Abstract
In many organisms the coordinated synthesis of membrane lipids is controlled by feedback systems that regulate the transcription of target genes. However, a complete description of the transcriptional changes that accompany the remodeling of membrane phospholipids has not been reported. To identify metabolic signaling networks that coordinate phospholipid metabolism with gene expression, we profiled the sequential and temporal changes in genome-wide expression that accompany alterations in phospholipid metabolism induced by inositol supplementation in yeast. This analysis identified six distinct expression responses, which included phospholipid biosynthetic genes regulated by Opi1p, endoplasmic reticulum (ER) luminal protein folding chaperone and oxidoreductase genes regulated by the unfolded protein response pathway, lipid-remodeling genes regulated by Mga2p, as well as genes involved in ribosome biogenesis, cytosolic stress response, and purine and amino acid metabolism. We also report that the unfolded protein response pathway is rapidly inactivated by inositol supplementation and demonstrate that the response of the unfolded protein response pathway to inositol is separable from the response mediated by Opi1p. These data indicate that altering phospholipid metabolism produces signals that are relayed through numerous distinct ER-to-nucleus signaling pathways and, thereby, produce an integrated transcriptional response. We propose that these signals are generated in the ER by increased flux through the pathway of phosphatidylinositol synthesis.
Highlights
The endoplasmic reticulum (ER)2 is a dynamic organelle that responds to environmental and developmental cues by regulating the levels of lipids and proteins required for the biogenesis and maintenance of membrane-bound compartments
We have shown that the addition of inositol to the medium of logarithmically growing yeast cells triggers a cascade of changes in global gene expression
These include genes involved in phospholipid biosynthesis, ER homeostasis, and lipid remodeling, suggesting a dynamic reprogramming of expression of genes involved in membrane biogenesis and homeostasis in response to signals derived from phospholipid metabolism
Summary
Strains and Plasmids—The wild-type strain BY4742 (MAT␣, his3⌬1, leu2⌬0, lys2⌬0, ura3⌬0) derived from S288C [20] was used in all microarray experiments. Cy5- and Cy3-labeled cDNA probes were synthesized from mRNA collected at each time point, combined with fluorescently labeled cDNA probes from the reference sample, and hybridized to Corning CMT Yeast-S288c Gene Arrays (version 1.32, Corning, Inc.) containing 6,135 unique Saccharomyces cerevisiae ORFs as described previously [16]. From this set of ORFs, 712 unique genes were selected whose absolute normalized M values exhibited Ն0.5-fold change in at least a single time point For these genes, a B-spline projection was performed followed by principle component analysis for the projected values, which captures the variance in a dataset [27]. Because a common reference sample was used, the absolute abundance for eight representative mRNAs (ACT1, ELO1, FAA4, HAC1, INO1, KAR2, OLE1, and TCM1) over the time course was verified by quantitative Northern blot analysis. Quantitation was performed by analysis on a STORM 860 PhosphorImager (Amersham Biosciences) and analyzed with ImageQuaNT software. pSJ34OLE1 was constructed by PCR-amplifying the OLE1 ORF and inserting the 798-bp HindIII-XbaI fragment into pGEM1. pSJ35-ACT1 was constructed by PCR-amplifying the ACT1 ORF and inserting the 321-bp BglII fragment into pGEM1. pSJ36-FAA4 was constructed by PCR-amplifying the FAA4 ORF and inserting the 837-bp EcoR1 fragment into pGEM1. pSJ37-lacZ was constructed by PCR-amplifying the Escherichia coli lacZ ORF from pAM6 and inserting the 723-bp HindIIIXbaI fragment into pGEM1. pSJ38-ELO1 was constructed by PCR-amplifying the ELO1 ORF and inserting the 585-bp HindIII-XbaI fragment into pGEM1
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