Fluorescent-detected retrotranslocation of an endoplasmic reticulum - associated degradation (ERAD) substrate in a mammalian in vitro system

Wahlman, Judit

10 October 2008

Secretory proteins that are unable to assemble into native proteins in the endoplasmic reticulum (ER) are transported back into the cytosol for degradation. Many cytosolic and ER resident proteins have been identified so far as being involved in this retrotranslocation process, but it is difficult to determine whether these proteins have a direct or indirect effect. Interpretations are further complicated if the loss of a specific protein is obscured by the presence of another protein that is partially or wholly redundant. To overcome these limitations, a mammalian in vitro system was developed that allowed to monitor retrotranslocation synchronously and in real time in the absence of concurrent translocation. To examine the roles of different components in ER-associated degradation (ERAD), well-defined and homogeneous mammalian ER microsomes were prepared biochemically by encapsulating a fluorescent-labeled ERAD substrate with specific lumenal components. After mixing ATP, specific cytosolic proteins, and specific fluorescence quenching agents with microsomes, substrate retrotranslocation was initiated. The rate of substrate efflux from microsomes was monitored spectroscopically and continuously in real time by the reduction in fluorescence intensity as the fluorescent substrates passed through the ER membrane and were exposed to the quenching agents. Retrotranslocation kinetics were not significantly altered by replacing all lumenal proteins with only protein disulfide isomerase, or all cytosolic proteins with only the 19S proteasome cap. Retrotranslocation was blocked by affinity-purified antibodies against Derlin1, but not by affinity-purified antibodies against Sec61α or by membrane-bound ribosomes. Since the substrate also photocrosslinked Derlin1, but not Sec61α or TRAM, retrotranslocation of this ERAD substrate apparently involves Derlin1, but not the translocon. By labeling either the C- or N-terminus, it was revealed that the N-terminus of one ERAD substrate leaves the ER lumen first. This finding suggests that the protein is retrotranslocated as a linear polymer in a preferred direction. When RRMs were reconstituted with a fluorescent-labeled ERAD substrate and various ions. Ca2+ ions in the ER lumen increased the rate and extent of retrotranslocation, while Ca2+ ions in the cytosol decreased retrotranslocation. This approach therefore provides the first direct evidence of the involvement and importance of specific ionic requirements for ERAD.

endoplasmic reticulum

Fluorescence

Kinetics and dynamics study on the allosteric pathway of phosphofructokinase from Escherichia coli

Tie, Cuijuan

10 October 2008

Phosphofructokinase from Escherichia coli (EcPFK) is allosterically regulated by MgADP and phosphoenolpyruvate (PEP), which act to activate or inhibit, respectively, by changing the substrate (Fru-6-P) affinity of the enzyme. Both ligands bind to the same allosteric site in EcPFK. Therefore, the questions we want to address are how these two molecules regulate EcPFK and how the allosteric signal is propagated throughout the enzyme. EcPFK has 28 potential site-site interactions. These interactions in turn derive from multiple copies of 6 potentially unique homotropic interactions and 4 potentially unique heterotropic interactions. Making hybrid tetramer of EcPFK is used to isolate a single heterotropic interaction. To improve the yield of the 1:3 hybrid, the in vivo hybrid formation method was developed. Four heterotropic interactions were isolated by this manner and re-evaluated. The same kinetics characteristics were obtained for each 1:3 hybrid from both the in vivo and in vitro method. To address the question of how the allosteric signal is transmitted throughout EcPFK, we identified residues (G184, Asp59 and S157) that are important for the allosteric regulation for both PEP inhibition and MgADP activation. The impact of each mutation on individual interaction is unique and also suggests that the structural basis for PEP inhibition is different from that for MgADP activation. Most importantly, since the sum of each heterotropic interaction with a modification in only one subunit is equal to the total heterotropic interaction with a modification in all four subunits, this result indicates that the heterotropic allosteric signal transmission is realized in a single subunit. The 23Ã heterotropic interaction, which contributes the most to the PEP inhibition, was chosen to study the dynamic properties. Fluorescence was used to study the dynamic perturbations of the 23Ã interaction upon ligand binding. Taking advantage of the hybrid formation strategy and the tryptophan-shift mutagenesis method, a tryptophan residue can be placed at different individual locations throughout the native subunit containing the 23Ã heterotropic interaction. The steady-state anisotropy and lifetime measurement at each tryptophan position indicate that the 23Ã allosteric interaction involves the perturbation of side-chain dynamics both near and quite far away from the respective ligand binding sites.

