Characterization of two DNase gamma-specific monoclonal antibodies and the in situ detection of DNase gamma in the nuclei of apoptotic rat thymocytes

Two novel monoclonal antibodies (mAbs), hg302 and hg303, raised against a synthetic peptide corresponding to the basic domain of human DNase gamma, are characterized in detail. In Western blot analysis, hg303 recognizes both wild type and C-terminal Myc-His-tagged human DNase gamma, but does not cross-react with human DNase I family members, DNase I, DNase X, or DNAS1L2. On the other hand, dot blot analysis reveals the fine specificity of hg302; it recognizes human, mouse, and rat DNase gamma, but not other DNase I family DNases under non-denaturing conditions. Furthermore, hg302 efficiently immunoprecipitates wild type, but not C-terminal Myc-His-tagged, human DNase gamma from cell lysates. In immunohistochemical analysis, hg302 strongly recognizes DNase gamma in the nuclei of X-ray irradiation-induced apoptotic, but not normal rat thymocytes. The specific detection of DNase gamma in apoptotic nuclei is confirmed by indirect-immunofluorescence analysis using TNF-alpha-induced apoptotic HeLa S3 cells transfected with DNase gamma. These results, together with the observations that DNase gamma is present in normal thymocytes and its activity is unchanged during the apoptosis, suggest that some molecular change(s), which triggers the activation of DNase gamma, occurs in response to apoptotic stimuli in the basic domain, and hg302 specifically recognizes the activated DNase gamma in immunohistochemical analysis.     

Non-classic characteristics define prominent DNase activities from the intestine and other tissues of Haemonchus contortus

The anthelmintic fenbendazole (FBZ) induces nuclear DNA fragmentation (DF) in intestinal cells of Haemonchus contortus. The DNA fragments had 3'-OH, which suggests involvement of a neutral DNase. To identify candidate DNase(s) involved, DNase activity in H. contortus intestine and other worm fractions was characterized relative to classic DNases I (neutral) and II (acidic). Seven distinct DNase activities were identified and had Mrs of 34, 36, 37 or 38.5 kDa on zymographic analysis. The different activities were distinguished according to pH requirement, sensitivity to 10 mM EDTA and worm compartment. Activities of intestinal DNases at 34, 36 and 38.5 kDa were sensitive to EDTA at pH 5.0 and 7.0. Sensitivity to EDTA at pH 5.0 was unexpected compared to classic acidic DNase II activity, suggesting unusual properties of these DNases. In whole worms, however, the activities at 36 and 38.5 kDa were relatively insensitive to EDTA, indicating predominance of DNases that are distinct from the intestine. The activity at 37 kDa in excretory/secretory products had an acidic pH requirement and was insensitive to EDTA, resembling classic acidic DNase activity. Under conditions of pH 5.0 and 7.0, intestinal DNases produced 3'-ends that could be labeled by terminal deoxynucleotidyl transferase, indicating presence of 3'-OH. The labeling of 3'-ends at pH 5.0, again, was unexpected for acidic DNase activity. These results and several other activities suggest that multiple H. contortus DNases have characteristics distinct from the classic mammalian DNases I and II. Treatment of H. contortus with FBZ did not induce any detectable DNase activities distinct from normal intestine, although relative activities of intestinal DNases appear to have been altered by this treatment.     

Role of DNAS1L3 in Ca2+- and Mg2+-dependent cleavage of DNA into oligonucleosomal and high molecular mass fragments

