Your search keyword '"Fischer, Alexandra L"' showing total 9 results

1. Developing New Spectroscopic Techniques to Study Carotenoid-Dependent Non-Photochemical Quenching in Plants and Algae

Author

Fischer, Alexandra L, Fleming, Graham R1, Fischer, Alexandra L, Fischer, Alexandra L, Fleming, Graham R1, and Fischer, Alexandra L

Abstract

Photosynthetic organisms live in environments with highly variable light conditions. In order to survive, they must maximize photosynthetic production while at the same time minimizing photodamage caused by excess absorbed sunlight. To prevent this photodamage, photosynthetic organisms have developed a suite of mechanisms called non-photochemical quenching (NPQ) mechanisms which dissipate excess excitation energy as heat. However, little is known about the specific molecular mechanisms that convert excitation energy to heat or how these mechanisms are activated and de-activated. NPQ mechanisms have previously been characterized according to their timescale of activation, with the fastest group, referred to as qE mechanisms, responding within 30 s to a few minutes to increases in light intensity. As the fastest responders, these mechanisms are responsible for the largest portion of the energy quenching. Previous work has shown that these mechanisms require the carotenoid zeaxanthin (Zea) in order to fully function. There have been two types of proposed molecular mechanisms by which this carotenoid could be directly involved in excitation energy quenching, and this thesis describes the development of new spectroscopic techniques that are capable of tracking intermediate species associated with each of these mechanisms as samples acclimate to high light conditions. These techniques were then used to determine the role of each of these quenching mechanisms in several photosynthetic organisms. The first molecular mechanism of interest is called charge transfer (CT) quenching. This mechanism involves a chlorophyll (Chl) –Zea dimer, which accepts excitation energy from light-harvesting chlorophylls, then undergoes charge separation, and finally charge recombination to complete the cycle. Previous transient absorption (TA) experiments found that an intermediate Zea cation species formed selectively in light-acclimated plant thylakoid samples, but did not determine at what p

Published

2018

2. Developing New Spectroscopic Techniques to Study Carotenoid-Dependent Non-Photochemical Quenching in Plants and Algae

Author

Fischer, Alexandra L, Fleming, Graham R1, Fischer, Alexandra L, Fischer, Alexandra L, Fleming, Graham R1, and Fischer, Alexandra L

Abstract

Photosynthetic organisms live in environments with highly variable light conditions. In order to survive, they must maximize photosynthetic production while at the same time minimizing photodamage caused by excess absorbed sunlight. To prevent this photodamage, photosynthetic organisms have developed a suite of mechanisms called non-photochemical quenching (NPQ) mechanisms which dissipate excess excitation energy as heat. However, little is known about the specific molecular mechanisms that convert excitation energy to heat or how these mechanisms are activated and de-activated. NPQ mechanisms have previously been characterized according to their timescale of activation, with the fastest group, referred to as qE mechanisms, responding within 30 s to a few minutes to increases in light intensity. As the fastest responders, these mechanisms are responsible for the largest portion of the energy quenching. Previous work has shown that these mechanisms require the carotenoid zeaxanthin (Zea) in order to fully function. There have been two types of proposed molecular mechanisms by which this carotenoid could be directly involved in excitation energy quenching, and this thesis describes the development of new spectroscopic techniques that are capable of tracking intermediate species associated with each of these mechanisms as samples acclimate to high light conditions. These techniques were then used to determine the role of each of these quenching mechanisms in several photosynthetic organisms. The first molecular mechanism of interest is called charge transfer (CT) quenching. This mechanism involves a chlorophyll (Chl) –Zea dimer, which accepts excitation energy from light-harvesting chlorophylls, then undergoes charge separation, and finally charge recombination to complete the cycle. Previous transient absorption (TA) experiments found that an intermediate Zea cation species formed selectively in light-acclimated plant thylakoid samples, but did not determine at what p

Published

2018

3. Chlorophyll–carotenoid excitation energy transfer and charge transfer in Nannochloropsis oceanica for the regulation of photosynthesis

Author

Park, Soomin, Park, Soomin, Steen, Collin J, Lyska, Dagmar, Fischer, Alexandra L, Endelman, Benjamin, Iwai, Masakazu, Niyogi, Krishna K, Fleming, Graham R, Park, Soomin, Park, Soomin, Steen, Collin J, Lyska, Dagmar, Fischer, Alexandra L, Endelman, Benjamin, Iwai, Masakazu, Niyogi, Krishna K, and Fleming, Graham R

Published

2019

4. Snapshot transient absorption spectroscopy: toward in vivo investigations of nonphotochemical quenching mechanisms.

Author

Park, Soomin, Park, Soomin, Steen, Collin J, Fischer, Alexandra L, Fleming, Graham R, Park, Soomin, Park, Soomin, Steen, Collin J, Fischer, Alexandra L, and Fleming, Graham R