kinetics

dynamics

fluorescence

hybrid

Fluorescent-detected retrotranslocation of an endoplasmic reticulum - associated degradation (ERAD) substrate in a mammalian in vitro system

Wahlman, Judit

15 May 2009

Secretory proteins that are unable to assemble into native proteins in the endoplasmic reticulum (ER) are transported back into the cytosol for degradation. Many cytosolic and ER resident proteins have been identified so far as being involved in this retrotranslocation process, but it is difficult to determine whether these proteins have a direct or indirect effect. Interpretations are further complicated if the loss of a specific protein is obscured by the presence of another protein that is partially or wholly redundant. To overcome these limitations, a mammalian in vitro system was developed that allowed to monitor retrotranslocation synchronously and in real time in the absence of concurrent translocation. To examine the roles of different components in ER-associated degradation (ERAD), well-defined and homogeneous mammalian ER microsomes were prepared biochemically by encapsulating a fluorescent-labeled ERAD substrate with specific lumenal components. After mixing ATP, specific cytosolic proteins, and specific fluorescence quenching agents with microsomes, substrate retrotranslocation was initiated. The rate of substrate efflux from microsomes was monitored spectroscopically and continuously in real time by the reduction in fluorescence intensity as the fluorescent substrates passed through the ER membrane and were exposed to the quenching agents. Retrotranslocation kinetics were not significantly altered by replacing all lumenal proteins with only protein disulfide isomerase, or all cytosolic proteins with only the 19S proteasome cap. Retrotranslocation was blocked by affinity-purified antibodies against Derlin1, but not by affinity-purified antibodies against Sec61α or by membrane-bound ribosomes. Since the substrate also photocrosslinked Derlin1, but not Sec61α or TRAM, retrotranslocation of this ERAD substrate apparently involves Derlin1, but not the translocon. By labeling either the C- or N-terminus, it was revealed that the N-terminus of one ERAD substrate leaves the ER lumen first. This finding suggests that the protein is retrotranslocated as a linear polymer in a preferred direction. When RRMs were reconstituted with a fluorescent-labeled ERAD substrate and various ions. Ca2+ ions in the ER lumen increased the rate and extent of retrotranslocation, while Ca2+ ions in the cytosol decreased retrotranslocation. This approach therefore provides the first direct evidence of the involvement and importance of specific ionic requirements for ERAD.

Fluorescence

endoplasmic reticulum

Single-molecule fluorescence microscopy studies of fluorescent probes in thin films and on nanoparticle surfaces

