Leiden University Scholarly Publications

Chhatta, A.R. (2023)

Novel regenerative therapies for the adaptive immune system: a fundamental and translational investigation to regenerate the thymus and repair T cells

Doctoral Thesis

A proper immune system is essential to fight off pathogens such as viruses, bacteria, and fungi. The immune system also plays a huge role in the protection against cancer, as it can eradicate tumor cells. All immune cells are derived from hematopoietic stem cells (HSC) that undergo differentiation in a highly regulated succession of developmental steps. Each of the cell types from the immune system perform a unique specialized role, and where most of these lineages develop in the bone marrow, the T cells that make part of our adaptive immunity, develop in the thymus within a specialized environment. To achieve this, the development of each of these cell types is regulated by a variety of transcription factors.
In Chapter 2 of this thesis, we reviewed the complexity of one of the important signaling pathways of hematopoietic development, the Wnt pathway. While this serves as an introduction to the fundamental research we performed, it also shines light...Show moreA proper immune system is essential to fight off pathogens such as viruses, bacteria, and fungi. The immune system also plays a huge role in the protection against cancer, as it can eradicate tumor cells. All immune cells are derived from hematopoietic stem cells (HSC) that undergo differentiation in a highly regulated succession of developmental steps. Each of the cell types from the immune system perform a unique specialized role, and where most of these lineages develop in the bone marrow, the T cells that make part of our adaptive immunity, develop in the thymus within a specialized environment. To achieve this, the development of each of these cell types is regulated by a variety of transcription factors.
In Chapter 2 of this thesis, we reviewed the complexity of one of the important signaling pathways of hematopoietic development, the Wnt pathway. While this serves as an introduction to the fundamental research we performed, it also shines light onto potential therapeutic targets within the Wnt pathway. For further study of the Wnt pathway, we generated a novel reporter mouse, which is described in Chapter 3 of this thesis. Here we developed a reporter mouse for the Axin2 gene with the fluorescent tag mTurquoise2 with CRISPR/Cas9 genome editing tools. Based on how the genetic engineering was done to create this reporter mouse, mice that are homozygous for this reporter knock-in are also a functional knockout for Axin2. For proper functional studies, the heterozygous mice should be used.
The Axin2-mTurquoise2 mouse was used in Chapter 4 of this thesis to study Wnt involvement in hematopoiesis and T cell development. We observed an increase of canonical Wnt-signaling in thymocytes from mice that have a loss of Axin2 (Axin2-TQtg/tg mice). This confirms the Wnt dosage effect that was reported previously in literature. Conclusively, these results indicate that Axin2 is required to fine-tune Wnt activity to the levels that are “just right” and cannot be maintained by Wnt activator Axin1 alone.
Chapters 2, 3 and 4 focused on fundamental research on hematopoiesis and T cell development. Chapter 5 is more translational oriented and is an introductory review to thymic regenerative therapies. In Chapter 6 of this thesis, we describe the development of a combined cell and gene therapy effort to regenerate a functional thymus transplant from human Induced Pluripotent Stem Cells (iPSCs). We generated an iPSC-derived thymus by directed differentiation of human iPSCs towards thymic epithelial progenitor cells (TEPCs) using FOXN1, formation of 3-D structures from these cells which we named iPSC-derived TEPCs, or iTEPCs, and transplantation of these organoids into mice that lack a functional thymus. Functionality was demonstrated by reconstitution of functional T cells from iPSC-derived grafts, which was introduced by FOXN1 gene therapy (FOXN1 iTEPCs).
Chapter 7 is the final translational research chapter of this thesis and investigated the use of iPSCs for the modeling of PIDs and the initial steps towards T cell regeneration in SCID patients. This chapter describes the iPSC generation, and its repair to use gene-corrected iPSCs from a RAG2 SCID patient to repair their disrupted immune system. The resulting iPSC model was used for disease modelling and provided novel insights into the T cell development in these RAG2-SCID patients, as we observed developmental blocks at every investigated stage of T cell development. The findings in this chapter also provide a proof-of-principle to treat a variety of SCID patients by utilizing ex vivo cell and gene therapy.
Altogether, this thesis tackles two sides of the same coin: fundamentals of hematopoiesis and T cell development, and regenerative therapies for the immune system. The fundamental tools and findings in this thesis can lead to important insights to find new treatment options or improve existing therapies. Furthermore, we provide the basis for two potential therapies to treat patients with a variety of immune disorders, including DiGeorge Syndrome, SCID, age-related immune deficiencies and (post-transplant) leukemia patients that received ablative therapies.Show less

iPSC

Regenerative Medicine

Cell therapy

Gene therapy

Adaptive immunity

SCID

CRISPR genome editing

T cells

Wnt-signaling

All authors

Chhatta, A.R.

Supervisor

Staal, F.J.T.

Co-supervisor

Mikkers, H.M.M.

Committee

Hoeben, R.C.; Burg, M. van der; Cupedo, T.; Langerak, A.W.

Qualification

Doctor (dr.)

Awarding Institution

Faculty of Medicine, Leiden University Medical Center (LUMC), Leiden University

Date

2023-09-19

ISBN (print)

9789464833393