Ammonium, calcium, and leaf senescence in rice

The possible involvement of calcium in the regulation of ammonium-promoted senescence of detached rice leaves was investigated. Calcium effectively reduced ammonium-promoted senescence of detached rice leaves. The effect of ammonium on the senescence was also significantly reduced by the calcium ionophore A23187. Ammonium-promoted senescence of detached rice leaves may be mediated through blocking the entrance of calcium ions into the cytosol.     

Human Dickkopf-1 (huDKK1) protein: characterization of glycosylation and determination of disulfide linkages in the two cysteine-rich domains

Human Dickkopf‐1 (huDKK1), an inhibitor of the canonical Wnt‐signaling pathway that has been implicated in bone metabolism and other diseases, was expressed in engineered Chinese hamster ovary cells and purified. HuDKK1 is biologically active in a TCF/lef‐luciferase reporter gene assay and is able to bind LRP6 coreceptor. In SDS‐PAGE, huDKK1 exhibits molecular weights of 27–28 K and 30 K at ～ 1:9 ratio. By MALDI‐MS analysis, the observed molecular weights of 27.4K and 29.5K indicate that the low molecular weight form may contain O‐linked glycans while the high molecular weight form contains both N‐ and O‐linked glycans. LC‐MS/MS peptide mapping indicates that ～ 92% of huDKK1 is glycosylated at Asn²²⁵ with three N‐linked glycans composed of two biantennary forms with 1 and 2 sialic acid (23% and 60%, respectively), and one triantennary structure with 2 sialic acids (9%). HuDKK1 contains two O‐linked glycans, GalNAc (sialic acid)‐Gal‐sialic acid (65%) and GalNAc‐Gal[sialic acid] (30%), attached at Ser 30 as confirmed by β‐elimination and targeted LC‐MS/MS. The 10 intramolecular disulfide bonds at the N‐ and C‐terminal cysteine‐rich domains were elucidated by analyses including multiple proteolytic digestions, isolation and characterization of disulfide‐containing peptides, and secondary digestion and characterization of selected disulfide‐containing peptides. The five disulfide bonds within the huDKK1 N‐terminal domain are unique to the DKK family proteins; there are no exact matches in disulfide positioning when compared to other known disulfide clusters. The five disulfide bonds assigned in the C‐terminal domain show the expected homology with those found in colipase and other reported disulfide clusters.     

Caveolin‐1 down‐regulation is required for Wnt5a‐Frizzled 2 signalling in Ha‐RasV12‐induced cell transformation

Caveolin‐1 (Cav1) is down‐regulated during MK4 (MDCK cells harbouring inducible Ha‐Ras^V12 gene) transformation by Ha‐Ras^V12. Cav1 overexpression abrogates the Ha‐Ras^V12‐driven transformation of MK4 cells; however, the targeted down‐regulation of Cav1 is not sufficient to mimic this transformation. Cav1‐silenced cells, including MK4/shCav1 cells and MDCK/shCav1 cells, showed an increased cell area and discontinuous junction‐related proteins staining. Cellular and mechanical transformations were completed when MDCK/shCav1 cells were treated with medium conditioned by MK4 cells treated with IPTG (MK4+I‐CM) but not with medium conditioned by MK4 cells. Nanoparticle tracking analysis showed that Ha‐Ras^V12‐inducing MK4 cells increased exosome‐like microvesicles release compared with their normal counterparts. The cellular and mechanical transformation activities of MK4+I‐CM were abolished after heat treatment and exosome depletion and were copied by exosomes derived from MK4+I‐CM (MK4+I‐EXs). Wnt5a, a downstream product of Ha‐Ras^V12, was markedly secreted by MK4+I‐CM and MK4+I‐EXs. Suppression of Wnt5a expression and secretion using the porcupine inhibitor C59 or Wnt5a siRNA inhibited the Ha‐Ras^V12‐ and MK4+I‐CM‐induced transformation of MK4 cells and MDCK/shCav1 cells, respectively. Cav1 down‐regulation, either by Ha‐Ras^V12 or targeted shRNA, increased frizzled‐2 (Fzd2) protein levels without affecting its mRNA levels, suggesting a novel role of Cav1 in negatively regulating Fzd2 expression. Additionally, silencing Cav1 facilitated the internalization of MK4+I‐EXs in MDCK cells. These data suggest that Cav1‐dependent repression of Fzd2 and exosome uptake is potentially relevant to its antitransformation activity, which hinders the activation of Ha‐Ras^V12‐Wnt5a‐Stat3 pathway. Altogether, these results suggest that both decreasing Cav1 and increasing exosomal Wnt5a must be implemented during Ha‐Ras^V12‐driven cell transformation.     

