David T. Cramb scite author profile

Under physiological conditions, multicomponent biological membranes undergo structural changes which help define how the membrane functions. An understanding of biomembrane structure-function relations can be based on knowledge of the physical and chemical properties of pure phospholipid bilayers. Here, we have investigated phase transitions in dipalmitoylphosphatidylcholine (DPPC) and dioleoylphosphatidylcholine (DOPC) bilayers. We demonstrated the existence of several phase transitions in DPPC and DOPC mica-supported bilayers by both atomic force microscopy imaging and force measurements. Supported DPPC bilayers show a broad L(beta)-L(alpha) transition. In addition to the main transition we observed structural changes both above and below main transition temperature, which include increase in bilayer coverage and changes in bilayer height. Force measurements provide valuable information on bilayer thickness and phase transitions and are in good agreement with atomic force microscopy imaging data. A De Gennes model was used to characterize the repulsive steric forces as the origin of supported bilayer elastic properties. Both electrostatic and steric forces contribute to the repulsive part of the force plot.

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Supported planar bilayer formation by vesicle fusion: the interaction of phospholipid vesicles with surfaces and the effect of gramicidin on bilayer properties using atomic force microscopy

Leonenko

Carnini

Cramb

2000

Biochimica et Biophysica Acta (BBA) - Biomembranes

196

182

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We have used magnetic alternating current mode atomic force microscopy (MAC-AFM) to investigate the formation of supported phospholipid bilayers (SPB) by the method of vesicle fusion. The systems studied were dioleoylphosphatidylcholine (DOPC) on mica and mica modified with 3-aminopropyl-triethoxy-silane (APTES), and DOPC vesicles with gramicidin incorporated on mica and APTES-modified mica. The AFM images reveal three stages of bilayer formation: localized disklike features that are single bilayer footprints of the vesicles, partial continuous coverage, and finally complete bilayer formation. The mechanism of supported phospholipid bilayers formation is the fusion of proximal vesicles, rather than surface disk migration. This mechanism does not appear to be affected by incorporation of gramicidin or by surface modification. Once formed, the bilayer develops circular defects one bilayer deep. These defects grow in size and number until a dynamic equilibrium is reached.

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Tailoring nanoparticle designs to target cancer based on tumor pathophysiology

Sykes

Dai

Sarsons

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

248

163

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Nanoparticles can provide significant improvements in the diagnosis and treatment of cancer. How nanoparticle size, shape, and surface chemistry can affect their accumulation, retention, and penetration in tumors remains heavily investigated, because such findings provide guiding principles for engineering optimal nanosystems for tumor targeting. Currently, the experimental focus has been on particle design and not the biological system. Here, we varied tumor volume to determine whether cancer pathophysiology can influence tumor accumulation and penetration of different sized nanoparticles. Monte Carlo simulations were also used to model the process of nanoparticle accumulation. We discovered that changes in pathophysiology associated with tumor volume can selectively change tumor uptake of nanoparticles of varying size. We further determine that nanoparticle retention within tumors depends on the frequency of interaction of particles with the perivascular extracellular matrix for smaller nanoparticles, whereas transport of larger nanomaterials is dominated by Brownian motion. These results reveal that nanoparticles can potentially be personalized according to a patient's disease state to achieve optimal diagnostic and therapeutic outcomes.cancer | nanoparticles | targeting | nano-bio interactions | tumor

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Microporous Metal−Organic Frameworks Formed in a Stepwise Manner from Luminescent Building Blocks

2006

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A series of trivalent lanthanides (Sm, Eu, Gd, Tb, Dy) have been complexed to the dianionic ligand, 4,4'-disulfo-2,2'-bipyridine-N,N'-dioxide, L, in a 3:1 ratio to form trianionic complex building blocks. These units were then cross-linked into a network solid by addition of BaCl2 to form mixed-metal networks of formula {Ba2(H2O)4[LnL3(H2O)2](H2O)nCl}infinity, Ln = Sm3+ (1), Eu3+ (2), Gd3+ (3), Tb3+ (4), Dy3+ (5). The networks were isostructural and contained open channels which readily absorbed and desorbed water accompanied by a spongelike shrinkage and expansion of the host. CO2 sorption measurements confirmed microporosity giving a DR surface area of 718 m2/gm and an average pore size of 6.4 A. Ligand L sensitized all the lanthanide ions with the exception of Gd3+. Studying the series of Ln complexes allowed the determination of the triplet state energy of L which is itself a new ligand for sensitization purposes. The luminescent properties of the lanthanide building blocks were retained in the porous network solid. From the luminescence data, it was possible to attribute the spongelike properties of the network to the Ba2+ coordination sphere rather than the Ln3+ center. Networks were characterized by X-ray crystallography, PXRD, DSC/TGA, water vapor and gas sorption, and luminescence spectroscopy.

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The DNA-Dependent Protein Kinase Interacts with DNA To Form a Protein−DNA Complex That Is Disrupted by Phosphorylation

et al. 2002

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DNA double-strand breaks are a serious threat to genome stability and cell viability. One of the major pathways for the repair of DNA double-strand breaks in human cells is nonhomologous end-joining. Biochemical and genetic studies have shown that the DNA-dependent protein kinase (DNA-PK), XRCC4, DNA ligase IV, and Artemis are essential components of the nonhomologous end-joining pathway. DNA-PK is composed of a large catalytic subunit, DNA-PKcs, and a heterodimer of Ku70 and Ku80 subunits. Current models predict that the Ku heterodimer binds to ends of double-stranded DNA, then recruits DNA-PKcs to form the active protein kinase complex. XRCC4 and DNA ligase IV are subsequently required for ligation of the DNA ends. Magnesium-ATP and the protein kinase activity of DNA-PKcs are essential for DNA double-strand break repair. However, little is known about the physiological targets of DNA-PK. We have previously shown that DNA-PKcs and Ku undergo autophosphorylation, and that this correlates with loss of protein kinase activity. Here we show, using electron spectroscopic imaging, that DNA-PKcs and Ku interact with multiple DNA molecules to form large protein-DNA complexes that converge at the base of multiple DNA loops. The number of large protein complexes and the amount of DNA associated with them were dramatically reduced under conditions that promote phosphorylation of DNA-PK. Moreover, treatment of autophosphorylated DNA-PK with the protein phosphatase 1 catalytic subunit restored complex formation. We propose that autophosphorylation of DNA-PK plays an important regulatory role in DNA double-strand break repair by regulating the assembly and disassembly of the DNA-PK-DNA complex.

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David T. Cramb

Investigation of Temperature-Induced Phase Transitions in DOPC and DPPC Phospholipid Bilayers Using Temperature-Controlled Scanning Force Microscopy

Supported planar bilayer formation by vesicle fusion: the interaction of phospholipid vesicles with surfaces and the effect of gramicidin on bilayer properties using atomic force microscopy

Tailoring nanoparticle designs to target cancer based on tumor pathophysiology

Microporous Metal−Organic Frameworks Formed in a Stepwise Manner from Luminescent Building Blocks

The DNA-Dependent Protein Kinase Interacts with DNA To Form a Protein−DNA Complex That Is Disrupted by Phosphorylation

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