We will investigate the roles of PUMPKIN, the sole plastid UMP kinase, both in sensing and/or changing the pyrimidine pool as well as in governing posttranscriptional processes. PUMPKIN is a homomultimeric protein that forms RNA-containing up to megadalton-sized complexes with unknown components. Some other complexes presumably do not contain RNA since they are RNase resistant. Remarkably, PUMPKIN is associated specifically with the introns of the five plastid transcripts ndhA, petB, petD, trnG-UCC and trnV-UAC in vivo as revealed by plastid transcriptome wide association studies (RIP-Seq). PUMPKIN also binds the petB intron RNA with high specificity and affinity in vitro and stabilizes the precursor transcripts most likely by masking endonuclease-sensitive sites. Null alleles and knockdowns of PUMPKIN are viable but clearly affected in growth, plastid translation and photosynthetic performance. In pumpkin mutants, levels of transcripts generated by the plastid-encoded polymerase are reduced, while those produced by the nuclear-encoded polymerase are even increased, indicating that UTP supply for plastid transcription is generally not limiting. Thus, the question arises whether the catalytic function of PUMPKIN had been replaced partially by a sensing function. Nevertheless, PUMPKIN is enzymatically active in vitro and in vivo and catalyses the ATP-dependent conversion of UMP to UDP with properties characteristic for known essential eubacterial UMP kinases. We will investigate to which extent and under which conditions lack of the enzymatic and of the RNA stabilizing functions of PUMPKIN contribute to the mutant phenotype based on the hypothesis that both functions are not necessarily mutually exclusive. Thus, we will dissect the individual roles of PUMPKIN as UMP kinase in the pyrimidine metabolism and as moonlighting RNA binding protein in posttranscriptional processes. The impact of the target RNAs on the enzymatic properties of PUMPKIN and the role of nucleotides on binding to its target RNAs will be explored. Complementation of pumpkin mutants with a eubacterial UMP kinase presumably not associated with the PUMPKIN target RNAs and with recombinant PUMPKIN forms devoid of the enzymatic or the RNA binding activity will be performed. Furthermore, the metabolic consequences of the pumpkin mutation, such as levels of the uracil nucleotide-dependent production of metabolites will be examined quantitatively by mass spectrometry. Interacting partners and the precise targets will be identified and the structure of the PUMPKIN-RNA complex will be solved. The contribution to the cellular pyrimidine metabolism of a further uncharacterized eubacterial UMP kinase (NUMPKIN), presumably present in the nucleus and also harbouring a moonlighting function, will be analysed. Finally, our data will highlight to which extent the two UMP kinases act as integrative sensors that link plastid and/or nuclear gene expression with changes in the uracil nucleotide pool.

DFG Programme Research Grants