Rabbit DNase I: purification from urine, immunological and proteochemical characterization, nucleotide sequence, expression in tissues, relationships with other mammalian DNases I and phylogenetic analysis

Controlling Nuclease Degradation of Wireframe DNA Origami with Minor Groove Binders

Viruslike particles (VLPs) fabricated using wireframe DNA origami are emerging as promising vaccine and gene therapeutic delivery platforms due to their programmable nature that offers independent control over their size and shape, as well as their site-specific functionalization. As materials that biodegrade in the presence of endonucleases, specifically DNase I and II, their utility for the targeting of cells, tissues, and organs depends on their stability in vivo. Here, we explore minor groove binders (MGBs) as specific endonuclease inhibitors to control the degradation half-life of wireframe DNA origami. Bare, unprotected DNA-VLPs composed of two-helix edges were found to be stable in fetal bovine serum under typical cell culture conditions and in human serum for 24 h but degraded within 3 h in mouse serum, suggesting species-specific endonuclease activity. Inhibiting endonucleases by incubating DNA-VLPs with diamidine-class MGBs increased their half-lives in mouse serum by more than 12 h, corroborated by protection against isolated DNase I and II. Our stabilization strategy was compatible with the functionalization of DNA-VLPs with HIV antigens, did not interfere with B-cell signaling activity of DNA-VLPs in vitro, and was nontoxic to B-cell lines. It was further found to be compatible with multiple wireframe DNA origami geometries and edge architectures. MGB protection is complementary to existing methods such as PEGylation and chemical cross-linking, offering a facile protocol to control DNase-mediated degradation rates for in vitro and possibly in vivo therapeutic and vaccine applications.

Origin and significance of the human DNase repertoire

The human genome contains four DNase1 and two DNase2 genes. The origin and functional specialization of this repertoire are not fully understood. Here we use genomics and transcriptomics data to infer the evolutionary history of DNases and investigate their biological significance. Both DNase1 and DNase2 families have expanded in vertebrates since ~ 650 million years ago before the divergence of jawless and jawed vertebrates. DNase1, DNase1L1, and DNase1L3 co-existed in jawless fish, whereas DNase1L2 originated in amniotes by tandem duplication of DNase1. Among the non-human DNases, DNase1L4 and newly identified DNase1L5 derived from early duplications that were lost in terrestrial vertebrates. The ancestral gene of the DNase2 family, DNase2b, has been conserved in synteny with the Uox gene across 700 million years of animal evolution,while DNase2 originated in jawless fish. DNase1L1 acquired a GPI-anchor for plasma membrane attachment in bony fishes, and DNase1L3 acquired a C-terminal basic peptide for the degradation of microparticle DNA in jawed vertebrates. The appearance of DNase1L2, with a distinct low pH optimum and skin localization, is among the amniote adaptations to life on land. The expansion of the DNase repertoire in vertebrates meets the diversified demand for DNA debris removal in complex multicellular organisms.

Purification and characterization of deoxyribonuclease from small intestine of camel Camelus dromedarius

The chromatography of deoxyribonuclease (DNase) from small intestine of camel Camelus dromedarius by DEAE-Sepharose separated three isoforms DNase 1, DNase 2 and DNase 3. The DNase 3 was purified to homogeneity by chromatography on Sephacryl S-200. The molecular weight of DNase 3 was 30 kDa using gel filtration and SDS-PAGE. The pH optimum of DNase 3 was reported at 7.0 using Tris-HCl buffer. The temperature optimum of DNase 3 was found to be 50 °C. The enzyme was stable up to 50 °C for one h incubation. The Km value was 28.5 µg DNA, where this low value indicated the high affinity of enzyme toward DNA as substrate. No activity of DNase 3 was determined in the absence of metal cations. Mg2+ and Ca2+ caused significant enhancement in the enzyme activity by 90 and 75%, respectively. The mixture of Mg2+ and Ca2+ caused 100% of enzyme activity. Ni2+, Co2+, Ba2+, Zn2+ and Cd2+ showed very strong inhibitory effect on enzyme activity. In conclusion, the characterization of DNase 3 indicated that the enzyme is considered as a member of DNase I family. The low Km value of the DNA suggested that the high digestion of DNA of camel forage by small intestine DNase 3.

DNA-hydrolyzing activity of IgG antibodies from the sera of patients with tick-borne encephalitis

DNase autoantibodies (Abzs) can be found in the blood of patients with several autoimmune diseases, while the blood of healthy donors or patients with diseases with an insignificant disturbance of the immune status does not contain DNase Abzs. Here we present the first analysis of the DNase Abzs activity in the patients with tick-borne encephalitis (TBE). Several strict criteria have been applied to show that the DNase activity is an intrinsic property of IgGs from the sera of TBE patients but not from healthy donors. The relative activity of IgGs has been shown to vary extensively from patient to patient, but most of the preparations (91%) had detectable levels of the DNase activity. Polyclonal DNase IgGs were not active in the presence of EDTA or after a dialysis against EDTA, but could be activated by several externally added metal ions, with the level of activity decreasing in the order Mn(2+) + Ca(2+) > or = Mn(2+)+ Mg(2+) > or = Mn(2+) > or = Mg(2+) + Ca(2+) > or = Co(2+) > or = Mg(2+) > Ca(2+), while K(+), Na(+), Ni(2+), Zn(2+), and Cu(2+) did not stimulate DNA hydrolysis. Affinity chromatography on DNA-cellulose separated the DNase IgGs into many subfractions with various affinities for DNA and very different levels of the relative activity. Possible reasons for catalytic diversity of polyclonal human Abzs are discussed.

