Germline Transcription Research Articles

Duality of Enhancer Functioning Mode Revealed in a Reduced TCRβ Gene Enhancer Knockin Mouse Model

The TCRbeta gene enhancer (Ebeta) commands TCRbeta gene expression through the lifespan of T lymphocytes. Genetic and molecular studies have implied that in early thymocytes, Ebeta directs chromatin opening over the Dbeta-Jbeta-Cbeta domains and triggers initial Dbeta-Jbeta recombination. In mature T cells, Ebeta is required for expression of the assembled TCRbeta gene. Whether these separate activities rely on distinct Ebeta regulatory sequences and involve differing modes of activation is unclear. Using gene targeting in mouse embryonic stem cells, we replaced Ebeta by a conserved core fragment (Ebeta169). We found that Ebeta169-carrying alleles were capable of sustaining beta gene expression and the development of mature T cells in homozygous knockin mice. Surprisingly, these procedures and underlying molecular transactions were affected to a wide range of degrees depending on the developmental stage. Early thymocytes barely achieved Dbeta-Jbeta germline transcription and recombination. In contrast, T cells displayed substantial though heterogeneous levels of VDJ-rearranged TCRbeta gene expression. Our results have implications regarding enhancer function in cells of the adaptive immune system and, potentially, TCRbeta gene recombination and allelic exclusion.

Distinct roles for E12 and E47 in B cell specification and the sequential rearrangement of immunoglobulin light chain loci

The E2A gene products, E12 and E47, are critical regulators of B cell development. However, it remains elusive whether E12 and E47 have overlapping and/or distinct functions during B lymphopoiesis. We have generated mice deficient for either E12 or E47 and examined their roles in B cell maturation. We show that E47 is essential for developmental progression at the prepro–B cell stage, whereas E12 is dispensable for early B cell development, commitment, and maintenance. In contrast, both E12 and E47 play critical roles in pre–B and immature B cells to promote immunoglobulin λ (Igλ) germline transcription as well as Igλ VJ gene rearrangement. Furthermore, we show that E12 as well as E47 is required to promote receptor editing upon exposure to self-antigen. We demonstrate that increasing levels of E12 and E47 act to induce Igλ germline transcription, promote trimethylated lysine 4 on histone 3 (H3) as well as H3 acetylation across the Jλ region, and activate Igλ VJ gene rearrangement. We propose that in the pre–B and immature B cell compartments, gradients of E12 and E47 activities are established to mechanistically regulate the sequential rearrangement of the Ig light chain genes.

Partitioning the C. elegans genome by nucleosome modification, occupancy, and positioning

We have characterized two post-translational histone modifications in Caenorhabditis elegans on a genomic scale. Micrococcal nuclease digestion and immunoprecipitation were used to obtain distinct populations of single nucleosome cores, which were analyzed using massively parallel DNA sequencing to obtain positional and coverage maps. Two methylated histone H3 populations were chosen for comparison: H3K4 histone methylation (associated with active chromosomal regions) and H3K9 histone methylation (associated with inactivity). From analysis of the sequence data, we found nucleosome cores with these modifications to be enriched in two distinct partitions of the genome; H3K4 methylation was particularly prevalent in promoter regions of widely expressed genes, while H3K9 methylation was enriched on specific chromosomal arms. For each of the six chromosomes, the highest level of H3K9 methylation corresponds to the pairing center responsible for chromosome alignment during meiosis. Enrichment of H3K9 methylation at pairing centers appears to be an early mark in meiotic chromosome sorting, occurring in the absence of components required for proper pairing of homologous chromosomes. H3K9 methylation shows an intricate pattern within the chromosome arms with a particular anticorrelation to regions that display a strong approximately 10.5 bp periodicity of AA/TT dinucleotides that is known to associate with germline transcription. By contrast to the global features observed with H3K9 methylation, H3K4 methylation profiles were most striking in their local characteristics around promoters, providing a unique promoter-central landmark for 3,903 C. elegans genes and allowing a precise analysis of nucleosome positioning in the context of transcriptional initiation.

