Protein metabolism in senescing wheat leaves : determination of synthesis and degradation rates and their effects on protein loss

Wheat leaves (Triticum aestivum L.) at the moment of their maximum expansion were detached and put in darkness. Their protein, RNA and DNA contents, as well as their rates of protein synthesis and degradation, were measured at different times from 0 to 5 days after detachment. Rates of protein synthesis were measured by incorporation into proteins of large amounts of [³H]leucine. Fractional rates of protein degradation were estimated either from the difference between the rates of synthesis and the net protein change or by the disappearance of radioactivity from proteins previously labeled with [³H]leucine or [¹⁴C]proline.

Protein loss reached a value of 20% during the first 48 hours of the process. RNA loss paralleled that of protein, whereas DNA content proved to be almost constant during the first 3 days and decreased dramatically thereafter.

Measurements of protein synthesis and degradation indicate that, in spite of a slowdown in rate of protein synthesis, an increased rate of protein breakdown is mainly responsible for the observed rapid protein loss.

     

Ribonucleic acid labelling and nucleotide pools during compensatory renal hypertrophy

During the first 48h of compensatory renal hypertrophy induced by unilateral nephrectomy, RNA content per cell increased by 20-40%. During this period, rates of RNA synthesis derived from the rates of labelling of UTP and RNA after a single injection of [5-(3)H]uridine showed no change in the rate of RNA synthesis (3.1nmol of UTP incorporated into RNA/min per mg of RNA). ATP and ADP pools were not changed. The rate of RNA synthesis was considerably in excess of the increment of total RNA appearing in the kidneys. With [5-(3)H]uridine as label, only continuous infusion for 24h could produce an increase (60%) in the specific radioactivity of renal rRNA in mice with contralateral nephrectomies. With a single injection of [methyl-(3)H]methionine used to identify methyl groups inserted into newly synthesized rRNA, the specific radioactivity of this rRNA was unchanged 5h after contralateral nephrectomy, increased by 60% at 9-48h, and returned to normal values at 120h. Most RNA synthesized in both nephrectomized and sham-nephrectomized mice has a short half-life. Since total cellular RNA content increases in compensatory hypertrophy despite unchanged rates of rRNA synthesis, the accretion of RNA might involve conservation of ribosomal precursor RNA or a change in rate of degradation of mature rRNA.     

Stimulation of ribosomal RNA synthesis during hypertrophic growth of cultured heart cells by phorbol ester

Primary cultures of neonatal cardiac myocytes were used to determine the effects of tumor-promoting phorbol esters on ribosomal RNA (rRNA) synthesis during myocyte growth. Treatment of myocytes with phorbol-12,13-dibutyrate (PDBu) increased protein accumulation by 25% and RNA content by 20%. Rates of rRNA synthesis were measured to assess the mechanism by which rRNA accumulated during myocyte growth. Rates of rRNA synthesis were determined from the incorporation of [³H]uridine into UMP of purified rRNA and the specific radioactivity of the cellular UTP pool. After 24h of PDBu treatment, cellular rates of 18S and 28S rRNA synthesis were accelerated by 67% and 64%, respectively. The increased rate of rRNA synthesis accounted for the net increase in myocyte rRNA content after PDBu treatment.     

Control of Chlorophyll Degradation in Detached Leaves of Barley and Oat through Effect of Kinetin on Chlorophyllase Levels

Chlorophyllase seems to be responsible for the degradation of chlorophyll during senescence of detached leaves of barley (Hordeum vulgare) and oat (Avena sativa). Treatment at temperatures higher than 40°C — which protects against chlorophyll loss — lowers the level of chlorophyllase. Kinetin treatment lowers the level of chlorophyllase in barley leaves and prevents its rise in oat leaves after their detachment. Synthesis of proteins in both cytoplasm and chloroplast seems to be required in order to maintain a high level of Chlorophyllase in barley leaves after detachment.     

