(Received for publication, October 26, 1994; and in revised form, January 6, 1995)
From the
A previous report from this laboratory described an estrogen-regulated endoribonuclease activity on Xenopus liver polysomes which had properties one might expect for a messenger ribonuclease involved in the regulated destabilization of albumin mRNA (Pastori, R. L., Moskaitis, J. E., and Schoenberg, D. R.(1991) Biochemistry 30, 10490-10498). This report describes the purification and properties of this ribonuclease. The purified nuclease fraction contained a doublet of 62 and 64 kDa and a small amount of a 40-kDa peptide. In situ analysis on both denaturing and nondenaturing gels using an albumin transcript as substrate showed all three proteins possess nuclease activity. Peptide mapping and Western blot with a polyclonal antiserum showed the 62- and 64-kDa peptides to be isoforms, and the 40-kDa peptide to be a degradation product of the larger species. Two-dimensional gel electrophoresis further separated the 62- and 64-kDa species into three pairs of proteins, with isoelectric points of 9.6, 9.8, and 9.8. The purified ribonuclease rapidly degraded a full-length albumin transcript, yet had no effect on either a full-length albumin antisense transcript or full-length ferritin transcript. A number of properties of the purified nuclease were characterized, including the effects of salt, divalent cations, EDTA, sulfhydryl reagents, and temperature. Treatment of the polysomal nuclease with micrococcal nuclease had no effect, indicating that this enzyme does not require an RNA cofactor for activity. Finally, primer extension mapped the major cleavage site to an overlapping repeated sequence APyrUGA, with cleavage between and adjacent to the two pyrimidine residues generating fragments with 5`-hydroxyls.
The past several years have seen significant advances in our understanding of gene regulation through changes in mRNA stability (reviewed in (1) ). A number of sequence elements have been identified that, when present in a given mRNA, can alter its stability. The best characterized examples of this are the AU-rich element found in the 3`-untranslated region of a number of cytokine and oncogene mRNAs (e.g. granulocyte-macrophage colony-stimulating factor, c-fos, c-myc,(2, 3, 4, 5, 6) ) and the iron-responsive element present in the 3`-untranslated region of the transferrin receptor mRNA(7, 8, 9) . It is clear that such elements can serve as binding sites for specific proteins, such as those specific for AU-rich elements (10, 11, 12) and the iron-responsive element-binding protein(8, 9, 13, 14) . It is believed that such binding promotes the degradation (in the case of granulocyte-macrophage colony-stimulating factor or c-myc) or stabilization (in the case of transferrin receptor) of the target mRNA.
A major advance in understanding the mechanisms of regulated mRNA turnover has been the development of in vitro degradation systems which mimic in vivo degradative pathways for a number of mRNAs (reviewed in (15) ). In general these systems can be subdivided into three components: the mRNA under study, the proteins that interact with specific sequence elements which identify such mRNA for selective stabilization or degradation, and a nuclease or group of nucleases that catalyze the degradative process. A number of such nucleases have been identified in crude extracts, each of which appears to play a role in specific mRNA degradation. Ross and co-workers (16, 17, 18) have identified a polysomal 3`-5` exonuclease that catalyzes the degradation of histone mRNA in vitro. That group has also identified and characterized a 3`-5` exonuclease that degrades c-myc mRNA in vitro(19) . Bandyopadhyay et al.(20) have reported on an endonuclease present in mRNP complexes, and a subsequent report from that laboratory described a 5`-3` exonuclease present in cytoplasmic extracts(21) . Perhaps the best characterized mRNA degradative enzyme in eukaryotes is the poly(A) nuclease found in Saccharomyces cervisiae(22) . The substrate for poly(A) nuclease is the complex of the 3` poly(A) tail with poly(A)-binding protein, which is degraded by poly(A) nuclease in a 3`-5` manner.