Lu, Yin

30 March 2011

Single-molecule (SM) fluorescence spectroscopy has become a useful and important experimental approach for investigating the optical properties of chemical systems. In this thesis, four subprojects in the field of SM fluorescence spectroscopy are presented in which SM spectroscopy has provided invaluable experimental insight into the systems of interest.<p> In the first project, the photophysical properties of Calcium-Green 1 (CG-1), a calcium-ion indicator, were studied at both the ensemble and SM levels. CG-1 is non-fluorescent in the absence of Ca2+ and becomes strongly fluorescent when bound to Ca2+. In the ensemble measurements, the absorption and fluorescence spectra were collected under various Ca2+ concentrations. In addition, the fluorescence lifetime of CG-2 was also studied as a function of [Ca2+]. From SM measurements, the photobleaching time and fluorescence intensity distributions of CG-1 were studied both in the presence and in absence of Ca2+. The results were compared with those obtained for the dual-fluorophoric variant, Calcium-Green 2 (CG-2), whose photophysical properties have been investigated by previous researchers. The experimental results reveal that CG-1 can exist in two different forms: a highly-quenched form due to the occurrence of photoinduced electron transfer (PET) in the absence of Ca2+, and a strongly fluorescent form when bound to Ca2+.<p> The second project is a continuation of a previous study on CG-2. In the dual-chromophore CG-2 system, energy transfer between chromophores is controlled by the orientation and spatial separation between chromophores. Dual polarization fluorescence microscopy was used to determine the relative conformation of the two fluorophores in the emissive form of CG-2. Distributions of fluorescence polarization of individual CG-2 molecules were collected for both Ca2+-free and Ca2+-saturated conditions. The experimental polarization results were compared to those calculated from a simple geometric model based on randomly-orientated fluorescent dimers. The results show good agreement with previous calculations of the molecular conformation of CG-2. This indicates that the dual polarization imaging approach has significant potential as a general tool for characterizing chromophore orientation in coupled-fluorophore systems.<p> In the third project, Nile Red (NR), a solvatochromic lipid stain, was incorporated into phase separated Langmuir-Blodgett (LB) films composed of arachidic acid (AA) and perfluorotetradecanoic acid (PA). According to previous studies by atomic force microscopy (AFM), two types of separated domains are formed in the LB films: micron-sized hexagonal discontinuous domains that are exclusively comprised of AA, and the surrounding continuous domains which are enriched in PA. The photophysical properties of NR were characterized in the two physically and chemically distinct domains via bulk and SM fluorescence measurements. In addition to fluorescence microscopy, fluorescence confocal spectromicroscopy was also applied in the ensemble measurements to determine the spectral properties of NR in different sub-environments. Experimental results indicated that a small sub-population of dye molecules localize on the perfluorinated regions of the sample, but this sub-population is spectroscopically indistinguishable from that associated with the hydrogenated domains. Contrast in images was primarily due to preferential accumulation of the hydrophobic dye on the hydrophobic regions of the LB films.<p> In the final project, the fluorescence quenching behavior of a strongly fluorescent probe Alexa Fluor 514 (AF514) was investigated when it was covalently bound to gold metal protected clusters (AuMPC) with negligible plasmon bands. The fluorescence emission of the dye-AuMPCs system was characterized at different dye/Au MPC loading ratios with a combination of steady state and time-resolved ensemble spectroscopic measurements. It was found that the extent of fluorescence quenching in the system was small. After correction of inner filter effects, the results from bulk measurement demonstrate that the weak quenching is due to static quenching of the dye by the AuMPCs. SM measurements provided further support for the bulk measurements, with the fluorescence intensity of coupled AF514 molecules being comparable with that of unconjugated molecules. The photobleaching of the dye-AuMPC conjugates took place as a series of consecutive photobleaching events, without additional blinking dynamics within the time resolution of the experiment. These results suggest that the fluorophores on the AuMPCs are either entirely quenched, or remaining unquenched, as is consistent with the ensemble measurements.

fluorescence

single-molecule

microscopy

Single-molecule fluorescence microscopy studies of fluorescent probes in thin films and on nanoparticle surfaces

