Multiple Transcription Research Articles

The Characterization of R2R3-MYB Genes in Water Lily Nymphaea colorata Reveals the Involvement of NcMYB25 in Regulating Anthocyanin Synthesis

Nymphaea colorata, valued for its diverse flower colors and attractive shapes, is a popular ornamental aquatic plant. Anthocyanins provide color to flowers, and their biosynthesis is regulated by the R2R3-MYB transcription factor. In this study, we identified and analyzed the R2R3-MYB genes in N. colorata, focusing on their structure, evolution, expression patterns, regulatory mechanisms, and biological functions. We also investigated the role of the NcMYB25 gene in anthocyanin biosynthesis. There were 59 R2R3-MYB genes in N. colorata, distributed across 14 chromosomes. Among these, 14 genes were involved in segmental duplications and 6 in tandem duplications. Multiple R2R3-MYB transcription factors appeared to play a role in biological processes in N. colorata, including NcMYB48 in flavonoid synthesis, NcMYB33 in lignin synthesis, NcMYB23 in cold stress response, and NcMYB54 in osmotic stress response. Additionally, we identified 92 miRNAs in N. colorata, with 43 interacting with 35 R2R3-MYB genes. The NcMYB25 protein is localized in the nucleus and possesses transcriptional activation activity. Overexpression of the NcMYB25 gene in an apple pericarp resulted in anthocyanin accumulation. These findings provide insight into the evolutionary trajectory of the R2R3-MYB genes in N. colorata and highlight the regulatory function of the NcMYB25 gene in anthocyanin biosynthesis.

Co-expression of multiple transcription factors is associated with clinical features and endocrine prognosis in growth hormone-secreting pituitary adenomas.

The types of growth hormone-secreting pituitary adenomas are diverse, we have found that there are significant differences in clinical features and prognosis between PIT-1 single-cell spectrum growth hormone adenomas and growth hormone phenotypic polyhormonal adenomas. This study examined a cohort of 193 patients with growth hormone-secreting pituitary adenoma (GHPA), stratifying them into two groups: PIT-1 single transcription factor positive growth hormone adenoma (STF-GHPA) and Multiple transcription factor-positive growth hormone-secreting adenomas (MTF-GHPA). The objective was to compare these two groups' clinical characteristics. Within the MTF-GHPA group, we further subtyped them based on transcription factors to evaluate potential variations in clinical manifestations. Logistic regression analyses were employed to develop a risk factor model for investigating factors influencing hormone remission. There were no statistically significant differences in terms of age, gender, serum GH, and IGF-1 levels between patients diagnosed with MTF-GHPA and STF-GHPA. However, patients with MTF-GHPA exhibited a higher proportion of hypopituitarism compared to those with STF-GHPA. Furthermore, MTF-GHPA were characterized by smaller tumor size and less invasiveness, as indicated by lower Knosp classes. However, patients with MTF-GHPA have a lower rate of hormonal remission (30.8%) and more postoperative complications (31.0%), which means that STF-GHPA (hormonal remission:71.6%; postoperative complications:13.4%) has a better endocrine outcome than MTF-GHPA patients. Between the PIT-1 + SF-1+ and PIT-1 + TPIT+ subtypes within MTF-GHPA, significant differences were also observed in tumor size, endocrine outcomes, and postoperative complications. Risk factors influencing hormonal remission for GHPA included preoperative GH level, primary/recurrent, extent of resection, and transcription factor expression. Co-expression of multiple transcription factors is an important factor associated with clinical behavior and endocrine outcomes in patients with GHPA.

IModulonMiner and PyModulon: Software for unsupervised mining of gene expression compendia.

Public gene expression databases are a rapidly expanding resource of organism responses to diverse perturbations, presenting both an opportunity and a challenge for bioinformatics workflows to extract actionable knowledge of transcription regulatory network function. Here, we introduce a five-step computational pipeline, called iModulonMiner, to compile, process, curate, analyze, and characterize the totality of RNA-seq data for a given organism or cell type. This workflow is centered around the data-driven computation of co-regulated gene sets using Independent Component Analysis, called iModulons, which have been shown to have broad applications. As a demonstration, we applied this workflow to generate the iModulon structure of Bacillus subtilis using all high-quality, publicly-available RNA-seq data. Using this structure, we predicted regulatory interactions for multiple transcription factors, identified groups of co-expressed genes that are putatively regulated by undiscovered transcription factors, and predicted properties of a recently discovered single-subunit phage RNA polymerase. We also present a Python package, PyModulon, with functions to characterize, visualize, and explore computed iModulons. The pipeline, available at https://github.com/SBRG/iModulonMiner, can be readily applied to diverse organisms to gain a rapid understanding of their transcriptional regulatory network structure and condition-specific activity.

