Transcriptional consequences of Jak-Stat signalling in haematopoiesis

Leal Cervantes, Ana Irene

January 2015

No description available.

616.1

JAK-STAT pathway ; Hematopoiesis

ROLES OF THE JAK PATHWAY IN FOLLICULAR PATTERNING IN DROSOPHILA

Xi, Rongwen

01 January 2002

The JAK-STAT pathway is an intracellular signaling pathway that is found to have crucial roles in hematopoiesis, immune response and the development of many other tissues in mammals. The pathway is conserved in Drosophila melanogaster, and is much simpler: there is only one Drosophila JAK (Hopscotch, Hop) and STAT (STAT92E) respectively, while there are at least 4 JAKs and 7 STATs in mammals. The pathway has been intensively studied in Drosophila, and has been implicated in many tissue development and cellular processes. In this work, I present several roles of JAK signaling in oogenesis.First, JAK signaling is required for cell differentiation within a specific lineage of follicle cells – stalk cells and polar cells. Unpaired (upd), which encodes the known ligand for the pathway, is expressed specifically in the polar cells in the developing egg. Reduced function of Upd or Hop results in fusions of egg chambers, which is primarily caused by improper formation of stalk cells, while general activation of the pathway in the egg chamber produces an extra number of stalk cells and sometimes eliminates polarfollicle cells. Based on the known function of the Notch pathway in oogenesis, we propose a model that Notch signaling determines a pool of precursors for the polar and stalk cells while JAK activity determines their specific fates within that pool.Second, JAK signaling is also involved in epithelial follicle cell differentiation. Consistent with the expression pattern of upd in the ovary, there is a gradient of JAK activity expanding from the poles, and this JAK activation gradient is both required and sufficient to suppress the main body follicle cell fate. Also, different levels of JAK activity are required and sufficient to determine both anterior and posterior terminal follicle cell fates. Consistent with these data is a model that a gradient of JAK activity triggered by Upd from the poles pre-patterns the epithelium into three domains and pre-determines sub-populations of terminal follicle cell fates prior to the EGFR activation, and cooperates with EGFR activity later to define posterior terminal follicle cell fates. This provides the first evidence for a morphogenic function of the JAK-STAT pathway in any organism.

Hair Growth Is Induced by Blockade of Macrophage-derived Oncostatin M and Downstream Jak-stat5 Signaling in Hair Follicle Stem Cells

Wang, Etienne Cho Ee

January 2018

Our lab recently described a role for JAK-STAT signaling in the maintenance of quiescence during the murine hair cycle. Research into signaling pathways and cytokines/growth factors involved in the mammalian hair cycle has not focused extensively on the JAK-STAT pathway. In this thesis, I investigated the upstream effector(s) and downstream mechanisms of JAK-STAT signaling in the HFSC during telogen, using a variety of methods, including murine conditional mutants of the JAK-STAT pathway, pharmacological and immunological techniques. The mechanism through which OSM exerts this effect is via JAK-STAT5 signaling downstream of the OSM receptor, which is antagonized by pharmacological JAK inhibition. Conditional epidermal ablation of OSMR or STAT5 during early- and mid-telogen (P42 – P60) shortens the telogen phase significantly, and inhibition of macrophages by way of neutralizing antibodies, small molecule inhibitors, and genetic ablation (with Csf1r-CreER::R26-iDTR mice) during telogen also promotes hair growth. Single-cell RNA sequencing of dermal immune cells across murine telogen identified a distinct subset of TREM2+ macrophages that are enriched for OSM, and gene-set analysis suggests these “trichophages” are similar to the microglia of the central nervous system. I show that this distinct subset of TREM2+ macrophages predominate during early- and mid-telogen, where they produce Oncostatin M (OSM), which is sufficient to maintain quiescence of hair follicle stem cells (HFSCs). Proliferation of HFSCs and hair growth is associated with depletion of this subset of TREM2+ macrophages. Interestingly, macrophage markers and OSM were found to be upregulated in the balding scalp of males with androgenetic alopecia, suggesting that this mechanism is physiologically relevant in the control of human hair cycling.

