Alan C. Mullen

Helper T Cell Differentiation Is Controlled by the Cell Cycle

Helper T (Th) cell differentiation is highly regulated by cytokines but initiated by mitogens. By examining gene expression in discrete generations of dividing cells, we have delineated the relationship between proliferation and differentiation. Initial expression of IL-2 is cell cycle-independent, whereas effector cytokine expression is cell cycle-dependent. IFNgamma expression increases in frequency with successive cell cycles, while IL-4 expression requires three cell divisions. Cell cycle progression and cytokine signaling act in concert to relieve epigenetic repression and can be supplanted by agents that hyperacetylate histones and demethylate DNA. Terminally differentiated cells exhibit stable epigenetic modification and cell cycle-independent gene expression. These data reveal a novel mechanism governing Th cell fate that initially integrates proliferative and differentiative signals and subsequently maintains stability of the differentiated state.

Effector and memory CD8 + T cell fate coupled by T-bet and eomesodermin

Two seemingly unrelated hallmarks of memory CD8+ T cells are cytokine-driven proliferative renewal after pathogen clearance and a latent effector program in anticipation of rechallenge. Memory CD8+ T cells and natural killer cells share cytotoxic potential and dependence on the growth factor interleukin 15. We now show that mice with compound mutations of the genes encoding the transcription factors T-bet and eomesodermin were nearly devoid of several lineages dependent on interleukin 15, including memory CD8+ T cells and mature natural killer cells, and that their cells had defective cytotoxic effector programming. Moreover, T-bet and eomesodermin were responsible for inducing enhanced expression of CD122, the receptor specifying interleukin 15 responsiveness. Therefore, these key transcription factors link the long-term renewal of memory CD8+ T cells to their characteristic effector potency.*Note: In the version of this article initially published online, the third sentence of the abstract was incorrect. The correct sentence is as follows: “We now show that mice with compound mutations of the genes encoding the transcription factors T-bet and eomesodermin were nearly devoid of several lineages dependent on interleukin 15, including memory CD8+ T cells and mature natural killer cells, and that their cells had defective cytotoxic effector programming.” The error has been corrected for the HTML and print versions of the article. Additionally, in the print version of this article and the version initially published online, some labels for Tbx21 in Figure 7b are incorrect. This correction has been appended to the PDF version.

Hlx is induced by and genetically interacts with T-bet to promote heritable T H 1 gene induction

Type 1 helper T (TH1) cells are essential for cellular immunity, but their ontogeny, maturation and durability remain poorly understood. By constructing a dominant-negative form of T-bet, we were able to determine the role played by this lineage-inducing trans-activator in the establishment and maintenance of heritable TH1 gene expression. Optimal induction of interferon-γ (IFN-γ) expression required genetic interaction between T-bet and its target, the homeoprotein Hlx. In fully mature TH1 cells, reiteration of IFN-γ expression and stable chromatin remodeling became relatively independent of T-bet activity and coincided with demethylation of DNA. In contrast, some lineage attributes, such as expression of IL-12Rβ2 (interleukin 12 receptor β2), required ongoing T-bet activity in mature TH1 cells and their progeny. These findings suggest that heritable states of gene expression might be maintained by continued expression of the inducing factor or by a mechanism that confers a stable imprint of the induced state.

Divergent transcription of long noncoding RNA/mRNA gene pairs in embryonic stem cells

Many long noncoding RNA (lncRNA) species have been identified in mammalian cells, but the genomic origin and regulation of these molecules in individual cell types is poorly understood. We have generated catalogs of lncRNA species expressed in human and murine embryonic stem cells and mapped their genomic origin. A surprisingly large fraction of these transcripts (>60%) originate from divergent transcription at promoters of active protein-coding genes. The divergently transcribed lncRNA/mRNA gene pairs exhibit coordinated changes in transcription when embryonic stem cells are differentiated into endoderm. Our results reveal that transcription of most lncRNA genes is coordinated with transcription of protein-coding genes.

Gene Silencing Quantitatively Controls the Function of a Developmental trans-Activator

How a single cell gives rise to progeny with differing fates remains poorly understood. We examined cells lacking methyl CpG binding domain protein-2 (MBD2), a molecule that has been proposed to link DNA methylation to silent chromatin. Helper T cells from Mbd2(-/-) mice exhibit disordered differentiation. IL-4, the signature of a restricted set of progeny, is expressed ectopically in Mbd2(-/-) parent and daughter cells. Loss of MBD2-mediated silencing renders the normally essential activator, Gata-3, dispensable for IL-4 induction. Gata-3 and MBD2 act in competition, wherein each factor independently, and quantitatively, regulates the binary choice of whether heritable IL-4 expression is established. Gata-3 functions, in part, to displace MBD2 from methylated DNA. These results suggest that activating and silencing signals integrate to provide spatially and temporally restricted patterns of gene activity.

