The use of multicomponent reactions in the development of bis-boronic acids for the detection of ß-sialic acid.

Sialic acid (SA) is a naturally occurring monosaccharide found in glycoproteins and glycolipids. Changes in the expression of SA are associated with several diseases; thus, the detection of SA is of great significance for biological research, cancer diagnosis, and treatment. Boronic acid analogs have emerged as a promising tool for detecting sugars such as SA due to its reversible covalent bonding ability. In this study, 11 bis-boronic acid compounds and 2 mono-boronic acid compounds were synthesized via a highly efficient Ugi-4CR strategy. The synthesized compounds were subjected to affinity fluorescence binding experiments to evaluate their binding capability to SA. Compound A1 was shown to have a promising binding constant of 2602 ± 100 M-1 at pH = 6.0. Density Functional Theory (DFT) calculations examining the binding modes between A1 and SA indicated that the position of the boronic acid functional group was strongly correlated with its interaction with SA's α-hydroxy acid unit. The DFT calculations were consistent with the observations from the fluorescence experiments, demonstrating that the number and relative positions of the boronic acid functional groups are critical factors in enhancing the binding affinity to SA. DFT calculations of both S and R configuration of A1 indicated that the effect of the S/R configuration of A1 on its binding with ß-sialic acid was insignificant as the Ugi-4CR generated racemic products. A fluorine atom was incorporated into the R2 substituent of A1 as an electron-withdrawing group to produce A5, which possessed a significantly higher capability to bind to SA (Keq = 7015 ± 5 M-1 at pH = 6.0). Finally, A1 and A5 were shown to possess exceptional binding selectivity toward ß-sialic acid under pH of 6.0 and 6.5 while preferring to bind with glucose, fructose, and galactose under pH of 7.0 and 7.5.

RhoA and membrane fluidity mediates the spatially polarized Src/FAK activation in response to shear stress.

While Src plays crucial roles in shear stress-induced cellular processes, little is known on the spatiotemporal pattern of high shear stress (HSS)-induced Src activation. HSS (65 dyn/cm(2)) was applied on bovine aortic endothelial cells to visualize the dynamic Src activation at subcellular levels utilizing a membrane-targeted Src biosensor (Kras-Src) based on fluorescence resonance energy transfer (FRET). A polarized Src activation was observed with higher activity at the side facing the flow, which was enhanced by a cytochalasin D-mediated disruption of actin filaments but inhibited by a benzyl alcohol-mediated enhancement of membrane fluidity. Further experiments revealed that HSS decreased RhoA activity, with a constitutively active RhoA mutant inhibiting while a negative RhoA mutant enhancing the HSS-induced Src polarity. Cytochalasin D can restore the polarity in cells expressing the active RhoA mutant. Further results indicate that HSS stimulates FAK activation with a spatial polarity similar to Src. The inhibition of Src by PP1, as well as the perturbation of RhoA activity and membrane fluidity, can block this HSS-induced FAK polarity. These results indicate that the HSS-induced Src and subsequently FAK polarity depends on the coordination between intracellular tension distribution regulated by RhoA, its related actin structures and the plasma membrane fluidity.

FAK and paxillin dynamics at focal adhesions in the protrusions of migrating cells.

Cell migration requires the fine spatiotemporal integration of many proteins that regulate the fundamental processes that drive cell movement. Focal adhesion (FA) dynamics is a continuous process involving coordination between FA and actin cytoskeleton, which is essential for cell migration. We studied the spatiotemporal relationship between the dynamics of focal adhesion kinase (FAK) and paxillin at FAs in the protrusion of living endothelial cells. Concurrent dual-color imaging showed that FAK was assembled at FA first, which was followed by paxillin recruitment to the FA. By tracking and quantifying FAK and paxillin in migrating cells, the normalized FAK/Paxillin fluorescence intensity (FI) ratio is > 1 (≈ 4 fold) at cell front, ≈ 1 at cell center, and < 1 at cell rear. The significantly higher FAK FI than paxillin FI at cell front indicates that the assembly of FAK-FAs occurs ahead of paxillin at cell front. To determine the time difference between the assemblies of FAK and paxillin at nascent FAs, FAs containing both FAK and paxillin were quantified by image analysis and time correlation. The results show that FAK assembles at the nascent FAs earlier than paxillin in the protrusions at cell front.

Dynamic motion of paxillin on actin filaments in living endothelial cells.

Our three-dimensional (3-D) images showed that paxillin co-localized on actin filaments as fibrous structures, as well as clusters, in endothelial cells (ECs). In living ECs under flow condition, we monitored concurrently the intracellular dynamics of DsRed2-paxillin and GFP-actin by time-lapse video recording and dual-color fluorescence imaging. The results showed that the dynamic motion of paxillin as fibrous structures was associated with actin filaments, but not with microtubules. Our findings suggest that the actin network plays an important role not only in the assembly/disassembly of paxillin at focal adhesions, but also as a track for the intracellular transport of paxillin, which is involved in signaling pathway.

Roles of microfilaments and microtubules in paxillin dynamics.

