scholarly journals Remote homology searches identify bacterial homologues of eukaryotic lipid transfer proteins, including Chorein-N domains in TamB and AsmA and Mdm31p

2019 ◽  
Vol 20 (1) ◽  
Author(s):  
Timothy P. Levine
Keyword(s):  
Lipid Binding ◽  
Intermembrane Space ◽  
Lipid Transfer ◽  
Lipid Transfer Proteins ◽  
Dimer Interface ◽  
Remote Homology ◽  
C Terminus ◽  
Eukaryotic Proteins ◽  
N Terminus ◽  
Almost All

Abstract Background All cells rely on lipids for key functions. Lipid transfer proteins allow lipids to exit the hydrophobic environment of bilayers, and cross aqueous spaces. One lipid transfer domain fold present in almost all eukaryotes is the TUbular LIPid binding (TULIP) domain. Three TULIP families have been identified in bacteria (P47, OrfX2 and YceB), but their homology to eukaryotic proteins is too low to specify a common origin. Another recently described eukaryotic lipid transfer domain in VPS13 and ATG2 is Chorein-N, which has no known bacterial homologues. There has been no systematic search for bacterial TULIPs or Chorein-N domains. Results Remote homology predictions for bacterial TULIP domains using HHsearch identified four new TULIP domains in three bacterial families. DUF4403 is a full length pseudo-dimeric TULIP with a 6 strand β-meander dimer interface like eukaryotic TULIPs. A similar sheet is also present in YceB, suggesting it homo-dimerizes. TULIP domains were also found in DUF2140 and in the C-terminus DUF2993. Remote homology predictions for bacterial Chorein-N domains identified strong hits in the N-termini of AsmA and TamB in diderm bacteria, which are related to Mdm31p in eukaryotic mitochondria. The N-terminus of DUF2993 has a Chorein-N domain adjacent to its TULIP domain. Conclusions TULIP lipid transfer domains are widespread in bacteria. Chorein-N domains are also found in bacteria, at the N-terminus of multiple proteins in the intermembrane space of diderms (AsmA, TamB and their relatives) and in Mdm31p, a protein that is likely to have evolved from an AsmA/TamB-like protein in the endosymbiotic mitochondrial ancestor. This indicates that both TULIP and Chorein-N lipid transfer domains may have originated in bacteria.

scholarly journals The lipid transfer protein Saposin B does not directly bind CD1d for lipid antigen loading

2019 ◽  
Vol 4 ◽  
pp. 117
Author(s):  
Maria Shamin ◽  
Tomasz H. Benedyk ◽  
Stephen C. Graham ◽  
Janet E. Deane
Keyword(s):  
Lipid Transfer Protein ◽  
Direct Interaction ◽  
Lipid Binding ◽  
Lipid Transfer ◽  
Binding Assays ◽  
Lipid Transfer Proteins ◽  
Lipid Antigens ◽  
Saposin B ◽  
Protein Components ◽  
Lipid Loading

Background: Lipid antigens are presented on the surface of cells by the CD1 family of glycoproteins, which have structural and functional similarity to MHC class I molecules. The hydrophobic lipid antigens are embedded in membranes and inaccessible to the lumenal lipid-binding domain of CD1 molecules. Therefore, CD1 molecules require lipid transfer proteins for lipid loading and editing. CD1d is loaded with lipids in late endocytic compartments, and lipid transfer proteins of the saposin family have been shown to play a crucial role in this process. However, the mechanism by which saposins facilitate lipid binding to CD1 molecules is not known and is thought to involve transient interactions between protein components to ensure CD1-lipid complexes can be efficiently trafficked to the plasma membrane for antigen presentation. Of the four saposin proteins, the importance of Saposin B (SapB) for loading of CD1d is the most well-characterised. However, a direct interaction between CD1d and SapB has yet to be described. Methods: In order to determine how SapB might load lipids onto CD1d, we used purified, recombinant CD1d and SapB and carried out a series of highly sensitive binding assays to monitor direct interactions. We performed equilibrium binding analysis, chemical cross-linking and co-crystallisation experiments, under a range of different conditions. Results: We could not demonstrate a direct interaction between SapB and CD1d using any of these binding assays. Conclusions: This work establishes comprehensively that the role of SapB in lipid loading does not involve direct binding to CD1d. We discuss the implication of this for our understanding of lipid loading of CD1d and propose several factors that may influence this process.

scholarly journals Lipid transfer proteins do their thing anchored at membrane contact sites… but what is their thing?