Ca2+- and Mg2+-dependent endonucleases have been implicated in DNA fragmentation during apoptosis. We have demonstrated that particular nucleases of this type are inhibited by poly(ADP-ribosyl)ation and suggested that subsequent cleavage of PARP by caspase-3 might release these nucleases from poly(ADP-ribosyl)ation-induced inhibition. Hence, we purified and partially sequenced such a nuclease isolated from bovine seminal plasma and identified human, rat and mouse homologs of this enzyme. The extent of sequence homology among these nucleases indicates that these four proteins are orthologous members of the family of DNase I-related enzymes. We demonstrate that the activation of the human homolog previously specified as DNAS1L3 can induce Ca2+- and Mg2+-dependent DNA fragmentation in vitro and in vivo. RT-PCR analysis failed to detect DNAS1L3 mRNA in HeLa cells and nuclei isolated from these cells did not exhibit internucleosomal DNA fragmentation when incubated in the presence of Ca2+and Mg2+. However, nuclei isolated from HeLa cells that had been stably transfected with DNAS1L3 cDNA underwent such DNA fragmentation in the presence of both ions. The Ca2+ionophore ionomycin also induced internucleosomal DNA degradation in transfected but not in control HeLa cells. Transverse alternating field electrophoresis revealed that in nuclei from transfected HeLa cells, but not in those from control cells, DNA was cleaved into fragments of >1000 kb in the presence of Mg2+; addition of Ca2+in the presence of Mg2+resulted in processing of the >1000 kb fragments into 50 kb and oligonucleosomal fragments. These results demonstrate that DNAS1L3 is necessary for Ca2+- and Mg2+-dependent cleavage of DNA into both oligonucleosomal and high molecular mass fragments in specific cell types.     

Apoptotic DNase network: Mutual induction and cooperation among apoptotic endonucleases

DNA fragmentation produced by apoptotic DNases (endonucleases) leads to irreversible cell death. Although apoptotic DNases are simultaneously induced following toxic/oxidative cell injury and/or failed DNA repair, the study of DNases in apoptosis has generally been reductionist in approach, focusing on individual DNases rather than their possible cooperativity. Coordinated induction of DNases would require a mechanism of communication; however, mutual DNase induction or activation of DNases by enzymatic or non-enzymatic mechanisms is not currently recognized. The evidence presented in this review suggests apoptotic DNases operate in a network in which members induce each other through the DNA breaks they produce. With DNA breaks being a common communicator among DNases, it would be logical to propose that DNA breaks from other sources such as oxidative DNA damage or actions of DNA repair endonucleases and DNA topoisomerases may also serve as triggers for a cooperative DNase feedback loop leading to elevated DNA fragmentation and subsequent cell death. Therefore, mutual induction of apoptotic DNases has serious implications for studies focused on activation or inhibition of specific DNases as a strategy for therapeutic intervention aimed at modulation of cell death.     

A role of the Ca2+/Mg2+-dependent endonuclease in apoptosis and its inhibition by Poly(ADP-ribose) polymerase

Apoptosis is characterized by various cell morphological and biochemical features, one of which is the internucleosomal degradation of genomic DNA. The role of the human chromatin-bound Ca(2+)- and Mg(2+)-dependent endonuclease (CME) DNAS1L3 and its inhibition by poly(ADP-ribosyl)ation in the DNA degradation that accompanies apoptosis was investigated. The nuclear localization of this endonuclease is the unique feature that distinguishes it from other suggested apoptotic nucleases. Purified recombinant DNAS1L3 was shown to cleave nuclear DNA into both high molecular weight and oligonucleosomal fragments in vitro. Furthermore, exposure of mouse skin fibroblasts expressing DNAS1L3 to inducers of apoptosis resulted in oligonucleosomal DNA fragmentation, an effect not observed in cells not expressing this CME, as well as in a decrease in cell viability greater than that apparent in the control cells. Recombinant DNAS1L3 was modified by recombinant human poly(ADP-ribose) polymerase (PARP) in vitro, resulting in a loss of nuclease activity. The DNAS1L3 protein also underwent poly(ADP-ribosyl)ation in transfected mouse skin fibroblasts in response to inducers of apoptosis. The cleavage and inactivation of PARP by a caspase-3-like enzyme late in apoptosis were associated with a decrease in the extent of DNAS1L3 poly(ADP-ribosyl)ation, which likely releases DNAS1L3 from inhibition and allows it to catalyze the degradation of genomic DNA.     

