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1. The Candida albicans virulence factor candidalysin polymerizes in solution to form membrane pores and damage epithelial cells

   https://doi.org/10.7554/eLife.75490  

   Russell, Charles M; Schaefer, Katherine G; Dixson, Andrew; Gray, Amber LH; Pyron, Robert J; Alves, Daiane S; Moore, Nicholas; Conley, Elizabeth A; Schuck, Ryan J; White, Tommi A; et al (September 2022, eLife)

   The fungus Candida albicans is the most common cause of yeast infections in humans. Like many other disease-causing microbes, it releases several virulent proteins that invade and damage human cells. This includes the peptide candidalysin which has been shown to be crucial for infection. Human cells are surrounded by a protective membrane that separates their interior from their external environment. Previous work showed that candidalysin damages the cell membrane to promote infection. However, how candidalysin does this remained unclear. Similar peptides and proteins cause harm by inserting themselves into the membrane and then grouping together to form a ring. This creates a hole, or ‘pore’, that weakens the membrane and allows other molecules into the cell’s interior. Here, Russell, Schaefer et al. show that candidalysin uses a unique pore forming mechanism to impair the membrane of human cells. A combination of biophysical and cell biology techniques revealed that the peptide groups together to form a chain. This chain of candidalysin proteins then closes in on itself to create a loop structure that can insert into the membrane to form a pore. Once embedded within the membrane, the proteins within the loops rearrange again to make the pores more stable so they can cause greater damage. This type of pore formation has not been observed before, and may open up new avenues of research. For instance, researchers could use this information to develop inhibitors that stop candidalysin from forming chains and harming the membranes of cells. This could help treat the infections caused by C. albicans. 

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2. Determine both the conformation and orientation of a specific residue in α-synuclein(61–95) even in monolayer by 13C isotopic label and p-polarized multiple-angle incidence resolution spectrometry (pMAIRS)

   https://doi.org/10.1007/s44211-022-00128-0  

   Wang, Chengshan; Zhou, Yiqun; Ewuola, Christopher; Akinleye, Toyin; Hasegawa, Takeshi; Leblanc, Roger M. (May 2022, Analytical Sciences)

   Abstract Protein’s magic function stems from its structure and various analytical techniques have been developed for it. Among proteins, membrane proteins are encoded 20–30% of genomes, whereas cause challenges for many analytical techniques. For example, lots of membrane proteins cannot form single crystal structure required by X-ray crystallography. As for NMR, the measurements were hindered by the low tumbling rates of membrane (i.e., phospholipid bilayers) where membrane proteins exist. In addition, membrane proteins usually lay parallel to the surface of phospholipid bilayers or form transmembrane structure. No matter parallel or perpendicular to phospholipid bilayers surface, membrane proteins form monolayer structure which is also difficult for X-ray and NMR to provide high-resolution results. Because NMR and X-ray crystallography are the two major analytical techniques to address protein’s structure, membrane proteins only contribute 2.4% to the solved protein databank. Surface FT-IR techniques can evaluate the conformation and orientation of membrane proteins by amide I band. Specifically for α-helical peptides/proteins, the orientation of the axis is critical to decide whether proteins form transmembrane structure. Notice that the traditional FT-IR can only provide “low-resolution” results.Here,¹³C isotope was introduced into the nonamyloid component (NAC), which spans residues 61–95 of α-synuclein (α-syn). Then, p-polarized multiple-angle incidence resolution spectrometry (pMAIRS) was used to determine the orientation of a specific residue of α-helical NAC in monolayer. In general, pMAIRS is a novel technique to work complementary with X-ray and NMR to address membrane peptides/proteins structure with high resolution even in monolayer. Graphical abstract 

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3. Plant Membrane-On-A-Chip: A Platform for Studying Plant Membrane Proteins and Lipids

   https://doi.org/10.1021/acsami.3c18562  

   Stuebler, Martin; Manzer, Zachary A; Liu, Han-Yuan; Miller, Julia; Richter, Annett; Krishnan, Srinivasan; Selivanovitch, Ekaterina; Banuna, Barituziga; Jander, Georg; Reimhult, Erik; et al (April 2024, ACS Applied Materials & Interfaces)