Antibodies against DNA hydrolyze DNA and RNA

In this work, rabbits were immunized with a high polymer DNA complexed with methylated BSA (mBSA) and by mBSA. It is shown that electrophoretically homogeneous preparations of polyclonal antibodies (Ab) from non-immunized rabbits and animals immunized by mBSA do not exhibit catalytic activity. Ab from the blood of rabbits immunized with the DNA-mBSA complex hydrolyzed poly(C) and different RNAs with efficiency exceeding that towards DNA by approximately 3-4 orders of magnitude. Affinity chromatography of the IgG on DNA cellulose separated the Ab into fractions hydrolyzing both RNA and DNA, and for the first time fractions that hydrolyze only RNA were found. Kinetic parameters that characterize the RNA and DNA hydrolysis by initial Ab preparations and their fractions obtained by separation on an affinity sorbent are compared.

Antibodies against RNA hydrolyze RNA and DNA

Immunization of animals with DNA leads to the production of anti-DNA antibodies (Abs) demonstrating both DNase and RNase activities. It is currently not known whether anti-RNA Abs can possess nuclease activities. In an attempt to address this question, we have shown that immunization of three rabbits with complex of RNA with methylated BSA (mBSA) stimulates production of IgGs with RNase and DNase activities belonging to IgGs, while polyclonal Abs from three non-immunized rabbits and three animals immunized with mBSA are catalytically inactive. Affinity chromatography of IgGs from the sera of autoimmune (AI) patients on DNA-cellulose usually demonstrates a number of fractions, all of which effectively hydrolyze both DNA and RNA, while rabbit catalytic IgGs were separated into Ab subfractions, some of which demonstrated only DNase activity, while others hydrolyzed RNA faster than DNA. The enzymic properties of the RNase and DNase IgGs from rabbits immunized with RNA distinguish them from all known canonical RNases and DNases and DNA- and RNA-hydrolyzing abzymes (Abzs) from patients with different AI diseases. In contrast to RNases and AI RNA-hydrolyzing Abs, rabbit RNase IgGs catalyze only the first step of the hydrolysis reaction but cannot hydrolyze the formed terminal 2',3'-cyclophosphate. The data indicate that Abzs of AI patients hydrolyzing nucleic acids in part may be Abs against RNA and its complexes with proteins.

Immunization of rabbits with DNase I produces polyclonal antibodies with DNase and RNase activities

Immunization of rabbits with DNase I leads to the production of antiidiotypic Abs with DNase activity. It is not known at present whether antiidiotypic Abs against DNA-hydrolyzing enzymes can possess RNase activity. Here we show that immunization of healthy rabbits with bovine DNase I produces IgGs with intrinsic DNase and RNase activities. Electrophoretically and immunologically homogeneous polyclonal IgGs were obtained by sequential chromatography of the immune sera on Protein A-Sepharose and gel filtration. Affinity chromatography on DNA cellulose using elution of Abs with different concentrations of NaCl and an acidic buffer separated catalytic IgGs into four Ab subfractions, three of which demonstrated only DNase activity while one subfraction hydrolyzed RNA faster than DNA. The serum of patients with many different autoimmune (AI) diseases contains small fractions of antibodies (Abs) interacting with immobilized DNA, which possess both DNase and RNase activities. Our data suggest that a fraction of abzymes from AI patients hydrolyzing both DNA and RNA can contain a subfraction of Abs against DNase I.

Susceptibility of mammalian deoxyribonucleases I (DNases I) to proteolysis by proteases and its relationships to tissue distribution: Biochemical and molecular analysis of equine DNase I

Equine (Equus caballus) deoxyribonuclease I (DNase I) was purified from the parotid gland, and its 1295-bp cDNA was cloned. The mature equine DNase I protein consisted of 260 amino acid residues. The enzymatic properties and structural aspects of the equine enzyme were closely similar to those of other mammalian DNases I. Mammalian DNases I are classified into three types--pancreatic, parotid and pancreatic-parotid-based on their tissue distribution; as equine DNase I showed the highest activity in the parotid gland, it was confirmed to be of the parotid-type. Comparison of the susceptibility of mammalian DNases I to proteolysis by proteases demonstrated a marked correlation between tissue distribution and sensitivity/resistance to proteolysis; pancreatic-type DNase I shared properties of resistance to proteolysis by trypsin and chymotrypsin, whereas parotid-type DNase I did not. In contrast, pancreatic-parotid-type DNase I exhibited resistance to proteolysis by pepsin, whereas the other enzyme types did not. However, site-directed mutagenesis analysis revealed that only a single amino acid substitution could not account for acquisition of proteolysis resistance in the mammalian DNase I family during the course of molecular evolution. These properties are compatible with adaptation of mammalian DNases I for maintaining their activity in vivo.

