Plant enzyme synthesis: Hormonal regulation of invertase and peroxidase synthesis in sugar cane

Summary Using sugar-cane internodal tissue in which RNA synthesis was ratelimiting for invertase of peroxidase synthesis, measurements were made of enzymeforming-capacity after blocking further RNA synthesis with actinomycin D or 6-methylpurine. In this way it was possible to determine whether added auxin (naphthaleneacetic acid) or gibberellic acid (GA₃) affected steps prior or subsequent to synthesis of the RNA fractions specifically required for synthesis of either enzyme. Both auxin and GA₃ increased the enzyme-forming-capacity for invertase but not for peroxidase. The effects of the two hormones are interpreted as causing stabilization of mRNA for invertase.Abscisic acid (ABA) increased the rate of synthesis of invertase but not peroxidase. ABA did not change the rate of loss of invertase when peptide-bond formation was blocked with cycloheximide, but stimulated its synthesis when RNA synthesis was blocked with 6-methyl purine. Hence, the site of action of ABA is subsequent to invertase-mRNA formation and prior to invertase destruction.Kinetin had no short-term effects when RNA synthesis was limiting for invertase production, and does not appear to directly modulate mRNA synthesis or stabilization, or amino-acid-polymerization steps. In treatments longer than 5 hours, kinetin inhibited synthesis of all three enzymes studied, so that its effect on enzyme synthesis in this tissue appears to be unspecific.Abbreviations used throughout text ABA (±)-abscisic acid (abscisin II, dormin) - GA₃ gibberellic acid - NAA -naphthaleneacetic acid     

Two differentially regulated mRNAs with different 5′ ends encode secreted and intracellular forms of yeast invertase

The SUC2 gene of yeast (Saccharomyces) encodes two forms of invertase: a secreted, glycosylated form, the synthesis of which is regulated by glucose repression, and an intracellular, nonglycosylated enzyme that is produced constitutively. The SUC2 gene has been cloned and shown to encode two RNAs (1.8 and 1.9 kb) that differ at their 5′ ends. The stable level of the larger RNA is regulated by glucose; the level of the smaller RNA is not. A correspondence between the presence of the 1.9 kb RNA and the secreted invertase, and between the 1.8 kb RNA and the intracellular invertase, was observed in glucose-repressed and -derepressed wild-type cells. In addition, cells carrying a mutation at the SNF1 locus fail to derepress synthesis of the secreted invertase and also fail to produce stable 1.9 kb RNA during growth in low glucose. Glucose regulation of invertase synthesis thus is exerted, at least in part, at the RNA level. A naturally silent allele (suc2°) of the SUC2 locus that does not direct the synthesis of active invertase was found to produce both the 1.8 and 1.9 kb RNAs under normal regulation by glucose. A model is proposed to account for the synthesis and regulation of the two forms of invertase: the larger, regulated mRNA contains the initiation codon for the signal sequence required for synthesis of the secreted, glycosylated form of invertase; the smaller, constitutively transcribed mRNA begins within the coding region of the signal sequence, resulting in synthesis of the intracellular enzyme.     

Regulation of invertase synthesis by glucose in Saccharomyces cerevisiae.

Saccharomyces cerevisiae growing under repressible conditions (1% of glucose or more) produces a burst of external invertase when shifted to higher temperatures. The secretion of this invertase requires protein synthesis, but was found to be independent of RNA formation. The level of mRNA accumulated and translated was inversely proportional to the glucose present in the growth medium. These results are consistent with the hypothesis that invertase is continuously synthesized both in the presence and absence of glucose, but under repressible conditions is degraded before secretion takes place.     