Intestinal DNases of 36 and 38.5kDa from the parasitic nematode Haemonchus contortus have non-classic DNase characteristics and produce DNA fragments with 3'-hydroxyls

Treatment with the anthelmintic fenbendazole induces fragmentation of genomic DNA in intestinal cells of Haemonchus contortus. This effect is characterized by DNA fragments with 3'-hydroxyls (OH). Investigation into DNases responsible identified intestinal DNase activities that produce DNA fragments with 3'-OH. However, this interpretation was complicated by a mixture of activities in the intestinal fractions evaluated. In addition, intestinal activities displayed non-classic characteristics. Here it is shown that heparin sulfate (HS) fractionation enriched for intestinal DNases that produce 3'-OH. The 2.0M NaCl fraction of HS contained DNase activity that produced 3'-OH with minimal contamination by activity that produced 3'-phosphates (P). 3'-OH were produced under acidic (pH 5.0) or neutral (pH 7.0) conditions by DNases in this fraction. These DNases were sensitive to EDTA under each condition. Furthermore, EDTA-sensitive DNase activity in this fraction digested H. contortus intestinal cell nuclear DNA in histological sections, producing 3'-OH under acidic and neutral conditions. DNases at 36 and 38.5kDa in this fraction each produced 3'-OH at pH 5.0 when gel eluted, and each activity was sensitive to EDTA. Hence, the 36 and 38.5kDa DNases in the 2.0M NaCl HS intestinal fraction have characteristics expected for candidate DNases that mediate DF in H. contortus intestinal cell nuclei induced by fenbendazole. DNase activity that produces 3'-OH under acidic condition with sensitivity to EDTA is unconventional for classic acidic or neutral DNases and is a unique finding for nematodes. Excretory/secretory products from the worm and whole worm lysates were also explored as sources to fractionate intestinal DNases identified. HS fractionation of those worm samples did not clearly resolve the intestinal DNases of interest, although DNases with distinct characteristics were identified in each source.     

DNases and apoptosis.

Here we review the different apoptotic DNases. From a functional point of view, DNases implicated in apoptosis may be classified into three groups: the Ca2+/Mg2+ endonucleases, the Mg2+-endonucleases, and the cation-independent endonucleases. The first group includes DNase I which has no specificity for the linker region, DNase gamma which has some homology with DNase I, and other DNases which cleave DNA in the linker region. Both DNase I and DNase gamma have been cloned. The other nucleases of this category have dispersed molecular weights. Their sequences are unknown and it is difficult to determine their role(s) in apoptosis. It seems that different pathways are present and that these nucleases may be activated either by caspases or serine proteases. The caspase 3 activated DNase (CAD, CPAN, or DFF40) belongs to the Mg2+-dependent endonucleases. DNase II belongs to the third group of acid endonucleases or cation-independent DNases. We have shown the involvement of DNase II in lens cell differentiation. Recently, the molecular structure of two different enzymes has been elucidated, one of which has a signal peptide and appears to be secreted. The other, called L-DNase II, is an intracellular protein having two enzymatic activities; in its native form, it is an anti-protease, and after posttranslational modification, it becomes a nuclease.     

Structure basis for the inhibitory mechanism of a novel DNase gamma-specific inhibitor, DR396

