Resveratrol and Estradiol Rapidly Activate MAPK Signaling through Estrogen Receptors α and β in Endothelial Cells
Vascular endothelial cells (EC)are an important target of estrogen action through both the classical genomic (i.e. nuclear-initiated) activities of estrogen receptors ␣ and  (ER␣ and ER) and the rapid "nongenomic" (i.e. membrane-initiated) activation of ER that stimulates intracellular phosphorylation pathways. We tested the hypothesis that the red wine polyphenol trans-resveratrol activates MAPK signaling via rapid ER activation in bovine aortic EC, human umbilical vein EC, and human microvascular EC. We report that bovine aortic EC, human umbilical vein EC, and human microvascular EC express ER␣ and ER. We demonstrate that resveratrol and estradiol (E 2 ) rapidly activated MAPK in a MEK-1, Src, matrix metalloproteinase, and epidermal growth factor receptor-dependent manner. Importantly, resveratrol activated MAPK and endothelial nitric-oxide synthase (eNOS) at nM concentrations (i.e. an order of magnitude less than that required for ER genomic activity) and concentrations possibly achieved transiently in serum following oral red wine consumption. Co-treatment with ER antagonists ICI 182,780 or 4-hydroxytamoxifen blocked resveratrol-or E 2 -induced MAPK and eNOS activation, indicating ER dependence. We demonstrate for the first time that ER␣-and ER-selective agonists propylpyrazole triol and diarylpropionitrile, respectively, stimulate MAPK and eNOS activity. A red but not a white wine extract also activated MAPK, and activity was directly correlated with the resveratrol concentration. These data suggest that ER may play a role in the rapid effects of resveratrol in EC and that some of the atheroprotective effects of resveratrol may be mediated through rapid activation of ER signaling in EC.Epidemiological studies have indicated that the consumption of red wine reduces the incidence of mortality from coronary heart disease (CHD) 1 (1, 2). The cardioprotective effect has been attributed to the polyphenol fraction of red wine (1). A key polyphenol in red wine is resveratrol, trans-3,5,4Ј-trihydroxystilbene, from grape skin. Red wine contains 1-75 mg of transresveratrol/liter (3). Studies in male rats demonstrated that an alcohol-free red wine extract and resveratrol protect the heart from ischemia reperfusion injury (4). Rodent studies showed that orally administered resveratrol is absorbed in the gut, has high affinity for heart and liver (5, 6), and is metabolized to glucuronides that have a t1 ⁄2 of ϳ1.5 h (7). A recurrent question is whether resveratrol, at concentrations present in red wine, is effective in vivo. The oral absorption of 25 mg of trans-
Photocrosslinkable and degradable polymers are finding a broad range of applications as drug-delivery vehicles, tissueengineering scaffolds, and in the fabrication of microdevices. [1][2][3] However, the synthesis of multifunctional macromers that form these degradable networks commonly involves multiple functionalization and purification steps, which makes the development of large numbers of polymers with diverse properties difficult. Here, we develop the first combinatorial library of degradable photocrosslinked materials. A library of acrylate-terminated poly(b-amino ester)s was synthesized in parallel via a condensation reaction that combines primary or secondary amines with diacrylates. This library of macromers was then photopolymerized to form degradable networks, with a wide range of degradation times (< 1 day to minimal mass loss after three months), mass-loss profiles, and mechanical properties (∼ 4 to 350 MPa). We believe this library approach will allow for the rapid screening and design of degradable polymers for a variety of applications. The spatial and temporal control afforded during photoinitiated polymerizations has motivated their wide application in the general field of biomaterials. [1,2] For example, photocrosslinkable hydrogels are used for the delivery of cells to injured tissues, [4][5][6][7][8] for the encapsulation and controlled delivery of biological molecules, [9][10][11] and for controlled fluid flow and cell confinement in microfluidics. [12,13] Additionally, highly crosslinked photopolymers are currently used in dentistry [14] and are being developed as bone-replacement materials [15,16] and for the fabrication of microdevices.[17] Many of these applications are only possible owing to the controlled nature of this type of polymerization. For example, photoinitiated control of polymerization allows for their application as injectable biomaterials [18,19] with a non-cytotoxic polymerization process.[20]Additionally, through use of masks and lasers, the spatial control of the polymerization process allows for unique patterning and construction of complex materials.[21]Numerous photopolymerizable and degradable materials have been developed, including polyanhydrides, poly(propylene fumarates), poly(ethylene glycol), and polysaccharides, [8,15,16,18] all utilizing multiple reaction and purification steps for synthesis of the photopolymerizable precursors. Despite this work, it has proven challenging to predict specific desirable properties (e.g., degradation and mechanics) from known chemical and structural details of the network precursors. These properties are essential in the design of degradable polymers. For instance, it may be desirable to synthesize a very hard material for some applications (e.g., orthopaedics), whereas a soft material is advantageous for other applications (e.g., tissue adhesive). [22,23] One potential solution to the inability to predict physical behavior is the generation of a higher-throughput approach to rapidly synthesize and screen photopolymerizable li...
