Emerging of a new CD3+CD31HCD184+ tang cell phenothype in Sjögren’s syndrome induced by microencapsulated human umbilical cord matrix-derived multipotent stromal cells

Background Sjögren’s syndrome (SS) is an autoimmune disease hallmarked by infiltration and destruction of exocrine glands. Currently, there is no therapy that warrants full recovery of the affected tissues. Umbilical cord-derived multipotent stromal cells, microincapsulated in an endotoxin-free alginate gel (CpS-hUCMS), were shown to modulate the inflammatory activity of PBMCs in SS patients in vitro, through release of soluble factors (TGFβ1, IDO1, IL6, PGE2, VEGF). These observations led us to set up the present study, aimed at defining the in vitro effects of CpS-hUCMS on pro- and anti-inflammatory lymphocyte subsets involved in the pathogenesis of SS. Methods and results Peripheral blood mononuclear cells (PBMCs) upon collection from SS patients and matched healthy donors, were placed in co-culture with CpS-hUCMS for five days. Cellular proliferation and T- (Tang, Treg) and B- (Breg, CD19+) lymphocyte subsets were studied by flow cytometry, while Multiplex, Real-Time PCR, and Western Blotting techniques were employed for the analysis of transcriptome and secretome. IFNγ pre-treated hUCMS were assessed with a viability assay and Western Blotting analysis before co-culture. After five days co-culture, CpS-hUCMS induced multiple effects on PBMCs, with special regard to decrease of lymphocyte proliferation, increase of regulatory B cells and induction of an angiogenic T cell population with high expression of the surface marker CD31, that had never been described before in the literature. Conclusion We preliminarily showed that CpS-hUCMS can influence multiple pro- and anti-inflammatory pathways that are deranged in SS. In particular, Breg raised and a new Tang phenothype CD3+CD31HCD184+ emerged. These results may considerably expand our knowledge on multipotent stromal cell properties and may open new therapeutic avenues for the management of this disease, by designing ad hoc clinical studies.

[1]  D. Francisci,et al.  Microencapsulated Wharton Jelly-derived adult mesenchymal stem cells as a potential new therapeutic tool for patients with COVID-19 disease: an in vitro study. , 2021, American journal of stem cells.

[2]  J. Tao,et al.  Circulating senescent angiogenic T cells are linked with endothelial dysfunction and systemic inflammation in hypertension , 2020, Journal of hypertension.

[3]  R. Calafiore,et al.  Microencapsulation of cells and molecular therapy of type 1 diabetes mellitus: The actual state and future perspectives between promise and progress , 2020, Journal of diabetes investigation.

[4]  Wenshan Lin,et al.  Clinical Efficacy and Safety of Mesenchymal Stem Cells for Systemic Lupus Erythematosus , 2020, Stem cells international.

[5]  Bella S Guerrouahen,et al.  Enhancing Mesenchymal Stromal Cell Immunomodulation for Treating Conditions Influenced by the Immune System , 2019, Stem cells international.

[6]  A. Alunno,et al.  Remission of hyperglycemia in spontaneously diabetic NOD mice upon transplant of microencapsulated human umbilical cord Wharton jelly‐derived mesenchymal stem cells (hUCMS) , 2018, Xenotransplantation.

[7]  David M. Schauder,et al.  Frontline Science: PECAM‐1 (CD31) expression in naïve and memory, but not acutely activated, CD8+ T cells , 2018, Journal of leukocyte biology.

[8]  J. Hua,et al.  Interactions between mesenchymal stem cells and the immune system , 2017, Cellular and Molecular Life Sciences.

[9]  L. Criswell,et al.  2016 American College of Rheumatology/European League Against Rheumatism Classification Criteria for Primary Sjögren's Syndrome: A Consensus and Data‐Driven Methodology Involving Three International Patient Cohorts , 2017, Arthritis & rheumatology.

[10]  S. Della Bella,et al.  Editorial: Senescent angiogenic T cells: the use of CD28 makes the difference in endothelial homeostasis , 2016, Journal of leukocyte biology.

[11]  L. Caminal-Montero,et al.  Senescent profile of angiogenic T cells from systemic lupus erythematosus patients , 2016, Journal of leukocyte biology.

[12]  V. Bini,et al.  Restoration of t cell substes of patients with type 1 diabetes mellitus by microencapsulated human umbilical cord Wharton jelly-derived mesenchymal stem cells: An in vitro study. , 2016, Clinical immunology.

[13]  G. Papp,et al.  A comprehensive investigation on the distribution of circulating follicular T helper cells and B cell subsets in primary Sjögren's syndrome and systemic lupus erythematosus , 2016, Clinical and experimental immunology.

[14]  Trevor Coward,et al.  An In-Vitro Study , 2016 .

[15]  M. Falasca,et al.  CD31 signals confer immune privilege to the vascular endothelium , 2015, Proceedings of the National Academy of Sciences.

[16]  J. Pers,et al.  B-Cells induce regulatory T cells through TGF-β/IDO production in A CTLA-4 dependent manner. , 2015, Journal of autoimmunity.

