Maturation of arabidopsis seeds is dependent on glutathione biosynthesis within the embryo

Glutathione (GSH) has been implicated in maintaining the cell cycle within plant meristems and protecting proteins during seed dehydration. To assess the role of GSH during development of Arabidopsis (Arabidopsis thaliana [L.] Heynh.) embryos, we characterized T-DNA insertion mutants of GSH1, encoding the first enzyme of GSH biosynthesis, gamma-glutamyl-cysteine synthetase. These gsh1 mutants confer a recessive embryo-lethal phenotype, in contrast to the previously described GSH1 mutant, root meristemless 1(rml1), which is able to germinate, but is deficient in postembryonic root development. Homozygous mutant embryos show normal morphogenesis until the seed maturation stage. The only visible phenotype in comparison to wild type was progressive bleaching of the mutant embryos from the torpedo stage onward. Confocal imaging of GSH in isolated mutant and wild-type embryos after fluorescent labeling with monochlorobimane detected residual amounts of GSH in rml1 embryos. In contrast, gsh1 T-DNA insertion mutant embryos could not be labeled with monochlorobimane from the torpedo stage onward, indicating the absence of GSH. By using high-performance liquid chromatography, however, GSH was detected in extracts of mutant ovules and imaging of intact ovules revealed a high concentration of GSH in the funiculus, within the phloem unloading zone, and in the outer integument. The observation of high GSH in the funiculus is consistent with a high GSH1-promoterbeta-glucuronidase reporter activity in this tissue. Development of mutant embryos could be partially rescued by exogenous GSH in vitro. These data show that at least a small amount of GSH synthesized autonomously within the developing embryo is essential for embryo development and proper seed maturation.     

Oxidative stress-dependent p66Shc phosphorylation in skin fibroblasts of children with mitochondrial disorders

p66Shc, the growth factor adaptor protein, can have a substantial impact on mitochondrial metabolism through regulation of cellular response to oxidative stress. We investigated relationships between the extent of p66Shc phosphorylation at Ser36, mitochondrial dysfunctions and an antioxidant defense reactions in fibroblasts derived from five patients with various mitochondrial disorders (two with mitochondrial DNA mutations and three with methylglutaconic aciduria and genetic defects localized, most probably, in nuclear genes). We found that in all these fibroblasts, the extent of p66Shc phosphorylation at Ser36 was significantly increased. This correlated with a substantially decreased level of mitochondrial superoxide dismutase (SOD2) in these cells. This suggest that SOD2 is under control of the Ser36 phosphorylation status of p66Shc protein. As a consequence, an intracellular oxidative stress and accumulation of damages caused by oxygen free radicals are observed in the cells.     

Polarized light-stimulated enzymatic hydrolysis of chitin and chitosan

Illumination with white linearly polarized light (WLPL) stimulated chitinase and chitosanase in their degradation of chitin and chitosan, respectively. Enzymes were illuminated at room temperature in separate vessels, then admixed in reactors containing polysaccharides. Hydrolysis of chitosan to glucosamine followed first order kinetics whereas hydrolysis of chitin to N-acetylglucosamine deviated from the first order kinetics. In both cases, an increase in the rate of hydrolysis depended on the illumination time. Efficient degradation required up to 60 min exposure of the enzyme to WLPL.     

Colonic gene expression profile in NHE3-deficient mice: evidence for spontaneous distal colitis

