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J Biol Chem, Vol. 274, Issue 31, 21981-21985, July 30, 1999
From the The product of the human oncogene ELL
encodes an RNA polymerase II transcription factor that undergoes
frequent translocation in acute myeloid leukemia (AML). In addition to
its elongation activity, ELL contains a novel type of RNA polymerase II
interaction domain that is capable of repressing polymerase activity in
promoter-specific transcription. Remarkably, the ELL translocation that
is found in patients with AML results in the deletion of exactly this
functional domain. Here we report that the EAP30 subunit of the ELL
complex has sequence homology to the Saccharomyces
cerevisiae SNF8, whose genetic analysis suggests its involvement
in the derepression of gene expression. Remarkably, EAP30 can interact
with ELL and derepress ELL's inhibitory activity in vitro.
This finding may reveal a key role for EAP30 in the pathogenesis of
human leukemia.
The identification of genes at breakpoints of frequently occurring
chromosomal translocations has been the basis for the discovery of
novel cellular factors involved in oncogenesis. Many such proteins are
transcription factors that regulate gene expression (1-3). The human
ELL gene had been identified initially as a gene on chromosome 19p13.1 undergoing frequent translocations with the trithorax-like MLL gene on chromosome 11q23 in acute myeloid
leukemia (AML)1 (4, 5). ELL
is an 80-kDa RNA polymerase II (Pol II) transcription factor that can
increase the catalytic rate of transcription elongation by Pol II from
both promoter-dependent and promoter-independent templates
(6-9). In addition to its elongation activity, ELL contains a novel
type of Pol II interaction domain that can repress polymerase activity
in promoter-specific transcription in vitro (6, 10). The
addition of ELL to transcription reactions before the assembly of the
preinitiation complex leads to a significant reduction in the yield of
full-length run-off transcripts. This repression has shown to be due to
the physical interaction of ELL with Pol II and the consequent
disruption of preinitiation complex formation (10). Remarkably, the
MLL-ELL translocation found in patients with AML results in the
deletion of a portion of the functional domain required for inhibition
of promoter-specific initiation by ELL (4, 5, 10). ELL mutants lacking
the sequence deleted by the translocation are fully active in
elongation; however, such mutants failed to inhibit initiation by Pol
II (10).
The partner of ELL in the chimeric protein produced by the MLL-ELL
translocation in patients with AML, is the product of the MLL gene (1, 11-13). This gene encodes a large, multidomain 3,968-amino acid protein containing an N-terminal A-T hook DNA-binding domain, a methyltransferase-like domain, and a C-terminal
trithorax-like region (11-13). The MLL gene is a recurring
target for translocation in a variety of clinically distinct leukemias
(12). The breakpoints of every MLL translocation create a putative
oncogene that encodes nearly the entire translocation partner fused to
the N terminus of the MLL protein. Although all these translocations
occur within the same region of MLL, each translocation is associated
with a clinically distinct form of leukemia, suggesting that MLL
translocation partners, such as ELL, play a major role in determining
the leukemic phenotype. In light of this data, recently it was
demonstrated that the replacement of the normal MLL gene
with an MLL-AF9 chimera led to the development of leukemia
in mice, suggesting that translocation causes the development of AML
(14).
Recently, we purified ELL in complex with three other cellular proteins
from total rat liver extract (15). Biochemical characterization of this
ELL-containing complex demonstrated that the ELL complex is capable of
increasing that catalytic rate of transcription elongation; however,
unlike ELL alone, the complex was unable to repress initiation of
transcription by RNA polymerase II. This lead to a model that suggested
that one or more of the ELL-associated proteins interact or at least
renders nonfunctional the N-terminal domain of the ELL protein, which
is shown to be important for ELL's transcriptional inhibitory activity
(10). In this view, the interaction of ELL with one of the EAPs
normally regulates the transcriptional inhibitory activity of ELL, and
deletion of this functional domain of ELL (i.e. MLL-ELL
translocation) bypasses this regulation. Here, we report the cloning,
expression, and biochemical characterization of the EAP30 subunit of
the ELL complex, which has sequence homology to the S. cerevisiae SNF8, a protein whose genetic analysis suggests its
involvement in the derepression of gene expression (18). Recombinant
EAP30 can interact with ELL, and this interaction leads to the
derepression of ELL's transcriptional inhibitory activity in
vitro.
