Biochemische und zellbiologische Charakterisierung des COP Vesikel vermittelten Proteintransports in Pflanzen

Pimpl, Peter

03 May 2001

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

COP Vesikel

ER

Golgi-Apparat

Sekretion

ER Retention

Amylase

Calreticulin

42.15 Zellbiologie

42.13 Molekularbiologie

42.40 Pflanzencytologie

Analyse der differentiellen Expression von Transportfaktoren und deren Funktion bei dem nukleocytoplasmatischen Transport von TFIIIA / Analysis of the differential expression of transport factors and their function in nucleocytoplasmic transport of TFIIIA

Wischnewski, Jörg

24 April 2002

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Xenopus laevis

Nukleozytoplasmatischer Transport

Karyopherin

Importin

Kerntransport

Ribosomale Proteine

Expressionsmuster

Synexpressionsgruppe

Xenopus laevis

nucleocytoplasmic transport

karyopherin

importin

nuclear transport

ribosomal proteins

expression pattern

synexpression group

42.15

42.13

42.23

42.67

WK 000: Entwicklungsbiologie

TIP47 is recruited to lipid droplets and important for the organelle biogenesis and function / TIP47 wird zu Lipid-Tröpfchen rekrutiert und ist wichtig für die Biogenese und Funktion dieser Organellen

Bulankina, Anna

22 January 2004

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

TIP47

MPRs

Lipid-Tröpfchen

Membrantransport

TIP47

MPRs

lipid droplets

membrane transport

42.15 Zellbiologie

42.13 Molekularbiologie

35.70 Biochemie

WA

WH

Submembrane cytoskeleton-regulated assembly and functional activity of gap junctions / Funktionelle Regulation von gap junctions und ihrer Anordnung durch das Sub-membranale Zytoskelett

Butkevich, Eugenia

29 June 2004

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Gap junctions

Connexin43

Drebrin

FRET

gap junctions

connexin43

drebrin

FRET

42.13

42.15

A novel parabolic prism-type TIR microscope to study gold nanoparticle-loaded kinesin-1 motors with nanometer precision

Schneider, René

06 June 2013

Movement of motor proteins along cytoskeletal filaments is fundamental for various cellular processes ranging from muscle contraction over cell division and flagellar movement to intracellular transport. Not surprisingly, the impairment of motility was shown to cause severe diseases. For example, a link between impaired intracellular transport and neurodegenerative diseases, such as Alzheimer’s, has been established. There, the movement of kinesin-1, a neuronal motor protein transporting vesicles along microtubules toward the axonal terminal, is thought to be strongly affected by roadblocks leading to malfunction and death of the nerve cell. Detailed information on how the motility of kinesin-1 deteriorates in the presence of roadblocks and whether the motor has a mechanism to circumvent such obstructions is scarce. In this thesis, kinesin-1 motility was studied in vitro in the presence of rigor kinesin-1 mutants, which served as permanent roadblocks, under controlled single-molecule conditions. The 25 nm wide microtubule track, consisting of 13 individual protofilaments, resembles a multi-lane environment for transport by processive kinesin-1 motors. The existence of multiple traffic-lanes, allows kinesin-1 to utilize different paths for cargo transport and potentially also for the circumvention of roadblocks. However, direct observation of motor encounters with roadblocks has been intricate in the past, mainly due to limitations in both, spatial and temporal resolution. These limitations, intrinsic to fluorescent probes commonly utilized to report on the motor positions, originate from a low rate of photon generation (low brightness) and a limited photostability (short observation time). Thus, studying kinesin-1 encounters with microtubule-associated roadblocks requires alternative labels, which explicitly avoid the shortcomings of fluorescence and consequently allow for a higher localization precision. Promising candidates for replacing fluorescent dyes are gold nanoparticles (AuNPs), which offer an enormous scattering cross-section due to plasmon resonance in the visible part of the optical spectrum. Problematic, however, is their incorporation into conventionally used (fluorescence) microscopes, because illumination and scattered light have the same wavelength and cannot be separated spectrally. Therefore, an approach based on total internal reflection (TIR) utilizing a novel parabolically shaped quartz prism for illumination was developed within this thesis. This approach provided homogenous and spatially invariant illumination profiles in combination with a convenient control over a wide range of illumination angles. Moreover, single-molecule fluorescence as well as single-particle scattering were detectable with high signal-to-noise ratios. Importantly, AuNPs with a diameter of 40 nm provided sub-nanometer localization accuracies within millisecond integration times and reliably reported on the characteristic 8 nm stepping of individual kinesin-1 motors moving along microtubules. These results highlight the potential of AuNPs to replace fluorescent probes in future single-molecule experiments. The newly developed parabolic prism-type TIR microscope is expected to strongly facilitate such approaches in the future. To study how the motility of kinesin-1 is affected by permanent roadblocks on the microtubule lattice, first, conventional objective-type TIRF microscopy was applied to GFP-labeled motors. An increasing density of roadblocks caused the mean velocity, run length, and dwell time to decrease exponentially. This is explained by (i) the kinesin-1 motors showing extended pausing phases when confronted with a roadblock and (ii) the roadblocks causing a reduction in the free path of the motors. Furthermore, kinesin-1 was found to be highly sensitive to the crowdedness of microtubules as a roadblock decoration as low as 1 % sufficed to significantly reduce the landing rate. To study events, where kinesin-1 molecules continued their runs after having paused in front of a roadblock, AuNPs were loaded onto the tails of the motors. When observing the kinesin-1 motors with nanometer-precision, it was interestingly found that about 60 % of the runs continued by movements to the side, with the left and right direction being equally likely. This finding suggests that kinesin-1 is able to reach to a neighboring protofilament in order to ensure ongoing transportation. In the absence of roadblocks, individual kinesin-1 motors stepped sideward with a much lower, but non-vanishing probability (0.2 % per step). These findings suggest that processive motor proteins may possess an intrinsic side stepping mechanism, potentially optimized by evolution for their specific intracellular tasks.