Hepatopancreatic nuclease of black tiger shrimp Penaeus monodon unlikely to be involved in viral triggered apoptosis

Nucleases are phosphodiesterases that hydrolyze DNA and/or RNA. In a search for shrimp nucleases involved in apoptosis, we discovered a nuclease from hepatopancreatic cDNA of the black tiger shrimp Penaeus monodon. The full-length nuclease gene was amplified and revealed to contain 1668bp corresponding to 381 deduced amino acid residues in the mature enzyme. Sequence analysis indicated 83% nucleic acid identity and 89% amino acid identity to a nuclease from the Kuruma shrimp Penaeus japonicus (also called Marsupenaeus japonicus). Comparative analysis of sequences, conserved motifs and phylogenetic trees indicated that P. monodon nuclease (PMN) belonged to the family of DNA/RNA non-specific endonucleases (DRNSN). RT-PCR analysis using primers specific for PMN mRNA with seven different shrimp tissues revealed that expression in normal shrimp was restricted to the hepatopancreas. Semiquantitative RT-PCR analysis of PMN using hepatopancreatic mRNA from normal shrimp and from shrimp challenged with white spot syndrome virus (WSSV) indicated significant up-regulation of PMN in the hepatopancreas (P<0.05) at the early stage of viral infection but a return to baseline levels as gross signs of disease developed. At the same time, expression was always confined to the hepatopancreas and never seen in other tissues, including those reported to be prime targets for WSSV and subject to increased levels of apoptosis after infection. The results suggested that PMN is probably a digestive enzyme that is unlikely to be involved in hallmark DNA digestion associated with apoptosis.

Actin-inhibition and folding of vertebrate deoxyribonuclease I are affected by mutations at residues 67 and 114

Amino acid (aa) residues (Val-67 and Ala-114) have been suggested as being mainly responsible for actin-binding in human and bovine deoxyribonucleases I (DNase I). This study presents evidence of these two aa mutational mechanisms, not only for actin-binding but also for folding of DNase I in mammals, reptiles and amphibians. Human and viper snake (Agkistrodon blomhoffii) enzymes are inhibited by actin, whereas porcine, rat snake (Elaphe quadrivirgata), and African clawed frog (Xenopus laevis) enzymes are not. To investigate the role of aa at 67, mutants of rat snake (Ile67Val) and viper snake (Val67Ile) enzymes were constructed. After substitution, the rat snake was inhibited by actin, while the viper snake was not. For the role of aa at 114, mutants of viper snake (Phe114Ala), rat snake (Phe114Ala), African clawed frog (Phe114Ala), and porcine (Ser114Ala/Ser114Phe) enzymes were constructed. Strikingly, the substitute mutants for viper snake, rat snake and African clawed frog expressed no protein. The porcine (Ser114Ala) enzyme was inhibited by actin, but not the porcine (Ser114Phe) enzyme. These results suggest that Val-67 may be essential for actin-binding, that Phe-114 may be related to the folding of DNase I in reptiles and amphibians, and that Ala-114 may be indispensable for actin-binding in mammals.

One-step purification of mammalian deoxyribonucleases I and differences among pancreas, parotid, and pancreas-parotid (mixed) types based on species-and organ-specific N-linked glycosylation

Mammalian deoxyribonucleases I (DNase I) are classified into three types, namely, pancreas, parotid, and pancreas-parotid (mixed), based on differences in their tissue concentrations. In this study, DNase I purification by concanavalin A-wheat germ agglutinin mixture-agarose column from rat (parotid type), rabbit (mixed type), and pig (pancreas type) is described. This method permits a relatively easy one-step purification of DNase I from rat and rabbit parotid glands, the rat submaxillary gland, and porcine pancreas. To elucidate differences among the three types, these DNases I were subjected to enzymatic deglycosylation either by peptide N-glycosidase F (PNGase F) or endoglycosidase H (Endo H). Following deglycosylation, digests were separated on DNA-casting polyacrylamide gel electrophoresis. PNGase F produced a single lower mobility product in all samples. Endo H produced a double band in rat and rabbit parotid glands and porcine pancreas, and a single band in the rabbit pancreas corresponding with the PNGase F product. DNase I activity of the porcine pancreas was completely extinguished by deglycosylation, while that of the parotid glands and rabbit pancreas was unaffected. Our results suggest that the distinct properties of DNase I exhibited by the three types may be attributed to differences in the extent of post-translational N-linked glycosylation of the enzyme.

Carp liver DNase—isolation, further characterization and interaction with endogenous actin

Deoxyribonuclease I (DNase I)-like enzyme from the liver of the carp (Cyprinus carpio) was purified to homogeneity and further characterized. Ion exchange chromatography on DEAE-cellulose, molecular filtration on Sephacryl S-300 and Con A-Sepharose affinity chromatography were applied for enzyme isolation. Carp liver DNase, similarly to DNase I from bovine pancreas, was found to be an endonuclease that hydrolyses linear DNA from salmon sperm as well as circular DNA forms--plasmid and cosmid. The purified enzyme is a glycoprotein and shows microheterogeneity, as observed in DNase zymograms prepared after native and two-dimensional electrophoresis (2D-PAGE). The composition of sugar component of the enzyme was characterized. Special attention was focused on the ability of carp liver DNase to interact with carp liver actin. The carp liver enzyme was inhibited by endogenous actin. The estimated binding constant of carp liver DNase to carp liver actin was calculated to be 1.1 x 10(6) M(-1).

