Asitha T Silva scite author profile

Asitha T Silva

2Publications

90Citation Statements Received

76Citation Statements Given

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126

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Oklahoma State University

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Conjugated polymer nanoparticles for effective siRNA delivery to tobacco BY-2 protoplasts

et al. 2010

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BackgroundPost transcriptional gene silencing (PTGS) is a mechanism harnessed by plant biologists to knock down gene expression. siRNAs contribute to PTGS that are synthesized from mRNAs or viral RNAs and function to guide cellular endoribonucleases to target mRNAs for degradation. Plant biologists have employed electroporation to deliver artificial siRNAs to plant protoplasts to study gene expression mechanisms at the single cell level. One drawback of electroporation is the extensive loss of viable protoplasts that occurs as a result of the transfection technology.ResultsWe employed fluorescent conjugated polymer nanoparticles (CPNs) to deliver siRNAs and knockdown a target gene in plant protoplasts. CPNs are non toxic to protoplasts, having little impact on viability over a 72 h period. Microscopy and flow cytometry reveal that CPNs can penetrate protoplasts within 2 h of delivery. Cellular uptake of CPNs/siRNA complexes were easily monitored using epifluorescence microscopy. We also demonstrate that CPNs can deliver siRNAs targeting specific genes in the cellulose biosynthesis pathway (NtCesA-1a and NtCesA-1b).ConclusionsWhile prior work showed that NtCesA-1 is a factor involved in cell wall synthesis in whole plants, we demonstrate that the same gene plays an essential role in cell wall regeneration in isolated protoplasts. Cell wall biosynthesis is central to cell elongation, plant growth and development. The experiments presented here shows that NtCesA is also a factor in cell viability. We show that CPNs are valuable vehicles for delivering siRNAs to plant protoplasts to study vital cellular pathways at the single cell level.

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Abstract 356: Effect of Long-Term Diet-Induced Hyperglycemia and Hyperlipidemia on Placenta Growth Factor Expression in Mouse Heart

Silva

Lloyd

2013

ATVB

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Arteriogenesis (collateral artery remodeling) is a vital adaptation of the vasculature in response to occlusion which serves to improve O2 and nutrient delivery to distal tissue, thereby decreasing risk of tissue damage due to ischemia. Stimulation of arteriogenesis would be highly beneficial in diabetics, who are especially prone to develop ischemic cardiovascular disease. However, arteriogenesis is suppressed in diabetes by an undefined mechanism. Placenta growth factor (PLGF) is a key arteriogenic factor; thus, we hypothesized that decreased PLGF levels might contribute to impaired arteriogenesis in diabetes. To test this hypothesis, we utilized three mouse models of long term (6 mo) diet-induced metabolic dysfunction: hyperglycemic + hyperlipidemic (high fat fed C57BL/6; HG/HL, n=7), hyperlipidemic (low fat fed ApoE-/-; HL, n=5) and extremely hyperlipidemic (high fat fed ApoE-/-; EXHL, n=12). A normoglycemic + normolipidemic control group (low fat fed C57BL/6; CONT, n=9) was also studied. Both males and females were studied to identify gender differences. Mouse phenotype was confirmed by plasma cholesterol assay, intraperitoneal glucose tolerance testing, and body weight. Cardiac PLGF gene expression was decreased in both male and female EXHL (~50%, p<0.01 and ~42%, p=0.09 respectively), compared to HL. PLGF mRNA was also decreased in male (~43%, p=0.06) but not female HG/HL, compared to CONT (n=5). This decrease was specific to PLGF, as mRNA for VEGFR1 (PLGF receptor) and the related growth factor VEGF-A was not affected by diet. We previously showed that PLGF is upregulated by low, physiological levels of hydrogen peroxide in vitro, suggesting that reactive oxygen species (ROS) signaling may be important in regulating PLGF. Since oxidative stress occurs in both hyperglycemia and hyperlipidemia, and arteriogenesis is known to be subject to a “redox window,” the inhibition of PLGF expression we observed may be mediated by oxidative stress. Plasma isoprostane levels confirmed that oxidative stress existed in HG/HL, HL, and EXHL compared to CONT. We conclude that hyperlipidemia is a key metabolic parameter influencing PLGF expression in cardiac tissue. Further studies to identify the role of oxidative stress in PLGF expression are needed.

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Asitha T Silva

Conjugated polymer nanoparticles for effective siRNA delivery to tobacco BY-2 protoplasts

Abstract 356: Effect of Long-Term Diet-Induced Hyperglycemia and Hyperlipidemia on Placenta Growth Factor Expression in Mouse Heart

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