Materials--
Ultrapure ribonucleoside 5'-triphosphates were
purchased form Amersham Pharmacia Biotech. [ Purification of the ELL-Complex--
Rat liver extract was
prepared by homogenization of 180 rat livers as described previously
(16), with the exception that nuclear and cytosolic extracts were
combined together after the removal of the lysosomal fraction. The
purification of the ELL complex was performed at 4 °C, and the
fractions were not frozen following the procedure as described
previously (15).
Cloning and Expression and Analysis of EAP30--
Total rat
liver extract was prepared as described previously (15), and the ELL
complex was purified following the previous procedure (15).
Approximately 25 pmol of the purified EAP30 was reduced,
S-carboxyamidomethylated, digested with trypsin, and then
either analyzed by matrix-assisted
laser desorption Ionization mass spectrometry (MALDI-MS) or fractionated
with microbore HPLC. Peptides isolated by microbore HPLC were then
subjected to sequencing by automated Edman degradation. A DNA fragment,
including the EAP30 coding sequence, was obtained by searching the
expressed sequence tag data base, and a human Jurkat T-cell cDNA
(AA306637) encoding the full-length EAP30 ORF was sequenced from the
expressed sequence tag clone. The EAP30 ORF was obtained by polymerase
chain reaction amplification using a 5' primer
(5'-gaggtgtcgacatgcaccgccgcggggtgggagct-3') and a 3' antisense primer
(5'-gtgtggatcctcatctcaggggagggcttctctggcctcc-3') for subcloning into a
M13 expression vector.
The construct for the expression of histidine-tagged EAP30 in bacteria
was prepared as described below. First, the DNA fragment encoding the
full-length EAP30 was obtained by polymerase chain reaction
amplification and was introduced into the SalI and
BamHI sites of M13mpET, which contains the complete pET T7
transcription-translation regions as well as the sequence encoding His
tag (17). Then the expression vector containing the entire EAP30
protein was expressed in Escherichia coli JM109 (DE3). About
500 ml of JM109 (DE3) culture was grown to an absorbance (at 600 nm) of
0.3 with gentle shaking in Luria broth medium containing 2.5 mM MgCl2 and MgSO4 at 37 °C.
Cells were infected with M13mpET carrying the EAP30 ORF at a
multiplicity of 30. After 4 h at 37 °C, infected cells were
induced with 100 mM
isopropyl-
Interaction between ELL and EAP30 was studied using an Amersham
Pharmacia Biotech Superose-12 PC column. The ELL alone eluted as a
100-kDa protein in buffer A (40 mM Tris-HCl (pH 7.9), 10% glycerol, and 400 mM KCl) at 50 µl/min, and the EAP30
alone eluted very broad (ranging from 30 to 80 kDa) protein under the
same conditions. These two polypeptides can be easily distinguished from each other on Superose-12. Renatured ELL alone, EAP30 alone, and
ELL/EAP30 were applied to a Amersham Pharmacia Biotech Superose-12 PC
column in buffer A at 50 µl/min, and fractions of 100 µl were collected. Each fraction was tested for the presence of EAP30 using
polyclonal antibodies generated to recombinant EAP30.
The interaction of ELL and EAP30 was also tested by nickel trapping of
His-ELL and EAP30 as described for His-ELL and RNA polymerase II (10).
About 10 µg of recombinant His-ELL was renatured with 10 µg of
recombinant EAP30 (in a 500-µl reaction mixture) in renaturation
buffer (40 mM Hepes-NaOH (pH 7.9), 0.4 M KCl, 50 µM ZnSO4, 1 mM DTT and 10%
(v/v) glycerol) for 3 h. Each reaction mixture was incubated with
ProBond resin for 1 h. After an hour, ProBond resin was washed and
eluted with 300 mM imidazole (pH 7.9) in renaturation
buffer. Fractions were tested for the presence of EAP30 on SDS-PAGE and
Western analysis using polyclonal antibodies raised against EAP30.
