(Received for publication, October 1, 1996)
From the Department of Biochemistry and Biophysics,
University of North Carolina, Chapel Hill, North Carolina 27599 and
¶ NIEHS, National Institutes of Health, Research Triangle Park,
North Carolina 27709
Previous work in our laboratory (Montague, J.,
Gaido, M., Frye, C., and Cidlowski, J. (1994) J. Biol.
Chem. 269, 18877-18880) has shown that human recombinant
cyclophilins A, B, and C have sequence homology with the apoptotic
nuclease NUC18 and that denatured cyclophilins can degrade DNA. We have
now evaluated the nucleolytic activity of recombinant cyclophilins
under native conditions. We show that nuclease activity inherent to
cyclophilins is distinct from cis-trans-peptidylprolyl
isomerase activity and is similar to that described for apoptotic
nucleases. Cyclophilin nucleolytic activity is stimulated by
Ca2+ and/or Mg2+, with a combination of the two
being optimal for cyclophilins A and B. Mg2+ alone is
sufficient for cyclophilin C nuclease activity. pH optimums are in the
range of pH 7.5-9.5. Cyclophilins can degrade both single-stranded and
double-stranded DNA. Additionally, cyclophilins produce 3-OH termini
in linear double-stranded substrates, suggesting the cuts produced are
similar to those of apoptotic cells. Cyclophilins also display
endonucleolytic activity, demonstrated by their ability to degrade
supercoiled DNA. In the absence of ions, cyclophilins bind linearized
DNA. When added to nuclei from nonapoptotic cells, cyclophilin C
induces 50-kilobase pair DNA fragmentation but not internucleosomal
fragmentation. Together, these data suggest that cyclophilins are
involved in degradation of the genome during apoptosis.
Cyclophilins (Cyps)1 comprise a highly conserved, ubiquitous family of proteins first identified as the intracellular receptors for the immunosuppressant drug cyclosporin A (CsA) (1). Cyps range in size from 15 to 40 kDa (1-3). This large family of proteins has been isolated from a diverse range of organisms, including Neurospora (4), Escherichia coli (5, 6), yeast (7), plants, and higher eukaryotes (7, 8). Cyps have been identified in every tissue studied in humans (7, 8) and have been localized to the cytoplasm (1), mitochondria (9), nucleus (8, 10), and endoplasmic reticulum (11) in various mammalian cells and the cytoplasm and periplasm (5, 12) in E. coli. Three well characterized Cyps, CypA (18 kDa) (1, 13), CypB (21 kDa) (11), and CypC (22.8 kDa) (14), are studied and discussed in this paper. The widespread nature of Cyps suggests they may play an important role in cellular metabolism.
Cyps have been shown to act as peptidylprolyl cis-trans-isomerases whose activity can be blocked by CsA. As isomerases, Cyps have been proposed to aid in protein folding. The folding rates of human carbonic anhydrase II (15), RNase T1, (16), and collagen (17) have been shown to be increased by Cyp in vitro. However, whether this isomerase activity is physiologically significant is still not clear. Cyps have also been proposed to act as chaperones (18, 19), chemotactic agents (20), or stress response proteins (21, 22). Additionally, CypA has been shown to bind to the p55 Gag protein of human immunodeficiency virus (23) and appears to be necessary for successful human immunodeficiency virus infection (24, 25).
Cyps also play a role in the immune system by binding to the immunosuppressant drug CsA, although the exact nature of this role is also unclear. When the Cyp·CsA complex is formed, it can bind to and inhibit calcineurin (protein phosphatase 2B) (26). The inhibition of calcineurin activity causes a decrease in the nuclear levels of the transcription factor NF-AT, preventing expression of the cytokine interleukin-2 and immune cell activation (27, 28).
We recently reported a novel nuclease activity associated with the Cyp proteins (29). The notion that Cyps might have nucleolytic capabilities was suggested by a surprising sequence and structural similarity between NUC18 (an 18-kDa nuclease isolated from apoptotic rat thymocytes) and the Cyp family of proteins. Apoptosis, or programmed cell death, is a type of cell death that is highly ordered and follows a series of distinct steps that eventually lead to the non-immune-responsive death of the cell. One characteristic of apoptosis is the specific degradation of the cell's nucleic acids. There are two DNA fragmentation patterns observed in apoptosis; one involves the production of fragments of DNA that are 180-200 base pairs in length (or multiples thereof), and the other involves the production of larger DNA fragments that are approximately 50 kb in length (30, 31). While the characteristics of these apoptotic nuclease activities have been extensively described (32-35), the actual enzymes responsible have not been identified.