Na+/H+ exchanger 3 (NHE3) provides a major route for intestinal Na+ absorption. NHE3 has been considered a target of proinflammatory cytokines and enteropathogenic bacteria, and impaired NHE3 expression and/or activity may be responsible for inflammation-associated diarrhea. However, the possibility of loss of NHE3 function reciprocally affecting gut immune homeostasis has not been investigated. In this report, we describe that NHE3-deficient mice spontaneously develop colitis restricted to distal colonic mucosa. NHE3(-/-) mice housed in a conventional facility exhibited phenotypic features such as mild diarrhea, occasional rectal prolapse, and reduced body weight. Genomewide microarray analysis identified not only a large group of transport genes that potentially represent an adaptive response, but also a considerable number of genes consistent with an inflammatory response. Histological examination demonstrated changes in the distal colon consistent with active inflammation, including crypt hyperplasia with an increased number of 5-bromo-2'-deoxyuridine-positive cells, diffuse neutrophilic infiltrate with concomitant 15-fold increase in matrix metalloproteinase 8 expression, an increased number of pSer276-RelA-positive cells, and a significant decrease in periodic acid-Schiff-positive goblet cells. Real-time PCR demonstrated elevated expression of inducible nitric oxide synthase (38-fold), TNF-alpha (6-fold), macrophage inflammatory protein-2 (48-fold), and IL-18 (3-fold) in the distal colon of NHE3(-/-) mice. NHE3(-/-) mice showed enhanced bacterial adhesion and translocation in the distal colon. Colitis was ameliorated by oral administration of broad-spectrum antibiotics. In conclusion, NHE3 deficiency leads to an exacerbated innate immune response, an observation suggesting a potentially novel role of NHE3 as a modifier gene, which when downregulated during infectious or chronic colitis may modulate the extent and severity of colonic inflammation.     

A systematic RNAi synthetic interaction screen reveals a link between p53 and snoRNP assembly

TP53 (tumour protein 53) is one of the most frequently mutated genes in human cancer and its role during cellular transformation has been studied extensively. However, the homeostatic functions of p53 are less well understood. Here, we explore the molecular dependency network of TP53 through an RNAi-mediated synthetic interaction screen employing two HCT116 isogenic cell lines and a genome-scale endoribonuclease-prepared short interfering RNA library. We identify a variety of TP53 synthetic interactions unmasking the complex connections of p53 to cellular physiology and growth control. Molecular dissection of the TP53 synthetic interaction with UNRIP indicates an enhanced dependency of TP53-negative cells on small nucleolar ribonucleoprotein (snoRNP) assembly. This dependency is mediated by the snoRNP chaperone gene NOLC1 (also known as NOPP140), which we identify as a physiological p53 target gene. This unanticipated function of TP53 in snoRNP assembly highlights the potential of RNAi-mediated synthetic interaction screens to dissect molecular pathways of tumour suppressor genes.     

Characterization of recombinant nonecotropic murine leukemia viruses from the wild mouse species Mus spretus

The wild mouse species most closely related to the common laboratory strains contain proviral env genes of the xenotropic/polytropic subgroup of mouse leukemia viruses (MLVs). To determine if the polytropic proviruses of Mus spretus contain functional genes, we inoculated neonates with Moloney MLV (MoMLV) or amphotropic MLV (A-MLV) and screened for viral recombinants with altered host ranges. Thymus and spleen cells from MoMLV-inoculated mice were plated on Mus dunni cells and mink cells, since these cells do not support the replication of MoMLV, and cells from A-MLV-inoculated mice were plated on ferret cells. All MoMLV-inoculated mice produced ecotropic viruses that resembled their MoMLV progenitor, although some isolates, unlike MoMLV, grew to high titers in M. dunni cells. All of the MoMLV-inoculated mice also produced nonecotropic virus that was infectious for mink cells. Sequencing of three MoMLV- and two A-MLV-derived nonecotropic recombinants confirmed that these viruses contained substantial substitutions that included the regions of env encoding the surface (SU) protein and the 5' end of the transmembrane (TM) protein. The 5' recombination breakpoint for one of the A-MLV recombinants was identified in RNase H. The M. spretus-derived env substitutions were nearly identical to the corresponding regions in prototypical laboratory mouse polytropic proviruses, but the wild mouse infectious viruses had a more restricted host range. The M. spretus proviruses contributing to these recombinants were also sequenced. The seven sequenced proviruses were 99% identical to one another and to the recombinants; only two of the seven had obvious fatal defects. We conclude that the M. spretus proviruses are likely to be recent germ line acquisitions and that they contain functional genes that can contribute to the production of replication-competent virus.     

