Time course and cellular site of mitotic activity in the exocrine pancreas of the rat during sustained hormone stimulation

Summary Previous studies from our laboratory indicate that the adaptive response of the exocrine pancreas of the rat to prolonged stimulation with optimal doses of caerulein (0.25 g × kg^-1 × h^-1) follows a characteristic time course in which each step in the secretory pathway is activated. The immediate response is the depletion of zymogen-granule stores followed by coordinate and anticoordinate changes in individual rates of (pro-)enzyme synthesis after a lag period of 2 h. The sum of such changes leads to an increase in total rate of protein synthesis by 3 h which is combined with acceleration of intracellular transport packaging and granule discharge. In the present study the time course of DNA synthesis and the labeling index of five populations of pancreatic cells have been analyzed after caerulein stimulation for periods ranging from 6 to 72 h, using in vivo labeling with 1 Ci/g ³H-thymidine 1 h prior to sacrifice of the animals. DNA synthesis did not change during the initial 18 h in spite of persistent stimulation indicated by a 80% reduction of enzyme content. Following this lag period a sharp rise in DNA synthesis 20- to 25-fold above control levels was observed, which decreased by 48 h to reach control levels by 72 h. Increase in DNA synthesis was most pronounced in animals with lowest enzyme content in the pancreas. From the five cell populations studied by autoradiography interlobular duct cells and islet cells had no significant increase in labeling index at any time of stimulation. Acinar cells, intralobular duct cells and interstitial cells showed a marked increase in labeling index after a latent period of 18 h with peak values at 36 h 30 to 50 times higher in intralobular duct and acinar cells, respectively, and 4 times higher in interstitial cells. The increased labeling indices in all three cell populations reverted to lower values at 48 h and reached control values by 72 h. The data indicate a phasic and limited growth response of the rat exocrine pancreas to persistent stimulation with acinar cells as the major contributing cell population.Supported by a grant from Deutsche Forschungsgemeinschaft (SFB215-C 3)     

Studies on intracellular transport of secretory proteins in the rat exocrine pancreas

Summary Prolonged secretory stimulation of the exocrine pancreas in the rat by in vivo infusion of caerulein leads to a rapid degranulation of the organ associated with a progressive reduction in the size of the zymogen granules. During the first six to twelve hours of stimulation Golgi complexes are enlarged and several structural forms of multivesicular bodies are found indicating a lysosomal degradation of membrane material in the Golgi area. Maximum secretory activity is obtained after a 24 hour infusion, Golgi complexes appear fragmented, the secretory granules measure only 1/3 to 1/4 their normal size. Thereafter, in spite of a continuous stimulation, the exocrine cells regranulate progressively up to 72 hours of infusion. This regranulation is associated with massive enlargement of the Golgi complexes.The phasic adaptation of the exocrine pancreas to prolonged stimulation, concluded from the structural studies, was confirmed by biochemical analysis of protein synthesis, intracellular transport and enzyme discharge. Pancreatic protein synthesis as measured by the incorporation of tritiated leucine remained unchanged during the first six hours of stimulation, then increased reaching a maximum of 230% of the control levels after 24 hours of infusion. After 48 and 72 hours the rate of protein synthesis decreased again to normal values. Most pronounced changes were observed in the kinetics of intracellular transport of newly synthesized proteins. Using pulse-chase incubation of prestimulated pancreatic lobules, the rate of transition of secretory proteins through the cell increased consistently with prolonged infusion periods reaching maximal acceleration after 24 hours. Newly synthesized proteins were transported and segregated up to ten times faster than in controls. After a maximum at 24 hours transport returned to normal rates after 72 hours of infusion. Enzyme secretion, measured for amylase, followed a similar pattern of stimulation.The results suggest a phasic adaptation of the exocrine pancreatic cell to prolonged stimulation. They demonstrate for the first time the possibility of an acceleration of intracellular transport by means of secretagogues.Dedicated to Professor W. Bargmann on the occasion of his 70th birthday.Supported by a grant from Deutsche Forschungsgemeinschaft (Ke 113/8). A preliminary communication was presented at the 9th annual meeting of the European Society for Clinical Investigation, Rotterdam (April 24–26, 1975). The expert technical assistance of Miss Helga Hollerbach and Miss Hiltraud Hosser is gratefully acknowledged.     