Cloning and Expression of EAP30--
Although the ELL protein is
the only MLL partner in leukemia whose biochemical function is known,
its precise role in leukemia remains a mystery. Since the
identification of ELL as a Pol II transcription factor (8, 9), several
lines of evidence have suggested that ELL exists in a complex with
other cellular factors. Recently, ELL was purified, together with three
other proteins from total rat liver extract, in our laboratory (15).
This complex can increase the catalytic rate of transcription
elongation by Pol II; however, unlike the ELL polypeptide, the ELL
complex is not capable of repressing polymerase activity in
promoter-specific transcription (15). The identification of EAPs that
derepress ELL's transcriptional inhibitory activity suggests that one
or more of the EAPs interacts with, or at least renders nonfunctional, the N-terminal domain of the ELL protein, a domain proven to be necessary for ELL's transcriptional inhibitory activity (8-10). This
hypothesis suggests a mechanism whereby the translocation could
eliminate regulation of promoter-specific initiation of transcription,
resulting in the loss of growth regulation. To investigate the role of
the EAPs, we have purified the ELL complex in large quantities and have
analyzed the N-terminal of several tryptic peptides of the EAPs using
sequential Edman degradation and/or MALDI analysis (19). These analyses
demonstrated that the EAP30 subunit of the ELL complex has sequence
similarity to the Saccharomyces cerevisiae SNF8 protein
(Fig. 1A).
The snf8 gene was identified initially by complementation
from S. cerevisiae as a 27-dalton protein whose mutations
impaired derepression of the SUC2 gene (18). Genetic
analysis of snf8 null mutations with spt6/ssn20
and ssn6 suppressor distinguished SNF8 from SNF1, SNF2, SNF4, SNF5, and
SNF6 (18). Remarkably, snf8,ssn6 double mutants
were extremely sick, and it has been postulated that SNF8 functions via
regulation of gene expression. Genetic analysis has also indicated that
snf8 in S. cerevisiae contributes to derepression
of SUC2 and may, along with other unknown proteins, provide a function
that is essential for derepression (18). No information is available
about the mammalian SNF8 protein.
To investigate the possibility that EAP30 can interact with ELL and
thus regulate the transcriptional repressory activity of ELL, we cloned
and expressed the full-length human EAP30 (Fig. 1B).
Recombinant EAP30 protein was purified to homogeneity from guanidine
solubilized inclusion bodies and was demonstrated to have a relative
molecular mass of about 30 kDa on SDS-PAGE (Fig. 1C). This
recombinant protein is recognized by polyclonal antibodies raised
against one of the peptides obtained from sequential Edman degradation
of EPA30 (Fig. 1C) (15). In addition, polyclonal antibodies
raised against the recombinant EAP30 protein recognized purified EAP30
(Fig. 1D). Taken together, these data suggest that cloned
recombinant EPA30 is the same as EAP30 purified from total rat liver extract.
EAP30 Can Interact with ELL in Vitro--
The interaction of
recombinant EAP30 with recombinant ELL was tested by two methods.
First, we renatured recombinant ELL or recombinant EAP30 alone or with
each other. To identify interaction between ELL and EAP30, we took
advantage of size exclusion chromatography on an Amersham Pharmacia
Biotech Superose-12 PC column. ELL and EAP30 alone can be easily
distinguished from each other on Superose-12 PC size exclusion
chromatography. If EAP30 interacts with ELL, it should elute as a
larger protein when renatured with ELL. Upon renaturation, size
exclusion chromatography, and Western analysis of ELL, EAP30, or ELL
with EAP30 on Superose-12, it was observed that when EAP30 was
renatured with ELL, it eluted as a larger protein with sharper elution
profile than when renatured alone (Fig.