快速提取、纯化叶绿体4.5SrRNA的方法

我们采用植物叶与热缓冲液、苯酚直接混合(约65℃)匀浆,离心抽提和乙醇沉淀后,得到植物叶总RNA。经聚丙烯酰胺凝胶电泳分离、纯化,即可得到叶绿体4.5S rRNA,此法不仅操作简单,而且得率高。 同时,经过对同一植物的不同组织或不同细胞组分,如根、细胞质、叶绿体和叶绿体核糖体小分子RNA的提取与鉴定,以简便的方法证明了4.5S rRNA是叶绿体核糖体成份,也证明了我们所采用的提取、纯化4.5SrRNA方法的可靠性。     

Protein synthesis by chloroplasts during the senescence of barley leaves

Chloroplasts were isolated from senescent leaf segments of barley ( Hordeum vulgare L. var. Mozoncillo) and assayed for protein synthesis. Protein synthesis activity of the chloroplasts greatly increased after 10–20 h of incubation of leaf segments in the dark in spite of an intense degradation of chloroplast rRNA. The rise in the activity of protein synthesis was more pronounced when kinetin was present in the incubation medium. However, as deduced from SDS-polyacrylamide gel electrophoresis of the products, different proteins were synthesized under the two conditions of incubation of the leaf segments. The activity of protein synthesis of the chloroplasts decreased during the first hours of incubation of the leaf segments in the light.
Cutting and incubation in the dark of the leaf segments enhanced the synthesis of a few proteins also formed by chloroplasts in attached senescing leaves. Hormone and senescence treatments changed the type and the rate of the protein synthesized by chloroplasts, which suggests that hormones may control senescence through a modulation of the protein synthesized by the chloroplasts.     

Isolation of active polyribosomes from the cytoplasm, mitochondria and chloroplasts of Euglena gracilis

1. A procedure is described for the isolation of intact polyribosomes from the cytoplasm, chloroplasts and mitochondria of Euglena gracilis. 2. All three polyribosomal preparations incorporated labelled amino acids in a system in vitro. The cytoplasmic system was inhibited by chcloheximide but not by chloramphenicol. Both the chloroplast and the mitochondrial systems, however, were inhibited by chloramphenicol but not by cycloheximide. It is shown that mitochondrial polyribosomes, like the polyribosomes from cytoplasm and chloroplasts, can participate directly in protein synthesis without supplementary mRNA being added to the synthesizing system, as in previously reported instances. 3. Sedimentation coefficients were measured for the ribosomes, ribosomal subunits, and rRNA of the cytoplasm, chloroplasts and mitochondria. 4. The G+C content was 55% for cytoplasmic rRNA, 50% for chloroplast rRNA, and 29% for mitochondrial rRNA. 5. The cytoplasmic ribosomal subunits contained a ribonuclease activity that was inhibited by heparin.     

Chloroplasts, Kinetin and Protein Synthesis

The effect of kinetin on protein synthesis of isolated chloroplasts was investigated by following the incorporation of ¹⁴C-leucine into isolated chloroplasts from Nicotiana tabacum. The incorporation activity varied greatly during the year, being largest in the winter and smallest in the summer. Conversely, the relative effect of kinetin on the incorporation of ¹⁴C-leucine, whether applied as a pretreatment to the leaves or directly in the incubation medium, was largest in the summer and smallest or absent altogether in the winter. Kinetin did not prolong the net incorporation period, which lasted about 40 min, but only enhanced the initial rate of the reaction. Chloroplasts extracted from leaves that had been detached for 24 or 48 h displayed very little of their original, pre-aged incorporation activity and treating the leaves with kinetin did not, essentially, prevent this loss. It was concluded that the major effect of kinetin upon chloroplasts may be related primarily to an effect upon hydration and permeability of the chloroplast and its membranes, and not to an effect directly upon its machinery for protein synthesis.     

High rates of [1-14C]acetate incorporation into the lipid of isolated spinach chloroplasts.

