Wolfgang Liebetrau scite author profile

The Saccharomyces cerevisiae PGMl and PGM2 genes encoding two phosphoglucomutase isoenzymes have been isolated and sequenced. The derived protein sequences are closely related to one another and show distinct sequence similarities to the human and rabbit phosphoglucomutases, especially in the region supposed to constitute the active site. PGMl and PGM2 are located on chromosomes XI and XIII, respectively, just upstream of the known genes YPKl and YKR2 coding for a pair of closely related putative protein kinases. These observations suggest that an extended region of DNA arose by the process of gene duplication. Cells deleted for both, PGMl and PGM2, could not grow on galactose. No residual phosphoglucomutase activity could be measured in crude extracts or in permeabilized cells of pgmll2 double mutants. Unexpectedly, growth with glucose was not impaired and the mutant cells were still able to accumulate trehalose and glycogen, although at a reduced level. Two further genes could be isolated and characterized which when over-expressed on a multi-copy plasmid could restore growth on galactose of the pgml/2 double deletion mutant. Multi-copy complementation was due to a sharply increased level of phosphoglucomutase activity, Partial sequencing and characterization of the two genes revealed one of them to be SEC53 encoding phosphomannomutase. No extended sequence similarities could be found in the databases for the second gene. However, part of the derived amino acid sequence contained a region of high similarity to the active-site consensus sequence of hexosephosphate mutases from different organism. Further investigations suggest that a complex network of mutases exist in yeast which interact and can partially substitute for each other.Phosphoglucomutase (PGM) catalyzes the reversible interconversion of glucose-1-phosphate (glucose-1 -P) and glucose-6-phosphate (glucose-6-P). PGM is needed to convert glucose-1-P which is the product of galactose and glycogen catabolism to glucose-6-P which can be metabolized by the glycolytic degradation pathway (Tsoi and Douglas, 1964). The reverse direction is required for the synthesis of glycogen, trehalose, cell-wall glucans and glycoproteins from fermentable or gluconeogenic carbon sources (Algranati and Cabib, 1962;Lillie and Pringle, 1980;Ballou, 1982;Tanner and Lehle, 1987) because glucose-1-P is needed for the synthesis of UDP-glucose which serves as an activated precursor for the formation of glycosidic bonds. Thus, PGM is required for both the formation of storage and structural carbohydrates from glucose-6-P on the one hand and the formation of glucose-6-P from galactose and glycogen on the other.

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High-throughput Functional Genomics Identifies Genes That Ameliorate Toxicity Due to Oxidative Stress in Neuronal HT-22 Cells

Zitzler¹,

Link²,

Liebetrau³

et al. 2004

Molecular & Cellular Proteomics

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We describe a novel genetic screen that is performed by transfecting every individual clone of an expression clone collection into a separate population of cells in a highthroughput mode. We combined high-throughput functional genomics with experimental validation to discover human genes that ameliorate cytotoxic responses of neuronal HT-22 cells upon exposure to oxidative stress. A collection of 5,000 human cDNAs in mammalian expression vectors were individually transfected into HT-22 cells, which were then exposed to H 2 O 2 . Five genes were found that are known to be involved in pathways of detoxification of peroxide (catalase, glutathione peroxidase-1, peroxiredoxin-1, peroxiredoxin-5, and nuclear factor erythroid-derived 2-like 2). The presence of those genes in our "hit list" validates our screening platform. In addition, a set of candidate genes was found that has not been previously described as involved in detoxification of peroxide. One of these genes, which was consistently found to reduce H 2 O 2 -induced toxicity in HT-22, was GFPT2. This gene is expressed at significant levels in the central nervous system (CNS) and encodes glutamine-fructose-6-phosphate transaminase (GFPT) 2, a rate-limiting enzyme in hexosamine biosynthesis. GFPT has recently also been shown to ameliorate the toxicity of methylmercury in Saccharomyces cerevisiae. Methylmercury causes neuronal cell death in part by protein modification as well as enhancing the production of reactive oxygen species (ROS). The protective effect of GFPT2 against H 2 O 2 toxicity in neuronal HT-22 cells may be similar to its protection against methylmercury in yeast. Thus, GFPT appears to be conserved among yeast and men as a critical target of methylmercury and ROS-induced cytotoxicity.