2016 ◽  
Vol 44 (2) ◽  
pp. 517-527 ◽  
Author(s):  
Louise H. Wong ◽  
Tim P. Levine
Keyword(s):  
Lipid Binding ◽  
Lipid Transfer ◽  
Transmembrane Helices ◽  
Lipid Transfer Proteins ◽  
Membrane Contact Sites ◽  
Contact Sites ◽  
Multiple Contacts ◽  
Membrane Contact ◽  
Organelle Communication ◽  
Lipid Binding Proteins

Membrane contact sites are structures where two organelles come close together to regulate flow of material and information between them. One type of inter-organelle communication is lipid exchange, which must occur for membrane maintenance and in response to environmental and cellular stimuli. Soluble lipid transfer proteins have been extensively studied, but additional families of transfer proteins have been identified that are anchored into membranes by transmembrane helices so that they cannot diffuse through the cytosol to deliver lipids. If such proteins target membrane contact sites they may be major players in lipid metabolism. The eukaryotic family of so-called Lipid transfer proteins Anchored at Membrane contact sites (LAMs) all contain both a sterol-specific lipid transfer domain in the StARkin superfamily (related to StART/Bet_v1), and one or more transmembrane helices anchoring them in the endoplasmic reticulum (ER), making them interesting subjects for study in relation to sterol metabolism. They target a variety of membrane contact sites, including newly described contacts between organelles that were already known to make contact by other means. Lam1–4p target punctate ER–plasma membrane contacts. Lam5p and Lam6p target multiple contacts including a new category: vacuolar non-NVJ cytoplasmic ER (VancE) contacts. These developments confirm previous observations on tubular lipid-binding proteins (TULIPs) that established the importance of membrane anchored proteins for lipid traffic. However, the question remaining to be solved is the most difficult of all: are LAMs transporters, or alternately are they regulators that affect traffic more indirectly?

Comparison of Lipid Binding and Transfer Properties of Two Lipid Transfer Proteins from Plants†

Biochemistry ◽  
1999 ◽  
Vol 38 (43) ◽  
pp. 14131-14137 ◽  
Author(s):  
Françoise Guerbette ◽  
Michèle Grosbois ◽  
Alain Jolliot-Croquin ◽  
Jean-Claude Kader ◽  
Alain Zachowski
Keyword(s):  
Lipid Binding ◽  
Lipid Transfer ◽  
Lipid Transfer Proteins ◽  
Transfer Properties

scholarly journals A Tetrameric Assembly of Saposin A: Increasing Structural Diversity in Lipid Transfer Proteins

Contact ◽  
2021 ◽  
Vol 4 ◽  
pp. 251525642110523
Author(s):  
Maria Shamin ◽  
Samantha J. Spratley ◽  
Stephen C. Graham ◽  
Janet E. Deane
Keyword(s):  
Hydrophobic Surface ◽  
Structural Diversity ◽  
Lipid Binding ◽  
Binding Property ◽  
Aqueous Environment ◽  
Lipid Transfer ◽  
Lipid Transfer Proteins ◽  
Small Proteins ◽  
Bound Lipids ◽  
Tetrameric Assembly

Saposins are lipid transfer proteins required for the degradation of sphingolipids in the lysosome. These small proteins bind lipids by transitioning from a closed, monomeric state to an open conformation exposing a hydrophobic surface that binds and shields hydrophobic lipid tails from the aqueous environment. Saposins form a range of multimeric assemblies to encompass these bound lipids and present them to hydrolases in the lysosome. This lipid-binding property of human saposin A has been exploited to form lipoprotein nanodiscs suitable for structural studies of membrane proteins. Here we present the crystal structure of a unique tetrameric assembly of murine saposin A produced serendipitously, following modifications of published protocols for making lipoprotein nanodiscs. The structure of this new saposin oligomer highlights the diversity of tertiary arrangement that can be adopted by these important lipid transfer proteins.

