Cell Competition, the Kinetics of Thymopoiesis, and Thymus Cellularity Are Regulated by Double-Negative 2 to 3 Early Thymocytes.

Cell competition in the thymus is a homeostatic process that drives turnover. If the process is impaired, thymopoiesis can be autonomously maintained for several weeks, but this causes leukemia. We aimed to understand the effect of cell competition on thymopoiesis, identify the cells involved, and determine how the process is regulated. Using thymus transplantation experiments, we found that cell competition occurs within the double-negative 2 (DN2) and 3 early (DN3e) thymocytes and inhibits thymus autonomy. Furthermore, the expansion of DN2b is regulated by a negative feedback loop that is imposed by double-positive thymocytes and determines the kinetics of thymopoiesis. This feedback loop affects the cell cycle duration of DN2b, in a response controlled by interleukin 7 availability. Altogether, we show that thymocytes do not merely follow a pre-determined path if provided with the correct signals. Instead, thymopoiesis dynamically integrates cell-autonomous and non-cell-autonomous aspects that fine-tune normal thymus function.

T Cell Acute Lymphoblastic Leukemia as a Consequence of Thymus Autonomy.

Thymus autonomy is the capacity of the thymus to maintain T lymphocyte development and export independently of bone marrow contribution. Prolonging thymus autonomy was shown to be permissive to the development of T cell acute lymphoblastic leukemia (T-ALL), similar to the human disease. In this study, performing thymus transplantation experiments in mice, we report that thymus autonomy can occur in several experimental conditions, and all are permissive to T-ALL. We show that wild type thymi maintain their function of T lymphocyte production upon transplantation into recipients with several genotypes (and corresponding phenotypic differences), i.e., Rag2 - / - γc - / -, γc - / -, Rag2 - / - IL-7rα - / -, and IL-7rα - / - We found that the cellularity of the thymus grafts is influenced exclusively by the genotype of the host, i.e., IL-7rα-/- versus γc -/- Nonetheless, the difference in cellularity detected in thymus autonomy bore no impact on onset, incidence, immunophenotype, or pathologic condition of T-ALL. In all tested conditions, T-ALL reached an incidence of 80%, demonstrating that thymus autonomy bears a high risk of leukemia. We also analyzed the microbiota composition of the recipients and their genetic background, but none of the differences found influenced the development of T-ALL. Taken together, our data support that IL-7 drives cellular turnover non-cell autonomously, which is required for prevention of T-ALL. We found no influence for T-ALL in the specific combination of the genotypic mutations tested (including the developmental block caused by Rag deficiency), in microbiota composition, or minor differences in the genetic background of the strains.

Cell competition, apoptosis and tumour development.

The phenomenon of cell competition is an interactive process originally discovered in the imaginal discs of Drosophila; it is a developmental mechanism that identifies and eliminates cells that are weaker than their neighbours or have features that make them different or not well adapted to their surroundings. It appears to be an important homeostatic mechanism to contribute to the general fitness of developing tissues. Here we discuss some of the basic features of cell competition and then focus on results indicating that cell competition is responsible for the removal of malignant or aberrant cells that may appear during development, although in certain circumstances it can revert its role to promote tumour growth. We also consider several recent studies that indicate that cell competition also occurs in vertebrates where it performs similar functions.