Activation of the mouse TCR enhancers by STAT5

The IL-7R controls local accessibility of joining (J) gamma gene segments in the mouse TCRgamma locus by recruiting signal transducers and activators of transcription (STAT) 5 and transcriptional coactivators to the Jgamma germ line promoters and inducing histone acetylation and germ line transcription. Because STAT consensus motifs are conserved not only in the Jgamma promoters but also in the TCRgamma 3' enhancer (Egamma) elements, it is possible that STAT5 interacts with and activates Egamma. To address this question, we first showed that the lysine 4 residue of histone H3 is substantially methylated at Egamma1 and Egamma4 elements in wild-type early thymocytes and that the levels of the methylation are reduced in IL-7R alpha chain-deficient mice. We also showed that STAT5 has potential to elevate histone acetylation of the Egamma elements in a cytokine-dependent cell line by cytokine stimulation. Next, we demonstrated that STAT5 is recruited to the STAT consensus motifs in the Egamma elements after cytokine stimulation and that transcription factors Runt-related (Runx) and c-Myb are constitutively recruited to Egamma. Furthermore, we showed that STAT5 augments basal Egamma activity controlled by Runx and c-Myb. These results suggest that STAT5 is recruited to the consensus motifs in the Egamma elements by cytokine stimulation and augments basal Egamma activity independent of Runx and c-Myb. Therefore, this study implies that the Egamma elements might be activated in two successive steps, first by Runx and c-Myb and next by STAT5.

S region sequence, RNA polymerase II, and histone modifications create chromatin accessibility during class switch recombination

Immunoglobulin class switch recombination is governed by long-range interactions between enhancers and germline transcript promoters to activate transcription and modulate chromatin accessibility to activation-induced cytidine deaminase (AID). However, mechanisms leading to the differential targeting of AID to switch (S) regions but not to constant (CH) regions remain unclear. We show that S and CH regions are dynamically modified with histone marks that are associated with active and repressed chromatin states, respectively. Chromatin accessibility is superimposable with the activating histone modifications, which extend throughout S regions irrespective of length. High density elongating RNA polymerase II (RNAP II) is detected in S regions, suggesting that the transcription machinery has paused and stalling is abolished by deletion of the S region. We propose that RNAP II enrichment facilitates recruitment of histone modifiers to generate accessibility. Thus, the histone methylation pattern produced by transcription localizes accessible chromatin to S regions, thereby focusing AID attack.

Promoter activity 5′ of Dβ2 is coordinated by E47, Runx1, and GATA-3

V(D)J recombination involves the stepwise assembly of B and T cell receptor genes as lymphocytes progress through the early stages of development. While the mechanisms that restrict each step in recombination to its appropriate developmental stage are largely unknown, they share many of the components that regulate transcription. For example, enhancer-dependent modifications in histone acetylation and methylation are essential for both germline transcription and rearrangement of antigen receptor genes. Promoters positioned proximal to individual D and J gene segments in Tcra, Tcrb, Tcrd, IgH, and Igk also contribute to antigen receptor gene assembly, though their effects appear more localized than those of enhancers. Tcrb assembly initiates with D-to-J joining at each of the two D–J–C gene segment clusters in DN1/2 thymocytes. DJ joints are fused with Vβ elements to complete Tcrb recombination in DN3 cells. We have previously shown that Dβ2 is flanked by upstream and downstream promoters, with the 5′ promoter being held inactive until D-to-J recombination deletes the NFκB-dependent 3′ promoter. We now report that activity of the 5′ promoter reflects a complex interplay among Runx1, GATA-3, and E47 transcription factors. In particular, while multiple E47 and Runx1 binding sites clustered near the Dβ2 5′RS and overlapping inr elements define the core 5′PDβ2, they act in concert with an array of upstream GATA-3 sites to overcome the inhibitory effects of a 110bp distal polypurine·polypyrimidine (R·Y) tract. The dependence of 5′PDβ2 on E47 is consistent with the reported role of E proteins in post-DN1 thymocyte development and V-to-DJβ recombination.