Spinach chloroplasts, isolated by techniques yielding preparations with high O2- evolving activity, showed rates of light-dependent acetate incorporation into lipids 3-4 fold higher than any previously reported. Incorporation rates as high as 500 nmol of acetate/h per mg of chlorophyll were measured in buffered sorbitol solutions containing only NaHCO3 and [1-14C]acetate, and as high as 800 nmol/h per mg of chlorophyll when 0.13 mM-Triton X-100 was also included in the reaction media. The fatty acids synthesized were predominantly oleic (70-80% of the total fatty acid radioactivity) and palmitic (20-25%) with only minor amounts (1-5%) of linoleic acid. Linolenic acid synthesis was not detected in the system in vitro. Free fatty acids accounted for 70-90% of the radioactivity incorporated and the remainder was shared fairly evenly between 1,2-diacylglycerols and polar lipids. Oleic acid constituted 80-90% of the free fatty acids synthesized, but the diacylglycerols and polar lipids contained slightly more palmitic acid than oleic acid. Triton X-100 stimulated the synthesis of diacylglycerols 3-6 fold, but stimulated free fatty acid synthesis only 1-1.5-fold. Added glycerol 1-phosphate stimulated both the synthesis of diacylglycerols and palmitic acid relative to oleic acid, but did not increase acetate incorporation into total chloroplast lipids. CoA and ATP, when added separately, stimulated acetate incorporation into chloroplast lipids to variable extents and had no effect on the types of lipid synthesized, but when added together resulted in 34% of the incorporated acetate appearing in long-chain acyl-CoA. Pyruvate was a much less effective precursor of chloroplast fatty acids than was acetate.     

Chloroplasts Isolated from Kidney Bean Leaves Are Capable of Phenolic Compound Biosynthesis

The homogenate and chloroplast fractions isolated from the leaves of 10–14-day-old kidney-bean (Phaseolus vulgaris L.) seedlings were incubated with ¹⁴C-L-phenylalanine for 30 min in the light, and the incorporation of radioactivity into phenolic compounds was determined. Label incorporation into phenolic compounds of the homogenate and chloroplast fractions amounted to 15–17 and 4–5% of the introduced radioactivity, respectively. The chloroplasts were about an order of magnitude higher than the homogenate in the specific radioactivity of phenolic compounds. Chloroplasts contained four flavonol glycosides (kaempferol and quercetin aglycones), which were the major components of soluble phenolic compounds of leaves. It was concluded that kidney-bean leaf chloroplasts were capable of performing phenolic compound biosynthesis.     

Photosynthetic apparatus of chilling-sensitive plants. X. Relationship between superoxide dismutase activity and photoperoxidation of chloroplast lipids

(1) The rate of photoperoxidation of chloroplast lipids, as measured by malondialdehyde formation following the illumination of either leaves or chloroplast preparations, is found to be approx. 2-fold higher in chloroplasts from both cold- and dark-stored as well as stored and illuminated tomato leaves than in those from fresh leaves. (2) Enhanced lipid photoperoxidation can also be observed in chloroplasts from fresh leaves treated with cyanide as well as in superoxide dismutase-depleted chloroplasts following washing with Tris or Hepes. (3) Cyanide-sensitive superoxide dismutase activity is not detected in chloroplasts isolated from cold- and dark-stored leaves. Their illumination does not reactivate the enzyme activity. (4) On the basis of these observations, it is concluded that inactivation of chloroplast cyanide-sensitive superoxide dismutase due to cold and dark treatment of leaves, rather than diminished electron transport, is responsible for accelerated chloroplast lipid photoperoxidation.     

Intracellular site of sucrose synthesis in leaves

Improved conditions for extraction and assay increased rates of sucrose synthesis from uridine diphosphate glucose (UDPglucose) plus fructose 6-phosphate (F.6.P) catalysed by leaf extracts 20-fold. Rates of 17.9, 25·0, 9·2 and 27·7 μmol/hr/g fr. wt respectively were obtained from pea shoots, spinach, wheat and bean leaves. Chloroplasts isolated from pea shoots, in which half the plastids were intact, contained less than 4% of the total UDPglucose-fructosephosphate glucosyltransferase, more than 30% of the ribulose diphosphate (RuDP) carboxylase, and more than 40% of the total chlorophyll of the leaf. Although some of the UDPglucose-fructose-phosphate glucosyltransferase was associated with particles smaller than chloroplasts at least 85% of the enzyme was not precipitated at 38 000 g. UDPglucose pyrophosphorylase, also thought to be essential for sucrose synthesis, was distributed between the cell fractions in a similar manner to UDPglucose-fructosephosphate glucosyltransferase. It is concluded that sucrose synthesis in pea shoots and spinach leaves occurs mainly, in the cytoplasm.     

