The
interior of living cells is a dense and polydisperse suspension
of macromolecules. Such a complex system challenges an understanding
in terms of colloidal suspensions. As a fundamental test we employ
neutron spectroscopy to measure the diffusion of tracer proteins (immunoglobulins)
in a cell-like environment (cell lysate) with explicit control over
crowding conditions. In combination with Stokesian dynamics simulation,
we address protein diffusion on nanosecond time scales where hydrodynamic
interactions dominate over negligible protein collisions. We successfully
link the experimental results on these complex, flexible molecules
with coarse-grained simulations providing a consistent understanding
by colloid theories. Both experiments and simulations show that tracers
in polydisperse solutions close to the effective particle radius R
eff = ⟨R
i
3⟩1/3 diffuse approximately as if the
suspension was monodisperse. The simulations further show that macromolecules
of sizes R > R
eff (R < R
eff) are slowed more
(less) effectively even at nanosecond time scales, which is highly
relevant for a quantitative understanding of cellular processes.
Coronavirus disease-2019
(COVID-19), a potentially lethal respiratory
illness caused by the coronavirus SARS-CoV-2, emerged in the end of
2019 and has since spread aggressively across the globe. A thorough
understanding of the molecular mechanisms of cellular infection by
coronaviruses is therefore of utmost importance. A critical stage
in infection is the fusion between viral and host membranes. Here,
we present a detailed investigation of the role of selected SARS-CoV-2
Spike fusion peptides, and the influence of calcium and cholesterol,
in this fusion process. Structural information from specular neutron
reflectometry and small angle neutron scattering, complemented by
dynamics information from quasi-elastic and spin–echo neutron
spectroscopy, revealed strikingly different functions encoded in the
Spike fusion domain. Calcium drives the N-terminal of the Spike fusion
domain to fully cross the host plasma membrane. Removing calcium,
however, reorients the peptide back to the lipid leaflet closest to
the virus, leading to significant changes in lipid fluidity and rigidity.
In conjunction with other regions of the fusion domain, which are
also positioned to bridge and dehydrate viral and host membranes,
the molecular events leading to cell entry by SARS-CoV-2 are proposed.
Probing molecules using perdeuteration (i.e deuteration in which all hydrogen atoms are replaced by deuterium) is extremely useful in a wide range of biophysical techniques. In the case of lipids, the synthesis of the biologically relevant unsaturated perdeuterated lipids is challenging and not usually pursued. In this work, perdeuterated phospholipids and sterols from the yeast Pichia pastoris grown in deuterated medium are extracted and analyzed as derivatives by gas chromatography and mass spectrometry respectively. When yeast cells are grown in a deuterated environment, the phospholipid homeostasis is maintained but the fatty acid unsaturation level is modified while the ergosterol synthesis is not affected by the deuterated culture medium. Our results confirm that the production of well defined natural unsaturated perdeuterated lipids is possible and gives also new insights about the process of desaturase enzymes.
The application of protein deuteration and high flux neutron reflectometry has allowed a comparison of the adsorption properties of lysozyme at the air-water interface from dilute solutions in the absence and presence of high concentrations of two strong denaturants: urea and guanidine hydrochloride (GuHCl). The surface excess and adsorption layer thickness were resolved and complemented by images of the mesoscopic lateral morphology from Brewster angle microscopy. It was revealed that the thickness of the adsorption layer in the absence of added denaturants is less than the short axial length of the lysozyme molecule, which indicates deformation of the globules at the interface. Two-dimensional elongated aggregates in the surface layer merge over time to form an extensive network at the approach to steady state. Addition of denaturants in the bulk results in an acceleration of adsorption and an increase of the adsorption layer thickness. These results are attributed to incomplete collapse of the globules in the bulk from the effects of the denaturants as a result of interactions between remote amino acid residues. Both effects may be connected to an increase of the effective total volume of macromolecules due to the changes of their tertiary structure, that is, the formation of molten globules under the influence of urea and the partial unfolding of globules under the influence of GuHCl. In the former case, the increase of globule hydrophobicity leads to cooperative aggregation in the surface layer during adsorption. Unlike in the case of solutions without denaturants, the surface aggregates are short and wormlike, their size does not change with time, and they do not merge to form an extensive network at the approach to steady state. To the best of our knowledge, these are the first observations of cooperative aggregation in lysozyme adsorption layers.
The activity of the potent but highly toxic antifungal drug Amphotericin B (AmB), used intravenously to treat systemic fungal and parasitic infections, is widely accepted to result from its specific interaction with the fungal sterol ergosterol. While the effect of sterols on AmB activity has been intensely investigated, the role of membrane phospholipid composition has largely been ignored, and structural studies of native membranes have been hampered by their complex and disordered nature. We show for the first time that the structure of fungal membranes derived from Pichia pastoris yeast depends on the degree of lipid polyunsaturation, which has an impact on the structural consequences of AmB activity. AmB inserts in yeast membranes even in the absence of ergosterol, and forms an extra-membraneous layer whose thickness is resolved to be 4-5 nm. In ergosterol-containing membranes, AmB insertion is accompanied by ergosterol extraction into this layer. The AmB-sponge mediated depletion of ergosterol from P. pastoris membranes gives rise to a significant membrane thinning effect that depends on the degree of lipid polyunsaturation. The resulting hydrophobic mismatch is likely to interfere with a much broader range of membrane protein functions than those directly involving ergosterol, and suggests that polyunsaturated lipids could boost the efficiency of AmB. Furthermore, a low degree of lipid polyunsaturation leads to least AmB insertion and may protect host cells against the toxic effects of AmB. These results provide a new framework based on lipid composition and membrane structure through which we can understand its antifungal action and develop better treatments.
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