Proteolytic processing of porcine deoxyribonuclease II occurs in lysosomes but is not required for enzyme activation.

DNase II purified from porcine spleen (pDNase II) comprises alpha(1), alpha(2) and beta subunits. The three subunits are encoded by one cDNA, in the sequence alpha(1), beta, and alpha(2), and the peptides linking these subunits are presumably cleaved out post-translationally. To understand the relevance of post-translational cleavage to pDNase II, recombinant pDNase II (rpDNase II) was produced in human 293T cells by transfection with an expression plasmid containing pDNase II cDNA (pcDNaseII). An 11.5, a 35 and a 46.5 kDa protein were detected in the cell lysates, whereas only a 46.5 kDa protein was detected in the culture medium of the pcDNaseII-transfected cells. The 46.5 kDa rpDNase II secreted into the medium was purified to homogeneity and characterized. MALDI-TOF MS and N-terminal amino acid sequencing of the 46.5 kDa protein revealed a single contiguous polypeptide chain of pDNase II. Zymographic analysis showed that the 46.5 kDa protein digested DNA in acidic conditions and that the specific activity of this rpDNase II was about twice that of pDNase II purified from porcine spleen. Treatment with chloroquine, a lysosomal inhibitor, resulted in the accumulation of only the 46.5 kDa protein in the pcDNaseII-transfected cells. Treatments with cycloheximide 22 h after transfection led to accumulation of the processed enzyme and disappearance of the 46.5 kDa protein. These results suggest that the proteolytic processing of rpDNase II occurs in the lysosome, which is not involved in the activation of pDNase II.

Putative secondary active site of bovine pancreatic deoxyribonuclease I.

Previous structural studies based on the co-crystal of a complex between bovine pancreatic deoxyribonuclease I (bpDNase I) and a double-stranded DNA octamer d(GCGATCGC)(2) have suggested the presence of a putative secondary active site near Ser43. In our present study, several crucial amino acid residues postulated in this putative secondary active site, including Thr14, Ser43, and His44 were selected for site-directed mutagenesis. A series of single, double and triple mutants were thus constructed and tested for their DNase I activity by hyperchromicity assay. Substitution of each or both of Thr14 and Ser43 by alanine results in mutant enzymes retaining 30-70% of WT bpDNase I activity. However, when His44 was replaced by aspartic acid, either in the single, double, or triple mutant, the enzyme activities were drastically decreased to 0.5-5% that of WT bpDNase I. Interestingly, when cysteine was substituted for Thr14 or Ser43, the specific DNase activities of the mutant enzymes were substantially increased by 1.5-100-fold, comparing to their alanine substitution mutant counterparts. Two other more sensitive DNase activity assay method, plasmid scission and zymogram analyses further confirm these observations. These results suggested that His44 may play a critical role in substrate DNA binding in this putative secondary active site, and introduction of sulfhydryl groups at Thr14 and Ser43 may facilitate Mn(2+)-coordination and further contribute to the catalytic activity of bpDNase I.

2-nitro-5-thiosulfobenzoic acid as a novel inhibitor specific for deoxyribonuclease I.

Bovine pancreatic deoxyribonuclease I (bpDNase I) contains four cysteine residues forming two disulfide bonds. Though there are no free sulfhydryl groups, incubation of bpDNase I with 2-nitro-5-thiosulfobenzoic acid (NTSB) in the presence of Ca(2+) or Mg(2+) at pH 7.5 results in inactivation of the enzyme. Amino acid analysis shows that NTSB-treated bpDNase I still contains all 4 half-cystine residues. The only amino acid residues having reduced values are threonine and serine, indicating that these may be the reaction sites for NTSB. Plasmid scission assay and circular dichroism analysis reveal the structural integrity of the inactivated enzyme. Treatment of bpDNase I with NTSB does not result in fragmentation, as demonstrated by SDS-PAGE analysis. NTSB binds bpDNase I through covalent modification, since dialysis and gel filtration can not reverse the inactivation reaction. However, after dilution into an acid buffer of pH 4.7, the inactivated enzyme regains about 40% of its initial activity, suggesting a reversible inactivation by acid treatment. NTSB does not inactivate DNase II, ribonuclease, chymotrypsin and lysozyme, while it effectively inactivates rat parotid DNase I. These results strongly suggest that NTSB can be considered as a novel inhibitor specific for DNase I.