   The cell plasma membrane is a two-dimensional, fluid mosaic material composed of lipids and proteins that create a semipermeable barrier defining the cell from its environment. Compared with soluble proteins, the methodologies for the structural and functional characterization of membrane proteins are challenging. An emerging tool for studies of membrane proteins in mammalian systems is a “plasma membrane on a chip,” also known as a supported lipid bilayer. Here, we create the “plant-membrane-on-a-chip,″ a supported bilayer made from the plant plasma membranes of Arabidopsis thaliana, Nicotiana benthamiana, or Zea mays. Membrane vesicles from protoplasts containing transgenic membrane proteins and their native lipids were incorporated into supported membranes in a defined orientation. Membrane vesicles fuse and orient systematically, where the cytoplasmic side of the membrane proteins faces the chip surface and constituents maintain mobility within the membrane plane. We use plant-membrane-on-a-chip to perform fluorescent imaging to examine protein–protein interactions and determine the protein subunit stoichiometry of FLOTILLINs. We report here that like the mammalian FLOTILLINs, FLOTILLINs expressed in Arabidopsis form a tetrameric complex in the plasma membrane. This plant-membrane-on-a-chip approach opens avenues to studies of membrane properties of plants, transport phenomena, biophysical processes, and protein–protein and protein–lipid interactions in a convenient, cell-free platform. 

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4. Flanking aromatic residue competition influences transmembrane peptide helix dynamics

   https://doi.org/10.1002/1873-3468.13926  

   McKay, Matthew J.; Greathouse, Denise V.; Koeppe, II, Roger E. (September 2020, FEBS Letters)

   To address biophysical principles and lipid interactions that underlie the properties of membrane proteins, modifications that vary the neighbors of tryptophan residues in the highly dynamic transmembrane helix of GW^4,20ALP23 (acetyl‐GGAW⁴A(LA)₆LAW²⁰AGA‐amide) were examined using deuterium NMR spectroscopy. It was found that L^5,19GW^4,20ALP23, a sequence isomer of the low to moderately dynamic GW^5,19ALP23, remains highly dynamic. By contrast, a removal of W4 to produce F^4,5GW²⁰ALP23 restores a low level of dynamic averaging, similar to that of the F^4,5GW¹⁹ALP23 helix. Interestingly, a high level of dynamic averaging requires the presence of both tryptophan residues W4 and W20, on opposite faces of the helix, and does not depend on whether residue 5 is Leu or Ala. Aspects of helix unwinding and potential oligomerization are discussed with respect to helix dynamic averaging and the locations of particular residues at a phosphocholine membrane interface. 

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5. Hydrophobic mismatch drives self-organization of designer proteins into synthetic membranes

   https://doi.org/10.1038/s41467-024-47163-1  

   Peruzzi, Justin A; Steinkühler, Jan; Vu, Timothy Q; Gunnels, Taylor F; Hu, Vivian T; Lu, Peilong; Baker, David; Kamat, Neha P (December 2024, Nature Communications)

   Abstract The organization of membrane proteins between and within membrane-bound compartments is critical to cellular function. Yet we lack approaches to regulate this organization in a range of membrane-based materials, such as engineered cells, exosomes, and liposomes. Uncovering and leveraging biophysical drivers of membrane protein organization to design membrane systems could greatly enhance the functionality of these materials. Towards this goal, we use de novo protein design, molecular dynamic simulations, and cell-free systems to explore how membrane-protein hydrophobic mismatch could be used to tune protein cotranslational integration and organization in synthetic lipid membranes. We find that membranes must deform to accommodate membrane-protein hydrophobic mismatch, which reduces the expression and co-translational insertion of membrane proteins into synthetic membranes. We use this principle to sort proteins both between and within membranes, thereby achieving one-pot assembly of vesicles with distinct functions and controlled split-protein assembly, respectively. Our results shed light on protein organization in biological membranes and provide a framework to design self-organizing membrane-based materials with applications such as artificial cells, biosensors, and therapeutic nanoparticles. 

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