Evidence that Ecotropic Murine Leukemia Virus Contamination in TZM-bl Cells Does Not Affect the Outcome of Neutralizing Antibody Assays with Human Immunodeficiency Virus Type 1

The TZM-bl cell line that is commonly used to assess neutralizing antibodies against human immunodeficiency virus type 1 (HIV-1) was recently reported to be contaminated with an ecotropic murine leukemia virus (MLV) (Y. Takeuchi, M. O. McClure, and M. Pizzato, J. Virol. 82:12585-12588, 2008), raising questions about the validity of results obtained with this cell line. Here we confirm this observation and show that HIV-1 neutralization assays performed with a variety of serologic reagents in a similar cell line that does not harbor MLV yield results that are equivalent to those obtained in TZM-bl cells. We conclude that MLV contamination has no measurable effect on HIV-1 neutralization when TZM-bl cells are used as targets for infection.It was recently reported that TZM-bl cells, which are commonly used to assess neutralizing antibodies (Abs) against human immunodeficiency virus type 1 (HIV-1), are contaminated with an ecotropic murine leukemia virus (MLV) (22). TZM-bl (also called JC.53bl-13) is a HeLa cell derivative that was engineered by amphotropic retroviral transduction to express CD4 and CCR5 (17) and was further engineered with an HIV-1-based vector to contain Tat-responsive reporter genes for firefly luciferase (Luc) and Escherichia coli β-galactosidase (24). These engineered features made TZM-bl cells highly susceptible to HIV-1 infection in a readily quantifiable assay for neutralizing Abs. Many published studies used this cell line for assessments of HIV-1 neutralization; these include several recent reports describing the magnitude, breadth, and epitope specificity of the neutralizing Ab response in infected individuals (14, 18-20), neutralization escape (25), and the neutralization phenotype of transmitted/founder viruses (10). TZM-bl cells are also gaining popularity for assessments of vaccine-elicited neutralizing Ab responses (13). The validity of these and other published results, together with a rationale for the continued use of TZM-bl cells in assessing neutralizing Abs against HIV-1, are very dependent on establishing to what extent, if any, MLV contamination affects the outcome of the assay.It was suggested that ecotropic MLV entered TZM-bl cells via the progenitor JC.53 cell line as an amphotropic MLV pseudotype (22). In this regard, JC.53 cells were constructed from HeLa cells in two stages by using ping-pong technology to amplify the pSFF vector derived from the replication-defective and highly truncated Friend spleen focus-forming virus (3). When used with this vector, this procedure has previously resulted in stable vector expression (17) without formation of replication-competent MLV recombinants (8, 11). A panel of HeLa-CD4 clones was made that express different amounts of CD4 and where the high-expression HI-J clone was used to make a derivative panel of clones (termed JC), including JC.53, that expressed diverse levels of CCR5 (9, 16, 17). In addition, the HeLa-CD4 clone HI-R that expressed low levels of CD4 was used to make another panel of CCR5-expressing clones (termed RC). To investigate this newly reported issue, cell extracts from these clonal panels and from TZM-bl cells were analyzed for MLV Gag antigens by Western immunoblotting. Representative data, as shown in Fig. ​Fig.1A,1A, confirm that JC.53 and TZM-bl cells express MLV Gag antigens, whereas the progenitor HI-J clone of HeLa-CD4 cells and many but not all of the other HeLa-CD4/CCR5 clones in the JC panel lack MLV antigens.Open in a separate windowFIG. 