We investigated the roles of microfilaments and microtubules in the localization and tyrosine phosphorylation of paxillin, a focal adhesion-associated signaling molecule, in bovine aortic endothelial cells (BAECs). Paxillin tyrosine phosphorylation is inhibited by cytochalasin D (CD), but slightly increased by colchicine and paclitaxol (taxol). CD also caused an overall disassembly of paxillin-containing focal adhesions (paxillin-FAs) and translocation of paxillin to the cytoplasm and perinuclear region with a diffuse distribution. Meanwhile, colchicine and taxol caused a disassembly of paxillin-FAs from cell periphery and lamellipodia, and their assembly in cell center. These results indicate that actin filaments are important in paxillin assembly in the FAs of the whole ECs and that microtubules are critical in paxillin assembly in cell periphery and lamellipodia; thus the microfilaments and microtubules play differential roles in the dynamics of paxillin assembly/disassembly. Our findings also suggest that tyrosine phosphorylation is an important element in paxillin dynamics at FAs.

Effects of flow patterns on the localization and expression of VE-cadherin at vascular endothelial cell junctions: in vivo and in vitro investigations.

Atherosclerosis occurs preferentially at vascular curvature and branch sites where the vessel walls are exposed to fluctuating shear stress and have high endothelial permeability. Endothelial permeability is modulated by intercellular adhesion molecules such as VE-cadherin. This study was designed to elucidate the effects of different flow patterns on the localization and expression of VE-cadherin in endothelial cells (ECs) both in vivo and in vitro. VE-cadherin staining at EC borders was much stronger in the descending thoracic aorta and abdominal aorta, where the pulsatile flow has a strong net forward component than in the aortic arch and the poststenotic dilatation site beyond an experimental constriction, where the flow near the wall is complex and reciprocating with little net flow. With the use of flow chambers the effects of pulsatile flow (12 +/- 4 dyn/cm2 at 1 Hz) and reciprocating flow (0.5 +/- 4 dyn/cm2 at 1 Hz) on VE-cadherin organization in endothelial monolayers were studied in vitro. VE-cadherin staining was continuous along cell borders in static controls. Following 6 h of either pulsatile or reciprocating flow, the VE-cadherin staining at cell borders became intermittent. When the pulsatile flow was extended to 24, 48 or 72 h the staining around the cell borders became continuous again, but the staining was still intermittent when the reciprocating flow was similarly extended. Exposure to pulsatile or reciprocating flow for 6 and 24 h neither change the expression level of VE-cadherin nor its distribution between membrane and cytosol fractions as determined by Western blot and compared with static controls. These findings suggest that the cell junction remodeling induced by different flow patterns may result from a redistribution of VE-cadherin within the cell membrane. Both the in vivo and in vitro data indicate that pulsatile and reciprocating flow patterns have different effects on cell junction remodeling. The lack of junction reorganization in regions of reciprocating flow in vivo and in vitro may provide a mechanistic basis for the high permeability and the preferential localization of atherosclerosis in regions of the arterial stress with complex flow patterns and fluctuating shear stress.

Differential regulation of Rho GTPases by beta1 and beta3 integrins: the role of an extracellular domain of integrin in intracellular signaling.

Integrins mediate cell adhesion and signal transduction at focal adhesions. Here we investigate the roles of integrin beta subunits in the regulation of actin cytoskeletal structure and the activities of Rho and Rac. The overexpression of beta3 integrin in Chinese hamster ovary cells enhances Rho activity and stress fiber formation, whereas the overexpression of beta1 integrin increases Rac activity and lamellipodia formation. The overexpression of a mutant beta1-3-1 integrin, in which the extracellular I-domain-like sequence of beta1 integrin has been replaced with the corresponding sequence of beta3 integrin, also enhances Rho activity and the formation of stress fibers. Our results demonstrate that beta1 and beta3 integrins differentially regulate the activities of Rho family GTPases and that the extracellular domains of integrin beta subunits play a critical role in transducing the extracellular ligand-binding information into specific intracellular signaling events.

Roles of microtubule dynamics and small GTPase Rac in endothelial cell migration and lamellipodium formation under flow.

Endothelial cell (EC) migration is required for vascular development and wound healing. We investigated the roles of microtubule (MT) dynamics and the small GTPase Rac in the fluid shear stress-induced protrusion of lamellipodia and enhancement of migration of bovine aortic ECs (BAECs). Shear stress increased lamellipodial protrusion and cell migration. Treating BAECs with paclitaxel (Taxol), an MT-stabilizing agent, inhibited lamellipodial protrusion and reduced migration speed in both the static and sheared groups. After Taxol washout, both lamellipodial protrusion and cell migration increased in the flow direction. Taxol treatment also decreased the shear-induced Rac activation. Transfection of BAECs with a dominant negative mutant of Rac1 inhibited lamellipodial protrusion and cell migration under static and shear conditions. Transfection with an activated mutant of Rac1 induced lamellipodia in all directions and attenuated the shear-induced migration, suggesting that an appropriate level of Rac activity and a polarized lamellipodial protrusion are important for cell migration under static and shear conditions. Our findings suggest that MT dynamics and optimum Rac activation are required for the polarized protrusion of lamellipodia that drives the directional EC migration under flow.