Inhibition of Auxin-induced Deoxyribonucleic Acid Synthesis and Chromatin Activity by 5-Fluorodeoxyuridine in Soybean Hypocotyl

Rootless soybean (Glycine max) seedlings were used as a test system to examine the action of auxin on chromatin-directed RNA synthesis. Chromatin from the basal tissue of rootless seedlings (both control and auxin-treated) had RNA synthetic capacity similar to that of chromatin from comparably treated intact seedlings. When DNA synthesis normally induced in the basal tissue by auxin was blocked in the rootless seedlings by 5-fluorodeoxyuridine, the auxin enhancement of chromatin activity was inhibited 70%. This level was still three times the control level, indicating that auxin influenced the synthetic activity of existing DNA template. Experiments with Escherichia coli RNA polymerase revealed that chromatin from both auxin- and auxin plus 5-fluorodeoxyuridine-treated tissue saturated at higher levels than chromatin from control tissue.     

Gibberellic acid-stimulated and auxin-stimulated cell growth in relation to RNA synthesis, protein synthesis and development in the wheat coleoptile

Young excised coleoptiles from dark grown wheat have their cell growth promoted by gibberellic acid (GA₃), while sections from older coleoptiles have their cell growth promoted by auxin. The GA₃ response has a much longer lag period than that of auxin. Neither GA₃ nor auxin has any effect on ¹⁴C-leucine and ¹⁴C-uridine incorporation and uptake after 1 h, indicating that the lag in growth stimulation following GA₃ application is not associated with changes in protein or RNA synthesis. Following a 6 h incubation there are small increases in ¹⁴C-leucine and ¹⁴C-uridine incorporation in response to both GA₃ and auxin, and in the case of auxin this is associated with increased uptake. Studies on protein and RNA turnover using pulse-chase experiments have shown that both GA₃ and auxin have no effect on protein and RNA stability. There are, however, developmental changes in RNA and protein synthesis that should be considered in any explanation of the mechanism of action of these hormones on cell growth. Young GA₃-sensitive tissue has high rates of RNA synthesis and low protein and RNA turnover, while auxin-sensitive tissue has low rates of RNA synthesis, slightly higher rates of RNA turnover and much higher rates of protein turnover. The evidence overall favours more effective utilisation by GA₃ and auxin of a basal control level of RNA and protein synthesis and turnover in coleoptile tissue.     

The Influence of Auxin and Ethylene on Chromatin-directed Ribonucleic Acid Synthesis in Soybean Hypocotyl

Soybean seedlings treated with ethylene exhibited small increases in ribonucleic acid content in the elongating section of the hypocotyl. Chromatin isolated from the elongating section of ethylene-treated seedlings showed a 35 to 60% increase in the capacity for RNA synthesis. The ethylene-induced response was saturated at 1 microliter/liter of ethylene and was fully expressed after 3 hours. Auxin caused marked accumulation of RNA and DNA in the elongating and basal tissue of the hypocotyl. Chromatin isolated from these auxin-treated tissues showed an 8- to 10- fold increase in RNA synthetic capacity as measured in vitro. Ethylene added with auxin reduced the auxin enhancement of nucleic acid synthesis in the elongating and basal tissues. Both ethylene and auxin treatment of the seedlings inhibited nucleic acid accumulation and chromatin activity in the apical tissue. Ethylene did not appear to mediate the auxin effects on nucleic acid synthesis in soybean hypocotyl with the possible exception of inhibition in the apical tissue.     

SENESCENCE: HORMONAL CONTROL OF RNA AND PROTEIN SYNTHESIS IN EXCISED BEAN POD TISSUE

The kinetics of degradation of RNA, total protein, ribosomal and soluble (R-S) protein and DNA were followed over 24 hours in excised segments of Kentucky Wonder pole beans (Phaseolus vulgaris). In absence of exogenous auxin, RNA degradation proceeded from about zero time. By 15 hours, after about 20% of the RNA had degraded, the degradation of DNA, total protein and R-S protein was initiated. Exogenous auxin (25 ppm α-napthaleneacetic acid) prevented these degradations. The addition of kinetin had little or no effect. Auxin enhanced incorporation of orotic acid into RNA two to several times more than it did amino acids into protein. Actinomycin D repressed RNA synthesis about 75% including a repression of auxin-induced synthesis. It had no effect on the basal level of protein synthesis but did repress auxin-induced synthesis. The results indicate that the primary action of auxin in preventing senescence of bean endocarp tissue is at the site of RNA synthesis, and the effect of auxin on DNA and protein is a consequence of the effect of auxin on RNA metabolism.     

