Parameters influencing the flow cytometric analysis of DNA sensitivity to nuclease S1

Some parameters that influence the analysis in situ of DNA sensitivity to digestion with nuclease S1 have been studied in isolated HeLa nuclei with flow cytometry. DNA staining with the intercalating fluorochrome propidium iodide allowed the nucleolytic activity on double-stranded (ds) DNA to be determined by monitoring the relative reduction in nuclear fluorescence intensity. Nuclei isolated in buffer at low ionic strength in order to decondense chromatin fibres, showed a lower fluorescence intensity than nuclei with native chromatin, after digestion with nuclease S1 under identical conditions. Nuclei prepared with dispersed chromatin and digested with increasing amounts of enzyme showed a decrease in fluorescence intensity that reached a limit value at about 50% of the value of undigested control samples. On the other hand, in nuclei with native chromatin, fluorescence intensity decreased only about 18%. The NaCl concentration in the reaction buffer strongly influenced the DNA sensitivity to S1 nuclease. By increasing salt molarity from 5 mM to 200 mM, the digestion of dsDNA was significantly reduced as also shown by the amount of released nucleotides from purified calf thymus DNA. The detection of DNA sensitivity to nuclease S1, as assessed by the cytometric method, was shown to be more sensitive than a biochemical technique involving hydrolysis of purines. These results indicate that both the procedure for nuclei isolation and the digestion conditions have to be carefully controlled when evaluating in situ the presence of S1-sensitive sites.     

DNase I sensitivity of nuclear DNA measured by flow cytometry

The DNase I digestion kinetics of DNA in isolated nuclei (from HeLa or murine mammary carcinoma, 67 cells) were assayed flow cytometrically by measuring the changes in ethidium bromide (EtBr) fluorescence following various digestion time intervals. The DNase I digestion curve was characterized by an initial 25-30% increase in fluorescence upon addition of the enzyme, a rapid reduction in fluorescence to approximately 50-55% in 30 minutes, and a limit digest of 45-50% beyond 45 minutes. Throughout digestion, the DNA histogram retained its characteristic bimodal shape, showing that histogram rearrangement was not responsible for the changes in EtBr fluorescence. Irradiation with 5 X 10(6) rads (137Cs-gamma-rays) or exposure to 50 mM EDTA caused an increase in EtBr fluorescence similar to that caused by DNase I, suggesting that DNA nicking and/or chromatin loosening were responsible for this increase. Residual DNA assayed by the solubilization of 14C-TdR (thymidine)-labeled DNA indicated a similar kinetic pattern without the initial increase. However, at the limit digest, the fraction of DNA remaining trichloroacetic acid (TCA) insoluble (10%) was smaller than that measured by loss of EtBr fluorescence (50% of initial, 40% of maximum). Part of this difference was due to the presence of TCA soluble DNA trapped within the nuclear matrix (15-20%). This trapped DNA was released when the digested nuclei were exposed to 0.5-1.0 M NaCl just prior to EtBr staining. Exposure of HeLa cells to three agents that are believed to cause changes in chromatin structure resulted in alterations in the DNase I digestion kinetics measured flow cytometrically.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA stainability with base-specific fluorochromes: dependence on the DNA topology in situ

The influence of DNA topology on stainability with the externally binding fluorochromes Hoechst 33258 (HO) and mithramycin (MI) was investigated in HeLa nuclei in comparison with the intercalating dye propidium iodide (PI). Changes in DNA topology were induced with a mild DNAse I treatment. Stainability properties of untreated and nuclease-treated nuclei were compared with those of the supercoiled-circular and the relaxed-linear forms of the plasmid pBR322. DNAse-treated nuclei stained with HO showed a higher fluorescence intensity than control samples, independently of the dye concentration, in contrast with the findings obtained with PI. Similar behaviour was observed with the relaxed-linear form of pBR322, compared with the supercoiled-circular molecule. With MI, the stainability of HeLa nuclei did not depend on the DNA topology, whereas the stainability of the plasmid was similar to that of HO. In order to assess whether this discrepancy depended on differences in the availability of DNAse-sensitive sites to the fluorochromes, fluorescence resonance energy transfer (FRET) studies were performed in nuclei stained with HO+PI, or with HO+MI dye pairs. After DNAse I digestion, the relative FRET efficiency between donor (HO) and acceptor molecules (PI or MI) was reduced significantly only when MI was the acceptor. This result may be due to greater stainability of DNAse-sensitive sites with HO than with MI. These findings indicate that DNA stainability with base-specific fluorochromes may be affected by the topology of chromatin regions.     