Parker and co-workers have identified what they believe will be a common pathway for non-regulated mRNA decay, in which the first committed step is deadenylation by the poly(A) nuclease, followed by decapping and subsequent degradation by the 5` exonuclease encoded by the XRN1 gene(23) . In addition, that laboratory recently reported that in yeast, nonsensemediated decay proceeds through decapping and degradation by the XRN1 nuclease without prior deadenylation(24) . To date there are no similar data on either constitutive mRNA turnover or nonsense-mediated mRNA turnover in higher eukaryotes.
In contrast to the decay pathways described above, there is a growing body of evidence that regulated mRNA instability may be affected through the action of endonucleases. Some examples of this include the degradation of apo-very low density lipoprotein II mRNA in avian liver (25) , interleukin 2 mRNA in T cells(26) , insulin-like growth factor II mRNA(27) , maternal homeobox-containing mRNAs in Xenopus oocytes(28, 29) , Drosophila embryos(29) , and transferrin receptor mRNA(30) . In the latter, the major endonuclease cleavage site maps to a region adjacent to an iron-responsive element. Binding of the iron-responsive element-binding protein to the iron-responsive element during periods of iron deprivation may stabilize transferrin receptor mRNA by masking this endonuclease cleavage site.
In Xenopus, liver estrogen
causes a reorganization of the translational pattern for secreted
proteins from one in which the major products are the serum proteins,
to one in which the yolk protein precursor vitellogenin predominates
(reviewed in (31) )). This is accomplished by three basic
mechanisms: 1) the transcriptional induction(31, 32) ,
2) subsequent stabilization (31) of vitellogenin mRNA, and 3)
the destabilization of the mRNAs encoding the major serum
proteins(33) . The latter results in the virtual disappearance
of mRNAs for albumin, transferrin, -fibrinogen, and trypsin
inhibitor from the cytoplasm shortly after exposure to hormone. The
mRNAs encoding ferritin, poly(A)-binding protein or actin remain
unaffected by estrogen, consistent with a model in which regulation is
restricted to those mRNAs encoding secreted proteins(33) .
We recently described a novel ribonuclease activity on Xenopus liver polysomes that has characteristics consistent with those of a messenger ribonuclease(34) . Little ribonuclease activity was detectable in polysome preparations from control male animals. However, polysomes from estrogen-treated male frogs showed substantial ribonuclease activity. This activity could be extracted with salt, and the extractable material showed differential activity against albumin versus ferritin mRNA using as substrate either total liver RNA or the 20-80 S mRNP fraction. The crude enzyme was shown to be an endonuclease that did not require divalent cations for activity and was not inhibited by EDTA. Similarly it was resistant to inhibition by placental ribonuclease inhibitor and N-ethylmaleimide. The nuclease is not a component of either ribosomal subunit, but requires both subunits be together in an 80 S complex for its association with polysomes(35) .
In order to decipher the molecular mechanisms involved in the estrogen regulation of albumin mRNA stability we chose to focus on the regulation and characterization of this enzyme. In the present report we describe the purification of this enzyme to homogeneity and examine a number of important properties of the purified nuclease. The purified enzyme is a substrate-selective endonuclease which displays many of the properties described earlier (34) for the crude activity extracted from polysomes. Primer extension analysis demonstrates that the major site of cleavage lies in a repeat of the sequence APyrUGA, suggesting that the messenger ribonuclease may also be considered a sequence selective enzyme.
Figure 3: Relationship between the 62-, 64-, and 40-kDa proteins. A, the 62-, 64-, and 40-kDa proteins present in a 1-µg sample of the purified nuclease were separated on a 12% SDS-PAGE. Each protein was digested separately with alkaline protease (lanes 1-3), endoproteinase Glu-C (lanes 4-6), and endoproteinase Lys-C (lanes 7-9) in the stacking gel of a 15% SDS-PAGE for 30 min. Following electrophoresis the proteolytic products were visualized by silver stain. The largest species in lanes 4, 5, 7, and 8 are the intact 62- and 64-kDa proteins, respectfully. The 40-kDa species is present as the largest band in lanes 3, 6, and 9. B, a polyclonal antiserum prepared against the 62/64-kDa doublet was diluted 1:20,000 and used to detect a Western blot of 1 µg of a partially purified nuclease preparation (lane 2) or 1 µg of a preparation of pure polysomal nuclease which has no contaminating 40-kDa material (lane 3). The sample in lane 4 is another lane from the blot that contains the same pure nuclease preparation as in lane 2. This was reacted with an immunoselected antibody that had been eluted from the 40-kDa band of a Western blot of a nuclease preparation like that in seen Fig. 4, lane 5. The bands were detected by enhanced chemiluminescence followed by a 10-s exposure to Hyperfilm-ECL.