Structural Analysis of CTLA-4 Function In Vivo

CTLA-4-mediated inhibition of T cell activation may be accomplished by competition for ligands and/or by signals mediated through the intracellular domain. Studies have implicated Tyr201 in the cytoplasmic domain of CTLA-4 in regulating CTLA-4 signal transduction and intracellular trafficking. To investigate the mechanism of CTLA-4 function in vivo, transgenes encoding wild-type CTLA-4 (FL), a mutant lacking the cytoplasmic domain of CTLA-4 (ΔCTLA-4 tail), or a CTLA-4 Tyr201 mutant (Y201V) were introduced into CTLA-4-deficient mice. CTLA-4−/− mice display an autoimmune lymphoproliferative disorder resulting in tissue destruction and early death. When either the FL or the Y201V transgene was bred into CTLA-4−/− animals, a complete rescue from lymphoproliferation and autoimmunity was observed. In contrast, CTLA-4−/− mice expressing the ΔCTLA-4 tail transgene were long lived with no evidence of multiorgan lymphocytic infiltration, but exhibited lymphadenopathy and accumulated large numbers of activated T cells. Furthermore, these animals displayed a Th2-biased phenotype which conferred susceptibility to Leishmania infection. These results indicate that the inhibitory effect of CTLA-4 is mediated in part through the ability of the extracellular domain to compete for ligands. The cytoplasmic domain of CTLA-4, however, is required for complete inhibitory function of the receptor and for regulation of Th cell differentiation in vivo.

Cell cycle controlling the silencing and functioning of mammalian activators

Naïve CD4(+) helper T (T(H)) cells respond to stimulation by terminally differentiating into two mature classes, T(H)1 cells, which express interferon gamma (IFN-gamma), and T(H)2 cells, which express interleukin 4 (IL-4). The transcriptional activators T-bet and Gata-3 mediate commitment to the T(H)1 and T(H)2 fates, respectively, including chromatin remodeling of signature genes. The cytokine IL-12 fosters growth of committed T(H)1 cells, while IL-4 fosters growth of committed T(H)2 cells. IL-12 and IL-4 also play critical roles in commitment by promoting transcriptional silencing of Gata-3 and T-bet, respectively. We now show that both T-bet and Gata-3 are induced in a cell cycle-independent manner in bipotent progenitor cells. In contrast, both lineage-restricted gene induction by the activator proteins and heritable silencing of the transcription of each activator, the hallmarks of terminal differentiation, are cell cycle dependent. We found that cells that cannot cycle remain uncommitted and bipotent in response to the most polarizing signals for maturation. These results provide mechanistic insight into a mammalian model of terminal differentiation by illustrating that cell cycle-coupled epigenetic effects, as originally described in yeast, may represent an evolutionarily conserved strategy for organizing signaling and cell fate.

Long noncoding RNAs expressed in human hepatic stellate cells form networks with extracellular matrix proteins

BackgroundHepatic fibrosis is the underlying cause of cirrhosis and liver failure in nearly every form of chronic liver disease, and hepatic stellate cells (HSCs) are the primary cell type responsible for fibrosis. Long noncoding RNAs (lncRNAs) are increasingly recognized as regulators of development and disease; however, little is known about their expression in human HSCs and their function in hepatic fibrosis.MethodsWe performed RNA sequencing and ab initio assembly of RNA transcripts to define the lncRNAs expressed in human HSC myofibroblasts. We analyzed chromatin immunoprecipitation data and expression data to identify lncRNAs that were regulated by transforming growth factor beta (TGF-β) signaling, associated with super-enhancers and restricted in expression to HSCs compared with 43 human tissues and cell types. Co-expression network analyses were performed to discover functional modules of lncRNAs, and principle component analysis and K-mean clustering were used to compare lncRNA expression in HSCs with other myofibroblast cell types.ResultsWe identified over 3600 lncRNAs that are expressed in human HSC myofibroblasts. Many are regulated by TGF-β, a major fibrotic signal, and form networks with genes encoding key components of the extracellular matrix (ECM), which is the substrate of the fibrotic scar. The lncRNAs directly regulated by TGF-β signaling are also enriched at super-enhancers. More than 400 of the lncRNAs identified in HSCs are uniquely expressed in HSCs compared with 43 other human tissues and cell types and HSC myofibroblasts demonstrate different patterns of lncRNA expression compared with myofibroblasts originating from other tissues. Co-expression analyses identified a subset of lncRNAs that are tightly linked to collagen genes and numerous proteins that regulate the ECM during formation of the fibrotic scar. Finally, we identified lncRNAs that are induced during progression of human liver disease.ConclusionslncRNAs are likely key contributors to the formation and progression of fibrosis in human liver disease.

Hippo Tips the TGF-β Scale in Favor of Pluripotency

How TGF-β signaling switches from enforcing pluripotency to promoting mesendodermal differentiation remains an open question. Recently in Cell Reports, Beyer et al. demonstrated that Hippo signaling components recruit the NuRD complex to repress expression of key genes targeted by TGF-β and thus determine whether TGF-β signaling will favor pluripotency or differentiation.

Helper T cell differentiation and the problem of cellular inheritance

The quality of the helper T cell response against antigen can determine the outcomes of infectious, inflammatory, and autoimmune diseases. Mature Th1 and Th2 cell subsets are thought to arise from acommonaive progenitor. In these precursorcells, effector cytokine genes appear to exist in a restrictive structure, which is determined by methylation of cytosine bases and higher-order structure of chromatin. The restrictive gene structures appear to be plastic, giving way to more active structures in some daughter cells. Some genetic loci, which are active in naive cells, however, become silenced during terminal differen tiation. Both the derepression of silent loci and the silencing of active loci appear to be linked to the process of DNA replication. Future investigation will be directed toward understanding the way in which patterns of gene expression are altered or transmitted during the cell division of helper T lymphocytes.