Ribozyme to human TGF-beta1 mRNA inhibits the proliferation of human vascular smooth muscle cells

The Function and Therapeutic Potential of Long Non-coding RNAs in Cardiovascular Development and Disease

The popularization of genome-wide analyses and RNA sequencing led to the discovery that a large part of the human genome, while effectively transcribed, does not encode proteins. Long non-coding RNAs have emerged as critical regulators of gene expression in both normal and disease states. Studies of long non-coding RNAs expressed in the heart, in combination with gene association studies, revealed that these molecules are regulated during cardiovascular development and disease. Some long non-coding RNAs have been functionally implicated in cardiac pathophysiology and constitute potential therapeutic targets. Here, we review the current knowledge of the function of long non-coding RNAs in the cardiovascular system, with an emphasis on cardiovascular development and biology, focusing on hypertension, coronary artery disease, myocardial infarction, ischemia, and heart failure. We discuss potential therapeutic implications and the challenges of long non-coding RNA research, with directions for future research and translational focus.

Vascular smooth-muscle-cell activation: proteomics point of view

Vascular smooth-muscle cells (VSMCs) are the main component of the artery medial layer. Thanks to their great plasticity, when stimulated by external inputs, VSMCs react by changing morphology and functions and activating new signaling pathways while switching others off. In this way, they are able to increase the cell proliferation, migration, and synthetic capacity significantly in response to vascular injury assuming a more dedifferentiated state. In different states of differentiation, VSMCs are characterized by various repertories of activated pathways and differentially expressed proteins. In this context, great interest is addressed to proteomics technology, in particular to differential proteomics. In recent years, many authors have investigated proteomics in order to identify the molecular factors putatively involved in VSMC phenotypic modulation, focusing on metabolic networks linking the differentially expressed proteins. Some of the identified proteins may be markers of pathology and become useful tools of diagnosis. These proteins could also represent appropriately validated targets and be useful either for prevention, if related to early events of atherosclerosis, or for treatment, if specific of the acute, mid, and late phases of the pathology. RNA-dependent gene silencing, obtained against the putative targets with high selective and specific molecular tools, might be able to reverse a pathological drift and be suitable candidates for innovative therapeutic approaches.

Chimeric DNA–RNA hammerhead ribozyme targeting transforming growth factor-β1 mRNA ameliorates renal injury in hypertensive rats

OBJECTIVE

Transforming growth factor (TGF)-beta is a critical factor in the progression of renal injury, regardless of the primary etiology. Such injury is characterized by glomerular sclerosis and tubulointerstitial fibrosis. To develop a ribozyme-based therapy for progressive renal diseases, we examined the effects of chimeric DNA-RNA hammerhead ribozyme targeting TGF-beta1 mRNA on glomerulosclerosis in salt-loaded, stroke-prone spontaneously hypertensive rats (SHR-SP) and salt-sensitive Dahl (Dahl-S) rats.

METHODS

The chimeric DNA-RNA ribozyme to TGF-beta1 was delivered by polyethylenimine to cultured mesangial cells from SHR-SP in vitro and to glomeruli in SHR-SP in vivo. The chimeric ribozyme reduced expression of TGF-beta1 mRNA and protein, which was accompanied by inhibition of expression of extracellular matrix molecules such as fibronectin and collagen type I in mesangial cells from SHR-SP in vitro.

RESULTS

One intraperitoneal injection of 200 microg of chimeric DNA-RNA ribozyme to TGF-beta1 in vivo markedly ameliorated thickening of capillary artery walls and glomerulosclerosis in salt-loaded SHR-SP and Dahl-S rats without a reduction in blood pressure. The chimeric ribozyme reduced expression of TGF-beta1 and connective tissue growth factor (CTGF) mRNAs in renal cortex in salt-loaded Dahl-S rats. Chimeric ribozyme to TGF-beta1 significantly reduced levels of protein in urine in the Dahl-S rats.

CONCLUSION

These results suggest that chimeric DNA-RNA ribozyme to TGF-beta1 may be useful as a gene therapy for progressive tissue injury in a wide variety of renal diseases, including hypertensive nephrosclerosis.

Transforming growth factor-beta is activated by plasmin and inhibits smooth muscle cell death in human saphenous vein

BACKGROUND

The effect of activation of endogenous transforming growth factor-beta (TGF-beta) on smooth muscle cell apoptosis was assessed in human saphenous vein.

METHODS

Segments of human saphenous vein, obtained at the time of bypass graft surgery, were cultured for 14 days. During this time, smooth muscle cells accumulated in the intima as a result of proliferation and migration, partly counterbalanced by apoptotic cell death.

RESULTS

Addition of exogenous TGF-beta(1) had no effect on smooth muscle cell proliferation or apoptosis. However, antibody neutralization of endogenous TGF-beta(1) caused significant increases in smooth muscle cell death in the media and intima without any change in proliferation. A plasmin inhibitor (alpha-N-acetyl-L-lysine methyl ester), a specific urokinase-type plasminogen activator (uPA) inhibitor (amiloride) and an anti-catalytic anti-uPA antibody all caused decreases in the tissue content of active TGF-beta and increases in smooth muscle cell death in the media and intima.

CONCLUSIONS

These data suggest that the amount of TGF-beta in human saphenous vein is sufficient, when in the active form, to protect smooth muscle cells against apoptosis. Adding exogenous TGF-beta(1) has no beneficial effect, but decreasing the amount of active TGF-beta causes smooth muscle cells to undergo apoptosis. Plasmin, generated by uPA, appears to be an important activator of endogenous latent TGF-beta.