Lu, Yin

30 March 2011

Single-molecule (SM) fluorescence spectroscopy has become a useful and important experimental approach for investigating the optical properties of chemical systems. In this thesis, four subprojects in the field of SM fluorescence spectroscopy are presented in which SM spectroscopy has provided invaluable experimental insight into the systems of interest.<p> In the first project, the photophysical properties of Calcium-Green 1 (CG-1), a calcium-ion indicator, were studied at both the ensemble and SM levels. CG-1 is non-fluorescent in the absence of Ca2+ and becomes strongly fluorescent when bound to Ca2+. In the ensemble measurements, the absorption and fluorescence spectra were collected under various Ca2+ concentrations. In addition, the fluorescence lifetime of CG-2 was also studied as a function of [Ca2+]. From SM measurements, the photobleaching time and fluorescence intensity distributions of CG-1 were studied both in the presence and in absence of Ca2+. The results were compared with those obtained for the dual-fluorophoric variant, Calcium-Green 2 (CG-2), whose photophysical properties have been investigated by previous researchers. The experimental results reveal that CG-1 can exist in two different forms: a highly-quenched form due to the occurrence of photoinduced electron transfer (PET) in the absence of Ca2+, and a strongly fluorescent form when bound to Ca2+.<p> The second project is a continuation of a previous study on CG-2. In the dual-chromophore CG-2 system, energy transfer between chromophores is controlled by the orientation and spatial separation between chromophores. Dual polarization fluorescence microscopy was used to determine the relative conformation of the two fluorophores in the emissive form of CG-2. Distributions of fluorescence polarization of individual CG-2 molecules were collected for both Ca2+-free and Ca2+-saturated conditions. The experimental polarization results were compared to those calculated from a simple geometric model based on randomly-orientated fluorescent dimers. The results show good agreement with previous calculations of the molecular conformation of CG-2. This indicates that the dual polarization imaging approach has significant potential as a general tool for characterizing chromophore orientation in coupled-fluorophore systems.<p> In the third project, Nile Red (NR), a solvatochromic lipid stain, was incorporated into phase separated Langmuir-Blodgett (LB) films composed of arachidic acid (AA) and perfluorotetradecanoic acid (PA). According to previous studies by atomic force microscopy (AFM), two types of separated domains are formed in the LB films: micron-sized hexagonal discontinuous domains that are exclusively comprised of AA, and the surrounding continuous domains which are enriched in PA. The photophysical properties of NR were characterized in the two physically and chemically distinct domains via bulk and SM fluorescence measurements. In addition to fluorescence microscopy, fluorescence confocal spectromicroscopy was also applied in the ensemble measurements to determine the spectral properties of NR in different sub-environments. Experimental results indicated that a small sub-population of dye molecules localize on the perfluorinated regions of the sample, but this sub-population is spectroscopically indistinguishable from that associated with the hydrogenated domains. Contrast in images was primarily due to preferential accumulation of the hydrophobic dye on the hydrophobic regions of the LB films.<p> In the final project, the fluorescence quenching behavior of a strongly fluorescent probe Alexa Fluor 514 (AF514) was investigated when it was covalently bound to gold metal protected clusters (AuMPC) with negligible plasmon bands. The fluorescence emission of the dye-AuMPCs system was characterized at different dye/Au MPC loading ratios with a combination of steady state and time-resolved ensemble spectroscopic measurements. It was found that the extent of fluorescence quenching in the system was small. After correction of inner filter effects, the results from bulk measurement demonstrate that the weak quenching is due to static quenching of the dye by the AuMPCs. SM measurements provided further support for the bulk measurements, with the fluorescence intensity of coupled AF514 molecules being comparable with that of unconjugated molecules. The photobleaching of the dye-AuMPC conjugates took place as a series of consecutive photobleaching events, without additional blinking dynamics within the time resolution of the experiment. These results suggest that the fluorophores on the AuMPCs are either entirely quenched, or remaining unquenched, as is consistent with the ensemble measurements.

fluorescence

single-molecule

microscopy

The Study of Material and Optical Properties for Cr-doped Fibers

Wang, Bo-Cyuan

23 July 2010

With the rapid growth of optical telecommunication, the low-loss windows from 1.3 to 1.6 £gm are available by using the technology of dry fiber fabrication. The operation range such as commercial Er-doped fiber amplifiers (EDFAs) is only 70 nm, so it is interesting to develop the broadband fiber amplifiers. The Cr ions classified into transition metals are doped in specific host materials to be a gain medium. The spectra near infrared range have shown 300 nm. In this study, we measure and develop the material and optical properties of Cr-doped fibers (CDFs) fabricated by drawing-tower technology. In the fabrication of CDFs using rod-in-tube (RIT), the smallest loss at 1550 nm is 0.08 dB/cm. The composition of core is 84% SiO2 and the structure is almost amorphous, but there is a little £^-Al2O3 nano-crystalline structure. In the fabrication of CDFs using modified RIT (MRIT), the smallest loss is 0.03 dB/cm. Both of CDFs fabricated by RIT and MRIT, the fluorescence intensity is weak. In the fabrication of CDFs using powder-in-tube (PIT), the smallest loss is 0.33 dB/cm. The 3dB emission spectrum is from 0.8 to 1 £gm and power density is 6 nW/10nm. The profile of spectra is difference because of Cr ions in distorted structure which allowed a wide distribution of sites. In the future, measure absorption spectra and analyze the core¡¦s composition dependence of the emission of CDFs to provide fabrication optimization. Promoting the spontaneous emission intensity makes CDFs for novel fiber lasers and broadband fiber amplifiers.