[17]  E. Rosser,et al.  Regulatory B cells: origin, phenotype, and function. , 2015, Immunity.

[18]  A. Khodadadi,et al.  Three-dimensional differentiation of adipose-derived mesenchymal stem cells into insulin-producing cells , 2015, Cell and Tissue Research.

[19]  L. Boon,et al.  Human Adipose Tissue‐Derived Mesenchymal Stem Cells Abrogate Plasmablast Formation and Induce Regulatory B Cells Independently of T Helper Cells , 2015, Stem cells.

[20]  R. Gerli,et al.  Characterization of circulating endothelial microparticles and endothelial progenitor cells in primary Sjögren's syndrome: new markers of chronic endothelial damage? , 2015, Rheumatology.

[21]  P. López,et al.  Angiogenic T cells are decreased in rheumatoid arthritis patients , 2014, Annals of the rheumatic diseases.

[22]  V. Bini,et al.  In vitro immunomodulatory effects of microencapsulated umbilical cord Wharton jelly-derived mesenchymal stem cells in primary Sjögren's syndrome. , 2015, Rheumatology.

[23]  J. Tabarkiewicz,et al.  A Modified Method of Insulin Producing Cells' Generation from Bone Marrow-Derived Mesenchymal Stem Cells , 2014, Journal of diabetes research.

[24]  Simon A. Jones,et al.  Regulatory B cells are induced by gut microbiota–driven interleukin-1β and interleukin-6 production , 2014, Nature Medicine.

[25]  M. Iadarola,et al.  Primary Sjögren's Syndrome Is Characterized by Distinct Phenotypic and Transcriptional Profiles of IgD+ Unswitched Memory B Cells , 2014, Arthritis & rheumatology.

[26]  Fengchun Zhang,et al.  B cell subsets and dysfunction of regulatory B cells in IgG4-related diseases and primary Sjögren’s syndrome: the similarities and differences , 2014, Arthritis Research & Therapy.

[27]  J. Coward,et al.  Interleukin-6: an angiogenic target in solid tumours. , 2014, Critical reviews in oncology/hematology.

[28]  M. Kloc,et al.  Insulin-Producing Cells from Adult Human Bone Marrow Mesenchymal Stem Cells Control Streptozotocin-Induced Diabetes in Nude Mice , 2013, Cell transplantation.

[29]  R. Rouhl,et al.  Angiogenic T-Cells and Putative Endothelial Progenitor Cells in Hypertension-Related Cerebral Small Vessel Disease , 2012, Stroke.

[30]  Francesca Di Giovanni,et al.  New simple and rapid method for purification of mesenchymal stem cells from the human umbilical cord Wharton jelly. , 2011, Tissue engineering. Part A.

[31]  D. Isenberg,et al.  CD19(+)CD24(hi)CD38(hi) B cells exhibit regulatory capacity in healthy individuals but are functionally impaired in systemic Lupus Erythematosus patients. , 2010, Immunity.

[32]  G. Illei,et al.  Pathogenesis of Sjögren's syndrome , 2009, Current opinion in rheumatology.

[33]  N. Rouas-Freiss,et al.  HLA-G is a Crucial Immunosuppressive Molecule Secreted by Adult Human Mesenchymal Stem Cells , 2009, Transplantation.

[34]  AbigailWoodfin,et al.  PECAM-1: A Multi-Functional Molecule in Inflammation and Vascular Biology , 2007 .

[35]  S. Nourshargh,et al.  PECAM-1: a multi-functional molecule in inflammation and vascular biology. , 2007, Arteriosclerosis, thrombosis, and vascular biology.

[36]  Ju-Young Kim,et al.  Identification of a Novel Role of T Cells in Postnatal Vasculogenesis: Characterization of Endothelial Progenitor Cell Colonies , 2007, Circulation.

[37]  D. Rawlings,et al.  Novel Suppressive Function of Transitional 2 B Cells in Experimental Arthritis1 , 2007, The Journal of Immunology.

[38]  X. Hou,et al.  Differentiation of bone marrow-derived mesenchymal stem cells from diabetic patients into insulin-producing cells in vitro. , 2007, Chinese medical journal.

[39]  P. Brunetti,et al.  Standard technical procedures for microencapsulation of human islets for graft into nonimmunosuppressed patients with type 1 diabetes mellitus. , 2006, Transplantation proceedings.

[40]  Giovanni Luca,et al.  Microencapsulated pancreatic islet allografts into nonimmunosuppressed patients with type 1 diabetes: first two cases. , 2006, Diabetes care.

[41]  Gudrun Wacker Similarities and Differences , 2005 .

[42]  R. Fox,et al.  Approaches to the treatment of Sjögren's syndrome. , 2000, The Journal of rheumatology. Supplement.

[43]  S. Akira,et al.  Interleukin-6 in biology and medicine. , 1993, Advances in immunology.

[44]  D. Connolly,et al.  Vascular permeability factor, an endothelial cell mitogen related to PDGF. , 1989, Science.

[45]  D. Connolly,et al.  Tumor vascular permeability factor stimulates endothelial cell growth and angiogenesis. , 1989, The Journal of clinical investigation.