Expression pattern of the deoxyribonuclease 1 gene: lessons from the Dnase1 knockout mouse

The tissue distribution of deoxyribonuclease 1 (DNASE1, DNase I), a Ca2+ and Mg2+/Mn2+-dependent secretory endonuclease, has previously been investigated. However, most of these studies did not account for the existence of different members of the DNASE1 gene family, did not differentiate between endogenous DNASE1 protein synthesis and its extracellular occurrence or were not performed with methods allowing both a sensitive and a specific detection. Now we re-examined the DNASE1 gene expression pattern by taking advantage of the Dnase1 knockout mouse model. Direct comparison of samples derived from wild-type (Dnase1+/+) and knockout (Dnase1-/-) mice allowed an unambiguous detection of Dnase1 gene expression at the mRNA and protein level. For the detection of Dnase1 activity, we developed a highly sensitive nuclease zymogram method. We observed high Dnase1 gene expression in the parotid and submandibular gland as well as in the kidney and duodenum, intermediate expression in the ileum, mesenterial lymph nodes, liver, ventral prostate, epididymis, ovary and stomach, and low expression in the sublingual, preputial, coagulation and pituitary gland. We report for the first time the lachrymal and thyroid glands, the urinary bladder and the eye to be Dnase1-expressing organs as well. Since Dnase1 knockout mice with the 129xC57Bl/6 mixed genetic background have indicated the protection against an anti-DNA autoimmune response as a new physiological function of Dnase1, knowledge of the physiological sites of its synthesis might prove helpful to find new therapeutic strategies.

Molecular evolution of shark and other vertebrate DNases I

We purified pancreatic deoxyribonuclease I (DNase I) from the shark Heterodontus japonicus using three-step column chromatography. Although its enzymatic properties resembled those of other vertebrate DNases I, shark DNase I was unique in being a basic protein. Full-length cDNAs encoding the DNases I of two shark species, H. japonicus and Triakis scyllia, were constructed from their total pancreatic RNAs using RACE. Nucleotide sequence analyses revealed two structural alterations unique to shark enzymes: substitution of two Cys residues at positions 101 and 104 (which are well conserved in all other vertebrate DNases I) and insertion of an additional Thr or Asn residue into an essential Ca(2+)-binding site. Site-directed mutagenesis of shark DNase I indicated that both of these alterations reduced the stability of the enzyme. When the signal sequence region of human DNase I (which has a high alpha-helical structure content) was replaced with its amphibian, fish and shark counterparts (which have low alpha-helical structure contents), the activity expressed by the chimeric mutant constructs in transfected mammalian cells was approximately half that of the wild-type enzyme. In contrast, substitution of the human signal sequence region into the amphibian, fish and shark enzymes produced higher activity compared with the wild-types. The vertebrate DNase I family may have acquired high stability and effective expression of the enzyme protein through structural alterations in both the mature protein and its signal sequence regions during molecular evolution.

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.

A single amino acid substitution can shift the optimum pH of DNase I for enzyme activity: biochemical and molecular analysis of the piscine DNase I family

We purified four piscine deoxyribonucleases I (DNases I) from Anguilla japonica, Pagrus major, Cryprus carpio and Oreochromis mossambica. The purified enzymes had an optimum pH for activity of approximately 8.0, significantly higher than those of mammalian enzymes. cDNAs encoding the first three of these piscine DNases I were cloned, and the sequence of the Takifugu rubripes enzyme was obtained from a database search. Nucleotide sequence analyses revealed relatively greater structural variations among the piscine DNase I family than among the other vertebrate DNase I families. From comparison of their catalytic properties, the vertebrate DNases I could be classified into two groups: a low-pH group, such as the mammalian enzymes, with a pH optimum of 6.5-7.0, and a high-pH group, such as the reptile, amphibian and piscine enzymes, with a pH optimum of approximately 8.0. The His residue at position 44 of the former group is replaced by Asp in the latter. Replacement of Asp44 of piscine and amphibian DNases I by His decreased their optimum pH to a value similar to that of the low-pH group. Therefore, Asp44His might be involved in an evolutionarily critical change in the optimum pH for the activity of vertebrate DNases I.

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.

A single amino acid substitution of Leu130Ile in snake DNases I contributes to the acquisition of thermal stability

We purified pancreatic deoxyribonucleases I (DNases I) from three snakes, Elaphe quadrivirgata, Elaphe climacophora and Agkistrodon blomhoffii, and cloned their cDNAs. Each mature snake DNase I protein comprised 262 amino acids. Wild-type snake DNases I with Leu130 were more thermally unstable than wild-type mammalian and avian DNases I with Ile130. After substitution of Leu130Ile, the thermal stabilities of the snake enzymes were higher than those of their wild-type counterparts and similar to mammalian wild-type enzyme levels. Conversely, substituting Ile130Leu of mammalian DNases I made them more thermally unstable than their wild-type counterparts. Therefore, a single amino acid substitution, Leu130Ile, might be involved in an evolutionally critical change in the thermal stabilities of vertebrate DNases I. Amphibian DNases I have a Ser205 insertion in a Ca2+-binding site of mammalian and avian enzymes that reduces their thermal stabilities [Takeshita, H., Yasuda, T., Iida, R., Nakajima, T., Mori, S., Mogi, K., Kaneko, Y. & Kishi, K. (2001) Biochem. J.357, 473-480]. Thus, it is plausible that the thermally stable wild-type DNases I of the higher vertebrates, such as mammals and birds, have been generated by a single Leu130Ile substitution of reptilian enzymes through molecular evolution following Ser205 deletion from amphibian enzymes. This mechanism may reflect one of the evolutionary changes from cold-blooded to warm-blooded vertebrates.

