In vivo NMR as a tool for probing molecular structure and dynamics in intact Chlamydomonas reinhardtii cells

Fatemeh Azadi-Chegeni,Christo Schiphorst,Anjali Pandit

doi:10.1007/s11120-017-0412-9

Fatemeh Azadi-Chegeni, Christo Schiphorst + Show 1 more

Open Access

https://doi.org/10.1007/s11120-017-0412-9

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Journal: Photosynthesis Research	Publication Date: Jun 23, 2017
Citations: 12	License type: open-access

Affiliation: Leiden University, University of Verona

Abstract

We report the application of NMR dynamic spectral editing for probing the structure and dynamics of molecular constituents in fresh, intact cells and in freshly prepared thylakoid membranes of Chlamydomonas reinhardtii (Cr.) green algae. For isotope labeling, wild-type Cr. cells were grown on 13C acetate-enriched minimal medium. 1D 13C J-coupling based and dipolar-based MAS NMR spectra were applied to distinguish 13C resonances of different molecular components. 1D spectra were recorded over a physiological temperature range, and whole-cell spectra were compared to those taken from thylakoid membranes, evaluating their composition and dynamics. A theoretical model for NMR polarization transfer was used to simulate the relative intensities of direct, J-coupling, and dipolar-based polarization from which the degree of lipid segmental order and rotational dynamics of the lipid acyl chains were estimated. We observe that thylakoid lipid signals dominate the lipid spectral profile of whole algae cells, demonstrating that with our novel method, thylakoid membrane characteristics can be detected with atomistic precision inside intact photosynthetic cells. The experimental procedure is rapid and applicable to fresh cell cultures, and could be used as an original approach for detecting chemical profiles, and molecular structure and dynamics of photosynthetic membranes in vivo in functional states.

Highlights

The plasticity of oxygenic photosynthetic membranes is tightly connected with plant fitness in fluctuating environments and their capability to respond to stress in excess light or drought conditions
Essential here fore is the parallel development of suitable tools and methodology that can analyze molecular composition, structure, and plasticity of intact photosynthetic membranes of plants and cells grown under various environmental conditions or in different functional states
The CH peaks of the unsaturated ω3 fatty acids (FA) have much higher intensities in Insensitive nucleusenhanced polarization-transfer (INEPT) than in CP and the 132 ppm peak of the C16 carbons towards the FA end-tail are absent in CP, indicating that the majority of the ω3 FA chains have low segmental ordering and highly dynamic FA tails

Summary

Introduction

The plasticity of oxygenic photosynthetic membranes is tightly connected with plant fitness in fluctuating environments and their capability to respond to stress in excess light or drought conditions. Keywords Solid-state NMR · Polarization transfer · Conformational dynamics · Thylakoid membrane The CH peaks of the unsaturated ω3 fatty acids (FA) have much higher intensities in INEPT than in CP and the 132 ppm peak of the C16 carbons towards the FA end-tail are absent in CP, indicating that the majority of the ω3 FA chains have low segmental ordering and highly dynamic FA tails.

Results

Conclusion