MPF-induced breakdown of cytokeratin filament organization in the maturing Xenopus oocyte depends upon the translation of maternal mRNAs

In Xenopus, one of the most dramatic events during oocyte maturation is the breakdown of the oocyte's asymmetrically organized system of cytokeratin-type intermediate filaments. Following oocyte maturation in vitro, we found that (1) the breakdown of cytokeratin filament organization proceeds in an animal to vegetal direction, (2) cytokeratin filament breakdown occurs normally in enucleated oocytes and so is independent of nuclear components, and (3) the injection of maturation-promoting factor (MPF) induces the breakdown of cytokeratin filaments. While the MPF-induced breakdown of the nuclear envelope is independent of new protein synthesis, the MPF-induced breakdown of cytokeratin filament organization requires the translation of maternal mRNAs. These results strongly suggest that the factors regulating cytokeratin reorganization in the oocyte are distinct from those involved in the breakdown of the nuclear envelope.     

Hot spots of leaf breakdown within a headwater stream reach: comparing breakdown rates among litter patch types with different macroinvertebrate assemblages

1. Detecting hot spots of litter decomposition will promote understanding of litter processing in a heterogeneous system. To identify hot spots of leaf breakdown within a headwater stream reach, we examined the difference in leaf breakdown rate among four types of litter patches, one that formed in riffles and three that formed in pools (middle, alcove, edge), in different seasons. 2. Middle patches showed the highest breakdown rate in some seasons; the rate in middle patches was 1.5–4 times higher than in the other patches. Thus middle patches can be regarded as hot spots of leaf breakdown in the study reach. This result contrasted with other studies showing higher breakdown rate in riffles than in pools. 3. Significant relationships between abundance of caddisfly shredders and breakdown rate were observed in seasons when the rate differed among patch types. Greater abundance of Lepidostoma seems to be responsible for middle patches being hot spots of leaf breakdown. 4. It is expected that when the proportion of leaves retained in middle patches within a reach is higher, the breakdown rate of the entire reach will be increased. Clarifying how the proportion of leaves retained on middle patches within a reach varies temporally and spatially would improve our understanding of leaf breakdown in headwater streams.     

The pH dependence of breakdown of various purified brain proteins by cathepsin D preparations

In a continuing study of control processes of cerebral protein catabolism we compared the activity of cathepsin D from three sources (rat brain, bovine brain, and bovine spleen) on purified CNS proteins (tubulin, actin, calmodulin, S-100 and glial fibrillary acidic protein). The pH optimum was 5 for hydrolysis with tubulin as substrate for all three enzyme preparations, and it was pH 4 with the other substrates. The pH dependence curve was somewhat variable, with S-100 breakdown relatively more active at an acidic pH range. The formation of initial breakdown products and the further catabolism of the breakdown products was dependent on pH; hence the pattern of peptides formed from glial fibrillary acidic protein was different in incubations at different pH's. The relative activity of the enzyme preparations differed, depending on the substrate: with tubulin and S-100 as substrates, rat brain cathepsin D was the most active and the bovine spleen enzyme was the least active. With calmodulin and glial fibrillary acidic protein as substrates, rat brain and spleen cathepsin D activities were similar, and bovine brain cathepsin D showed the lowest activity. Actin breakdown fell between these two patterns.The rates of breakdown of the substrates were different; expressed as μg of substrate split per unit enzyme per h, with rat brain cathepsin D activity was 8–9 with calmodulin and S-100, 4 with glial fibrillary acidic protein, 1.8 with actin, and 0.9 with tubulin. The results show that there are differences in the properties of a protease like cathepsin D, depending on its source; furthermore, the rate of breakdown and the characteristics of breakdown are also dependent on the substrate.We recently measured the breakdown of brain tubulin by cerebral cathepsin D in a continuing study of the mechanisms and controls of cerebral protein catabolism (Bracco et al., 1982a). We found that tubulin breakdown is heterogeneous, that membrane-bound tubulin is resistant to cathepsin D but susceptible to thrombin (Bracco et al., 1982b), and that cytoplasmic tubulin was in at least two pools, one with a higher, another with a lower, rate of breakdown. The pH optimum of tubulin breakdown by cerebral cathepsin D differed significantly from the pH optimum of hemoglobin breakdown by the same enzyme.These findings showed that the properties of breakdown by a cerebral protease depend on the substrate. To further examine this dependence of properties of breakdown on the substrate, we now report measurements of pH dependence of breakdown of several purified proteins (tubulin, actin, calmodulin, S-100, glial fibrillary acidic protein [GFA]) from brain by cathepsin D preparations from three sources, rat brain, bovine brain, and bovine spleen. We also compare the rate of breakdown of the various proteins with the rate of hemoglobin breakdown.     