In this manuscript, we have evaluated and characterized the nuclease activity of Cyps under native conditions and assessed their potential role in apoptosis. We demonstrate that the nuclease activity from Cyps under native conditions is distinct from the isomerase activity and that there are many similarities between the characteristics of nuclease activity from purified Cyps and those reported for apoptotic nuclease activity. In addition, CypC is shown to produce 50-kb fragments in chromatin, further suggesting a nucleolytic role for Cyps in apoptosis.
Purified recombinant CypA, -B, and -C were generously provided by Sandoz Laboratories in Basel, Switzerland (36). They reveal no contaminants according to the limits of the silver stain analysis of SDS-polyacrylamide gels (29). The sources for other materials and enzymes are provided throughout.
Thymocyte PreparationThymocytes were prepared from thymi isolated from adrenalectomized male Sprague Dawley rats. Control thymocytes were isolated from untreated rats, and apoptotic thymocytes were prepared from thymi removed at different times following injection of the rat with 5 mg/kg of body weight dexamethasone (Steraloids). After removal from the rat, the thymus gland was placed into ice-cold phosphate-buffered saline, cut into small pieces, and homogenized with 10-15 passes of a loose-fitting Dounce homogenizer. The sample was then poured through a Nitex mesh filter, and the cells were collected by centrifugation at 4 °C (5 min, 4,000 rpm). The cells were resuspended in fresh phosphate-buffered saline and passed through another Nitesh mesh filter. After a second centrifugation, the cells were resuspended in 5 ml of phosphate-buffered saline and counted with a Coulter counter. 1 × 108 cells were removed and spun down in a microcentrifuge tube. Resuspension of the cells in 200 µl of 10 mM MgCl2, 0.25% Nonidet P-40 buffer caused lysis of the plasma membrane and release of the nuclei. The cells were incubated in this solution for 5 min on ice, and then the nuclei were centrifuged out of solution (5 min, 4,000 rpm). The cytoplasmic supernatant was transferred to a clean tube, and the nuclei were resuspended in an equal volume of the MgCl2/Nonidet P-40 solution. The extracts were prepared by the addition of an equal volume of a loading buffer containing SDS and boiled 5 min.
Western Blot AnalysesEqual volumes of the cytoplasmic and nuclear preparation of control and apoptotic thymocytes were electrophoresed through a 15% SDS-polyacrylamide gel. The proteins were transferred to nitrocellulose (BA-85) in a TBE (89 mM Tris, 89 mM boric acid, 2.5 mM EDTA)/methanol buffer over 2 h at 80 V. Protein was detected following the ECL (Amersham Corp.) detection procedure. Antibodies directed against purified recombinant CypA were prepared in rabbits and purified according to the protocol of Weigel et al. (37) using the purified recombinant CypA affinity column.
Preparation of Substrate DNAHB101 cells (Life Technologies, Inc.) containing pUC18 plasmid (2690 base pairs) were grown at 37 °C in Luria broth to an OD of 0.8 at 595 nm. Chloramphenicol was added to a final concentration of 170 mg/liter, and incubation was continued overnight. The cells were harvested, and the plasmid was purified via standard cesium chloride gradient techniques. Plasmid DNA was linearized (where stated) with the restriction endonuclease SmaI or XbaI (New England Biolabs). Single-stranded DNA was prepared by boiling the double-stranded DNA and immediately cooling on ice.
Solution Nuclease AssayThe solution nuclease assay was used to determine optimal digestion conditions and enzyme kinetics. CypA, -B, or -C was incubated with a nucleic acid substrate (supercoiled plasmid, linear double-stranded DNA, and linear single-stranded DNA) at 37 °C in a 20 mM Tris solution with appropriate ions and pH, as described in Table I. In general, 1 µg of Cyp and 1 µg of DNA (linearized pUC18) were combined in a total volume of 10 µl, resulting in a final concentration of 5.6 µM CypA, 4.8 µM CypB, 4.4 µM CypC, and 56 nM pUC18 (30 mM phosphodiester bonds); any differences are noted in the figure legends. A combination of 1 mM CaCl2 and 1 mM MgCl2 was used for the kinetic assays. After incubation, loading buffer was added, and the samples were heated to 65 °C for 10 min. The DNA was electrophoresed through a 1% agarose gel and visualized by ethidium bromide staining.
