Mice Homozygous for a Truncated Form of CREB-Binding Protein Exhibit Defects in Hematopoiesis and Vasculo-angiogenesis

The aryl hydrocarbon receptor promotes aging phenotypes across species

The ubiquitously expressed aryl hydrocarbon receptor (AhR) induces drug metabolizing enzymes as well as regulators of cell growth, differentiation and apoptosis. Certain AhR ligands promote atherosclerosis, an age-associated vascular disease. Therefore, we investigated the role of AhR in vascular functionality and aging. We report a lower pulse wave velocity in young and old AhR-deficient mice, indicative of enhanced vessel elasticity. Moreover, endothelial nitric oxide synthase (eNOS) showed increased activity in the aortas of these animals, which was reflected in increased NO production. Ex vivo, AhR activation reduced the migratory capacity of primary human endothelial cells. AhR overexpression as well as treatment with a receptor ligand, impaired eNOS activation and reduced S-NO content. All three are signs of endothelial dysfunction. Furthermore, AhR expression in blood cells of healthy human volunteers positively correlated with vessel stiffness. In the aging model Caenorhabditis elegans, AhR-deficiency resulted in increased mean life span, motility, pharynx pumping and heat shock resistance, suggesting healthier aging. Thus, AhR seems to have a negative impact on vascular and organismal aging. Finally, our data from human subjects suggest that AhR expression levels could serve as an additional, new predictor of vessel aging.

Histone-modifying enzymes: regulators of developmental decisions and drivers of human disease

Precise transcriptional networks drive the orchestration and execution of complex developmental processes. Transcription factors possessing sequence-specific DNA binding properties activate or repress target genes in a step-wise manner to control most cell lineage decisions. This regulation often requires the interaction between transcription factors and subunits of massive protein complexes that bear enzymatic activities towards histones. The functional coupling of transcription proteins and histone modifiers underscores the importance of transcriptional regulation through chromatin modification in developmental cell fate decisions and in disease pathogenesis.

Regulation of the expression of intracellular beta-carbonic anhydrase in response to CO2 and light in the marine diatom Phaeodactylum tricornutum

Cells of the marine diatom Phaeodactylum tricornutum Bohlin (UTEX 642) grown in 5% CO(2) were transferred to air-level CO(2) in the light or dark and allowed to acclimate to air. No accumulation of the transcript of the P. tricornutum beta-carbonic anhydrase 1 (ptca1) was detected in 5% CO(2)-grown cells, but ptca1 mRNA accumulated and reached a peak after 6 h acclimation to air but decreased over the next 18 h. A similar accumulation time course was observed in cells air-acclimated in the dark, except that levels of mRNA were <50% those in the light. These results suggest that air-level [CO(2)] is required to trigger the transcription of ptca1 and that light affects the extent of acclimation. During acclimation to air for 120 h in the light, levels of ptca1 mRNA exhibited a periodic oscillation with a cycle of about 24 h, which, however, was not reflected in protein accumulation levels. A 5'-upstream region from the transcription-start site toward -1,292 bp of ptca1 was cloned by inverse polymerase chain reaction, and 5'-truncations were carried out on this fragment. The truncated promoter regions were fused with the beta-glucuronidase gene (uidA) and introduced into P. tricornutum. The promoter fragments, truncated at positions -1,292, -824, -484, -225, and -70 bp, conferred on transformants clear CO(2)-responsive beta-glucuronidase expressions. In contrast, the CO(2)-responsive regulation was severely impaired or completely abolished by truncations, respectively, at position -50 or -30 bp. These results indicate that critical cis-elements required for CO(2)-responsive transcription of ptca1 may be located between -70 and -30 bp relative to the transcription start site.