Solubilization of chromatin by an endogenous enzymic Ca2+, Mg2+-dependent factor. Activity of residual chromatin]

An endogenous Ca2+, Mg2+-dependent factor of enzymic nature (apparently an endonuclease) digests a part of chromatin in the rat liver nuclei producing DNA fragments of an uniform size. After 60 min of incubation at 15 degrees C and pH 7.50 in the presence of 5 mM MgCl2 and 2 mM CaCl2 87-93% of the total chromatin becomes soluble. The insoluble chromatin however contains 70-85% of the in vivo newly synthesized RNA. In regenerating liver the proportion of the insoluble residual chromatin increases while the radioactivity of the newly synthesized DNA in this fraction is highest. Residual chromatin can be solubilized by ultrasonic treatment only. The Ca2+, Mg2+-dependent dissolving factor is not present either in brain or in PMN leucocyte nuclei.     

Alterations of neuronal nuclear matrix and chromatin structure after irradiation under aerobic and anoxic conditions

This study was undertaken to determine if structural alterations of the bulk chromatin and the amount of protein associated with the nuclear matrix in cerebellar neurons depend on radiation dose and a cell's state of oxygenation. After irradiation with 2.5 to 25.0 Gy under both aerobic and anoxic conditions, the sensitivity of the neuronal chromatin to m. nuclease digestion increase linearly with dose up to about 5 Gy, beyond which there was no further increase. The same increase in accessibility of chromatin to micrococcal nuclease digestion was observed when neuronal nuclei were irradiated at 4 degrees C. Neuronal nuclei were stained with propidium iodide (PI) for DNA and with fluorescein isothiocyanate (FITC) for protein, both before and after complete digestion with DNase I, and analyzed by flow cytometry. There was no change in either the PI (P greater than 0.4) or the FITC (P greater than 0.9) fluorescence of undigested nuclei after irradiation. For the DNase I digested nuclei, the PI fluorescence was unchanged after irradiation (P greater than 0.4), but the FITC fluorescence increased significantly (P less than 0.02). This increase in the FITC fluorescence was linear with dose up to about 5 Gy, beyond which there was no further increase. The flow cytometry results from DNase I digested nuclei were identical for neurons irradiated under aerobic or anoxic conditions, indicating that this phenomenon is oxygen independent. This increase in FITC fluorescence after irradiation was inhibited at ice-cold temperatures and probably reflects an increase in protein content at the nuclear matrix that requires metabolism. This may explain our previously observed resistance of nuclear matrix-associated DNA to digestion by DNase I. This protein increase at the nuclear matrix appears to follow "saturation" kinetics identical to that previously reported for repair of DNA strand breaks in cerebellar neurons. However, the exact molecular nature of this process and its role in DNA repair or cell survival remains to be determined.     

Apoptotic cell nuclei favour aggregation and fluorescence quenching of DNA dyes

 Apoptotic cell nuclei are known to stain hyperchromatically with absorption dyes and dimly with many DNA fluorochromes. We hypothesised that both optical phenomena have the same cause - the ability of apoptotic chromatin to aggregate cationic dyes. This hypothesis was tested using prednisolone-primed rat thymus, which is known to contain apoptotic cells. The apoptotic cells were classified as early and late, based on their morphology, in thin and semithin sections and in thymus imprints on slides. Direct reaction for DNA strand breaks (TUNEL) indicated the presence of breaks in both categories of cells, with more intense labelling in late apoptosis. The chromatin ultrastructure of early apoptotic cells initially retained the supranucleosomal order of packaging which characterises control cells, whereas the dense chromatin of late apoptotic cells possessed the degraded structure. Absorption spectra of the toluidine blue-stained early apoptotic cell chromatin revealed a metachromatic shift, indicating a change of DNA conformation and polymerisation of the dye. When the staining was performed by acridine orange (preceded by a short acid treatment), a paradoxical several-fold increase of fluorescence intensity at a several-fold dilution of the dye was found. The simultaneous reduction of the ratio of red to green components of fluorescence confirmed that the concentration-dependent fluorescence quenching was due to aggregation of the dye. The results suggest that the enhanced affinity of the chromatin of early apoptotic cells for cationic dyes is associated with conformational relaxation rather than degradation of DNA. In late apoptotic cells, the very dense packaging of degraded DNA promotes further aggregation of dyes. The results suggest alternative methods for detection and discrimination of early and late apoptotic cells. Accepted: 12 February 1997     