Effects of shredding amphipod density on watercress Nasturtium officinale breakdown

Shredding stream invertebrates should have a positive influence on the breakdown rates of leaf litter via direct consumption and particle fragmentation. To determine the effects of shredder density on litter breakdown, breakdown of the emergent stream macrophyte, Nasturtium officinale , was investigated using three litter bag mesh sizes [fine (0.2 mm), medium (1 mm) and coarse (3 mm) mesh] and four stocking densities of the shredder, Gammarus pseudolimnaeus , (0, 4, 8 and 16 per bag). Watercress decayed very rapidly, with breakdown rates ( k values) ranging from 0.075 d^-1 for fine mesh with no shredders to 0.24 d^-1 for coarse mesh. Stocked Gammarus increased breakdown rates significantly in fine mesh bags (p < 0.001), but only marginally in medium mesh bags (p < 0.1). Breakdown rates also increased significantly with mesh size. A regression model showed a significant relation of breakdown rate to Gammarus density and mesh size. These results clearly show that shredders can significantly influence breakdown rates and can account for up to 30% of breakdown, but that mesh size effects such as particle size reduction and loss are also very important.     

Intracellular protein breakdown in thermophilic and mesophilic fungi

1. The rate of protein breakdown was determined on growing and non-growing cultures of thermophilic and mesophilic fungi. 2. In growing cells protein breakdown was negligible. 3. In non-growing cells the breakdown rate of total protein varied between 5.2%/h and 6.7%/h. These values were found to be dependent on both the temperature of the protein breakdown assay and the temperature of growth of the organism. 4. The rate of breakdown of soluble protein in thermophilic fungi was 9-15%/h whereas the rate in mesophilic fungi for the soluble protein fraction was only 4%/h.     

The breakdown of the individual neurofilament proteins by cathepsin D

In a continuing study of proteolysis of CNS proteins by CNS enzymes, neurofilament proteins (210 K, 155 K, 70 K) and desmin were separated, and the breakdown of individual proteins by purified brain cathepsin D was measured and compared to breakdown by plasma thrombin. With both cathepsin D and thrombin, the rate of breakdown of the 70 K protein was the highest, followed by the 155 K, and that of the 210 K was the lowest. With each substrate cathepsin D breakdown was the highest at pH 3; small but significant breakdown could be seen at pH 6. The pattern of intermediate breakdown products depended on pH, with greater amounts of fragments detected at higher pH, and the patterns with the two enzymes were different. We showed that differences exist in cleavage sites and breakdown rates of the neurofilament proteins. The capacity of the cathepsin D present in the tissue to hydrolyze these substrates was high, even at pH close to neutral, and was greatly in excess of that needed for physiological neurofilament turnover.     