Transmembrane activator, calcium modulator, and cyclophilin ligand interactor drives plasma cell differentiation in LPS-activated B cells

Transmembrane activator, calcium modulator, and cyclophilin ligand interactor (TACI) expression on B cells is upregulated by Toll-like receptor (TLR) 4. We sought to examine whether TACI synergizes with TLR4 in driving immunoglobulin production by B cells and to examine the mechanism of this synergy. Purified mouse naive B cells were stimulated with the TACI ligand a proliferation-inducing ligand (APRIL) and with suboptimal concentrations of the TLR4 ligand LPS in the presence or absence of IL-4. Immunoglobulin secretion was measured by means of ELISA. Surface IgG1-positive B cells and CD138+ plasmacytoid cells were enumerated by means of FACS. Expression of gamma1 and epsilon germline transcripts, activation-induced cytidine deaminase, and gamma1 and epsilon mature transcripts was measured by means of RT-PCR. APRIL synergized with LPS in driving B-cell proliferation and IgM, IgG1, IgG3, IgE, and IgA production. This was mediated by TACI because it was preserved in B-cell maturation antigen-/-, but not TACI-/-, B cells. APRIL and LPS synergized to promote isotype switching, as evidenced by increased expression of activation-induced cytidine deaminase and gamma1 and epsilon mature transcripts and generation of surface IgG1-positive cells. More importantly, APRIL and LPS strongly synergized to drive the plasma cell differentiation program, as evidenced by an increase in CD138+ cells and expression of B lymphocyte induced maturation protein-1 (Blimp-1), interferon regulatory factor-4 (IRF-4), and the spliced form of X-box binding protein-1 (XBP-1). TACI-/- mice had impaired IgM and IgG1 antibody responses to immunization, with a suboptimal dose of the type I T cell-independent antigen 2, 4, 6- Trinitrophenol (TNP)-LPS. These observations suggest that TACI cooperates with TLR4 to drive B-cell differentiation and immunoglobulin production in vitro and in vivo.

Incomplete T-cell receptor–β peptides target the mitochondrion and induce apoptosis

AbstractThe default pathway of cell-surface T-cell receptor (TCR) complex formation, and the subsequent transport to the membrane, is thought to entail endoplasmic reticulum (ER) localization followed by proteasome degradation of the unassembled chains. We show herein an alternative pathway: short, incomplete peptide versions of TCRβ naturally occur in the thymus. Such peptides, which have minimally lost the leader sequence or have been massively truncated, leaving only the very C terminus intact, are sorted preferentially to the mitochondrion. As a consequence of the mitochondrial localization, apoptotic cell death is induced. Structure function analysis showed that both the specific localization and induction of apoptosis depend on the transmembrane domain (TMD) and associated residues at the COOH-terminus of TCR. Truncated forms of TCR, such as the short peptides that we detected in the thymus, may be products of protein degradation within thymocytes. Alternatively, they may occur through the translation of truncated mRNAs resulting from unfruitful rearrangement or from germline transcription. It is proposed that mitochondria serve as a subcellular sequestration site for incomplete TCR molecules.

