Messenger RNA-associated protein drives multiple paths in T-cell development, study finds
RNA is both the bridge between DNA and the production of proteins that carry out the functions of life and what guides which and how much protein gets made. As messenger RNA (mRNA) is transcribed from DNA to carry genetic information out of the nucleus, segments that don't code for actual proteins need to be removed from the RNA strand and the remaining pieces spliced together. Different pieces of the expressed gene (exons) are cut out, and these sections are joined together to form the final mRNA strand. Cells gain their ability to produce proteins with various functions by using variations of this splicing.
The lab of Kristen Lynch, PhD, a professor of in the departments of Biochemistry & Biophysics and Genetics, at the Perelman School of Medicine at the University of Pennsylvania, studies how this splicing occurs in T cells and how it is regulated by multiple proteins. A new study published in the Proceedings of the National Academy of Sciences from her lab describes a cascade of events that may explain changes in gene expression that occur during the development of the human immune system.
"An understanding of the patterns and mechanisms of alternative splicing is essential for a full comprehension how the genome is interpreted under different conditions to affect protein function," says Lynch.
Alternative splicing is a key mechanism for gene regulation that is regulated in response to developmental and antigen signaling in T cells. However, the extent and mechanisms of regulated splicing, particularly during T-cell development, have not been well characterized. T cells need all kinds of new proteins to go through the necessary alterations to fight infections or mature. The cells do this two ways: turn new genes on to produce new proteins or change how mRNA is spliced together to get different forms of the same proteins. These two mechanisms can work separately or together in a cell.
The team demonstrated that the expression of an RNA binding protein called CELF2 is increased in response to T-cell stimulation such as occurs in response to circulating antigens from foreign microbes or tumors. For example, T cells go through changes that ramp up division and proliferation and express gene products such as cytokines to help fight infections. The increase in CELF2 expression drives widespread changes in mRNA splicing in cultured T cells and correlates with changes in mRNA splicing during T-cell development, which occurs in the thymus.
Using next-generation sequencing, they catalogued the splicing pattern of 5,000 exons and looked for the changes in pattern in stimulated versus unstimulated T cells to see how the overall complement of proteins made had changed. These differences in splicing can lead to physiologically important changes in proteins such as activity, whether the protein functions in the nucleus or the cytoplasm, or which other molecules it can interact with.
"We believe that this paper is the first to catalogue splicing changes during T cell development," says Lynch. "The take-home message is that the increase in CELF2 expression drives a large proportion of splicing changes that occur during T cell activation and also T cell development in the thymus when we are young. These results provide unprecedented insight into the regulation of splicing during thymic development and reveal an important biologic role of CELF2 in human T cells."