Genetic programs regulating HSC specification, maintenance and expansion

All mature blood cells originate from a small population of self-renewing pluripotent hematopoietic stem cells (HSCs). The capacity to self-renew characterizes all stem cells, whether normal or neoplastic. Interestingly, recent studies suggest that self-renewal is essential for tumor cell maintenance, implicating that this process has therapeutic relevance. Unfortunately, the molecular bases for self-renewal of vertebrate cells remain poorly defined. This article will focus on the developmental mechanisms underlying fetal and adult HSC homeostasis. Specifically, distinctions between genetic programs regulating HSC specification (identity), self-renewal (in both fetal and adult) and differentiation/commitment will be discussed with a special emphasis on transcriptional and chromatin regulators.

p300/CBP and cancer

p300 and cyclic AMP response element-binding protein (CBP) are adenoviral E1A-binding proteins involved in multiple cellular processes, and function as transcriptional co-factors and histone acetyltransferases. Germline mutation of CBP results in Rubinstein-Taybi syndrome, which is characterized by an increased predisposition to childhood malignancies. Furthermore, somatic mutations of p300 and CBP occur in a number of malignancies. Chromosome translocations target CBP and, less commonly, p300 in acute myeloid leukemia and treatment-related hematological disorders. p300 mutations in solid tumors result in truncated p300 protein products or amino-acid substitutions in critical protein domains, and these are often associated with inactivation of the second allele. A mouse model confirms that p300 and CBP function as suppressors of hematological tumor formation. The involvement of these proteins in critical tumorigenic pathways (including TGF-beta, p53 and Rb) provides a mechanistic route as to how their inactivation could result in cancer.

Distinct roles for CREB-binding protein and p300 in hematopoietic stem cell self-renewal

Hematopoietic stem cells (HSC) are tightly regulated through, as yet, undefined mechanisms that balance self-renewal and differentiation. We have identified a role for the transcriptional coactivators CREB-binding protein (CBP) and p300 in such HSC fate decisions. A full dose of CBP, but not p300, is crucial for HSC self-renewal. Conversely, p300, but not CBP, is essential for proper hematopoietic differentiation. Furthermore, in chimeric mice, hematologic malignancies emerged from both CBP(-/-) and p300(-/-) cell populations. Thus, CBP and p300 play essential but distinct roles in maintaining normal hematopoiesis, and, in mice, both are required for preventing hematologic tumorigenesis.

Growth suppression of human carcinoma cells by reintroduction of the p300 coactivator

The p300 and closely related cAMP response element binding protein (CREB)-binding protein (CBP) acetyltransferases function as global transcriptional coactivators and play important roles in a broad spectrum of biological processes, including cell proliferation and differentiation. A role of p300/CBP in tumor suppression has been proposed from the fact that these coactivators are targeted by viral oncoproteins and that biallelic mutations of p300 have been identified in carcinomas. Here, we show that transcriptional response to the transforming growth factor beta (TGF-beta), an inhibitor of epithelial cell growth, was severely impaired in human carcinoma cell lines carrying p300 mutations accompanied by inactivation of the second allele, and that wild-type expression restored TGF-beta-dependent transcriptional activity. Furthermore, reintroduction of wild-type p300 suppressed the growth of p300-deficient carcinoma cells, whereas p300 did not inhibit the growth of carcinoma cells examined, which have no detectable alterations in p300 protein and retain the TGF-beta-dependent transcriptional response. In addition, tumor-derived mutants missing the bromodomain or glutamine-rich region, which are respectively important for chromatin interaction and coactivator activities, lost the suppressive activity. In contrast, CBP exhibited no or reduced ability to suppress the growth of p300-deficient carcinoma cells. These results provide experimental evidence to show that p300 acts as a suppressor of tumor cell growth and suggest a distinct role of p300 in suppression of epithelial tumors.

Nuclear receptor coregulators: multiple modes of modification

Many proteins have been characterized as coregulators that can be recruited by DNA-binding nuclear receptors to influence transcriptional regulation. Recent genetic and biochemical studies have shown that cellular levels of coregulators are crucial for nuclear receptor-mediated transcription, and many coregulators have been shown to be targets for diverse intracellular signaling pathways and post-translational modifications. This review focuses on the different modes of regulation of nuclear receptor coregulators and the implications for tissue- and context-specific transcriptional responses to hormone and membrane receptor signaling.