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Densitometry was used to quantitate the percentage of DNA degraded. Pictures of the ethidium bromide-stained gels were scanned into a PowerMacIntosh (8100/80) and then quantitated with the Image 1.56 ppc program (National Institutes of Health). The amount of DNA used in each assay and the time of exposure of the film were designed to ensure a densitometry reading that was linear with respect to the concentration of the DNA. A two-step process was used to calculate the percentage of DNA degraded at a specific time point. First, the area under the peak corresponding to the degraded DNA (less than 2690 base pairs) was divided by the area under the peak corresponding to the total amount of DNA in the sample and then this figure was multiplied by 100. For the relative efficacy of the activating ions, the amount of degraded DNA minus background was determined, and the percentage of DNA degraded relative to the Ca2+/Mg2+ sample was calculated. For the relative rate of DNA degradation, the amount of DNA degraded at a specific time was determined for each Cyp as well as micrococcal nuclease. This amount was then divided by the time of degradation (in minutes) and the molarity of each enzyme so that the percentage degraded/min/mol of enzyme was determined. The amount of degradation of linear double-stranded pUC18/min/mol of CypA, -B, and -C relative to the amount degraded/min/mol of micrococcal nuclease was calculated.
End Labeling Degraded DNAAfter incubation with Cyp, the DNA was purified by phenol/chloroform/isoamyl alcohol (25:24:1) extractions followed by chloroform/isoamyl alcohol (24:1) alone. 10 units of terminal deoxynucleotidyltransferase (Life Technologies, Inc.) and 750,000 cpm of [32P]dCTP (ICN) were added to the DNA and incubated for 2 h at 37 °C. Labeled DNA was isolated by centrifugation through a Sephadex G-50 (Sigma) column and was then electrophoresed through a 1% agarose gel. The gel was dried and then exposed to autoradiographic film for visualization.
Gel Shift AssaysThe substrate DNA was an 18-mer oligonucleotide (CGACCAGAGTACGTGATG) that was end-labeled with terminal deoxynucleotidyltransferase (Life Technologies, Inc.) and [32P]dCTP. After incubating the DNA in the labeling reaction for 0.5 h at 37 °C, the reaction was stopped with 2 µl of 10 mM EDTA and brought to 100 ml with double-distilled H2O. The labeled DNA was separated from unincorporated nucleotides by a Sephadex G-25 (Sigma) spin column. The resulting labeled DNA was then diluted to 20,000 cpm/µl. 1 µl of this DNA was incubated in the absence or presence of 1 µg of CypB in a binding buffer (20 mM Tris-HCl, pH 8.0, 1 mM EDTA, 5% glycerol) for 16 h at 4 °C. The samples were then electrophoresed through a 6% polyacrylamide gel, the gels were dried, and the samples were visualized by exposure to XAR film (Kodak).
Electron MicroscopyElectron microscopy was performed as described previously (38). Briefly, the CypB/DNA samples were prepared by incubation of 1 µg of CypB with 1 µg of linearized plasmid DNA in the absence of ions. The samples were fixed with 0.6% glutaraldehyde and then passed through a BioGel A5 m (Bio-Rad) column to remove unbound proteins. The samples were mounted onto charged carbon-coated grids and dehydrated through a series of graded alcohol rinses, with a final wash of 100% alcohol. The grids were then shadowed with tungsten and examined by transmission electron microscopy.
Peptidylprolyl Isomerase AssayThe cis-trans-peptidylprolyl isomerase assay was performed as described previously (39). 50 µM n-succinyl-Ala-Ala-Pro-Phe p-nitroanilide was added to 35 mM Tris-HCl (pH 8) in a total volume of 1 ml at 10 °C. 1 µg of Cyp and 50 µl of 100 µM chymotrypsin were quickly added to the substrate and mixed. The chymotrypsin can cleave the p-nitroanilide substrate only when the proline residue is in the trans configuration. Once cleaved, the substrate produces a yellow color that can be quantitated by its absorbance at 390 nm (OD 390). The increase in optical density over time is indicative of the number of proline residues converted to trans over time. The OD 390 is read every 0.3 s for 3 s on a Beckman DU 640 spectrophotometer. The slope of OD versus time is the rate of conversion, and the average of at least three separate assays is shown for each given condition.
