Artificial thymic organoids represent a reliable tool to study T-cell differentiation in patients with severe T-cell lymphopenia

Bosticardo, Marita; Pala, Francesca; Calzoni, Enrica; Delmonte, Ottavia M.; Dobbs, Kerry; Gardner, Cameron L.; Sacchetti, Nicolò; Kawai, Tomoki; Garabedian, Elizabeth; Draper, Debbie; Bergerson, Jenna; Ravin, Suk See De; Freeman, Alexandra F.; Güngör, Tayfun; Hartog, Nicholas; Holland, Steven M.; Kohn, Donald B.; Malech, Harry L.; Markert, M. Louise; Weinacht, Katja G.; Villa, Anna; Seet, Christopher S.; Montel‐Hagen, Amélie; Notarangelo, Luigi D.

doi:10.1182/bloodadvances.2020001730

Cited by 72 publications

(68 citation statements)

References 20 publications

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“…While there are differences in T-cell development between humans and mice ( 43 – 46 ), the murine model continues to offer fundamental insight into this process and some of these developmental stages have been reproduced during the in vitro differentiation of human hematopoietic stem cells (HSCs) in co-culture systems with Notch ligand-expressing murine stromal cells ( 47 – 49 ). Additionally, novel molecular tools, such as high-throughput RNA sequencing, efficient high-precision genome editing and the possibility to use HSCs and induced pluripotent stem cells (iPSCs) from certain PID patients, are further facilitating the study of human T-cell development in new ex vivo ( 50 – 52 ) and in vivo models ( 53 , 54 ).…”

Section: Thymus Development and Functionmentioning

confidence: 99%

“…We have taken advantage of a monolayer co-culture system of patients’ bone marrow-derived CD34 + cells together with OP9/DL1 stromal cells and growth factors ( 49 ). Recently, two groups reported the use of artificial thymic organoids aggregating DLL4-expressing stromal cell lines (OP9/DLL4 and MS5-hDLL4) to facilitate the differentiation of CD34 + cells, isolated either from the patients’ bone marrow aspirate ( 52 ) or from their peripheral blood ( 131 ). Using these three-dimensional tools, they have shown that CD34 + cells of two cDGS patients, one with a TBX1 mutation and the other with a deletion at chromosome 22q11.2, had the potential to differentiate into CD3 + mature T-cells, in line with their disorder not affecting the HSC.…”

Section: Abnormalities Of Thymic Stromal Development and Functionmentioning

confidence: 99%

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Current and Future Therapeutic Approaches for Thymic Stromal Cell Defects

2021

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Inborn errors of thymic stromal cell development and function lead to impaired T-cell development resulting in a susceptibility to opportunistic infections and autoimmunity. In their most severe form, congenital athymia, these disorders are life-threatening if left untreated. Athymia is rare and is typically associated with complete DiGeorge syndrome, which has multiple genetic and environmental etiologies. It is also found in rare cases of T-cell lymphopenia due to Nude SCID and Otofaciocervical Syndrome type 2, or in the context of genetically undefined defects. This group of disorders cannot be corrected by hematopoietic stem cell transplantation, but upon timely recognition as thymic defects, can successfully be treated by thymus transplantation using cultured postnatal thymic tissue with the generation of naïve T-cells showing a diverse repertoire. Mortality after this treatment usually occurs before immune reconstitution and is mainly associated with infections most often acquired pre-transplantation. In this review, we will discuss the current approaches to the diagnosis and management of thymic stromal cell defects, in particular those resulting in athymia. We will discuss the impact of the expanding implementation of newborn screening for T-cell lymphopenia, in combination with next generation sequencing, as well as the role of novel diagnostic tools distinguishing between hematopoietic and thymic stromal cell defects in facilitating the early consideration for thymus transplantation of an increasing number of patients and disorders. Immune reconstitution after the current treatment is usually incomplete with relatively common inflammatory and autoimmune complications, emphasizing the importance for improving strategies for thymus replacement therapy by optimizing the current use of postnatal thymus tissue and developing new approaches using engineered thymus tissue.

