Enrichment of sugar content in melon fruits by hydrogen peroxide treatment

Since sweetness is one of the most important qualities of many fruits, and since sugars are translocated from leaves to fruits, the present study investigates photosynthetic activity, activity of sugar metabolizing enzymes, sugar content in leaves and fruits and endogenous levels of hydrogen peroxide in leaves of melon plants treated with various dilutions of hydrogen peroxide, a nonspecific signaling molecule in abiotic stress. For this purpose, 4-month-old melon plants were treated with various concentrations (<50mM) of hydrogen peroxide by applying 300mL per day to the soil of potted plants. The treatments resulted in increased fructose, glucose, sucrose and starch in the leaves and fruits. The most effective concentration of hydrogen peroxide was 20mM. During the day, soluble sugars in leaves were highest at 12:00h and starch at 15:00h. Furthermore, the peroxide treatment increased the photosynthetic activity and the activities of chloroplastic and cytosolic fructose-1,6-bisphosphatase, sucrose phosphate synthase and invertases. Thus, our data show that exogenous hydrogen peroxide, applied to the soil, can increase the soluble sugar content of melon fruits.     

The critical period for thyroid hormone responsiveness through thyroid hormone receptor isoform α in the postnatal small intestine

During second and third weeks after birth in rats, serum thyroid hormone level is elevated. In this study, we investigated the jejunal expression of thyroid hormone receptor (TR) α in developing rats. The TRα-1 mRNA level and TRα-1/TRα-2 mRNA ratio increased two-fold from 5 to 13 days after birth. This high level of TRα-1 mRNA was maintained until 20 days and then decreased to the basal level by the end of weaning period at 27 days; however, the level of TRα-2 mRNA remained unchanged throughout the developmental period. The increase in the TRα-1/TRα-2 mRNA ratio from 5 to 13 days was accompanied by an initial rise in the levels of mRNA for hexose transporters in the jejunum. Administration of T₃ during the suckling period (8–13 days) caused a 50% increase in the TRα-1/TRα-2 mRNA ratio, while administration of T₃ on days 12–17 and days 16–21, but not on days 22–27, caused a two to four-fold increase in the levels of mRNA for hexose transporters. These results suggest that a transient variation in the TRα-1/TRα-2 expression ratio is closely related to the critical period of thyroid hormone responsiveness for hexose transporters expression in the developing rat jejunum.     

Inducers of glycinebetaine synthesis in barley.

Glycinebetaine is an osmoprotectant accumulated by barley (Hordeum vulgare) plants in response to high levels of NaCl, drought, and cold stress. Using barley seedlings in hydroponic culture, we characterized additional inducers of glycinebetaine accumulation. These included other inorganic salts (KCl, MgCl(2), LiCl, and Na(2)SO(4)), oxidants (H(2)O(2) and cumene hydroperoxide), and organic compounds (abscisic acid, polymixin B, n-butanol, salicylic acid, and aspirin). Stress symptoms brought on by high NaCl and other inducers, and not necessarily correlated with glycinebetaine accumulation, include wilting, loss of chlorophyll, and increase in thiobarbituric acid reacting substances. For NaCl, Ca(2+) ions at 10 to 20 mM decrease these stress symptoms without diminishing, or even increasing, glycinebetaine induction. Abscisic acid induces glycinebetaine accumulation without causing any of the stress symptoms. NaCl, KCl, and H(2)O(2) (but not other inducers) induce glycinebetaine at concentrations below those needed for the other stress symptoms. Mg(2+) at 10 to 20 mM induces both stress symptoms and glycinebetaine, but only at low (0.2 mM) Ca(2+). Although illumination is needed for optimal induction, a significant increase in the leaf glycinebetaine level is found in complete darkness, also.     

Essentiality of the small subunit (B) in the catalysis of RuBP carboxylase/oxygenase is not related to substrate-binding in the large subunit (A)

The small subunit (B) of ribulose 1,5-bisphosphate (RuBP) carboxylase/oxygenase from Aphanothece halophytica is absolutely required for the catalysis, but depletion of subunit B does not significantly affect the formation of the quaternary complex-[enzyme.activator CO2.Mg.carboxyarabinitol bisphosphate] in the catalytic core. The inhibition of RuBP carboxylase activity by the reaction of the epsilon-amino group of a lysine in the RuBP-binding site with pyridoxal 5-P is the same whether subunit B is added to the catalytic core before or after the inactivating reaction. The function of subunit B is not related to the substrate binding.     