2A). We note that recombinant
renatured EAP30 alone shows molecular mass ranging from 30 to about 100 kDa on size exclusion. We believe that recombinant EAP30 alone is not
renatured properly, and therefore, it behaves with a broad elution
profile from size exclusion column. However, when EAP30 is renatured
with ELL, it behaves with a much sharper elution profile, due to its
proper folding. We also noticed that the total yield of ELL recovered when ELL was renatured with EAP30 was much higher than when ELL was
renatured alone (data not shown).
Our second strategy to investigate the possibility that EAP30 protein
can interact with ELL took advantage of the ability of histidine-tagged
ELL to retain untagged EAP30 on nickel agarose as described under
"Experimental Procedures." When EAP30 was renatured alone and then
applied to nickel chromatography, virtually no EAP30 was detected in
the nickel bound fraction as tested with polyclonal antibodies raised
against EAP30 (Fig. 2B, lane 5). However, when
EAP30 was renatured with His-ELL, almost all EAP30s were found in the
nickel-bound fraction (Fig. 2B, lane 6). These experiments indicated that EAP30 is capable of direct physical interaction with ELL in about a 1:1 ratio.
EAP30 Confers Derepression of ELL's Transcriptional Inhibitory
Activity--
We next sought to determine whether the interaction of
EAP30 with ELL can regulate ELL's transcriptional inhibitory activity (15). As demonstrated previously, Pol II and the general initiation factors will synthesize the trinucleotide CpApC at the AdML promoter when provided with CpA and [
We also tested if such derepression of the inhibitory activity of ELL
by EAP30 is dependent on the concentration of EAP30. ELL and ELL with
increasing concentrations of EAP30 were added to transcription
reactions before the formation of preinitiation complexes to test the
derepression of the inhibitory activity of ELL by EAP30. In this
experiment, when 50 ng of ELL was added to transcription reaction
before the formation of preinitiation complex, it dramatically
decreased the yield of CpApC synthesis (Fig. 3, lane 1).
However, when 10 ng of EAP30 was renatured with ELL, it partially
derepressed ELL's inhibitory activity (Fig. 3, lane 3). We
observed a maximum derepression at about 50 ng of EAP30 with 50 ng of
ELL. We noted that the derepression of ELL's inhibitory activity by
EAP30 is not 100%. This may be due in part to the absence of EAP20 and
EAP45, which could possibly be required to increase the stability of
ELL-EAP30 complex. These findings indicated that the EAP30 protein,
whose S. cerevisiae relative, SNF8, was identified by
genetic analysis to be involved in derepression of gene expression, is
a component of the ELL complex. Human EAP30 can interact with ELL, and
such interaction confers derepression of ELL's transcriptional
inhibitory activity in vivo.
Genetic and molecular analysis of a large number of chromosomal
abnormalities in human cancer has revealed that the MLL gene is a recurring target for translocation in a variety of phenotypically distinct leukemias (13). To date, genes encoding eight MLL
translocation partners have been isolated by genetic analysis. No
information regarding the biochemical activities of any of the MLL
partners (besides ELL) is available. We identified the product of the
ELL gene, a partner of MLL in AML, as Pol II transcription
factor. The ELL protein can regulate both the transcriptional
initiation and elongation activities of Pol II. ELL contains a novel
type of Pol II interaction domain that can repress polymerase activity in promoter-specific transcription in vitro (10). This
repression of transcription by ELL has been demonstrated to be due to
its physical interaction with Pol II and the disruption of the
formation of preinitiation complex (10).
The ELL domain required for this transcriptional inhibitory activity is
lost in the MLL-ELL translocation found in patients with AML. Since its
identification as a Pol II transcription factor, ELL has been
demonstrated to interact with three unknown cellular factors in total
liver extract to form the ELL complex. Unlike ELL alone, the ELL
complex is unable to repress initiation of transcription by Pol II
(15). It has been proposed that one or more of the ELL-associated
proteins can interact with ELL and render nonfunctional the N-terminal
domain of the ELL protein required for ELL's transcriptional
inhibitory activity (15). This hypothesis raises several questions: (i)
what are the components of the ELL complex, (ii) which EAPs can
interact with ELL and regulate its transcriptional repressory activity,
and (iii) do the EAPs that interact with ELL regulate transcription
in vivo? Here, we have identified the human EAP30
gene product to be a component of the ELL complex. The EAP30 protein
can interact with ELL and derepress ELL's transcriptional inhibitory
activity. This observation is consistent with the genetic analysis of
the S. cerevisiae SNF8 where it was proposed to be involved
in derepression of gene expression (18). In principle, EAP30 could
regulate the expression of specific genes by controlling the rate of
transcriptional initiation by Pol II. In conclusion, the identification
of EAP30 as a component of the ELL complex and the analysis of its
interaction with ELL in the regulation of ELL's transcriptional
inhibitory activity may provide a model in which the EAP30 protein may
play a key role in the regulation of cell growth and the pathogenesis of leukemia.