In-vivo stimulation of rat pancreatic acinar cells by infusion of secretin

Infusion of synthetic secretin in conscious unrestricted rats for periods up to 24 h was used to study the structural and functional adaptation of pancreatic acinar cells to this secretagogue. Initial dose-response studies established 16 clinical units (CU) per kg and h (corresponding to 4.64 micrograms X kg-1 X h-1) as optimal dose for persistent stimulation of enzyme discharge. Infusion of this dose led to a slow but progressive depletion of enzyme stores with minimal content by 12 h stimulation. As a result of persistent stimulation total protein synthesis in the acinar cells increased after a lag period of 3 h and reached maximal values 90% above controls by 6 and 12 h secretin infusion. No structural equivalent for pronounced fluid and bicarbonate secretion was observed for either acinar or duct cells over the entire dose range (1 to 64 CU X kg-1 X h-1) and infusion period (1-24 h), except an increased number of coated vesicles in duct cells. Discharge of enzymes from acinar cells was paralleled by a high frequency of exocytotic images at the luminal plasma membrane and was accompanied by the occurrence of membrane fragments in the luminal space, especially after 3 and 6 h secretin infusion. An increased number of lysosomal bodies at these time points especially in the vicinity of the Golgi complex was interpreted in relation to membrane recycling following massive exocytosis. This pattern of structural and functional adaptation of acinar cells following secretin infusion corresponds to previously described changes following caerulein and carbamylcholine stimulation.     

Anabolic Effect of Natural and Synthetic Antioxidants

The order of responses of cell systems of organs and the changes in the content of some proteins in mouse and dog blood in response to addition of natural (-tocopherol) and synthetic (ionol) antioxidants was studied at the whole-body level using ERP spectroscopy, radioisotope analysis, and chemiluminescence technique. Responses were evaluated by the temporary and concentration-dependent changes in the activity of ribonucleotide reductase and the rate of protein and DNA synthesis in organs of the mouse, as well as by the changes in the pools of Fe³⁺-transferrin and Cu²⁺-ceruloplasmin in blood and the antiradical activity of blood plasma of the dog and mouse. During the first 24 h of exposure to -tocopherol, the activity ribonucleotide reductase in the bone marrow rapidly increased, whereas the activity of this enzyme and the rate of DNA synthesis in the thymus and spleen were suppressed by 30–50% compared to the control. The changes in these parameters had a phase mode with maxima on days 2–3 and 6–8. The stimulatory effect of the antioxidant on the processes of synthesis was concentration-dependent. We found that the optimal stimulation of the synthesis of deoxyribonucleotides, DNA, and protein was achieved by single administration of -tocopherol at a dose of 20 mg per dog with an average weight of 15 kg and 17 mg/kg in the case of mice. Single or repeated administration of higher doses of -tocopherol was either ineffective or even suppressed the synthesis of DNA and deoxyribonucleotides. Ionol administered at a dose of 60 mg/kg increased DNA and protein synthesis in mouse organs 2–4 and 1.2–1.5 times, respectively, compared to the control. It was also shown that single and repeated administration of -tocopherol to dogs increased the pool of Fe³⁺-transferrin and Cu²⁺-ceruloplasmin in blood 2–3 times and by 20–30%, respectively, compared to the control. It is suggested to use changes in Fe³⁺-transferrin pool in peripheral blood for evaluation of the stimulatory effect of antioxidants on the synthesis of macromolecules in organs and for the determination of dependence of this effect on the concentration of antioxidants.     