Chromatin Degradation AssayThe HeLa nuclei assay was performed as described previously (40).2 Briefly, HeLa cells were grown in suspension culture (1-7 × 105 cells/ml) at 37 °C in Joklik's minimum essential medium supplemented with 2% fetal calf serum, 2% calf serum, 2 mM glutamine, 75 units/ml penicillin and 50 units/ml streptomycin sulfate. HeLa nuclei were prepared by pelleting the cells and resuspending in 10 mM MgCl2, 0.25% Nonidet P-40. The nuclei were then pelleted and resuspended in 50 mM Tris (pH 7.4). Aliquots (2 × 106 nuclei) were then added to tubes containing 50 mM Tris (pH 7.4), 2 mM MgCl2, 1 mM CaCl2 (final concentrations in a total volume of 400 µl) in the presence or absence of 500 nM CypC. Samples were incubated for 5 h at room temperature with gentle rotation. Studies in our laboratory have shown that HeLa nuclei incubated under these conditions undergo very little spontaneous chromatin degradation (41).
For pulsed field analysis, 200 µl was removed at the end of the incubation, mixed with an equal volume of 1% Incert agarose (FMC Bioproducts) at 37 °C, transferred to a 0.5-cm2 mold, and placed at 4 °C for 5 min to solidify. Plugs were then incubated in 100 mM EDTA, 1% (w/v) N-lauroylsarcosine (10 ml) at 37 °C overnight before being transferred to 1 ml of the same buffer containing proteinase K (100 µg) and reincubated for a minimum of 16 h at 50 °C. Plugs were stored at 4 °C in this buffer until used. A 2.0-mm-thick slice of the agarose plug was equilibrated in 50 ml of 0.5 × TBE buffer for >3 h before being incorporated into a 1% agarose gel. The gel was placed in a clamped homogeneous electric field pulsed field system (Bio-Rad) filled with 0.5 × TBE and allowed to equilibrate to 14 °C before electrophoresis for 19 h at 6.0 V/cm with a linear switch interval ramp from 0.5 to 45.0 s. The parameters were chosen to optimally separate DNA fragments ranging from 10 to 500 kb (42)3 The gel was then stained with ethidium bromide and visualized by UV transillumination.
Following removal of the aliquot for pulsed field analysis,
conventional electrophoresis samples were prepared from the remaining nuclei by first adding EDTA, NaCl, and sodium dodecyl sulfate to a
final concentration of 25 mM, 540 mM, and
0.5%, respectively. TE buffer (10 mM Tris, pH 7.4, 1 mM EDTA) was added to bring the final volume to 400 µl,
and Proteinase K was added to 0.5 mg/ml. Samples were then incubated
for 1 h at 50 °C and extracted twice with
phenol/chloroform/isoamyl alcohol (25:24:1) and once with chloroform/isoamyl alcohol (24:1) alone. DNA was precipitated by adding
10 µl of 5 M NaCl plus 1 ml of ice-cold 100% ethanol and
incubating at 70 °C for at least 20 min. DNA was collected by
centrifugation, dried, and resuspended by incubating the pellet overnight at 37 °C in TE buffer containing 0.33 mg/ml DNase-free RNase A. DNA concentrations were determined spectrophotometrically, and
samples (15 µg) were then electrophoresed (3.25 h; 80 V) on a 1.8%
agarose gel submerged in 0.5 × TPE (40 mM
Tris-phosphate, 4 mM EDTA). Gels were subsequently stained
with ethidium bromide and visualized by UV transillumination.
Previously, we used a radioactive gel nuclease assay
to demonstrate that three members of the Cyp family, CypA, -B, and -C, are able to degrade DNA (29); however, this assay used a protein denaturation and renaturation step prior to analysis of nuclease activity, and thus it was unclear if native Cyps have the same nucleolytic activity. To determine whether the native Cyps could degrade DNA, we employed a solution nuclease assay that evaluates the
nuclease activity from the nondenatured recombinant protein. In this
assay, the purified Cyp is incubated with linearized plasmid (pUC18) in
the presence of 1 mM Ca2+ and 1 mM
Mg2+. The production of low molecular weight DNA indicates
an active nuclease in that sample. The results of the solution nuclease assay with purified CypA, -B, and -C are shown in Fig.
1. Samples with DNA only, in the absence or presence of
ions (Fig. 1A, Con panel, +EDTA,
+Ca2+/Mg2+
lanes, respectively) do not contain detectable levels
of degraded DNA. CypA and CypB show greater DNA degradation in the
presence of Ca2+ and Mg2+ than in the absence
of these ions (Fig. 1A, CypA and CypB
panels), whereas CypC can also degrade substantial levels of DNA
in the absence of any additional ions (Fig. 1A, CypC
panel, +EDTA lane). The nuclease activity of CypC is,
however, enhanced by the addition of the divalent cations (Fig.