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P53 Activates Fanconi Anemia Group C Gene Expression

Liebetrau

Budde

Savoia

et al. 1997

Human Molecular Genetics

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The tumor suppressor protein p53 (wtp53) can bind to specific target sequences and activate transcription of genes adjacent to these DNA elements. Two p53 binding sites are present in the gene coding for the Fanconi anemia complementation group C (FAC), one in the promoter region (from -1295 to -1266) and one in the coding region of FAC (from +1828 to +1848). Gel shift experiments show that wtp53 binds to the p53 target sequence in the promoter region of the FAC gene. We have investigated whether binding of p53 to these target sites may affect expression of the FAC gene. Transfection experiments show that overexpression of wtp53 in human diploid fibroblasts and lymphoblasts augments transcription of the FAC gene up to three-fold. The transfection efficacy was approximately 15% for both cell types. The FAC expression activity per transformed cell was stimulated to an estimated level of 18- to 21-fold upon overexpression of p53. The tumor-derived p53 mutants, His175 and His273, that fail to bind DNA showed only a reduced stimulatory activity on FAC transcription. Luciferase assays demonstrated that interaction of p53 with its target site in the FAC promoter does not modulate the promoter activity. We suggest that the p53 binding site contributes to, but may not be an absolute prerequisite for p53-directed transcriptional activation. We conclude that the FAC gene can be added to the list of genes that interact with p53.

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Dexamethasone-enhanced sensitivity of mouse hippocampal HT22 cells for oxidative stress is associated with the suppression of nuclear factor-κB

Braun

Liebetrau

Berning

et al. 2000

Neuroscience Letters

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Mutagenic activity of ambient oxygen and mitomycin C in Fanconi's anaemia cells

Liebetrau¹,

Rünger

Mehling³

et al. 1997

Mutagenesis

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Cellular evidence suggests that Fanconi's anaemia (FA) might be a condition of increased oxygen sensitivity. In order to test this hypothesis, a common shuttle vector assay with the plasmid pZ189 was utilized. We transfected intact, circular plasmid into FA and control lymphoblast and fibroblast host cells maintained at 5 and 20% O2 (v/v). In parallel experiments, host cells were exposed to different concentrations of mitomycin C (MMC), a cross-linking agent towards which FA cells are known to be hypersensitive. Baseline mutation frequencies at 20% oxygen were significantly higher in plasmids passaged through FA lymphoblasts or FA fibroblasts in comparison with passage through the corresponding control cells. Lowering the oxygen concentration during the 48 h transfection period to 5% resulted in a significant decrease of mutation frequencies in plasmids passaged through FA cells. Sequence analysis of plasmids recovered from FA lymphoblasts revealed a mutation hot spot (22% of point mutations with G:C to A:T base substitutions) at base 117 of the supF tRNA gene. This hot spot was present only at 20% oxygen. 59% of the base changes at the hot spot and 39% of the changes elsewhere in the supF gene were C to T transitions (the corresponding figures are 0 and 27% at 5% oxygen), the most common type of base change induced by oxygen. The mutation spectrum observed suggests a role for 8-hydroxydeoxyguanosine in G:C to A:T base substitutions: at 20% oxygen, FA cells displayed 4 times as many G:C to T:A transversions than FA cells kept at 5% O2. In MMC treated cells the decrease in plasmid survival is dose dependent and more pronounced in FA than control cells. Mutation analysis shows similar rates of deletions for both control and FA cells. However, FA cells generate a specific type of deletion whose breakpoint involves an indirect repeat that corresponds to a heptamer signal sequence commonly seen at recombination sites. Together our data provide compelling evidence that the genetic defect in FA causes oxygen sensitivity and recombinational types of DNA lesions following exposure to MMC.

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