Stimulation of pancreatic secretory process in the rat by low-molecular weight proteinase inhibitor

Summary Previous studies with rats have shown that a single oral dose of the proteinase inhibitor Camostate (FOY-305) induces release of cholecystokinin (CCK) into the circulation, which lasts for 3 to 6h. This transient endogenous release of hormone results in a depletion of pancreatic enzyme stores within 1 h and an increase in total rate of protein synthesis, which peaks at 6 to 9 h. At the level of individual enzyme biosynthesis a transient decrease in amylase and an increase in trypsinogen and chymotrypsinogen is observed. In the present study the time course of DNA synthesis and the labeling index of 5 populations of pancreatic cells have been analysed following a single oral dose of 50 or 100 mg/kg proteinase inhibitor, using in vivo labeling with 12 Ci/g body weight ³H-thymidine 1 h prior to sacrifice of the animals. DNA synthesis did not change during the initial 12 h following inhibitor feeding and then showed a phasic increase with a peak (20-fold) at 24h and intermediate increases (4- to 5-fold) at 18 and 36 h, respectively. From the 5 pancreatic cell populations studied by autoradiography the labeling indices of interlobular duct cells and islet cells did not change over the entire observation period. Acinar cells, intralobular duct cells and interstitial cells showed a marked increase in labeling index with peak values at 24h, which were 20-fold in acinar cells and 5.5- and 8.5-fold in intralobular duct cells and interstitial cells, respectively. The data demonstrate a significant growth response of pancreatic acinar tissue after a single episode of endogenous CCK-release, which is similar in extent, time course and cellular source as previously demonstrated during persistent stimulation of the pancreas by prolonged infusion of the CCK-analogue caerulein.     

Time dependent effect of indomethacin on the stimulation of protein synthesis in isolated rabbit muscle by insulin

Insulin (100 U/ml) stimulated protein synthesis and PGF₂ release in isolated rabbit muscle, but had little effect on the rate of protein degradation. The effect of insulin persisted for at least 5 h after removal of the hormone. Indomethacin, added at the start of the incubation, inhibited the stimulatory effect of insulin on protein synthesis and PGF₂ release, but did not block the binding of iodinated insulin. When added 2 h after insulin, indomethacin did not inhibit the stimulation of protein synthesis but completely inhibited the increase in PGF₂ release. The results suggest that the stimulation of protein synthesis by insulin is mediated by metabolites of membrane phospholipids but that these changes are involved during the phase of response that immediately follows the binding of insulin to its receptor.     

In-vivo stimulation of rat pancreatic acinar cells by infusion of secretin

Summary Infusion of synthetic secretin in conscious unrestricted rats for periods up to 24 h was used to study the structural and functional adaptation of pancreatic acinar cells to this secretagogue. Initial dose-response studies established 16 clinical units (CU) per kg and h (corresponding to 4.64 ug x kg^-1 x h^-1) as optimal dose for persistent stimulation of enzyme discharge. Infusion of this dose led to a slow but progressive depletion of enzyme stores with minimal content by 12 h stimulation. As a result of persistent stimulation total protein synthesis in the acinar cells increased after a lag period of 3 h and reached maximal values 90% above controls by 6 and 12 h secretin infusion. No structural equivalent for pronounced fluid and bicarbonate secretion was observed for either acinar or duct cells over the entire dose range (1 to 64 CU x kg^-1 x h^-1) and infusion period (1–24 h), except an increased number of coated vesicles in duct cells.Discharge of enzymes from acinar cells was paralleled by a high frequency of exocytotic images at the luminal plasma membrane and was accompanied by the occurrence of membrane fragments in the luminal space, especially after 3 and 6 h secretin infusion. An increased number of lysosomal bodies at these time points especially in the vicinity of the Golgi complex was interpreted in relation to membrane recycling following massive exocytosis. This pattern of structural and functional adaptation of acinar cells following secretin infusion corresponds to previously described changes following caerulein and carbamylcholine stimulation.Supported by a grant from Deutsche Forschungsgemeinschaft (Ke 113/15-1)     

Protein turnover in the attached leaves of non-stressed and stressed barley seedlings