Single Nucleotide Changes in the Human Iγ1 and Ιγ4 Promoters Underlie Different Transcriptional Responses to CD40

Analysis of subclass-specific germline transcription in activated peripheral B cells revealed a highly biased expression pattern of the four Igamma transcripts to signals through CD40 and IL-4. This difference was most pronounced when comparing the profile of Igamma1 and Igamma4 transcripts and was not expected given the very high degree of sequence conservation between promoters. In this report, the influence of sequence differences on the regulation of the Igamma1 and Igamma4 promoters has been investigated given the highly muted transcriptional activity of the Igamma4 promoter. Two regions were analyzed where single nucleotide differences corresponded to major changes in transcriptional activity. These regions were the previously defined CD40 response region containing three putative NF-kappaB-binding sites and the downstream 36-bp region containing CREB/activating transcription factor and kappaB6 sites. Mutation of a single nucleotide at position 6 within the Igamma4 kappaB6 site increased promoter activity to approximately 50% of the activity of the Igamma1 promoter. Furthermore, elevated promoter strength corresponded with increased binding of p50, p65, c-Rel, RelB, and p300 proteins to a level comparable with that of Igamma1. Minor nucleotide changes to both the Igamma4 CD40 response region and the 36-bp element resulted in a response undistinguishable from an Igamma1 response, suggesting cooperation between the two regulatory regions for optimal transcriptional activity. Collectively, these mutational analyses suggest that minor sequence differences contribute to the composition and affinity of transcriptional protein complexes regulating subclass-specific germline transcription, which in part impacts the overall level of class switch recombination to targeted C(H) regions.

The Epigenetic Profile of Ig Genes Is Dynamically Regulated during B Cell Differentiation and Is Modulated by Pre-B Cell Receptor Signaling

Ag receptor loci poised for V(D)J rearrangement undergo germline transcription (GT) of unrearranged genes, and the accessible gene segments are associated with posttranslational modifications (PTM) on histones. In this study, we performed a comprehensive analysis of the dynamic changes of four PTM throughout B and T cell differentiation in freshly isolated ex vivo cells. Methylation of lysines 4 and 79 of histone H3, and acetylation of H3, demonstrated stage and lineage specificity, and were most pronounced at the J segments of loci poised for, or undergoing, rearrangement, except for dimethylation of H3K4, which was more equally distributed on V, D, and J genes. Focusing on the IgL loci, we demonstrated there are no active PTM in the absence of pre-BCR signaling. The kappa locus GT and PTM on Jkappa genes are rapidly induced following pre-BCR signaling in large pre-B cells. In contrast, the lambda locus shows greatly delayed onset of GT and PTM, which do not reach high levels until the immature B cell compartment, the stage at which receptor editing is initiated. Analysis of MiEkappa(-/-) mice shows that this enhancer plays a key role in inducing not only GT, but PTM. Using an inducible pre-B cell line, we demonstrate that active PTM on Jkappa genes occur after GT is initiated, indicating that histone PTM do not make the Jkappa region accessible, but conversely, GT may play a role in adding PTM. Our data indicate that the epigenetic profile of IgL genes is dramatically modulated by pre-BCR signaling and B cell differentiation status.

Biallelic, ubiquitous transcription from the distal germline Igκ locus promoter during B cell development

Allelic exclusion of Ig gene expression is necessary to limit the number of functional receptors to one per B cell. The mechanism underlying allelic exclusion is unknown. Because germline transcription of Ig and TCR loci is tightly correlated with rearrangement, we created two novel knock-in mice that report transcriptional activity of the Jkappa germline promoters in the Igkappa locus. Analysis of these mice revealed that germline transcription is biallelic and occurs in all pre-B cells. Moreover, we found that the two germline promoters in this region are not equivalent but that the distal promoter accounts for the vast majority of observed germline transcript in pre-B cells while the activity of the proximal promoter increases later in development. Allelic exclusion of the Igkappa locus thus occurs at the level of rearrangement, but not germline transcription.