1A, CypC panel,
+Ca2+/Mg2+
lane). Similarly, single-stranded DNA is best
degraded by CypA and CypB in the presence of Ca2+ and
Mg2+ and by Cyp C in either the absence or the presence of
these ions (Fig. 1B). Together, these data demonstrate a
nucleolytic action on different forms of DNA by native Cyps.
Determination of Optimal Conditions for Cyp Nuclease Activity
To obtain the ideal conditions for each Cyp's nuclease
activity and to be able to compare Cyp nuclease activity with that of
other apoptotic nucleases, we determined the optimal pH and ion
requirements of CypA, -B, and -C in vitro. The optimal pH for each Cyp was determined by performing a series of solution nuclease
assays over a pH range from 5.5 to 10.0, with increments of 0.5 pH
units. As shown in Fig. 2, CypA, -B, and -C can degrade the linearized plasmid substrate over the range of pH values, with the
maximum activity seen from pH 7.5 to pH 9.5. Quantitation of these
assays (data not shown) revealed that each Cyp had a slightly different
pH optimum, with CypA being most efficient at pH 8.0, CypB at pH 8.5, and CypC at pH 9.5.
Cation Dependence
Many of the nucleases proposed to be involved in apoptosis have been shown to be dependent on Ca2+ and/or Mg2+ for activation (32, 34, 43, 44); therefore, we were interested in determining how these two cations affected nuclease activity derived from Cyps. As shown in Fig. 1, some degradation occurs in the absence of added ions, especially with CypC; however, further experimentation with a series of solution nuclease assays performed at increasing Ca2+ and Mg2+ concentrations revealed that optimal degradation by each Cyp occurred at 1 mM of either ion (data not shown). The amount of DNA degraded in the presence of either ion alone was determined as the percentage degraded relative to the amount degraded in the presence of 1 mM Ca2+ and Mg2+. These results are shown in Table I. CypA and CypB had optimal nuclease activity with a combination of Ca2+ and Mg2+, whereas CypC was most active in the presence of Mg2+ alone. Under all circumstances, CypC displayed the greatest efficiency at DNA degradation, with a 100 times greater DNA degrading activity than CypA or CypB under the same experimental conditions (data not shown). Interestingly, this difference in activity was not appreciated in the previous experiments performed under denaturing conditions (29) and probably reflects an inefficient renaturation of CypC, the highest molecular weight protein of the three studied. These optimal conditions were applied to further characterizations of the nuclease activity and the interaction of Cyps with DNA.
Cyps Have Endonucleolytic ActivitySubstitution of
supercoiled DNA for linear DNA as substrate in the solution nuclease
assay allows for discrimination of Cyp endo- or exonuclease activity.
The addition of supercoiled plasmid to the digestion assays revealed
that it could be cleaved by CypA, -B, and -C (Fig. 3),
indicating that each pure protein had endonucleolytic activity.
Interestingly, both nicking and linearizing activities were observed in
both the presence and absence of added ions. CypA and CypB, which
degrade at a slower rate than CypC, clearly demonstrate a nicking
activity by the conversion of the supercoiled substrate (SC)
to both open circular (OC) and linear (L) forms prior to degradation to lower molecular weight forms (Fig. 3, CypA, +Ca++/Mg++
lane, and CypB,
+Ca++/Mg++
lane). CypC shows only a conversion to low molecular
weight DNA in the same time period (Fig. 3, CypC,
+Ca++/Mg++
lane).
CypB Binds to DNA in the Absence of Ca2+ and Mg2+
To explore the interaction between Cyps and DNA
more directly, we took advantage of the different efficiencies of DNA
degradation by the different Cyps. While CypC demonstrates a clear
nucleolytic activity in the absence of added ions, CypA and CypB show
much lower levels of DNA degradation in the absence of ions. Thus, by
incubating CypA and CypB with DNA in the absence of added ions, we were
able to observe a direct interaction between protein and the DNA
substrate. Several different approaches were employed, including gel
shift assays and electron microscopy, which allowed for a clear picture
of Cyp/DNA interaction. Fig. 4A shows a gel shift assay with CypB and radiolabeled linear pUC18 as a substrate. The
CypB lane shows a band of slower migrating DNA, indicating that it is bound to the protein. Electron micrographs of linear pUC18
and CypB incubated in a similar manner, i.e. without added ions, reveal CypB bound at discrete sites along the DNA strand (Fig.
