Transcriptional regulation of plant phosphate transporters. (1/227)

Phosphorus is acquired by plant roots primarily via the high-affinity inorganic phosphate (Pi) transporters. The transcripts for Pi transporters are highly inducible upon Pi starvation, which also results in enhanced Pi uptake when Pi is resupplied. Using antibodies specific to one of the tomato Pi transporters (encoded by LePT1), we show that an increase in the LePT1 transcript under Pi starvation leads to a concurrent increase in the transporter protein, suggesting a transcriptional regulation for Pi acquisition. LePT1 protein accumulates rapidly in tomato roots in response to Pi starvation. The level of transporter protein accumulation depends on the Pi concentration in the medium, and it is reversible upon resupply of Pi. LePT1 protein accumulates all along the roots under Pi starvation and is localized primarily in the plasma membranes. These results clearly demonstrate that plants increase their capacity for Pi uptake during Pi starvation by synthesis of additional transporter molecules.  (+info)

Transcriptional repression of the yeast CHA1 gene requires the chromatin-remodeling complex RSC. (2/227)

In eukaryotes, DNA is packaged into chromatin, a compact structure that must be disrupted when genes are transcribed by RNA polymerase II. For transcription to take place, chromatin is remodeled via nucleosome disruption or displacement, a fundamental transcriptional regulatory mechanism in eukaryotic organisms. Here we show that the yeast chromatin-remodeling complex, RSC (remodels the structure of chromatin), isolated on the basis of homology to the SWI/SNF complex, is required for proper transcriptional regulation and nucleosome positioning in the highly inducible CHA1 promoter. In the absence of Sth1p/Nps1p (a homolog of Swi2p/Snf2p) or of Swh3p (a homolog of Swi3p), expression of CHA1 in non-induced cells is increased to a level comparable with that of fully induced cells. Furthermore, in non-induced cells depleted for Sth1p/Nps1p or Swh3p, a nucleosome positioned over the TATA box of the CHA1 promoter is disrupted, an architectural change normally only observed during transcriptional induction. In addition, deletion of the gene-specific activator Cha4p did not affect derepression of CHA1 in cells depleted for Swh3p. Thus, CHA1 constitutes a target for the RSC complex, and we propose that RSC is essential for maintaining a repressive chromatin structure at the CHA1 promoter.  (+info)

Efficient gene delivery to quiescent interleukin-2 (IL-2)-dependent cells by murine leukemia virus-derived vectors harboring IL-2 chimeric envelope glycoproteins. (3/227)

Interleukin-2 (IL-2) is a cytokine that induces the proliferation of certain IL-2 receptor expressing quiescent cells. Human IL-2 was fused to the amino-terminus of amphotropic murine leukemia virus (MLV) envelope glycoproteins. Retroviral vectors were pseudotyped with both the IL-2 chimeric envelope and the wild-type amphotropic MLV envelope. The chimeric IL-2 glycoproteins were incorporated on retroviral vectors and the IL-2-displaying vector particles could bind specifically to cell surface IL-2 receptors. In addition, the IL-2-displaying vectors could infect proliferating cells through amphotropic receptors irrespective of whether the cells expressed the IL-2 receptor. IL-2-displaying vector particles could also transiently stimulate the cell cycle entry and proliferation of several IL-2-dependent cell lines. Finally, retroviral vectors displaying IL-2 could efficiently transduce G0/G1-arrested cells expressing the IL-2 receptor at a 34-fold higher efficiency compared with vectors with unmodified envelopes. This new strategy, whereby C-type retroviral vector particles display a ligand that activates the cell cycle of the target cells at the time of virus entry, may represent an alternative to lentivirus-derived retroviral vectors for the infection of quiescent cells. In addition, upon infection of an heterogeneous population of nonproliferating cells, MLV-retroviral vectors that display cytokines/growth factors will allow the transgene of interest to be integrated specifically in quiescent cells expressing the corresponding cytokine/growth factor receptor.  (+info)

Subcellular redistribution of Pit-2 P(i) transporter/amphotropic leukemia virus (A-MuLV) receptor in A-MuLV-infected NIH 3T3 fibroblasts: involvement in superinfection interference. (4/227)

Amphotropic murine leukemia virus (A-MuLV) utilizes the Pit-2 sodium-dependent phosphate transporter as a cell surface receptor to infect mammalian cells. Previous studies established that infection of cells with A-MuLV resulted in the specific down-modulation of phosphate uptake mediated by Pit-2 and in resistance to superinfection with A-MuLV. To study the mechanisms underlying these phenomena, we constructed plasmids capable of efficiently expressing epsilon epitope- and green fluorescent protein (GFP)-tagged human Pit-2 proteins in mammalian cells. Overexpression of epsilon-epitope-tagged Pit-2 transporters in NIH 3T3 cells resulted in a marked increase in sodium-dependent P(i) uptake. This increase in P(i) uptake was specifically blocked by A-MuLV infection but not by infection with ecotropic MuLV (E-MuLV) (which utilizes a cationic amino acid transporter, not Pit-2, as a cell surface receptor). These data, together with the finding that the tagged Pit-2 transporters retained their A-MuLV receptor function, indicate that the insertion of epitope tags does not affect either retrovirus receptor or P(i) transporter function. The overexpressed epitope-tagged transporters were detected in cell lysates, by Western blot analysis using both epsilon-epitope- and GFP-specific antibodies as well as with Pit-2 antiserum. Both the epitope- and GFP-tagged transporters showed almost exclusive plasma membrane localization when expressed in NIH 3T3 cells, as determined by laser scanning confocal microscopy. Importantly, when NIH 3T3 cells expressing these proteins were productively infected with A-MuLV, the tagged transporters and receptors were no longer detected in the plasma membrane but rather were localized to a punctate structure within the cytosolic compartment distinct from Golgi, endoplasmic reticulum, endosomes, lysosomes, and mitochondria. The intracellular Pit-2 pool colocalized with the virus in A-MuLV-infected cells. A similar redistribution of the tagged Pit-2 proteins was not observed following infection with E-MuLV, indicating that the redistribution of Pit-2 is not directly attributable to general effects associated with retroviral infection but rather is a specific consequence of A-MuLV-Pit-2 interactions.  (+info)

