C/EBPα enters the nucleolus

Comment on: Müller C, et al. EMBO J 2010; doi:10.1038/emboj.2009.404.     

Integral role of the I′-helix in the function of the “inactive” C-terminal domain of catalase–peroxidase (KatG)

Catalase–peroxidases (KatGs) have two peroxidase-like domains. The N-terminal domain contains the heme-dependent, bifunctional active site. Though the C-terminal domain lacks the ability to bind heme or directly catalyze any reaction, it has been proposed to serve as a platform to direct the folding of the N-terminal domain. Toward such a purpose, its I′-helix is highly conserved and appears at the interface between the two domains. Single and multiple substitution variants targeting highly conserved residues of the I′-helix were generated for intact KatG as well as the stand-alone C-terminal domain (KatG^C). Single variants of intact KatG produced only subtle variations in spectroscopic and catalytic properties of the enzyme. However, the double and quadruple variants showed substantial increases in hexa-coordinate low-spin heme and diminished enzyme activity, similar to that observed for the N-terminal domain on its own (KatG^N). The analogous variants of KatG^C showed a much more profound loss of function as evaluated by their ability to return KatG^N to its active conformation. All of the single variants showed a substantial decrease in the rate and extent of KatG^N reactivation, but with two substitutions, KatG^C completely lost its capacity for the reactivation of KatG^N. These results suggest that the I′-helix is central to direct structural adjustments in the adjacent N-terminal domain and supports the hypothesis that the C-terminal domain serves as a platform to direct N-terminal domain conformation and bifunctionality.     

Gα(12) binds to the N-terminal regulatory domain of p120(ctn), and downregulates p120(ctn) tyrosine phosphorylation induced by Src family kinases via a RhoA independent mechanism

p120 Catenin (p120(ctn)) regulates cadherin stability, and thus facilitates strong cell-cell adhesion. Previously, we demonstrated that Gα(12) interacts with p120(ctn). In the present study, we have delineated a region of p120(ctn) that binds to Gα(12). We report that the N-terminal region of p120(ctn) (amino acids 1-346) is necessary and sufficient for the interaction. While the coiled-coiled domain and a charged region, comprising a.a 102-120, were found to be dispensable, amino acids 121-323 were required for p120(ctn) binding to Gα(12). This region harbors the phosphorylation domain of p120(ctn) and has been postulated as important for RhoA regulation. Downregulation of Src family kinase-induced tyrosine phosphorylation of p120(ctn) was observed in the presence of activated Gα(12). This down-regulation was triggered by three different Gα(12) mutants uncoupled from RhoA signalling. Furthermore, a dominant active form of RhoA did not reduce Src-induced phosphoryaltion of p120(ctn). In summary, our results suggest that Gα(12) binds to p120(ctn) and modulates its phosphorylation status through a Rho-independent mechanism. Gα(12) emerges as an important regulator of p120(ctn) function, and possibly of cadherin-mediated adhesion and/or cell motility.     

Molecular characterization and expression analysis of the putative interleukin 6 receptor (IL-6Rα and glycoprotein-130) in rainbow trout (<Emphasis Type="Italic">Oncorhynchus mykiss</Emphasis>): Salmonid IL-6Rα possesses a polymorphic N-terminal Ig domain with variable numbers of two repeats

Interleukin (IL)-6, the founding member of IL-6 family cytokines, plays non-redundant roles in hematopoiesis and acute phase responses. IL-6 signals via a specific private IL-6Rα and a common beta chain gp130. In this study, we have cloned both the IL-6Rα and gp130 in rainbow trout. The trout gp130 cDNA encodes 906 aa and is similar in size, extracellular domain structure (D1–D6) and presence of intracellular motifs important for signal transduction to tetrapod gp130s. The trout IL-6Rα cDNA encodes for 834 aa and is larger compared to tetrapod IL-6Rαs, as are other fish IL-6Rα molecules due to a large D1 domain. However, the cytokine-binding domain is well conserved across vertebrates, with four conserved cysteine residues in the N-terminal FNIII domain and a WSXWS motif in the C-terminal FNIII domain. Furthermore, a phylogenetic tree analysis confirmed that the reported fish IL-6Rα and gp130 molecules are orthologues to their tetrapod counterparts. The extra large D1 domain of the salmonid IL-6Rα molecules results partially from the insertions of two repetitive sequences of [TS]-[TF]-VSTTT-[ND]-TTSNG and TTVS-[AT]-IKD-[DG]-S-[KD]-N-[GR], respectively. Furthermore the numbers of repetitions of the two motifs were variable in different individuals and cell lines, and even in the same fish allelic polymorphism exists. Trout IL-6Rα was expressed at higher levels than gp130 in a number of tissues examined and the expression of both IL-6Rα and gp130 could be modulated by LPS and Poly I:C in the cell lines studied. The expression patterns of the receptors suggest that high level expression of IL-6Rα is critical for IL-6 responsiveness.     

