RESUMO
Two mutants of barley (Hordeum vulgare L.), LaPr 85/55 and LaPr 87/30, have been isolated that accumulate glycine, with a concomitant reduction in the aminodonors glutamate and alanine, when transferred to air. Studies have shown that these plants have wild-type levels of serine transhydroxymethylase (EC 2.1.2.1) activity. When supplied (14)CO(2), 48 and 66% of the supplied carbon was retained as glycine in LaPr 85/55 and LaPr 87/30, respectively, compared with a value of 11% for the wild type. In the short-term, both mutant plants are unable to metabolize [(14)C] glycine, but when fed the isotope for 2 hours, LaPr 85/55 was able to metabolize most (70%) of the supplied carbon into sugars with only 15% remaining in glycine. LaPr 87/30, however, was unable to metabolize more than 4% of the supplied carbon into sugars even after 2 hours. Measurement of glycine decarboxylase (EC 2.1.2.10) activity via the glycine-bicarbonate exchange reaction showed LaPr 85/55 to have approximately 70% wild-type activity with LaPr 87/30 having only 14% wild-type activity. The approximation of LaPr 85/55 to wild-type activities was maintained for (14)CO(2) release from [(14)C]glycine feeding and ammonia accumulation in the presence of methionine sulphoximine with the equivalent rates for LaPr 87/30 being less than 40% and 10%, respectively. CO(2) fixation rates for the mutants fell to between 35 and 40% of wild-type rates within 10 min of transfer to air. This was shown to be partly due to a run down of aminodonors, because when 40 millimolar serine was supplied through the xylem stream these rates recovered for both mutants to 70% of the wild-type rate. These data suggested a mutation in a glycine transport system for LaPr 85/55 and in the proteins of glycine decarboxylase for LaPr 87/30. Western blotting with antisera to the P, H, T, and L proteins of glycine decarboxylase showed cross-reaction against all four proteins for LaPr 85/55 but little cross-reaction against P or H protein for LaPr 87/30, reaffirming the possibility of a transport mutation in LaPr 85/55. We also suggest that genes for P and H proteins could be either coordinately regulated or that one protein is undetectable or unstable in the absence of the other.
RESUMO
The use of LaPr 88/29 mutant of barley (Hordeum vulgare), which lacks NADH-preferring hydroxypyruvate reductase (HPR-1), allowed for an unequivocal demonstration of at least two related NADPH-preferring reductases in this species: HPR-2, reactive with both hydroxypyruvate and glyoxylate, and the glyoxylate specific reductase (GR-1). Antibodies against spinach HPR-1 recognized barley HPR-1 and partially reacted with barley HPR-2, but not GR-1, as demonstrated by Western immunoblotting and immunoprecipitation of proteins from crude leaf extracts. The mutant was deficient in HPR-1 protein. In partially purified preparations, the activities of HPR-1, HPR-2, and GR-1 could be differentiated by substrate kinetics and/or inhibition studies. Apparent K(m) values of HPR-2 for hydroxypyruvate and glyoxylate were 0.7 and 1.1 millimolar, respectively, while the K(m) of GR-1 for glyoxylate was 0.07 millimolar. The K(m) values of HPR-1, measured in wild type, for hydroxypyruvate and glyoxylate were 0.12 and 20 millimolar, respectively. Tartronate and P-hydroxypyruvate acted as selective uncompetitive inhibitors of HPR-2 (K(i) values of 0.3 and 0.4 millimolar, respectively), while acetohydroxamate selectively inhibited GR-1 activity. Nonspecific contributions of HPR-1 reactions in assays of HPR-2 and GR-1 activities were quantified by a direct comparison of rates in preparations from wild-type and LaPr 88/29 plants. The data are evaluated with respect to previous reports on plant HPR and GR activities and with respect to optimal assay procedures for individual HPR-1, HPR-2, and GR-1 rates in leaf preparations.
RESUMO
A mutant of barley (Hordeum vulgare L.), LaPr 88/29, deficient in NADH-dependent hydroxypyruvate reductase (HPR) activity has been isolated. The activities of both NADH (5%) and NADPH-dependent (19%) HPR were severely reduced in this mutant compared to the wild type. Although lacking an enzyme in the main carbon pathway of photorespiration, this mutant was capable of CO(2) fixation rates equivalent to 75% of that of the wild type, in normal atmospheres and 50% O(2). There also appeared to be little disruption to the photorespiratory metabolism as ammonia release, CO(2) efflux and (14)CO(2) release from l-[U-(14)C]serine feeding were similar in both mutant and wild-type leaves. When leaves of LaPr 88/29 were fed either [(14)C]serine or (14)CO(2), the accumulation of radioactivity was in serine and not in hydroxypyruvate, although the mutant was still able to metabolize over 25% of the supplied [(14)C]serine into sucrose. After 3 hours in air the soluble amino acid pool was almost totally dominated by serine and glycine. LaPr 88/29 has also been used to show that NADH-glyoxylate reductase and NADH-HPR are probably not catalyzed by the same enzyme in barley and that over 80% of the NADPH-dependent HPR activity is due to the NADH-dependent enzyme. We also suggest that the alternative NADPH activity can metabolise a proportion, but not all, of the hydroxypyruvate produced during photorespiration and may thus form a useful backup to the NADH-dependent enzyme under conditions of maximal photorespiration.
RESUMO
Manipulation of the CO2 concentration of the atmosphere allows the selection of photorespiratory mutants from populations of seeds treated with powerful mutagens such as sodium azide. So far, barley lines deficient in activity of phosphoglycolate phosphatase, catalase, the glycine to serine conversion, glutamine synthetase, glutamate synthase, 2-oxoglutarate uptake and serine: glyoxylate aminotransferase have been isolated. In addition one line of pea lacking glutamate synthase activity and one barley line containing reduced levels of Rubisco are available. The characteristics of these mutations are described and compared with similar mutants isolated from populations of Arabidopsis. As yet, no mutant lacking glutamine synthetase activity has been isolated from Arabidopsis and possible reasons for this difference between barley and Arabidopsis are discussed. The value of these mutant plants in the elucidation of the mechanism of photorespiration and its relationships with CO2 fixation and amino acid metabolism are highlighted.
RESUMO
A mutant of Hordeum vulgare L. (LaPr 85/84) deficient in serine: glyoxylate aminotransferase (EC 2.6.1.45) activity has been isolated. The plant also lacks serine: pyruvate aminotransferase and asparagine: glyoxylate aminotransferase activities. Genetic analysis of the mutation strongly indicates that these three activities are all carried on the same enzyme protein. The mutant is incapable of normal rates of photosynthesis in air but can be maintained at 0.7% CO2. The rate of photosynthesis cannot be restored by supplying hydroxypyruvate, glycerate, glutamate or ammonium sulphate through the xylem stream. This photorespiratory mutant demonstrates convincingly that photorespiration still occurs under conditions in which photosynthesis becomes insensitive to oxygen levels. Two major peaks and one minor peak of serine: glyoxylate aminotransferase activity can be separated in extracts of leaves of wild-type barley by diethylaminoethyl-sephacel chromatography. All three peaks are missing from the mutant, LaPr 85/84. The mutant showed the expected rate (50%) of ammonia release during photorespiration but produced CO2 at twice the wild-type rate when it was fed [(14)C]glyoxylate. The large accumulation of serine detected in the mutant under photorespiratory conditions shows the importance of the enzyme activity in vivo. The effect of the mutation on transient changes in chlorophyll a fluorescence initiated by changing the atmospheric CO2 concentration are presented and the role of the enzyme activity under nonphotorespiratory conditions is discussed.