TIRF Mikroskopie

Goldnanopartikel

Kinesin-1

Motor Protein

Hindernis

Blockade

Nanometer Tracking

Lokalisation

intrazellulärer Transport

in vitro

motility assay

TIRF microscopy

prism-type

gold nanoparticles

kinesin-1

motor protein

roadblock

obstacle

side stepping

nanometer tracking

localization

cargo transport

intracellular transport

side stepping

in vitro

motility assay

ddc:570

rvk:WC 2900

On the chloride dependence of vesicular glutamate transport / Über die Chloridabhängigkeit des vesikulären Glutamattransports

Schenck, Stephan

26 June 2009

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Neurotransmitter

Glutamat

Chlorid

Synaptisches Vesikel

Liposomen

Chloridkanal

Ionenkanal

VGLUT

ClC-3

neurotransmitter

glutamate

chloride

synaptic vesicle

liposome

chloride channel

ion channel

VGLUT

ClC-3

30.42

WHC 900: Vakuolen {Cytologie}

Identification of a new factor essential for vacuolar aminopeptidase I activity. / Identifizierung eines neuen, für die Aktivität der vakuolären Aminopeptidase I essentiellen Faktors

Pasupuleti, Naga Rekha

03 November 2004

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Zytoplasma-Vakuole Transportweg

Aminopeptidase

Vakuole

Cytoplasm-to-vacuole transport

Aminopeptidase

Vacuole

42.15 Zellbiologie

42.13 Molekularbiologie

35.70 Biochemie

WA

WH

The establishment and characterization of an improved cell-free assay for exocytosis in neuroendocrine PC12 cells / Etablierung und Charakterisierung eines verbesserten zellfreien Exozytose-Assays in neuroendokrinen PC12-Zellen

Barszczewski, Marcin Miroslaw

24 June 2005

No description available.

570 Biowissenschaften, Biologie

SNARE

NSF

alpha-SNAP

PC12-Zellen

ATP

Exozytose

priming

Fusion

SNARE

NSF

alpha-SNAP

PC12 cells

ATP

exocytosis

priming

fusion

42.13

42.15

Charakterisierung eines Proteinkomplexes in Säugerzellen, der am Transport zwischen Membrankompartimenten beteiligt ist. / Characterisation of a SNARE-complex involved in Golgi-to-ER retrograde transport in mammalian cells