4B). These are the first such images to show direct
interaction between CypB and linear DNA. The stochastic arrangement of
the CypB multimers along the DNA substrate suggests that some
specificity may be involved in Cyp binding to DNA.
Inhibitors of Cyp Nuclease Activity
An important property of a nuclease is its ability to be regulated in vivo. There are several agents, such as zinc (45) and aurintricarboxylic acid (46), that are well known inhibitors of both apoptosis and nucleases. We have previously shown that these two agents are capable of inhibiting Cyp nuclease activity in the radioactive gel assay at 2 and 1 mM, respectively (29). In the solution nuclease assay, 100 µM zinc completely blocked DNA degradation by each Cyp (data not shown). However, we were interested in determining whether more physiologically relevant factors, such as certain common ions, could also attenuate Cyp nuclease activity. We chose to examine the effects of K+ and Na+ on Cyp nuclease activity because ion fluxes have recently been shown to be involved in apoptosis (47, 48). When either K+ or Na+ was added to a solution nuclease assay containing 1 mM Ca2+ and Mg2+, there was a dose-dependent decrease in the amount of DNA degraded, with IC50 values at approximately 79 mM K+ and 48 mM Na+ (Table II). Lower concentrations of each ion resulted in partial inhibition of nuclease activity from Cyps in a dose-dependent manner. The effect of a specific Cyp-binding agent was then assessed for its ability to inhibit or enhance Cyp nuclease activity.
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The binding of the
immunosuppressant drug CsA to Cyp is known to inhibit the
peptidylprolyl isomerase activity of Cyps (16, 49). We also observe CsA
inhibition of peptidylprolyl isomerase activity. As shown in Fig.
5A, when the Cyp is incubated at a 1:1 molar
ratio with CsA for 15 min prior to being added to the assay reaction,
there is a complete inhibition of the Cyp isomerase activity (see
"Experimental Procedures"). However, when CsA is added to the
solution nuclease assay, we do not observe any change in the DNA
degradation profile (Fig. 5B). These results demonstrate that the Cyps we were evaluating for nuclease activity have isomerase activity and, further, that these Cyps are capable of binding to CsA
with a well characterized response. In addition, these data show for
the first time that the nuclease activity of Cyps is separate from the
isomerase activity.
Cyp Is Located in the Nucleus of Control and Apoptotic Thymocytes
While our previous work demonstrated a surprising
homology between NUC18, a nuclease isolated from apoptotic rat
thymocyte nuclei, and Cyp proteins (29), it was not clear whether Cyps were nuclear proteins in rat thymocytes. To address this question, we
developed antibodies directed against Cyp proteins. Western blot
analyses of nuclear and cytoplasmic extracts from rat thymocytes could
then be performed. The results (Fig. 6) showed an 18-kDa band that reacts to these antibodies, revealing that Cyp is located in
both the nucleus and the cytoplasm of rat thymocytes. Additionally, we
were also interested in determining whether Cyp levels in either compartment were altered following stimulation of apoptosis. Nuclear and cytoplasmic extracts were prepared from thymocytes isolated at
increasing time points following dexamethasone treatment of rats (0-4
h) and analyzed by Western blotting. These results indicated that there
were no changes in Cyp levels in either the nucleus or cytoplasm during
the early stages of apoptosis. The Western blot for the 4-h time point
is also shown in Fig. 6. Thus, we observed that Cyps are located in the
nucleus as well as the cytoplasm of rat thymocytes and that the levels
of the protein are unchanged during dexamethasone-induced
apoptosis.
Cyps Produce 3
After characterizing a variety of
aspects of nuclease activity from Cyps to compare with apoptotic
nucleases, we next wanted to determine what type of termini was
produced in the Cyp-fragmented DNA, because apoptotic DNA fragmentation
is associated with the formation of 3-OH termini (50). Terminal
deoxynucleotidyltransferase specifically attaches free nucleotides to
3
-OH termini of DNA, so we could determine if Cyps caused the
formation of free 3
-OH groups by attempting to label Cyp-cleaved DNA
products with terminal deoxynucleotidyltransferase and
[32P]dCTP. These assays revealed an increase in the
number of 3
-OH termini in the digested versus the control
samples (Fig. 7; cf. Control lane
with CypA and CypB lanes). The DNA digested with micrococcal nuclease, which produces termini with 3
-phosphate groups
does not label with terminal deoxynucleotidyltransferase (Fig. 7,
MN lane). With the generation of 3
-OH termini, Cyps exhibit
a similarity with the nuclease (or nucleases) activated during
apoptosis.