The bHLH/PAS factor MOP3 does not participate in hypoxia responses

The basic helix-loop-helix/PAS (bHLH/PAS) family of proteins regulates transcriptional responses during development and in response to environmental stimuli. bHLH/PAS factors act as heterodimers, and genetic and biochemical data indicate that multiple heterodimeric combinations are found in vivo to regulate hypoxic gene expression. For example, HIF1alpha heterodimerizes with the highly related proteins ARNT or ARNT2 in neurons. In vivo, MOP3 interacts with CLOCK to regulate circadian rhythms; however, its role in hypoxia responses is unclear. We show here that unlike ARNT and ARNT2, MOP3 does not effectively form HIF-1 complexes or restore HIF-1 target gene expression in response to low oxygen when expressed in Arnt(-/-) ES cells. Furthermore, Mop3(-/-) day 9.5 embryos exhibit no angiogenic defects as shown for Arnt(-/-), Hif1alpha(-/-), and Hif2alpha(-/-) embryos. Therefore, by a variety of criteria, we show that MOP3 has little if any role in the regulation of hypoxia responses in vivo.

Targeted mutation of the murine arylhydrocarbon receptor nuclear translocator 2 (Arnt2) gene reveals partial redundancy with Arnt

The ubiquitously expressed basic helix-loop-helix (bHLH)-PAS protein ARNT (arylhydrocarbon receptor nuclear transporter) forms transcriptionally active heterodimers with a variety of other bHLH-PAS proteins, including HIF-1alpha (hypoxia-inducible factor-1alpha) and AHR (arylhydrocarbon receptor). These complexes regulate gene expression in response to hypoxia and xenobiotics, respectively, and mutation of the murine Arnt locus results in embryonic death by day 10.5 associated with placental, vascular, and hematopoietic defects. The closely related protein ARNT2 is highly expressed in the central nervous system and kidney and also forms complexes with HIF-1alpha and AHR. To assess unique roles for ARNT2 in development, and reveal potential functional overlap with ARNT, we generated a targeted null mutation of the murine Arnt2 locus. Arnt2(-/-) embryos die perinatally and exhibit impaired hypothalamic development, phenotypes previously observed for a targeted mutation in the murine bHLH-PAS gene Sim1 (Single-minded 1), and consistent with the recent proposal that ARNT2 and SIM1 form an essential heterodimer in vivo [Michaud, J. L., DeRossi, C., May, N. R., Holdener, B. C. & Fan, C. (2000) Mech. Dev. 90, 253-261]. In addition, cultured Arnt2(-/-) neurons display decreased hypoxic induction of HIF-1 target genes, demonstrating formally that ARNT2/HIF-1alpha complexes regulate oxygen-responsive genes. Finally, a strong genetic interaction between Arnt and Arnt2 mutations was observed, indicating that either gene can fulfill essential functions in a dose-dependent manner before embryonic day 8.5. These results demonstrate that Arnt and Arnt2 have both unique and overlapping essential functions in embryonic development.

CBP, a transcriptional coactivator and acetyltransferase

The CREB binding protein (CBP) was first identified as a protein that specifically binds to the active phosphorylated form of the cyclic-AMP response element binding protein (CREB). CBP was initially defined as a transcriptional coactivator that, as a result of its large size and multiple protein binding domain modules, may function as a molecular scaffold. More recently, an acetyltransferase activity, both of histones and nonhistones, has been found to be essential for transactivation. In this review, we will discuss the current understanding of the acetyltransferase specificity and activity of the CBP protein and how it may function to coactivate transcription. We will also examine the regulation of the CBP histone acetyltransferase activity in the cell cycle, by signal-transduction pathways and throughout development.Key words: CBP, acetyltransferase, chromatin, acetylation, p300.