Hammerhead ribozyme targeting connective tissue growth factor mRNA blocks transforming growth factor-beta mediated cell proliferation

PURPOSE

Excessive scarring following trauma or surgery of cornea, conjunctiva or retina can greatly impair visual outcome. At present, no agents are clinically available that selectively reduce activity of genes that regulate fibrosis. Connective tissue growth factor (CTGF) has been linked to fibrosis in several tissues, including cornea and conjunctiva. In this study, hammerhead ribozymes targeting CTGF mRNA were synthesized, kinetic parameters were measured, and the effect on TGF-beta-mediated cell proliferation was measured in cultured human fibroblasts.

METHODS

The mRNA sequence of human CTGF was scanned for potential hammerhead ribozyme cleavage sites, and predicted secondary folding structures around the sites were calculated. Synthetic 12mer ribozymes and 33mer oligonucleotide mRNA targets corresponding to two sites were synthesized, and kinetic constants calculated from Hanes-Wolff plots of in vitro cleavage reactions. The ribozyme with higher percentage cleavage and kinetic rate was cloned into an expression plasmid (pTR-UF21) and stably transfected into cultured human fibroblasts. An inactive ribozyme plasmid served as a negative control. The effects of the ribozyme on expression of TGF-beta-induced CTGF mRNA and protein levels were measured using ELISA and real-time TaqMan quantitative RT-PCR. Finally, the effect of the CTGF ribozyme on TGF-beta-mediated proliferation of fibroblasts was measured using a non-radioactive cell proliferation microtiter assay.

RESULTS

Of the eight potential hammerhead ribozyme cleavage sites in human CTGF mRNA, two sites (CHR 745, and CHR 859) were identified with optimal secondary folding. CHR 859 cleaved 94% of the target mRNA, compared to 46% cleavage for CHR 745 after 16 hr of reaction. CHR 859 had a K(m) of 1.56 microM and a K(cat) of 2.97 min(-1), while CHR 745 had a K(m) of 7.80 microM and a K(cat) of 5.7 min(-1). The turnover numbers (K(cat)/K(m)) of CHR 859 and CHR 745 were 1.9 x 10(6) M min(-1) and 7.4 x 10(5) M min(-1), respectively, indicating CHR 859 is 2.6 times more efficient than CHR 745 in destroying CTGF mRNA. Stable transfection of CHR 859 into human fibroblasts reduced CTGF mRNA levels 55% and protein levels 72% compared to the inactive ribozyme control. Furthermore, TGF-beta-induced cell proliferation was reduced 90% in fibroblasts stably transfected with CHR 859 compared to control cell groups.

CONCLUSIONS

The CHR 859 hammerhead ribozyme cleaved human CTGF mRNA with high kinetic efficiency in vitro, effectively reduced levels of CTGF mRNA and protein in cultured human fibroblasts, and blocked TGF-beta-induced cell proliferation without nonspecific toxicity. These data support the concept that CTGF mediates TGF-beta-induced cell proliferation, and imply that regulating CTGF expression with ribozymes may be effective in reducing ocular scarring.

Interleukins in atherosclerosis: molecular pathways and therapeutic potential

Interleukins are considered to be key players in the chronic vascular inflammatory response that is typical of atherosclerosis. Thus, the expression of proinflammatory interleukins and their receptors has been demonstrated in atheromatous tissue, and the serum levels of several of these cytokines have been found to be positively correlated with (coronary) arterial disease and its sequelae. In vitro studies have confirmed the involvement of various interleukins in pro-atherogenic processes, such as the up-regulation of adhesion molecules on endothelial cells, the activation of macrophages, and smooth muscle cell proliferation. Furthermore, studies in mice deficient or transgenic for specific interleukins have demonstrated that, whereas some interleukins are indeed intrinsically pro-atherogenic, others may have anti-atherogenic qualities. As the roles of individual interleukins in atherosclerosis are being uncovered, novel anti-atherogenic therapies, aimed at the modulation of interleukin function, are being explored. Several approaches have produced promising results in this respect, including the transfer of anti-inflammatory interleukins and the administration of decoys and antibodies directed against proinflammatory interleukins. The chronic nature of the disease and the generally pleiotropic effects of interleukins, however, will demand high specificity of action and/or effective targeting to prevent the emergence of adverse side effects with such treatments. This may prove to be the real challenge for the development of interleukin-based anti-atherosclerotic therapies, once the mediators and their targets have been delineated.

Hammerhead ribozymes for target validation

Expensive failures in the pharmaceutical industry might be avoided by target validation at an early stage. Often, the full consequences of inhibiting a chosen drug target do not emerge until late in the development process. One option is to use hammerhead ribozymes as highly specific ribonucleases targeted exclusively at the mRNA encoding the target protein. The first part of this review is concerned with the mechanism and design of hammerhead ribozymes. This includes the chemistry of their action, specificity of cleavage and ability to discriminate between different mRNAs and selection of suitable cleavage sites. In considering their use for target validation, hammerhead ribozymes are divided into two categories. Endogenous ribozymes are transcribed inside the cell where they act whilst exogenous are introduced into the cell from outside. Exogenous ribozymes are synthesised chemically and must be protected against cellular nucleases. Information is provided on transfection methods and vectors that have been used with endogenous ribozymes as well as synthesis and chemical modification of exogenous ribozymes. Of proteins inhibited in cells or whole organisms, those in animal experiments are emphasised. Comparisons are made with other approaches, especially the use of antisense oligonucleotides or RNA.