Changes in the Number and Composition of Chloroplasts during Senescence of Mesophyll Cells of Attached and Detached Primary Leaves of Wheat (Triticum aestivum L.)

Changes in the number and composition of chloroplasts of mesophyll cells were followed during senescence of the primary leaf of wheat (Triticum aestivum L.). Senescence was due to the natural pattern of leaf ontogeny or was either induced by leaf detachment and incubation in darkness, or incubation of attached leaves in the dark. In each case discrete sections (1 centimeter) of the leaf, representing mesophyll cells of the basal, middle, and tip regions, were examined. For all treatments, senescence was characterized by a loss of chlorophyll and the protein ribulose 1,5-bisphosphate carboxylase (RuBPCase). Chloroplast number per mesophyll cell remained essentially constant during senescence. It was not until more than 80% of the plastid chlorophyll and RuBPCase was degraded that some reduction (22%) in chloroplast number per mesophyll cell was recorded and this was invariably in the mesophyll cells of the leaf tip. We conclude that these data are consistent with the idea that degradation occurs within the chloroplast and that all chloroplasts in a mesophyll cell senesce with a high degree of synchrony rather than each chloroplast senescing sequentially.     

Gas exchange in paphiopedilum: lack of chloroplasts in guard cells correlates with low stomatal conductance

Net photosynthesis and stomatal conductance were measured in attached leaves of Paphiopedilum insigne. At 20°C and a vapor-pressure deficit of 0.5 kilopascal, both net photosynthesis and stomatal conductance were light-saturated below 0.2 millimole per square meter per second, a response typical of shade plants. The absolute values of photosynthetic rate and conductance however were remarkably low, presumably reflecting an adaptation to the low-light, limited-nutrient habitat characteristic of these orchids. The leaves also showed a vapor-pressure deficit response, with net photosynthesis and conductance varying over a 2-fold range between 0.3 and 1.6 kilopascals.

These results confirm that Paphiopedilum stomata are functional. The correlation between achlorophyllous guard cells and low conductance rates, however, singles them out as an exceptional biological system, exhibiting basic differences from typical stomata in higher plants. Available evidence showing that guard-cell chloroplasts are needed to sustain high conductance rates at moderate to high irradiances indicates that the genetic changes leading to the loss of chloroplast differentiation in Paphiopedilum guard cells were not deleterious because of the low conductance rates characteristic of this genus.

     

On the control of long-chain-fatty acid synthesis in isolated intact spinach (Spinacia oleracea) chloroplasts

1. Chloroplasts isolated from spinach leaves by using the low-ionic-strength buffers of Nakatani & Barber [(1977) Biochim. Biophys. Acta.461, 510-512] had higher rates of HCO(3) (-)-dependent oxygen evolution (up to 369mumol/h per mg of chlorophyll) and higher rates of [1-(14)C]acetate incorporation into long-chain fatty acids (up to 1500nmol/h per mg of chlorophyll) than chloroplasts isolated by using alternative procedures. 2. Acetate appeared to be the preferred substrate for fatty acid synthesis by isolated chloroplasts, although high rates of synthesis were also measured from H(14)CO(3) (-) in assays permitting high rats of photosynthesis. Incorporation of H(14)CO(3) (-) into fatty acids was decreased by relatively low concentrations of unlabelled acetate. Acetyl-CoA synthetase activity was present 3-4 times in excess of that required to account for rates of [1-(14)C]acetate incorporation into fatty acids, but pyruvate dehydrogenase was either absent or present in very low activity in spinach chloroplasts. 3. Rates of long-chain-fatty acid synthesis from [1-(14)C]acetate in the highly active chloroplast preparations, compared with those used previously, were less dependent on added cofactors, but showed a greater response to light. The effects of added CoA plus ATP, Triton X-100 and sn-glycerol 3-phosphate on the products of [1-(14)C]acetate incorporation were similar to those reported for less active chloroplast preparations. 4. Endogenous [(14)C]acetyl-CoA plus [(14)C]malonyl-CoA was maintained at a constant low level even when fatty acid synthesis was limited by low HCO(3) (-) concentrations. Endogenous [(14)C]acyl-(acyl-carrier protein) concentrations increased with increasing HCO(3) (-) concentration and higher rates of fatty acid synthesis, but were slightly lower in the presence of Triton X-100. It is proposed that rates of long-chain-fatty acid synthesis in isolated chloroplasts at saturating [1-(14)C]acetate concentrations and optimal HCO(3) (-) concentrations may be primarily controlled by rates of removal of the products of the fatty acid synthetase.     