Protein turnover was examined, using tritiated water, in various 2-cm regions of 7-11-d-old, first leaves of barley (Hordeum vulgare). Differences were found between the regions in their protein turnover and their responses to stress. The rate constant for degradation for total protein was the same throughout the leaf and the average half-life (t_1/2) of protein=approx. 220 h. Only in the older regions did a 24-h pulse of³H₂O preferentially label protein with a t_1/2 (90 h) considerably shorter than the t_1/2 for total protein. Soluble protein was degraded faster than insoluble protein and contained an appreciable short-lived protein component observable by short-pulse labelling. The rate of protein synthesis was greatest in the cells of the youngest region and declined as each region aged. The mean rate of protein synthesis over the 4-d period was 4 and 7 nmol h^-1 of amino-N with respect to the regions 1–3 and 7–9 cm from the leaf tip. Seedlings, stressed by adding polyethylene glycol (2.0 MPa) to the roots, showed a marked loss of protein from the older leaf regions with only small losses in the younger regions. Amino acids accumulated in the younger region continuously whereas in the older region little accumulation occurred until day 3 of stress when proline levels increased. Protein synthesis was decreased by between 30% and 50% in all leaf regions. In the region 1–3 cm from the leaf tip, the rate of protein degradation of total protein was enhanced and equalled the rate of degradation of 24-h-pulse-labelled protein which was not itself significantly affected by stress (t_1/2=approx. 90 h). In the region 3–5 cm, the degradation of both 4-d and 24-h-labelled protein was enhanced by stress to rates similar to those found in the region 1–3 cm. This was largely through increases in the degradation of the insoluble protein, but the degradation of soluble protein was also raised. Protein degradation in the region 7–9 cm was not affected by stress.Abbreviations t_1/2 average half-life - PEG polyethylene glycol     

Pretraining but not Preexposure to the Task Apparatus Prevents the Memory Impairment Induced by Blockade of Protein Synthesis,PKA or MAP Kinase in Rats

Adult male Wistar rats were trained and tested in a step-down inhibitory avoidance task (0.4 mA footshock, 24 h training-test interval). Fifteen minutes before or 0, 1.5 or 3 hours after training, animals received a 0.8 l intrahippocampal infusion of the protein synthesis inhibitor anisomycin (80 g), the PKA inhibitor Rp-cAMP (0.05 g), the MAPK kinase inhibitor PD 098059 (50 M solution) or vehicle (phosphate buffer in saline, pH 7.4). Anisomycin, Rp-cAMP and PD 098059 impaired retention test performance in animals injected at different times, prior and after training. Pretraining with a low footshock intensity (0.2 mA) 24 h before training prevented the amnestic effect of all drugs studied. However, simple preexposure to the inhibitory avoidance apparatus did not alter the amnestic effects of all drugs. The results suggest that memory processing requires hippocampal mechanisms dependent on protein synthesis, PKA and MAPK kinase at different times after training. These findings suggest that weak training must be sufficient to produce some lasting cellular expression of the experience so that the enhancement of consolidation of a previously acquired memory is not dependent on protein synthesis, PKA or MAPK.     

Brief fasting decreases protein synthesis in the brain of adult rats

The influence of starvation on protein synthesis in the adult rat brain was studied in vivo by an intravenous injection of a flooding dose of unlabeled valine including a tracer dose ofL-[3,4(n)-³H]valine. Brief starvation (24 hours) induced a 20% decline in fractional and absolute rates of brain protein synthesis. This decline resulted from a 20% decrease in the efficiency of protein synthesis (g protein synthesized per day per g RNA) whereas the capacity for protein synthesis (g RNA per mg protein) was maintained. Prolonged starvation (5 days) was marked by no further significant changes in the fractional rate, absolute rate and efficiency of protein synthesis, whereas the capacity for protein synthesis cecreased slightly. The relative contribution of brain to wholebody body protein synthesis increased during fasting, and neither the protein nor the RNA brain content did change during the experiment. These results clearly indicate that brain proteins are spared in response to brief and prolonged food deprivation, and that brain protein synthesis is very sensitive to short-term fasting.     

Cyclic stretch induces the release of growth promoting factors from cultured neonatal cardiomyocytes and cardiac fibroblasts

