Gene expression after intrarenal injection of plasmid DNA in the rat

HDAC5 inactivates CYR61-regulated CD31/mTOR axis to prevent the occurrence of preeclampsia

Our study was to pinpoint the significance of histone deacetylase 5 (HDAC5) affecting the pathogenesis of preeclampsia (PE) via CD31/mammalian target of rapamycin (mTOR) axis by regulating cysteine-rich angiogenic inducer 61 (CYR61). Expression of HDAC5, CYR61, and CD31/mTOR in placental tissues of patients with PE and trophoblast cells HTR-8/SVneo cells was determined first followed by their interaction analysis. Following different transfection, the significance of HDAC5 in cell functions was assayed in relation to CYR61 and CD31/mTOR. An in vivo PE mouse model was constructed for further validation. The clinical tissue and in vitro cell experimentations discovered that HDAC5 was downregulated in placental tissues of PE patients and trophoblast cells, while CYR61, CD31, mTOR, and p-mTOR displayed upregulation. After overexpression of HDAC5, trophoblast cell functions were enhanced. HDAC5 reduced the acetylation enrichment of H3K27 to inhibit the expression of CYR61. Furthermore, CYR61 promoted the activation of CD31/mTOR axis, thereby inhibiting HTR-8/SVneo cell functions. The in vivo rat model confirmed the above alterations. Taken together, HDAC5 contributes to downregulation of CYR61 through histone deacetylation, inactivating CD31/mTOR axis, which prevents the occurrence and development of PE.

RNA interference with special reference to combating viruses of crustacea

RNA interference has evolved from being a nuisance biological phenomenon to a valuable research tool to determine gene function and as a therapeutic agent. Since pioneering observations regarding RNA interference were first reported in the 1990s from the nematode worm, plants and Drosophila, the RNAi phenomenon has since been reported in all eukaryotic organisms investigated from protozoans, plants, arthropods, fish and mammals. The design of RNAi therapeutics has progressed rapidly to designing dsRNA that can specifically and effectively silence disease related genes. Such technology has demonstrated the effective use of short interfering as therapeutics. In the absence of a B cell lineage in arthropods, and hence no long term vaccination strategy being available, the introduction of using RNA interference in crustacea may serve as an effective control and preventative measure for viral diseases for application in aquaculture.

Conjugated bile acids regulate hepatocyte glycogen synthase activity in vitro and in vivo via Galphai signaling

The regulation of glycogen synthase activity by bile acids in primary hepatocytes and in the intact liver was investigated. Bile acids (deoxycholic acid, DCA; taurocholic acid, TCA) activated AKT and glycogen synthase (GS) in primary rat hepatocytes. Incubation with a phosphatidyl inositol-3 kinase inhibitor or expression of dominant-negative AKT in primary rat hepatocytes abolished activation of AKT and GS by DCA and TCA. TCA, but not DCA, activated Galpha(i) proteins in primary rat hepatocytes. Treatment of cells with pertussis toxin or expression of dominant-negative Galpha(i) blocked TCA-induced activation of AKT and of GS but did not alter AKT or GS activation caused by DCA. TCA caused activation of AKT and GS in intact rat liver. Expression of dominant-negative Galpha(i) reduced TCA-induced activation of AKT and of GS in intact rat liver. Together, our findings demonstrate that bile acids are physiological regulators of glycogen synthase in rat liver and that conjugated bile acids use a Galpha(i)-coupled G protein-coupled receptor to regulate GS activity in vitro and in vivo.

Approaches and methods in gene therapy for kidney disease

Renal gene therapy may offer new strategies to treat diseases of native and transplanted kidneys. Several experimental techniques have been developed and employed using nonviral, viral, and cellular vectors. The most efficient vector for in vivo transfection appears to be adenovirus. Glomeruli, blood vessels, interstitial cells, and pyelum can be transfected with high efficiency. In addition, electroporation and microbubbles with ultrasound, both being enhanced naked plasmid techniques, offer good opportunities. Trapping of mesangial cells into the glomeruli as well as natural targeting of monocytes or macrophages to inflamed kidneys are elegant methods for site-specific delivery of genes. For gene therapy in kidney transplantation, hemagglutinating virus of Japan liposomes are efficient vectors for tubular transfection, whereas enhanced naked plasmid techniques are suitable for glomerular transfection. However, adenovirus offers the best opportunities in a renal transplantation setup because varying parameters of graft perfusion allows targeting of different cell types. In renal grafts, lymphocytes can be used for selective targeting to sites of inflammation. In conclusion, for both in vivo and ex vivo renal transfection, enhanced naked plasmids and adenovirus offer the best perspectives for effective clinical application. Moreover, the development of safer, nonimmunogenic vectors and the large-scale production could make clinical renal gene therapy a realistic possibility for the near future.

Hydrodynamic delivery of DNA

Hydrodynamic delivery is an efficient and inexpensive procedure to deliver a wide range of nucleic acids to hepatic tissues and other organs in vivo. The successful application of hydrodynamic delivery is dependent on the rapid injection of a large aqueous volume containing DNA, RNA or other molecules into the vasculature of the liver. In this review, the development of the procedures for hydrodynamic delivery will be described and the parameters necessary for attaining maximal gene expression will be highlighted. A review of the mechanisms for transfecting hepatocytes, as well as potential uses of this approach in various research and clinical applications, will also be discussed.

In vivo gene transfer to kidney by lentiviral vector

BACKGROUND

The growing understanding of the molecular basis of renal diseases makes the development of gene therapy for kidney disorders a potential treatment alternative. Work aimed at determining the feasibility and the efficiency of gene transfer to the kidney using different viral and nonviral transduction systems is a necessary component to understanding the full potential. Lentiviral vectors have been shown to transduce stably different tissues and cell types that are refractory to other gene transfer approaches. To date, the potential of lentiviral vectors to transfer genes in kidney has not been investigated. The scope of this work was to analyze the efficiencies of in vivo transduction of kidney by a lentiviral vector.

METHODS

A pseudotyped lentiviral vector carrying the gene for the enhanced green fluorescent protein (EGFP) was delivered into one kidney of experimental mice by retrograde infusion through the ureter. The presence of the virus and the expression of the reporter protein were monitored over time.

RESULTS

Both viral DNA and EGFP expression were measurable in the kidney infused with the lentiviral vector but not in the contralateral kidney. Protein expression was detected by immunostaining, as EGFP fluorescence was masked by the high background fluorescence of the kidney. Expression of EGFP persisted for the entire two-month duration of the experiments.

CONCLUSIONS

Lentiviral vectors can effectively deliver exogenous genes to the kidney in vivo, resulting in persistent expression of the introduced gene.