scholarly journals Ribosome-Associated Mba1 Escorts Cox2 from Insertion Machinery to Maturing Assembly Intermediates

2016 ◽  
Vol 36 (22) ◽  
pp. 2782-2793 ◽  
Author(s):  
Isotta Lorenzi ◽  
Silke Oeljeklaus ◽  
Christin Ronsör ◽  
Bettina Bareth ◽  
Bettina Warscheid ◽  
...  
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Scaffold Protein ◽  
Intermembrane Space ◽  
Dependent Manner ◽  
Inner Membrane ◽  
Content Type ◽  
Mitochondrial Ribosomes ◽  
C Terminus ◽  
N Terminus ◽  
Conserved Core

The three conserved core subunits of the cytochrome c oxidase are encoded by mitochondria in close to all eukaryotes. The Cox2 subunit spans the inner membrane twice, exposing the N and C termini to the intermembrane space. For this, the N terminus is exported cotranslationally by Oxa1 and subsequently undergoes proteolytic maturation in Saccharomyces cerevisiae . Little is known about the translocation of the C terminus, but Cox18 has been identified to be a critical protein in this process. Here we find that the scaffold protein Cox20, which promotes processing of Cox2, is in complex with the ribosome receptor Mba1 and translating mitochondrial ribosomes in a Cox2-dependent manner. The Mba1-Cox20 complex accumulates when export of the C terminus of Cox2 is blocked by the loss of the Cox18 protein. While Cox20 engages with Cox18, Mba1 is no longer present at this stage. Our analyses indicate that Cox20 associates with nascent Cox2 and Mba1 to promote Cox2 maturation cotranslationally. We suggest that Mba1 stabilizes the Cox20-ribosome complex and supports the handover of Cox2 to the Cox18 tail export machinery.

scholarly journals Characterization and Antifungal Properties of Wheat Nonspecific Lipid Transfer Proteins

2008 ◽  
Vol 21 (3) ◽  
pp. 346-360 ◽  
Author(s):  
Jin-Yue Sun ◽  
Denis A. Gaudet ◽  
Zhen-Xiang Lu ◽  
Michele Frick ◽  
Byron Puchalski ◽  
...  
Keyword(s):  
Fatty Acid ◽  
Spore Germination ◽  
Sodium Dodecyl ◽  
Membrane Integrity ◽  
Lipid Binding ◽  
Binding Activity ◽  
Lipid Transfer ◽  
Lipid Transfer Proteins ◽  
Fatty Acid Binding

This study simultaneously considered the phylogeny, fatty acid binding ability, and fungal toxicity of a large number of monocot nonspecific lipid transfer proteins (ns-LTP). Nine novel full-length wheat ns-LTP1 clones, all possessing coding sequences of 348 bp, isolated from abiotic- and biotic-stressed cDNA libraries from aerial tissues, exhibited highly conserved coding regions with 78 to 99 and 71 to 100% identity at the nucleotide and amino acid levels, respectively. Phylogenetic analyses revealed two major ns-LTP families in wheat. Eight wheat ns-LTP genes from different clades were cloned into the expression vector pPICZα and transformed into Pichia pastoris. Sodium dodecyl sulfate polyacrylamide gel electrophoresis, Western blotting, and in vitro lipid binding activity assay confirmed that the eight ns-LTP were all successfully expressed and capable of in vitro binding fatty acid molecules. A comparative in vitro study on the toxicity of eight wheat ns-LTP to mycelium growth or spore germination of eight wheat pathogens and three nonwheat pathogens revealed differential toxicities among different ns-LTP. Values indicating 50% inhibition of fungal growth or spore germination of three selected ns-LTP against six fungi ranged from 1 to 7 μM. In vitro lipid-binding activity of ns-LTP was not correlated with their antifungal activity. Using the fluorescent probe SYTOX Green as an indicator of fungal membrane integrity, the in vitro toxicity of wheat ns-LTP was associated with alteration in permeability of fungal membranes.