Growth factors and hormones may play an autocrine/paracrine role in mechanical stress-induced cardiac hypertrophy. Using an in vitro model of mechanical stress, i.e. stretch of cardiomyocytes and cardiac fibroblasts, we tested the involvement of growth factors and hormones in this process.We found that conditioned medium (CM) derived from 4 h cyclicly (1 Hz) stretched cardiomyocytes increased the rate of protein synthesis in static cardiomyocytes by 8 ± 3%. Moreover, CM derived from 2 h stretched fibroblasts increased the rate of protein synthesis in static fibroblasts as well as in static cardiomyocytes by 8 ± 2 and 6 ± 2%, respectively. Analysis of CM using size-exclusion HPLC showed that cardiomyocytes and fibroblasts released at least three factors with MW 10 kD, their quantities being time-dependently increased by stretch. Subsequent analyses using immunoassays revealed that cardiomyocytes released atrial natriuretic peptide (ANP) and transforming growth factor-beta1 (TGF₁) being increased by 45 ± 17 and 21 ± 4% upon 4 h of stretch, respectively. Fibroblasts released TGF₁ and very low quantity of endothelin-1 (ET-1). The release of TGF₁ was significantly increased by 18 ± 4% after 24 h of stretch in fibroblasts. Both cell types released no detectable amount of angiotensin II (Ang II).In conclusion, upon cyclic stretch cardiomyocytes and fibroblasts secrete growth factors and hormones which induce growth responses in cardiomyocytes and fibroblasts in an autocrine/paracrine way. TGF secreted by cardiomyocytes and fibroblasts, and ANP secreted by cardiomyocytes are likely candidates. We found no evidence for the involvement of Ang II and ET-1 in autocrine/paracrine mechanisms between cardiac cell types.     

Oxidative enzymes in the pancreatic islets of normal and obese-hyperglycemic mice

Summary Histochemical data are presented concerning distributions of succinic dehydrogenase (SD), lactic dehydrogenase (LD), diphosphopyridine nucleotide diaphorase (DPND), triphosphopyridine nucleotide diaphorase (TPND) and glucose-6-phosphate dehydrogenase (G-6-PD) in the pancreas from the American variety of obese-hyperglycemic mice (AO-mice) and their lean litter mates (AN-mice).A high LD activity was found in the exocrine parenchyma, while the reaction in the islet tissue and the duct epithelium was only weak. A considerable reaction for DPND was noted throughout the pancreas. SD activity was slightly more pronounced in the acinar tissue and duct epithelium as compared to the islet tissue, where only a moderate activity appeared. Strong reactions for TPND and G-6-PD were found in the islet cells and duct epithelium, while the activity in the exocrine parenchyma was less pronounced. The hyperactive islet B cells in the AO-mice showed no obvious differences in enzyme activity and distribution compared to that of the AN-mice. The enzyme pattern of the A cells could not be clearly distinguished from that in the B cells.The results suggest the existence at least in the B cells of the mice islet tissue of an active hexosemonophosphate shunt. The probable significance of the hexosemonophosphate shunt for insulin synthesis is briefly discussed.The following abbreviations are used DPN Diphosphopyridine nucleotide - DPND Diphosphopyridine nucleotide diaphorase - DPNH Diphosphopyridine nucleotide, reduced form - EM Embden-Meyerhof - G-6-PD Glucose-6-phosphate dehydrogenase - HMP Hexose monophosphate - LD Lactic dehydrogenase - MTT 3,5-diphenyl-2-(4,5-dimethyl-thiazol-2-yl) tetrazolium bromide - Nitro-BT 2,2-di-p-nitrophenyl-5,5-diphenyl-3,3-(3,3-dimethoxy-4,4-biphenylene)-ditetrazolium chloride - PVP Polyvinyl pyrrolidone (M. W. 11 000) - SD Succinic dehydrogenase - TPN Triphosphopyridine nucleotide - TPND Triphosphopyridine nucleotide diaphorase - TPNH Triphosphopyridine nucleotide, reduced form     

Starvation is associated with changes in the elemental composition of the pancreatic β-cell

By using the proton microprobe technique we have investigated the elemental composition of both pancreatic -cells and exocrine pancreas from fed and 24 h or 48 h starved obese hyperglycemic mice. Among the 15 elements measured in the -cells both Ca and Fe increased while Mg and S decreased significantly after 24 h of starvation, the effects being more pronounced after 48 h. When animals were starved for 48 h there was a decrease in the contents of Cl, Rb and Cu, whereas that of Al and Mn increased with 152 and 55%, respectively. There was an initial decrease in Na after 24 h of starvation, which was followed by an increase after 48 h. This is in contrast to Cd, which first increased and then decreased to a value lower than that obtained in the fed animal. The content of K showed a small decrease and that of Pb showed an increase only in the 24 h starved group. In the -cells the contents of Zn and P did not change subsequent to starvation. In the exocrine pancreas Na, Cl and P decreased after 24 h of starvation and except for Na, the decrease was maintained when the starvation period was increased to 48 h. After 24 h there was a significant, though transient, increase in K, Mg and Rb. With regard to the contents of Zn, Cu and S there was a progressive decrease as the starvation continued. In contrast to the endocrine pancreas the content of Al in the exocrine pancreas did not change after 48 h of starvation. There was no change in islet insulin content subsequent to starvation. The extent to which the observed changes in -cell elemental composition is involved in the impaired insulin release associated with starvation, merits further investigations.     

