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. 2002 Aug 20;99(17):11487-92.
doi: 10.1073/pnas.172390399. Epub 2002 Aug 12.

Integral membrane proteins of the chloroplast envelope: identification and subcellular localization of new transporters

Affiliations

Integral membrane proteins of the chloroplast envelope: identification and subcellular localization of new transporters

Myriam Ferro et al. Proc Natl Acad Sci U S A. .

Abstract

A two-membrane system, or envelope, surrounds plastids. Because of the integration of chloroplast metabolism within the plant cell, the envelope is the site of many specific transport activities. However, only a few proteins involved in the processes of transport across the chloroplast envelope have been identified already at the molecular level. To discover new envelope transporters, we developed a subcellular proteomic approach, which is aimed to identify the most hydrophobic envelope proteins. This strategy combined the use of highly purified and characterized membrane fractions, extraction of the hydrophobic proteins with organic solvents, SDS/PAGE separation, and tandem mass spectrometry analysis. To process the large amount of MS/MS data, a blast-based program was developed for searching in protein, expressed sequence tag, and genomic plant databases. Among the 54 identified proteins, 27 were new envelope proteins, with most of them bearing multiple alpha-helical transmembrane regions and being very likely envelope transporters. The present proteomic study also allowed us to identify common features among the known and newly identified putative envelope inner membrane transporters. These features were used to mine the complete Arabidopsis genome and allowed us to establish a virtual plastid envelope integral protein database. Altogether, both proteomic and in silico approaches identified more than 50 candidates for the as yet previously uncharacterized plastid envelope transporters. The predictable function of some of these proteins opens up areas of investigation that may lead to a better understanding of the chloroplast metabolism. The present subcellular proteomic approach is amenable to the analysis of the hydrophobic core of other intracellular membrane systems.

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Figures

Fig 1.
Fig 1.
Subcellular localization of the IEP60 (Pht2;1 phosphate transporter) and HP45 proteins in (A) the chloroplast envelope and (B) the inner membrane of the chloroplast envelope. M, markers; Cp, crude chloroplast extract; S, stroma; T, thylakoid; E, envelope; IM, inner membrane; OM, outer membrane (20 μg of proteins per lane). SDS/PAGE and Western blots performed with the antibodies raised against the IEP60 and HP45 synthetic peptides. (C) Plastid targeting of IEP60 in Arabidopsis leaves. Images correspond to the superimposition of 8–10 optical sections, each 1 μm thick. GFP, 35Ω-sGFP(S65T) plasmid. TP-GFP, 35Ω-TP-sGFP(S65T) plasmid containing the TP from RBCs fused to GFP. P60-GFP, 35Ω-SoPht2;1-sGFP(S65T) plasmid containing the precursor of the spinach IEP60 protein fused to GFP.
Fig 2.
Fig 2.
Identification of common features in the proteins identified by means of the proteomic approach. Position of the spots was determined according to hydrophobicity (Res/TM ratio), and calculated pI of all proteins was identified through the proteomic approach (Table 1). Inner envelope proteins (gray circles), outer envelope proteins (white circles), stroma proteins (squares), and proteins of unknown subplastidial localization (triangles).
Fig 3.
Fig 3.
Combination of proteomics and in silico analyses to identify transporters from the inner membrane of the chloroplast envelope. The proteomics approach showed that (i) CHLOROP (18) is the most reliable program for the prediction of chloroplast envelope TP prediction, (ii) known envelope inner membrane proteins have specifically pI > 8.8, and (iii) known envelope inner membrane transporters have TM ≥ 4 and Res/TM < 100. These parameters were used to screen the AMPL database (10).

References

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