Abstract

Although the importance of nonphotochemical quenching (NPQ) on photosynthetic biomass production and crop yields is well established, the in vivo operation of the individual mechanisms contributing to overall NPQ is still a matter of controversy. In order to investigate the timescale and activation dynamics of specific quenching mechanisms, we have developed a technique called snapshot transient absorption (TA) spectroscopy, which can monitor molecular species involved in the quenching response with a time resolution of 30 s. Using intact thylakoid membrane samples, we show how conventional TA kinetic and spectral analyses enable the determination of the appropriate wavelength and time delay for snapshot TA experiments. As an example, we show how the chlorophyll-carotenoid charge transfer and excitation energy transfer mechanisms can be monitored based on signals corresponding to the carotenoid (Car) radical cation and Car S1 excited state absorption, respectively. The use of snapshot TA spectroscopy together with the previously reported fluorescence lifetime snapshot technique (Sylak-Glassman et al. in Photosynth Res 127:69-76, 2016) provides valuable information such as the concurrent appearance of specific quenching species and overall quenching of excited Chl. Furthermore, we show that the snapshot TA technique can be successfully applied to completely intact photosynthetic organisms such as live cells of Nannochloropsis. This demonstrates that the snapshot TA technique is a valuable method for tracking the dynamics of intact samples that evolve over time, such as the photosynthetic system in response to high-light exposure.

Published

2019

5. Snapshot transient absorption spectroscopy: toward in vivo investigations of nonphotochemical quenching mechanisms.

Author

Park, Soomin, Park, Soomin, Steen, Collin J, Fischer, Alexandra L, Fleming, Graham R, Park, Soomin, Park, Soomin, Steen, Collin J, Fischer, Alexandra L, and Fleming, Graham R

Abstract

Although the importance of nonphotochemical quenching (NPQ) on photosynthetic biomass production and crop yields is well established, the in vivo operation of the individual mechanisms contributing to overall NPQ is still a matter of controversy. In order to investigate the timescale and activation dynamics of specific quenching mechanisms, we have developed a technique called snapshot transient absorption (TA) spectroscopy, which can monitor molecular species involved in the quenching response with a time resolution of 30 s. Using intact thylakoid membrane samples, we show how conventional TA kinetic and spectral analyses enable the determination of the appropriate wavelength and time delay for snapshot TA experiments. As an example, we show how the chlorophyll-carotenoid charge transfer and excitation energy transfer mechanisms can be monitored based on signals corresponding to the carotenoid (Car) radical cation and Car S1 excited state absorption, respectively. The use of snapshot TA spectroscopy together with the previously reported fluorescence lifetime snapshot technique (Sylak-Glassman et al. in Photosynth Res 127:69-76, 2016) provides valuable information such as the concurrent appearance of specific quenching species and overall quenching of excited Chl. Furthermore, we show that the snapshot TA technique can be successfully applied to completely intact photosynthetic organisms such as live cells of Nannochloropsis. This demonstrates that the snapshot TA technique is a valuable method for tracking the dynamics of intact samples that evolve over time, such as the photosynthetic system in response to high-light exposure.

Published

2019

6. Chlorophyll-Carotenoid Excitation Energy Transfer in High-Light-Exposed Thylakoid Membranes Investigated by Snapshot Transient Absorption Spectroscopy.

Author

Park, Soomin, Park, Soomin, Fischer, Alexandra L, Steen, Collin J, Iwai, Masakazu, Morris, Jonathan M, Walla, Peter Jomo, Niyogi, Krishna K, Fleming, Graham R, Park, Soomin, Park, Soomin, Fischer, Alexandra L, Steen, Collin J, Iwai, Masakazu, Morris, Jonathan M, Walla, Peter Jomo, Niyogi, Krishna K, and Fleming, Graham R

Abstract

Nonphotochemical quenching (NPQ) provides an essential photoprotection in plants, assuring safe dissipation of excess energy as heat under high light. Although excitation energy transfer (EET) between chlorophyll (Chl) and carotenoid (Car) molecules plays an important role in NPQ, detailed information on the EET quenching mechanism under in vivo conditions, including the triggering mechanism and activation dynamics, is very limited. Here, we observed EET between the Chl Q y state and the Car S1 state in high-light-exposed spinach thylakoid membranes. The kinetic and spectral analyses using transient absorption (TA) spectroscopy revealed that the Car S1 excited state absorption (ESA) signal after Chl excitation has a maximum absorption peak around 540 nm and a lifetime of ∼8 ps. Snapshot TA spectroscopy at multiple time delays allowed us to track the Car S1 ESA signal as the thylakoid membranes were exposed to various light conditions. The obtained snapshots indicate that maximum Car S1 ESA signal quickly rose and slightly dropped during the initial high-light exposure (<3 min) and then gradually increased with a time constant of ∼5 min after prolonged light exposure. This suggests the involvement of both rapidly activated and slowly activated mechanisms for EET quenching. 1,4-Dithiothreitol (DTT) and 3,3'-dithiobis(sulfosuccinimidyl propionate) (DTSSP) chemical treatments further support that the Car S1 ESA signal (or the EET quenching mechanism) is primarily dependent on the accumulation of zeaxanthin and partially dependent on the reorganization of membrane proteins, perhaps due to the pH-sensing protein photosystem II subunit S.