Induced production of invertase in sugar-beet root by γ-irradiation: Role of RNA

Summary Gamma-irradiation dosages between 100 and 200 krad greatly stimulate the development of invertase activity in sugar-beet tissue. However, exposure of tissue to 800 krad virtually eliminates the production of invertase. The production of the enzyme in control and irradiated tissue requires RNA and protein synthesis. Failure of 5-fluorouracil to inhibit the development of invertase implies that the synthesis of ribosomal RNA is not required for enzyme production. A close correlation between irradiation-stimulated methylation of sRNA and enzyme production is noted. We suggest that the synthesis or modification of some RNA required for the translation of masked invertase RNA is stimulated by -irradiation.This research was supported by a contract (C00-1313-30) from the U.S. Atomic Energy Commission. This is journal paper 4473 of the Purdue University Agriculture Experiment Station.     

Effect of auxins and ectomycorrhizal elicitors on wall-bound proteins and enzymes of spruce [Picea abies (L.) Karst.] cells

Summary Elicitors of the ectomycorrhizal fungus Hebeloma crustuliniforme and auxins (IAA, NAA and 2,4-D) were tested for their effects on apoplastic proteins and enzymes of suspension cultured cells of Picea abies (L.) Karst. The ectomycorrhizal elicitor increased the amount of some ionically wall-bound proteins (36, 28, 24, 21 kDa) and decreased the amount of others (61, 22 kDa). The elicitor triggered an H₂O₂ burst and enhanced the peroxidase (EC 1.11.1.7) activity of the Picea cells by increasing one of the two wall-bound peroxidase isoforms. Auxins significantly suppressed the elicitor induction of peroxidase but did not influence the elicitor-triggered H₂O₂ burst. The elicitors and auxin did not change the amount and the pattern of wall-bound invertase isoforms (EC 3.2.1.26) of spruce cells. However, auxin reduced the uptake of glucose by spruce cells and increased the acidification of the cell culture medium. Since Hebeloma lacks apoplastic invertase as well as a sucrose uptake system, utilization of plant-derived sucrose depends on the apoplastic plant invertase activity. Although the host invertase is constitutive, the fungus might be able to increase this invertase activity within a mycorrhiza by lowering the pH of the interface towards the pH optimum of the enzyme via the action of auxin. This fungus-released hormone could increase the H⁺ extrusion of plant cells by activation of the plant membrane H⁺-ATPases. Additionally, an auxin-dependent suppression of glucose uptake by cortical root cells could improve the glucose supply for the fungus. Furthermore, the fungal auxin might suppress the elicitor induced formation of defense enzymes, such as peroxidase.     

Greater Length of Ribonucleic Acid Synthesized by Chromatin-bound Polymerase from Auxin-treated Soybean Hypocotyls

An investigation has been made of the RNA synthesized by chromatin-bound RNA polymerase from soybean hypocotyls (Glycine max var. Wayne). Polymerase activity is 4- to 5-fold higher with chromatin from tissue treated with 2,4-dichlorophenoxyacetic acid, a synthetic auxin, compared to untreated tissue. Thin layer chromatography of the RNA hydrolysis products and acrylamide gel electrophoresis of the RNA synthesized by the chromatin show that increased activity induced by 2,4-dichlorophenoxyacetic acid is due primarily to the production of longer RNA chains, with only 20 to 50% increase in the number of RNA chains. The observation that 2,4-dichlorophenoxyacetic acid treatment leads to greater rates of RNA synthesis, producing longer chains in unit time, suggests that one manifestation of auxin activity is in activation of RNA polymerase I (ribosomal RNA polymerase).     