DNase gamma, a member of the DNase I family, has been suggested to cause DNA fragmentation during apoptosis. We recently identified 4-(4,6-dichloro-[1,3,5]-triazine-2-ylamino)-2-(6-hydroxy-3-oxo-3H-xanthen-9-yl)-benzoic acid (DR396) as a novel specific inhibitor for human DNase gamma [Sunaga, S.; Kobayashi, T.; Yoshimori, A.; Shiokawa, D.; Tanuma, S. Biochem. Biophys. Res. Commun.2004, 325, 1292]. However, the binding mode (coordinate) of DR396 to DNase gamma has not yet been defined. Here, we examined the molecular basis for the inhibitory activity of DR396 to DNase gamma by structure-based computational docking studies. In the blind-docking study using a human DNase gamma homology model, a unique binding site of DR396 was predicted, which is tentatively named the 'DNA trapping site' because of the binding domain of the unhydrolyzed DNA strand, but not the active site. Targeting the DNA trapping site as a hot spot, new human DNase gamma inhibitors were obtained from our diverse chemical library in silico. These inhibitors showed high correlations between their predicted binding-free energies (DeltaGs) and observed IC50 values in the DNA trapping site but not the active site. The IC50 of a regioisomer of DR396, 5-(4,6-dichloro-[1,3,5]-triazine-2-ylamino)-2-(6-hydroxy-3-oxo-3H-xanthen-9-yl)-benzoic acid (DF365), was 73 microM (DeltaG=-9.75 kcal/mol), a 20-fold weaker inhibitory ability than that of DR396 (IC50=3.2 microM, DeltaG=-11.22 kcal/mol). Fluorescein and triazine derivatives, partial structures of DR396, had little inhibitory activity for DNase gamma. Docking analyses of the interaction between DR396 and DNase gamma revealed that DR396 binds tightly to three subsites (S1, S2, and S3) in the trapping site of DNase gamma by forming six hydrogen bonds, whereas DF365 and the partial structures are unable to form hydrogen bonds at all three subsites. These findings suggest that the specificity and potency of the inhibitory activity of DR396 for DNase gamma is due to the specific interaction of DR396 with three subsites in the DNA trapping site of DNase gamma.     

A novel inhibitor that protects apoptotic DNA fragmentation catalyzed by DNase gamma

The internucleosomal cleavage of genomic DNA is the biochemical hallmark of apoptosis. DNase gamma, a Ca(2+)/Mg(2+)-dependent endonuclease, has been suggested to be one of the apoptotic endonucleases. We identified here 4-(4,6-dichloro-[1,3,5]-triazin-2-ylamino)-2-(6-hydroxy-3-oxo-3H-xanthen-9-yl)-benzoic acid (DR396) as a novel and potent DNase gamma inhibitor using stable HeLa S3 transfectants of DNase gamma (HeLa-gamma cells). DR396 inhibited apoptotic DNA fragmentation in HeLa-gamma cells induced by staurosporine (STS) and in rat splenocytes exposed to gamma-ray irradiation in a dose-dependent manner. This compound potently and selectively inhibited DNase gamma activity with an IC(50) value of 3.2 microM. DR396 did not delay the apoptotic processes as judged by the morphological changes and the cleavage of a death substrate, poly(ADP-ribose) polymerase (PARP). Furthermore, the compound did not prevent apoptotic DNA fragmentation in Jurkat cells induced by anti-Fas antibody (Ab), which is catalyzed by caspase-activated DNase (CAD). These findings clearly indicate that DR396 exerts chemical knockdown effect of DNase gamma on cells, suggesting that the compound could be an attractive tool for understanding of the physiological significance of DNase gamma.     

Differential DNases are selectively used in neuronal apoptosis depending on the differentiation state

In this study, we investigate the roles of two apoptotic endonucleases, CAD and DNase gamma, in neuronal apoptosis. High expression of CAD, but not DNase gamma, is detected in proliferating N1E-115 neuroblastoma cells, and apoptotic DNA fragmentation induced by staurosporine under proliferating conditions is abolished by the expression of a caspase-resistant form of ICAD. After the induction of neuronal differentiation, CAD disappearance and the induction of DNase gamma occur simultaneously in N1E-115 cells. Apoptotic DNA fragmentation that occurs under differentiating conditions is suppressed by the downregulation of DNase gamma caused by its antisense RNA. The induction of DNase gamma is also observed during neuronal differentiation of PC12 cells, and apoptotic DNA fragmentation induced by NGF deprivation is inhibited by the antisense-mediated downregulation of DNase gamma. These observations suggest that DNA fragmentation in neuronal apoptosis is catalyzed by either CAD or DNase gamma depending on the differentiation state. Furthermore, DNase gamma is suggested to be involved in naturally occurring apoptosis in developing nervous systems.     