Verrier, Sophie

03 November 2005

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

SNARE Proteine

FRET an lebenden Zellen

COPI-Vesikeln

KDEL-Rezeptor

Transports Golgi-ER

SNARE-proteins

Live-cell FRET

COPI-vesicles

KDEL-receptor

Golgi-ER transport

42.15 zellbiologie

A novel parabolic prism-type TIR microscope to study gold nanoparticle-loaded kinesin-1 motors with nanometer precision

Schneider, René

21 February 2013

Movement of motor proteins along cytoskeletal filaments is fundamental for various cellular processes ranging from muscle contraction over cell division and flagellar movement to intracellular transport. Not surprisingly, the impairment of motility was shown to cause severe diseases. For example, a link between impaired intracellular transport and neurodegenerative diseases, such as Alzheimer’s, has been established. There, the movement of kinesin-1, a neuronal motor protein transporting vesicles along microtubules toward the axonal terminal, is thought to be strongly affected by roadblocks leading to malfunction and death of the nerve cell. Detailed information on how the motility of kinesin-1 deteriorates in the presence of roadblocks and whether the motor has a mechanism to circumvent such obstructions is scarce. In this thesis, kinesin-1 motility was studied in vitro in the presence of rigor kinesin-1 mutants, which served as permanent roadblocks, under controlled single-molecule conditions. The 25 nm wide microtubule track, consisting of 13 individual protofilaments, resembles a multi-lane environment for transport by processive kinesin-1 motors. The existence of multiple traffic-lanes, allows kinesin-1 to utilize different paths for cargo transport and potentially also for the circumvention of roadblocks. However, direct observation of motor encounters with roadblocks has been intricate in the past, mainly due to limitations in both, spatial and temporal resolution. These limitations, intrinsic to fluorescent probes commonly utilized to report on the motor positions, originate from a low rate of photon generation (low brightness) and a limited photostability (short observation time). Thus, studying kinesin-1 encounters with microtubule-associated roadblocks requires alternative labels, which explicitly avoid the shortcomings of fluorescence and consequently allow for a higher localization precision. Promising candidates for replacing fluorescent dyes are gold nanoparticles (AuNPs), which offer an enormous scattering cross-section due to plasmon resonance in the visible part of the optical spectrum. Problematic, however, is their incorporation into conventionally used (fluorescence) microscopes, because illumination and scattered light have the same wavelength and cannot be separated spectrally. Therefore, an approach based on total internal reflection (TIR) utilizing a novel parabolically shaped quartz prism for illumination was developed within this thesis. This approach provided homogenous and spatially invariant illumination profiles in combination with a convenient control over a wide range of illumination angles. Moreover, single-molecule fluorescence as well as single-particle scattering were detectable with high signal-to-noise ratios. Importantly, AuNPs with a diameter of 40 nm provided sub-nanometer localization accuracies within millisecond integration times and reliably reported on the characteristic 8 nm stepping of individual kinesin-1 motors moving along microtubules. These results highlight the potential of AuNPs to replace fluorescent probes in future single-molecule experiments. The newly developed parabolic prism-type TIR microscope is expected to strongly facilitate such approaches in the future. To study how the motility of kinesin-1 is affected by permanent roadblocks on the microtubule lattice, first, conventional objective-type TIRF microscopy was applied to GFP-labeled motors. An increasing density of roadblocks caused the mean velocity, run length, and dwell time to decrease exponentially. This is explained by (i) the kinesin-1 motors showing extended pausing phases when confronted with a roadblock and (ii) the roadblocks causing a reduction in the free path of the motors. Furthermore, kinesin-1 was found to be highly sensitive to the crowdedness of microtubules as a roadblock decoration as low as 1 % sufficed to significantly reduce the landing rate. To study events, where kinesin-1 molecules continued their runs after having paused in front of a roadblock, AuNPs were loaded onto the tails of the motors. When observing the kinesin-1 motors with nanometer-precision, it was interestingly found that about 60 % of the runs continued by movements to the side, with the left and right direction being equally likely. This finding suggests that kinesin-1 is able to reach to a neighboring protofilament in order to ensure ongoing transportation. In the absence of roadblocks, individual kinesin-1 motors stepped sideward with a much lower, but non-vanishing probability (0.2 % per step). These findings suggest that processive motor proteins may possess an intrinsic side stepping mechanism, potentially optimized by evolution for their specific intracellular tasks.

info:eu-repo/classification/ddc/570

ddc:570