scholarly journals A tetrameric assembly of saposin A: increasing structural diversity in lipid transfer proteins

2021 ◽  
Author(s):  
Maria Shamin ◽  
Samantha J Spratley ◽  
Stephen C Graham ◽  
Janet E Deane
Keyword(s):  
Hydrophobic Surface ◽  
Structural Diversity ◽  
Lipid Binding ◽  
Binding Property ◽  
Aqueous Environment ◽  
Lipid Transfer ◽  
Lipid Transfer Proteins ◽  
Small Proteins ◽  
Bound Lipids ◽  
Tetrameric Assembly

Saposins are lipid transfer proteins required for the degradation of sphingolipids in the lysosome. These small proteins bind lipids by transitioning from a closed, monomeric state to an open conformation exposing a hydrophobic surface that binds and shields hydrophobic lipid tails from the aqueous environment. Saposins form a range of multimeric assemblies to encompass these bound lipids and present them to hydrolases in the lysosome. This lipid-binding property of human saposin A has been exploited to form lipoprotein nanodiscs suitable for structural studies of membrane proteins. Here we present the crystal structure of a unique tetrameric assembly of murine saposin A produced serendipitously, following modifications of published protocols for making lipoprotein nanodiscs. The structure of this new saposin oligomer highlights the diversity of tertiary arrangement that can be adopted by these important lipid transfer proteins.

scholarly journals TMEM106B in humans and Vac7 and Tag1 in yeast are predicted to be lipid transfer proteins

2021 ◽  
Author(s):  
Tim P. Levine
Keyword(s):  
Integral Membrane Protein ◽  
Lipid Binding ◽  
Lipid Transfer ◽  
Neuronal Function ◽  
Host Proteins ◽  
Lipid Transfer Proteins ◽  
Over Expression ◽  
Late Endosomes ◽  
Standard Tool ◽  
Binding Groove

AbstractTMEM106B is an integral membrane protein of late endosomes and lysosomes involved in neuronal function, its over-expression being associated with familial frontotemporal lobar degeneration, and under-expression linked to hypomyelination. It has also been identified in multiple screens for host proteins required for productive SARS-CoV2 infection. Because standard approaches to understand TMEM106B at the sequence level find no homology to other proteins, it has remained a protein of unknown function. Here, the standard tool PSI-BLAST was used in a non-standard way to show that the lumenal portion of TMEM106B is a member of the LEA-2 domain superfamily. The non-standard tools (HMMER, HHpred and trRosetta) extended this to predict two yeast LEA-2 proteins in the lumenal domains of the degradative vacuole, equivalent to the lysosome: one in Vac7, a regulator of PI(3,5)P2 production, and three in Tag1 which signals to terminate autophagy. Further analysis of previously unreported LEA-2 structures indicated that LEA-2 domains have a long, conserved lipid binding groove. This implies that TMEM106B, Vac7 and Tag1 may all be lipid transfer proteins in the lumen of late endocytic organelles.

scholarly journals The human erythrocyte anion-transport protein. Further amino acid sequence from the integral membrane domain homologous with the murine protein

1986 ◽  
Vol 235 (3) ◽  
pp. 899-901 ◽  
Author(s):  
C J Brock ◽  
M J A Tanner
Keyword(s):  
Amino Acid ◽  
Human Erythrocyte ◽  
Proteolytic Enzymes ◽  
Transmembrane Helix ◽  
Anion Transport ◽  
Transport Protein ◽  
Membrane Domain ◽  
C Terminus ◽  
N Terminus ◽  
Almost All

Sequences from the human erythrocyte anion-transport protein homologous with residues 417-449 and 794-813 of the murine erythrocyte anion-transport protein have been determined. The former sequence includes the putative transmembrane helix closest to the N-terminus of the protein. The latter sequence traverses almost all of the lipid bilayer and is located towards the C-terminus of the protein. Sites have been identified by alignment with the murine sequence in the integral membrane domain that are accessible to proteolytic enzymes. Sequences from the integral membrane domain of the erythrocyte anion-transport protein are highly conserved.

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