1996
DOI: 10.1002/pro.5560050103
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Structure in solution of a four‐helix lipid binding protein

Abstract: Because of the low solubility of lipids in water, intercellular and intracellular pathways of lipid transfer are necessary, e.g., for membrane formation. The mechanism by which lipids in vivo are transported from their site of biogenesis (endoplasmatic reticulum and the chloroplasts) to their place of action is unknown. Several small plant proteins with the ability to mediate transfer of radiolabeled phospholipids in vitro from liposomal donor membranes to mitochondrial and chloroplast acceptor membranes have … Show more

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Cited by 115 publications
(113 citation statements)
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“…E-mail : sodano@cnrs-orleans.fr helices and a C-terminal fragment organized around a long internal cavity which has been suggested to be the lipid binding site. This type of organization was then confirmed with the maize ns-LTP structure that we established in solution [3] and in crystal by Shin et al [4] and more recently with the barley ns-LTP structure [5]. The crystal structure of the complex of the maize protein with palmitic acid [4], the solution structure of its complex with l-palmitoyl-2-lysophosphatidylcholine [3] and the barley ns-LTP complex with palmitoylCoA [6] demonstrated the capacity of ns-LTPs to incorporate a long fatty acid chain in their internal cavity.…”
Section: Introductionsupporting
confidence: 75%
See 1 more Smart Citation
“…E-mail : sodano@cnrs-orleans.fr helices and a C-terminal fragment organized around a long internal cavity which has been suggested to be the lipid binding site. This type of organization was then confirmed with the maize ns-LTP structure that we established in solution [3] and in crystal by Shin et al [4] and more recently with the barley ns-LTP structure [5]. The crystal structure of the complex of the maize protein with palmitic acid [4], the solution structure of its complex with l-palmitoyl-2-lysophosphatidylcholine [3] and the barley ns-LTP complex with palmitoylCoA [6] demonstrated the capacity of ns-LTPs to incorporate a long fatty acid chain in their internal cavity.…”
Section: Introductionsupporting
confidence: 75%
“…The C-terminal region was devoid of any regular hydrogen bonded canonical structure except for a ß-turn involving residues 82-85 and ran parallel to H4 from residues 77 to 83 and then to H3 from residue 84 to the C-terminal residue. The protein scaffold which was common to all available ns-LTP structures [3][4][5] was maintained by a network of four disulfide bridges distributed in pairs on two protein poles, providing great stability to this protein. The RMSD calculated on the heavy atoms of the backbone of the four helices relative to the mean structure is 0.75 A which is indicative of a moderate resolution solution structure.…”
Section: Resultsmentioning
confidence: 99%
“…The ns-LTPs are all helical proteins, stabilized by four disulfide bridges 75,120,193 . The ns-LTP1 structural fold is characterized by four α-helices separated by short turns and held together with four disulphide bridges, and a flexible nonstructured C-terminal arm 120 (Fig. 13).…”
Section: Non-specific Lipid-transfer Proteins (Ns-ltp1 and Ns-ltp2) (mentioning
confidence: 99%
“…The three-dimensional structures of ns-LTP1 from barley 68 , wheat 53 , rice 86 and maize grain 136 have been resolved. They all exhibit a similar fold, differing only in details 121 .…”
Section: Structure Of Barley Grain Ns-ltp1mentioning
confidence: 99%