1.Characterization of HeLa clones for MLV Gag expression, HIV-1 susceptibility, and cell surface expression of HIV-1 fusion receptors. (A) MLV Gag antigen expression in HeLa cells and derivative clones expressing CD4 or CD4 and CCR5. Cell lysates were prepared from the cell clones and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blotting with Abs to MLV Gag antigens (upper blot). The lysates were also probed with anti-tubulin antibodies (lower blot). Lane 1, HeLa cells; lanes 2 and 3, HeLa CD4 clones HI-R and HI-J, respectively; lanes 4, 5, and 6, HeLa-CD4/CCR5 clones JC.10, JC.48, and JC.53, respectively; lane 7, TZM-bl cells; lane 8, psi-2 packaging cells positive for MLV Gag. (B) HIV-1 infectivity on the HeLa-CD4/CCR5 JC panel. Target cells were infected with HIV-1 isolate JRCSF that had been produced from clone JC.53 cells (black) or with JRCSF produced from transfected HEK293T cells (red). The target cells were also infected with the JR-FL isolate produced from peripheral blood mononuclear cells (PBMC; green). The HeLa-CD4/CCR5 target cells had a CCR5 expression range of 2 × 10³ (clone JC.10) to 1.3 × 10⁵ (clones JC.53 and TZM-bl) CCR5 molecules/cell. Each set of three data points at a given CCR5 expression level represents a single HeLa-CD4/CCR5 JC clone. None of the HIV-1 isolates was able to infect HeLa-CD4 cells lacking CCR5. The blue asterisks indicate clones that are negative for MLV Gag proteins. Clones JC.48 (used for subsequent infection and neutralization assays) and JC.53 (progenitor of TZM-bl cells) are specifically labeled. (C) Surface expression of CD4, CCR5, and CXCR4 on TZM-bl and JC.48 cells was assessed by flow cytometry using the same stocks of cells that were used in infection and neutralization assays in Fig. ​Fig.2.2. Surface staining was performed with phycoerythrin-conjugated mouse monoclonal Abs to CD4, CCR5 (CD195), and CXCR4 (CD184). Background staining was performed with isotype-matched control Abs. All Abs for flow cytometry were purchased from BD Biosciences Pharmingen (San Diego, CA). Results are shown as the mean fluorescence intensity (MFI) of positive cells. Most cells (>90%) stained positive in each case.Initial studies of HI-R cells and other clonal panels that were made using these methods also suggested a lack of MLV antigens (data not shown). We then determined the titers of replication-competent HIV-1_JRCSF preparations using JC.53 and TZM-bl cells as well as other representative HeLa-CD4/CCR5 clones in the JC panel. The results are plotted in Fig. ​Fig.1B1B as a function of cellular CCR5 content. Clones having more than a low threshold level of ∼8,000 CCR5/cell were equally susceptible to infection regardless of whether they contained MLV antigens, clearly demonstrating that HIV-1_JRCSF titers were not significantly affected by MLV. As expected, titers obtained with JC.53 and TZM-bl cells were also equivalent. In addition, these results demonstrate that HIV-1_JRCSF preparations made in JC.53 cells and in cells lacking MLV antigens (i.e., HEK293T cells and human peripheral blood mononuclear cells) were unable to infect HeLa cells lacking CCR5. The results in Fig. ​Fig.1B1B were expected because previous studies demonstrated that ecotropic MLVs cannot infect human cells or even bind to the human CAT-1 receptor paralog (1, 6, 21, 23). Moreover, it has been shown that ecotropic host range MLVs do not interfere with superinfection by any retrovirus capable of infecting human cells, including gibbon ape leukemia virus, amphotropic MLV, baboon endogenous virus, and feline leukemia virus subgroup C (21). In view of the report by Takeuchi et al. (22), we were surprised to find that JC.53 and TZM-bl cells express very small amounts of ecotropic MLV Env glycoproteins, as indicated by immunofluorescence microscopy and by their resistance to complement-dependent killing by a cytotoxic antiserum specific for MLV envelope glycoproteins (6). Nevertheless, the cell clones that contained MLV Gag all released ecotropic host range virions that replicated in murine NIH 3T3 cells but not in human cells (data not shown).To determine whether MLV affects the measurement of neutralizing Abs in TZM-bl cells, parallel assays were performed in TZM-bl and JC.48 cells; these latter cells were determined to be MLV free by Western blot analysis (Fig. ​(Fig.1)1) and by an inability to transfer MLV infection to NIH 3T3 cells (data not shown). Because JC.48 cells express CCR5 at somewhat lower levels than JC.53 cells (∼2-fold lower; Fig. ​Fig.1B),1B), it may be expected that they would be less susceptible to HIV-1 infection than are TZM-bl cells. Differences in susceptibility to HIV-1 infection may require the use of adjusted virus doses to achieve equivalent assay performance when measuring neutralizing Abs. Indeed, levels