Increased sensitivity of various genes to endogenous DNase activity in terminal differentiating chick lens fibers

In the lens, epithelial cells from the equatorial zone differentiate into postmitotic elongated fibers. One aspect of this differentiation is nuclear shape transformation and DNA degradation. This process is controlled by DNase activity which in fiber nuclei increases with development. DNase activity is also present in the epithelial cell nuclei which appears to be non-functional but could be activated in vitro by exogenous addition of Ca2+. We have analyzed the possible selective action of endogenous DNase on 3 genes involved in lens terminal differentiation, namely delta-crystallin, beta-tubulin and vimentin, and on 1 gene not thought to participate in this process, ovalbumin. We have compared restriction DNA patterns of these genes in nuclei isolated from 11-day-old chick embryos and incubated in Ca2+-free medium or in fresh epithelial and fiber lens tissue at 11 and 18 days of development. During incubation in vitro of 11-day fiber nuclei, there is a net increase in the sensitivity of the delta-crystallin, beta-tubulin, ovalbumin and vimentin chromatin to the endogenous DNase. The vimentin gene appears to be more stable than the beta-tubulin and delta-crystallin genes indicating a degree of specificity of the endogenous DNase activity. In the epithelial nuclei, the lens-specific genes appear to be more stable but paradoxically there is a net degradation of the ovalbumin gene. In freshly isolated tissues the 4 genes were detected in epithelial and fiber cells at 11 and 18 days. Furthermore, in the mature fibers in which the nuclei were degenerating, the latter genes were still not completely digested.     

Adsorption of DNA to sand and variable degradation rates of adsorbed DNA

Adsorption and desorption of DNA and degradation of adsorbed DNA by DNase I were studied by using a flowthrough system of sand-filled glass columns. Maximum adsorption at 23 degrees C occurred within 2 h. The amounts of DNA which adsorbed to sand increased with the salt concentration (0.1 to 4 M NaCl and 1 mM to 0.2 M MgCl2), salt valency (Na+ less than Mg2+ and Ca2+), and pH (5 to 9). Maximum desorption of DNA from sand (43 to 59%) was achieved when columns were eluted with NaPO4 and NaCl for 6 h or with EDTA for 1 h. DNA did not desorb in the presence of detergents. It is concluded that adsorption proceeded by physical and chemical (Mg2+ bridging) interaction between the DNA and sand surfaces. Degradability by DNase I decreased upon adsorption of transforming DNA. When DNA adsorbed in the presence of 50 mM MgCl2, the degradation rate was higher than when it adsorbed in the presence of 20 mM MgCl2. The sensitivity to degradation of DNA adsorbed to sand at 50 mM MgCl2 decreased when the columns were eluted with 0.1 mM MgCl2 or 100 mM EDTA before application of DNase I. This indicates that at least two types of DNA-sand complexes with different accessibilities of adsorbed DNA to DNase I existed. The degradability of DNA adsorbed to minor mineral fractions (feldspar and heavy minerals) of the sand differed from that of quartz-adsorbed DNA.     

Adsorption of DNA to sand and variable degradation rates of adsorbed DNA.

Adsorption and desorption of DNA and degradation of adsorbed DNA by DNase I were studied by using a flowthrough system of sand-filled glass columns. Maximum adsorption at 23 degrees C occurred within 2 h. The amounts of DNA which adsorbed to sand increased with the salt concentration (0.1 to 4 M NaCl and 1 mM to 0.2 M MgCl2), salt valency (Na+ less than Mg2+ and Ca2+), and pH (5 to 9). Maximum desorption of DNA from sand (43 to 59%) was achieved when columns were eluted with NaPO4 and NaCl for 6 h or with EDTA for 1 h. DNA did not desorb in the presence of detergents. It is concluded that adsorption proceeded by physical and chemical (Mg2+ bridging) interaction between the DNA and sand surfaces. Degradability by DNase I decreased upon adsorption of transforming DNA. When DNA adsorbed in the presence of 50 mM MgCl2, the degradation rate was higher than when it adsorbed in the presence of 20 mM MgCl2. The sensitivity to degradation of DNA adsorbed to sand at 50 mM MgCl2 decreased when the columns were eluted with 0.1 mM MgCl2 or 100 mM EDTA before application of DNase I. This indicates that at least two types of DNA-sand complexes with different accessibilities of adsorbed DNA to DNase I existed. The degradability of DNA adsorbed to minor mineral fractions (feldspar and heavy minerals) of the sand differed from that of quartz-adsorbed DNA.     

