Perspectives on plant photorespiratory metabolism.

Being intimately intertwined with (C3) photosynthesis, photorespiration is an incredibly high flux-bearing pathway. Traditionally, the photorespiratory cycle was viewed as closed pathway to refill the Calvin-Benson cycle with organic carbon. However, given the network nature of metabolism, it hence follows that photorespiration will interact with many other pathways. In this article, we review current understanding of these interactions and attempt to define key priorities for future research, which will allow us greater fundamental comprehension of general metabolic and developmental consequences of perturbation of this crucial metabolic process.

In vivo studies on the interaction of RecBCD enzyme and lambda Gam protein.

The interaction between the RecBCD enzyme of Escherichia coli and the lambda Gam protein was investigated. Two types of experiments were done. In one type, Gam protein was produced by transient induction of the cells lysogenic for lambda cI857gam+. The presence of Gam protein, which inhibits RecBCD nuclease, enabled these cells to support the growth of a gene 2 mutant of bacteriophage T4 (T4 2). The lysogens overproducing the RecB subunit of RecBCD enzyme could titrate Gam protein and thus prevent the growth of T4 2. In contrast, the lysogens overproducing either RecC or RecD retained their capacity for growth of T4 2. It is therefore concluded that the RecB subunit is capable of binding Gam protein. In the second type of experiments, Gam protein was provided by derepressing the gamS gene on the plasmid pSF117 (S. A. Friedman and J. B. Hays, Gene 43:255-263, 1986). The presence of this protein did not interfere with the growth of wild-type cells (which were F-). Gam protein had a certain effect on recF mutants, whose doubling time became significantly longer. This suggests that the recF gene product plays an important role in maintenance of viability of the Gam-expressing cells. Gam protein exerted the most striking effect on growth of Hfr bacteria. In its presence, Hfr bacteria grew extremely slowly, but their ability to transfer DNA to recipient cells was not affected. We showed that the effect on growth of Hfr resulted from the interaction between the RecBCD-Gam complex and the integrated F plasmid.

Isolation, characterization, and functional expression of cDNAs encoding NADH-dependent methylenetetrahydrofolate reductase from higher plants.

Methylenetetrahydrofolate reductase (MTHFR) is the least understood enzyme of folate-mediated one-carbon metabolism in plants. Genomics-based approaches were used to identify one maize and two Arabidopsis cDNAs specifying proteins homologous to MTHFRs from other organisms. These cDNAs encode functional MTHFRs, as evidenced by their ability to complement a yeast met12 met13 mutant, and by the presence of MTHFR activity in extracts of complemented yeast cells. Deduced sequence analysis shows that the plant MTHFR polypeptides are of similar size (66 kDa) and domain structure to other eukaryotic MTHFRs, and lack obvious targeting sequences. Southern analyses and genomic evidence indicate that Arabidopsis has two MTHFR genes and that maize has at least two. A carboxyl-terminal polyhistidine tag was added to one Arabidopsis MTHFR, and used to purify the enzyme 640-fold to apparent homogeneity. Size exclusion chromatography and denaturing gel electrophoresis of the recombinant enzyme indicate that it exists as a dimer of approximately 66-kDa subunits. Unlike mammalian MTHFR, the plant enzymes strongly prefer NADH to NADPH, and are not inhibited by S-adenosylmethionine. An NADH-dependent MTHFR reaction could be reversible in plant cytosol, where the NADH/NAD ratio is 10(-3). Consistent with this, leaf tissues metabolized [methyl-(14)C]methyltetrahydrofolate to serine, sugars, and starch. A reversible MTHFR reaction would obviate the need for inhibition by S-adenosylmethionine to prevent excessive conversion of methylene- to methyltetrahydrofolate.

S-methylmethionine plays a major role in phloem sulfur transport and is synthesized by a novel type of methyltransferase.

All flowering plants produce S-methylmethionine (SMM) from Met and have a separate mechanism to convert SMM back to Met. The functions of SMM and the reasons for its interconversion with Met are not known. In this study, by using the aphid stylet collection method together with mass spectral and radiolabeling analyses, we established that l-SMM is a major constituent of the phloem sap moving to wheat ears. The SMM level in the phloem ( approximately 2% of free amino acids) was 1.5-fold that of glutathione, indicating that SMM could contribute approximately half the sulfur needed for grain protein synthesis. Similarly, l-SMM was a prominently labeled product in phloem exudates obtained by EDTA treatment of detached leaves from plants of the Poaceae, Fabaceae, Asteraceae, Brassicaceae, and Cucurbitaceae that were given l-(35)S-Met. cDNA clones for the enzyme that catalyzes SMM synthesis (S-adenosylMet:Met S-methyltransferase; EC 2.1.1.12) were isolated from Wollastonia biflora, maize, and Arabidopsis. The deduced amino acid sequences revealed the expected methyltransferase domain ( approximately 300 residues at the N terminus), plus an 800-residue C-terminal region sharing significant similarity with aminotransferases and other pyridoxal 5'-phosphate-dependent enzymes. These results indicate that SMM has a previously unrecognized but often major role in sulfur transport in flowering plants and that evolution of SMM synthesis in this group involved a gene fusion event. The resulting bipartite enzyme is unlike any other known methyltransferase.