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Ion specific effects in bundling and depolymerization of taxol-stabilized microtubules
Needleman, Daniel J.,Ojeda-Lopez, Miguel A.,Raviv, Uri,Miller, Herbert P.,Li, Youli,Song, Chaeyeon,Feinstein, Stuart C.,Wilson, Leslie,Choi, Myung Chul,Safinya, Cyrus R. The Royal Society of Chemistry 2013 Faraday discussions Vol.166 No.-
<P>Microtubules (MTs) are nanometer scale hollow cylindrical biological polyelectrolytes. They are assembled from α/β-tubulin dimers, which stack to form protofilaments (PFs) with lateral interactions between PFs resulting in the curved MT. In cells, MTs and their assemblies are critical components in a range of functions from providing tracks for the transport of cargo to forming the spindle structure during mitosis. Previous studies have shown that while cations with valence equal to or larger than 3+ tend to assemble tight 3D bundles of taxol-stabilized MTs, certain divalent cations induce relatively loose 2D bundles of different symmetry (D. J. Needleman <I>et al.</I>, <I>Proc. Natl. Acad. Sci. U. S. A.</I>, 2004, <B>101</B>, 16099). Similarly, divalent cations form 2D bundles of DNA adsorbed on cationic membranes (I. Koltover <I>et al.</I>, <I>Proc. Natl. Acad. Sci. U. S. A.</I>, 2000, <B>97</B>, 14046). The bundling behavior for these biological polyelectrolyte systems is qualitatively in agreement with current theory. Here, we present results which show that, unlike the case for DNA adsorbed on cationic membranes, bundling of taxol-stabilized MTs occurs only for certain divalent cations above a critical ion concentration (<I>e.g.</I> Ca<SUP>2+</SUP>, Sr<SUP>2+</SUP>, Ba<SUP>2+</SUP>). Instead, many divalent cations pre-empt the bundling transition and depolymerize taxol-stabilized MTs at a lower counterion concentration. Although previous cryogenic TEM has shown that, in the absence of taxol, Ca<SUP>2+</SUP> depolymerizes MTs assembling in buffers containing GTP (guanosine triphosphate), our finding is surprising given the known stabilizing effects of taxol on GDP (guanosine diphosphate)-MTs. The ion concentration required for MT depolymerization decreases with increasing atomic number for the divalents Mg<SUP>2+</SUP>, Mn<SUP>2+</SUP>, Co<SUP>2+</SUP>, and Zn<SUP>2+</SUP>. GdCl<SUB>3</SUB> (3+) is found to be extremely efficient at MT depolymerization requiring ion concentrations of about 1 mM, while oligolysine (2+), is observed not to depolymerize MTs at concentrations as high as 144 mM. The surprising MT depolymerization results are discussed in the context of divalents either disrupting lateral interactions between PFs (which are strengthened for taxol containing β-tubulin), or interfering with taxol's ability to induce flexibility at the interface between two tubulin dimers in the same PF (which has been recently suggested as a mechanism by which taxol stabilizes MTs post-hydrolysis with the induced flexibility counteracting the kink between GDP-tubulin dimers in a PF).</P>
Successful Treatment of a Superficial Femoral Artery Pseudoaneurysm with Balloon Tamponade
Hugo Laparra-Escareno,Cesar Cuen-Ojeda,Ramon García-Alva,Gabriel Lopez-Pena,Javier E. Anaya-Ayala,Carlos A. Hinojosa 대한혈관외과학회 2019 Vascular Specialist International Vol.35 No.3
The development of post-catheterization arterial pseudoaneurysms is one of the most common vascular access complications following angiographies and endovascular interventions. Different therapeutic options to treat these lesions have been used. We herein report the case of a 79-year-old woman who was referred to our service for evaluation with a post-catheterization superficial femoral artery pseudoaneurysm measuring 4 cm. Owing to the anatomical location of the arterial pseudoaneurysm and the patient’s refusal to undergo open surgery, we treated the lesion using an endovascular approach with a balloon tamponade. The procedure was successful, and the patient recovered well and was discharged from the hospital without complications. At 6-month follow-up she remained symptom-free and without recurrence.
Safinya, Cyrus R.,Raviv, Uri,Needleman, Daniel J.,Zidovska, Alexandra,Choi, Myung Chul,Ojeda‐,Lopez, Miguel A.,Ewert, Kai K.,Li, Youli,Miller, Herbert P.,Quispe, Joel,Carragher, Bridget,Potter, WILEY‐VCH Verlag 2011 ADVANCED MATERIALS Vol.23 No.20
<P><B>Abstract</B></P><P>The review will describe experiments inspired by the rich variety of bundles and networks of interacting microtubules (MT), neurofilaments, and filamentous‐actin in neurons where the nature of the interactions, structures, and structure‐function correlations remain poorly understood. We describe how three‐dimensional (3D) MT bundles and 2D MT bundles may assemble, in cell free systems in the presence of counter‐ions, revealing structures not predicted by polyelectrolyte theories. Interestingly, experiments reveal that the neuronal protein tau, an abundant MT‐associated‐protein in axons, modulates the MT diameter providing insight for the control of geometric parameters in bio‐ nanotechnology. In another set of experiments we describe lipid‐protein‐nanotubes, and lipid nano‐ tubes and rods, resulting from membrane shape evolution processes involving protein templates and curvature stabilizing lipids. Similar membrane shape changes, occurring in cells for the purpose of specific functions, are induced by interactions between membranes and proteins. The biological materials systems described have applications in bio‐nanotechnology.</P>