Construction and characterization of a bifunctional enzyme with deoxyribonuclease I and thioredoxin-like activities.

One large essential (C173-C209) and one small nonessential (C101-C104) disulfide loops occur in bovine pancreatic deoxyribonuclease I (bpDNase I). In our recent study, the reduced nonessential disulfide (-CESC-), which is structurally homologous to the active-site motif (-CGPC-) of thioredoxin, was shown to have thioredoxin-like activity. In order to gain further insight into the potential redox activity of the nonessential disulfide in bpDNase I, four double (GP, PG, WK, and KW) and two quadruple (WGPK, KPGW) mutants were constructed. Most of the mutant enzymes possess similar specific DNase activities as that of WT bpDNase I, while KPGW exhibited only half of the activity, possibly due to gross structural alteration, as revealed by CD analysis. All these mutants were able to accelerate the rate of insulin precipitation. The highest thioredoxin-like activity (66%) measured for WGPK indicated that the conserved sequence (-WCGPCK-) of thioredoxin is crucial for its redox activity. Our results suggested that engineering of the nonessential disulfide in bpDNase I was able to generate a novel bifunctional enzyme with enhanced disulfide/dithiol exchange reactivity, while retaining its full DNA-hydrolyzing activity.

Probing the catalytic mechanism of bovine pancreatic deoxyribonuclease I by chemical rescue.

Previous structural and mutational studies of bovine pancreatic deoxyribonuclease I (bpDNase I) have demonstrated that the active site His134 and His252 played critical roles in catalysis. In our present study, mutations of these two His residues to Gln, Ala or Gly reduced the DNase activity by a factor of four to five orders of magnitude. When imidazole or primary amines were added exogenously to the Ala or Gly mutants, the residual DNase activities were substantially increased by 60-120-fold. The rescue with imidazole was pH- and concentration-dependent. The pH-activity profiles showed nearly bell-shaped curves, with the maximum activity enhancement for H134A at pH 6.0 and that for H252A at pH 7.5. These findings indicated that the protonated form of imidazole was responsible for the rescue in H134A, and the unprotonated form was for that in H252A, prompting us to assign unambiguously the roles for His134 as a general acid, and His252 as a general base, in bpDNase I catalysis.

Structure and function of bovine pancreatic deoxyribonuclease I.

Bovine pancreatic deoxyribonuclease I (bpDNase), the first DNase discovered, is the best characterized among various types of DNase. A catalytic mechanism has been suggested based on the X-ray structure of the bpDNase-octamer complex. In this review, we will focus on three aspects: 1) the distinctive functions of the two structural calcium atoms; 2) the biological functions of the two disulfides; and 3) the involvement of the N- and C-terminal fragments in the enzyme folding for activity.

Identification of three crucial histidine residues (His115, His132 and His297) in porcine deoxyribonuclease II.

DNase II is an acid endonuclease that is involved in the degradation of exogenous DNA and is important for DNA fragmentation and degradation during cell death. In an effort to understand its catalytic mechanism, we constructed plasmids encoding nine different histidine (H)-to-leucine (L) mutants for porcine DNase II and examined the enzyme properties of the expressed mutant proteins. Of the mutants, all but H132L were secreted into the medium of expressing cells. Six of the mutated DNase II proteins (H41L, H109L, H206L, H207L, H274L and H322L) showed enzyme activity, whereas the H115L, H132L and H297L mutants exhibited very little activity. The H115L and H297L mutants were found to undergo correct protein folding, but were inactive. To further examine these mutants, we expressed H115A and H297A DNase II mutants; these mutants were inactive, but their DNase activities could be rescued with imidazole, indicating that His115 and His297 are likely to function as a general acid and a general base respectively in the catalytic centre of the enzyme. In contrast with the secreted mutants, the H132L mutant protein was found in cell lysates within 16 h after transfection. This protein was inactive, improperly folded and was drastically degraded via the proteosomal pathway after 24 h. The polypeptide of another substitution for His132 with lysine resulted in the misfolded form being retained in endoplasmic reticulum.