Changes in the Number and Size of Chloroplasts during Senescence of Primary Leaves of Wheat Grown under Different Conditions

Changes in the number and size of chloroplasts in mesophyllcells were investigated in primary leaves of wheat from fullexpansion to yellowing under different growth conditions. Thenumber of chloroplasts per cell decreased slowly, although thedecrease was steady and statistically significant, until thelast stage of leaf senescence, when rapid degradation of chloroplaststook place. Rates of leaf senescence, or the decline in thenumber of chloroplasts, varied greatly among plants grown atdifferent seasons of the year, but about 20% of chloroplastsalways disappeared during the phase when steady loss of chloroplastsoccurred. The area of chloroplast disks also decreased graduallybut significantly, with a rapid decrease late in senescence.Thus, the total quantity of chloroplasts per mesophyll celldecreased substantially during leaf senescence. Yellowed leavescontained numerous structures that resemble oil drops but nochloroplasts. Decreases in rates of photosynthesis that occurduring senescence may, therefore, be largely due to decreasesin the quantity of chloroplasts. However, a better correlationwas found between the decrease in the maximum capacity for photosynthesisand the degradation of RuBP carboxylase. When plants had beengrown with a sufficient supply of nutrients, the number of chloroplastsdecreased steadily but at a reduced rate and the reduction inthe area of chloroplast disks was strongly suppressed. Thus,the quantitative decrease in chloroplasts in senescing leavesappears to be regulated by the requirements for nutrients (nitrogen)of other part of the plant. ³Present address: Department of Biology, Faculty of Science,Toho University, Miyama, Funabashi, Chiba, 274 Japan     

Accelerated rates of ribosomal RNA synthesis during growth of contracting heart cells in culture

Contractile activity of neonatal cardiac myocytes stimulated hypertrophic growth as compared with nonbeating cells that were depolarized with 50 mM KCl. Growth of contracting myocytes was associated with an increased rRNA content as measured by the total RNA/DNA ratio. The fractional rates of rRNA synthesis (K8) and rRNA degradation were determined in contracting and nonbeating myocytes to assess their relative contributions in increasing rRNA content during growth. The values for K8 were calculated from the specific radioactivity of 3'-[3H]UMP in 18 and 28 S rRNA after purification by hybridization to cloned rDNA. The cellular [3H]UTP pool served as the precursor for rRNA synthesis in myocytes that were labeled with 50 microM [3H]uridine. K8 values for 18 and 28 S rRNA in contracting myocytes were accelerated by 59 and 53%, respectively, after 3 days as compared with nonbeating myocytes. Calculations of the rate of cellular rRNA synthesis, which took into account the increased content of myocyte rRNA, revealed that synthesis of both 18 and 28 S rRNA was accelerated 2-fold after 2 days of contraction. The derived values for degradation of 18 and 28 S rRNA were increased marginally in contracting myocytes, but cellular rRNA degradation rates averaged 57% higher. The difference between cellular rates of rRNA synthesis and degradation in contracting myocytes accounted for the 30% increase in rRNA content. These data demonstrated that increased rRNA content in contracting myocytes resulted from acceleration of the fractional rate of rRNA synthesis.     