fluorescence

loss

CDF

Fluorescent-detected retrotranslocation of an endoplasmic reticulum - associated degradation (ERAD) substrate in a mammalian in vitro system

Wahlman, Judit

15 May 2009

Secretory proteins that are unable to assemble into native proteins in the endoplasmic reticulum (ER) are transported back into the cytosol for degradation. Many cytosolic and ER resident proteins have been identified so far as being involved in this retrotranslocation process, but it is difficult to determine whether these proteins have a direct or indirect effect. Interpretations are further complicated if the loss of a specific protein is obscured by the presence of another protein that is partially or wholly redundant. To overcome these limitations, a mammalian in vitro system was developed that allowed to monitor retrotranslocation synchronously and in real time in the absence of concurrent translocation. To examine the roles of different components in ER-associated degradation (ERAD), well-defined and homogeneous mammalian ER microsomes were prepared biochemically by encapsulating a fluorescent-labeled ERAD substrate with specific lumenal components. After mixing ATP, specific cytosolic proteins, and specific fluorescence quenching agents with microsomes, substrate retrotranslocation was initiated. The rate of substrate efflux from microsomes was monitored spectroscopically and continuously in real time by the reduction in fluorescence intensity as the fluorescent substrates passed through the ER membrane and were exposed to the quenching agents. Retrotranslocation kinetics were not significantly altered by replacing all lumenal proteins with only protein disulfide isomerase, or all cytosolic proteins with only the 19S proteasome cap. Retrotranslocation was blocked by affinity-purified antibodies against Derlin1, but not by affinity-purified antibodies against Sec61α or by membrane-bound ribosomes. Since the substrate also photocrosslinked Derlin1, but not Sec61α or TRAM, retrotranslocation of this ERAD substrate apparently involves Derlin1, but not the translocon. By labeling either the C- or N-terminus, it was revealed that the N-terminus of one ERAD substrate leaves the ER lumen first. This finding suggests that the protein is retrotranslocated as a linear polymer in a preferred direction. When RRMs were reconstituted with a fluorescent-labeled ERAD substrate and various ions. Ca2+ ions in the ER lumen increased the rate and extent of retrotranslocation, while Ca2+ ions in the cytosol decreased retrotranslocation. This approach therefore provides the first direct evidence of the involvement and importance of specific ionic requirements for ERAD.

Fluorescence

endoplasmic reticulum

Design of novel dyes towards the near-infrared

Loudet, Aurore

15 May 2009

A series of seven functionalized near-infrared aza-BODIPY dyes have been synthesized and their spectroscopic properties measured. Their fluorescence emissions could be tuned by altering the electronic substituents on the aryl-groups. A through-bond energy transfer cassette featuring two fluorescein units as donor, and an aza-BODIPY dye as acceptor, was then synthesized and its preliminary spectroscopic properties examined. This cassette exhibited absorption and fluorescence characteristics that were highly dependent on the pH and the solvent polarity. Furthermore, no energy transfer was observed upon excitation of the donor. Novel near-infrared aza-BODIPY were also synthesized via a one-pot, two step reaction. Upon demethylation and intermolecular cyclization onto the B-atom, a ~ 100 nm red¬shift of both the absorption and fluorescence emission maxima could be observed. Through-bond energy transfer cassettes based on squaraines have also been synthesized and their spectroscopic properties studied. These cassettes exhibited fast and efficient energy transfer from the donor to the acceptor. In depth experiments have also been realized to correlate the rate of energy transfer and structure on 3 different sets of through-bond energy transfer cassettes. No correlations could be made between the rate of the energy transfer and the nature of the acceptor, and the distance between the donor and acceptor. Finally, the use of DPP (diketo-pyrrolopyrolle) pigment as a potential donor for through-bond energy transfer cassettes was investigated. Three water-soluble DPPs dyes were prepared and studied. They all displayed weak fluorescence in water.