RNA Stimulated by Indole Acetic Acid

THE stimulation of RNA synthesis in plant cells by auxins^1,2 may be due, in part, to gene derepression, since chromatin isolated from hormone-treated cells is a better template. Mathysse and Phillips³ demonstrated that an acceptor protein for auxin can interact with the chromatin to derepress the genome. In their system the hormone and protein do not affect the rate of RNA synthesis if pure DNA. is used as a template. However, the actual mechanism of auxin on RNA synthesis by isolated RNA polymerase system has yet to be elucidated.     

Senescence: action of auxin and kinetin in control of RNA and protein synthesis in subcellular fractions of bean endocarp

A comparative study was made of the effects of auxin (α-naphthalene acetic acid), kinetin (6-furfurylaminopurine) and a mixture of auxin and kinetin applied in vivo on synthesis of RNA and protein and the distribution of such synthesis amongst the subcellular fractions of sections of endocarp from Kentucky Wonder pole beans (Phaseolus vulgaris, L.). Auxin caused considerable enhancement of incorporation of labeled precursors into RNA and protein of all subcellular fractions, and induced net synthesis of RNA and protein. That auxin-induced net synthesis of protein is repressed by actinomycin D indicates that auxin acts primarily to stimulate synthesis of RNA, as a result of which synthesis of protein is enhanced. The effect of kinetin alone on synthesis of RNA, or of kinetin on auxin-induced synthesis of RNA was variable, with either stimulation or inhibition observed in different experiments. Kinetin-enhancement of synthesis of both RNA and protein in subcellular fractions also varied, with enhancement of synthesis in 1 or all subcellular fractions among different experiments. The variable effect of kinetin did not seem to be related to the amount of endogenous or added auxin. The mode of action of kinetin is discussed.     

Biochemical and Cytological Analyses of RNA Synthesis in Kinetin-treated Pea Root Parenchyma

Excised cortical parenchyma from the pea root (cv. Little Marvel) responds to kinetin/auxin treatment with an increased rate of RNA synthesis well before reinitiating DNA synthesis. Few cells synthesize RNA in the 1st hour of culture. In the presence of kinetin/auxin, the nuclear labeling index increases 2.5-fold as compared to control cultures. The RNA synthesis response has an apparent lag period of 2-4 hours as shown by double label ([³H]adenosine/[¹⁴C]adenosine) experiments. Qualitatively, the RNA synthesized at 4-6 hours sediments between 18S and 5S. The RNA synthesized at 14-16 hours and 24-26 hours is primarily ribosomal RNA when kinetin is present. In the absence of kinetin, no clear pattern of RNA synthesis emerges.     

The regulation of sugar uptake and accumulation in bean pod tissue

The identity, localization and physiological significance of enzymes involved in sugar uptake and accumulation were determined for endocarp tissue of pods of Kentucky Wonder pole beans (Phaseolus vulgaris). An intracellular, alkaline invertase (pH optimum, 8) was assayed in extracted protein, as well as enzymes involved in sucrose synthesis, namely, uridinediphosphate (UDP-glucose pyrophosphorylase and UDP-glucose-fructose transglucosylase). Indirect evidence indicated the presence also of hexokinase, phosphohexoseisomerase and phosphoglucomutase. The data suggested that sucrose synthesis occurred in the cytoplasm, and that both sugar storage and an alkaline invertase occurred in the vacuole. The latter functions to hydrolyze accumulated sucrose. An outer space invertase (pH optimum, 4.0) was detected, but was variable in occurrence. Although its activity at the cell surface enhanced sucrose uptake, sucrose may be taken up unaltered.

Over a wide range of concentrations of exogenous glucose the sucrose/reducing sugar ratio of accumulated sugars remained unchanged at about 20. Synthesis of sucrose appears to be requisite to initial accumulation from glucose or fructose, as free hexoses do not increase at the apparent saturating concentration for uptake. Sucrose accumulation from exogenous hexose represents a steady-state value, in which sucrose is transported across the tonoplast into the vacuole at a rate equivalent to its rate of synthesis. Evidence indicates that this component of the accumulation process involves active transport of sucrose against a concentration gradient. The ratio of sucrose/reducing sugars in the accumulated sugars immediately after a period of uptake was inversely related to the level of inner space invertase. Within 16 hours after a period of accumulation, practically all of the sugar occurs as glucose and fructose.