A reappraisal of evidence for probabilistic models of allelic exclusion

B cell development requires the coordinated rearrangement of Ig heavy (IgH) and light chain loci (IgL). Most mature B cells express a single B cell receptor of unique specificity, and a central question in immunology concerns the mechanisms that prevent the productive rearrangement of >1 IgH and IgL allele per cell. Probabilistic models of allelic exclusion maintain that simultaneous rearrangement of both alleles is rare, because the likelihood of undergoing rearrangement is low for a given Ig allele. Strong support for this idea came from studies in which a GFP marker was inserted into the Igk locus. In this system, the probability of high-level germ-line transcription and subsequent locus rearrangement appeared to be low in pre-B cells. Readdressing the validity of GFP expression as a reporter for the level of germ-line transcription, we found a striking discordance between GFP transcript and protein levels at the pre-B cell stage, which is explained at least in part by the developmentally regulated usage of 2 alternative Igk-J germ-line promoters. These results question the validity of the kappa-GFP system as evidence for probabilistic models of allelic exclusion.

Andolast Acts at Different Cellular Levels to Inhibit Immunoglobulin E Synthesis

The anti-asthmatic agent andolast is thought to inhibit the release of allergic mediators, but its mechanism of action is not fully understood. We investigated whether the compound inhibits immunoglobulin E (IgE) synthesis and tested the hypothesis that andolast affects immunoglobulin class switching. Interleukin (IL)-4 and the interaction of CD40 expressed on B cells with its ligand on T cells are necessary for IgE synthesis. Thus, peripheral blood mononuclear cells (PBMCs) from 40 asthmatic, 16 non-asthmatic allergic, and 9 normal donors were stimulated with IL-4 and/or anti-CD40 antibody. T cells from 9 additional allergic donors were activated with anti-CD3/CD28 antibodies to express IL-4 mRNA. After incubation in the absence or presence of test compounds, immunoglobulin concentrations were measured by enzyme immunoassay, and mRNA levels were analyzed by RT-PCR. Andolast significantly inhibited IgE synthesis by stimulated PBMCs from both asthma patients and combined allergic/normal donors. In mechanistic studies, andolast was found to act at different cellular levels. Firstly, it reduced by about 45 percent (p<0.05) the levels of IL-4 mRNA in T cells stimulated with anti-CD3/CD28. Secondly, andolast reduced by about 36 percent (p<0.05) the expression of epsilon germline transcripts in PBMCs stimulated with IL-4/anti-CD40. Thirdly, the effect of andolast on immunoglobulin synthesis was selective in that the production of IgG4 antibodies was not significantly inhibited. Our findings, while supporting the evidence that andolast is effective for the treatment of asthma, provide new insights into its mechanism of action.

IgA subclass and IgA deficiency

There are two subclasses of IgA, IgA1 and IgA2, and its heavy chains are encoded by two different genes, alpha1 and alpha2 genes. These two subclasses play important roles in the first line of defense, and the amount ratio of these molecules in secretions varies. IgA deficiency (IgAD) is the most common immunodeficiency, however the pathogenesis in most cases of IgAD is unknown. The class switch disorder in IgA producing B lymphocytes is one of the important factors in IgAD patients. The decreased expression levels of Ialpha germline transcripts before a class switch may be the cause of selective IgAD. The alpha1 and alpha2 gene expression levels are low in most IgAD patients. Using RT-PCR method in which alpha1 and alpha2 mRNAs can be separately evaluated, we identified the second case of alpha1 gene deletion in Japan. Longitudinal change in the serum IgA of the patient with alpha1 gene deletion showed the pattern of the partial IgAD. Patients with alpha1 gene deletion can be considered as having partial IgAD.

The zinc finger protein Gfi1 is implicated in the regulation of IgG2b production and the expression of Iγ2b germline transcripts

Gfi1 is a zinc finger transcription factor that is undetectable in B lymphocytes but its expression rises rapidly upon antigenic stimulation or treatment with lipopolysaccharide (LPS). Here we show that Gfi1(-/-) mice have higher serum levels of gamma isotype immunoglobulin than WT animals. When challenged with antigen, Gfi1(-/-) mice react with accelerated formation of PNA+/CD19+ germinal center B cells and an increased production of antigen-specific IgG2a and IgG2b. Moreover, Gfi1(-/-) B cells secrete more IgG2a and IgG2b than WT cells and produce higher levels of Igamma2b sterile germline transcripts when cultured with LPS. While the proliferative response to stimulation with anti-IgM antibodies and plasma cell differentiation was normal in Gfi1(-/-) B cells, we found that mRNA and protein levels of TGFbeta1 were significantly increased in the absence of Gfi1. TGFbeta1 has been shown to be essential for the regulation of IgG subclass production and was previously found to selectively stimulate IgG2b secretion. Our findings reveal a new function of Gfi1 in the control of IgG isotype production.