of CD4 and CCR5 were approximately twofold lower on JC.48 cells than on TZM-bl cells, whereas levels of CXCR4 were approximately equal (Fig. ​(Fig.1C).1C). We therefore measured the susceptibility of both cell lines to infection by three molecularly cloned Env-pseudotyped viruses, each bearing an Env from a different CCR5-tropic HIV-1 subtype B virus (SF162.LS, Bal.26, and QH0692.42). Infection was quantified by Luc activity expressed as relative luminescence units (RLU). Because JC.48 cells do not contain a reporter gene, the Env-pseudotyped viruses were prepared by cotransfection with the NL4-3.Luc.R-E- reporter backbone plasmid (7). Identical Luc-containing, Env-pseudotyped virus stocks were used in both cell lines. As shown in Fig. ​Fig.2A,2A, the infectivity of each pseudotyped virus was somewhat diminished in JC.48 cells compared to the infectivity in TZM-bl cells. Nonetheless, the levels of infectivity in JC.48 cells remained acceptable for neutralization assays.Open in a separate windowFIG. 2.HIV-1 infectivity and neutralization in TZM-bl and JC.48.CD4.CCR5 cells. (A) TZM-bl and JC.48 cells were incubated with serial fourfold dilutions (11 dilutions total) of three HIV-1 Env-pseudotyped viruses in quadruplicate in 96-well culture plates. Luc activity was measured after 48 h of incubation and is expressed as RLU after subtraction of background luminescence from cell control wells. Squares, TZM-bl cells; triangles, JC.48 cells. (B) Neutralization assays were performed with three HIV-1 Env-pseudotyped viruses in either TZM-bl or JC.48 cells. Input virus doses were adjusted to yield equivalent infectivity in both cell lines. Black bars, TZM-bl; gray bars, JC.48. Top panel: sCD4, monoclonal Abs, and HIVIG (purified immunoglobulin G from pooled HIV-1-positive plasmas). Bottom panel: individual HIV-1-positive plasma samples. The same three stocks of virus were used in both experiments. All three Env-pseudotyped viruses were prepared with the NL4-3.Luc.R-E- reporter backbone plasmid.With this information in hand, neutralization assays were performed in JC.48 and TZM-bl cells using adjusted virus doses that yielded equivalent infectivity levels in both cell lines. These neutralization assays were performed in a 96-well format as described previously (12), where the 50% inhibitory dose (ID₅₀) was reported as either the concentration or sample dilution at which RLU were reduced by 50% compared to RLU in virus control wells (cells plus virus without test sample) after subtraction of background RLU from cell control wells (cells only). A wide variety of serologic reagents was tested, including sCD4, a monoclonal Ab to the CD4 binding site of gp120 (immunoglobulin G1b12) (15); a monoclonal Ab that recognizes a glycan-specific epitope on gp120 (2G12) (5); two monoclonal Abs that recognize adjacent epitopes in the membrane proximal external region of gp41 (2F5 and 4E10) (2, 4); and serum samples from seven antiretroviral-naive HIV-1-infected individuals. As shown in Fig. ​Fig.2B,2B, results in the two cell lines were similar for all three viruses and all serologic reagents tested. Indeed, ID₅₀ values in the two cell types agreed within twofold, which is within the normal range of variability of the assay. These results indicate that equivalent neutralization results were obtained in both cell lines.In summary, we found no evidence that ecotropic MLV contamination in TZM-bl cells has a measurable effect on HIV-1 neutralization when these cells are used as targets for infection. This outcome indicates that the presence of ecotropic MLV in TZM-bl cells does not alter the ability of Ab to neutralize HIV-1, nor does it interfere with the detection of neutralization by using HIV-1 Tat-regulated reporter gene expression in a single-cycle infection assay. However, we discourage the use of TZM-bl cells to generate HIV-1 stocks, because the latter would likely be contaminated with ecotropic MLV and contain pseudovirions with mixtures of HIV-1 and ecotropic MLV Env glycoproteins. For this reason, we have begun efforts to produce an uncontaminated, second-generation panel of HeLa-CD4/CCR5 cell clones that express diverse amounts of CCR5 and to isolate a TZM-bl variant lacking MLV antigens.     

