Ali Tinazli scite author profile

Ageing of biological systems is accompanied by alterations in mitochondrial morphology, including a transformation from networks and filaments to punctuate units. The significance of these alterations with regard to ageing is not known. Here, we demonstrate that the dynamin-related protein 1 (Dnm1p), a mitochondrial fission protein conserved from yeast to humans, affects ageing in the two model systems we studied, Podospora anserina and Saccharomyces cerevisiae. Deletion of the Dnm1 gene delays the transformation of filamentous to punctuate mitochondria and retards ageing without impairing fitness and fertility typically observed in long-lived mutants. Our data further suggest that reduced mitochondrial fission extends life span by increasing cellular resistance to the induction of apoptosis and links mitochondrial dynamics, apoptosis and life-span control.

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Molecular Self‐Assembly, Chemical Lithography, and Biochemical Tweezers: A Path for the Fabrication of Functional Nanometer‐Scale Protein Arrays

Turchanin

et al. 2008

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Electron‐induced chemical lithography combined with self‐assembled monolayers and multivalent chelators for high‐affinity capturing of His‐tagged proteins are used to obtain specific, stable, highly parallel, and functional protein micro‐ and nanoarrays on solid substrates. The functionality of the generated large‐area protein arrays is shown in situ via specific, homogeneous, oriented and reversible immobilization of His6‐tagged 20S proteasome and fluorescence labelled His10‐tagged maltose binding proteins.

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High‐Affinity Chelator Thiols for Switchable and Oriented Immobilization of Histidine‐Tagged Proteins: A Generic Platform for Protein Chip Technologies

Tinazli

Tang

Valiokas

et al. 2005

Chemistry A European J

152

149

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Protein micro-/nanoarrays are becoming increasingly important in systematic approaches for the exploration of protein-protein interactions and dynamic protein networks, so there is a high demand for specific, generic, stable, uniform, and locally addressable protein immobilization on solid supports. Here we present multivalent metal-chelating thiols that are suitable for stable binding of histidine-tagged proteins on biocompatible self-assembled monolayers (SAMs). The architectures and physicochemical properties of these SAMs have been probed by various surface-sensitive techniques such as contact angle goniometry, ellipsometry, and infrared reflection-absorption spectroscopy. The specific molecular organization of proteins and protein complexes was demonstrated by surface plasmon resonance, confocal laser scanning, and atomic force microscopy. In contrast to the mono-NTA/His6 tag interaction, which has major drawbacks because of its low affinity and fast dissociation, drastically improved stability of protein binding by these multivalent chelator surfaces was observed. The immobilized histidine-tagged proteins are uniformly oriented and retain their function. At the same time, proteins can be removed from the chip surface under mild conditions (switchability). This new platform for switchable and oriented immobilization should assist proteome-wide wide analyses of protein-protein interactions as well as structural and single-molecule studies.

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Native protein nanolithography that can write, read and erase

et al. 2007

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The development of systematic approaches to explore protein-protein interactions and dynamic protein networks is at the forefront of biological sciences. Nanopatterned protein arrays offer significant advantages for sensing applications, including short diffusion times, parallel detection of multiple targets and the requirement for only tiny amounts of sample. Atomic force microscopy (AFM) based techniques have successfully demonstrated patterning of molecules, including stable proteins, with submicrometre resolution. Here, we introduce native protein nanolithography for the nanostructured assembly of even fragile proteins or multiprotein complexes under native conditions. Immobilized proteins are detached by a novel vibrational AFM mode (contact oscillation mode) and replaced by other proteins, which are selectively self-assembled from the bulk. This nanolithography permits rapid writing, reading and erasing of protein arrays in a versatile manner. Functional protein complexes may be assembled with uniform orientation at dimensions down to 50 nm. Such fabrication of two-dimensionally arranged nano-objects with biological activity will prove powerful for proteome-wide interaction screens and single molecule/virus/cell analyses.

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Two-substrate association with the 20S proteasome at single-molecule level

Hutschenreiter

Tinazli

Model

et al. 2004

EMBO J

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The bipartite structure of the proteasome raises the question of functional significance. A rational design for unraveling mechanistic details of the highly symmetrical degradation machinery from Thermoplasma acidophilum pursues orientated immobilization at metal-chelating interfaces via affinity tags fused either around the pore apertures or at the sides. End-on immobilization of the proteasome demonstrates that one pore is sufficient for substrate entry and product release. Remarkably, a 'deadend' proteasome can process only one substrate at a time. In contrast, the side-on immobilized and free proteasome can bind two substrates, presumably one in each antechamber, with positive cooperativity as analyzed by surface plasmon resonance and single-molecule crosscorrelation spectroscopy. Thus, the two-stroke engine offers the advantage of speeding up degradation without enhancing complexity.

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Ali Tinazli

Reducing mitochondrial fission results in increased life span and fitness of two fungal ageing models

Molecular Self‐Assembly, Chemical Lithography, and Biochemical Tweezers: A Path for the Fabrication of Functional Nanometer‐Scale Protein Arrays

High‐Affinity Chelator Thiols for Switchable and Oriented Immobilization of Histidine‐Tagged Proteins: A Generic Platform for Protein Chip Technologies

Native protein nanolithography that can write, read and erase

Two-substrate association with the 20S proteasome at single-molecule level

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