The α/β hydrolase CGI-58 and peroxisomal transport protein PXA1 coregulate lipid homeostasis and signaling in Arabidopsis

Sunjung Park; Satinder K Gidda; Christopher N James; Patrick J Horn; Nicholas Khuu; Damien C Seay; Jantana Keereetaweep; Kent D Chapman; Robert T Mullen; John M Dyer

doi:10.1105/tpc.113.111898

The α/β hydrolase CGI-58 and peroxisomal transport protein PXA1 coregulate lipid homeostasis and signaling in Arabidopsis

Plant Cell. 2013 May;25(5):1726-39. doi: 10.1105/tpc.113.111898. Epub 2013 May 10.

Authors

Sunjung Park¹, Satinder K Gidda, Christopher N James, Patrick J Horn, Nicholas Khuu, Damien C Seay, Jantana Keereetaweep, Kent D Chapman, Robert T Mullen, John M Dyer

Affiliation

¹ U.S. Department of Agriculture-Agricultural Research Service, U.S. Arid-Land Agricultural Research Center, Maricopa, Arizona 85138, USA.

Abstract

COMPARATIVE GENE IDENTIFICATION-58 (CGI-58) is a key regulator of lipid metabolism and signaling in mammals, but its underlying mechanisms are unclear. Disruption of CGI-58 in either mammals or plants results in a significant increase in triacylglycerol (TAG), suggesting that CGI-58 activity is evolutionarily conserved. However, plants lack proteins that are important for CGI-58 activity in mammals. Here, we demonstrate that CGI-58 functions by interacting with the PEROXISOMAL ABC-TRANSPORTER1 (PXA1), a protein that transports a variety of substrates into peroxisomes for their subsequent metabolism by β-oxidation, including fatty acids and lipophilic hormone precursors of the jasmonate and auxin biosynthetic pathways. We also show that mutant cgi-58 plants display changes in jasmonate biosynthesis, auxin signaling, and lipid metabolism consistent with reduced PXA1 activity in planta and that, based on the double mutant cgi-58 pxa1, PXA1 is epistatic to CGI-58 in all of these processes. However, CGI-58 was not required for the PXA1-dependent breakdown of TAG in germinated seeds. Collectively, the results reveal that CGI-58 positively regulates many aspects of PXA1 activity in plants and that these two proteins function to coregulate lipid metabolism and signaling, particularly in nonseed vegetative tissues. Similarities and differences of CGI-58 activity in plants versus animals are discussed.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

ATP-Binding Cassette Transporters / genetics
ATP-Binding Cassette Transporters / metabolism*
Acyltransferases / genetics
Acyltransferases / metabolism*
Adenosine Triphosphatases
Amino Acid Sequence
Arabidopsis / genetics
Arabidopsis / growth & development
Arabidopsis / metabolism*
Arabidopsis Proteins / genetics
Arabidopsis Proteins / metabolism*
Cell Nucleus / metabolism
Cyclopentanes / metabolism
Fatty Acid Transport Proteins / genetics
Fatty Acid Transport Proteins / metabolism
Fatty Acids / metabolism
Homeostasis
Hydrolases / genetics
Hydrolases / metabolism
Indoleacetic Acids / metabolism
Indoleacetic Acids / pharmacology
Lipid Metabolism*
Luminescent Proteins / genetics
Luminescent Proteins / metabolism
Microscopy, Confocal
Molecular Sequence Data
Mutation
Oxylipins / metabolism
Peroxisomes / metabolism
Plant Growth Regulators / metabolism
Plant Growth Regulators / pharmacology
Plant Roots / drug effects
Plant Roots / genetics
Plant Roots / growth & development
Protein Binding
Seeds / genetics
Seeds / growth & development
Seeds / metabolism
Sequence Homology, Amino Acid
Signal Transduction
Triglycerides / metabolism
Two-Hybrid System Techniques

Substances

ATP-Binding Cassette Transporters
Arabidopsis Proteins
Cyclopentanes
Fatty Acid Transport Proteins
Fatty Acids
Indoleacetic Acids
Luminescent Proteins
Oxylipins
Plant Growth Regulators
Triglycerides
jasmonic acid
Acyltransferases
2-acylglycerophosphate acyltransferase
Hydrolases
Adenosine Triphosphatases
At4g39850 protein, Arabidopsis