Disulfide Bond Formation at the C Termini of Vaccinia Virus A26 and A27 Proteins Does Not Require Viral Redox Enzymes and Suppresses Glycosaminoglycan-Mediated Cell Fusion

Vaccinia virus A26 protein is an envelope protein of the intracellular mature virus (IMV) of vaccinia virus. A mutant A26 protein with a truncation of the 74 C-terminal amino acids was expressed in infected cells but failed to be incorporated into IMV (W. L. Chiu, C. L. Lin, M. H. Yang, D. L. Tzou, and W. Chang, J. Virol 81:2149-2157, 2007). Here, we demonstrate that A27 protein formed a protein complex with the full-length form but not with the truncated form of A26 protein in infected cells as well as in IMV. The formation of the A26-A27 protein complex occurred prior to virion assembly and did not require another A27-binding protein, A17 protein, in the infected cells. A26 protein contains six cysteine residues, and in vitro mutagenesis showed that Cys441 and Cys442 mediated intermolecular disulfide bonds with Cys71 and Cys72 of viral A27 protein, whereas Cys43 and Cys342 mediated intramolecular disulfide bonds. A26 and A27 proteins formed disulfide-linked complexes in transfected 293T cells, showing that the intermolecular disulfide bond formation did not depend on viral redox pathways. Finally, using cell fusion from within and fusion from without, we demonstrate that cell surface glycosaminoglycan is important for virus-cell fusion and that A26 protein, by forming complexes with A27 protein, partially suppresses fusion.Vaccinia virus, the prototype of the Orthopoxvirus genus of the family Poxviridae, infects many cell lines and animals (13) and produces several forms of infectious particles, among which the intracellular mature virus (IMV) is the most abundant form inside cells. The IMV can be wrapped with additional Golgi membrane, transported through microtubules, and released from cells as extracellular enveloped viruses (10). The IMV has evolved to enter host cells through plasma membrane fusion (1, 3, 12, 29, 47) or endocytosis (11, 48). Recently, Mercer et al. reported that IMV entered HeLa cells through apoptotic mimicry and macropinocytosis (32), and Huang et al. reported that IMV enters into HeLa cells through a dynamin-dependent fluid-phase endocytosis that required the cellular protein VPEF (22).The IMV contains more than 75 viral proteins. Of these, more than 10 viral envelope proteins are known to be involved in vaccinia virus entry into cells (6, 34, 55). Vaccinia virus contains at least five attachment proteins, with H3, A27, and D8 binding to cell surface glycosaminoglycans (GAGs) (7, 21, 28), A26 protein binding to the extracellular matrix protein laminin (5), and L1 protein binding to unidentified cell surface molecules (14). A27 protein also binds to the viral A17 protein through its C-terminal region (35, 50), and it was recently shown that the coexpression of A17 and A27 proteins resulted in cell fusion in transiently transfected 293T cells (27). In this study, we demonstrate the formation through disulfide bonds of complexes between two viral attachment proteins, A26 and A27, and we determine the cysteine residues that are critical for these disulfide bonds. We also address the biological role of the A26-A27 protein complex formation in cell fusion regulation.     

Propylene oxide production from propylene by immobilized whole cells of Methylosinus sp. CRL 31 in a gas-solid bioreactor

Summary Methanotrophic bacteria have been shown to oxidize gaseous alkenes to the corresponding epoxides utilizing an NADH₂-dependent methane monooxygenase. A cell paste of methane-grown methylotrophs was coated on porous glass beads. The production of propylene oxide from propylene was performed in a gas-solid bioreactor to ensure continuous production and removal of product epoxide from the microenvironment of the biocatalyst. The amount of propylene oxide produced before cofactor regeneration was between 120–145 moles/20 mg cells in about 10 h depending on the microbial strains used. The conversion rate for propylene was 2.7%. Regeneration of cofactor NADH₂ was performed in the bioreactor with the vapor of a cosubstrate, methanol.     

Modulation of in vivo IgG crystallization in the secretory pathway by heavy chain isotype class switching and N-linked glycosylation

Crystalline bodies (CBs) can develop in the endoplasmic reticulum (ER) of antibody-producing cells. Although this phenotype is often reported in association with plasma cell dyscrasias and other hematological disorders, the details of CB biogenesis and CB's roles in pathophysiology remain poorly understood. Using an imaging-based screening method, we identified a secretion-competent human IgG2/λ clone that develops spindle-shaped intracellular crystals in transiently-transfected HEK293 cells upon Brefeldin A treatment. When stably overexpressed from CHO cells, the IgG2/λ clone spontaneously produced spindle-shaped CBs in the ER. Some CBs were released to the extracellular space while remaining enclosed by the membranes of secretory pathway origin. Structural modeling on the variable-region did not uncover prominent surface characteristics such as charge clusters. In contrast, alterations to the constant domain-encoded properties revealed their modulatory roles in CB-inducing propensities and CB morphology. For example, deletion of the entire Fc domain changed the morphology of CBs into thin filaments. Elimination of an N-linked glycan by a N297A mutation promoted Russell body biogenesis accompanied by marked reduction in IgG secretion. Isotype class switching from the original IgG2 to IgG1 and IgG4 changed the crystal morphology from spindle-shaped to long needle and acicular shaped, respectively. The IgG3 version, in contrast, suppressed the CB formation. Either the HC or LC alone or the Fc-domain alone did not trigger CB biogenesis. An IgG's in vivo crystal morphology and crystallization propensity can thus be modulated by the properties genetically and biochemically encoded in the HC constant region.