Inhibition of Ischemia-Induced Fodrin Breakdown by a Novel Phenylpyrimidine Derivative NS-7: An Implication for Its Neuroprotective Action in Rats with Middle Cerebral Artery Occlusion

Abstract: The effect of a novel neuroprotective compound, NS-7[4-(4-fluorophenyl)-2-methyl-6-(5-piperidinopentyloxy)pyrimidine hydrochloride], on ischemia-induced fodrin breakdown was examined both in vitro and in vivo. The fodrin breakdown was measured by western blot followed by a densitometric analysis. In slices of the rat cerebral cortex, a pronounced fodrin breakdown was observed under hypoxic and hypoglycemic conditions. The enhancement of fodrin breakdown was completely blocked by omission of extracellular Ca²⁺ and significantly inhibited by calpain inhibitors such as E-64 and calpain inhibitor-I, thereby suggesting that the fodrin breakdown induced by hypoxia/hypoglycemia is due to the activation of Ca²⁺-stimulated neutral protease calpain. NS-7 (1–30 µ M ) produced a concentration-dependent inhibition of hypoxia/hypoglycemia-induced fodrin breakdown. In rats with unilateral middle cerebral artery occlusion (MCAO), a pronounced fodrin breakdown was observed in the cerebral cortex and striatum, although the time course for the development of the fodrin breakdown was much slower in the cerebral cortex than in the striatum. NS-7 (0.5 mg/kg i.v.), when injected immediately after MCAO, suppressed not only the fodrin breakdown but also the infarction in the cerebral cortex. From these results it is suggested that inhibition of calpain activation is implicated in the neuroprotective action of NS-7.     

Hormonal regulation of phosphatidylinositol breakdown

Cyclic AMP and Ca2+ are intracellular mediators of hormone action. Catecholamines interact with beta adrenoceptors to activate adenylate cyclase or with alpha 2 adrenoceptors to inhibit adenylate cyclase. Alpha 1 adrenoceptor activation results in elevation of cytosol Ca2+ and an increased breakdown of phosphatidylinositol. In blowfly salivary glands, 5-hydroxytryptamine (5-HT) interacts with beta type receptors resulting in adenylate cyclase activation while alpha type receptors are involved in phosphatidylinositol breakdown and elevation of cytosol Ca2+. The link between Ca2+ mobilization and phosphatidylinositol breakdown remains to be established but breakdown of the receptor-regulated pool of phosphatidylinositol is not secondary to the rise in Ca2+. Direct addition of 5-HT to cell-free homogenates of blowfly salivary glands results in activation of phosphatidylinositol breakdown in the absence of Ca2+. In rat liver plasma membrane preparations, vasopressin increases phosphatidylinositol breakdown in the absence of Ca2+ or cytosol if deoxycholate is present. The data do not indicate whether hormone activation increases the availability of substrate to enzymatic hydrolysis or activates phospholipase C. However, they demonstrate that hormones directly accelerate phosphatidylinositol breakdown.     

Effects of corticosterone on connectin content and protein breakdown in rat skeletal muscle

We examined the effects of a glucocorticoid, corticosterone, on calpain activity, connectin content and protein breakdown in rat muscle. The results indicated that calpain activity was increased by corticosterone and thus breakdown of connectin was stimulated followed by increased breakdown of skeletal muscle protein.     

Skeletal-muscle growth and protein turnover.

Because of turnover, protein synthesis and breakdown can each be involved in the regulation of the growth of tissue protein. To investigate the regulation of skeletal-muscle-protein growth we measured rates of protein synthesis and breakdown in growing rats during development on a good diet, during development on a marginally low-protein diet and during rehabilitation on a good diet after a period of severe protein deficiency. Rates of protein synthesis were measured in vivo with a constant intravenous infusion of [14C]tyrosine. The growth rate of muscle protein was measured and the rate of breakdown calculated as breakdown rate=synthesis rate-growth rate. These measurements showed that during development on a good diet there was a fall with age in the rate of protein synthesis resulting from a fall in capacity (RNA concentration) and activity (synthesis rate per unit of RNA). There was a fall with age in the breakdown rate so that the rate was highest in the weaning rats, with a half-life of 3 days. There was a direct correlation between the fractional growth and breakdown rates. During rehabilitation on the good diet, rapid growth was also accompanied by high rates of protein breakdown. During growth on the inadequate diet protein synthesis rates were lesss than in controls, but growth occurred because of decreased rates of protein breakdown. This compression was not complete, however, since ultimate muscle size was only one-half that of controls. It is suggested that increased rates of protein breakdown are a necessary accompaniment to muscle growth and may result from the way in which myofibrils proliferate.     