The homeodomain regulates stable DNA binding of prostate cancer target ONECUT2.

The CUT and homeodomain are ubiquitous DNA binding elements often tandemly arranged in multiple transcription factor families. However, how the CUT and homeodomain work concertedly to bind DNA remains unknown. Using ONECUT2, a driver and therapeutic target of advanced prostate cancer, we show that while the CUT initiates DNA binding, the homeodomain thermodynamically stabilizes the ONECUT2-DNA complex through allosteric modulation of CUT. We identify an arginine pair in the ONECUT family homeodomain that can adapt to DNA sequence variations. Base interactions by this ONECUT family-specific arginine pair as well as the evolutionarily conserved residues are critical for optimal DNA binding and ONECUT2 transcriptional activity in a prostate cancer model. The evolutionarily conserved base interactions additionally determine the ONECUT2-DNA binding energetics. These findings provide insights into the cooperative DNA binding by CUT-homeodomain proteins.

Transcriptional changes of genes encoding sarcoplasmic reticulum calcium binding and up-taking proteins in normal and Duchenne muscular dystrophy dogs

BackgroundCytosolic calcium overload contributes to muscle degradation in Duchenne muscular dystrophy (DMD). The sarcoplasmic reticulum (SR) is the primary calcium storage organelle in muscle. The sarco-endoplasmic reticulum ATPase (SERCA) pumps cytosolic calcium to the SR during muscle relaxation. Calcium is kept in the SR by calcium-binding proteins.MethodsGiven the importance of the canine DMD model in translational studies, we examined transcriptional changes of SERCA (SERCA1 and SERCA2a), SERCA regulators (phospholamban, sarcolipin, myoregulin, and dwarf open reading frame), and SR calcium-binding proteins (calreticulin, calsequestrin 1, calsequestrin 2, and sarcalumenin) in skeletal muscle (diaphragm and extensor carpi ulnaris) and heart (left ventricle) in normal and affected male dogs by droplet digital PCR before the onset (≤ 2-m-old), at the active stage (8 to 16-m-old), and at the terminal stage (30 to 50-m-old) of the disease. Since many of these proteins are expressed in a fiber type-specific manner, we also evaluated fiber type composition in skeletal muscle.ResultsIn affected dog skeletal muscle, SERCA and its regulators were down-regulated at the active stage, but calcium-binding proteins (except for calsequestrin 1) were upregulated at the terminal stage. Surprisingly, nominal differences were detected in the heart. We also examined whether there exists sex-biased expression in 8 to 16-m-old dogs. Multiple transcripts were significantly downregulated in the heart and extensor carpi ulnaris muscle of female dogs. In fiber type analysis, we found significantly more type I fiber in the diaphragm of 8 to 16-m-old affected dogs, and significantly more type II fibers in the extensor carpi ulnaris of 30 to 50-m-old affected dogs. However, no difference was detected between male and female dogs.ConclusionsOur study adds new knowledge to the understanding of muscle calcium regulation in normal and dystrophic canines.

Exploring the Role of Secondary Metabolites from Plants and Microbes as Modulators of Macrophage Differentiation.

