Effect of neurectomy on nuclease activity in skeletal muscles of rats

Author followed up the activity of the three enzymes involved in the catabolism of nucleic acids--acid deoxyribonulease (DNase II), alkaline ribonuclease (RNase I), and acid ribonuclease (RNase II)--in the denervated gastrocnemius and soleus muscles of rats for 28 postoperative days. The activity of both acid nucleases increased in both types of denervated muscles, compared with the respective controls. Up to the 14th postoperative day, the activity excess of both acid nucleases was more significant in the m. gastrocnemius than in the m. soleus. The RNase I ran below the control activity during the whole period in the m. soleus and up to the 14th day in the m. gastrocnemius. The role of nucleases and nuclease inhibitors in the changes of nucleic acid catabolism in neurogenic muscular atrophies is discussed.     

Muscle cell growth in protein deficient rats following administration of sheep red blood cells.

In order to observe the effects of sheep red blood cells (SRBC) administration on the muscle cell growth in malnourished states, adult male Wistar rats (135 +/- 10 g 10 animals per group) subjected during 30 days to 1% and 10% protein diets, were injected (i.v.) either 15.5 x 10(8) sheep red blood cells or 0.5 ml saline/100 g b.w. after 20 days of experiment. On the 10th day after injection the animals were sacrificed and the gastrocnemius muscle was removed, weighed and homogenized. The supernatant fluids were used to evaluate muscle protein, DNA and RNA rates and acid DNase activity. All parameters were depleted in malnourished rats, indicating a muscle cellular atrophy as well as a decrease in muscle protein synthesis per DNA-unit. Muscle hyperplasia and hypertrophy were found in antigenically stimulated rats fed 10% protein against non-stimulated control. In contrast, muscle growth in protein-deficient rats SRBC-treated was unmodified when compared to non-stimulated malnourished muscle, although RNA functionality seems to be enhanced (RNA/DNA). These data suggest that a redistribution of essential nutrients occurred for muscle growth adaptation rather than for defensive mechanism.     

Duality of polynucleotide substrates for Phi29 DNA polymerase: 3'-->5' RNase activity of the enzyme

Phi29 DNA polymerase is a small DNA-dependent DNA polymerase that belongs to eukaryotic B-type DNA polymerases. Despite the small size, the polymerase is a multifunctional proofreading-proficient enzyme. It catalyzes two synthetic reactions (polymerization and deoxynucleotidylation of Phi29 terminal protein) and possesses two degradative activities (pyrophosphorolytic and 3'-->5' DNA exonucleolytic activities). Here we report that Phi29 DNA polymerase exonucleolyticaly degrades ssRNA. The RNase activity acts in a 3' to 5' polarity. Alanine replacements in conserved exonucleolytic site (D12A/D66A) inactivated RNase activity of the enzyme, suggesting that a single active site is responsible for cleavage of both substrates: DNA and RNA. However, the efficiency of RNA hydrolysis is approximately 10-fold lower than for DNA. Phi29 DNA polymerase is widely used in rolling circle amplification (RCA) experiments. We demonstrate that exoribonuclease activity of the enzyme can be used for the target RNA conversion into a primer for RCA, thus expanding application potential of this multifunctional enzyme and opening new opportunities for RNA detection.     

Changes in the metabolism of muscle RNA in rats given a high protein diet

The effect of a high protein diet (20% casein + D,L-methionine) administered to adult Wistar rats on some aspects of muscle RNA metabolism has been studied. Body weight increased in spite of lower intake. However, gastrocnemius muscle remained unmodified, although protein content increased. Total RNA decreased in the whole muscle although RNA/DNA ratio did not change. Protein synthesis capacity diminished 81% relative to controls in spite the fact that an excessive amount of available amino acids exists. RNA loss might depend on a high catabolism, since acid RNase activity increased over control values. Therefore, it may be concluded that a high protein diet leads to a lower protein synthesis capacity through an elevated RNA breakdown.     

The Enzyme and the cDNA Sequence of a Thermolabile and Double-Strand Specific DNase from Northern Shrimps (Pandalus borealis)

Background

We have previously isolated a thermolabile nuclease specific for double-stranded DNA from industrial processing water of Northern shrimps (Pandalus borealis) and developed an application of the enzyme in removal of contaminating DNA in PCR-related technologies.