CypC Generates 50-kb DNA Fragments in Chromatin
With the
solution nuclease assay, we have been able to show that many aspects of
Cyp nuclease activity are similar to that of apoptotic nucleases. To
further explore the notion that Cyps may be nucleolytically active
during apoptosis, we investigated the most active Cyp, CypC, for its
ability to digest chromatin DNA in the HeLa nuclei assay. Because there
are two different types of DNA degradation observed during apoptosis
(50-kb fragments and smaller, internucleosomally cleaved fragments
(51)), we looked for both DNA degradation patterns in HeLa DNA
following incubation with CypC. As shown in Fig. 8, the
addition of CypC to HeLa nuclei in the presence of Ca2+ and
Mg2+ completely eliminated the high molecular weight
chromatin (panel B), as shown by loss of DNA in the well and
the compression band. The addition of CypC also generated a 50-kb band
of DNA from the HeLa chromatin. Additionally, an increase in low
molecular weight DNA is observed (panel A), although
internucleosomal degradation patterns were not observed. This assay
demonstrates that CypC is capable of acting on chromatin DNA and
generating a 50-kb product, similar to what is observed during
apoptosis.
Cyps comprise a highly abundant family of proteins (1) that are expressed in every organism studied to date. They possess peptidylprolyl cis-trans-isomerase activity (16, 49), and have been shown to enhance the folding rate of several proteins in vitro (15-17). We recently reported a sequence and structural homology between Cyps and NUC18, an apoptotic nuclease, and demonstrated that several members of the Cyp family have an inherent nuclease activity (29). We have now further characterized the nuclease activity of Cyp and demonstrated that it is located in the nucleus and shares many characteristics with nucleases associated with apoptosis.
Although there is still some debate as to the pH in apoptotic cells,
there are many reports of an apoptotic nuclease with a pH optimum in
the 7.5-9.5 range (32, 52-54), similar to that observed for CypA, -B,
and -C. These three Cyps display an ion-dependent nuclease
activity that can be activated by either Ca2+ or
Mg2+ or by a combination of both, although to different
efficiencies in each. This Ca2+/Mg2+ dependence
correlates with what has been observed for apoptotic nucleases in other
studies (32-35). Interestingly, we observe a much stronger activation
of CypC by Mg2+ alone than by Mg2+ plus
Ca2+. Sun and Cohen (43) were recently able to distinguish
two apoptotic nuclease activities (50-kb fragmentation from
internucleosomal cleavage) by using Ca2+ and
Mg2+ ions, such that the addition of Mg2+ alone
to nuclei resulted in the digestion of DNA into 50-kb fragments, while
internucleosomal cleavage was not observed until Ca2+ was
added in conjunction with the Mg2+. Thus, the strong
activation of CypC by Mg2+ alone, plus the observation that
CypC addition to isolated nuclei results in the formation of 50-kb
fragments of chromatin DNA, suggests that CypC could be responsible for
the cleavage of DNA into 50-kb fragments. We also observe inhibition of
Ca2+/Mg2+-stimulated nuclease activity at
physiologically relevant levels with the ions Na+ and
K+. The normal intracellular concentration of
K+ is approximately 140 mM, a concentration
high enough to inhibit Cyp nuclease activity; however, the decrease in
the intracellular K+ concentration during the shrinkage of
cells undergoing apoptosis (47)4 results in
conditions in which Cyps become active nucleases. The inhibitory effect
of Na+ at concentrations that correspond to the higher
levels observed in necrotic cells (55) suggests that Cyps would not act
during necrotic cell death. Thus, these two facts together imply that Cyps can act as apoptotic-specific nucleases. An important finding first discovered in our study is the production of 3-OH termini by
Cyp, which corresponds to what has been observed in many cases of
apoptosis (50). In fact, the terminal
deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling
(TUNEL) method, a technique widely used to detect apoptotic cells
in situ (50), is based on the overproduction of 3
-OH ends
in apoptotic cells. Thus, these data demonstrate that the
characteristics of Cyp nuclease activity are suggestive of an apoptotic
nuclease.