Identification, Localization, and Expression of Two Novel Human Genes Similar to Deoxyribonuclease I

Two novel cDNAs, DNAS1L2 and DNAS1L3, are predicted to encode proteins of 299 and 305 amino acids with 56 and 46% residue identity (71 and 63% similarity), respectively, to deoxyribonuclease I (DNase I). DNAS1L2 is located on a 16p13.3 cosmid, while DNAS1L3 maps to 3p14.3–p21.1 by fluorescencein situhybridization and by PCR analysis of a radiation hybrid panel. Northern analysis revealed DNAS1L3 expression nearly exclusively in liver, while DNAS1L2 expression was detected in brain by RT-PCR. The previously defined DNL1L or DNAS1L1 is expressed highest in heart and skeletal muscle, while DNase I is expressed in the pancreas, parotid gland, and kidney. Thus, to date, four DNase I-like genes that show different tissue expression patterns are known. A comparison of DNAS1L1, DNAS1L2, and DNAS1L3 with the well-characterized DNase I suggests that the DNAS1L proteins are unlikely to be glycosylated or bind actin; however, catalytic and calcium- and DNA-binding residues are conserved, and potentially cleavable signal peptides are present among all these proteins. This analysis also identifies regions of high conservation among these proteins with no currently assigned function.     

Functional characterization of DNase X, a novel endonuclease expressed in muscle cells

The activation of endonucleases resulting in the degradation of genomic DNA is one of the most characteristic changes in apoptosis. Here, we report the characterization of a novel endonuclease, termed DNase X due to its X-chromosomal localization. The active nuclease is a 35 kDa protein with 39% identity to DNase I. When incubated with isolated nuclei, recombinant DNase X was capable of triggering DNA degradation at internucleosomal sites. Similarly to DNase I, the nuclease activity of DNase X was dependent on Ca(2+) and Mg(2+) and inhibited by Zn(2+) ions or chelators of bivalent cations. Overexpression of DNase X caused internucleosomal DNA degradation and induction of cell death associated with increased caspase activation. Despite the presence of two potential caspase cleavage sites, DNase X was processed neither in vitro nor in vivo by different caspases. Interestingly, after initiation of apoptosis DNase X was translocated from the cytoplasm to the nuclear compartment and aggregated as a detergent-insoluble complex. Abundant expression of DNase X mRNA was detected in heart and skeletal muscle cells, suggesting that DNase X may be involved in apoptotic or other biological events in muscle tissues.     

Endonuclease activities in the coleoptile and the first leaf of developing etiolated wheat seedlings

DNase activity in coleoptiles and the first leaf apices of winter wheat (Triticum aestivum L., cv. Mironovskaya 808) etiolated seedlings was found to increase significantly during seedling growth, peaking on the eighth day of plant development. The maximum of DNase activity was coincident with apoptotic internucleosomal DNA fragmentation in these organs. Wheat endonucleases are capable of hydrolyzing both singleand double-stranded DNA of various origins. The leaf and coleoptiles were found to exhibit nuclease activities that hydrolyzed the lambda phage DNA with N⁶-methyladenine and 5-methylcytosine more actively compared to the hydrolysis of similar unmethylated DNAs. Thus, the endonucleases of wheat seedlings are sensitive to the methylation status of their substrate DNAs. The leaves and coleoptiles exhibited both Ca²⁺/Mg²⁺- and Zn²⁺-dependent nuclease activities that underwent differential changes during development and senescence of seedling organs. EDTA at a concentration of 50 mM fully inhibited the total DNase activity. Electrophoretic heterogeneity was observed for DNase activities operating simultaneously in the coleoptile and the first leaf at different stages of seedling development. Proteins exhibiting DNase activity (16–80 kD mol wt) were revealed in the first leaf and the coleoptile; these proteins were mostly nucleases with the pH optimum around 7.0. Some endonucleases (mol wts of 36, 39, and 28 kD) were present in both organs of the seedling. Some other DNases (mol wts of 16, 56, and about 80 kD) were found in the coleoptile; these DNases hydrolyzed DNA in the nucleus at terminal stages of apoptosis. Different suites of DNase activities were revealed in the nucleus and the cytoplasm, the nuclear DNase activities being more diverse than the cytoplasmic ones. Thus, the cellular (organspecific) and subcellular heterogeneity in composition and activities of DNases has been revealed in wheat plants. These DNases undergo specific changes during seedling development, serving at various stages of programmed cell death in seedling tissues.     