Dyes

fluorescence

near-infrared

Evaluation of chlorophyll fluorescence as a tool for the identification of drought tolerance in upland cotton

Longenberger, Polly Suzanne

15 May 2009

A novel bioassay for the evaluation of plant water status was developed by Burke (2007). The research reported herein was designed to evaluate this new protocol as a tool for use in cotton breeding programs for the identification of drought tolerant genotypes. Twenty genotypes were selected to represent diverse germplasm pools for a two-year field evaluation. Replicated tests were performed in Lubbock, TX and College Station, TX in 2005, 2006, and 2007. Dryland and irrigated treatments were administered in a split plot arrangement of a randomized complete block design. Fluorescence measurements were taken at mid-bloom and late bloom growth stages of growth. Source leaf tissue was harvested at predawn and subjected to high temperature incubation with fluorescence measurements subsequently taken hourly for five hours. Drought stressed plants had not mobilized their carbohydrate reserves from their source leaves overnight and thus maintained cell viability and therefore higher chlorophyll fluorescence values throughout the incubation with the opposite being true for nonstressed plants. Fiber lint yield and fiber properties were measured at the conclusion of the 2005 season in College Station and the 2006 season in College Station and Lubbock for comparison with the fluorescence data. Five genotypes, ‘Acala 1517-99’, ‘Deltapine 491’ (PVP no. 200100159), ‘Tamcot CAMD-E’, ‘Tamcot 22’ and TAM 89E-51, an unreleased breeding line, were selected based on field evaluation results in a preliminary study in 2005 to be included in a diallel analysis to determine the heritability of fluorescence measurements. Genotype x treatment effects complicated the classification of genotypic responses to drought. Few and inconsistent correlations were found among fluorescence values and lint yield or fiber properties. The diallel analysis did not identify general combining ability or specific combining ability effects for chlorophyll fluorescence measurements. Thus this procedure provides little potential in selecting plants for drought tolerance when plants are grown under field culture. Selection among Tamcot 22 and TAM 89E-51 plants for high and low genotypes according to fluorescence values did not yield progeny different from unselected Tamcot 22 and TAM 89E-51.

cotton

drought

fluorescence

Investigating cotranslational integration of a multi-spanning membrane protein into the endoplasmic reticulum membrane

Jongsma, Candice Gene

15 May 2009

Most membrane proteins in eukaryotic cells are co-translationally integrated into the endoplasmic reticulum (ER) membrane at aqueous pores termed translocons. During multi-spanning membrane protein (MSMP) integration, the nascent polypeptide is threaded into the translocon pore where each successive transmembrane segment (TMS) is moved laterally through the translocon into the bilayer. The hydrophilic polypeptide segments on each side of the TMS are alternately directed into either the aqueous cytosol or the aqueous ER lumen. How is the ER membrane permeability barrier maintained during this process? For a single-spanning signal-cleaved membrane protein, nascent chain movement into the lumen occurs while an ion-tight ribosome-translocon junction prevents ion flow through the translocon pore. Prior to opening this junction to allow nascent chain movement into the cytosol, BiP (Hsp70 binding protein) effects closure at the lumenal end of the pore to maintain the membrane permeability barrier. To determine whether the ribosome and BiP alternately mediate pore closure during the integration of a MSMP, integration intermediates with nascent chains of different lengths were prepared with a fluorescent probe positioned in the nascent chain far inside the ribosomal tunnel. Nascent chain exposure to the cytosol or lumen was then detected by the collisional quenching of the probe by iodide ions located on either the cytosolic or lumenal side of the membrane. While the first TMS through the tunnel caused the ribosome-translocon junction to open, the second TMS elicited both the closure of this junction and the opening of the lumenal end of the pore. Movement of a third TMS through the tunnel caused the ribosome-translocon junction to re-open after closure of the lumenal end. Pore opening and closing occurred after each TMS was 4-7 residues from the peptidyltransferase center, irrespective of TMS location in the nascent chain. The ribosome treated all TMSs in the same manner, regardless of their individual sequence or their native orientation. The ER membrane permeability barrier is maintained by ribosome-translocon interactions during cotranslational MSMP integration.

MEMBRANE

PROTEIN

FLUORESCENCE