Kinetics of DNase I digestion of interphase chromatin in differentiated cell nuclei of the mouse: a flow cytometric study

The process of DNA digestion with DNase I was monitored in interphase chromatin of differentiated cells by flow cytometry after DNA staining with either the intercalating dye propidium iodide (PI) or the AT specific dye Hoechst 33258 (HO). Nuclei from the liver, kidney and spleen of the mouse were studied after different digestion times (0 to 120 min). During the first 30 min of treatment, a tissue specific digestion pattern was found after PI staining; from 60 min onward, the digestion curves ran parallel, with minor quantitative differences among the cell types. After HO staining, the digestion kinetics appeared to be similar for all the cell types; this is likely due to the peculiar base composition of the mouse genome, where inactive c-heterochromatin is exceptionally AT-rich. No quantitative correlation was found between interphase "heterochromatin" and chromatin DNA which is resistant to DNase I cleavage, while the amount of DNase-I-sensitive DNA does not correspond to the interphase "euchromatic" component. It was confirmed that the flow cytometric approach is a tool for quantifying relative changes in the functional state of chromatin in differentiated cell systems.     

Ability of hamster spermatozoa to digest their own DNA

Mammalian sperm chromatin is bound by protamines into highly condensed toroids with approximately 50 kilobases (kb) of DNA. It is also organized into loop domains of about the same size that are attached at their bases to the proteinaceous nuclear matrix. In this work, we test our model that each sperm DNA-loop domain is condensed into a single protamine toroid. Our model predicts that the protamine toroids are linked by chromatin that is more sensitive to nucleases than the DNA within the toroids. To test this model, we treated hamster sperm nuclei with DNase I and found that the sperm chromatin was digested into fragments with an average size of about 50 kb, by pulse-field gel electrophoresis (PFGE). Surprisingly, we also found that spermatozoa treated with 0.25% Triton X-100 (TX) and 20 mM MgCl2 overnight resulted in the same type of degradation, suggesting that sperm nuclei have a mechanism for digesting their own DNA at the bases of the loop domains. We extracted the nuclei with 2 M NaCl and 10 mM dithiothreitol (DTT) to make nuclear halos. Nuclear matrices prepared from DNase I-treated spermatozoa had no DNA attached, suggesting that DNase I digested the DNA at the bases of the loop domains. TX-treated spermatozoa still had their entire DNA associated with the nuclear matrix, even though the DNA was digested into 50-kb fragments as revealed by PFGE. The data support our donut-loop model for sperm chromatin structure and suggest a functional role for this type of organization in that sperm can digest its own DNA at the sites of attachment to the nuclear matrix.     

Nuclease-induced DNA structural changes assessed by flow cytometry with the intercalating dye propidium iodide

A flow cytometric analysis of DNA structural changes induced by cleavage with nucleases was performed on isolated HeLa nuclei by assessing changes in stainability with the DNA-specific fluorochrome propidium iodide (PI). After mild digestion with DNAse I, micrococcal nuclease, or with the single-strand-specific S1 and Neurospora crassa nucleases, fluorescence intensity of nuclei stained with PI increased by about 15-30% above the value of undigested control samples. No significant modifications were observed with the restriction enzymes Eco RI, Alu I, and Not I. The DNAse I-induced increase in fluorescence intensity was also observed with the non-intercalating dye Hoechst 33258, but not with mithramycin. Nuclease-induced fluorescence intensity changes as determined with PI were found to be dependent on the dye concentration. A constant increase (about 20%) was measured at dye/DNA-P ratios greater than 0.11. Below this value (2 micrograms/ml PI), the fluorescence intensity of digested samples was 15-30% lower than that of undigested controls. This behaviour towards intercalating dyes is similar to that of the relaxed (nicked) vs. the supercoiled (intact) form of circular DNA. These results suggest that conformation- but not sequence-specific nucleases induce a relaxation of DNA supercoils.     