DNase I and II present in avian oocytes: a possible involvement in sperm degradation at polyspermic fertilisation

During polyspermic fertilisation in birds numerous spermatozoa enter the eggs, in contrast to the situation in mammals where fertilisation is monospermic. However, in birds only one of the spermatozoa which have entered an egg participates in zygote nucleus formation, while the supernumerary spermatozoa degenerate at early embryogenesis. Our previous work has demonstrated the presence in preovulatory quail oocytes of DNase I and II activities able to digest naked lambdaDNA/HindIII substrate in vitro. In the present studies, the activities of both DNases in quail oocytes at different stages of oogenesis and in ovulated mouse oocytes were assayed in vitro using the same substrate. Degradation of quail spermatozoa by quail oocyte extracts was also checked. Digestion of the DNA substrate was evaluated by electrophoresis on agarose gels. The activities of DNase I and II in quail oocytes increased during oogenesis and were the highest in mature oocytes. The activities were present not only in germinal discs but also in a thin layer of cytoplasm adhering to the perivitelline layer surrounding the yolk. At all stages of oogenesis the activity of DNase II was much higher than that of DNase I. DNA contained in spermatozoa was also degraded by the quail oocyte extracts under conditions optimal for both DNases. In contrast to what is observed in quail oocytes, no DNase activities were detected in ovulated mouse eggs; this is logical as they would be useless or even harmful in monospermic fertilisation. The possible role of DNase activities in avian oocytes, in degradation of accessory spermatozoa during polyspermic fertilisation, is discussed.     

Expression and characterization of a DNase I-Fc fusion enzyme

Recombinant human deoxyribonuclease I (DNase I) is an important clinical agent that is inhaled into the airways where it degrades DNA to lower molecular weight fragments, thus reducing the viscoelasticity of sputum and improving the lung function of cystic fibrosis patients. To investigate DNases with potentially improved properties, we constructed a molecular fusion of human DNase I with the hinge and Fc region of human IgG1 heavy chain, creating a DNase I-Fc fusion protein. Infection of Sf9 insect cells with recombinant baculovirus resulted in the expression and secretion of the DNase I-Fc fusion protein. The fusion protein was purified from the culture medium using protein A affinity chromatography followed by desalting by gel filtration and was characterized by amino-terminal sequence, amino acid composition, and a variety of enzyme-linked immunosorbent assays (ELISA) and activity assays. The purified fusion contains DNase I, as determined by a DNase I ELISA and an actin-binding ELISA, and an intact antibody Fc region, which was quantified by an Fc ELISA, in a 2:1 stoichiometric ratio, respectively. The dimeric DNase I-Fc fusion was functionally active in enzymatic DNA digestion assays, albeit about 10-fold less than monomeric DNase I. Cleavage of the DNase I-Fc fusion by papain resulted in a specific activity comparable to the monomeric enzyme. Salt was inhibitory for wild type monomeric DNase I but actually enhanced the activity of the dimeric DNase I-Fc fusion. The DNase I-Fc fusion protein was also less Ca2+-dependent than DNase I itself. These results are consistent with a higher affinity of the dimeric fusion protein to DNA than monomeric DNase I. The engineered DNase I-Fc fusion protein described herein has properties that may have clinical benefits.     