E proteins are required to activate germline transcription of the TCR Vβ8.2 gene

Each TCR Vbeta gene is regulated by an individual Vbeta promoter, which becomes active prior to V(D) J recombination and drives germline transcription. It has been shown that Vbeta gene locus activation and recombination are dependent on the Vbeta promoter. However, transcription factors that regulate Vbeta germline transcription remain largely undefined. A major challenge in studying Vbeta gene germline transcription is the quantitative assessment of relatively low-level transcripts in T-cell progenitors. Here we used the established Vbeta8.2(CD2) knock-in mouse model to assess functions of E-protein transcription factors in Vbeta8.2 germline transcription. We show that E proteins are required for the activation but not the maintenance of the Vbeta8.2 germline transcription during thymocyte development. The activation of Vbeta8.2 germline transcription depends more on the E proteins encoded by the E2A gene than by the HEB gene. We further show that IL-7 receptor (IL-7R)-mediated signals are essential for Vbeta8.2 germline transcription. We provide evidence that IL-7R expression is only partially controlled by E2A, suggesting a role for E2A in driving Vbeta8.2 germline transcription independent of IL-7R activation.

Genetic or pharmaceutical blockade of p110δ phosphoinositide 3-kinase enhances IgE production

Recent studies indicate that pharmaceutical blockade of phosphoinositide 3-kinase (PI3K) signaling enzymes might be effective in reducing allergic airway inflammation. Signals generated by the p110delta PI3K isoform play critical roles in signaling through antigen and cytokine receptors and were shown to be required for induction of type 2, but not type 1, cytokine responses. We sought to determine the effect of genetic or pharmaceutical inactivation of p110delta PI3K on induction of IgE responses. We determined the effect of p110delta inactivation on induction of systemic IgE responses and on the ability of purified B lymphocytes to undergo IgE isotype switch in vitro. IgG and IgE germline transcription, postswitch transcription, protein expression, and secretion were measured, as well as cell division and expression of activation-induced cytidine deaminase, an enzyme required for isotype switch. Paradoxically, inactivation of p110delta PI3K led to markedly increased IgE responses, despite reduced production of other antibody isotypes. This result was seen by using genetic inactivation of p110delta inhibition with IC87114 compound or blockade with the broad-spectrum PI3K inhibitors PIK-90 and PI-103. Significant increases in IgG1/IgE double-positive cells were observed, indicating that inactivation of PI3K leads to uncontrolled sequential switching from IgG1 to IgE. Disruption of p110delta signaling results in increased germline transcription at the epsilon locus and increased activation-induced cytidine deaminase expression, suggesting deregulation at the level of the isotype switch process. Blockade of PI3K signaling leads to markedly enhanced B-cell switch to IgE and increased IgE levels in vivo, despite reduced type 2 cytokine production.

Global Transcriptional Repression in C. elegans Germline Precursors by Regulated Sequestration of TAF-4

In C. elegans, four asymmetric divisions, beginning with the zygote (P0), generate transcriptionally repressed germline blastomeres (P1-P4) and somatic sisters that become transcriptionally active. The protein PIE-1 represses transcription in the later germline blastomeres but not in the earlier germline blastomeres P0 and P1. We show here that OMA-1 and OMA-2, previously shown to regulate oocyte maturation, repress transcription in P0 and P1 by binding to and sequestering in the cytoplasm TAF-4, a component critical for assembly of TFIID and the pol II preinitiation complex. OMA-1/2 binding to TAF-4 is developmentally regulated, requiring phosphorylation by the DYRK kinase MBK-2, which is activated at meiosis II after fertilization. OMA-1/2 are normally degraded after the first mitosis, but ectopic expression of wild-type OMA-1 is sufficient to repress transcription in both somatic and later germline blastomeres. We propose that phosphorylation by MBK-2 serves as a developmental switch, converting OMA-1/2 from oocyte to embryo regulators.