Prion and TNFα: TAC(E)it agreement between the prion protein and cell signaling

Prion diseases are rare and fatal neurodegenerative disorders that occur when the cellular prion protein (PrPC) is converted into a conformationally modified isoform that originates the novel infectious agent, called prion. Although much information is now available on the different routes of prion infection, both the mechanisms underlying prion neurotoxicity and the physiologic role of PrPC remain unclear. By use of a novel paradigm, we have shown in a recent paper that - following a myotoxin-induced degenerative challenge - PrPC is implicated in the morphogenesis of the skeletal muscle of adult mice. PrPC accomplished this task by modulating signaling pathways central to the myogenic process, in particular the p38 kinase pathway. The possibility that PrPC acts in cell signaling has already been suggested after in vitro studies. Using our in vivo approach, we have instead provided proof of the physiologic relevance of PrPC commitment in signaling events, and that PrPC likely performed the task by controlling the activity of the enzyme (TACE) secreting the signaling TNF-α molecule. After a brief summary of our data, here we will discuss the suggestion, arising from our and other recent findings, implying that regulation of TACE, and of other members of the protease family TACE belongs to, may be exploited by PrPC in different cell contexts. Notably, this advancement of knowledge on PrPC physiology could also shed light on the defense mechanisms against the onset of a more common neurodegenerative disorder than prion disease, such as Alzheimer disease.     

14-3-3σ (sigma) regulates proliferation and differentiation of multipotent p63-positive cells isolated from human breastmilk

The mammary gland is a dynamic organ that only undergoes complete differentiation during pregnancy. Differentiation is fuelled by asymmetric division of stem cells that reside in normally quiescent niches in the resting gland in response to pregnancy-associated hormones. Loss of regulation of stem cells is believed to underlie some breast cancers. This process is poorly understood in humans since it is difficult to extract stem cells from the lactating gland. We have identified a p63-positive population in breastmilk that proliferates and differentiates into at least two separate mammary lineages in culture. Nuclear translocation of p63 coincides with expression of the cell-cycle arrest protein 14-3-3σ (Sigma) and precedes differentiation. Transient down-regulation of Sigma promotes maintenance of the p63-positive population without affecting normal differentiation. We propose that p63-postive cells from breastmilk represent a novel source of cells to model regulation of mammary gland development and tumorigenesis.     

Genetic structure of the Canarian palm tree (Phoenix canariensis) at the island scale: does the ‘island within islands’ concept apply to species with high colonisation ability?

• Oceanic islands are dynamic settings that often promote within‐island patterns of strong population differentiation. Species with high colonisation abilities, however, are less likely to be affected by genetic barriers, but island size may impact on species genetic structure regardless of dispersal ability.
• The aim of the present study was to identify the patterns and factors responsible for the structure of genetic diversity at the island scale in Phoenix canariensis, a palm species with high dispersal potential. To this end, we conducted extensive population sampling on the three Canary Islands where the species is more abundant and assessed patterns of genetic variation at eight microsatellite loci, considering different within‐island scales.
• Our analyses revealed significant genetic structure on each of the three islands analysed, but the patterns and level of structure differed greatly among islands. Thus, genetic differentiation fitted an isolation‐by‐distance pattern on islands with high population densities (La Gomera and Gran Canaria), but such a pattern was not found on Tenerife due to strong isolation between colonised areas. In addition, we found a positive correlation between population geographic isolation and fine‐scale genetic structure.
• This study highlights that island size is not necessarily a factor causing strong population differentiation on large islands, whereas high colonisation ability does not always promote genetic connectivity among neighbouring populations. The spatial distribution of populations (i.e. landscape occupancy) can thus be a more important driver of plant genetic structure than other island, or species′ life‐history attributes.

     

Main regulatory element (MRE) of the <Emphasis Type="Italic">Danio rerio</Emphasis> α/β-globin gene domain exerts enhancer activity toward the promoters of the embryonic-larval and adult globin genes

In warm-blooded vertebrates, the α- and β-globin genes are organized in domains of different types and are regulated in different fashion. In cold-blooded vertebrates and, in particular, the tropical fish Danio rerio, the α- and β-globin genes form two gene clusters. A major D. rerio globin gene cluster is in chromosome 3 and includes the α- and β-globin genes of embryonic-larval and adult types. The region upstream of the cluster contains c16orf35, harbors the main regulatory element (MRE) of the α-globin gene domain in warm-blooded vertebrates. In this study, transient transfection of erythroid cells with genetic constructs containing a reporter gene under the control of potential regulatory elements of the domain was performed to characterize the promoters of the embryonic-larval and adult α- and β-globin genes of the major cluster. Also, in the 5th intron of c16orf35 in Danio rerio was detected a functional analog of the warm-blooded vertebrate MRE. This enhancer stimulated activity of the promoters of both adult and embryonic-larval α- and β-globin genes.     