The role of glutamate in the locus coeruleus during opioid withdrawal and effects of H-7, a protein kinase inhibitor, on the action of glutamate in rats

To investigate the role of glutamate in the locus coeruleus (LC) during opioid withdrawal, rats were continuously infused with morphine (a -opioid receptor agonist, 26 nmol/µl/h) or butorphanol (a //-mixed opioid receptor agonist, 26 nmol/µl/h) intracerebroventricularly (i.c.v.) via osmotic minipumps for 3 days. A direct LC injection of glutamate (1 or 10 nmol/5 µl) or naloxone (an opioid receptor antagonist, 24 nmol/5 µl) induced withdrawal signs in morphine- or butorphanol-dependent animals. However, these agents failed to precipitate any withdrawal signs in saline-treated control animals. On the other hand, the expression of withdrawal signs precipitated by the administration of glutamate or naloxone in opioid-dependent animals was completely blocked by concomitant infusion with 1 or 10 nmol/µl/h of an inhibitor of adenosine 3,5-cyclic monophosphate (cAMP)-dependent protein kinase and protein kinase C, H-7 [1-(5-isoquinolinesulfonyl)-2-methylpiperazine]. In animals that had been infused with opioids in the same manner, i.c.v. injection of naloxone (48 nmol/5 µl) precipitated withdrawal signs and increased extracellular fluid levels of glutamate in the LC of morphine- or butorphanol-dependent rats measured by in vivo microdialysis method. However, concomitant infusion with H-7 inhibited the increases of glutamate levels in the LC. These results strongly suggest that an expeditious release of glutamate in the LC region plays an important role in the expression of physical dependence on opioids. Furthermore, the action on glutamate release might be increased by the enhancement of cAMP-dependent protein kinase and/or protein kinase C activity.     

Ethanol alters astrocyte development: A study of critical periods using primary cultures

Using astrocytes obtained from 21-day-old rat fetuses, in primary culture, we have analyzed the effect of prenatal alcohol consumption on DNA and protein synthesis of astrocytes during their development. The variation in sensitivity of astrocytes to ethanol in vitro during the proliferation and maturation periods was also assessed. Control astrocytes showed peaks of DNA and protein synthesis at 8 and 15 days, respectively. A significant decrease in both DNA and protein synthesis was found in astrocytes from fetuses prenatally exposed to ethanol. This effect on DNA synthesis was also observed when control astrocytes were exposed to ethanol (100mM) in vitro during the entire culture period. The effects on astrocytes of short term (48h) exposure to ethanol during the proliferation or differentiation periods on the above mentioned parameters and on the cell cycle as well as the possible recovery from these effects were also evaluated. Decreases in DNA and protein synthesis were found in both periods. However, DNA synthesis and content were more affected in astrocytes exposed to ethanol during the proliferation period. This effect correlates with an accumulation of cells in the G_o/G₁ phase of the cell cycle. On the other hand, when cells exposed to ethanol were cultured in alcohol-free medium to assess recovery, only cells exposed to ethanol during days 4 to 6 still showed DNA ethanol-induced effects at 21 days. In conclusion, our results show that ethanol consumption during gestation induces serious damage to cortical astrocyte progenitor cells. Our results further demonstrate that although astrocytes are more sensitive to the toxic effect of alcohol during the proliferation period, exposure to ethanol during glial maturation also alters their normal development.     