Methodology/Principal Findings

A 43 kDa nuclease with a high specific activity of hydrolysing linear as well as circular forms of DNA was purified from hepatopancreas of Northern shrimp (Pandalus borealis). The enzyme displayed a substrate preference that was shifted from exclusively double-stranded DNA in the presence of magnesium to also encompass significant activity against single-stranded DNA when calcium was added. No activity against RNA was detected. Although originating from a cold-environment animal, the shrimp DNase has only minor low-temperature activity. Still, the enzyme was irreversibly inactivated by moderate heating with a half-life of 1 min at 65°C. The purified protein was partly sequenced and derived oligonucleotides were used to prime amplification of the encoding cDNA. This cDNA sequence revealed an open reading frame encoding a 404 amino acid protein containing a signal peptide. By sequence similarity the enzyme is predicted to belong to a family of DNA/RNA non-specific nucleases even though this shrimp DNase lacks RNase activity and is highly double-strand specific in some respects. These features are in agreement with those previously established for endonucleases classified as similar to the Kamchatka crab duplex-specific nuclease (Par_DSN). Sequence comparisons and phylogenetic analyses confirmed that the Northern shrimp nuclease resembles the Par_DSN-like nucleases and displays a more distant relationship to the Serratia family of nucleases.

Conclusions/Significance

The shrimp nuclease contains enzyme activity that may be controlled by temperature or buffer compositions. The double-stranded DNA specificity, as well as the thermolabile feature, strengthens its potential for in vitro applications.     

Preparation of the bifunctional enzyme ribonuclease-deoxyribonuclease by cross-linkage.

Protease-free bovine pancreatic deoxyribonuclease (DNase) (1.6 X 10(-4) mmol) was thiolated on the NH2 groups with N-acetyl-DL-homocysteine thiolactone (2.4 X 10(-2) mmol) at pH 10.5 with imidazole (2.4 X 10(-2) mmol) as the catalyst in the presence of 4,4'-dithiodipyridine (4.2 X 10(-2) mmol). The product obtained after 16 h at 4 degrees C, 2-acetamido-4-(4'-dithiopyridyl)butyryl-DNase, isolated by gel filtration, contained an average of 0.87 +/- 0.13 mol of mixed disulfide per mol of DNase. Ribonuclease (RNase) was thiolated in a similar manner, but under N2 in the absence of 4,4'-dithiodipyridine. The protein N-acetylhomocysteinyl-RNase contained on the average 0.94 +/- 0.11 mol of sulfhydryl groups per mol of RNase. The coupling of RNase ot DNase was accomplished by thiol-disulfide interchange at pH 6.2 and 25 degrees C for 90 min. The hybrid enzyme (yield 25--33%, based upon the DNase derivative used) was freed from unreacted DNase, RNase, and homodimers by gel filtration, affinity chromatography, and salting-out chromatography. The purified enzyme contained one molecule each of DNase and RNase and hydrolyzed thymus deoxyribonucleic acid (DNA) and yeast or transfer ribonucleic acid (RNA) with 75 and 40% of the efficiencies, respectively, of the parent enzymes. The RNA strand of the hybrid substrate, phage f1 DNA-[3H]RNA, prepared from phage DNA with RNA polymerase, was hydrolyzed rapidly by the hybrid enzyme but was not hydrolyzed by RNase alone. A conjugate of the two enzymes offers the possibility in vivo of delivering two enzymes that differ in size, charge, and biological function to the same site at the same time.     

DNA-Dependent RNA Polymerase Activity Associated with Subviral Particles of Polyhedral Cytoplasmic Dexoyribovirus

Polyhedral cytoplasmic deoxyribovirus virions contain a DNA-dependent RNA polymerase which catalyzes the incorporation of ribonucleotides into an acid-precipitable product. Treatment of virions with sodium deoxycholate and dithiothreitol resulted in the formation of subviral particles which could be separated from virions by rate zonal centrifugation in sucrose gradients. Subviral particles were RNA polymerase-positive and more active per unit mass of protein than virions. In vitro enzyme activity associated with subviral particles required addition of ribonucleotides, Mg(2+), and exogenous denatured DNA template. Optimal enzyme activity occurred over a broad pH (7.2 to 8.8) and Mg(2+) concentration (2 to 10 mumol) range. The specific activity of the RNA polymerase was maximal at 37 C. Addition of DNase or actinomycin D to the reaction mixture reduced the incorporation of [(3)H]UMP into an acid-precipitable product. The product of the reaction was sensitive to degradation by RNase but not to DNase or Pronase. These data suggest that the enzyme copies DNA into RNA.     