We are grateful to Drs. Joan and Ronald
Conaway for their conversations. The senior author thanks Dr. William
S. Sly for encouragement and support and also Joyce Williams for
critical reading of the manuscript.
*
The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AF156102.
¶
An Edward Mallinckrodt, Jr., Young Investigator. To whom
correspondence should be addressed. Tel.: 314-577-8137; 314-577-8131; Fax: 314-577-8156; E-mail: shilatia@slu.edu.
The abbreviations used are:
AML, acute myeloid
leukemia;
Pol II, polymerase II;
EAP, ELL-associated protein;
MALDI-MS, matrix-assisted laser desorption Ionization mass spectrometry;
HPLC, high performance liquid chromatography;
ORF, open reading frame.
Cloning and Characterization of the EAP30 Subunit of the ELL
Complex That Confers Derepression of Transcription by RNA Polymerase
II*
,,,¶
Edward A. Doisy Department of Biochemistry,
Saint Louis University School of Medicine, Saint Louis, Missouri
63104 and § The Wistar Institute,
Philadelphia, Pennsylvania 10104
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-32P]CTP
was obtained from ICN. Leupeptin, antipeptin, phenylmethylsulfonyl fluoride, and heparin were obtained from Sigma. Bovine serum albumin (Pentex fraction V) and Western development reagents were obtained from
ICN ImmunoBiologicals. Glycerol (spectro-analyzed grade), potassium
chloride, Hepes, Tris, ammonium sulfate, and ultrapure sucrose were
purchased from Fisher. The chromatographic columns Superose-12 HR and
Superose-6 were purchased from Amersham Pharmacia Biotech.
-D-thiogalactopyranoside for another 4 h.
Cells were harvested by centrifugation at 2,500 × g
for 30 min at 4 °C. Inclusion bodies were solubilized by
resuspension in 7 ml of ice-cold 6 M guanidine HCl with 50 mM Tris-HCl (pH 7.9) and recombinant EAP30 was purified by
nickel chromatography on ProBond resin. The mutation of EAP30 to remove
its His tag was performed by site-directed mutagenesis with the use of
the Bio-Rad Muta-gen kit. The EAP30 without His tag was expressed as
above, and the interaction of EAP30 with His-ELL was carried out using
nickel chromatography on ProBond resin. Polyclonal antibodies to either
peptide sequence FAQDVSQDDLI or the entire ORF of EAP30 were prepared
in either rabbit or mice, respectively, following published methods.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (36K):
[in a new window]
Fig. 1.
Identification, cloning, and expression of
human EAP30 protein, a component of the ELL complex. A,
sequence analysis of EAP30 from the ELL complex purification with Edman
degradation and/or MALDI analysis. B, cloning and sequence
comparison of EAP30 with S. cerevisiae SNF8 protein.
C, Western and silver stain analysis of recombinant human
EAP30. Human EAP30 protein was cloned and expressed as described under
"Experimental Procedures" and analyzed either with polyclonal
antibody raised against the peptide (FAQDVSQDDLIR) (left
panel) obtained from the purified EAP30 or with silver staining
(right panel). D, co-chromatography of human
EAP30 with the purified ELL complex. Superose-6 PC fractions from the
final purification step of the ELL complex purification (15) were
analyzed for the presence of human EAP30 with polyclonal antibody
raised against recombinant EAP30 in mouse (upper panel).