Xyloglucan (amyloid) mobilisation in the cotyledons of Tropaeolum majus L. seeds following germination

The levels of cell-wall xyloglucan (amyloid) in nasturtium (Tropaeolum majus L.) cotyledons were monitored during a 28-d period covering seed imbibition, germination and early seedling development. The activities of the following enzymes capable of hydrolysing the glycosidic linkages in the xyloglucan were assayed in cotyledon extracts over the same period: endo-(14)--glucanase (EC 3.2.1.4), -glucosidase (EC 3.2.1.21), -xylosidase and -galactosidase (EC 3.2.1.23). The endo--glucanase was assayed viscometrically using xyloglucan as substrate, and the three glycosidases using appropriate p-nitrophenylglycosides. Alpha xylosidase and -galactosidase, the enzymes which would be expected to hydrolyse the side-chains from the xyloglucan molecule, were also assyed using xyloglucan as substrate. Under our culture conditions, xyloglucan levels remained constant at 30 mg per cotyledon pair for 7 d, that is until 3 d after germination: thereafter, the amount of xyloglucan diminished to zero in a 12-d period. The most rapid period of depletion was between days 9 and 13. The mobilisation of all reserve substances from the cotyledons resulted in a weight-loss of 92 mg: xyloglucan, therefore, is an important storage substance, representing 33% by weight of the seed's substrate reserves. It is a cell-wall storage polysaccharide. Xyloglucan mobilisation was accompanied by a 17-fold increase in endo--glucanase activity, a 7-fold increase in -galactosidase and an 8-fold increase in -xylosidase activities, all determined using xyloglucan as substrate. All three activities began to increase at day 5, peaked at days 12–14 when the most rapid phase of xyloglucan breakdown was over, and had declined to zero by days 22–25. The levels of theses enzymes have been shown to be consistent with their being responsible for xyloglucan hydrolysis in vivo. Nitrophenyl--galactosidase activity increased up to day 3, remained constant and then increased again 2.5-fold from day 5, peaking at day 11. Nitrophenyl--glucosidase remained relatively constant up to day 16 and then decreased to zero by day 25. Nitrophenyl--xylosidase activity was not detected.     

Die Regulation der PAL-Aktivität durch Phytochrom in Senfkeimlingen (Sinapis alba L.)

Summary The present paper is a contribution to the molecular analysis of photomorphogenesis. L-phenylalanine ammonia-lyase (=PAL) (EC 4.3.1.5) has been used as a model system to demonstrate that enzyme synthesis, enzyme inactivation and gene repression are important in determining the response of a particular enzyme to phytochrome.The level of PAL in the mustard seedling is controlled by P_fr (the active form of phytochrome) in a characteristic manner which is illustrated in Fig. 1. The seedlings were irradiated with continuous standard far-red light. Long time irradiation with far-red will maintain a low but virtually constant level of the effector molecule P_fr in the seedling over an extended period of time. At the moment when the far-red light is turned off the action of P_fr will instantly decrease and will eventually cease probably within the order of an hour (cf. Karow and Mohr, 1969). The approach followed in the present paper has been to turn off the far-red light after varying periods and follow the enzyme kinetics in darkness (Fig. 2). The main results can be summarized as follows: The far-red kinetics of PAL (Fig. 1) can be explained as the result of three processes, namely, Pfr-mediated enzyme synthesis, inactivation of PAL by an inactivator, and eventual repression of enzyme synthesis.—During the period 1.5–12 hrs after the onset of far-red only enzyme synthesis occurs. Then enzyme inactivation comes into play while enzyme synthesis continues at a constant rate (Fig. 3). This antagonism of synthesis and inactivation leads to a true steady state which is observed between about 24 and 27 hrs after the onset of far-red. After this period the rate of enzyme synthesis decreases and as a consequence, inactivation dominates. 36 hours after the onset of far-red the P_fr-mediated PAL synthesis is hardly dtectable. The results of secondary irradiations with far-red (Fig.4) indicate that the inactivator of PAL does not have any direct influence on PAL synthesis. The kinetics in darkness (Fig.1,2) can best be understood by assuming that a certain enzyme level represented by the plateau cannot be overcome in the dark. The overshoot response which is obvious in the enzyme kinetics immediately after the cessation of far-red (Fig. 2) cannot be explained readily in molecular terms.

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PAL=Phenylalaninammoniumlyase (EC 4.3.1.5).

