Jason Correnti

piggyBac transposon mediated transgenesis of the human blood fluke, Schistosoma mansoni

The transposon piggyBac from the genome of the cabbage looper moth Trichoplusia ni has been observed in the laboratory to jump into the genomes of key model and pathogenic eukaryote organisms including mosquitoes, planarians, human and other mammalian cells, and the malaria parasite Plasmodium falciparum. Introduction of exogenous transposons into schistosomes has not been reported but transposon‐mediated transgenesis of schistosomes might supersede current methods for functional genomics of this important human pathogen. In the present study we examined whether the piggyBac trans‐poson could deliver reporter transgenes into the genome of Schistosoma mansoni parasites. A piggyBac donor plasmid modified to encode firefly luciferase under control of schistosome gene promoters was introduced along with 7‐methylguanosine capped RNAs encoding piggyBac transposase into cultured schistosomula by square wave electroporation. The activity of the helper transposase mRNA was confirmed by Southern hybridization analysis of genomic DNA from the transformed schistosomes, and hybridization signals indicated that the piggyBac transposon had integrated into numerous sites within the parasite chromosomes. piggyBac integrations were recovered by retrotransposon‐anchored PCR, revealing characteristic piggyBac TTAA footprints in the vicinity of the endogenous schistosome retro‐transposons Boudicca, sri, and sr2. This is the first report of chromosomal integration of a transgene and somatic transgenesis of this important human pathogen, in this instance accomplished by mobilization of the piggyBac transposon.—Morales, M. E., Mann, V. H., Kines, K.J., Gobert, G. N., Fraser, M. J.,Jr., Kalinna, B. H., Correnti, J. M., Pearce, E. J., Brindley, P. J. piggyBac transposon mediated transgenesis of the human blood fluke, Schistosoma mansoni. FASEB J. 21, 3479–3489 (2007)

Phase Variation of Ag43 Is Independent of the Oxidation State of OxyR

OxyR is a DNA binding protein that differentially regulates a cells response to hydrogen peroxide-mediated oxidative stress. We previously reported that the reduced form of OxyR is sufficient for repression of transcription of agn43 from unmethylated template DNA, which is essential for deoxyadenosine methylase (Dam)- and OxyR-dependent phase variation of agn43. Here we provide evidence that the oxidized form of OxyR [OxyR(ox)] also represses agn43 transcription. In vivo, we found that exogenous addition of hydrogen peroxide, sufficient to oxidize OxyR, did not affect the expression of agn43. OxyR(ox) repressed in vitro transcription but only from an unmethylated agn43 template. The -10 sequence of the promoter and three Dam target sequences were protected in an in vitro DNase I footprint assay by OxyR(ox). Furthermore, OxyR(ox) bound to the agn43 regulatory region DNA with an affinity similar to that for the regulatory regions of katG and oxyS, which are activated by OxyR(ox), indicating that binding at agn43 can occur at biologically relevant concentrations. OxyR-dependent regulation of Ag43 expression is therefore unusual in firstly that OxyR binding at agn43 is dependent on the methylation state of Dam target sequences in its binding site and secondly that OxyR-dependent repression appears to be independent of hydrogen-peroxide mediated oxidative stress and the oxidation state of OxyR.

Dam-dependent phase variation of Ag43 in Escherichia coli is altered in a seqA mutant

In Escherichia coli, phase variation of the outer membrane protein Ag43 encoded by the agn43 gene is mediated by DNA methylation and the global regu‐lator OxyR. Transcription of agn43 occurs (ON phase) when three Dam target sequences in the agn43 regulatory region are methylated, which prevents the repressor OxyR from binding. Conversely, transcription is repressed (OFF) when these Dam target sequences are unmethylated and OxyR binds. A change in expression phase requires a concomitant change in the DNA methylation state of these Dam target sequences. To gain insight into the process of inheritance of the expression phase and the DNA methylation state, protein–DNA interactions at agn43 were examined. Binding of OxyR at agn43 was sufficient to protect the three GATC sequences contained within its binding site from Dam‐dependent methylation in vitro, suggesting that no other factors are required to maintain the unmethylated state and OFF phase. To maintain the methylated state of the ON phase, however, Dam must access the hemimethylated agn43 region after DNA replication, and OxyR binding must not occur. OxyR bound hemimethylated agn43 DNA, but the affinity was severalfold lower than for unmethylated DNA. This presumably contributes to the maintenance of the methylated state but, at the same time, may allow for infrequent OxyR binding and a switch to the OFF phase. Hemimethylated agn43 DNA was also a binding substrate for the sequestration protein SeqA. Thus, SeqA, OxyR and Dam may compete for the same hemimethylated agn43 DNA that is formed after DNA replication in an ON phase cell. In isolates with a mutant seqA allele, agn43 phase variation rates were altered and resulted in a bias to the OFF phase. In part, this can be attributed to the observed decrease in the level of DNA methylation in the seqA mutant.

Insulin resistance in clinical and experimental alcoholic liver disease

Alcoholic liver disease (ALD) is the number one cause of liver failure worldwide; its management costs billions of healthcare dollars annually. Since the advent of the obesity epidemic, insulin resistance (IR) and diabetes have become common clinical findings in patients with ALD; and the development of IR predicts the progression from simple steatosis to cirrhosis in ALD patients. Both clinical and experimental data implicate the impairment of several mediators of insulin signaling in ALD, and experimental data suggest that insulin‐sensitizing therapies improve liver histology. This review explores the contribution of impaired insulin signaling in ALD and summarizes the current understanding of the synergistic relationship between alcohol and nutrient excess in promoting hepatic inflammation and disease.

Ethanol and C2 ceramide activate fatty acid oxidation in human hepatoma cells

Obesogenic lipids and the sphingolipid ceramide have been implicated as potential cofactors in alcoholic liver disease (ALD) patients. However, the mechanisms by which these lipids modulate lipid trafficking in ethanol-treated human liver cells to promote steatosis, an early stage of ALD, are poorly understood. We measured fatty acid (FA) uptake, triglyceride export, FA synthesis and FA oxidation in human hepatoma (VL-17A) cells in response to ethanol and the exogenous lipids oleate, palmitate and C2 ceramide. We found that in combination with ethanol, both oleate and palmitate promote lipid droplet accumulation while C2 ceramide inhibits lipid droplet accumulation by enhancing FA oxidation. Further, using both a pharmacologic and siRNA approach to reduce peroxisome proliferator-activated receptors α (PPARα) gene expression, we demonstrate that C2 ceramide abrogates ethanol-mediated suppression of FA oxidation through an indirect PPARα mechanism. Together, these data suggest that lipids interact differentially with ethanol to modulate hepatocellular lipid droplet accumulation and may provide novel targets for preventing the earliest stage of alcoholic liver disease, alcoholic steatosis.