Elizabeth S. Erickson scite author profile

Dunn

2005

Heating near the aperture of aluminum coated, fiber optic near-field scanning optical microscopy probes was studied as a function of input and output powers. Using the shear-force feedback method, near-field probes were positioned nanometers above a thermochromic polymer and spectra were recorded as the input power was varied. Excitation at 405 nm of a thin polymer film incorporating perylene and N-allyl-N-methylaniline leads to dual emission peaks in the spectra. The relative peak intensity is temperature sensitive leading to a ratiometric measurement, which avoids complications based solely on intensity. Using this method, we find that the proximal end of typical near-field probes modestly increase in temperature to 40-45°C at output powers of a few nanowatts ͑input power of ϳ0.15 mW͒. This increases to 55-65°C at higher output powers of 50 nW or greater ͑input power of ϳ2-4 mW͒. Thermal heating of the probe at higher powers leads to probe elongation, which limits the heating experienced by the sample.

Nuclear side conformational changes in the nuclear pore complex following calcium release from the nuclear membrane

Erickson²,

Moore-Nichols³

et al. 2004

Phys. Biol.

Changes in nuclear pore complex (NPC) structure are studied following treatments modifying the cisternal calcium levels located between the two lipid bilayers that together form the nuclear envelope. Since the NPC forms the only known passageway across the nuclear envelope, it plays a central role in nucleocytoplasmic transport. Understanding the origin of conformational changes that may affect this trafficking or modify cargo interactions with the NPC is, therefore, necessary to completely understand the function of these complex molecules. In previous studies on the cytoplasmic side of the nuclear envelope, a central mass was observed in the pore of the NPC and its location was shown to be sensitive to the cisternal calcium levels. Here we report atomic force microscopy (AFM) measurements on the nuclear side of the envelope, which also reveal a cisternal calcium dependence in the conformational state of the NPC. These measurements, made at the single nuclear pore level, reveal a displacement of the central mass towards the nuclear side of the membrane following treatments with adenophostin A, a specific agonist of calcium channels (inositol 1,4,5-trisphosphate (IP(3)) receptors) located in the nuclear envelope. We further demonstrate that these conformational changes are observed in nuclear pores lacking the basket structure while samples prepared in the presence of protease inhibitors retain baskets and block AFM measurements of the channel. While these measurements are unable to distinguish whether the central mass is cargo or an integral component of the NPC, its dose-dependent displacement with cisternal calcium levels does suggest links to transport or to changes in cargo interactions with the NPC. Taken together with previous measurements done on the cytoplasmic side of the nuclear envelope, these studies argue against a piston-like displacement of the central mass and instead suggest a more complicated mechanism. One possibility involves a concerted collapse of the NPC rings towards one another following cisternal calcium release, thus leading to the apparent emergence of the central mass from each side of the NPC.

Activation of ryanodine receptors in the nuclear envelope alters the conformation of the nuclear pore complex

Moore-Nichols

et al. 2004

Biophysical Chemistry

The role of nuclear envelope calcium in modifying nuclear pore complex structureThis paper is one of a selection of papers published in this Special Issue, entitled The Nucleus: A Cell Within A Cell.

Can. J. Physiol. Pharmacol.

Moore

et al. 2006

Some of the most important trafficking processes in cells involve transport across the nuclear envelope. Whether it is the import of transcription factors or the export of RNA, the only known portal across the double lipid bilayer that forms the nuclear envelope are the macromolecular pores known as nuclear pore complexes (NPCs). Understanding how signals influence the conformation of the NPC is important for testing models of, and perhaps modifying, transport across the nuclear envelope. Here we summarize high-resolution atomic force microscopy studies of NPC structure following manipulation of nuclear envelope calcium stores of nuclei from Xenopus laevis oocytes. The results show that the release of calcium from these stores through the specific activation of inositol 1,4,5-trisphosphate receptors leads to changes in NPC structure observable from both sides of the nuclear envelope. The diameter of the NPC is also sensitive to these calcium stores and increases upon calcium release. Western blot analysis reveals the presence of ryanodine receptors in the nuclear envelope of X. laevis oocytes, although in low abundance. Activation of these calcium channels also leads to the displacement of the central mass and changes in NPC diameter. This change in structure may involve a displacement of the cytoplasmic and nuclear rings of the NPC towards each other, leading to the apparent emergence of the central mass from both sides of the NPC. The changes in conformation and diameter of the NPC may alter cargo access and binding to phenylalanine-glycine repeats lining the pore, thus altering transport.

Characterization of power induced heating and damage in fiber optic probes for near-field scanning optical microscopy

Dickenson

et al. 2007

Tip-induced sample heating in near-field scanning optical microscopy ͑NSOM͒ is studied for fiber optic probes fabricated using the chemical etching technique. To characterize sample heating from etched NSOM probes, the spectra of a thermochromic polymer sample are measured as a function of probe output power, as was previously reported for pulled NSOM probes. The results reveal that sample heating increases rapidly to ϳ55-60°C as output powers reach ϳ50 nW. At higher output powers, the sample heating remains approximately constant up to the maximum power studied of ϳ450 nW. The sample heating profiles measured for etched NSOM probes are consistent with those previously measured for NSOM probes fabricated using the pulling method. At high powers, both pulled and etched NSOM probes fail as the aluminum coating is damaged. For probes fabricated in our laboratory we find failure occurring at input powers of 3.4± 1.7 and 20.7± 6.9 mW for pulled and etched probes, respectively. The larger half-cone angle for etched probes ͑ϳ15°for etched and ϳ6°for pulled probes͒ enables more light delivery and also apparently leads to a different failure mechanism. For pulled NSOM probes, high resolution images of NSOM probes as power is increased reveal the development of stress fractures in the coating at a taper diameter of ϳ6 m. These stress fractures, arising from the differential heating expansion of the dielectric and the metal coating, eventually lead to coating removal and probe failure. For etched tips, the absence of clear stress fractures and the pooled morphology of the damaged aluminum coating following failure suggest that thermal damage may cause coating failure, although other mechanisms cannot be ruled out.