Breakdown of brain tubulin by cerebral cathepsin D

The breakdown of cytoplasmic tubulin from brain (purified by ammonium sulfate fractionation and DEAE cellulose chromatography) by cathepsin D from brain (purified by ammonium sulfate fractionation and pepstatin Sepharose chromatography) was studied; changes in the intensity of tubulin gel bands were determined. The pH optimum of hemoglobin breakdown by cathepsin D was 3.2; the pH optimum for tubulin breakdown was 5.8; at pH 5.8 there was no significant hemoglobin breakdown by the enzyme. Tubulin breakdown had an apparent K_m of 1.8 × 10⁻⁵ M and a V_max of 0.56 μg tubulin (μg enzyme per min). The rate of breakdown was heterogeneous and studied on length of incubation; the major portion of tubulin was rapidly broken down and a smaller portion was more stable. The rate under our experimental conditions was 18%/h in the 1–4 h period and 2%/h after 4 h. This was not due to enzyme instability: after 4 h of inhibition freshly added tubulin was rapidly broken down, whereas freshly added enzyme did not increase the rate of breakdown. Thus breakdown heterogeneity was due to substrate (tubulin) heterogeneity. Pepstatin inhibited cathepsin D breakdown of tubulin at acid pH; at pH 7.6 it had no effect. Leupeptin was not inhibitory. We calculated that the cathepsin D content in brain, if fully active, could break down cytoplasmic tubulin with a half-life of 24 h, but it is likely that under in vivo conditions enzyme activity is greatly modified.     

Dielectric breakdown measurements of human and bovine erythrocyte membranes using benzyl alcohol as a probe molecule

Dielectric breakdown of intact erythrocytes and subsequent haemolysis in the presence of increasing concentrations of benzyl alcohol were investigated by means of an electrolytical discharge chamber and a hydrodynamic focusing Coulter Counter.Low concentrations of the drug stabilized human and bovine erythrocytes against haemolysis induced by dielectric breakdown of the cell membrane in isotonic solutions, while high concentrations caused lysis similar to hypotonic and mechanical haemolysis. The stabilizing effect of the drug on electrically induced haemolysis depends on the pulse length of the applied electric field. The critical dielectric breakdown voltage of the membranes of intact cells decreases progressively with increasing benzyl alcohol concentrations, at which the membrane is also more stabilized against electrical and osmotic haemolysis. Occasionally, an increase in the dielectric breakdown voltage is observed at drug concentrations at which lysis occurs. A similar dependence of the breakdown voltage on drug concentration was found for human erythrocyte ghost cells prepared by dielectric breakdown.The results are consistent with the electromechanical model suggested for the dielectric breakdown mechanism and with the assumption of Metcalfe, using NMR and ESR techniques, that the fluidity of the membrane increases with increasing benzyl alcohol concentration.     

Effects of Corticosterone on Connectin Content and Protein Breakdown in Rat Skeletal Muscle

We examined the effects of a glucocorticoid, corticosterone, on calpain activity, connectin content and protein breakdown in rat muscle. The results indicated that calpain activity was increased by corticosterone and thus breakdown of connectin was stimulated followed by increased breakdown of skeletal muscle protein.     

Quantitative analysis of the process and propagation of cortical granule breakdown in sea urchin eggs