Recent research has uncovered that secondary metabolites-biologically active compounds produced by plants, microbes, and other organisms-play a significant role in regulating the differentiation and function of macrophages. Macrophages, key components of the innate immune system, are crucial for a wide range of physiological processes, including immune response modulation, tissue homeostasis, and host defense against pathogens. This research delves into the mechanisms by which secondary metabolites influence macrophage differentiation signaling pathways, with a focus on how specific compounds affect macrophage polarization and functional phenotypes. Understanding these effects can open new avenues for developing therapeutic strategies that target macrophage-mediated immune responses. Secondary metabolites, such as nitrogen (N) and sulfur (S) containing compounds, terpenoids, and phenolic compounds from plants and microbes, can modulate macrophage differentiation by influencing cytokine production and activity. The activation of signaling pathways in macrophages involves multiple receptors and transcription factors, including IFN-γ receptor activation leading to STAT1 activation, TLR4 triggering IRF5, NFκB, and AP1, IL-4 receptor activation leading to STAT6 and IRF4 activation, PPARγ activation via the fatty acid receptor, TLR4 increasing CREB and C/EBP levels. The complex interplay between transcription factors and cytokines is crucial for maintaining the balance between the M1 and M2 states of macrophages. Despite these insights, further research is needed to unravel the specific molecular mechanisms involved and to identify promising secondary metabolites that could be translated into clinical applications.

“Биполярное” действие ингибитора васкулогенной мимикрии на экспрессию генов в клетках меланомы

Multiple exogenous or endogenous factors alter gene expression patterns by different mechanisms that yet are poorly understood. We used RNA-Seq analysis in order to study changes in gene expression in melanoma cells capable to vasculogenic mimicry upon action of inhibitor of vasculogenic mimicry. Here, we describe that the drug induces a strong upregulation of 50 genes controlling cell cycle and microtubule cytoskeleton coupled with a strong downregulation of 50 genes controlling different cellular metabolic processes. We found that both groups of genes are simultaneously regulated by multiple sets of transcription factors. We conclude, that one way for coordinated regulation of big groups of genes is the regulation simultaneously by multiple transcription factors.

Elevated proline and melatonin alter the methylation pattern in the promoter of their biosynthesis genes in rice

Salt stress upregulates osmoprotectants proline and melatonin in plants, and their exogenous application under salt stress can protect them from stress. While melatonin-induced plant epigenetic reprogramming is known in plants, such a mechanism is yet to be identified in the case of proline. The studies conducted so far used proline and melatonin along with one or more stress factors to look into their stress-alleviating effects. We investigated the impact of externally applied proline and melatonin on the methylation of promoter sequences of proline and melatonin biosynthesis genes in 14-day-old rice plants using a combination of biochemical, bioinformatics, and molecular techniques. Our findings demonstrate that exogenously applied proline and melatonin elevate endogenous levels of these compounds in rice, mimicking stress conditions in plants, as the biochemical assays corroborated the activation of antioxidant systems, particularly ascorbate peroxidase (APX) and catalase (CAT). Bioinformatics analysis unveiled multiple stress-responsive transcription factor binding sites on gene promoters associated with proline and melatonin biosynthesis pathways. Restriction analysis using the isoschizomer pair MspI/HpaII revealed distinct cytosine methylations at the restriction sites on the promoters analyzed in plants treated with proline and melatonin compared to the control. Differential methylation identified in the promoter sequences were matching with the biosynthesis of proline and melatonin and also the antioxidant enzyme levels. These observations are consistent with previous transcriptome data of proline and melatonin biosynthesis genes, providing insights into underlying regulatory mechanisms of proline and melatonin biosynthesis, their role in epigenome control during abiotic stress, and the evolution of various stress-tolerant varieties.

B-328 A Novel Pathway of Akt-Dependent PARP1 Activation Through the Nuclear Localization of EPRS1

