Comparison of solution and crystal structures of maize nonspecific lipid transfer protein: A model for a potential in vivo lipid carrier protein

Gomar, Jérôme; Sodano, P.; Sy, D.; Shin, Dongkun; Lee, Jae Young; Suh, Se Won; Marion, Didier; Vovelle, F.; Ptak, Marius

doi:10.1002/(sici)1097-0134(19980501)31:2<160::aid-prot6>3.0.co;2-q

Cited by 39 publications

(29 citation statements)

References 52 publications

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“…A thorough analysis of the dimensions of the protein cavity showed that the volume is highly variable depending on small conformational changes of internal side-chains and backbone [21]. The present study shows that ns-LTPs are able to interact with both monoacyl and diacyl lipids and with both lipid forming micelles or lamellar liquid-crystalline phases.…”

Section: Resultsmentioning

confidence: 61%

“…The volume of the internal hydrophobic cavity occupied by the two myristoyl chains was estimated to be 750 A 3 (±250 A 3 ) using the program 'CAVITE' [21]. The pocket was bordered by hydrophobic residues belonging to the four helices and to the C-terminal tail.…”

Section: Resultsmentioning

confidence: 99%

“…The best DIANA structure was used to build a preliminary structure of the complex with DMPG via the SYBYL software (Tripos, St. Louis, MO, USA) on a SILICON GRAPHICS workstation as follows : the use of the program 'CAVITE', which delineates cavity inside protein structures [21], defined a large hydrophobic cavity in the interior of the DIANA structure where both chains of the lipid were inserted. The orientation of the lipid was deduced from intermolecular NOEs between the lipid glycerol moieties and side-chain protons of residues His 35 and Arg 44 .…”

Section: Nmr Spectroscopy and Molecular Modellingmentioning

confidence: 99%

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¹H NMR and fluorescence studies of the complexation of DMPG by wheat non‐specific lipid transfer protein. Global fold of the complex

Sodano

Caille

et al. 1997

FEBS Letters

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Plant non-specific lipid transfer proteins (LTPs) are proteins which transfer lipids between membranes in vitro and are believed to be involved in the transport of cutin monomers to the cuticle layer in vivo or in the plant defence against phytopathogens. The complexation of DMPG, a diacyl phospholipid, by wheat ns-LTP, a protein extracted from wheat seeds, was followed by *H NMR and fluorescence spectroscopy. The global fold of the protein was calculated using the DIANA software package from a list of 968 distance constraints. The internal cavity volume, a feature common to all known ns-LTP structures, was estimated to be 750 A 3 using the 'CAVITE' program. This model of the complex was obtained by inserting a lipid molecule in the cavity and was energy minimized. The study showed that the protein fold described for the free form was only weakly affected by the insertion of the bulky lipid. Observation of some intermolecular NOEs between the protein and the lipid glycerol moiety revealed that the cavity entrance was located between residues His 35 and Arg 44 . The resulting solution structure was compared to the crystal structure of the maize ns-LTP/palmitate complex.

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Section: Resultsmentioning

confidence: 61%

Section: Resultsmentioning

confidence: 99%

Section: Nmr Spectroscopy and Molecular Modellingmentioning

confidence: 99%

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¹H NMR and fluorescence studies of the complexation of DMPG by wheat non‐specific lipid transfer protein. Global fold of the complex

Sodano

Caille

et al. 1997

FEBS Letters

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“…In previous studies of the maize LTP-long chain lipid complex, a hydrogen bond was found between the carboxylate or carbonyl group of the lipid and the hydroxyl of the C-terminal Tyr 81 (in maize LTP numbering), stabilizing the protein-lipid complex (11,12,58). The conserved N-terminal Tyr 17 (in maize LTP numbering) on the helix H1 is mostly solvent-exposed (12), and its role in the lipid complexation is obscure.…”

Section: Slvnpslglnaaivagipakmentioning

confidence: 99%

Two SCA (Stigma/Style Cysteine-rich Adhesin) Isoforms Show Structural Differences That Correlate with Their Levels of in Vitro Pollen Tube Adhesion Activity