Cortical granule breakdown in sea urchin eggs has been investigated with a video microscope system using Nomarski differential interference contrast optics, when induced by fertilization, microinjecting inositol 1,4,5-trisphosphate (IP3) or Ca-EGTA buffer solution into the egg, or perfusing a medium containing 1 mM Ca2+ to isolated cortices. The cortical granule increased up to 1.2 times in diameter and broke down within 40 msec. These values were almost constant among the three methods used to induce cortical granule breakdown. Upon fertilization, the cortical granule breakdown propagated over the egg surface at a speed of 3.3 microns/sec in Clypeaster japonicus eggs, which indicates that cortical granule breakdown propagated through the 3.3-microns-wide egg surface within 1 sec. In such a small area of the egg surface, however, it took much more than 1 sec for all cortical granules to break down because the maximal rate of breakdown was 7.6%/sec; that is, it took 9 sec and 18 sec for 50% and 90% respectively, of cortical granules to break down. Moreover, the rate did not simply decrease with time, and a shoulder was found during the reducing phase, which suggests that cortical granules are divided into fast and slow breakdown groups according to the responsiveness to the breakdown stimulus. The cortical granule breakdown induced by microinjecting the Ca-EGTA buffer and IP3 solutions propagated at 68 microns/sec and 35 microns/sec, respectively. The stimulus for cortical granule breakdown is discussed concerning the transient intracellular Ca2+ increase.     

Enhancement by Potassium of Carbachol-Stimulated Inositol Phospholipid Breakdown in Rat Cerebral Cortical Miniprisms: Comparison with Other Depolarising Agents

Increasing the [K+] in the assay medium from 5.7 to 17.8 mM produces a large enhancement of the inositol phospholipid breakdown response to the muscarinic agonist carbachol in rat cerebral cortical miniprisms, with minor effects on basal inositol phospholipid breakdown. This effect is also found with Rb+. The enhancement by a raised [K+] is not accompanied by a change in the composition of the labelled polyphosphoinositides. The carbachol-stimulated inositol phospholipid breakdown at 17.8 and 42.7 mM K+ was antagonised by veratrine (5-80 microM), 4-aminopyridine (5 mM), and tetraethylammonium (20 mM). These compounds, however, also inhibited the binding of [3H]quinuclidinyl benzilate to cortical membranes. BRL 34915 (0.2-20 microM) was without significant effect on carbachol-stimulated inositol phospholipid breakdown at either 5.7 or 17.8 mM K+.Mg2+ (10 mM) considerably reduced the carbachol-stimulated inositol phospholipid breakdown at 17.8, but not 42.7, mM K+. Inositol phospholipid breakdown was also stimulated, albeit to a small extent, by L-glutamate (100-3,000 microM) and quisqualate (1-100 microM), with the stimulation being additive to that produced by carbachol at both 5.7 and 17.8 mM K+. N-Methyl-D-aspartate (10-1,000 microM in Mg2+-free medium) had no significant effect on basal inositol phospholipid breakdown and had little or no effect on carbachol-stimulated inositol phospholipid breakdown at either 5.7 or 17.8 mM K+. It is concluded that it may not be correct to ascribe wholly the enhancement by K+ of carbachol-stimulated inositol phospholipid breakdown to the tissue-depolarising actions of this ion and that other actions of K+ may be involved.     

The effects of caffeine, ultraviolet and x-irradiation on DNA breakdown in E. coli B and some of its dark repair mutants

Summary Caffeine (4 and 8 mM) increased the rate of spontaneous DNA breakdown which occurred during normal growth of a culture of E. coli Bs-11, but neither affected breakdown in the EXR strain Bs-2 nor the parental strain B. It slightly impaired the rate of DNA breakdown which follows UV-irradiation of E. coli B, but did not depress the final fraction degraded. On the other hand even 12 mM caffeine had no detectable effect on the (excessive) rate of DNA breakdown of U. V.-irradiated cultures of the EXR strain Bs-2. The effects of X-irradiation on DNA breakdown in E. coli B and a number of its U. V.-sensitive and resistant mutants are described. Caffeine had no detectable effect on the kinetics of X ray-induced DNA breakdown of E. coli B.     

The breakdown of cell membranes by electrical and mechanical stress.

