Characterisation of seeds of a C4 phosphoenolpyruvate carboxylase-deficient mutant of Amaranthus edulis.

Seeds from the C(4) plant Amaranthus edulis were studied as part of the characterisation of a mutant (designated LaC(4) 2.16), which contains reduced amounts (5% of wild type) of the photosynthetic leaf form of phosphoenolpyruvate carboxylase (PEPC). On a per seed basis, the amount of PEPC activity was not significantly altered, while the weight and protein content of the mutant seeds were 34% lower than that of the wild type. Western gel blot analysis detected two PEPC polypeptides with molecular masses of 105 kDa (minor) and 100 kDa (major). The determination of in vitro phosphorylation in reconstituted assays revealed the presence of both calcium-dependent and calcium-independent PEPC-kinase activities in protein extracts of wild-type and mutant seeds. However, PEPC proteins were phosphorylated in dry seeds, and PEPC phosphorylation did not occur in vivo during seed imbibition in the presence of (32) P-phosphate. In contrast, (32) P-phosphate was incorporated into a range of proteins in wild-type seeds, but not in mutant seeds. In addition, ATP content was much reduced in germinating mutant seeds and this did not increase following the supply of phosphate. Collectively, these data suggest that the deficiency in C(4) PEPC in mutant A. edulis leaves has no effect on C(3) -type PEPC content and phosphorylation state in seeds, but causes impairment of energy production, thereby accounting for the reduced germination of the mutant.

A splice site mutation gives rise to a mutant of the C4 plant Amaranthus edulis deficient in phosphoenolpyruvate carboxylase activity.

The molecular nature of a mutant of the C4 plant Amaranthus edulis that has been shown to contain only 5% of the normal activity and protein of phosphoenolpyruvate carboxylase (PEPC) (Dever et al., 1995) has been investigated. Using Northern blot analysis, it has been shown here that the PEPC transcripts are produced in the mutant. In-vitro translation of these transcripts generated two products immunoprecipitable by a PEPC N-terminus-specific antibody. One of these products has the size of the complete PEPC polypeptide, the other is 9kDa smaller and was not revealed when using a PEPC C-terminus-specific antibody. In the mutant plant, using the same N- and C-terminus-specific antibodies, only the larger polypeptide was immunodetected, whilst at a very low level. A sequence analysis of the suspected faulty region of the mRNA revealed incorrect splicing of the last intron of the PEPC pre-mRNA. Two mis-splicings have been identified, both occurring after an AG site, one leading to a protein lacking five amino acids, the other to a truncated protein due to a stop codon generated by a frame shift in the translation. Finally, the sequencing of the boundary between the last intron and exon showed that these inaccurate splicings result from a mutation in the genuine canonical 3'AG splicing site.

C3-carboxylation as an anaplerotic reaction in phosphoenolpyruvate carboxylase-deficient Corynebacterium glutamicum.

Phosphoenolpyruvate carboxylase (PEPCx) has recently been found to be dispensable as an anaplerotic enzyme for growth and lysine production of Corynebacterium glutamicum. To clarify the role of the glyoxylate cycle as a possible alternative anaplerotic sequence, defined PEPCx- and isocitrate-lyase (ICL)-negative double mutants of C. glutamicum wild-type and of the l-lysine-producing strain MH20-22B were constructed by disruption of the respective genes. Analysis of these mutants revealed that the growth on glucose and the lysine productivity were identical to that of the parental strains. These results show that PEPCx and the glyoxylate cycle are not essential for growth of C. glutamicum on glucose and for lysine production and prove the presence of another anaplerotic reaction in this organism. To study the anaplerotic pathways in C. glutamicum further, H13CO3--labeling experiments were performed with cells of the wild-type and a PEPCx-negative strain growing on glucose. Proton nuclear magnetic resonance analysis of threonine isolated from cell protein of both strains revealed the same labeling pattern: about 37% 13C enrichment in C-4 and 3.5% 13C enrichment in C-1. Since the carbon backbone of threonine corresponds to that of oxaloacetate, the label in C-4 of threonine positively identifies the anaplerotic pathway as a C3-carboxylation reaction that also takes place in the absence of PEPCx.

Expression of Escherichia coli phosphoenolpyruvate carboxylase in a cyanobacterium. Functional complementation of Synechococcus PCC 7942 ppc.

The gene (ppc) coding for phosphoenolpyruvate carboxylase (PEPCase) in the cyanobacterium Synechococcus PCC 7942 has been inactivated via insertional mutagenesis while being functionally complemented by Escherichia coli ppc. Cyanobacterial cells functionally complemented by E. coli ppc showed decreased PEPCase activity in crude cell lysates and detergent-permeabilized whole cell assays. Decreased rates of growth, reduced levels of chlorophyll a, and decreased photosynthetic O2 evolution capacity per cell when compared to wild-type cyanobacterial cells were also observed. Phycobiliprotein levels were not affected. The results are discussed in terms of the impact of reduced PEPCase activity on cyanobacterial cell metabolism and the regulatory properties of the E. coli gene product.