4S polycyclic aromatic hydrocarbon receptor (glycine N‐methyltransferase) and the aryl hydrocarbon receptor nuclear translocator (hypoxia inducible factor‐1β) interaction in Chinese hamster ovary and rat hepatoma cells: 4S PAH‐R/ARNT hetero‐oligomers?

Rat CYP1A1 promoter‐luciferase, transiently transfected wild‐type and 4S PAH receptor (glycine N‐methyl transferase, GNMT)‐transformed Chinese hamster ovary (CHO) cells were exposed to benzo[a]pyrene and assayed for luciferase activity as an indicator of CYP1A1 promoter activity. CHO cells transformed with the rat 4S PAH receptor/GNMT expression vector had twice the induction level of luciferase activity with respect to wild‐type CHO cells in concert with previously published reports that the 4S PAH receptor/GNMT mediates benzo[a]pyrene induction of CYP1A1 gene expression. Lysates of GNMT‐transformed CHO cells and wild‐type H4IIE rat hepatoma cells exposed to benzo[a]pyrene were immuno‐precipitated with anti‐GNMT antibodies, separated by SDS–polyacrylamide gel electrophoresis and transferred to PVDF membrane for Western blot analysis with anti‐aryl hydrocarbon receptor nuclear translocator (ARNT, HIF‐1β) antibodies. Results of this analysis indicated that the 4S PAH receptor/GNMT forms a hetero‐oligomer (dimer?) with ARNT/HIF‐1β which dissociates in the presence of B[a]P. These observations further indicate the role of GNMT (which has been shown to be multifunctional) and B[a]P in the induction of CYP1A1 and also a potential role of GNMT in the modulation of hypoxia inducible factor‐1 function with respect to the HIF‐1β subunit (ARNT). J. Cell. Biochem. 112: 2015–2018, 2011. © 2011 Wiley‐Liss, Inc.     

Essential roles of the nitric oxide (no)/cGMP/protein kinase G type-Iα (PKG-Iα) signaling pathway and the atrial natriuretic peptide (ANP)/cGMP/PKG-Iα autocrine loop in promoting proliferation and cell survival of OP9 bone marrow stromal cells

Inappropriate signaling conditions within bone marrow stromal cells (BMSCs) can lead to loss of BMSC survival, contributing to the loss of a proper micro-environmental niche for hematopoietic stem cells (HSCs), ultimately causing bone marrow failure. In the present study, we investigated the novel role of endogenous atrial natriuretic peptide (ANP) and the nitric oxide (NO)/cGMP/protein kinase G type-Iα (PKG-Iα) signaling pathway in regulating BMSC survival and proliferation, using the OP9 BMSC cell line commonly used for facilitating the differentiation of HSCs. Using an ANP-receptor blocker, endogenously produced ANP was found to promote cell proliferation and prevent apoptosis. NO donor SNAP (S-nitroso-N-acetylpenicillamine) at low concentrations (10 and 50 μM), which would moderately stimulate PKG activity, protected these BMSCs against spontaneous apoptosis. YC-1, a soluble guanylyl cyclase (sGC) activator, decreased the levels of apoptosis, similar to the cytoprotective effects of low-level NO. ODQ (1H-[1,2,4]oxadiazolo[4,3,-a]quinoxalin-1-one), which blocks endogenous NO-induced activation of sGC and thus lowers endogenous cGMP/PKG activity, significantly elevated apoptotic levels by 2.5- and three-fold. Pre-incubation with 8-Bromo-cGMP or ANP, which bypass the ODQ block, almost completely prevented the ODQ-induced apoptosis. A highly-specific PKG inhibitor, DT-3, at 20, and 30 μM, caused 1.5- and two-fold increases in apoptosis, respectively. ODQ and DT-3 also decreased BMSCs proliferation and colony formation. Small Interfering RNA gene knockdown of PKG-Iα increased apoptosis and decreased proliferation in BMSCs. The data suggest that basal NO/cGMP/PKG-Iα activity and autocrine ANP/cGMP/PKG-Iα are necessary for preserving OP9 cell survival and promoting cell proliferation and migration.