Figure 4: Two-dimensional gel analysis of the 62-, 64-, and 40-kDa peptides. Five µg of a preparation that contained a substantial fraction of the 40-kDa breakdown product was separated by isoelectric focusing in the first dimension and SDS-PAGE in the second dimension. The separated proteins were visualized by silver staining.
Isoelectric focusing was
performed in a 10 8-cm slab gel (1.5 mm thick) consisting of 5%
acrylamide/bisacrylamide (37.5:1), 10% glycerol, 1.5% 3/10 Bio-Lyte
ampholyte, and 0.5% 8/10 Bio-Lyte ampholyte (Bio-Rad). In the
experiment shown in Fig. 4, a 5-µg sample containing both
the 62/64-kDa nuclease and the 40-kDa fragment was mixed with an equal
volume of 60% glycerol, 1.5% 3/10 ampholyte, 0.5% 8/10 ampholyte and
loaded onto the gel. The gel was focussed at 200 V for 1.5 h (4 °C)
in 25 mM NaOH (cathode) and 20 mM acetic acid
(anode). The pI of the samples was determined by the migration of
isoelectric focusing standards (Bio-Rad) run in a parallel lane. The
gel was fixed after isoelectric focusing in 10% trichloroacetic acid
for 10 min, followed by an overnight incubation in 1% trichloroacetic
acid. The gel strip containing the separated proteins was equilibrated
for 30 min in SDS sample buffer and overlaid onto the stacking gel of a
12% SDS-PAGE (10
8 cm, 1.5 mm). The separated proteins were
visualized by silver staining.
Figure 2:
Reconstitution of nuclease activity on
denaturing and nondenaturing gels. A, two µg of purified
nuclease shown in Fig. 1, lane 5, was electrophoresed
at 4 °C in an SDS-PAGE containing 220 µg/ml of unlabeled
albumin transcript. Following electrophoresis the gel was processed for
protein renaturation, incubated at 37 °C to enable in situ digestion of the RNA, and stained with toluidine blue. B,
one µg (lanes 2-4) or 1.5 µg (lane 5)
of the indicated samples were electrophoresed at 4 °C on a
nondenaturing polyacrylamide gel in which 3 10
dpm
of radiolabeled transcript had been incorporated. Following
electrophoresis the gel was equilibrated in reaction buffer, incubated
at 25 °C to enable in situ digestion of the RNA, dried,
and autoradiographed. C, the portion of a paired gel to that
in B, which contained nuclease activity and had not been
dried, was electrophoresed on a 12% SDS-PAGE and
silver-stained.
Figure 1: Summary SDS-PAGE of active fractions throughout the isolation procedure. The samples from each fractionation step that contained enzymatic activity were analyzed on a single 12% SDS-PAGE and visualized by silver stain. All lanes contain 0.5 µg of protein except for lane 5 which contains 1 µg. The starting dissociated liver polysomal extract applied to the QAE column (QAE load) is shown in lane 2, the eluate of this column which was applied to the SE column (SE load) is in lane 3, the eluate of the SE column which was applied to the HTP column (HTP load) is in lane 4, and the peak of activity from the HTP column is in lane 5 (see ``Materials and Methods'' for details on the column fractionation procedure).
In Fig. 2B, a native 10% polyacrylamide gel was prepared
in 8.9 mM Tris, pH 8.4, 8.9 mM boric acid, 2 mM EDTA containing 3 10
dpm/ml of a
P uniformly labeled albumin transcript. The gel was
electrophoresed at 150 V for 2 h at 4 °C. It was next washed for 1
h in 40 mM Tris-HCl, pH 7.5, 10 mM MgCl
,
2 mM EDTA, 10% glycerol at 25 °C and left overnight in the
same buffer at 4 °C. The gel was dried and autoradiographed.
