The Predicted Candidates of Arabidopsis Plastid Inner Envelope Membrane Proteins and Their Expression Profiles

doi:10.1104/pp.008052

The Predicted Candidates of Arabidopsis Plastid Inner Envelope Membrane Proteins and Their Expression Profiles¹^,^[w]

Abraham J.K. Koo and John B. Ohlrogge^*

Department of Plant Biology, Michigan State University, East Lansing, Michigan 48824-1312

Plastid envelope proteins from the Arabidopsis nuclear genome were predicted using computational methods. Selection criteriawere: first, to find proteins with NH₂-terminal plastid-targetingpeptides from all annotated open reading frames from Arabidopsis;second, to search for proteins with membrane-spanning domainsamong the predicted plastidial-targeted proteins; and third, tosubtract known thylakoid membrane proteins. Five hundred forty-oneproteins were selected as potential candidates of the Arabidopsisplastid inner envelope membrane proteins (AtPEM candidates). Only34% (183) of the AtPEM candidates could be assigned to putativefunctions based on sequence similarity to proteins of known function(compared with the 69% function assignment of the total predictedproteins in the genome). Of the 183 candidates with assigned functions,40% were classified in the category of "transport facilitation,"indicating that this collection is highly enriched in membranetransporters. Information on the predicted proteins, tissue expressiondata from expressed sequence tags and microarrays, and publiclyavailable T-DNA insertion lines were collected. The data set complementsproteomic-based efforts in the increased detection of integralmembrane proteins, low-abundance proteins, or those not expressedin tissues selected for proteomic analysis. Digital northern analysisof expressed sequence tags suggested that the transcript levelsof most AtPEM candidates were relatively constant among differenttissues in contrast to stroma and the thylakoid proteins. However,both digital northern and microarray analyses identified a numberof AtPEM candidates with tissue-specific expressionpatterns.

¹ This work was supported by the National Science Foundation (grant no. MCB98-17882) and by the Michigan Agricultural ExperimentStation.

^[w] The online version of this article contains Web-only data. The supplemental material is available at www.plantphysiol.org.

^* Corresponding author; e-mail ohlrogge{at}msu.edu; fax 517-353-1926.

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The Predicted Candidates of Arabidopsis Plastid Inner Envelope Membrane Proteins and Their Expression Profiles1,[w]

The Predicted Candidates of Arabidopsis Plastid Inner Envelope Membrane Proteins and Their Expression Profiles¹^,^[w]