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Diese Arbeit ist Herrn Professor H. Borris, Greifswald, mit guten Wünschen zum 60. Geburtstag gewidmet.     

Inhibition of polyamine synthesis reduces the growth rate and delays the expression of differentiated phenotypes in primary cultures of embryonic mesoderm from chick

Summary Inhibition of polyamine synthesis in early chick embryos blocks their development at gastrulation. Analyses of arrested embryos show that mesodermal outgrowth and differentiation are drastically impaired. To study these effects in greater detail, we have used primary cultures of embryonic mesoderm from chick. The cultures were treated with -difluoromethylornithine (DFMO), an enzyme-activated irreversible inhibitor of ornithine decarboxylase, the first and rate-limiting enzyme in polyamine synthesis. In control culture medium, mesodermal cells retained their in ovo outgrowth behavior and differentiation pattern. Addition of 10 mM DFMO to the culture medium, however, retarded attachment and outgrowth, and reduced the rate of proliferation of the mesodermal cells. Furthermore, the expression of differentiated phenotypes, such as beating heart tissue, erythroid cells, and adipocyte-like cells, was delayed. Simultaneous addition of 100 M putrescine prevented or reduced the effects of DFMO, showing that these were indeed caused by polyamine deficiency. In the DFMO-treated mesoderm, DNA synthesis was markedly suppressed by the first day. Similar effects on RNA and protein synthesis developed at a later time. Our data suggest that a reduction in the concentrations of the polyamines decreases the rate of mesodermal cell proliferation, and as a conseqence delays the expression of differentiated phenotypes.     

Amino acid ester synthesis by immobilized α-chymotrypsin

Summary A screening of immobilized -chymotrypsin preparations suitable for the synthesis of N-acetyl-L-tyrosine ethyl ester from N-acetyl-L-tyrosine and up to 99% ethanol was carried out. -Chymotrypsin adsorbed to Sepharose LH-20 or covalently bound to Sepharose 4B (tresyl chloride activation) was found to be an efficient catalyst. A column packed with immobilized enzyme retained 60% of its initial activity after 6 days of operation in a cyclohexane-ethanol medium.     

Gibberellic acid and abscisic acid modulate protein synthesis and mRNA levels in barley aleurone layers

Using in vivo pulse labeling, changes in the pattern of protein synthesis were detected in isolated barley aleurone layers treated with fibberellic acid (GA₃). GA₃ greatly altered the relative rates of synthesis of many polypeptides, increasing some, notably -amylase, and decreasing others. -Amylase synthesis increased until it was the major product (over 60%) of protein synthesis after 24h. The pulse-labeled pattern of secreted polypeptides was also changed by GA₃. There was the expected increase in -amylase together with a number of other polypeptides but there was reduced secretion of several polypeptides also.Cell-free translation of RNA isolated from control and hormone-treated tissues was used to measure changes in mRNA levels. GA₃ caused many changes, particularly in the level of mRNA for -amylase. In vitro synthesized -amylase, identified by immunoaffinity chromatography, had an Mr of 46 000. This polypeptide was partially processed to a polypeptide with Mr 44 000 by the addition of dog pancreas membranes to the in vivo translation mixture. The level of mRNA for -amylase began to increase 2–4 h after GA₃ was added and reached a maximum level of about 20% of total mRNA after 16 h. Thus after 16 h, the synthesis of -amylase as a proportion of total protein synthesis, continued to increase while the level of its mRNA as a proportion of total mRNA remained constant. These results indicate that protein synthesis was modified more extensively than we can account for by changes in mRNA.Abscisic acid (ABA) reversed all of the effects of GA₃ on protein synthesis and mRNA levels. It also promoted synthesis of a small number of new polypeptides and increased the level of some mRNAs. GA₃ reversed the accumulation of ABA-promoted mRNAs. Although, ABA strongly suppressed the increase in the level of translatable mRNA for -amylase, there was an even stronger inhibition of enzyme synthesis and accumulation.We conclude that both GA₃ and ABA regulate protein synthesis both positively and negatively in aleurone cells largely by regulating levels of mRNA and in the case of -amylase, possibly also by changing the efficiency of translation of its mRNA.