Cytology

Immunology

Biomedical engineering

JAK-STAT pathway

Hair--Growth

Amplified EPOR/JAK2 Genes Define a Unique Subtype of Acute Erythroid Leukemia / EPOR/JAK2の増幅は急性赤白血病のユニークな一群を規定する

Takeda, June

23 March 2023

京都大学 / 新制・論文博士 / 博士(医学) / 乙第13534号 / 論医博第2274号 / 新制||医||1065(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 滝田 順子, 教授 伊藤 貴浩, 教授 江藤 浩之 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

acute erythroid leukemia

therapeutic targets

JAK-STAT pathway

490

The JAK/STAT pathway in <i>Drosophila</i> hematopoiesis: function and regulatory mechanisms

Shen, Ying

January 2007

No description available.

Drosophila hematopoiesis

JAK/STAT pathway

SUMOylation

Toll pathway

JAK/STAT SIGNALING REGULATES GAMETOGENESIS AND AGE-RELATED REPRODUCTIVE MAINTENANCE

Giedt, Michelle Suzanne

01 January 2018

Cell signaling is central to integration of internal and external cues that regulate development and homeostasis. Most development is thought of as pre-adult, but limited developmental processes occur in adults. Gametogenesis incorporates elements of both these facets, with a distinct developmental plan for gamete synthesis which is regulated by integration of homeostatic inputs such as nutrient status, and environmental cues. Signaling pathways integrate and transduce information from these cues to evoke a response. A decline in homeostasis and subsequent cues occurs over time, in the case of reproductive tissues leading to a progressive loss of fertility. The Janus Kinase and Signal Transducer and Activator of Transcription or Jak/Stat signaling pathway is conserved between vertebrates and invertebrates and is necessary for numerous functions needed to maintain organism and reproductive homeostasis, as well as contributing to various developmental events. The pathway in the fruit fly Drosophila melanogaster, is composed of a single receptor, Domeless, one Janus kinase, Hopscotch, one known effector, Stat92E, and the Unpaired family of ligands consisting of Upd, Upd2, and Upd3. Jak/Stat signaling is highly pleiotropic in both sexes with involvement in homeostasis and reproduction, making it an ideal model for studying the role of signaling in reproductive aging. Reduction of pathway activity in females results in a higher proportion of unfertilized eggs, which increases with age, and in males leads to a premature onset of infertility. Central to both is integration through cell signaling to evoke an appropriate response. This dissertation explores two of the requirements for Jak/Stat signaling: the pleiotropic requirement for Jak/Stat activity during oogenesis and male reproductive maintenance. Jak/Stat functions from the beginning of oogenesis, in the stem cell niche. From there it participates in multiple functions including specification of a subset of somatic cells called the border cells through the polar cells, a pair of cells at either pole of the egg. Pathway stimulation in the border cells drives their migration with the polar cells to the oocyte boundary, where the polar cells each form an extension in a coordinated manner into the micropyle, the means for sperm entrance during fertilization. Loss of Jak/Stat activity in the border cells prevents border cell migration. While border cell migration has been well studied, polar cell involvement after completion of border cell migration is less well known. To investigate the requirements for polar cell activity and Jak/Stat activity after the completion of border cell migration, we reduced Jak/Stat signaling in the polar cells which, while having no effect on border cell migration, results in blocked micropyles due to loss of coordination of extensions during their outgrowth. Reduced function in the polar cells did not significantly affect expression of adhesion molecules. But, the loss of Stat92E is phenocopied by loss of DE-cadherin. Hence, these results indicate a previously unknown autocrine requirement for Jak/Stat activity in the polar cells. The testes also have a continuous requirement for Jak/Stat activity for stem cell maintenance and differentiation of the germline into mature sperm. Reproductive maintenance not only requires sustained production of gametes, but reproductive tissues are also subject to deterioration of homeostatic functions that contribute to organismal aging. Males from thirty-nine lines of the Drosophila Genetic Reference Panel (DGRP), a panel of inbred, fully sequenced lines, were screened for age at infertility. Data were used to perform a genome-wide association study (GWAS) to identify the genetic architecture of reproductive aging. Candidate variants associated with cell signaling regulators, genes with functions in maintaining cell homeostasis, and organism behavior were uncovered. Notably, several SNPs fell in and near Ptp61F, a negative regulator of Jak/Stat activity. While variants in the primary components of the Jak/Stat pathway were not identified, the general classes of candidate loci functions reflect the requirements for homeostasis, metabolism, and development that have been shown by other studies examining the genetics of aging and fecundity. Thus, we show that Jak/Stat has an amazing amount of pleiotropy that encompasses both the real-time functions of fertility and the time related process of aging.