In vivo expression of human immunoglobulin germ-line mRNA in normal and in immunodeficient individuals.

Previous in vitro studies suggest that transcription of the unrearranged immunoglobulin switch region and its 5' flanking region precedes isotype switching. These transcripts, which are devoid of a variable region, contain unique exons and are called germ-line (GL) mRNA. A crucial point in this regard is whether such transcripts could be detected in vivo, and if their expression correlates with immunoglobulin class switching in health and disease. To understand the in vivo role of this transcriptional activity we have adapted the reverse transcription-polymerase chain reaction (PCR) to analyse the GL transcripts from unstimulated peripheral blood mononuclear cells (PBMC) in healthy individuals and in different immunological diseases. Furthermore, mononuclear cells from different human organs were also analysed. We report here that GL (I alpha, I gamma and I epsilon used to designate the GL mRNA for IgA, IgG and IgE, respectively) mRNA are expressed differentially during ontogeny of B cells. Unexpectedly, no difference of I alpha mRNA expression between the PBMC and the secondary lymphoid organs was detected. Rather, the levels of GL transcripts were correlated to the number of sIgM+ cells. GL mRNA of all three isotypes could be detected in PBMC from healthy donors, whereas there was a decrease of specific GL transcript synthesis in individuals with immunoglobulin deficiency. Furthermore, during the in vivo immune response in a parasitic infection, we could demonstrate an induction of GL I epsilon mRNA during in vivo immune response. Concomitantly, there was also increased synthesis of productive epsilon transcripts. These findings implicate a potential role of GL transcription during in vivo immunoglobulin class switching.

MEK1/2 Induces STAT5-Mediated Germline Transcription of the TCRγ Locus in Response to IL-7R Signaling

The IL-7R plays an essential role in gammadelta T cell development by inducing V-J recombination of the TCRgamma locus through STAT5. Although tyrosine residues in the intracellular domain of the mouse IL-7R alpha-chain (IL-7Ralpha) have been implicated in STAT5 activation, it is still unknown whether they are essential for gammadelta T cell development. In this study, we showed that those IL-7Ralpha tyrosine residues are not essential for gammadelta T cell development, because phenylalanine replacement of four intracellular tyrosine residues (IL-7R-FFFF) partially rescued gammadelta T cell development of IL-7Ralpha-/- progenitors. To examine signaling pathways activated by IL-7R-FFFF, we introduced a chimeric receptor consisting of the human IL-4R alpha-chain and mouse IL-7R-FFFF (4R/7R-FFFF) into an IL-7-dependent pre-B cell line and found that 4R/7R-FFFF induced TCRgamma germline transcription and STAT5 activation. Treatment of cells with MEK1/2 inhibitors significantly decreased levels of TCRgamma germline transcription and STAT5 tyrosine phosphorylation mediated by 4R/7R-FFFF, suggesting that MEK1/2 plays an alternative role in STAT5 activation by IL-7R. MEK1/2 associated with STAT5 and induced STAT5 tyrosine phosphorylation and DNA binding activity. Furthermore, MEK1 directly phosphorylated a STAT5 tyrosine residue in vitro. Finally, active MEK1 partially rescued TCRgamma germline transcription by IL-7R in a pre-T cell line. These results demonstrate that MEK1/2 induces TCRgamma germline transcription by phosphorylating STAT5 through IL-7R-FFFF and suggest a potential role for MAPK in IL-7R tyrosine-independent activation of STAT5.