Parameters influencing the flow cytometric analysis of DNA sensitivity to nuclease S1

Summary Some parameters that influence the analysis in situ of DNA sensitivity to digestion with nuclease S1 have been studied in isolated HeLa nuclei with flow cytometry. DNA staining with the intercalating fluorochrome propidium iodide allowed the nucleolytic activity on double-stranded (ds) DNA to be determined by monitoring the relative reduction in nuclear fluorescence intensity. Nuclei isolated in buffer at low ionic strength in order to decondense chromatin fibres, showed a lower fluorescence intensity than nuclei with native chromatin, after digestion with nuclease S1 under identical conditions. Nuclei prepared with dispersed chromatin and digested with increasing amounts of enzyme showed a decrease in fluorescence intensity that reached a limit value at about 50% of the value of undigested control samples. On the other hand, in nuclei with native chromatin, fluorescence intensity decreased only about 18%. The NaCl concentration in the reaction buffer strongly influenced the DNA sensitivity to S1 nuclease. By increasing salt molarity from 5 mM to 200 mM, the digestion of dsDNA was significantly reduced as also shown by the amount of released nucleotides from purified calf thymus DNA. The detection of DNA sensitivity to nuclease S1, as assessed by the cytometric method, was shown to be more sensitive than a biochemical technique involving hydrolysis of purines. These results indicate that both the procedure for nuclei isolation and the digestion conditions have to be carefully controlled when evaluating in situ the presence of S1-sensitive sites.     

High order packing of DNA as revealed by autodigestion of chromatin in small intestine cell nuclei

Small intestine cell nuclei incubated in sucrose media released large fractions of DNA into the culture medium. This effect was partially or completely suppressed when incubation was carried out in the presence of a protease inhibitor, 10 to 30 mM NaHSO3. The DNA released in sucrose media containing NaHSO3 was precipitated as a DNA-protein complex by increasing the bivalent ion concentration to 10 mM Ca2+ or 20 mM Mg2+. Most of the released DNA was not precipitated by Ca2+ or Mg2+ when incubation was performed without NaHSO3. As determined by viscosity measurements the mean molecular weight of the DNA released in the absence of NaHSO3 was from 3.5-8.0 x 10(5) and increased to about 11 x 10(5) (corresponding to 8 nucleosomes) when the incubation mixture contained NaHSO3. End group analysis indicated that the DNA segments were terminated by 3'-OH groups. It is suggested that fragmentation of DNA in chromatin was produced by a endogenous alkaline endonuclease activity which was present in the fraction of released DNA. The data support the view that the third-order repeat structure of chromatin consists of subunits containing 8 nucleosomes.     

A structure of potentially active and inactive genes of chicken erythrocyte chromatin upon decondensation.

In the presence of 3 mM MgCl2 DNase I cleavage of bulk, globin and ovalbumin gene chromatin in chicken erythrocyte nuclei generates fragments which are multiples of a double-nucleosome repeat. However, in addition to the dinucleosomal periodicity beta-globin gene chromatin was fragmented into multiples of a 100 b.p. interval which is characteristic for partially unfolded chromatin. This distinction correlates with higher sensitivity of beta-globin domain to DNase I and DNase II as compared to the inactive ovalbumin gene. At 0.7 mM MgCl2 where these DNases fragment bulk chromatin into series of fragments with a 100 b.p. interval, the difference in digestibility of the investigated genes is dramatically decreased. When chromatin has been decondensed by incubation of nuclei in 10 mM Tris-buffer, DNase II generates a typical nucleosomal repeat, and the differential nuclease sensitivity of the analyzed genes is not observed. The data suggest that higher nuclease sensitivity of potentially active genes is due to irregularities in higher order chromatin structure.     

Sex-specific alterations in chromatin conformation of the brain of aging mouse

Chromatin conformation has been analysed in the brain cortex of adult (24±2 weeks) and old (65±4 weeks) male and female mice. Nuclei purified from different groups of mice were digested with MNase and DNase I for varying time periods (0–90 min), and with endogenous endonucleases for 1 h. MNase and DNase I digestion kinetics showed that the percentage of acid solubility of chromatin was relatively lower in old than adult and in female than male. This was further supported by electrophoretic analysis of nuclease digested DNA fragments. When the nuclei were incubated with only Ca²⁺or mg²⁺, no endonuclease digestion was observed. However, under similar conditions, the liver DNA was cleaved substantially. When divalent cations were added together, they activated endogenous endonucleases and digested the brain chromatin. The activity of Ca²⁺/Mg²⁺-dependent endogenous endonucleases was higher in male than female. Thus the accessibility of chromatin to MNase, DNase I and endogenous endonucleases was higher in male than female, and MNase as well as DNase I were more active in adult than old. Such sex- and age-dependent conformation of chromatin may attribute to differential expression of genes in the mouse brain.     