Abstract Background Glutamyl-prolyl-tRNA synthetase (EPRS1) is the only bifunctional aminoacyl-tRNA synthetase (aaRS) and is essential for interpreting the genetic code. EPRS1, along with seven other aaRSs, forms the multi-tRNA synthetase complex (MSC). EPRS1 consists of two catalytic domains, GluRS and ProRS, connected by a linker region. Several aaRSs within the MSC, including EPRS1, can dissociate from the MSC in response to specific stimuli. This dissociation enables non-canonical activities distinct from their primary role in protein synthesis. Breast cancer cells harboring a loss-of-function mutation in phosphatase and tensin homolog (PTEN) are known to have more activity in the serine/threonine kinase Akt. Poly-(ADP)-ribose polymerase 1 (PARP1), plays a vital role in DNA damage repair (DDR). PARP1 deposits one or more ADP-Ribose moieties onto damaged DNA or other proteins in a process referred to as PARylation. We hope to connect Akt activation and PARP1 activity through the nuclear localization and noncanonical function of EPRS1. We hypothesize, that when Akt is activated, either through the loss of PTEN function or through stimuli such as heat shock or H2O2 treatment, will stimulate the nuclear localization of EPRS1 and modulate PARP1 activity. Methods To test our hypothesis, we evaluate Akt activation, EPRS1 localization, and PARP1 activity. Using pharmacological activators and inhibitors of Akt, we test if inhibitors and activators alone are sufficient to cause the nuclear localization of EPRS1. Biochemically, we isolate nuclear and cytosolic fractions used in various western blot analysis. We use a variety of assays for PARP1 activity and DDR that include immobilized histones, calculating IC50s of PARP1 inhibitors, comet assay, and confocal microscopy. To ascertain the connection between PARP1 and EPRS1 we use LC-MS/MS analysis and immunoprecipitation. Results We show, in both patient-derived and cultured breast cancer cells, elevated levels of EPRS1 not only in the cytoplasm, but also within the nucleus. We find that nuclear localization EPRS1 is facilitated by a nuclear localization sequence (NLS) located within the linker region of the protein. Breast cancer cells harboring a loss-of-function in PTEN exhibit higher levels of EPRS1 in the nucleus compared to PTEN-positive cells. In EPRS1 knockdown cells, there is diminished expression of multiple tumor-related transcription factors, DNA-damage repair, tumor cell survival, and PARP1 auto-PARylation. We demonstrate that nuclear EPRS1 binds to and shares an interactome with PARP1. Conclusions EPRS1-mediated regulation of PARP1 activity provides a new mechanistic link between PTEN loss in breast cancer cells, PARP1 activation, and cell survival and tumor growth. Targeting the non-canonical activity of EPRS1, without inhibiting canonical tRNA ligase activity, might provide a new therapeutic approach in breast and other forms of cancer, potentially supplementing existing cancer therapeutics.

Rise and SINE: roles of transcription factors and retrotransposons in zygotic genome activation.

In sexually reproducing organisms, life begins with the fusion of transcriptionally silent gametes, the oocyte and sperm. Although initiation of transcription in the embryo, known as zygotic genome activation (ZGA), is universally required for development, the transcription factors regulating this process are poorly conserved. In this Perspective, we discuss recent insights into the mechanisms of ZGA in totipotent mammalian embryos, namely ZGA regulation by several transcription factors, including by orphan nuclear receptors (OrphNRs) such as the pioneer transcription factor NR5A2, and by factors of the DUX, TPRX and OBOX families. We performed a meta-analysis and compiled a list of pan-ZGA genes, and found that most of these genes are indeed targets of the above transcription factors. Remarkably, more than a third of these ZGA genes appear to be regulated both by OrphNRs such as NR5A2 and by OBOX proteins, whose motifs co-occur in SINE B1 retrotransposable elements, which are enriched near ZGA genes. We propose that ZGA in mice is activated by recruitment of multiple transcription factors to SINE B1 elements that function as enhancers, and discuss a potential relevance of this mechanism to Alu retrotransposable elements in human ZGA.

Hexosaminidase B-driven cancer cell-macrophage co-dependency promotes glycolysis addiction and tumorigenesis in glioblastoma

Glycolytic metabolic reprogramming in cancer is regulated by both cancer intrinsic variations like isocitrate dehydrogenase 1 (IDH1) status and non-cancerous microenvironment components like tumor associated macrophages (TAMs). However, the detailed mechanism remains elusive. Here, we identify hexosaminidase B (HEXB) as a key regulator for glycolysis in glioblastoma (GBM). HEXB intercellularly manipulates TAMs to promote glycolysis in GBM cells, while intrinsically enhancing cancer cell glycolysis. Mechanistically, HEXB elevation augments tumor HIF1α protein stability through activating ITGB1/ILK/YAP1; Subsequently, HIF1α promotes HEXB and multiple glycolytic gene transcription in GBM cells. Genetic ablation and pharmacological inhibition of HEXB elicits substantial therapeutic effects in preclinical GBM models, while targeting HEXB doesn’t induce significant reduction in IDH1 mutant glioma and inhibiting IDH1 mutation-derived 2-hydroxyglutaric acid (2-HG) significantly restores HEXB expression in glioma cells. Our work highlights a HEXB driven TAMs-associated glycolysis-promoting network in GBM and provides clues for developing more effective therapies against it.

