抗坏血酸对植物生长发育的作用及其缺失突变体的研究进展

抗坏血酸（ascorbic acid,AsA）是植物组织内广泛存在的高丰度小分子物质。近年的研究表明它可能通过复杂的信号转导网络来调节植物生长、诱导开花以及延缓衰老。本文介绍了AsA对植物生长发育的作用及其缺失突变体的研究进展,为深入利用AsA缺失突变体来发掘AsA新的生物学功能提供参考。     

光呼吸突变体研究进展

光呼吸（photorespiration）是绿色植物在光下吸收氧气并释放CO2的过程。C3植物光呼吸可消耗25%光合产物,故合理改良光呼吸可望提高植物的光合效率。筛选与利用光呼吸突变体是研究光呼吸代谢及其功能的最为有效的途径。该文对光呼吸代谢途径、光呼吸突变体的筛选以及研究进展进行综述,以期为深入探讨植物光呼吸的生物学功能及进行植物分子改良提供帮助。     

Effects of pigment-deficient mutants on the accumulation of photosynthetic proteins in maize

We have monitored the accumulation of photosynthetic proteins in developing pigment-deficient mutants of Zea mays. The proteins examined are the CO₂-fixing enzymes, phoshoenolpyruvate carboxylase (E.C. 4.1.1.31) and ribulose-1,5-bisphosphate carboxylase (E.C.4.1.1.39), and three thylakoid membrane proteins, the light-harvesting chlorophyll a/b binding protein (LHCP) of photosystem II, the 65 kilodalton chlorophyll a binding protein of photosystem I and the alpha subunit polypeptide of coupling factor I. Using a sensitive protein-blot technique, we have compared the relative quantities of each protein in mutants and their normal siblings. Carboxylase accumulation was found to be independent of chlorophyll content, while the amounts of the thylakoid proteins increase at about the same time as chlorophyll in delayed-greening mutants. The relative quantity of LHCP is closely correlated with the relative quantity of chlorophyll at all stages of development in all mutants. Because pigment-deficient mutants are arrested at early stages in chloroplast development, these findings suggest that the processes of chloroplast development, chlorophyll synthesis and thylakoid protein accumulation are coordinated during leaf development but that carboxylase accumulation is controlled by different regulatory mechanisms. A white leaf mutant was found to contain low levels of LHCP mRNA, demonstrating that the accumulation of LHCP mRNA is not controlled exclusively by phytochrome.     

The DNA gyrase of Escherichia coli participates in the formation of a spontaneous deletion by recA-independent recombination in vivo

Summary A system for detecting a spontaneous deletion in Escherichia coli was developed and the role of DNA gyrase in deletion formation was studied. A derivative of plac5, AM36, was isolated in which whole pBR322 DNA was inserted in the lacZ gene and 227 by of the lac gene duplicated at both sides of the pBR322 DNA. E. coli lac ^–strains lysogenized by AM36 had a Lac^– phenotype and segregated Lac^– revertants. Sequence analyses showed that the revertant was formed by a deletion that eliminated the inserted pBR322 DNA and one copy of the duplicated segments. The frequency of lac ^– revertant formation was independent of recA function, was increased by oxolinic acid, an inhibitor of DNA gyrase, but was not increased in a lysogen of a nalidixic acid-resistant derivative. The reversion frequencies of temperature sensitive mutants of gyrA gene are 10 to 100 times lower than that of the wild-type strain. These results indicate that the DNA gyrase of E. coli participated in the in vivo deletion formation resulting from the direct repeats.     

A New Simple Method for Isolating Multistress-Tolerant Semidominant Mutants of Saccharomyces cerevisiae by One-Step Selection under Lethal Hydrogen Peroxide Stress Condition

A tetrathionate-decomposing enzyme that catalyzes the decomposition of tetrathionate into thiosulfate and sulfate was purified to homogeneity from tetrathionate-grown Thiobacillus thiooxidans. The enzyme had an apparent molecular weight of 104,000, and was composed of two identical subunits (MW = 58,000) as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The enzyme had an isoelectric point at 9.6 and was most active at pH 3.0–3.5 and 40°C. Enzyme activity was increased approximately 100-fold in the presence of 400 mm sulfate ion. The Michaelis constant of this enzyme for tetrathionate in the presence of 20, 50, and 200 mm of sulfate ion was 2.4 mm. Mercuric and ferric ions completely inhibited the enzyme activity at 1 mm. Though cupric ion up to 0.01 mm markedly stimulated the activity in the presence of 20 mm sulfate ion, a higher concentration (1 mm) rather strongly inhibited the activity. Ethylenediaminetetraacetic acid (EDTA) strongly inhibited the activity, but this inhibiton was completely restored by cupric ion.     

The Molecular Genetics of Superoxide Dismutase in E. Coli

The biological role and the regulation of superoxide dismutase (SOD) in E. coli have been investigated using genetics. Cloning of both E. coli SOD genes permitted construction of mutants completely lacking SOD. The conditional oxygen sensitivity of those mutants, together with their increased mutation rate, demonstrated the essential biological role of SOD. SOD-deficient mutants constitute a powerful tool to assess a possible role of O^?2 or SOD in biological processes. Complementation of their deficiencies by the expression of SOD originating from a different organism is used for screening libraries for SOD genes of other species. Regulation of MnSOD has been studied using protein and operon fusions with the lactose operon, and isolating regulation mutants. These studies reveal multiregulation of MnSOD including response to the superoxide mediated oxidative stress and response to variations of the intracellular redox state induced by metabolic changes.     

