fatty infiltration

et al. 2017

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Aims/hypothesis Identification of a pancreatic neuro-insular network in mice suggests that a similar integration of islets and nerves may be present in the human pancreas. To characterise the neuro-insular network and the intra-pancreatic ganglia in a clinically related setting, we examined human pancreases in health and with fatty infiltration via 3-dimensional (3D) histology and compared the human pancreatic microenvironment with its counterpart in mice. Methods Human pancreatic specimens from individuals with normal BMI, high BMI (≥ 25) and type 2 diabetes were used to investigate the neuro-insular network. Transparent specimens were prepared by tissue clearing for transmitted light and deeptissue fluorescence imaging to simultaneously visualise infiltrated adipocytes, islets and neurovascular networks. Results High-definition images of human islets reveal that both the sympathetic and parasympathetic nerves enter the islet core and reside in the immediate microenvironment of islet cells. Around the islets, the neuro-insular network is visualised with 3D histology to identify the intra-pancreatic ganglia (peri-lobular and intra-parenchymal ganglia) and the islet-ganglionic association. In humans, but not in mice, pancreatic fatty infiltration (BMI dependent) features adipocytes infiltrating into the parenchyma and accumulating in the perilobular space, in which the peri-lobular ganglia also reside. We identified the formation of adipose-ganglionic complexes in the peri-lobular space and enlargement of ganglia around adipocytes. In the specimen from the individual with type 2 diabetes, an increase in the number of nerve projections from the intra-parenchymal ganglia is associated with severe fatty infiltration. Conclusions/interpretation We present new perspectives of human pancreas and islet innervation via 3D histology. Our results strongly suggest that fatty infiltration in the human pancreas creates a neurotrophic microenvironment and promotes remodelling of pancreatic innervation.

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“…To elucidate the ability of Schwann cells and pericytes in the participation of islet graft neurovascular regeneration, in this research we transplanted the mouse islets under the kidney capsule and prepared transparent graft specimens by tissue clearing (or optical clearing, use of an immersion solution of high refractive index to reduce scattering in optical microscopy; Chiu et al, 2012 , Fu et al, 2009 , Fu and Tang, 2010 , Liu et al, 2015 ) to characterize the 3-dimensional (3-D) features of the Schwann cell and vascular networks, which otherwise cannot be easily portrayed by the standard microtome-based histology. We also transplanted the labeled islets with the nestin (the marker of neurovascular stem/progenitor cells; Dore-Duffy et al, 2006 , Mignone et al, 2004 , Treutelaar et al, 2003 ) promoter-driven green fluorescence protein (GFP) expression in the Schwann cells and pericytes ( Alliot et al, 1999 , Clarke et al, 1994 , Frisen et al, 1995 ) to trace their locations and activities in the recipient.…”

Section: Introductionmentioning

confidence: 99%

3-D Imaging Reveals Participation of Donor Islet Schwann Cells and Pericytes in Islet Transplantation and Graft Neurovascular Regeneration

et al. 2015

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The primary cells that participate in islet transplantation are the endocrine cells. However, in the islet microenvironment, the endocrine cells are closely associated with the neurovascular tissues consisting of the Schwann cells and pericytes, which form sheaths/barriers at the islet exterior and interior borders. The two cell types have shown their plasticity in islet injury, but their roles in transplantation remain unclear. In this research, we applied 3-dimensional neurovascular histology with cell tracing to reveal the participation of Schwann cells and pericytes in mouse islet transplantation. Longitudinal studies of the grafts under the kidney capsule identify that the donor Schwann cells and pericytes re-associate with the engrafted islets at the peri-graft and perivascular domains, respectively, indicating their adaptability in transplantation. Based on the morphological proximity and cellular reactivity, we propose that the new islet microenvironment should include the peri-graft Schwann cell sheath and perivascular pericytes as an integral part of the new tissue.

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Perivascular Interstitial Cells of Cajal in Human Colon

Cited by 13 publications

References 51 publications

Enteric Glia: S100, GFAP, and Beyond

Enteric Glia: S100, GFAP, and Beyond

Human pancreatic neuro-insular network in health and fatty infiltration

3-D Imaging Reveals Participation of Donor Islet Schwann Cells and Pericytes in Islet Transplantation and Graft Neurovascular Regeneration

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