Ribonuclease activity was identified as a clear area on the
autoradiogram. The portion of the gel containing the activity shown in Fig. 2B was excised from a paired sample, denatured,
and electrophoresed on a 12% SDS-PAGE. Protein was detected by silver
stain (Fig. 2C).
Figure 6:
Properties of the purified polysomal
nuclease. In each experiment the basic protocol utilized 250 ng of
purified nuclease incubated at 22 °C for 30 min with 500 pg of P-labeled transcript of the 5` 500 nt of albumin mRNA in
40 mM Tris-HCl, pH 7.5, 2 mM dithiothreitol. Lane
2 is the starting transcript, lane 3 is transcript
incubated alone under the above conditions, and lane 4 shows
the result of the 30-min incubation of transcript with the nuclease. In lanes 5 and 6 the reaction mixture was supplemented
with 10 mM MgCl
or 10 mM EDTA,
respectively. Lanes 7-10 show the effect of addition of
10, 50, 100, and 400 mM NaCl to the reaction buffer. Placental
ribonuclease inhibitor (20 and 100 units) was added to the reaction
mixture in lanes 11 and 12. In lanes 13-17 the purified nuclease was first heated for 5 min at 50, 60, 70,
80, and 90 °C prior to the start of the reaction. Lane 1 (M) contains a marker of end-labeled HinfI
restriction fragments of
X174 DNA. The position of the 194-nt
doublet cleavage fragment is shown with the closed arrow, and
the 306-nt fragment from the 3` portion of the transcript is shown with
the open arrow.
Figure 7:
Endonuclease activity of the purified
enzyme. A, the RNA degradation assay was performed with a 5`
end-labeled albumin substrate RNA prepared by transcription in a buffer
containing [-
P]GTP. Lanes 2 and 3 contain RNA incubated at 4 and 22 °C, respectively, with
no added nuclease. The cleavage of the end-labeled transcript by the
nuclease is shown in lane 4. B, double-stranded RNA
was prepared by hybridization of a
P-labeled albumin sense
transcript with an excess of unlabeled antisense transcript. Lanes
2 and 3 are the same controls as in A.Lane
4 is a control for the standard digestion of albumin sense
transcript with 250 ng of purified nuclease. Lane 5 consists
of double-stranded RNA incubated without added nuclease, and lane 6 shows the effect of the same RNA incubated with the purified
nuclease. Lane 1 contains
X174 HinfI fragments
as size markers. The arrowhead on both gels shows the position
of the 194-nt doublet cleavage product.
Figure 8:
Evidence that an RNA cofactor is not
required for nuclease activity. P-Labeled albumin
substrate transcript was incubated for 30 min at 22 °C in the
absence of added nuclease (lane 1), with purified polysomal
nuclease (lane 2), with micrococcal nuclease (MNase)
at 20 °C for 15 min (lane 3), followed by 10 mM EGTA to stop the reaction (lane 3), or with micrococcal
nuclease in buffer containing 10 mM EGTA (lane 4). In
the reaction shown in lane 5, purified nuclease was incubated
first with micrococcal nuclease for 15 min at 20 °C, followed by 10
mM EGTA to stop the reaction. This was then added to
radiolabeled albumin substrate transcript and incubated under standard
reaction conditions. The arrow shows the position of the
194-nt doublet cleavage product.
Figure 9: Determination of the nuclease cleavage site on the substrate transcript. The substrate transcript was digested for 30 min at 22 °C with purified nuclease, extracted with phenol, and ethanol-precipitated. The product of this reaction was annealed with an endlabeled oligonucleotide complementary to a site 311 nt from the 5` end of the RNA followed by primer extension with reverse transcriptase. Samples from duplicate reactions were applied to the gel (lanes 5 and 6). Lane 7 is a control primer extension performed on undigested RNA. The position of the cleavage sites was determined relative to a dideoxy sequencing ladder generated with the same primer, cloned albumin cDNA and modified T7 DNA polymerase (lanes 1-4).