Production and characterization of murine monoclonal anti-human DNase II antibodies, and their use for immunoaffinity purification of DNase II from human liver and urine

Four murine monoclonal anti-human deoxyribonuclease II (DNase II) antibodies were obtained from BALB/c mice immunized with human DNase II purified from human liver. Both single radial enzyme diffusion (SRED) and DNA-cast polyacrylamide gel electrophoresis (DNA-cast PAGE) were very useful for obtaining the DNase II-specific antibodies. All of the antibodies showed specific inhibition of human DNase II enzyme activity and specific immunostaining of the 32-kDa enzyme band, which is one of the three non-identical subunits of human DNase II molecule separated by sodium dodecyl sulfate (SDS)-PAGE followed by blotting on a transfer membrane. A formyl-cellulofine resin conjugated with each antibody specifically adsorbed and efficiently desorbed the active DNase II enzyme. Insertion of the immunoaffinity step in our purification procedure made the purification of human DNase II easier, faster and more effective than the conventional procedure.

Abrupt pubertal elevation of DNase I gene expression in human pituitary glands of both sexes

Deoxyribonuclease I (DNase I) was confirmed to be expressed in the human pituitary gland, particularly the anterior lobe, at levels comparable to those in the pancreas. The DNase I activity and the amount of gene transcript present in the pituitary glands of individuals aged from 1 month to 89 years was significantly age-dependent, with an abrupt elevation after the neonatal and prepubertal periods irrespective of gender, followed by a gradual age-dependent decline in males and a marked reduction in females in their postreproductive period. This DNase I age dependence in the pituitary gland was not present in the pancreas and serum. These observations suggest that tissue-specific up-regulation of DNase I gene expression in the pituitary gland occur, possibly at the onset of puberty.

DNase I is present in the chief cells of human and rat stomachs

The distribution of deoxyribonuclease I (DNase I) in human and rat stomachs was examined by biochemical, molecular biological and immunohistochemical techniques. By the use of monoclonal anti-human DNase I and polyclonal anti-rat DNase I antibodies, we determined that strong immunoreactivity was present in the cytoplasm of chief cells of the human fundus and the rat pars glandularis, respectively. High DNase I enzyme activity was detected in tissue homogenates of both human fundus and rat pars glandularis. The presence of DNase I-specific mRNA was verified by reverse transcriptase-polymerase chain reaction analysis of the total RNAs extracted from human and rat stomachs. Immunoelectron microscopy revealed gold particles localized in the chief cells, with most labelling in exocrine secretory granules. These results show that the chief cells of human and rat stomach produce DNase I. This is the first report to demonstrate that secretion of DNase I is controlled by the chief cells in human and rat stomachs.

Amphibian DNases I are characterized by a C-terminal end with a unique, cysteine-rich stretch and by the insertion of a serine residue into the Ca2+-binding site

We purified four amphibian deoxyribonucleases I from the pancreases of one toad, two frog and one newt species, by using three different column chromatography methods in sequence. Each of the purified enzymes had a molecular mass of approx. 40 kDa and an optimal pH for activity of approx. 8.0. These values were significantly greater than those for other vertebrate DNases I. The full-length cDNA encoding each amphibian DNase I was constructed from the total RNA of the pancreas by using rapid amplification of cDNA ends. Nucleotide sequence analyses revealed two structural characteristics unique to amphibian DNases I: a stretch of approx. 70 amino acids with a high cysteine content (approx. 15%) in the C-terminal region, and the insertion of a serine residue at position 205 (in a domain containing an essential Ca2+-binding site). Expression analysis of a series of mutant constructs indicated that both of these structures are essential in generating the active form of the enzyme. 'DNase I signature sequences', which are well conserved in other vertebrate DNases I, could not be found in any of the amphibian DNases I tested, whereas a 'somatomedin B motif' was identified in the Cys-rich stretches of all four. Although DNase I has so far been considered to be a secretory glycoprotein, amphibian DNase I seems to be non-glycosylated. These structural findings indicate strongly that amphibian DNases I are situated in a unique position on the phylogenetic tree of the DNase I family.

Molecular, biochemical and immunological analyses of porcine pancreatic DNase I

Deoxyribonuclease I (DNase I) was purified 26500-fold in 39% yield from porcine pancreas to electrophoretic homogeneity using three-step column chromatography. The purified enzyme was inhibited by an antibody specific to the purified enzyme but not by G-actin. A 1303 bp cDNA encoding porcine DNase I was constructed from total RNA from porcine small intestine using a rapid amplification of cDNA ends method, followed by sequencing. Mature porcine DNase I protein was found to consist of 262 amino acids. Unlike all other mammalian DNase I enzymes that are inhibited by G-actin, porcine DNase I has H65 and S114 instead of Y65 and A114, which presumably results in the lack of inhibition. Porcine DNase I was more sensitive to low pH than rat or bovine enzymes. Compared with their primary structures, the amino acid at position 110 was N in porcine enzyme, but S in rat and bovine enzymes. A porcine mutant enzyme in which N was substituted by S alone at position 110 (N110S) became resistant to low pH to a similar extent as the rat and bovine enzymes.