Effect of ionic strength on chain elongation in ADP-ribosylation of various nucleases

With the use of a reconstituted poly(ADP-ribosyl)ating enzyme system and three purified nucleases, micrococcal nuclease (MN), bull seminal RNase (BS RNase) and Ca2+, Mg2+-dependent endonuclease (BS DNase), as model acceptor proteins for ADP-ribose, the effect of ionic strength on the modification reaction was examined in detail. When these three nucleases were extensively poly(ADP-ribosyl)ated in this system at a low ionic strength (5 mM Tris), they were all inhibited by about 80% and the chain length of the polymer covalently bound to the nucleases was 13 to 23 ADP-ribose units. The observed inhibition was markedly prevented by increasing the ionic strength in the reaction mixture with a concomitant decrease in the polymer size bound to the nucleases. The NaCl concentrations required for decreasing the extent of the inhibition to half of the maximum were calculated to be 20, 50, and 100 mM for MN, BS RNase, and BS DNase, respectively. These values are similar to the NaCl concentrations required for decreasing the average chain lengths of the polymer to half, suggesting that the length of polymer is closely correlated to the extent of inhibition of these nucleases. DNA-binding affinities of these nucleases, expressed in terms of the NaCl concentrations required for eluting the enzymes from DNA-cellulose, were 140, 280, and 340 mM for MN, BS RNase, and BS DNase, respectively. Considering that maintainance of a ternary complex of poly(ADP-ribose) synthetase, acceptor and DNA may be essential for the modification reaction, the relatively strong salt effect observed in the modification of MN may be explained by its low DNA-binding affinity.     

DETERMINATION OF RNA AND DNA CONCENTRATIONS IN NATURAL PLANKTON SAMPLES USING THIAZOLE ORANGE IN COMBINATION WITH DNASE AND RNASE DIGESTIONS1

A fluorometric technique, based on the combination of RNase and DNase incubation with the use of thiazole orange (RNase/DNase method), was investigated to determine DNA and RNA concentrations in marine plankton. Tests were performed to optimize both RNase and DNase assay conditions. The RNase assay should be conducted at 37° C for 20 min with 0.5 μg·mL^?1 of DNase-free RNase. An incubation at 25° C for 20 min with 10 units ·mL^-1 of RNase-free DNase were the optimal conditions required for DNA digestion by DNase. The detection limits in terms of minimum biomass for reliable measurements of DNA and RNA were 7.5 and 10 μg of protein · (mL assay)^?1, respectively. RNA and DNA concentration were estimated in oligotrophic water samples using the RNase/DNase and other available methods (e.g. a double fluorochrome method). The different techniques provided similar DNA estimations. However, the RNase/DNase method provided the highest sensitivity and a low variability for the estimation of RNA.     

Androgens regulate mitochondrial cytochrome c oxidase and lysosomal hydrolases in mouse skeletal muscle.

The gastrocnemius, a fast-twitch white muscle, and the soleus, a slow-twitch red muscle, were studied in A/J mice. The specific activities of the lysosomal hydrolases, beta-D-glucuronidase, hexosaminidase, beta-D-galactosidase and arylsulphatase, the inner-mitochondrial-membrane enzyme cytochrome c oxidase, and the outer-mitochondrial-membrane enzyme monoamine oxidase, were greater in the soleus than in the gastrocnemius. The specific activities of the lysosomal hydrolases and cytochrome c oxidase in the gastrocnemius and soleus were substantially higher in male mice than in female mice. Orchiectomy abolished this sex difference. Testosterone increased the activities of the lysosomal hydrolases and cytochrome c oxidase and coincidentally induced muscle hypertrophy and an accretion of protein and RNA, but total DNA remained constant. Monoamine oxidase was unaffected by sex, orchiectomy and testosterone. These findings indicate that endogenous androgens regulate the activity of enzymes associated with lysosomes and the inner mitochondrial membrane, as well as muscle fibre growth in mouse skeletal muscle.     

Paraquat and roundup effects on nucleases activities of alfalfa seedlings and alfalfa nucleases activities on paraquat-treated and roundup-treated nucleic acids