Ca<Superscript>2+</Superscript>, Mg<Superscript>2+</Superscript>-dependent DNase Involvement in Apoptotic Effects in Spermatozoa of Sea Urchin <Emphasis Type="Italic">Strongylocentrotus intermedius</Emphasis> Induced by Two-Headed Sphingolipid Rhizochalin

Previously, we have purified three distinct DNases from spermatozoa of sea urchin Strongylocentrotus intermedius and we suppose the role of Ca²⁺, Mg²⁺-dependent DNase (Ca, Mg-DNase) in apoptosis of spermatozoa. Two-headed sphingolipid rhizochalin (Rhz) induced characteristic apoptotic nuclear chromatin changes, internucleosomal DNA cleavage, and activation of caspase-9, caspase-8, and caspase-3 in spermatozoa as was shown by fluorescence Hoechst 33342/PI/FDA analysis, DNA fragmentation assay, and fluorescence caspase inhibitors FAM-LEHD-fmk, FAM-IETD-fmk, and FAM-DEVD-fmk, respectively. Inhibitor of caspase-3 z-DEVD-fmk subdued Rhz-induced internucleosomal ladder formation, which confirmed the major role of caspase-3 in apoptotic DNA cleavage probably through Ca, Mg-DNase activation. Participation of sea urchin Ca, Mg-DNase in apoptosis of spermatozoa was demonstrated by ions Zn²⁺ blocking of Rhz-induced DNA fragmentation due to direct inhibition of the Ca, Mg-DNase and internucleosomal cleavage of HeLa S and Vero E6 cell nuclei chromatin by highly purified Ca, Mg-DNase.     

Utilization of an in vitro assay to evaluate chromatin degradation by candidate apoptotic nucleases

Apoptosis is commonly associated with the catabolism of the genome in the dying cell. The chromatin degradation occurs in essentially two forms: (1) internucleosomal DNA cleavage to generate oligonucleosomal-length fragments (180-200 bp and multiples thereof), and (2) cleavage of higher order chromatin structures to generate approximately 30-50 Kb fragments. To investigate this component of apoptosis and identify the nuclease(s) responsible, we have developed and utilized an in vitro assay that recapitulates the genomic destruction seen during apoptosis in vivo and allows the simultaneous analysis of both forms of DNA degradation from the same sample. Using this assay we evaluated the digestion patterns of several candidate apoptotic nucleases: DNase I, DNase II, and cyclophilin (NUC18) as well as the bacterial enzyme micrococcal nuclease (not thought to be involved in apoptosis). Chromatin degraded by DNase I formed a smear of DNA on conventional static-field agarose gels and approximately amp;30 - 50 Kb DNA fragments on pulsed field gels. In contrast, DNase II, at a physiologically relevant pH, had no effect on the integrity of HeLa chromatin in either analysis. Similar to DNase I, cyclophilin C produced only approximately 30-50 Kb DNA fragments but did not generate internucleosomal fragments. In contrast, micrococcal nuclease generated both oligonucleosomal and approximately 30-50 Kb DNA fragments. Nuclear extracts from glucocorticoid-treated apoptotic thymocytes generated oligonucleosomal DNA fragments and the larger approximately 30-50 Kb DNA fragments, fully recapitulating both types of apoptotic DNA degradation. Previously, differential sensitivity of nucleases to inhibition by Zn2+ was used to argue that two distinct enzymes mediate approximately 30-50 Kb DNA cleavage and internucleosomal DNA degradation. While, the nuclease activity present in thymocyte nuclear extracts was differentially sensitive to inhibition by Zn2+ during short term incubations it was not during prolonged digestions, suggesting that differences in DNA detection are likely to account for previous results. Together our studies show that none of the nucleases commonly associated with apoptosis could fully recapitulate the DNA degradation seen in vivo.