Published

2018

7. Chlorophyll-Carotenoid Excitation Energy Transfer in High-Light-Exposed Thylakoid Membranes Investigated by Snapshot Transient Absorption Spectroscopy.

Author

Park, Soomin, Park, Soomin, Fischer, Alexandra L, Steen, Collin J, Iwai, Masakazu, Morris, Jonathan M, Walla, Peter Jomo, Niyogi, Krishna K, Fleming, Graham R, Park, Soomin, Park, Soomin, Fischer, Alexandra L, Steen, Collin J, Iwai, Masakazu, Morris, Jonathan M, Walla, Peter Jomo, Niyogi, Krishna K, and Fleming, Graham R

Abstract

Nonphotochemical quenching (NPQ) provides an essential photoprotection in plants, assuring safe dissipation of excess energy as heat under high light. Although excitation energy transfer (EET) between chlorophyll (Chl) and carotenoid (Car) molecules plays an important role in NPQ, detailed information on the EET quenching mechanism under in vivo conditions, including the triggering mechanism and activation dynamics, is very limited. Here, we observed EET between the Chl Q y state and the Car S1 state in high-light-exposed spinach thylakoid membranes. The kinetic and spectral analyses using transient absorption (TA) spectroscopy revealed that the Car S1 excited state absorption (ESA) signal after Chl excitation has a maximum absorption peak around 540 nm and a lifetime of ∼8 ps. Snapshot TA spectroscopy at multiple time delays allowed us to track the Car S1 ESA signal as the thylakoid membranes were exposed to various light conditions. The obtained snapshots indicate that maximum Car S1 ESA signal quickly rose and slightly dropped during the initial high-light exposure (<3 min) and then gradually increased with a time constant of ∼5 min after prolonged light exposure. This suggests the involvement of both rapidly activated and slowly activated mechanisms for EET quenching. 1,4-Dithiothreitol (DTT) and 3,3'-dithiobis(sulfosuccinimidyl propionate) (DTSSP) chemical treatments further support that the Car S1 ESA signal (or the EET quenching mechanism) is primarily dependent on the accumulation of zeaxanthin and partially dependent on the reorganization of membrane proteins, perhaps due to the pH-sensing protein photosystem II subunit S.

Published

2018

8. Snapshot Transient Absorption Spectroscopy of Carotenoid Radical Cations in High-Light-Acclimating Thylakoid Membranes.

Author

Park, Soomin, Park, Soomin, Fischer, Alexandra L, Li, Zhirong, Bassi, Roberto, Niyogi, Krishna K, Fleming, Graham R, Park, Soomin, Park, Soomin, Fischer, Alexandra L, Li, Zhirong, Bassi, Roberto, Niyogi, Krishna K, and Fleming, Graham R

Abstract

Nonphotochemical quenching mechanisms regulate light harvesting in oxygenic photosynthesis. Measurement techniques for nonphotochemical quenching have typically focused on downstream effects of quenching, such as measuring reduced chlorophyll fluorescence. Here, to directly measure a species involved in quenching, we report snapshot transient absorption (TA) spectroscopy, which rapidly tracks carotenoid radical cation signals as samples acclimate to excess light. The formation of zeaxanthin radical cations, which is possible evidence of zeaxanthin-chlorophyll charge-transfer (CT) quenching, was investigated in spinach thylakoids. Together with fluorescence lifetime snapshot data and time-resolved high-performance liquid chromatography (HPLC) measurements, snapshot TA reveals that Zea•+ formation is closely related to energy-dependent quenching (qE) in nonphotochemical quenching. Quantitative and dynamic information on CT quenching discussed in this work give insight into the design principles of photoprotection in natural photosynthesis.

Published

2017

9. Snapshot Transient Absorption Spectroscopy of Carotenoid Radical Cations in High-Light-Acclimating Thylakoid Membranes.

Author

Park, Soomin, Park, Soomin, Fischer, Alexandra L, Li, Zhirong, Bassi, Roberto, Niyogi, Krishna K, Fleming, Graham R, Park, Soomin, Park, Soomin, Fischer, Alexandra L, Li, Zhirong, Bassi, Roberto, Niyogi, Krishna K, and Fleming, Graham R

Abstract

Nonphotochemical quenching mechanisms regulate light harvesting in oxygenic photosynthesis. Measurement techniques for nonphotochemical quenching have typically focused on downstream effects of quenching, such as measuring reduced chlorophyll fluorescence. Here, to directly measure a species involved in quenching, we report snapshot transient absorption (TA) spectroscopy, which rapidly tracks carotenoid radical cation signals as samples acclimate to excess light. The formation of zeaxanthin radical cations, which is possible evidence of zeaxanthin-chlorophyll charge-transfer (CT) quenching, was investigated in spinach thylakoids. Together with fluorescence lifetime snapshot data and time-resolved high-performance liquid chromatography (HPLC) measurements, snapshot TA reveals that Zea•+ formation is closely related to energy-dependent quenching (qE) in nonphotochemical quenching. Quantitative and dynamic information on CT quenching discussed in this work give insight into the design principles of photoprotection in natural photosynthesis.

Published

2017