Co-immunoprecipitation analysis of the phosphoenolpyruvate carboxylase interactome of developing castor oil seeds

Co-immunoprecipitation (co-IP) followed by proteomic analysis was employed to examine the phosphoenolpyruvate carboxylase (PEPC) interactome of developing castor oil seed (COS) endosperm. Earlier studies suggested that immunologically unrelated 107-kDa plant-type and 118-kDa bacterial-type PEPCs (p107/PTPC and p118/BTPC, respectively) are subunits of an unusual ∼910-kDa hetero-octameric Class-2 PEPC complex of developing COS. The current results confirm that a tight physical interaction occurs between p118 and p107 since p118 quantitatively co-IP'd with p107 following elution of COS extracts through an anti-p107-IgG immunoaffinity column. No PEPC activity or immunoreactive PTPC or BTPC polypeptides were detected in the corresponding flow-through fractions. Although BTPCs lack the N-terminal phosphorylation site characteristic of PTPCs, Pro-Q Diamond Phosphoprotein staining, immunoblotting with phospho-(Ser/Thr) Akt substrate IgG, and phosphate-affinity PAGE demonstrated that the co-IP'd p118 was significantly phosphorylated at unique Ser and/or Thr residue(s). The co-IP of p118 and p107 was not influenced by their phosphorylation status. As p118 phosphorylation appeared unchanged 48 h following elimination of photosynthate supply due to COS depodding, the signaling mechanisms responsible for photosynthate-dependent p107 phosphorylation differ from those controlling p118's in vivo phosphorylation. A third PEPC polypeptide of ∼110-kDa (p110; RcPPC1) co-IP'd with p118 and p107 when depodded COS was used. Analysis of RcPpc1's full-length cDNA sequence revealed p110's identity with PTPCs, but that a pair of unique amino-acid substitutions occurs in its N-terminal sequence that may render p110 non-phosphorylatable in vivo. The plastidial pyruvate dehydrogenase complex (PDCpl) was identified as a novel PEPC interactor. Subcellular fractionation indicated that p118 and p107 are strictly cytosolic, but that PDCpl is targeted to both the cytosol and leucoplast of developing COS. Thus, a putative cytosolic metabolon involving PEPC and PDCpl could function to channel carbon from phosphoenolpyruvate to acetyl-CoA and/or to recycle CO2 from PDCpl to PEPC.