A Nuclear Mutation in Nicotiana sylvestris Causing a Thiamine-Reversible Defect in Synthesis of Chloroplast Pigments

We report the recovery of a nuclear recessive mutation in Nicotiana sylvestris (Spegazzini and Comes) producing a conditional disruption in the pathway for synthesis of chlorophyll a and b and carotenoids which is fully reversible by exogenous thiamine (0.3 micromolar). In the absence of supplemental thiamine, chlorophyll levels declined by 50% after 5 days, and fell to undetectable levels by 11 days. Mitochondrial (KCN sensitive) respiration rates remained normal in albino leaves (80% loss of chlorophyll), suggesting that chlorosis results primarily from a deficiency of thiamine in the chloroplasts. After thiamine removal, mutant plants produced at least 10 albino leaves with a substantial capacity for growth (0-15 centimeters; 70-fold increase in area), demonstrating sustained operation of many cellular functions in spite of chloroplast disruption. Activities of the plastid isozymes of phosphoglucomutase and phosphoglucoisomerase in albino leaves indicated that the decline in pigment synthesis does not result from a general loss of metabolic activity in chloroplast. Plastid pyruvate dehydrogenase from mutant and wild-type plants displayed a similar affinity for thiamine pyrophosphate, showing that chlorosis does not result from an alteration in this enzyme. Growth of albino leaves and ultrastructural evidence for thylakoid membranes in the chloroplasts suggest that a certain level of fatty acid synthesis is maintained after the interruption of pigment synthesis. Since thiamine deprivation is expected to block production of acetyl-coenzyme A from pyruvate by pyruvate dehydrogenase, acetyl-coenzyme A supporting fatty acid synthesis in albino leaves may be derived solely from mitochondrial acetate.     

Role of protein degradation in the growth of livers after a nutritional shift.

Fractional rates of synthesis and degradation of liver porteins were estimated during the rapid restoration of liver mass observed in protein-depleted mice when they are fed with an adequate diet. 1. Net protein gain was fastest 12h after the nutritional shift, when it reached a rate of 48% per day. 2. The RNA/protein ratio in livers of protein-depleted animals was essentially the same as in normal livers; it increased by a maximum of 13% 12h after the nutritional shift. 3. Rates of protein synthesis in vivo were measured by the incorporation into liver protein of massive amounts of L-[1-14C]leucine. In protein-depleted animals, the rate of synthesis per mg of RNA was 72% of that in normal livers. Normal rates were recovered within 12h of the nutritional shift. 4. The fraction of newly synthesized protein retained by the liver was studied after they were pulse-labelled by the intravenous injection of radioactive leucine, and, 5 min later, pactamycin (an inhibitor of the initiation of protein synthesis); 3h later the livers in both experimental situations retained 58% of the newly synthesized protein. 5. Fractional rates of protein degradation were estimated either from the difference between the synthesis of stable liver proteins and the net protein increase, or by the disappearance of radioactivity from the liver protein previously labelled by the administration to the mice of NaH14CO3. Both procedures demonstrated a large decrease in the rate of protein degradation during liver growth.     

Rates and products of long-chain Fatty Acid synthesis from [1-C]acetate in chloroplasts isolated from leaves of 16:3 and 18:3 plants

Chloroplasts highly active in the synthesis of long-chain fatty acids from [1-¹⁴C]acetate were prepared from leaves of Solanum nodiflorum, Chenopodium quinoa, Carthamus tinctorius, and Pisum sativum. These preparations were used to test whether the various additions to incubation media found to stimulate the synthesis of particular lipid classes in vitro by Spinacia oleracea chloroplasts were applicable generally. Chloroplasts from 18:3 plants incorporated a greater proportion of radioactivity into unesterified fatty acids under control conditions than did those from 16:3 plants. Supplying exogenous sn-glycerol 3-phosphate or Triton X-100 to chloroplasts increased the synthesis of glycerolipids in all cases and accentuated the capacity of chloroplasts from 18:3 plants to accumulate phosphatidic acid rather than the diacylglycerol accumulated by chloroplasts from 16:3 plants. The UDP-galactose-dependent synthesis of labeled diacylgalactosylglycerol was much less active in incubations of chloroplasts from 18:3 plants also containing sn-glycerol 3-phosphate and Triton X-100 compared with similar incubations from 16:3 plants. Exogenous CoA stimulated total fatty acid synthesis in all chloroplast preparations and the further addition of ATP diverted radioactivity from the unesterified fatty acid to acyl-CoA. The results have been discussed in terms of the two pathway hypothesis for lipid synthesis in leaves.