Involvement of the N- and C-terminal fragments of bovine pancreatic deoxyribonuclease in active protein folding.

The three-dimensional structure of bovine pancreatic (bp) DNase revealed that its N- and C-termini form an antiparallel beta-sheet structure. The involvement of this beta-sheet structure in the active protein folding of bpDNase was thus investigated via a series of deletion and substitution variants. Several substitution variants of N-terminal Leu1 and C-terminal Leu259, and one variant with only the last Thr260 deleted, remained fully active. However, the other deletion variants, in which 2-10 amino acid residues were removed from the C- or N-terminus, all lost the DNase activity. The results indicated that the backbone hydrogen bonding in the antiparallel beta-sheet, rather than the side-chain interactions, is crucial for the correct protein folding. When the deletion variants were complemented with synthetic peptides of the deleted N- or C-terminal sequences, the DNase activity was generated. The highest DNase activity was generated when the C-terminal 10-residue-deleted brDNase(Delta251-260) was admixed with the C-terminal 10-residue peptide (peptide C10) in a molar ratio of 1:400. The noncovalent binding between brDNase(Delta251-260) and peptide C10 exhibited a dissociation constant of 48 microM. Circular dichroism spectra showed that the deletion variants were partially folded with mainly helical structures and that admixture with corresponding peptides facilitated their folding into the nativelike beta-sheet-rich structure. Thermal denaturation profiles also revealed that the transition temperature for brDNase(Delta251-260) was increased from 55 to 63 degrees C after incubation with peptide C10. The folding activation process for the deletion variant occurred in two stages, and Ca(2+) was required.

Biological functions of the disulfides in bovine pancreatic deoxyribonuclease.

We characterized the biochemical functions of the small nonessential (C101-C104) and the large essential (C173-C209) disulfides in bovine pancreatic (bp) DNase using alanine mutants [brDNase(C101A)] and [brDNase(C173A) and brDNase(C209A)], respectively. We also characterized the effects of an additional third disulfide [brDNase(F192C/A217C)]. Without the Ca(2+) protection, bpDNase and brDNase(C101A) were readily inactivated by trypsin, whereas brDNase(F192C/A217C) remained active. With Ca(2+), all forms of DNase, except for brDNase(C101A), were protected against trypsin. All forms of DNase, after being dissolved in 6 M guanidine-HCl, were fully reactivated by diluting into a Ca(2+)-containing buffer. However, when diluted into a Ca(2+)-free buffer, bpDNase and brDNase(C101A) remained inactive, but 60% of the bpDNase activity was restored with brDNase(F192C/A217C). When heated, bpDNase was inactivated at a transition temperature of 65 degrees C, brDNase(C101A) at 60 degrees C, and brDNase(F192C/A217C) at 73 degrees C, indicating that the small disulfide, albeit not essential for activity, is important for the structural integrity, and that the introduction of a third disulfide can further stabilize the enzyme. When pellets of brDNase(C173A) and brDNase(C209A) in inclusion bodies were dissolved in 6 M guanidine-HCl and then diluted into a Ca(2+)-containing buffer, 10%-18% of the bpDNase activity was restored, suggesting that the "essential" disulfide is not absolutely crucial for enzymatic catalysis. Owing to the structure-based sequence alignment revealing homology between the "nonessential" disulfide of bpDNase and the active-site motif of thioredoxin, we measured 39% of the thioredoxin-like activity for bpDNase based on the rate of insulin precipitation (DeltaA650nm/min). Thus, the disulfides in bpDNase not only play the role of stabilizing the protein molecule but also may engage in biological functions such as the disulfide/dithiol exchange reaction.

Chicken deoxyribonuclease: purification, characterization, gene cloning and gene expression.