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Section: Thymus Development and Functionmentioning

confidence: 99%

Section: Abnormalities Of Thymic Stromal Development and Functionmentioning

confidence: 99%

Current and Future Therapeutic Approaches for Thymic Stromal Cell Defects

2021

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“…TEC-like progenitors appropriate for this purpose have also been generated by direct conversion of embryonic fibroblasts by induced expression of the TEC transcription factor FOXN1 [ 253 ], as well as inducing TECs from embryonic ctem cells or iPS cells from both mouse and human [ 92 – 94 , 254 ]. Although the efficacy of ATOs have not yet been extensively evaluated in the setting of regeneration outside of mice, ATOs have recently been used to great effect to distinguish hematopoietic from intrinsic thymic defects in pediatric immunodeficiencies; thereby identifying patients with DGS that would be candidates for thymus transplant [ 190 ].…”

Section: Repairing the Thymus In Settings Of Acute And Chronic Injurymentioning

confidence: 99%

Dynamics of thymus function and T cell receptor repertoire breadth in health and disease

et al. 2021

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T cell recognition of unknown antigens relies on the tremendous diversity of the T cell receptor (TCR) repertoire; generation of which can only occur in the thymus. TCR repertoire breadth is thus critical for not only coordinating the adaptive response against pathogens but also for mounting a response against malignancies. However, thymic function is exquisitely sensitive to negative stimuli, which can come in the form of acute insult, such as that caused by stress, infection, or common cancer therapies; or chronic damage such as the progressive decline in thymic function with age. Whether it be prolonged T cell deficiency after hematopoietic cell transplantation (HCT) or constriction in the breadth of the peripheral TCR repertoire with age; these insults result in poor adaptive immune responses. In this review, we will discuss the importance of thymic function for generation of the TCR repertoire and how acute and chronic thymic damage influences immune health. We will also discuss methods that are used to measure thymic function in patients and strategies that have been developed to boost thymic function.

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“…T cell lymphopaenia may mistakenly be ascribed to an undefined haematopoietic defect and a thymic aetiology only suspected after absent immune reconstitution post-HSCT. Novel tools are emerging to facilitate the distinction of primary haematopoietic defects from inborn errors of thymic stromal cells in patients presenting with genetically undefined severe T cell lymphopaenia [ 126 , 129 , 146 , 147 ]. These include the use of artificial thymic organoids that express DLL4 and can therefore support the differentiation of CD34 + haematopoietic stem cells (HSCs) into mature T cells [ 146 , 147 ].…”

Section: Diagnosis Of Inborn Errors Of Thymic Stromal Cell Developmenmentioning

confidence: 99%

“…Novel tools are emerging to facilitate the distinction of primary haematopoietic defects from inborn errors of thymic stromal cells in patients presenting with genetically undefined severe T cell lymphopaenia [ 126 , 129 , 146 , 147 ]. These include the use of artificial thymic organoids that express DLL4 and can therefore support the differentiation of CD34 + haematopoietic stem cells (HSCs) into mature T cells [ 146 , 147 ]. In principle, HSCs from patients with thymic stromal cell defects should be able to generate mature T cells, whereas the T cell differentiation capacity of HSCs derived from patients with haematopoietic defects is generally expected to be impaired, although there may be exceptions as has been seen for adenosine deaminase deficiency [ 146 , 147 ].…”

Section: Diagnosis Of Inborn Errors Of Thymic Stromal Cell Developmenmentioning

confidence: 99%

Inborn errors of thymic stromal cell development and function

2020

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As the primary site for T cell development, the thymus is responsible for the production and selection of a functional, yet self-tolerant T cell repertoire. This critically depends on thymic stromal cells, derived from the pharyngeal apparatus during embryogenesis. Thymic epithelial cells, mesenchymal and vascular elements together form the unique and highly specialised microenvironment required to support all aspects of thymopoiesis and T cell central tolerance induction. Although rare, inborn errors of thymic stromal cells constitute a clinically important group of conditions because their immunological consequences, which include autoimmune disease and T cell immunodeficiency, can be life-threatening if unrecognised and untreated. In this review, we describe the molecular and environmental aetiologies of the thymic stromal cell defects known to cause disease in humans, placing particular emphasis on those with a propensity to cause thymic hypoplasia or aplasia and consequently severe congenital immunodeficiency. We discuss the principles underpinning their diagnosis and management, including the use of novel tools to aid in their identification and strategies for curative treatment, principally transplantation of allogeneic thymus tissue.

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Artificial thymic organoids represent a reliable tool to study T-cell differentiation in patients with severe T-cell lymphopenia

Cited by 72 publications

References 20 publications

Current and Future Therapeutic Approaches for Thymic Stromal Cell Defects

Current and Future Therapeutic Approaches for Thymic Stromal Cell Defects

Dynamics of thymus function and T cell receptor repertoire breadth in health and disease

Inborn errors of thymic stromal cell development and function

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