Abstract

In this study, we used optical spectroscopy to characterize the physical properties of microvesicles released from the thermoacidophilic archaeon Sulfolobus acidocaldarius (Sa-MVs). The most abundant proteins in Sa-MVs are the S-layer proteins, which self-assemble on the vesicle surface forming an array of crystalline structures. Lipids in Sa-MVs are exclusively bipolar tetraethers. We found that when excited at 275 nm, intrinsic protein fluorescence of Sa-MVs at 23 °C has an emission maximum at 303 nm (or 296 nm measured at 75 °C), which is unusually low for protein samples containing multiple tryptophans and tyrosines. In the presence of 10–11 mM of the surfactant n-tetradecyl-β-d-maltoside (TDM), Sa-MVs were disintegrated, the emission maximum of intrinsic protein fluorescence was shifted to 312 nm, and the excitation maximum was changed from 288 nm to 280.5 nm, in conjunction with a significant decrease (>2 times) in excitation band sharpness. These data suggest that most of the fluorescent amino acid residues in native Sa-MVs are in a tightly packed protein matrix and that the S-layer proteins may form J-aggregates. The membranes in Sa-MVs, as well as those of unilamellar vesicles (LUVs) made of the polar lipid fraction E (PLFE) tetraether lipids isolated from S. acidocaldarius (LUVPLFE), LUVs reconstituted from the tetraether lipids extracted from Sa-MVs (LUVMV) and LUVs made of the diester lipids, were investigated using the probe 6-dodecanoyl-2-dimethylaminonaphthalene (Laurdan). The generalized polarization (GP) values of Laurdan in tightly packed Sa-MVs, LUVMV, and LUVPLFE were found to be much lower than those obtained from less tightly packed DPPC gel state, which echoes the previous finding that the GP values from tetraether lipid membranes cannot be directly compared with the GP values from diester lipid membranes, due to differences in probe disposition. Laurdan’s GP and red-edge excitation shift (REES) values in Sa-MVs and LUVMV decrease with increasing temperature monotonically with no sign for lipid phase transition. Laurdan’s REES values are high (9.3–18.9 nm) in the tetraether lipid membrane systems (i.e., Sa-MVs, LUVMV and LUVPLFE) and low (0.4–5.0 nm) in diester liposomes. The high REES and low GP values suggest that Laurdan in tetraether lipid membranes, especially in the membrane of Sa-MVs, is in a very motionally restricted environment, bound water molecules and the polar moieties in the tetraether lipid headgroups strongly interact with Laurdan’s excited state dipole moment, and “solvent” reorientation around Laurdan’s chromophore in tetraether lipid membranes occurs very slowly compared to Laurdan’s lifetime.

Highlights

  • Microvesicles (MVs) released from the thermoacidophilic archaeon Sulfolobus acidocaldarius contain considerably fewer proteins (29 [1]) than MVs released from bacteria and mammalian cells

  • The generalized polarization (GP) and red edge excitation shift (REES) values of Laurdan fluorescence in Sa-MVs are compared with those obtained from the unilamellar vesicles (LUVs) made of the polar lipid fraction E (PLFE) lipids isolated from S. acidocaldarius (LUVPLFE) and the large unilamellar vesicles (LUVs) reconstituted from the tetraether lipids extracted from Sa-MVs (LUVMV) as well as the LUVs made of the synthetic diester lipids

  • There is a high possibility that the polar headgroups in Sa-MV lipids are very different from those in PLFE lipids; and (3) Sa-MV membrane is covered by an S-layer and contains membrane-bound proteins whereas LUVMV and LUVPLFE are protein free

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Summary

Introduction

Microvesicles (MVs) released from the thermoacidophilic archaeon Sulfolobus acidocaldarius (designated as Sa-MVs) contain considerably fewer proteins (29 [1]) than MVs released from bacteria and mammalian cells (hundreds [2,3]). There is a high possibility that the polar headgroups in Sa-MV lipids are very different from those in PLFE lipids; and (3) Sa-MV membrane is covered by an S-layer and contains membrane-bound proteins whereas LUVMV and LUVPLFE are protein free In these three tetraether lipid-based membrane systems, Laurdan’s GP decreases with increasing temperature monotonically without any abrupt changes. XTahmeihniegdh[R40E,4E1S].(FTihgeuhreig8h) aRnEdESlow(FiGguPre(F8ig)uarned6)lovwaluGePs o(fFLigauurreda6n) vflauloureesscoefnLceauinrdtaentrafeluthoererslcipenidc-ebainsetdetmraeemthberralnipeisdy-sbtaesmeds smuegmgebsrtatnheast ythsteembosusnudggweasttetrhmatotlheecubloeus nadndwtahteerpmoloalrelciupliedsmanodietthiees pinoltahrelippoidlarmhoeiaedtigesroinupthreegpioolnasr headgroup regions of tetraether lipid membranes, where the chromophore of Laurdan resides, strongly interact with Laurdan’s excited-state dipole moment [29] and that the solvent reorientation around the chromophore occurs very slowly compared to Laurdan’s fluorescence lifetime [42] Among these three tetraether membrane systems examined, the REES values of Sa-MVs Through the DPPC gel-to-fluid phase transition, the Laurdan’s depth penetration and orientation are changed resulting in an increase in REES, despite that solvent reorientation increases somewhat with increasing temperature

Growth of Archaea and Isolation of Sa-MVs
Chemicals and Reagents
Spectroscopy Measurements
Findings
Conclusions

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