The absence of competition among hexoses and sucrose indicated that a common carrier was not involved in their uptake. From a series of studies on the kinetics of uptake of glucose and fructose, including competition studies, the effects of inhibitors, radioactive assay of accumulated sugars and the distribution of label in accumulated sucrose it appeared that rate limitation for glucose or fructose uptake resides in the sequence of reactions leading to sucrose synthesis, rather than in a process mediated by a carrier protein.

     

Change in invertase activity of sweet potato in response to wounding and purification and properties of its invertases

When root tissue of sweet potato (Ipomoea batatas Lam.) was sliced, acid invertase activity, initially absent in freshly sliced tissue, appeared after a 3- to 6-hour lag phase, rapidly reached a maximum in 18 hours, and thereafter decreased. The increase in invertase activity was accompanied by a decrease in sucrose content of the root tissue. Alkaline invertase activity was present in fresh root tissue, but changed little after wounding. Acid invertase in wounded tissue and alkaline invertase in fresh tissue were purified and their properties were investigated. The acid invertase was a ß-fructofuranosidase and was unaffected by substrate or by any of the cations and several metabolites. The alkaline invertase was more specific for sucrose, was inhibited by glucose and glucose 6-phosphate, and displayed non-Michaelis-Menten kinetics.     

Effect of 2,4-dichlorophenoxyacetic acid on polysomal profiles and polyadenylated RNA in excised tuber tissue of Jerusalem artichoke (Helianthus tuberosus)

Dormant tuber tissue of Jerusalem artichoke ( Helianthus tuberosus L.) can be stimulated by wounding to initiate RNA and protein synthesis. No DNA synthesis or cell divisions occur unless an auxin is provided. Changes in polysomal profiles and levels of Poly(A)⁺-RNA in response to wounding and auxin treatment were studied. Polysomes were isolated at various times after excision and incubation of tissue in the presence or absence of 10⁻⁵ M 2,4-dichlorophenoxyacetic acid. Polysomal profiles were studied by sucrose density gradient centrifugation. Dormant tissue contained ribosomes mainly in monosome form. Within 4 h of excision, a significant increase in the polysomal fraction was observed both in control and auxin-treated tissue. Increases in polysomes continued during the next 20 h. Poly(A)⁺-RNA was isolated from total polysomal RNA by oligo(dT)-cellulose column chromatography. There was a large increase in the amount of poly(A)⁺-RNA within 4 h of excision. During the first 43 h of incubation, levels of total polysomal RNA as well as poly(A)⁺-RNA in tissue treated with 2,4-dichlorophenoxyacetic acid were significantly higher than those in controls.     

RNA biosynthesis in adipose tissue: effect of fasting

RNA metabolism has been examined in intact adipose tissue and isolated fat cells from rats. The lipocyte contains three species of RNA with sedimentation rates corresponding to those of ribosomal and transfer RNA. The de novo biosynthesis of RNA by adipose tissue cells in vitro was demonstrated. The base ratios of the RNA formed indicate that it was synthesized from a DNA template. Actinomycin D administered in vivo and in vitro decreased total RNA synthesis with the most marked effect on the synthesis of the heavy RNA components. Actinomycin D or puromycin added in vitro was not toxic: they did not inhibit total fatty acid biosynthesis or glucose utilization by the fat pad nor did they inhibit the immediate stimulation of fatty acid biosynthesis and glucose uptake by the addition of insulin in vitro. Starvation for 48-72 hr significantly depressed the synthesis of the heavy RNA components as measured by in vitro uridine incorporation into the individual RNA classes. Refeeding the fasted rat with glucose repaired the defect in RNA biosynthesis before the biosynthesis of monoenoic fatty acid was completely restored. Actinomycin D administered at the time of refeeding prevented the repair of monoenoic fatty acid synthesis. It is concluded that RNA metabolism is intimately involved in the control of biosynthetic reactions in adipose tissue.