We operationally define 1 unit of the
polysomal nuclease as that which causes the disappearance of 1 ng of a P-labeled 5` 500-nt albumin transcript completely in 30
min at 22 °C. The activities of each of the column fractions were
determined by PhosphorImager analysis of the surviving transcript on
acrylamide/urea gels. Linear plots of the degree of substrate
disappearance with time for each of the column fractions were then used
to calculate the purification data in Table 1. By this approach
we determined the overall purification was 235-fold for the final
fraction obtained from the HTP column compared with the starting
polysomal extract. This number is likely a significant underestimate of
the actual fold purification (see ``Discussion'').
Further confirmation that the proteins identified in Fig. 1possess nuclease activity was obtained by native (nondenaturing) gel electrophoresis (Fig. 2B). In this experiment, radiolabeled albumin transcript was incorporated into the gel and 1 µg (lanes 2-4) or 1.5 µg (lane 5) of the indicated samples were electrophoresed at 4 °C. The gel was equilibrated in reaction buffer, incubated at 25 °C to allow for in situ digestion of the radiolabeled transcript, washed, dried, and autoradiographed. The nuclease that generates the 194-doublet cleavage product is a basic protein as evidenced by its inability to bind to QAE and its behavior in preparative isoelectric focusing (see below). We anticipated that it would barely enter the gel, whereas other nucleases would likely fractionate throughout. The data in Fig. 2B confirm this. Electrophoresis of the crude Triton-EDTA extract (QAE load, lane 2) resulted in clearing over one-half of the length of the gel. A similar pattern of nuclease activity was observed in that which eluted in the unbound fraction of the QAE column (SE load, lane 3). The presence of nuclease activity only at the top of the gel in the sample obtained from the SE column (HTP load, lane 4) indicated that this column separated the enzyme under study from most other contaminating nucleases. Similarly, clearing was only observed at the top of the lane containing the purified nuclease (lane 5). It should be noted that the stronger signal here resulted from the use of a larger amount (1.5 µg) of a more purified protein fraction than was loaded onto lane 4. To identify which proteins were responsible for the nuclease activity in lane 5, this portion of the gel was excised and fractionated by SDS-PAGE. Silver staining reveals only the presence of the 62/64-kDa doublet and a small amount of the 40-kDa peptide (Fig. 2C, lane 7). We have also extracted the 62/64-kDa doublet and the 40-kDa peptide from SDS gels, renatured these samples, and found that they both contain nuclease activity (data not shown). Taken together, these data prove that the proteins eluted from the HTP column correspond to the nuclease which generates the unique cleavage of albumin mRNA in vitro.
Further proof of the relationship between the 40- and 62/64-kDa proteins was obtained by Western blot. A polyclonal antiserum was prepared in one rabbit, using as antigen the 62/64-kDa material excised from an SDS-PAGE of the purified nuclease. This antiserum reacts with both the 62/64-kDa doublet and the 40-kDa band when used to study preparations that contain both species (like that shown in Fig. 1, lane 5, data not shown). To determine whether the 40- and 62/64-kDa species are related, the antibody bound to the 40-kDa band was eluted from the membrane and used to probe a Western blot of a preparation of pure nuclease that contained no detectable 40-kDa species by silver stain. The data in Fig. 3B, lane 4, demonstrate that the antibody selected against the 40-kDa peptide reacts with the 62/64-kDa species. This result provides further proof that the 40-kDa peptide is related to the 62/64-kDa species. For the purpose of comparison, lanes 2 and 3 of Fig. 3B show blots of adjacent lanes of the same gel containing partially purified material obtained from the SE column (Fig. 1, HTP load, lane 4) and the pure nuclease used in lane 4 probed with the unfractionated antiserum. The unfractionated antiserum identifies the 62/64-kDa species in both cases, and upon longer exposure, the 40-kDa species can be seen in the partially purified material in lane 2 (data not shown).