Expression of DNase gamma during Fas-independent apoptotic DNA fragmentation in rodent hepatocytes

Endonuclease-induced DNA fragmentation is a hallmark of apoptosis. DNase gamma (DNase ) was recently identified as one of the endonucleases responsible for apoptotic DNA fragmentation. In this study, immunohistochemistry for DNase was performed on paraffin sections of rodent liver in well-defined models of hepatocyte apoptosis induced by Fas antibody (Fas) or cycloheximide (CHX), and necrosis induced by lipopolysaccharide (LPS) or carbon tetrachloride (CCl₄). DNase immunoreactivity was compared with TdT-mediated dUTP nick-end labeling (TUNEL) reactivity. Our results showed TUNEL reactivity in both apoptotic and necrotic hepatocytes. DNase immunoreactivity was not detected during LPS-induced or CCl₄-induced hepatocyte necrosis. In contrast, it was evident during CHX-induced, but not Fas-induced, apoptotic DNA fragmentation. These findings suggest that DNase plays an important role in Fas-independent apoptotic DNA fragmentation in hepatocytes.     

Characteristics of DNase activities in excretory/secretory products of infective larvae of Haemonchus contortus

While multiple DNase activities occur in the excretory/secretory products (ESPs) of the adult Haemonchus contortus, the DNase activities in ESPs of the infective larvae (L3) have not been studied. Thus, the DNase activities in ESPs of H. contortus L3 were investigated and compared to those of adults for developmental stage-specific analysis. The DNase activities had relative molecular masses (M rs) of 34 and 36 kDa upon zymographic analysis at pH 5.0 and 7.0 when the larvae were incubated for over 48 h. The 34 and 36 kDa DNases of L3 ESPs were also detected in adult ESPs with similar characteristics. However, the 37 and 38.5 kDa DNases of the adult ESPs were not detected in the L3 ESPs. Since the 37 and 38.5 kDa DNase activities were mainly detected in adult ESPs, these activities appear to be specific to the adult stage whereas the other ESP DNase activities appear to be expressed during multiple stages of the parasite's life cycle. While the difference in DNase activities of L3 and adults remains obscure, the role of DNase in larval development should be further clarified and the identification of stage-specific developmental markers will lead to the discovery of specific factors that stimulate larval development.     

Correlation between decreased sensitivity of the Daudi lymphoma cells to VP-16-induced apoptosis and deficiency in DNAS1L3 expression

A functional relationship between the apoptotic endonuclease DNAS1L3 and the chemotherapeutic drug VP-16 was established. The lymphoma cell line, Daudi, exhibited a significant resistance to VP-16 treatment in comparison to the lymphoma/leukemia cell line, U-937. While U-937 cells degraded their DNA into internucleosomal fragments, Daudi cells failed to undergo such fragmentation in response to the drug. Activation of both caspase-3 and DNA fragmentation factor was not sufficient to trigger internucleosomal DNA fragmentation in Daudi cells. No correlation was found between expression levels of topoisomerase-II, Pgp, Bcl-2, Bax, or Bad and decreased sensitivity of Daudi cells to VP-16. Daudi cells failed to express DNAS1L3 and ectopic expression of this protein significantly sensitized the cells to VP-16. An enhancement of caspase-3 activity and collapse of mitochondrial membrane potential underlie DNAS1L3-mediated sensitization of Daudi cells to VP-16, which may be a direct result of DNAS1L3-mediated increase in PARP-1-activating DNA breaks after VP-16 treatment. Our results suggest that DNAS1L3 plays an active role in lymphoma cell sensitization to VP-16 and that its deficiency may constitute a novel mechanism of drug resistance in these cells.     

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.