Regulation of intracellular cyclic adenosine 3,5-monophosphate (cAMP) is integral in mediating cell growth, cell differentiation, and immune responses in hematopoietic cells. To facilitate studies of cAMP regulation we developed a BRET (bioluminescence resonance energy transfer) sensor for cAMP, CAMYEL (cAMP sensor using YFP-Epac-RLuc), which can quantitatively and rapidly monitor intracellular concentrations of cAMP in vivo. This sensor was used to characterize three distinct pathways for modulation of cAMP synthesis stimulated by presumed G s -dependent receptors for isoproterenol and prostaglandin E 2 . Whereas two ligands, uridine 5-diphosphate and complement C5a, appear to use known mechanisms for augmentation of cAMP via G q /calcium and G i , the action of sphingosine 1-phosphate (S1P) is novel. In these cells, S1P, a biologically active lysophospholipid, greatly enhances increases in intracellular cAMP triggered by the ligands for G s -coupled receptors while having only a minimal effect by itself. The enhancement of cAMP by S1P is resistant to pertussis toxin and independent of intracellular calcium. Studies with RNAi and chemical perturbations demonstrate that the effect of S1P is mediated by the S1P 2 receptor and the heterotrimeric G 13 protein. Thus in these macrophage cells, all four major classes of G proteins can regulate intracellular cAMP.Cyclic adenosine 3Ј,5Ј-monophosphate (cAMP), a ubiquitous second messenger, mediates a wide range of cellular functions including cell metabolism (1), cell proliferation and differentiation (1), immune responses (2, 3), memory formation (4), and cardiac contractility (5). Canonically, the concentration of intracellular cAMP is regulated by two distinct families of enzymes. The transmembrane adenylyl cyclases (ACs) 3 synthesize cAMP from adenosine triphosphate (6, 7), whereas the cAMP-specific phosphodiesterases metabolize cAMP to biologically inactive adenosine 5Ј-monophosphate (8, 9). ACs are primarily activated by G␣ s but their activities can also be differentially regulated by G␣ i , G␥, or Ca 2ϩ (10, 11). The activities of various phosphodiesterases can be regulated by protein kinase A (PKA), extracellular-regulated kinase (ERK), phosphoinositide 3-kinase, and the concentration of cAMP itself (12-16). Thus integration of signaling by stimuli that can regulate the intracellular concentration of cAMP will depend strongly on the various pathways and the subtypes of ACs and phosphodiesterases expressed in individual cells at any given time.Assessment of the regulation of intracellular cAMP in vivo has only become possible recently. Zaccolo et al. (17) first described a FRET sensor for cAMP based on the cAMP binding domain of PKA. Subsequently, several reports have described FRET sensors for cAMP based on binding of the nucleotide to the Epac proteins (18 -21). While these FRET sensors have been effective for measuring changes and localization of cAMP in single cells, measurements are tedious. Furthermore, the requirement for excitation of donor molecules pro...
The transcription factor SOX2 is expressed most notably in the developing CNS and placodes, where it plays critical roles in embryogenesis. Heterozygous de novo mutations in SOX2 have previously been associated with bilateral anophthalmia/microphthalmia, developmental delay, short stature, and male genital tract abnormalities. Here we investigated the role of Sox2 in murine pituitary development. Mice heterozygous for a targeted disruption of Sox2 did not manifest eye defects, but showed abnormal anterior pituitary development with reduced levels of growth hormone, luteinizing hormone, and thyroid-stimulating hormone. Consequently, we identified 8 individuals (from a cohort of 235 patients) with heterozygous sequence variations in SOX2. Six of these were de novo mutations, predicted to result in truncated protein products, that exhibited partial or complete loss of function (DNA binding, nuclear translocation, or transactivation). Clinical evaluation revealed that, in addition to bilateral eye defects, SOX2 mutations were associated with anterior pituitary hypoplasia and hypogonadotropic hypogonadism, variable defects affecting the corpus callosum and mesial temporal structures, hypothalamic hamartoma, sensorineural hearing loss, and esophageal atresia. Our data show that SOX2 is necessary for the normal development and function of the hypothalamo-pituitary and reproductive axes in both humans and mice. Introduction SOX2 is a member of the sex-determining region of the Y chromosome-related (SRY-related) high-mobility group (HMG) box (SOX) family of transcription factors, encoded by 20 genes in humans and mice, each of which carries a 79-amino acid HMG box DNA-binding domain similar to that of SRY as well as domains implicated in transcriptional regulation (1, 2). Based on HMG box homology, they are grouped into different subfamilies. SOX1, SOX2, and SOX3 belong to the B1 subfamily and are expressed in various phases of embryonic development and cell differentiation, where they play critical roles in embryogenesis (3, 4). All 3 mark neuroepithelial progenitors and stem cells from the earliest stages of development, and there is a strong, but not absolute, tendency for them to be downregulated as cells differentiate.In the mouse, Sox2 RNA is first detected in cells at the morula stage (2.5 dpc) and then in the inner cell mass of the blastocyst (3.5 dpc).