Co-chromatography of ELL with EAP30 using monoclonal antibodies raised
against ELL ( ELL) and polyclonal antibodies raised against EAP30
(EAP30) is demonstrated above. Also, column fractions were tested
for transcriptional elongation activity. Column fractions were added to
transcription reactions containing RNA polymerase II and
oligo(dC)-tailed template pCpGR220 S/P/X. Transcription was initiated
by the addition of three ribonucleoside triphosphates (50 µM ATP, 50 µM GTP and
[-32P]CTP) without UTP and incubated at 30 °C for
10 min. Transcripts were analyzed by electrophoresis through 7% (w/v)
acrylamide, 7 M urea. The synthesis of the 135-nucleotide
transcript is indicated by the arrow.
View larger version (31K):
[in a new window]
Fig. 2.
Physical interaction between ELL and EAP30.
A, either recombinant EAP30 alone (upper panel)
or EAP30 and ELL (lower panel) was subjected to size
exclusion chromatography on Superose-12 PC. Fractions were then
analyzed on SDS-PAGE and by Western analysis with polyclonal antibodies
raised against EAP30. B, either EAP30 alone (lanes
2 and 5) or EAP30 with His-tagged ELL (lanes
3 and 6) were applied to nickel chromatography. Bound
fractions (lanes 5 and 6) were eluted with
imidazole and analyzed on SDS-PAGE and by Western analysis with
polyclonal antibodies raised against EAP30.
-32P]CTP (15). The
addition of recombinant ELL to transcription reaction before, but not
after, the formation of preinitiation complex dramatically decreased
the yield of CpApC synthesis (10, 15). The addition of the purified ELL
complex to transcription reactions before assembly of the preinitiation
complex, however, did not decrease the yield of CpApC synthesis (15).
This indicated that the transcriptional inhibitory activity of the ELL
protein is suppressed in the purified complex. To test whether EAP30, which is capable of physical interaction with ELL, can suppress ELL's
transcriptional inhibitory activity, we tested the effect of EAP30 on
transcriptional inhibitory activity of ELL in the ELL-EAP30 complex.
Synthesis of CpApC was initiated by addition of CpA,
[-32P]CTP, and dATP. The reactions were incubated for
the times indicated. Transcripts were analyzed by electrophoresis
through 25% acrylamide, 3% bisacrylamide polyacrylamide gels
containing 7.0 M urea and 1 × TBE (0.045 M Tris borate, 0.001 M EDTA, pH 8.0). The
migration of the trinucleotide, CpApC, is indicated by the
arrow. When ELL was renatured alone and added to
transcription reactions before the formation of the preinitiation
complex, it markedly decreased the yield of CpApC synthesis (Fig.
3B, lanes 5-8). On
the other hand, when EAP30 was renatured with ELL and added to
transcription reaction before the formation of the preinitiation
complex, it suppressed ELL's inhibitory activity (Fig. 3B,
lanes 9-12).
View larger version (22K):
[in a new window]
Fig. 3.
Human EAP30 confers derepression of ELL's
transcriptional inhibitory activity. A, nontemplate
strand sequences surrounding the transcription start site of the AdML
promoter. RNA polymerase II synthesizes the trinucleotide CpApC at the
AdML promoter when provided with the dinucleotide primer CpA and
[ -32P]CTP. The nontemplate strand sequence
corresponding to the CpApC product is underlined. B, either
no ELL (lanes 1-4), ELL (lanes 5-8), or
ELL-EAP30 complex (lanes 9-12) were added to transcription
reactions before the formation of preinitiation complexes
(PIC). Synthesis of CpApC in the presence of no ELL, ELL,
and ELL-EAP30 complex were initiated by the addition of 500 µM CpA, 10 µCi of [-32P]CTP, and 5 µM dATP and reactions incubated for indicated time
postinitiation. Transcripts were analyzed by electrophoresis through
25% (w/v) acrylamide, 7 M urea gels. C, either
50 ng of ELL (lane 1), no ELL (lane 2), or 50 ng
of ELL renature with increasing concentration of EAP30 (lanes
3-7) was added to transcription reactions before the formation of
PICs. