Abstract
Phosphoenolpyruvate carboxylase (PEPC) is a tightly regulated enzyme situated at the core of plant C-metabolism. Although its anaplerotic role and control by allosteric effectors, reversible phosphorylation, and oligomerization have been well documented in the endosperm of developing castor oil seeds (COS), relatively little is known about PEPC in germinating COS. The initial phase of COS germination was accompanied by elevated PEPC activity and accumulation of comparable amounts of pre-existing 107-kDa and inducible 110-kDa immunoreactive PEPC polypeptides (p107 and p110, respectively). A 440-kDa PEPC heterotetramer composed of an equivalent ratio of non-phosphorylated p110 and p107 subunits was purified from germinated COS. N-terminal microsequencing, mass spectrometry, and immunoblotting revealed that both subunits arose from the same gene (RcPpc3) that encodes the p107 subunit of a phosphorylated 410-kDa PEPC homotetramer in developing COS but that p110 is a monoubiquitinated form of p107. Tandem mass spectrometry sequencing of a diglycinated tryptic peptide identified Lys-628 as p110's monoubiquitination site. This residue is conserved in vascular plant PEPCs and is proximal to a PEP-binding/catalytic domain. Incubation with a human deubiquitinating enzyme (USP-2 core) converted the p110:p107 PEPC heterotetramer into a p107 homotetramer while significantly reducing the enzyme's K(m)(PEP) and sensitivity to allosteric activators (hexose-Ps, glycerol-3-P) and inhibitors (malate, aspartate). Monoubiquitination is a non-destructive and reversible post-translational modification involved in the control of diverse processes such as transcription, endocytosis, and signal transduction. The current study demonstrates that tissue-specific monoubiquitination of a metabolic enzyme can also occur and that this modification influences its kinetic and regulatory properties.
Highlights
The molecular and functional properties of two classes of PEPC sharing the same 107-kDa subunit have been investigated in detail from the triglyceride-rich endosperm of developing castor oil seeds (COS) (4 –9)
RcPPC3 exists as a typical 410-kDa Class-1 PEPC homotetramer that is activated in vivo by phosphorylation of its p107 subunit at Ser-11 and tightly interacts with the bacterial-type PEPC RcPPC4 (p118) to form the 910-kDa Class-2 PEPC hetero-octameric complex (4, 6 –9)
COS maturation is accompanied by disappearance of the Class-2 PEPC complex and RcPPC4/p118 polypeptides and RcPpc4 transcripts, a marked reduction in the activity of the Class-1 PEPC and the amount of its RcPPC3/p107 subunits, as well as conversion of p107 into its dephosphorylated form (4, 6, 8)
Summary
PEPC Monoubiquitination in Germinated Castor Oil Seeds effectors relative to Class-1 PEPC, led to the hypotheses that: (i) Class-1 and Class-2 PEPC respectively support glycolytic carbon flux required for storage protein and storage lipid synthesis in developing COS and (ii) the p118 bacterial-type PEPC functions as a regulatory subunit within the Class-2 PEPC complex (4, 8). Mature and germinating COS endosperm contain immunoreactive plant-type PEPC polypeptides that co-migrate with the p107 of developing COS PEPC. An additional PEPC polypeptide of ϳ110-kDa (p110) appears immediately following COS imbibition and persists throughout germination at an equivalent ratio with the p107 (8, 10). We demonstrate that RcPPC3 (p107) subunits become monoubiquitinated at a conserved Lys residue during the initial stages of COS germination, resulting in formation of an unusual p110:p107 Class-1 PEPC heterotetramer. There have been no reports describing regulatory monoubiquitination of a metabolic enzyme in any biological system studied to date
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