Attachment of CuZn-Superoxide Dismutase to Thylakoid Membranes at the Site of Superoxide Generation (PSI) in Spinach Chloroplasts: Detection by Immuno-Gold Labeling After Rapid Freezing and Substitution Method

In chloroplasts O^–₂ is photoproduced via the univalentreduction of O₂ in PSI even under conditions that are favorablefor photosynthesis. The photogenerated O^–₂ is disproportionatedto H₂O₂ and O₂ in a reaction that is catalyzed by superoxidedismutase (SOD). The H₂O₂-scavenging ascorbate peroxidase isbound to the thylakoid membranes at or near the PSI reactioncenter [Miyake and Asada (1992) Plant Cell Physiol. 33: 541],and the primary product of oxidation in the peroxidase-catalyzedreaction, the monodehydroascorbate radical, is photoreducedto ascorbate in PSI in a reaction mediated by ferredoxin [Miyakeand Asada (1994) Plant Cell Physiol. 35: 539]. Therefore, SODshould be localized at or near the PSI complex. We report herethe microcompartmentalization of the chloroplastic CuZn-SODon the stromal-faces of thylakoid membranes where the PSI-complexis located. Spinach leaves were fixed and substituted by a rapidfreezing and substitution method that allows visualization ofintact chloroplasts. The embedded sections were immuno labeledwith the antibody against CuZn-SOD by the immunogold method.About 70% of the immunogold particles were found within 5 nmfrom the surface of the stromal-faces of thylakoid membranes.Of these particles, about 40% were found at the ends and marginsof the grana thylakoids and 60% were found on the stromal sideof the stromal thylakoids. From these results, the local concentrationof CuZn-SOD on the stroma-facing surfaces of the thylakoid membraneswas estimated to be about 1 mM. The effect of the microcompartmentalizationof CuZn-SOD on the scavenging of superoxide radicals is discussed. (Received November 25, 1994; Accepted February 23, 1995)     

Immunolocalization of glucomannans in the cell wall of differentiating tracheids inChamaecyparis obtusa

Summary A polyclonal antibody against glucomannans (GMs) was raised in a mouse. A dot-blot immunoassay and competitive-inhibition tests indicated that the antibody was specific for GMs. The antibody enables visualization of the localization of GMs in differentiating tracheids ofChamaecyparis obtusa. Labeling of GMs was restricted to the secondary walls of the tracheids. The labeling density temporarily increased and then decreased in the outer and middle layers of the secondary wall during cell wall formation. This is probably due to the accumulation of lignin. In comparison with previous studies of glucuronoxylans, there must be a clear difference between the deposition of GMs and that of glucuronoxylans.     

Export and functions of sphingosine-1-phosphate

The sphingolipid metabolite, sphingosine-1-phosphate (S1P), has emerged as a critical player in a number of fundamental biological processes and is important in cancer, angiogenesis, wound healing, cardiovascular function, atherosclerosis, immunity and asthma, among others. Activation of sphingosine kinases, enzymes that catalyze the phosphorylation of sphingosine to S1P, by a variety of agonists, including growth factors, cytokines, hormones, and antigen, increases intracellular S1P. Many of the biological effects of S1P are mediated by its binding to five specific G protein-coupled receptors located on the cell surface in an autocrine and/or paracrine manner. Therefore, understanding the mechanism by which intracellularly generated S1P is released out of cells is both interesting and important. In this review, we will discuss how S1P is formed and released. We will focus particularly on the current knowledge of how the S1P gradient between tissues and blood is maintained, and the role of ABC transporters in S1P release.     

Charges on proteins and distances of electron transfer in metalloprotein redox reactions

A modified form of the Debye-Marcus equation relating electron transfer rate constants to charges on proteins and distances of electron transfer has been applied to the reaction of chemically modified cytochrome f, in which positively charged amino groups are replaced with negatively charged carboxyl groups. The rate of electron transfer from reduced cytochrome f to ferricyanide decreased with increasing ionic strength when the native and singly substituted cytochrome f were used, although a sharp decrease was observed in the former case. When doubly or more than triply substituted cytochrome f was used, the rate of electron transfer was almost constant or increased with increasing ionic strength, respectively. The kinetic-ionic strength effects on this reaction can be well explained by the Debye-Marcus equation in which the charge and radius of the protein are treated as variable parameters. The results show the importance of local positive charges of about 2.0 on native cytochrome f and effective radius of about 11 A of cytochrome f for the electron transfer to ferricyanide. Since the net charge on the native cytochrome f is negative and the calculated radius of the protein is 22.8 A, the above results indicate that positive charges on the electron transfer site control the electrostatic interactions in this reaction. Previously reported data which had been analyzed by using the total net charge and full radius of the protein, were also well explained by the local charge and effective radius of the protein.(ABSTRACT TRUNCATED AT 250 WORDS)