Figure 5:
Selectivity of the purified nuclease for
albumin mRNA. Uniformly labeled full-length transcripts of albumin
mRNA, the antisense strand of albumin mRNA, and ferritin mRNA were
incubated with the purified nuclease at 22 °C. Portions of the
reaction mixture were removed at the indicated times and
electrophoresed on a urea/acrylamide gel. A 4-h exposure of that
portion of the gel containing the full-length mRNAs is shown in A, and a quantitative analysis of the disappearance of these
RNAs is shown in B (, albumin mRNA;
, ferritin
mRNA;
, albumin antisense transcript). A 20-h exposure of the
entire gel is shown in C, with the arrow indicating
the position of the characteristic 194-nt doublet cleavage
fragment.
The data in lanes 7-10 show the effect of 10, 50, 100, and 400 mM NaCl on the activity of the purified enzyme. Ten mM NaCl gave the same result as the control (lane 4). However, 50 mM NaCl resulted in more substantial substrate degradation (lane 8) and still greater degradation was obtained at 100 mM NaCl (lane 9). It is interesting to note that at this higher salt concentration there was also preferential accumulation of the 194-doublet cleavage product. The significance of this is unclear, although this higher salt concentration might stabilize the major cleavage product. Addition of 400 mM NaCl resulted in the inactivation of the purified nuclease (lane 10). Most ribonucleases related to the RNase A family of enzymes can be inhibited by placental ribonuclease inhibitor (RNasin(TM)). Addition of either 20 units (lane 11) or 100 units (lane 12) of recombinant RNasin increased enzymatic activity. We have been able to achieve the same effect with bovine serum albumin, suggesting that this effect is due to stabilization of the nuclease at the low protein concentration used in the assay (see below). Control experiments demonstrated that neither the RNasin or BSA preparations used in these experiments possess nuclease activity in our assay (data not shown). The sulfhydryl reagent N-ethylmaleimide had no effect on the activity of the purified nuclease (data not shown). Last, the relative temperature stability of the purified nuclease was examined. Lanes 13-17 show the effect of a 5-min incubation at 50, 60, 70, 80, and 90 °C prior to the start of the reaction. The nuclease activity was unaffected by incubation at 50 and 60 °C (compare lanes 13 and 14 with lane 4) and was inactivated at 70 °C and above. Thus, the nuclease is relatively temperature-stable. It should be noted that all of the experiments in this paper were performed at the optimal pH for activity of the nuclease (7.5).
The preceding experiments were all performed with the albumin sense transcript alone. The experiment in Fig. 7B was a first step toward addressing the role of RNA structure and/or conformation as it relates to cleavage by the polysomal nuclease. In this experiment a double-stranded RNA was generated by hybridizing an excess of unlabeled albumin antisense transcript to the radiolabeled sense strand. Whereas the radiolabeled sense strand alone was degraded by the purified nuclease (lane 4), the hybrid formed with the antisense strand was resistant to digestion (lane 6). It is highly unlikely that the inhibition observed resulted from competition by excess unhybridized antisense RNA because inclusion of 10 µg of either liver RNA or tRNA have no effect on the degradation of the substrate transcript, and the nuclease does not degrade albumin antisense RNA (see Fig. 5). The band that migrated slightly faster than the substrate transcript in lane 6 results from incomplete denaturation of the duplexed RNA and is not a product of nuclease degradation. We conclude that there must be structural features of albumin mRNA that are important in either the mechanisms of targeting or degradation by the nuclease.
This is the first report of the isolation and
characterization of a ribonuclease involved in regulated mRNA turnover
in higher eukaryotes. Several lines of evidence point to this protein
as being important in the destabilization of albumin mRNA following
estrogen administration. First, the amount of enzymatic activity is
significantly increased following estrogen administration. Second, this
activity shows differential substrate selectivity for albumin versus ferritin mRNA that mirrors the relative stabilities of
these mRNAs in vivo after hormone treatment(33) .