Regulation of the yeast transcriptional factor PHO2 activity by phosphorylation. (5/227)

The induction of yeast Saccharomyces cerevisiae gene PHO5 expression is mediated by transcriptional factors PHO2 and PHO4. PHO4 protein has been reported to be phosphorylated and inactivated by a cyclin-CDK (cyclin-dependent kinase) complex, PHO80-PHO85. We report here that PHO2 can also be phosphorylated. A Ser-230 to Ala mutation in the consensus sequence (SPIK) recognized by cdc2/CDC28-related kinase in PHO2 protein led to complete loss of its ability to activate the transcription of PHO5 gene. Further investigation showed that the Pro-231 to Ser mutation inactivated PHO2 protein as well, whereas the Ser-230 to Asp mutation did not affect PHO2 activity. Since the PHO2 Asp-230 mutant mimics Ser-230-phosphorylated PHO2, we postulate that only phosphorylated PHO2 protein could activate the transcription of PHO5 gene. Two hybrid assays showed that yeast CDC28 could interact with PHO2. CDC28 immunoprecipitate derived from the YPH499 strain grown under low phosphate conditions phosphorylated GST-PHO2 in vitro. A phosphate switch regulates the transcriptional activation activity of PHO2, and mutations of the (SPIK) site affect the transcriptional activation activity of PHO2 and the interaction between PHO2 and PHO4. BIAcore(R) analysis indicated that the negative charge in residue 230 of PHO2 was sufficient to help PHO2 interact with PHO4 in vitro.  (+info)

Role of the mouse ank gene in control of tissue calcification and arthritis. (6/227)

Mutation at the mouse progressive ankylosis (ank) locus causes a generalized, progressive form of arthritis accompanied by mineral deposition, formation of bony outgrowths, and joint destruction. Here, we show that the ank locus encodes a multipass transmembrane protein (ANK) that is expressed in joints and other tissues and controls pyrophosphate levels in cultured cells. A highly conserved gene is present in humans and other vertebrates. These results identify ANK-mediated control of pyrophosphate levels as a possible mechanism regulating tissue calcification and susceptibility to arthritis in higher animals.  (+info)

Scope, limitations and mechanistic aspects of the photo-induced cross-linking of proteins by water-soluble metal complexes. (7/227)

BACKGROUND: Chemical cross-linking is a valuable tool with which to study protein-protein interactions. Recently, a new kind of cross-linking reaction was developed in which the photolysis of associated proteins with visible light in the presence of ammonium persulfate and tris(2,2'-bipyridyl)ruthenium(II) dication or palladium(II) porphyrins results in rapid and efficient covalent coupling (Fancy, D.A. & Kodadek, T. (1999). Proc. Natl. Acad. Sci. USA 96, 6020-6024 and Kim, K., Fancy, D.A. & Kodadek, T. (1999). J. Am. Chem. Soc. 121, 11896-11897). Here, mechanistic and practical aspects of the reaction of importance for its application to biochemical problems are examined. RESULTS: It is shown that the photo-initiated cross-linking chemistry can be optimized for the analysis of protein-protein interactions in crude cell extracts. A number of commonly used epitope or affinity tags survive the reaction in functional form, allowing the simple visualization of the cross-linked products, or their isolation. It is shown that very little light-independent oxidation of protein residues occurs and that significant perturbation of complexes of interest prior to the brief photolysis period does not occur. Finally, evidence is presented that is consistent with a mechanistic model in which ammonium persulfate functions simply as an electron acceptor, facilitating the generation of the key high valent metal complex from the photoexcited species by electron transfer. In the absence of an electron acceptor, a much lower efficiency reaction is observed that appears to involve products resulting from reaction of the excited state metal complex with molecular oxygen. CONCLUSIONS: These results provide useful practical information for chemists and biochemists who may wish to employ this new cross-linking chemistry for the analysis of protein complexes. They also shed new light on the mechanism of this interesting reaction.  (+info)

Histone H2A.Z regulats transcription and is partially redundant with nucleosome remodeling complexes. (8/227)

Nucleosomes impose a block to transcription that can be overcome in vivo by remodeling complexes such as SNF/SWI and histone modification complexes such as SAGA. Mutations in the major core histones relieve transcriptional repression and bypass the requirement for SNF/SWI and SAGA. We have found that the variant histone H2A.Z regulates gene transcription, and deletion of the gene encoding H2A.Z strongly increases the requirement for SNF/SWI and SAGA. This synthetic genetic interaction is seen at the level of single genes and acts downstream of promoter nucleosome reorganization. H2A.Z is preferentially crosslinked in vivo to intergenic DNA at the PH05 and GAL1 loci, and this association changes with transcriptional activation. These results describe a novel pathway for regulating transcription using variant histones to modulate chromatin structure.  (+info)