Electrospun fibrous scaffolds are being developed for the engineering of numerous tissues. Advantages of electrospun scaffolds include the similarity in fiber diameter to elements of the native extracellular matrix and the ability to align fibers within the scaffold to control and direct cellular interactions and matrix deposition. To further expand the range of properties available in fibrous scaffolds, we developed a process to electrospin photocrosslinkable macromers from a library of multifunctional poly(β-amino ester)s. In this study, we utilized one macromer (A6) from this library for initial examination of fibrous scaffold formation. A carrier polymer [poly(ethylene oxide) (PEO)] was used for fiber formation because of limitations in electrospinning A6 alone. Various ratios of A6 and PEO were successfully electrospun and influenced the scaffold fiber diameter and appearance. When electrospun with a photoinitiator and exposed to light, the macromers crosslinked rapidly to high double bond conversions and fibrous scaffolds displayed higher elastic moduli compared to uncrosslinked scaffolds. When these fibers were deposited onto a rotating mandrel and crosslinked, organized fibrous scaffolds were obtained, which possessed higher moduli (~4-fold) in the fiber direction than perpendicular to the fiber direction, as well as higher moduli (~12-fold) than that of nonaligned crosslinked scaffolds. With exposure to water, a significant mass loss and a decrease in mechanical properties were observed, correlating to a rapid initial loss of PEO which reached an equilibrium after 7 days. Overall, these results present a process that allows for formation of fibrous scaffolds from a wide variety of possible photocrosslinkable macromers, increasing the diversity and range of properties achievable in fibrous scaffolds for tissue regeneration.
A library of photocrosslinkable poly(beta-amino ester)s (PBAEs) was recently synthesized to expand the number of degradable polymers that can be screened and developed for a variety of biological applications. In this work, the influence of variations in macromer chemistry and macromer molecular weight (MMW) on network reaction behavior, overall bulk properties, and cell interactions were investigated. The MMW was controlled through alterations in the initial diacrylate to amine ratio (> or =1) during synthesis and decreased with an increase in this ratio. Lower MMWs reacted more quickly and to higher double bond conversions than higher MMWs, potentially due to the higher concentration of reactive groups. Additionally, the lower MMWs led to networks with higher compressive and tensile moduli that degraded slower than networks formed from higher MMWs because of an increase in the crosslinking density and decrease in the number of degradable units per crosslink. The adhesion and spreading of osteoblast-like cells on polymer films was found to be dependent on both the macromer chemistry and the MMW. In general, the number of cells was similar on networks formed from a range of MMWs, but the spreading was dramatically influenced by MMW (higher spreading with lower MMWs). These results illustrate further diversity in photocrosslinkable PBAE properties and that the chemistry and macromer structure must be carefully selected for the desired application.
Photopolymerizable and degradable biomaterials are becoming important in the development of advanced materials in the fields of tissue engineering, drug delivery, and microdevices. We have recently developed a library of poly(beta-amino ester)s (PBAEs) that form networks with a wide range of mechanical properties and degradation rates that are controlled by simple alterations in the macromer molecular weight or chemical structure. In this study, the influence of macromer branching on network properties was assessed by adding the trifunctional monomer pentaerythritol triacrylate (PETA) during synthesis. This led to a dose-dependent increase in the network compressive modulus, tensile modulus, and glass transition temperature, and a decrease in the network soluble fraction, yet led to only minor variations in degradation profiles and reaction behavior. For instance, the tensile modulus increased from 1.98+/-0.09MPa to 3.88+/-0.20MPa when the macromer went from a linear structure to a more branched structure with the addition of PETA. When osteoblast-like cells were grown on thin films, there was an increase in cell adhesion and spreading as the amount of PETA incorporated during synthesis increased. Towards tissue engineering applications, porous scaffolds were fabricated by photopolymerizing around a poragen and then subsequently leaching the poragen. Interconnected pores were observed in the scaffolds and observed trends translated to the porous scaffold (i.e., increasing mechanics with increasing branching). These findings demonstrate a simple variation during macromer synthesis that can be used to further tune the physical properties of scaffolds for given applications, particularly for candidates from the PBAE library.
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