Chicken DNase was purified to apparent homogeneity from the pancreas extract. It showed two isoforms, A and B forms, on cation-exchange chromatography. On SDS-PAGE it was a 30-kDa protein. When analyzed on an electrospray-mass analyzer, form A showed a major mass peak of 30859, and form B, 30882. The enzyme was bound to concanavalin A, indicating its glycoprotein nature. The carbohydrate side chain could be removed by endoglycosidase F. Chicken DNase was activated by metal ions and for half-maximum activation, Mn2+ and Mg2+ required were 1 mM and 4 mM, respectively. The pH optimum was between 7 and 8 depending on the metal ions used. In the presence of Cu2+, it was almost completely inactivated by 0.1 M iodoacetate within 1 min. In the absence of Ca2+ at pH 8, chicken DNase resisted to the trypsin or beta-mercaptoethenol inactivation. When the purified enzyme was subjected to protein sequencing, approximately 93% of the sequence was established. Based on the amino acid sequence, the cDNA of chicken DNase was amplified, cloned and sequenced. The cDNA sequence consisted of 1079 nucleotides in which 67 were of the 5'-untranslated region and 166 of the 3' and, in the 5'-untranslated region, two types of sequences occurred. The polypeptide chain of 282 amino acids, translated from the open reading frame, was composed of the mature protein of 262 amino acids and a putative signal peptide of 20 amino acids. As compared with mammalian DNases, chicken DNase had an overall 58 +/- 61% sequence identity, one less potential N-glycosylation site, and one extra disulfide. The cDNA was cloned into the pET15b expression vector. When induced, active recombinant chicken DNase was expressed in Escherichia coli strain BL21(DE3)pLysS and was present in the insoluble fraction of cell lysates.

Expression of DNase I in rat parotid gland and small intestine is regulated by starvation and refeeding.

DNase I in rats is mainly expressed in the parotid gland and the small intestine and functions as a digestive enzyme. Male Wistar rats were deprived of food for 48 h, refed with nonpurified diet for 2 h and killed at 0, 0.33, 0.67, 1, 2, 6 or 12 h. The activity and mRNA of DNase I in the parotid gland and the small intestine were determined. We found that in rats that were not fed for 48 h there was accumulation of DNase I in the parotid gland but not in the small intestine. In the parotid gland, refeeding decreased DNase I activity (P < 0.05), perhaps due to an increase in secretion. The increase in DNase I mRNA probably resulted from the need for protein synthesis. However, in the small intestine, both the enzyme activity and the amount of mRNA were up-regulated by refeeding (P < 0.05). Exposing rats to food in a sealed transparent flask also caused a 2.5-fold increase in DNase I mRNA within 30 min in the parotid gland. These data suggested that the expression of rat parotid DNase I is up-regulated by feeding and that mastication is not essential for the regulation.

The distinctive functions of the two structural calcium atoms in bovine pancreatic deoxyribonuclease.

The two amino acid residues, Asp 99 and Asp 201, involved in the coordination of the two calcium atoms in the X-ray structure of bovine pancreatic (bp) DNase, were individually changed by site-directed mutagenesis. The two altered proteins, brDNase(D99A) and brDNase(D201A) were expressed in Escherichia coli and purified by anion exchange chromatography. Equilibrium dialysis showed that mutation destroyed one Ca(2+)-binding site each in brDNase(D99A) and brDNase(D201A). Compared with bpDNase, the Vmax value for brDNase(D99A) remained unchanged and that for brDNase(D201A) was decreased, whereas the K(m) values for the two variants were increased two- to threefold when the DNA hydrolytic hyperchromicity assay was used. Like bpDNase, brDNase(D99A) was able to make double scission on duplex DNA with Mg(2+) plus Ca(2+) and was effectively protected by Ca(2+) from the trypsin inactivation. But under the same conditions, brDNase(D201A) lost the double-scission ability and was not protected by Ca(2+). Nevertheless, the two variant proteins retained the characteristics of the Ca(2+)-induced conformational changes and the Ca(2+) protection against the beta-mercaptoethanol disruption of the essential disulfide bond, suggesting that other weaker Ca(2+)-binding sites not found in the X-ray structure were responsible for these properties. Therefore, the two structural calcium atoms are not for maintaining the overall conformation of the active DNase, as it has been indicated in the X-ray analysis, but rather play the role in the fine-tuning of the DNase activity.