Third, breakdown products identified in liver RNA after estrogen
administration result from cleavage in vivo at the same sites
as cleaved in vitro by the purified nuclease. ()
Throughout these prior studies we used the ability of the polysomal nuclease to generate a doublet 194-nt cleavage product from a 500-nt 5` albumin transcript as an assay for the specific estrogen-inducible activity. This property was used here to follow the purification of the nuclease and to characterize some properties of the purified enzyme. Although the major site of cleavage is that which generates the 194-nt doublet product (Fig. 9), the product generated by this is itself subject to further cleavage by the nuclease. Because of this we had to rely on the disappearance of the substrate transcript for calculating the specific activity of the polysomal nuclease throughout its purification. By this method an overall 235-fold purification was obtained from the crude polysomal extract to the final product from the HTP column. It is likely this is a significant underestimate of the true magnitude of purification. The data in Fig. 2B indicate that there are many nucleases present in the crude polysomal extract. The 77 units/mg calculated for this material represents the sum of the activities of all of these nucleases, of which the enzyme of interest likely represents only a small fraction. Further confounding these data is the presence of an endogenous inhibitor of the polysomal nuclease that we described previously(34) . It is unclear to what degree this inhibitor alters the observed specific activity, at which step in the purification it is removed, or indeed how strongly it binds to, and inhibits the action of the nuclease.
Based on the purification and in situ gel reconstitution data, we believe that the biologically active form of the nuclease is represented in the 62- and 64-kDa species. As noted above, peptide mapping data indicate these to be isoforms of the same enzyme, their duplication likely a result of the duplicated Xenopus genome. We believe that the 40-kDa peptide is most likely a breakdown fragment of the larger proteins that is generated during purification. There are six reasons for this supposition. First, the 40-kDa peptide possesses catalytic activity similar to that of the larger molecules. Second, it is not found in every preparation of nuclease, and its presence appears to correlate inversely with the relative recovery of the 62/64-kDa material. Third, it is found in that portion of the nondenaturing gel in Fig. 2B that contains both the 62- and 64-kDa species and ribonuclease activity. Fourth, only the 66-kDa fraction obtained by gel filtration of crude material demonstrates specific ribonuclease activity on albumin RNA. Fifth, a peptide fragment generated with endoproteinase Glu-C digestion of the 40-kDa protein coincides with a fragment obtained from the 62- and 64-kDa species. The 40-kDa peptide is not cleaved with endoproteinase Lys-C at the concentration employed in this experiment, yet endoproteinase Lys-C digestion of the 62- and 64-kDa proteins yields the same size fragment. In fact, both endoproteinase Glu-C and alkaline protease digestion of the 62- and 64-kDa proteins yield a 40-kDa fragment (Fig. 3A, lanes 1, 2, 4, and 5). Finally, an antiserum prepared against the gel-purified 62/64-kDa species crossreacts with the 40-kDa peptide. Immunoselection with the 40-kDa peptide yields a preparation that reacts strongly with the 62/64-kDa species (Fig. 3B).
The 62- and 64-kDa proteins present in our final preparation of the nuclease are heterogeneous with respect to their isoelectric points (Fig. 4). There appear to be three forms of each protein, with isoelectric points of 9.6, 9.7, and 9.8. It is likely that the differences in pI come from posttranslational modification, such as phosphorylation. Posttranslational modification might be related to selectivity of the nuclease for 80 S ribosome complexes (but not 40 or 60 S ribosomal subunits(35) ) or the increase in enzyme activity found on polysomes following estrogen administration(34) . The destabilization of albumin mRNA can be blocked by agents such as 4-hydroxytamoxifen (which also blocks the transcriptional induction of vitellogenin(46) ), yet this process is independent of new protein synthesis(47) . The recent demonstration that adenylate cyclase can be activated by estrogen, and this activation can be blocked by antiestrogens(48) , provides a rational basis for a model in which the destabilization of the major serum protein-coding mRNAs in Xenopus liver might result from posttranslational activation of the polysomal nuclease. Experiments to address this are in progress. Since the catalytically active 40-kDa fragment is less basic (pI = 8.7) and appears to lack the heterogeneity in isoelectric point seen for the 62- and 64-kDa species, we speculate that the nuclease has at least two domains. The first is a highly basic domain which is subject to posttranslational modification and is involved in targeting the enzyme to polysomes, mRNPs, or mRNA itself. The second is a more neutral catalytic domain. Resolution of this must await the cloning of the nuclease.