Because the catalytic activity most associated with Cyps is peptidyl-prolyl isomerization, we were interested in determining whether the novel nuclease activity of Cyps was related to the isomerase activity. The addition of the high affinity ligand CsA to the solution nuclease assay did not affect the ability of Cyps to degrade DNA, whereas it completely blocked the isomerase activity. These results indicate that the nuclease and isomerase properties of Cyps are distinct.
Although the rate of isomerization by the Cyps in in vitro
assays shows a high efficiency (56), Cyps degrade DNA at a lower rate
compared with the well characterized micrococcal nuclease. This highly
efficient enzyme (which has a turnover rate of 95 s1;
Ref. 57) degrades DNA approximately 1000 times faster than CypC. CypC,
in turn, displays a nuclease activity approximately 100 times greater
than CypA and CypB. There are several potential reasons for this
apparently slower rate of Cyp nuclease activity. The first is that the
proteins used in these assays are recombinant forms and therefore may
be missing an essential post-translational modification that enhances
their nucleolytic activity. Another possibility is that complete
activation of the Cyps requires a co-factor or additional protein that
was absent from our solution nuclease assays. We have shown that
multimers of CypB bind to a strand of DNA with some specificity. It may
be that an additional protein will enhance the DNA binding and
nucleolytic activities of Cyp. Indeed, Cyp binds only weakly to
calcineurin by itself, but it shows great affinity for calcineurin with
the addition of CsA (58). Thus, there are several possibilities to
account for the rate of DNA degradation by Cyps. Nevertheless, it was important for us to determine if the nuclease activity of Cyps was
sufficient to account for the levels of DNA degradation observed during
apoptosis in vivo. To completely convert chromatin, which contains 6 × 109 nucleotides (59), to 50-kb
fragments, 60,000 phosphodiester bonds must be cleaved. Human
thymocytes contain approximately 540,000 molecules of CypA (based on an
average of 1.6 µg of CypA/mg of cell protein) (8). Therefore, only
60,000, or 11%, of all CypA molecules in the thymocyte need to be in
contact with the chromatin and to make one disruption of the
phosphodiester bond to completely reduce the chromatin to 50-kb
fragments. Thus, the number of CypA molecules is more than adequate to
at least account for the complete degradation of the genome to 50-kb
fragments during apoptosis.
How might Cyps become active as nucleases during apoptosis? We have already shown that the levels of the protein remain unchanged during apoptosis; therefore, we propose several potential activation mechanisms. The first potential activation mechanism involves the loss of K+ ions at the onset of apoptosis. We have shown how the normal intracellular K+ levels are sufficient to prevent Cyp activity and that a decrease in K+ levels allows Cyp nuclease activity to occur. Thus, attenuation of K+ levels in the nucleus may be all that is necessary to activate Cyp nuclease activity. An additional possibility is that the loss of K+ ions stimulates release of Cyp from an inhibitory complex, freeing the active Cyp to act on the chromatin. In support of this idea, earlier work in our laboratory revealed that NUC18 was associated with a high molecular weight complex in nonapoptotic cells (60). Work performed in other laboratories (61), has shown that Cyp is part of a large multiprotein complex, which also suggests the possibility of an inhibitory complex for Cyp under nonapoptotic conditions. Another possible mechanism for activation of Cyp nuclease activity is that Cyps may have altered post-translational modification during apoptosis such that they are now capable of degrading the chromatin DNA. Recently, Chatellard-Gruaz et al. (62) demonstrated that isoforms of CypA were differentially expressed during keratinocyte differentiation, a process with many similarities to apoptosis. Additionally, Krummrei et al. (41), who describe CypA as a Zn2+-dependent DNA-binding protein, suggest that CypA exists in two isoforms, one of which involves Zn2+-dependent DNA binding and the other involving Zn2+-independent isomerase and nucleolytic activity. Thus, there are several potential mechanisms to explain how Cyp might act as an apoptotic nuclease.
In summary, we have characterized several different aspects of Cyp
nuclease activity, all of which suggest that Cyps could be apoptotic
nucleases. For example, Cyps display a dependence on Ca2+
and Mg2+ for optimal activity, and they produce 3-OH
termini in the digested DNA. They are also capable of degrading a
variety of DNA substrates and can generate 50-kb fragments in HeLa
chromatin. We propose that Cyps are activated to degrade chromatin
during apoptosis. Further analysis of the role of Cyp in apoptosis is
ongoing.
We thank Sandoz Laboratories for the generous donation of purified cyclophilins A, B, and C. We also thank Dr. Jack Griffith and Carl Bortner for knowledgeable assistance with electron microscopy.