Schistosomes infect more than 200 million people. These parasitic flatworms rely on a syncytial outer coat called the tegument to survive within the vasculature of their host. Although the tegument is pivotal for their survival, little is known about maintenance of this tissue during the decades schistosomes survive in the bloodstream. Here, we demonstrate that the tegument relies on stem cells (neoblasts) to specify fusogenic progenitors that replace tegumental cells lost to turnover. Molecular characterization of neoblasts and tegumental progenitors led to the discovery of two flatworm-specific zinc finger proteins that are essential for tegumental cell specification. These proteins are homologous to a protein essential for neoblast-driven epidermal maintenance in free-living flatworms. Therefore, we speculate that related parasites (i.e., tapeworms and flukes) employ similar strategies to control tegumental maintenance. Since parasitic flatworms infect every vertebrate species, understanding neoblast-driven tegumental maintenance could identify broad-spectrum therapeutics to fight diseases caused by these parasites.
Polyphosphates, linear polymers of inorganic phosphates linked by phosphoanhydride bonds, are widely present among organisms and play diverse roles in biology, including functioning as potent natural modulators of the human blood clotting system. However, studies of proteinpolyphosphate interactions are hampered by a dearth of methods for derivatizing polyphosphate or immobilizing it onto solid supports. We now report that EDAC (1-ethyl-3-[3-dimetyhlaminopropyl]carbodiimide) efficiently promotes the covalent attachment of a variety of primary aminecontaining labels and probes to the terminal phosphates of polyphosphates via stable phosphoramidate linkages. Using 31 P NMR, we confirmed that EDAC-mediated reactions between primary amines and polyphosphate results in phosphoramidate linkages with the terminal phosphate groups. We show that polyphosphate can be biotinylated, labeled with fluorophores and immobilized onto solid supports; that immobilized polyphosphate can be readily used to quantify protein binding affinities; that covalently derivatized or immobilized polyphosphate retains its ability to trigger blood clotting; and that derivatizing the ends of polyphosphate with spermidine protects it from exopolyphosphatase degradation. Our findings open up essentially the entire armamentarium of protein chemistry to modifying polyphosphate, which should greatly facilitate studies of its biological roles.Inorganic polyphosphate (polyP), a linear polymer of orthophosphate residues linked via phosphoanhydride bonds, is widely distributed in biology and plays important and diverse roles in nature (1,2). We recently showed that polyP is a potent modulator of the blood clotting cascade (3)(4)(5), and an expanding body of research is investigating its roles in other biological systems (6-11). Many technical obstacles remain, for investigating the biological roles of polyP and there is a real need for improved microscale methods for analyzing polyP. In particular, there is a dearth of approaches for covalently modifying polyP or attaching it to solid supports. One of the few published methods for immobilizing polyP onto surfaces is via Lewis acid/base interactions between polyP and zirconia beads (12). Although we have successfully used this method (13), it suffers from relatively high nonspecific binding of proteins to zirconia. Furthermore, this chemistry is not readily adaptable for attaching labels to polyP, or to immobilizing polyP onto the sorts of solid supports routinely used in analyses † This work was supported by grant R01 HL47014 from the National Heart, Lung and Blood institute to J.H.M., grant R01 GM75937 from the National Institute of General Medical Sciences to C.M.R., and postdoctoral fellowship grant 0920045G from the American Heart Association to R.L. Immobilization of polyP onto Polystyrene Microplate Wells and Coagulometer CuvettesA variety of reaction conditions were tested in order to optimize EDAC-mediated covalent coupling of polyP HMW to primary amines displayed on Amine Surface stripwe...
Schistosome parasites kill 250,000 people every year. Treatment of schistosomiasis relies on the drug praziquantel. Unfortunately, a scarcity of molecular tools has hindered the discovery of new drug targets. Here, we describe a large-scale RNA interference (RNAi) screen in adult Schistosoma mansoni that examined the function of 2216 genes. We identified 261 genes with phenotypes affecting neuromuscular function, tissue integrity, stem cell maintenance, and parasite survival. Leveraging these data, we prioritized compounds with activity against the parasites and uncovered a pair of protein kinases (TAO and STK25) that cooperate to maintain muscle-specific messenger RNA transcription. Loss of either of these kinases results in paralysis and worm death in a mammalian host. These studies may help expedite therapeutic development and invigorate studies of these neglected parasites.
Regulation of intracellular cAMP by multiple pathways enables differential function of this ubiquitous second messenger in a context-dependent manner. Modulation of G s -stimulated intracellular cAMP has long been known to be modulated by the G i and G q /Ca 2؉ pathways. Recently, the G 13 pathway was also shown to facilitate cAMP responses in murine macrophage cells. We report here that this synergistic regulation of cAMP synthesis by the G s and G 13 pathways is mediated by a specific isoform of adenylyl cyclase, AC7. Furthermore, this signaling paradigm exists in several hematopoietic lineages and can be recapitulated by exogenous expression of AC7 in HEK 293 cells. Mechanistic characterization of this synergistic interaction indicates that it occurs downstream of receptor activation and it can be mediated by the ␣ subunit of either G 12 or G 13 . Our results demonstrate that AC7 is a specific downstream effector of the G 12/13 pathway.
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