Role of anthocyanin metabolic diversity in bract coloration of Curcuma alismatifolia varieties

Anthocyanins are one of the key metabolites influencing the coloration of ornamental bracts in plants. Curcuma alismatifolia is an emerging ornamental plant, known for the rich diversity in the coloration of its bracts and the variety of anthocyanins present. However, the specific anthocyanin metabolites contributing to this diversity are not entirely clear. This study examines the bract color variation across 19 C. alismatifolia varieties using colorimetric analysis and spectrophotometric determination of total anthocyanin content. The 19 accessions were categorized into four color groups: white, light pink, pink, and purple. Further analysis using anthocyanin metabolomics and transcriptomics was conducted on five C. alismatifolia varieties with significant differences in coloration and total anthocyanin content. In addition to previously reported anthocyanins, delphinidin-3-O-glucoside and peonidin-3-O-rutinoside were identified for the first time as important contributors to the diverse bract coloration in C. alismatifolia. Fifty-three differentially expressed genes (DEGs) were identified in the anthocyanin biosynthesis pathway, and two significant gene modules were determined through WGCNA analysis. Correlation network analysis revealed two BZ1 genes that may be key terminal enzyme genes affecting anthocyanin synthesis in C. alismatifolia bracts. Multiple transcription factors, including MYB, NAC, WRKY, ERF, and bHLH, may be involved in regulating the accumulation of different anthocyanin contents in the bracts. This research sheds light on the genetic and metabolic factors that influence bract coloration in C. alismatifolia.

Therapeutic, Clinicopathological, and Molecular Correlates of PRKACA Expression in Gastrointestinal Cancers.

PRKACA alterations have clear diagnostic and biological roles in the fibrolamellar variant of hepatocellular carcinoma and a potential predictive role in that cancer type. However, the roles of PRKACA have not been comprehensively examined in gastric and colorectal cancers (GC and CRC). This study, therefore, sought to investigate the roles of PRKACA expression in GC and CRC. The clinico-genomic data of 441 GC and 629 CRC cases were analyzed for therapeutic, clinicopathological, and biological correlates using appropriate bioinformatics and statistical tools. Furthermore, the deregulation of PRKACA expression in GC and CRC was investigated using correlative and regression analyses. The results showed that PRKACA expression subsets were enriched for gene targets of chemotherapeutics, tyrosine kinase, and β-adrenergic inhibitors. Moreover, high PRKACA expression was associated with adverse clinicopathological and genomic features of GC and CRC. Gene Ontology Enrichment Analysis also showed that PRKACA-high subsets of the GI cancers were enriched for the biological and molecular functions that are associated with cell motility, invasion, and metastasis but not cell proliferation. Finally, multiple regression analyses identified multiple methylation loci, transcription factors, miRNA species, and PRKACA copy number changes that deregulated PRKACA expression in GC and CRC. This study has identified potential predictive and clinicopathological roles for PRKACA expression in GI cancers and has added to the growing body of knowledge on the deregulation of PRKACA in cancer.

MAX inactivation deregulates the MYC network and induces neuroendocrine neoplasia in multiple tissues.

MAX inactivation deregulates multiple transcription factors to induce neuroendocrine cancers.

Full-length RNA transcript sequencing traces brain isoform diversity in house mouse natural populations.

The ability to generate multiple RNA transcript isoforms from the same gene is a general phenomenon in eukaryotes. However, the complexity and diversity of alternative isoforms in natural populations remain largely unexplored. Using a newly developed full-length transcript enrichment protocol with 5' CAP selection, we sequenced full-length RNA transcripts of 48 individuals from outbred populations and subspecies of Mus musculus, and from the closely related sister species Mus spretus and Mus spicilegus as outgroups. The data set represents the most extensive full-length high-quality isoform catalog at the population level to date. In total, we reliably identify 117,728 distinct isoforms, of which only 51% were previously annotated. We show that the population-specific distribution pattern of isoforms is phylogenetically informative and reflects the segregating single nucleotide polymorphism (SNP) diversity between the populations. We find that ancient housekeeping genes are a major source of the overall isoform diversity, and that the generation of alternative first exons plays a major role in generating new isoforms. Given that our data allow us to distinguish between population-specific isoforms and isoforms that are conserved across multiple populations, it is possible to refine the annotation of the reference mouse genome to a set of about 40,000 isoforms that should be most relevant for comparative functional analysis across species.