Molecular cloning of cDNA encoding Xenopus laevis deoxyribonuclease I

A 1200-bp cDNA encoding Xenopus laevis deoxyribonuclease I (X. laevis DNase I) was constructed from the total RNA of a X. laevis pancreas using a rapid amplification of cDNA ends method. When the cDNA was transiently transfected into COS-7 cells, the recombinant polypeptide exhibited similar enzymological properties to those of the native pancreatic DNase I. The recombinant enzyme was considerably more labile than most other vertebrate DNase I enzymes. The X. laevis DNase I polypeptide was larger than any other known vertebrate DNase I, containing a unique Cys-rich stretch of 68 or 70 amino acid residues at the carboxyl terminus, and it had less well conserved binding sites for the Ca2+, G-actin and DNA, and two DNase I signature motifs. These alterations might account for its heat instability.

DNase I: structure, function, and use in medicine and forensic science

In this review, available structural data of deoxyribonucleases I (DNases I) from several mammalian species, hen, snake and frog are summarized. Comparative studies on enzymatic and immunological properties and glycosylation are discussed, and several evolutionary conclusions are presented. Over the past decade, the availability of new investigative tools, including sensitive methods of electrophoresis, detection and determination, and genetically modified DNase I models has resulted in a clearer understanding of the molecular mechanisms that connect the function and usefulness of DNase I in medicine and forensic science.

Tissue-specific in vivo inhibition of DNase I gene expression by somatostatin

Administration of somatostatin to rats induced a transient reduction of serum levels of deoxyribonuclease I (DNase I) activity in a dose-dependent manner, followed by a substantial decrease of DNase I activity in the lower gut. Activity in the parotid gland, liver, and kidney did not change. Real-time PCR analysis of the DNase I gene transcript in ileum indicated that the decrease was due to down-regulation of gene expression. Based on these responses, rat tissues expressing DNase I could be classified into two types, somatostatin-sensitive and somatostatin-resistant, and the level of DNase I activity in the lower gut seems to be controlled by somatostatin.

The efficiency of N-linked glycosylation of bovine DNase I depends on the Asn-Xaa-Ser/Thr sequence and the tissue of origin

Bovine DNase I contains two potential N-linked glycosylation sites with the sequences Asn(18)-Ala-Thr and Asn(106)-Asp-Ser. A previous report established that pancreatic DNase I has only one sugar chain at Asn(18) [Liao, Salnikow, Moore and Stein (1973) J. Biol. Chem. 248, 1489-1495]. We found, however, that bovine DNase I expressed in COS-1 cells was glycosylated about 70% at Asn(106) in addition to being completely glycosylated at Asn(18). Glycosylation of Asn(106) increased to 97% when Asp(107) was mutated to Glu or when Ser(108) was mutated to Thr. Mutation of Asp(107) to Trp had no effect, whereas a substitution with Pro at this position abolished glycosylation of Asn(106). Analysis of the state of glycosylation of DNase I purified from a variety of bovine tissues revealed that DNase I from spleen, submaxillary gland, lung and adrenal had two sugar chains, whereas enzyme from pancreas and kidney had only one sugar chain. These findings demonstrate a major difference in the ability of various tissues to utilize N-linked glycosylation signals that contain suboptimal residues in the second and third positions.

The role of ATP, ADP and divalent cations in the formation of binary and ternary complexes of actin, cofilin and DNase I

Actin is the major cytoskeletal protein of virtually all eukaryotic cells. Actin assembly/disassembly is involved in a variety of cellular processes and actin-binding proteins are essential in regulation of the pool of actin monomers. Cofilin and DNase I are actin-binding proteins, which form both binary (actin-DNase 1, cofilin-actin) and ternary (cofilin-actin-DNase I) complexes with actin. Here we use native gel electrophoresis to examine the roles of ATP, ADP, Ca2+ and Mg2+ in the formation of these complexes as well as on the ability of actin to self-assemble. Conditions which favour actin polymerisation are: ATP (no Me2+) > or = ADP (no Me2+) > ADP-Ca2+ = ADP-Mg2+ > ATP-Mg2+ > ATP-Ca2+. Preferential conditions for the formation of the binary actin-cofilin complex are: ADP-Mg2+ > or = ADP-Ca2+ >> ATP-Ca2+ approximately equals ATP-Mg2+ approximately equals ADP-No Me2+ approximately equals ATP-No Me2+. Actin forms a very tight complex with DNase I in the order: ATP-Ca2+ > or = ATP-Mg2+ approximately equals ADP-Mg2+ approximately equals ADP-Ca2+ > or = ADP-(no Me2+) > ATP-(no Me2+). Effectively, the complex does not form in the presence of ATP and the absence of free Me2+. Finally, the conditions which favour the formation of a ternary complex of cofilin-actin-DNase I resemble the actin-DNase I, namely: ATP-Ca2+ approximately equals ADP-Ca2+ approximately equals ADP-Mg2+ approximately equals ATPMg2+ ADP (no Me2+) > ATP-(no Me2+).

Mammalian deoxyribonucleases I are classified into three types: pancreas, parotid, and pancreas-parotid (mixed), based on differences in their tissue concentrations

Deoxyribonuclease I (DNase I) activities were measured in 14 different tissues from humans and 5 other mammals (bovine, pig, rabbit, rat, and mouse) by using the single radial enzyme diffusion (SRED) method, which is a sensitive and nonradioactive assay for nucleases. The results indicated that these species are classifiable into three groups on the basis of their different tissue distributions of DNase I. In human and pig, the pancreas showed the highest activity of DNase I; in rat and mouse, the parotid glands showed the highest activity; and in bovine and rabbit, both pancreas and parotid glands showed high activity. Therefore we designated human and pig DNase I as pancreas type, rat and mouse DNase I as parotid type, and bovine and rabbit DNase I as pancreas-parotid (or mixed) type. DNase I of the pancreas type was more sensitive to low pH than the other types. DNase I of pancreas type is secreted into the intestinal tract under neutral pH conditions, whereas the other types are secreted from the parotid gland and have to pass through the very acidic conditions in the stomach. Differences in the tissue distribution and acid sensitivity of mammalian DNases I may provide important information about their digestive function from the evolutionary perspective.

