The role of lipids in the biogenesis of integral membrane proteins

Schneiter, Roger; Toulmay, Alexandre

doi:10.1007/s00253-006-0707-9

Cited by 24 publications

(18 citation statements)

References 72 publications

(76 reference statements)

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“…Recent studies on the protonpumping H 1 -ATPase, Pma1, reveal some of these functions (90). Pma1 has been a valuable model for determining how proteins are transported from the ER to the plasma membrane, and readers are directed to published reviews for more detailed information (91,92). Like all integral membrane proteins, Pma1 becomes part of the hydrophobic membrane in the ER, where lipids must contribute to the microenvironment necessary for the correct folding of Pma1 into a functional conformation.…”

Section: Secretory Pathway Endocytosis and The Plasma Membranementioning

confidence: 99%

Thematic Review Series: Sphingolipids. New insights into sphingolipid metabolism and function in budding yeast

Dickson

2008

Journal of Lipid Research

203

215

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Our understanding of sphingolipid metabolism and functions in the baker's yeast Saccharomyces cerevisiae has progressed substantially in the past 2 years. Yeast sphingolipids contain a C 26 -acyl moiety, all of the genes necessary to make these long-chain fatty acids have been identified, and a mechanism for how chain length is determined has been proposed. Advances in understanding how the de novo synthesis of ceramide and complex sphingolipids is regulated have been made, and they demonstrate that the Target Of Rapamycin Complex 2 (TORC2) controls ceramide synthase activity. Other work shows that TORC2 regulates the level of complex sphingolipids in a pathway using the Slm1 and Slm2 proteins to control the protein phosphatase calcineurin, which regulates the breakdown of complex sphingolipids. The activity of Slm1 and Slm2 has also been shown to be regulated during heat stress by phosphoinositides and TORC2, along with sphingoid long-chain bases and the Pkh1 and Pkh2 protein kinases, to control the actin cytoskeleton, the trafficking of nutrient transporters, and cell viability.Together, these results provide the first molecular insights into understanding previous genetic interaction data that indicated a connection between sphingolipids and the TORC2 and phosphoinositide signaling networks. This new knowledge provides a foundation for greatly advancing our understanding of sphingolipid biology in yeast.-Dickson, R. C. New insights into sphingolipid metabolism and function in budding yeast. J. Lipid Res. 2008. 49: 909-921.

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Section: Secretory Pathway Endocytosis and The Plasma Membranementioning

confidence: 99%

Thematic Review Series: Sphingolipids. New insights into sphingolipid metabolism and function in budding yeast

Dickson

2008

Journal of Lipid Research

203

215

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“…This occurs to maintain constant membrane fluidity. As the temperature decreases, the lipids found in the cell membrane become more rigid, which interferes with the activity of the membrane and membranebound components like channels and pumps (27,29). To the best of our knowledge, the time required for various Listeria monocytogenes strains to adjust their membrane fluidity is unknown.…”

Section: Resultsmentioning

confidence: 99%

“…When L. monocytogenes is grown at low temperatures, the phospholipids of the cell membrane become more rigid and can interfere with normal functions of the membrane and membrane-associated proteins (23,29,32,34). To counteract this phenomenon, L. monocytogenes modifies its plasma membrane to maintain its fluidity at low temperature (32); this is collectively termed homeoviscous adaptation (30).…”

mentioning

confidence: 99%

Changes in Listeria monocytogenes Membrane Fluidity in Response to Temperature Stress

Najjar

Chikindas

Montville

2007

Appl Environ Microbiol

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Listeria monocytogenes is a food-borne pathogen that has been implicated in many outbreaks associated with ready-to-eat products. Listeria adjusts to various stresses by adjusting its membrane fluidity, increasing the uptake of osmoprotectants and cryoprotectants, and activating the B stress factor. The present work examines the regulation of membrane fluidity through direct measurement based on fluorescent anisotropy. The membrane fluidities of L. monocytogenes Scott A, NR30, wt10403S, and cld1 cells cultured at 15 and 30°C were measured at 15 and 30°C. The membrane of the cold-sensitive mutant (cld1) was more rigid than the membranes of the other strains when grown at 30°C, but when grown at 15°C, it was able to adjust its membrane to approach the rigidity of the other strains. The difference in rigidities, as determined at 15 and 30°C, was greater in liposomes than in whole cells. The rates of fluidity adjustment and times required for whole cells to adjust to a different temperature were similar among strains but different from those of liposomes. This suggests that the cells had a mechanism for homeoviscous adaptation that was absent in liposomes.

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“…Membrane proteins require an appropriate lipid environment for their structural integrity and in some cases for their correct insertion and possibly oligomeric state (Schneiter and Toulmay, 2007). From an organism's point of view, this is the strongest dependence on lipids because without the functional protein there would be no transport at all.…”

Section: Discussionmentioning

confidence: 99%

Influence of lipids on protein-mediated transmembrane transport

Denning

Beckstein

2013

Chemistry and Physics of Lipids

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Transmembrane proteins are responsible for transporting ions and small molecules across the hydrophobic region of the cell membrane. We are reviewing the evidence for regulation of these transport processes by interactions with the lipids of the membrane. We focus on ion channels, including potassium channels, mechanosensitive and pentameric ligand gated ion channels, and active transporters, including pumps, sodium or proton driven secondary transporters and ABC transporters. For ion channels it has been convincingly shown that specific lipid-protein interactions can directly affect their function. In some cases, a combined approach of molecular and structural biology together with computer simulations has revealed the molecular mechanisms. There are also many transporters whose activity depends on lipids but understanding of the molecular mechanisms is only beginning.

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The role of lipids in the biogenesis of integral membrane proteins

Cited by 24 publications

References 72 publications

Thematic Review Series: Sphingolipids. New insights into sphingolipid metabolism and function in budding yeast

Thematic Review Series: Sphingolipids. New insights into sphingolipid metabolism and function in budding yeast

Changes in Listeria monocytogenes Membrane Fluidity in Response to Temperature Stress

Influence of lipids on protein-mediated transmembrane transport

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