A transcription network underlies the dual genomic coordination of mitochondrial biogenesis.

Mitochondrial biogenesis requires the expression of genes encoded by both the nuclear and mitochondrial genomes. However, aside from a handful transcriptional factors regulating specific subsets of mitochondrial genes, the overall architecture of the transcriptional control of mitochondrial biogenesis remains to be elucidated. The mechanisms coordinating these two genomes are largely unknown. We performed a targeted RNAi screen in developing eyes with reduced mitochondrial DNA content, anticipating a synergistic disruption of tissue development due to impaired mitochondrial biogenesis and mtDNA deficiency. Among 638 transcription factors annotated in Drosophila genome, 77 were identified as potential regulators of mitochondrial biogenesis. Utilizing published ChIP-seq data of positive hits, we constructed a regulatory network revealing the logic of the transcription regulation of mitochondrial biogenesis. Multiple transcription factors in core layers had extensive connections, collectively governing the expression of nearly all mitochondrial genes, whereas factors sitting on the top layer may respond to cellular cues to modulate mitochondrial biogenesis through the underlying network. CG1603, a core component of the network, was found to be indispensable for the expression of most nuclear mitochondrial genes, including those required for mtDNA maintenance and gene expression, thus coordinating nuclear genome and mtDNA activities in mitochondrial biogenies. Additional genetics analyses validated YL-1, a transcription factor upstream of CG1603 in the network, as a regulator controlling CG1603 expression and mitochondrial biogenesis.

Identification of pectin acetylesterase genes in moso bamboo (Phyllostachys edulis) reveals PePAE6 involved in pectin accumulation of leaves

As an indispensable polysaccharide, pectin profoundly affects various aspects of plant growth and development. Pectin acetylesterase (PAE) adjusts the acetylation level of pectin, thereby affecting the properties of pectin and cell walls, particularly in tissues such as leaves, where primary cell walls are predominant and rich in pectin. However, the PAE family in bamboo remains unknown. In the present study, ten PAE genes (PePAE1-PePAE10) were identified and characterized in moso bamboo (Phyllostachys edulis). All PePAEs possessed unique conserved domains and motifs of plant PAEs. The expression patterns of PePAEs varied across different tissues and developmental stages, indicating the sub-functionalization of these genes. Notably, the expression level of PePAE6 displayed the most remarkable change during leaf growth and was co-expressed with multiple transcription factors. Using various experimental approaches, we found that PeWRKY-1 and PeWRKY-2 negatively regulated PePAE6 by binding to its promoter. Knockdown of PeWRKY-1 or PeWRKY-2 inversely increased expression of PePAE6. While knockdown of PePAE6 resulted in increased acetylation levels and reduced galacturonic acid (GalA) content in moso bamboo leaves. Furthermore, overexpression of PePAE6 in rice indirectly enhanced vegetative growth and photosynthetic capacity, with a reduction in pectin acetylation levels and an increase in GalA. Additionally, an in vitro pectin acetylesterase activity assay confirmed that PePAE6 catalyzed pectin deacetylation, releasing acetic acid as a byproduct. These findings provide valuable insights into the basic characteristics of PAE in bamboo and reveal that PePAE6 is a functional gene involved in pectin accumulation, which could be helpful in genetic engineering in bamboo breeding.

Rack1 regulates B-cell development and function by binding to and stabilizing the transcription factor Pax5.