Jak/Stat pathway

Drosophila

micropyle

polar cells

senescence

fertility

Cell Biology

Developmental Biology

Genetics

IDENTIFICATION AND CHARACTERIZATION OF SOCS44A IN DROSOPHILA

Rawlings, Jason Scott

01 January 2004

The JAK/STAT pathway is but one of the signal transduction cascades responsible for proper development and homeostasis. Gain-of-function mutations of pathway components are causative agents of several leukemias, highlighting the necessity for proper regulation of signal transduction. Drosophila presents an attractive model to study JAK/STAT signaling because mutations in the pathway behave in an analogous manner. Furthermore, the Drosophila cascade is much simpler as only one of each component required for activation has been characterized; whereas in mammals, there are many ligands, receptors, 4 JAKs and 7 STATs.Suppressors of Cytokine Signaling (SOCS) are one family of molecules which regulate JAK/STAT signaling via a negative feedback loop. All SOCS share a distinct modular domain architecture, which we exploited to locate three putative SOCS homologues within the Drosophila genome. I present the identification and initial characterization of one of these homologues, Socs44A. I show that Socs44A is not responsive to or dependent on JAK activity. However, I demonstrate that Socs44A is capable of downregulating JAK/STAT signaling in the developing wing but not inoogenesis, indicating that its ability to regulate the pathway is tissue specific, a phenomenon observed in the mammalian model.Signal transduction pathways are integrated at multiple levels. This interplay allows for combinatorial signaling, resulting in a higher order of complexity in the signals that can be received and interpreted by a cell. Well documented are the interactions between the JAK/STAT and the EGFR/MAPK pathways. In this work, I show that Socs44A can genetically interact with, and upregulate, the EGFR/MAPK pathway, analogous to a recent report involving SOCS-3.Starting with the Drosophila genome sequence, I initiated a reverse genetic approach to studying the function of the Socs44A locus. During the course of this investigation, I designed and implemented a novel post-processor of the BLAST algorithm, called Multi-BLAST, which facilitates retrieval of multiple domain sequences from public databases. In what would have been the ultimate achievement of this study, I attempted two mutagenesis screens designed to isolate Socs44A loss-of-function alleles. Progress on these screens is reported.