Anion uptake in maize roots: Interactions between chlorate and nitrate

Effects of nitrate, chloride and chlorate ions upon nitrate and chlorate uptake by roots of maize ( Zea mays L., cv. B73) seedlings were examined. Net nitrate uptake, ³⁶ClO₃⁻ influx and ³⁶Cl⁻ influx (the latter two in a background of 0.5 m M KNO₃) displayed similar pH profiles with optima at pH 5.5 and below. External, non-labeled chloride had little effect on the accumulation of ³⁶ClO₃⁻ (both in 5 h and 20 min uptake assays), while nitrate and chlorate had almost identical, marked inhibitory effects. Nitrate pretreatment caused an apparent induction of both ³⁶ClO₃⁻ and ¹⁵NO₃⁻ uptake activities. After 5 h of treatment in nitrate, the uptake activities of chloride- and chlorate-pretreated plants increased to that of nitrate-pretreated plants. During 6 h exposure to chlorate, ³⁶ClO₃⁻ uptake activity of nitrate-pretreated plants decreased to that of chlorate- and chloride-pretreated plants. The results support the existence of a shared nitrate/chlorate transport system in maize roots which is not inhibited by external chloride, and which is induced by nitrate, but not by chlorate or chloride. The suggestion is made that selection of chlorate-resistant mutants of maize can identify nitrate uptake as well as nitrate reductase mutants.     

Symbiotic relationships between soil fungi and plants reduce N2O emissions from soil

N₂O is a potent greenhouse gas involved in the destruction of the protective ozone layer in the stratosphere and contributing to global warming. The ecological processes regulating its emissions from soil are still poorly understood. Here, we show that the presence of arbuscular mycorrhizal fungi (AMF), a dominant group of soil fungi, which form symbiotic associations with the majority of land plants and which influence a range of important ecosystem functions, can induce a reduction in N₂O emissions from soil. To test for a functional relationship between AMF and N₂O emissions, we manipulated the abundance of AMF in two independent greenhouse experiments using two different approaches (sterilized and re-inoculated soil and non-mycorrhizal tomato mutants) and two different soils. N₂O emissions were increased by 42 and 33% in microcosms with reduced AMF abundance compared to microcosms with a well-established AMF community, suggesting that AMF regulate N₂O emissions. This could partly be explained by increased N immobilization into microbial or plant biomass, reduced concentrations of mineral soil N as a substrate for N₂O emission and altered water relations. Moreover, the abundance of key genes responsible for N₂O production (nirK) was negatively and for N₂O consumption (nosZ) positively correlated to AMF abundance, indicating that the regulation of N₂O emissions is transmitted by AMF-induced changes in the soil microbial community. Our results suggest that the disruption of the AMF symbiosis through intensification of agricultural practices may further contribute to increased N₂O emissions.     

A general method for the quantitative analysis of functional chimeras: applications from site-directed mutagenesis and macromolecular association

Two new parameters, I: and C:, are introduced for the quantitative evaluation of functional chimeras: I: (impact) and C: (context dependence) are the free energy difference and sum, respectively, of the effects on a given property measured in forward and retro chimeras. The forward chimera is made by substitution of a part "a" from ensemble A into the analogous position of homologous ensemble B (S:(B --> A)). The C: value is a measure of the interaction of the interrogated position with its surroundings, whereas I: is an expression of the quantitative importance of the probed position. Both I: and C: vary with the evaluated property, for example, kinetics, binding, thermostability, and so forth. The retro chimera is the reverse substitution of the analogous part "b" from B into A, S:(A --> B). The I: and C: values derived from original data for forward and retro mutations in aspartate and tyrosine aminotransferase, from literature data for quasi domain exchange in oncomodulin and for the interaction of Tat with bovine and human TAR are evaluated. The most salient derived conclusions are, first, that Thr 109 (AATase) or Ser 109 (TATase) is an important discriminator for dicarboxylic acid selectivity by these two enzymes (I: < -2.9 kcal/mol). The T109S mutation in AATase produces a nearly equal and opposite effect to S109T in TATase (C: < 0.4 kcal/mol). Second, an I: value of 5.5 kcal/mol describes the effects of mirror mutations D94S (site 1) and S55D (site 2) in the Ca(2+) binding sites of oncomodulin on Ca(2+) affinity. The second mirror set, G98D (site 1) and D59G (site 2), yields a smaller impact (I: = -3.4 kcal/mol) on Ca(2+) binding; however, the effect is significantly more nearly context independent (C: = -0.6 versus C: = -2.7 kcal/mol). Third, the stem and loop regions of HIV and BIV TAR are predominantly responsible for the species specific interaction with BIV Tat(65-81) (I: = -1.5 to -1.6 kcal/mol), whereas I: = 0.1 kcal/mol for bulge TAR chimeras. The C: values are from -0.3 to -1.2 kcal/mol. The analysis described should have important applications to protein design.