Mapping of multiple subunits of the neuronal nicotinic acetylcholine receptor to chromosome 15 in man and chromosome 9 in mouse

The alpha 3, alpha 5, and beta 4 genes (human gene symbols CHRNA3, CHRNA5, and CHRNB4 respectively; mouse gene symbols Acra-3, Acra-5, and Acrb-4, respectively) are members of the nicotinic acetylcholine receptor gene family and are clustered within a 68-kb segment of the rat genome (Boulter et al., 1990, J. Biol. Chem. 265:4472). By somatic cell hybrid analysis, three cDNAs corresponding to these genes were used to map the homologous loci to human chromosome 15 and to mouse chromosome 9. Linkage analysis using CEPH pedigrees showed that the CHRNA5 gene was closely linked to the following chromosome 15 loci: D15S46, D15S52, D15S28, D15S34, and D15S35. Using interspecies crosses in mice, the Acra-5 gene was found closely linked to the Mpi-1 locus. The mapping of these members of a neurotransmitter receptor gene family may facilitate the identification of relationships between the neurotransmitter receptors and murine or human phenotypes.     

Connexin 43 and metabolic effect of fatty acids in stressed endothelial cells

Changes in the inner mitochondrial membrane potential (∆ψ) may lead either to apoptosis or to protective autophagy. Connexin 43 (Cx43), a gap junction protein, is suggested to affect mitochondrial membrane permeability. The aim of our study was to analyze Cx43 gene expression, Cx43 protein localization and mitochondrial function in the human endothelial cells stressed by dietary-free fatty acids (FFA) and TNFα. Human endothelial cells (HUVECs) were incubated with (10–30 uM) palmitic (PA), oleic (OA), eicosapentaenoic (EPA) or arachidonic (AA) acids for 24 h. TNFα (5 ng/ml) was added at the last 4 h of incubation. The Cx43 gene expression was analyzed by the quantitative real-time PCR. The Cx43 protein concentrations in whole cells and in the isolated mitochondria were measured. Changes in ∆ψ and Cx43 localization were analyzed by flow cytometry or fluorescence microscopy. Generated ATP was measured by a luminescence assay. TNFα, PA and OA significantly decreased ∆ψ, while AA (P = 0.047) and EPA (P = 0.004) increased ∆ψ value. Preincubation with EPA or AA partially prevented the TNFα-induced decrease of ∆ψ. Incubation with AA resulted in up-regulation of the Cx43 gene expression. AA or PA significantly increased Cx43 protein content; however, presence of TNFα in general aggravated the negative effect of FFA. Only EPA was found to increase ATP generation in HUVECs. The fatty acid-specific induction of changes in Cx43 expression and protein concentration as well as the normalization of ∆ψ and increase of ATP generation seem to be the separate, independent mechanisms of FFA-mediated modulatory effect in the human endothelial cells pathology.