We attempted to determine whether mechanical tension and electrical stress couple to cause membrane breakdown in cells. Using cell-attached patches from HEK293 cells, we estimated the mechanically produced tension from the applied pressure and geometry of the patch. Voltage pulses of increasing amplitude were applied until we observed a sudden increase in conductance and capacitance. For pulses of 50 micros duration, breakdown required >0.5 V and was dependent on the tension. For pulses of 50-100 ms duration, breakdown required 0.2-0.4 V and was independent of tension. Apparently two physically different processes can lead to membrane breakdown. We could explain the response to the short, high-voltage pulses if breakdown occurred in the lipid bilayer. The critical electromechanical energy per unit area for breakdown by short pulses was approximately 4 dyne/cm, in agreement with earlier results on bilayers. Our data suggest that, at least in a patch, the bilayer may hold a significant fraction (approximately 40%) of the mean tension. To be compatible with the large, nonlytic area changes of patches, the bilayer appears to be pulled toward the pipette tip, perhaps by hydrophobic forces wetting membrane proteins bound to the glass. Although breakdown voltages for long pulses were in agreement with earlier work on algae, the mechanism(s) for this breakdown remain unclear.     

Inhibition of protein breakdown by epidermal growth factor in IMR90 human fibroblasts and other mammalian cell lines.

1. Epidermal growth factor (EGF) inhibits intracellular protein breakdown in IMR90 human fibroblasts and other cell lines having EGF receptors. 2. Inhibition is achieved within 1 h of exposure to the growth factor and is reversed equally rapidly upon removal of EGF. 3. EGF inhibits protein breakdown and stimulates protein and DNA labelling with similar dependency on concentration. Half-maximal effects for all processes with IMR90 and AG2804 cell lines occur at 0.2 nM- and 0.05 nM-EGF respectively. 4. EGF and insulin effects on protein breakdown are additive only when the factors are included at suboptimal concentrations. 5. The apparent Kd for EGF binding in several cell lines is approximately 10-fold higher than the concentration needed for half-maximal inhibition of protein breakdown. 6. Down-regulation of EGF receptors in IMR90 cells produced a 60% decrease in the binding of 125I-labelled EGF. This was accompanied by a displacement of the concentration curve for EGF inhibition of protein breakdown by approximately two orders of magnitude, suggesting that protein breakdown can no longer respond to the down-regulated receptor-growth-factor complex. 7. Phorbol esters decrease the inhibitory effect of EGF, but not of insulin, on protein breakdown in IMR90 cells.     

Roles of protein synthesis and tRNA aminoacylation in the regulation of intracellular protein breakdown in E. coli

The previously suggested roles of protein synthesis and tRNA aminoacylation in the regulation of intracellular protein breakdown were examined in strains of E. coli temperature-sensitive for aminoacyl-tRNA synthetases. Direct measurements of tRNA aminoacylation show no correlation between the degree of tRNA charging and the rate of protein breakdown. Protein breakdown was accelerated by transfer from 30°C to 42°C to about the same degree in temperature-sensitive mutants as in related normal strains. Deprivation of inorganic phosphate at the high temperature stimulated further protein breakdown in normal, but not in temperature-sensitive strains. It is concluded that the regulation of protein breakdown requires concomitant protein synthesis and is not influenced by the level of aminoacylation of tRNA.     

Effects of nutrient enrichment on boreal streams: invertebrates, fungi and leaf-litter breakdown

1. The effect of nutrient enrichment on structural (invertebrate indices) and functional (leaf‐litter breakdown rates) characteristics of stream integrity was studied in nine boreal streams. 2. The results showed predicted changes in biotic indices and leaf‐litter breakdown along a complex (principal component) nutrient gradient. Biotic indices were better correlated with nutrient effects than leaf‐litter breakdown. 3. Fungal biomass and invertebrate densities in the litter bags were positively correlated with leaf‐litter breakdown, and both were also positively related to the nutrient gradient. 4. Invertebrate community composition influenced breakdown rate. High breakdown rates at one site were associated with the high abundance of the detritivore Asellus aquaticus. 5. This study lends support to the importance of invertebrate and fungi as mediators of leaf‐litter decomposition. However, our study also shows that study design (length of incubation) can confound the interpretation of nutrient‐induced effects on decomposition.