Molecular, biochemical and immunological studies of hen pancreatic deoxyribonuclease I

Deoxyribonuclease I (DNase I) was purified from the hen pancreas to electrophoretic homogeneity using six-step column chromatography. The purified enzyme showed a molecular mass of about 33 kDa and maximum activity at pH 7.0. It required divalent cations, Mg2+ and Ca2+, for its activity and was inhibited by EDTA, EGTA and an antibody specific to the purified enzyme but not by G-actin. A 1066-bp cDNA encoding hen DNase I was constructed from the total RNA of a hen pancreas using a combination of the reverse transcriptase-polymerase chain reaction and rapid amplification of cDNA ends methods, followed by sequencing. The cDNA was expressed in Escherichia coli, and the recombinant polypeptide exhibited significant enzyme activity. The mature hen DNase I protein was found to consist of 262 amino acids. In human and bovine DNase I four amino acid residues, Glu-13, Tyr-65, Val-67 and Ala-114 are involved in actin binding, whereas in the hen DNase I these positions were occupied by Asp, Phe, Ser and Phe, respectively. A survey of the DNase I distribution in 15 hen tissues showed that the pancreas had the highest levels of both DNase I enzyme activity and DNase I gene expression. The results of our phylogenetic and immunological analyses indicate that the hen DNase I is not closely related to the mammalian enzymes. This is the first report in which has been described the results of molecular, biochemical and immunological analyses on hen DNase I.

A new allele, DNASE1*6, of human deoxyribonuclease I polymorphism encodes an Arg to Cys substitution responsible for its instability

A new allele, DNASE1*6, of human deoxyribonuclease I (DNase I) has been discovered by isoelectric focusing: its gene product has the most cathodic pI of the six electrophoretic variants. Results of DNA sequencing, mismatched PCR-restriction fragment length polymorphism, and transient transfection of the variant construct showed that the mutant was caused by a C-T transition at nucleotide position 1826, resulting in an Arg to Cys substitution at amino acid position 185 of the mature enzyme. The variant isoenzyme, expressed in COS-7 cells, was more labile than the other types. Instability and an increase in the pI value of the variant suggest that a structural alteration, perhaps due to aberrant formation of a disulfide bond, could occur in the enzyme.

Protein structure and gene cloning of Syncephalastrum racemosum nuclease

The complete amino acid sequence of the fungus Syncephalastrum racemosum (Sr-) nuclease has been delineated on the basis of protein sequencing of the intact protein and its protease-digested peptides. The resulting 250-residue sequence shows a carbohydrate side chain attached at Asn134 and two half-cystine residues (Cys242 and Cys247) cross-linked to form a small disulphide loop. On the basis of the sequence of Sr-nuclease, a computer search in the sequence database yielded 60% and 48% positional identities with the sequences of Cunninghamella echinulata nuclease C1 and yeast mitochondria nuclease respectively, and very little similarity to those of several known mammalian DNases I. Sequence alignment of the three similar nucleases reveals that the single small disulphide loop is unchanged but the carbohydrate attachment in Sr-nuclease is absent from the other two nucleases. Alignment also shows a highly conserved region harbouring Sr-nuclease His85, which is assigned as one of the essential residues in the active site. The cDNA encoding Sr-nuclease was amplified by using reverse transcriptase-mediated PCR with degenerate primers based on its amino acid sequence. Subsequently, specific primers were synthesized for use in the 3' and 5' rapid amplification of cDNA ends (RACE). Direct sequencing of the RACE products led to the deduction of a 1.1 kb cDNA sequence for Sr-nuclease. The cDNA contains an open reading frame of 320 amino acid residues including a 70-residue putative signal peptide and the 250-residue mature protein. Finally, the recombinant Sr-nuclease was expressed in Escherichia coli strain BL21(DE3) in which the recombinant protein, after solubilization with detergent and renaturation, showed both DNase and RNase activities. The assignment of His85 to the active site was further supported by evidence that the mutant protein Sr-nuclease (H85A), in which His85 was replaced by Ala, was not able to degrade DNA or RNA.

Site-directed mutagenesis of phosphate-contacting amino acids of bovine pancreatic deoxyribonuclease I

Bovine pancreatic deoxyribonuclease I (DNase I) is an endonuclease which cleaves double-stranded DNA. Cocrystal structures of DNase I with oligonucleotides have revealed interactions between the side chains of several amino acids (N74, R111, N170, S206, T207, and Y211) and the DNA phosphates. The effects these interactions have on enzyme catalysis and DNA hydrolysis selectivity have been investigated by site-directed mutagenesis. Mutations to R111, N170, T207, and Y211 severely compromised activity toward both DNA and a small chromophoric substrate. A hydrogen bond between R111 (which interacts with the phosphate immediately 5' to the cutting site) and the essential amino acid H134 is probably required to maintain this histidine in the correct orientation for efficient hydrolysis. Both T207 and Y211 bind to the phosphate immediately 3' to the cleavage site. Additionally, T207 is involved in binding an essential, structural, calcium ion, and Y211 is the nearest neighbor to D212, a critical catalytic residue. N170 interacts with the scissile phosphate and appears to play a direct role in the catalytic mechanism. The mutation N74D, which interacts with a phosphate twice removed from the scissile group, strongly reduced DNA hydrolysis. However, a comparison of DNase I variants from several species suggests that certain amino acids, which allow interaction with phosphates (positively charged or hydrogen bonding), are tolerated. S206, which binds to a DNA phosphate two positions away from the cleavage site, appears to play a relatively unimportant role. None of the enzyme variants, including a triple mutation in which N74, R111, and Y211 were altered, affected DNA hydrolysis selectivity. This suggests that phosphate binding residues play no role in the selection of DNA substrates.