As noted above, the purified polysomal nuclease is a sequence-selective enzyme, showing preference for albumin versus ferritin mRNA or a full-length albumin antisense RNA (Fig. 5). The same experiment done with RNase A yields identical decay curves for all RNAs examined (data not shown). In several experiments a curved line suggestive of a second order reaction provided the best fit for in vitro degradation of albumin mRNA. This result was puzzling as we expected a first order decay process for a reaction containing only the purified enzyme and its RNA substrate. At present we believe this results from loss of enzyme activity over time. Future studies will examine the kinetics of the degradation reaction in detail to determine the nature of this phenomenon.
Many of the properties of the purified nuclease,
including the ineffectiveness of EDTA or N-ethylmaleimide to
inhibit activity, the resistance to placental ribonuclease inhibitor,
temperature stability, inhibition by 400 mM NaCl, and
resistance of double-stranded RNA to degradation, are similar to those
reported earlier for the crude enzyme extracted from liver polysomes of
estrogen-treated male frogs(34) . However, a number of
differences were observed with the purified nuclease. The nuclease does
not require divalent cations for activity, but their presence results
in increased activity (Fig. 6). Mg,
Ca
, or Zn
all have similar effects.
Little stimulation of activity was observed at concentrations below 5
mM, and maximal stimulation was observed at 10 mM.
Although NaCl is not required for activity, 100 mM NaCl
stimulated activity much like 10 mM MgCl
. The
exact degree of stimulation was not determined by rigorous analysis of
enzyme kinetics, so at this point it is unclear whether this is an
effect on the K
of the enzyme or results from
stabilization of the secondary structure of albumin mRNA, producing a
more suitable substrate for digestion.
An important step toward
understanding the mechanism of substrate selectivity is to identify the
precise cleavage site(s) for the nuclease on albumin mRNA. The primer
extension experiment in Fig. 9localized the sites responsible
for generating the 194-nt doublet cleavage products to the sequence
AUUGACUGA at positions 187-195 in the transcript, with the
predominant product coming from cleavage after position 193. This
sequence can be thought of as a direct overlapping repeat of the
sequence APyrUGA. Of those unstable mRNAs we have sequenced to date,
the sequence APyrUGA is present 14 times in albumin mRNA, 9 times in
transferrin mRNA, and 7 times in -fibrinogen mRNA. It is absent
from ferritin mRNA. Of the 14 copies of this sequence present in
albumin mRNA, 4 are in the 5` fragment used to assay the enzyme.
Secondary cleavages at these sites may contribute to the disappearance
of the 194-nt doublet product and to some of the other bands observe in Fig. 8and Fig. 9. It is also possible that a change in
the structure of the RNA after cleavage renders secondary sites
available for additional cleavage. The data in Fig. 7B indicate that the substrate transcript is not cleaved when present
in double-stranded RNA. Analysis of the secondary structure of the 5`
500 nt of albumin mRNA indicates that the bases in position
187-195 are located in a single-stranded loop adjacent to a
duplex stem.
Furthermore, this loop appears to be the major
site of cleavage in the 5` portion of albumin mRNA in vivo following estrogen administration (op. cit.).
In conclusion, we present here the isolation and characterization of an estrogen-regulated ribonuclease that catalyzes the selective degradation of albumin mRNA. The properties of this enzyme indicate that a major facet of the process of mRNA turnover may be endonuclease recognition of a specific sequence element in a favorable conformation. Other factors, such as sequence-specific RNA-binding proteins, subcellular localization, and the presence of translating ribosomes may influence the in vivo selectivity of the polysomal nuclease for mRNAs encoding secreted proteins.