THE JAK/STAT PATHWAY IS REUTILIZED IN <em>DROSOPHILA</em> SPERMATOGENESIS

Tang, Lingfeng

01 January 2014

In the Drosophila testis, sperm are derived from germline stem cells (GSCs) which undergo a stereotyped pattern of divisions and differentiation. The somatic cells at the tip of the testis form the hub, which is the niche for both the somatic cyst stem cells (CySCs) and GSCs. The hub expresses Upd, a ligand for the JAK/STAT pathway that has roles in the maintenance of CySCs and GSCs. Male mutants of upd3, another ligand of the JAK/STAT pathway, become sterile much earlier than the wild-type, leading to the hypothesis that similar to upd, upd3 also promotes the self-renewal of stem cells in testis. It was found here that upd3 is also expressed in the hub, and that mutants of upd3 have fewer CySCs and GSCs. Using a GFP reporter of the JAK/STAT pathway, it was found that the JAK/STAT pathway is not only activated in the stem cells, consistent with its known function in the maintenance of stem cells, but is also activated in the elongated cyst cells that encapsulate late stage differentiating spermatids. The reduction of JAK/STAT activity in the somatic cyst cells led to impaired spermatid individualization, a late stage of spermatogenesis during which the syncytial spermatids are separated. The impairment of individualization was shown by the loss of three characteristic structures: individualization complexes (ICs), cystic bulges (CBs), and waste bags (WBs). The failure of IC formation implies STAT activity is required for the initiation of individualization, and the loss of CBs and WBs suggests STAT activity is required for the progression of individualization. Activation of caspases in elongated spermatids is known to be required for individualization. The reduction of JAK/STAT activity in cyst cells almost completely eliminated the activation of two effector caspases: drICE and DCP-1. It was concluded that JAK/STAT activity in somatic cyst cells promotes individualization by stimulating caspase activity in spermatids. The JAK/STAT pathway is not only required for the maintenance of stem cells at the tip, but also required for individualization away from the tip during late differentiation, thus is reutilized in Drosophila spermatogenesis.

JAK/STAT pathway

Drosophila

Spermatogenesis

Individualization

Caspase

Cell and Developmental Biology

Genetics and Genomics

THE FUNCTION OF Socs GENES IN DROSOPHILA DEVELOPMENT AND SIGNALING PATHWAYS

Guo, Qian

01 January 2007

The duration and intensity of the JAK/stat signaling must be tightly regulated to prevent excessive transcriptional response and to reset the pathway to receive additional signals. Socs are the largest class of these regulators in mammals. Eight Socs genes have been found in mammals. CIS, and SOCS1-3, the canonical Socs, are transcriptionally activated by and down-regulate the JAK signaling. Socs4-7, the non-canonical Socs, are less studied and their relationship with the JAK/STAT pathway has not been well established. The Drosophila genome encodes three non-canonical Socs homologues, Socs16D, Socs36E, and Socs44A. Expression of Socs36E is controlled by the JAK pathway and misexpression causes phenotypes similar to that from reduction of JAK in both ovary and wing, which may make it functionally more similar to the canonical Socs. Expression of Socs44A is not controlled by the JAK pathway and misexpression causes JAK mutant phenotypes in wing but not in ovary. Imprecise excision mutants of the three Socs genes have been generated by us and have no visible phenotypes. The mutants of Socs36E and Socs44A significantly enhance the tumor formation in hopTum-l mutant, a gain-of-function mutation of the JAK/STAT pathway. The function of Drosophila Socs will be further studied with different strategies.

Inactivation Of Type I IFN Jak-STAT Pathway In EBV Latency

Ning, Shunbin, Wang, Ling

05 August 2016

Epstein-Barr Virus (EBV) latent infection is associated with a variety of lymphomas and carcinomas. Interferon (IFN) Regulatory Factors (IRFs) are a family of transcription factors, among which IRF7 is the “master” regulator of type I IFNs (IFN-I) that defends against invading viruses. Robust IFN-I responses require a positive feedback loop between IRF7 and IFN-I. In recent years, we have discovered that IRF7 is significantly induced and activated by the principal EBV oncoprotein--Latent Membrane Protein 1 (LMP1); however, IRF7 fails to trigger robust IFN-I responses in EBV latency. We believe this intriguing finding is critical for EBV latency and oncogenesis, yet the underlying mechanism of this paradoxical phenomenon remains unclear. It is well known that tyrosine phosphorylation of most components of the IFN-I Jak-STAT pathway is essential for its signaling transduction. Thus, we have performed phosphotyrosine proteomics. We have found that the IFN-I Jak-STAT pathway is inactive due to the attenuated STAT2 activity, whereas the IFN-II Jak-STAT pathway is constitutively active, in EBV latency. We further confirmed these results by immunoblotting. This pilot study provides valuable information for the critical question regarding how the IRF7-mediated IFN-I response is evaded by EBV in its latency, and will prompt us to elucidate the underlying mechanisms.

Type I IFN

Jak-STAT Pathway

EBV Latency

Internal Medicine

Internal Medicine