Structural requirements of a human deoxyribonuclease II for the development of the active enzyme form, revealed by site-directed mutagenesis

Using site-directed mutagenesis, we eliminated three potential N-glycosylation sites (N86, N212, and N266) of human deoxyribonuclease II (DNase II), conserved in mammalian enzymes, and a proteolytic processing site (Q46-R47), forming a propeptide subunit of the enzyme. We expressed a series of these mutant DNase II constructs in COS-7 and Hep G2 cells. Liberation of each glycosylation site at N86 and N266 and the cleavage site interfered dramatically with expression of the intracellular and secreted DNase II activities, irrespective of cell line transfected. A chimeric mutant in which the signal peptide of the DNase II was replaced with that of human DNase I had no intracellular or secreted enzyme activity. Therefore, a simultaneous attachment of a carbohydrate moiety to N86 and N266, cleavage of the propeptide from the single DNase II precursor, and the inherent signal peptide might be required for subcellular sorting and proteolytic maturation of the enzyme.

Identification of the three non-identical subunits constituting human deoxyribonuclease II

We purified DNase II from human liver to apparent homogeneity. The N-terminal amino acid sequences of each of three components constituting the purified mature enzyme were then separately determined by automatic Edman degradation. A combination of this chemical information and the previously reported nucleotide sequence of the cDNA encoding human DNase II [Yasuda et al. (1998) J. Biol. Chem. 273, 2610-2626] allowed detailed elucidation of the enzyme's subunit structure: human DNase II was composed of three non-identical subunits, a propeptide, proprotein and mature protein, following a signal peptide. Expression analysis of a series of deletion mutants derived from the cDNA of DNase II in COS-7 cells suggested that although a single large precursor protein may not be necessary for proteolytic maturation, the propeptide region L17-Q46 may play an essential role in generating the active form of the enzyme.

Detection of isozymes of deoxyribonucleases I and II on electrophoresed gels with picogram sensitivity using SYBR Green I

A highly sensitive method for detecting deoxyribonucleases (DNases) I and II on an electrophoresed gel is described. A dried agarose film sheet containing DNA as a substrate and a buffer reagent was placed in contact with the gel surface after electrophoresis (DAFO method, Yasuda et al., Anal. Biochem. 1989, 183, 84-88). After an appropriate incubation period, the film sheet was peeled off and stained with SYBR-Green I (SG), and then the DNase isozyme bands were detected using a fluorescence image analyzer. We could detect pg levels of the DNases (DNase I, 2 pg; DNase II, 2pg), which represents a 32- to 128-fold increase in sensitivity compared with the original DAFO method using ethidium bromide (EB) as the fluorescent dye. A combination of this new detection method and isoelectric focusing electrophoresis in polyacrylamide gel allowed accurate DNase I typing from 1 microL human serum. This new technique has been named SG-DAFO, after its original dried agarose film overlay method using EB (EB-DAFO).

Two novel screening methods for selecting monoclonal antibodies which specifically inhibit DNase I enzyme activity

Two novel screening methods, single radial enzyme diffusion and the DNA-cast polyacrylamide gel electrophoresis, for selecting monoclonal antibodies which detect human deoxyribonuclease I (DNase I) enzyme activity are described. The former was adopted for initial screening to select potential objective antibodies from numerous hybridoma culture supernatants, because it was easy to perform and a powerful mass-screening tool. The latter was utilized for the subsequent precise selection of the antibodies in the supernatants selected after preliminary screening by the former, because it was clearly more accurate and sensitive, although the procedure was slightly more complicated. The consecutive use of these two methods resulted in the isolation of 25 anti-human DNase I antibodies, all of which specifically inhibited the activity of human DNase I.

Molecular cloning of the cDNA encoding human deoxyribonuclease II

A rapid amplification of cDNA ends method, using degenerate oligonucleotides based upon the N-terminal amino acid sequence of human hepatic deoxyribonuclease II (DNase II), allowed a novel cDNA encoding DNase II to be constructed from thyroid gland RNA. The composite nucleotide sequence (1593 bases) included an open reading frame of 1080 bases, which encoded a single polypeptide of 360 amino acids (signal peptide, 16; propeptide, 91; mature protein, 253). Although the sequence of DNase II showed no significant homology to other mammalian proteins, its cDNA structural organization resembled those of the lysosomal cathepsin families. The two parts of the cDNA corresponding to the propeptide and the mature protein were expressed in Escherichia coli, and the recombinant polypeptides thus obtained were strongly stained with an anti-DNase II antibody on Western blotting. DNase II is ubiquitously expressed in human tissues, and the DNase II gene (DNASE2) was assigned to chromosome 19.