The specific activities of acid (pH 5.5) and neutral (pH 7) DNases and RNases were determined in alfalfa (Medicago sativa L.) seedlings grown in the dark in the presence of 3.7 mM paraquat (PQ) or 1 mM roundup (RD). Seedlings were taken at 0, 1, 3, and 5 days. Plant growth parameters (plant height and fresh weight) were dramatically reduced under these conditions of growth comparing to the control (grown in water). The DNase and RNase specific activities of herbicide-treated seedlings were reduced. The reduction of activities ranged by about 50–90 and 15–70% in PQ- and RD-treated seedlings, respectively. In vitro, PQ- and RD-treated nucleic acids [single-stranded DNA (ssDNA), RNA, and plasmid DNA (pl-DNA)] were incubated with acid and neutral nucleases. Both enzymes were isolated and purified from alfalfa seedlings. Electrophoretic analysis on agarose gel of the above incubated mixtures revealed the following: (a) neutral nuclease (pH 7) was capable of hydrolyzing PQ-treated ssDNA while acid nuclease (pH 5.5) was incapable. This could be due to the fact that acid and neutral nucleases displayed different base linkage specificity toward ssDNA; (b) RD formed strong complexes with ssDNA that were unable to be hydrolyzed by both nucleases; (c) in contrast, both enzymes were capable of hydrolyzing PQ- or RD-treated RNA; (d) neutral nuclease was capable of nicking and linearizing both PQ- and RD-treated pl-DNA while acid nuclease had the same activity only toward the PQ-treated pl-DNA; (e) the enzyme activities were not inhibited in the presence of both herbicides. The data suggest that the complexes of PQ or RD with DNA should not be functional substrates of nucleases, and consequently cell processes (e.g., metabolism of nucleic acids, gene expression, replication), in which DNA and nucleases are involved, could be disturbed.     

Hydrolytic Enzymes of Euglena gracilis: Characterization and Activity as a Function of Culture Age and Carbon Deprivation*†

SYNOPSIS. Optimal assay conditions are described for 8 hydrolases of Euglena gracilis var. bacillaris, SM-L1 (streptomycinbleached) strain, 7 of which have an acid pH-optimum. Acid phosphatase, β-galactosidase, β-glucosidase, β-fucosidase, cathepsin D, RNase, DNase, and an esterase are active in cell homogenates. Amylase has very low activity, and β-glucuronidase, arylsulfatase, β, N-acetyl-glucosaminidase, α-fucosidase, and α- and β-mannosidase are inactive. Hydrolase activity increases as a culture proceeds from the midexponential to the late stationary-phase of growth, being most pronounced in the case of β-glucosidase. In cultures deprived of a utilizable carbon source, the specific activities of the hydrolases (per mg total protein or dry weight) increase. When expressed on a per cell basis, however, the activities of DNase decrease while those of β-galactosidase, cathepsin D, and RNase increase. The hydrolases appear to be involved in the adaptation of Euglena to the metabolic demands imposed by different conditions of growth.     

Isolation and characterization of cell-associated nucleases related to streptococcal extracellular deoxyribonuclease D.

A group of at least four distinct nucleases designated DcI through DcIV were isolated from cellular extracts of group A streptococcal strain S43 and shown to be antigenically similar to streptococcal extracellular deoxyribonuclease (DNase) D. These cellular endonucleases degraded single- and double-stranded deoxyribonucleic acid (DNA) as well as ribonucleic acid (RNA) to acid-soluble oligonucleotides. The products of digestion of DNA bore 5'-terminal phosphates, and in partial digests pdX-pdG linkages were most susceptible and pdA-pdX linkages were most resistant to nuclease action. The enzymes had pH optima of 8.0 to 8.5, were inhibited by NaCl, were unaffected by sulfhydryl modifying reagents, and absolutely required a divalent cation. Nucleases DcIII and DcIV were apparently hydrophobic in nature since they required the presence of detergents for migration on nondenaturing polyacrylamide gels. All four nucleases were electrophoretically distinct on such gels, from each other, and from DNase D. Molecular weights of DcI and DcII were similar to that of DNase D, suggesting that the mobility differences of these enzymes at least are reflections of differing net charges. It is suggested that the cellular nucleases represent a group of processing intermediates in the maturation and excretion of DNase D.     

The DNase activity of RNase T and its application to DNA cloning.

RNase T is one of eight distinct 3'-->5' exoribonucleases present in Escherichia coli. The enzyme plays an important role in stable RNA metabolism, including tRNA end turnover and 3' maturation of most stable RNAs because it is the only RNase that can efficiently remove residues near a double-stranded (ds) stem. In the course of study of its specificity and mechanism, we found that RNase T also has single-strand-specific DNase activity. Purified RNase T degrades both single-stranded (ss)RNA and ssDNA in a non-processive manner. However, in contrast to its action on RNA, RNase T binds ssDNA much more tightly and shows less sequence specificity. As with RNA, DNA secondary structure strongly affects its degradation by RNase T. Thus, RNase T action on a dsDNA with a single-stranded 3'-extension efficiently generates blunt-ended DNA. This property of RNase T suggested that it might be a useful enzyme for blunt-ended DNA cloning. We show here that RNase T provides much higher cloning efficiency than the currently used mung bean nuclease.     