Chae

Zhang

et al. 2007

Journal of Biological Chemistry

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Lily pollen tubes grow adhering to an extracellular matrix produced by the transmitting tract epidermis in a hollow style. SCA, a small (ϳ9.4 kDa), basic protein plus low esterified pectin from this extracellular matrix are involved in the pollen tube adhesion event. The mode of action for this adhesion event is unknown. We partially separated three SCA isoforms from the lily stigma in serial size exclusion column fractions (SCA1, 9370 Da; SCA2, 9384 Da; SCA3, 9484 Da). Peptide sequencing analysis allowed us to determine two amino acid variations in SCA3, compared with SCA1. For SCA2, however, there are more sequence variations yet to be identified. Our structural homology and molecular dynamics modeling results show that SCA isoforms have the plant nonspecific lipid transfer protein-like structure: a globular shape of the orthogonal 4-helix bundle architecture, four disulfide bonds, an internal hydrophobic and solvent-inaccessible cavity, and a long C-terminal tail. The Ala 71 in SCA3, replacing the Gly 71 in SCA1, has no predictable effect on structure. The Arg 26 in SCA3, replacing the Gly 26 in SCA1, is predicted to cause structural changes that result in a significantly reduced volume for the internal hydrophobic cavity in SCA3. The volume of the internal cavity fluctuates slightly during the molecular dynamics simulation, but overall, SCA1 displays a larger cavity than SCA3. SCA1 displays higher activity than SCA3 in the in vitro pollen tube adhesion assay. No differences were found between the two SCAs in a binding assay with pectin. The larger size of the hydrophobic cavity in SCA1 correlates with its higher adhesion activity.During lily pollination, pollen tubes are guided to the ovary on an extracellular matrix (ECM) 2 produced by the specialized stylar transmitting tract epidermis (TTE). This guidance includes an adhesion event between the pollen tube and the TTE (1-4). For the purpose of identifying molecular factors in lily pollen tube adhesion, Jauh et al. (5) developed an in vitro bioassay using ECM molecules attached to a nitrocellulose membrane as an artificial style. Using this in vitro bioassay, two molecules from the style ECM, SCA (stigma/style cysteine-rich adhesin) and a low esterified pectic polysaccharide, were found to be responsible for pollen tube adhesion on the stylar matrix (6, 7). The level of SCA mRNA was high in stigma/style tissue, petal, and young leaf, but it was absent in pollen tubes (8). Localization of both SCA and the low esterified pectin on the surface of the stylar TTE supported their involvement in in vivo pollen tube adhesion. The mechanism of action for SCA and pectin in pollen tube adhesion is yet unknown. Neither of these molecules alone is active in the adhesion assay. Only when they were combined did SCA and pectin bind to each other in a pH-dependent manner and form the functional, adhesive matrix (6). The pH effect implies that a charge interaction occurs, rather than a tight cross-linking, between SCA and the low esterified pectin in lily pistils.SCA is a sm...

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“…Three-dimensional structures of LTPs from maize (Gomar et al 1996(Gomar et al , 1998, wheat (Pons et al 2003) and barley (Lerche and Poulsen 1998) have led to a model structure of four helices linked by three loops and a C-terminal tail without a regular structure (Han et al 2001;Stolowich et al 1997). A fold is established by the four disulfide bonds and the helices encode an internal K.…”

Section: Introductionmentioning

confidence: 99%

Isolation and characterization of a lipid transfer protein expressed in ripening fruit of Capsicum chinense

Liu

Jiang

Moore

et al. 2005

Planta

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A novel LTP (CcLTP) from a Capsicum chinense cv Habanero was isolated from a fruit-specific SSH library. While this gene shares similarity with other LTPs, it is considerably larger than any lipid transfer protein reported to date and has a neutral predicted pI. CcLTP is consistently expressed in seedlings from three Capsicum species. It is also present at very high levels in ripening and mature fruit in C. chinense, but not in fruit of any C. annuum or C. frutescens varieties examined. We have obtained 3.8 kb of sequence containing the CcLTP gene and isolated two forms of mRNA transcripts which result from an alternative splicing event. Both transcripts are full-length cDNAs with putative open reading frames of 492 bp and 519 bp, encoding proteins of 164 and 173 amino acids, respectively, which differ only by an insertion of 9 amino acids. Both splice variants are detected consistently via RT-PCR. A 19 bp deletion in the promoter region differentiates C. chinense CcLTP from that of C. annuum and C. frutescens. The protein and its expression are characterized in C. chinense fruit, and a possible role in pepper fruit ripening and maturation is discussed.

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Comparison of solution and crystal structures of maize nonspecific lipid transfer protein: A model for a potential in vivo lipid carrier protein

Cited by 39 publications

References 52 publications

¹H NMR and fluorescence studies of the complexation of DMPG by wheat non‐specific lipid transfer protein. Global fold of the complex

¹H NMR and fluorescence studies of the complexation of DMPG by wheat non‐specific lipid transfer protein. Global fold of the complex

Two SCA (Stigma/Style Cysteine-rich Adhesin) Isoforms Show Structural Differences That Correlate with Their Levels of in Vitro Pollen Tube Adhesion Activity

Isolation and characterization of a lipid transfer protein expressed in ripening fruit of Capsicum chinense

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Comparison of solution and crystal structures of maize nonspecific lipid transfer protein: A model for a potential in vivo lipid carrier protein

Cited by 39 publications

References 52 publications

1H NMR and fluorescence studies of the complexation of DMPG by wheat non‐specific lipid transfer protein. Global fold of the complex

1H NMR and fluorescence studies of the complexation of DMPG by wheat non‐specific lipid transfer protein. Global fold of the complex

Two SCA (Stigma/Style Cysteine-rich Adhesin) Isoforms Show Structural Differences That Correlate with Their Levels of in Vitro Pollen Tube Adhesion Activity

Isolation and characterization of a lipid transfer protein expressed in ripening fruit of Capsicum chinense

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¹H NMR and fluorescence studies of the complexation of DMPG by wheat non‐specific lipid transfer protein. Global fold of the complex

¹H NMR and fluorescence studies of the complexation of DMPG by wheat non‐specific lipid transfer protein. Global fold of the complex