HHV-8 encoded vIRF-1 represses the interferon antiviral response by blocking IRF-3 recruitment of the CBP/p300 coactivators

Human herpes virus 8 (HHV-8) has developed unique mechanisms for altering cellular proliferative and apoptotic control pathways by incorporating viral homologs to several cellular regulatory genes into its genome. One of the important pirated genes encoded by the ORF K9 reading frame is a viral homolog of the interferon regulatory factors (IRF), a family of cellular transcription proteins that regulates expression of genes involved in pathogen response, immune modulation and cell proliferation. vIRF-1 has been shown to downregulate the interferon- and IRF-mediated transcriptional activation of ISG and murine IFNA4 gene promoters. In this study we demonstrate that vIRF-1 efficiently inhibited virus-induced expression of endogenous interferon B, CC chemokine RANTES and CXC chemokine IP-10 genes. Co-expression analysis revealed that vIRF-1 selectively blocked IRF-3 but not IRF-7-mediated transactivation. vIRF-1 was able to bind to both IRF-3 and IRF-7 in vivo as detected by coimmunoprecipitation analysis, but did not affect IRF-3 dimerization, nuclear translocation and DNA binding activity. Rather, vIRF-1 interacted with the CBP/p300 coactivators and efficiently inhibited the formation of transcriptionally competent IRF-3-CBP/p300 complexes. These results illustrate that vIRF-1 is able to block the early stages of the IFN response to virus infection by interfering with the activation of IRF-3 responsive, immediate early IFN genes.

Extensive brain hemorrhage and embryonic lethality in a mouse null mutant of CREB-binding protein

CREB-binding protein (CBP) is a transcriptional co-activator which is required by many transcription factors. Rubinstein-Taybi syndrome (RTS), which is an autosomal dominant syndrome characterized by abnormal pattern formation, is associated with mutations in the human CBP gene. Various abnormalities occur at high frequency in the skeletal system of heterozygous Cbp-deficient mice, but some features of RTS such as cardiac anomalies do not, suggesting that some symptoms of RTS are caused by a dominant-negative mechanism. Here we report the characterization of homozygous Cbp-deficient mice. Homozygous mutants died around E10.5-E12.5, apparently as a result of massive hemorrhage caused by defective blood vessel formation in the central nervous system, and exhibited apparent developmental retardation as well as delays in both primitive and definitive hematopoiesis. Cbp-deficient embryos exhibited defective neural tube closure which was similar to those observed in twist-deficient embryos. However, a decrease in the level of twist expression was not observed in Cbp-deficient embryos. Anomalous heart formation, a feature of RTS patients and mice mutated in the CBP-related molecule, p300, was not observed in Cbp-deficient embryos. Since both Cbp and p300 are ubiquitously expressed in embryonic tissues including the developing heart, these results suggest that cardiac anomalies observed in RTS patients may be caused by a dominant negative effect of mutant CBP.

A stimulus-specific role for CREB-binding protein (CBP) in T cell receptor-activated tumor necrosis factor alpha gene expression

The cAMP response element binding protein (CREB)-binding protein (CBP)/p300 family of coactivator proteins regulates gene transcription through the integration of multiple signal transduction pathways. Here, we show that induction of tumor necrosis factor alpha (TNF-alpha) gene expression in T cells stimulated by engagement of the T cell receptor (TCR) or by virus infection requires CBP/p300. Strikingly, in mice lacking one copy of the CBP gene, TNF-alpha gene induction by TCR activation is inhibited, whereas virus induction of the TNF-alpha gene is not affected. Consistent with these findings, the transcriptional activity of CBP is strongly potentiated by TCR activation but not by virus infection of T cells. Thus, CBP gene dosage and transcriptional activity are critical in TCR-dependent TNF-alpha gene expression, demonstrating a stimulus-specific requirement for CBP in the regulation of a specific gene.