The 5S rRNA maturase, ribonuclease M5, is a Toprim domain family member

The maturation of 5S ribosomal RNA in low G+C Gram-positive bacteria is catalyzed by a highly conserved, ~190 residue, enzyme, called ribonuclease M5 (RNase M5). Sequence alignment had predicted that the N-terminal half of RNase M5 would consist of a Toprim domain, a protein fold found in type IA and type II topoisomerases, DnaG-like primases, OLD family nucleases and RecR proteins [L. Aravind, D. D. Leipe and E. V. Koonin (1998) Nucleic Acids Res., 26, 4205–4213]. Here, we present structural modelling data and a mutational analysis of RNase M5 that confirms this hypothesis. The N-terminal half of RNase M5 can be fitted to the Toprim domain of the DnaG catalytic core. Mutation of amino acid residues highly conserved among RNase M5 enzymes and members of the Toprim domain family showed that alteration of residues critical for topoisomerase and primase activity also had a dramatic effect on the cleavage of 5S rRNA precursor by RNase M5 both in vivo and in vitro. This suggests that the mechanisms of double-stranded RNA cleavage by RNase M5 and double-stranded DNA cleavage by members of the topoisomerase family are related.     

High protein diet in pregnancy. Effects on neonatal metabolism

The effect of a high protein diet (20% casein + D,L-methionine) administered to Wistar rats during pregnancy on some aspects of cellular growth and RNA metabolism of progeny has been studied. Comparisons were made with well-nourished (10% casein + D,L-methionine) controls. Newborns individual weight, litter weight and number of newborns per litter were unmodified. However, neonate protein content dropped significantly when compared with controls. Both rate of DNA and number of nuclei were unchanged. Protein/DNA ratio (cellular size relative to protein) decreased, which might have led to an atrophy phenomenon, even if the newborn weight/number of nuclei ratio was not modified. Acid DNase activity rose, bringing about DNA breakdown. Total RNA content together with RNase activity fell in newborn from rats suffering high protein diet. Moreover, protein synthesis capacity (RNA/protein ratio) did not change. These results suggest that the administration of a high protein diet to pregnant rats lead to changes in newborn protein rate and nucleic acid turnover by modulating specific nuclease activity.     

Bacteriophage T4 RNase H removes both RNA primers and adjacent DNA from the 5' end of lagging strand fragments

Bacteriophage T4 RNase H belongs to a family of prokaryotic and eukaryotic nucleases that remove RNA primers from lagging strand fragments during DNA replication. Each enzyme has a flap endonuclease activity, cutting at or near the junction between single- and double-stranded DNA, and a 5'- to 3'-exonuclease, degrading both RNA.DNA and DNA.DNA duplexes. On model substrates for lagging strand synthesis, T4 RNase H functions as an exonuclease removing short oligonucleotides, rather than as an endonuclease removing longer flaps created by the advancing polymerase. The combined length of the DNA oligonucleotides released from each fragment ranges from 3 to 30 nucleotides, which corresponds to one round of processive degradation by T4 RNase H with 32 single-stranded DNA-binding protein present. Approximately 30 nucleotides are removed from each fragment during coupled leading and lagging strand synthesis with the complete T4 replication system. We conclude that the presence of 32 protein on the single-stranded DNA between lagging strand fragments guarantees that the nuclease will degrade processively, removing adjacent DNA as well as the RNA primers, and that the difference in the relative rates of synthesis and hydrolysis ensures that there is usually only a single round of degradation during each lagging strand cycle.     

定量测定黑鲷生长激素受体mRNA的液相杂交/RNase保护法

目的　建立液相杂交 核糖核酸酶保护测定 (RibonucleaseProtectionAssay,RPA)技术定量检测黑鲷(Sparusmacrocephalus)生长激素受体mRNA水平。方法　将黑鲷生长激素受体cDNA片断亚克隆至pGEM T载体 ,制备特异性的放射性反义RNA探针及正义RNA ,将反义RNA探针与正义RNA及样品总RNA进行液相杂交 ,用RNaseA和RNaseT1 降解杂交产物的单链RNA ,双链杂交体得到保护 ,然后检测杂交体的分子大小及放射强度。结果　检测出了黑鲷生长激素受体反义RNA探针与正义RNA及样品总RNA的特异性杂交片断 ,由此建立了定量测定黑鲷生长激素受体mRNA的液相杂交 RNase保护法 ,并采用该方法在黑鲷的多种组织中检测出了生长激素受体基因的表达 ,表达水平在肝脏中最高。该结果与我们曾采用生长激素放射受体分析法对黑鲷生长激素受体所研究的结果相吻合。结论　为进一步深入研究鱼类生长激素受体分子内分泌的调控理论提供了有力手段。