The transcription factor Pax5 activates genes essential for B-cell development and function. However, the regulation of Pax5 expression remains elusive. The adaptor Rack1 can interact with multiple transcription factors and modulate their activation and/or stability. However, its role in the transcriptional control of B-cell fates is largely unknown. Here, we show that CD19-driven Rack1 deficiency leads to pro-B accumulation and a simultaneous reduction in B cells at later developmental stages. The generation of bone marrow chimeras indicates a cell-intrinsic role of Rack1 in B-cell homeostasis. Moreover, Rack1 augments BCR and TLR signaling in mature B cells. On the basis of the aberrant expression of Pax5-regulated genes, including CD19, upon Rack1 deficiency, further exploration revealed that Rack1 maintains the protein level of Pax5 through direct interaction and consequently prevents Pax5 ubiquitination. Accordingly, Mb1-driven Rack1 deficiency almost completely blocks B-cell development at the pro-B-cell stage. Ectopic expression of Pax5 in Rack1-deficient pro-B cells partially rescues B-cell development. Thus, Rack1 regulates B-cell development and function through, at least partially, binding to and stabilizing Pax5.

Deciphering regulation of FOXP3 expression in human conventional T cells.

FOXP3 is a lineage-defining transcription factor that controls differentiation and maintenance of suppressive function of regulatory T cells (Tregs). Foxp3 is exclusively expressed in Tregs in mice. However, in humans, FOXP3 is not only constitutively expressed in Tregs; it is also transiently expressed in stimulated CD4+CD25- conventional T cells (Tconvs)1-3. Mechanisms governing the expression of FOXP3 in human Tconvs are not understood. Here, we performed CRISPR interference (CRISPRi) screens using a 15K-member gRNA library tiling 39 kb downstream of the FOXP3 transcriptional start site (TSS) to 85 kb upstream of the TSS in Treg and Tconvs. The FOXP3 promoter and conserved non-coding sequences (CNS0, CNS1, CNS2 and CNS3), characterized as enhancer elements in murine Tregs, were required for maintenance of FOXP3 in human Tregs. In contrast, FOXP3 in human Tconvs depended on regulation at CNS0 and a novel Tconv-specific noncoding sequence (TcNS+) located upstream of CNS0. Arrayed validations of these sites identified an additional repressive cis-element overlapping with the PPP1R3F promoter (TcNS-). Pooled CRISPR knockouts revealed multiple transcription factors required for proper expression of FOXP3 in Tconvs, including GATA3, STAT5, IRF4, ETS1 and DNA methylation-associated regulators DNMT1 and MBD2. Analysis of ChIP-seq and ATAC-seq paired with knock-out (KO) of GATA3, STAT5, IRF4, and ETS1 revealed regulation of CNS0 and TcNS+ accessibility. Collectively, this work identified Treg-shared and Tconv-specific cis-elements and the trans-factors that interact with them, building a network of regulators controlling FOXP3 expression in human Tconvs.

The KNAT3a1-WND2A/3A module positively regulates fiber secondary cell wall biosynthesis in Populus tomentosa

The secondary cell wall (SCW) is essential for plant growth and development in vascular plants, and its biosynthesis is mainly controlled by a complex hierarchical regulatory network involving multiple transcription factors (TFs) at the transcription level. However, TFs that specifically regulate secondary xylem have not been widely reported. In this study, we described a poplar KNOTTED1-like homeobox (KNOX) TF PtoKNAT3a1, which was mainly expressed in the expanding xylem cells of stems. PtoKNAT3a1 overexpression caused fiber SCW thickening and increased all measured SCW compositions by upregulating the expression of SCW -biosynthetic genes and -associated TFs, but had no effect on the vessels of SCW. The opposite phenotype was observed in the PtoKNAT3a1-knockout lines. Hence, we further demonstrated that PtoKNAT3a1 could physically interact with the NAC master switches PtoWND2A/3A to enhance the expression of downstream MYB TFs and SCW biosynthetic genes (including PtoMYB20, PtoMYB21, PtoMYB90, PtoCoMT2, PtoGT43B and PtoCesA8). Meanwhile, the studies also demonstrate that the KNAT3 has functional differentiation in xylem development. Taken together, these data suggest that the KNAT3a1-WND2A/3A module positively regulates fiber development of the secondary xylem in poplar via the WND2A/3A-mediated hierarchical regulatory network, and supplies useful information for fiber SCW formation. The research not only deepens the understanding of the hierarchical regulatory network affecting SCW formation but also supplies genetic resources and molecular targets for plant fiber utilization.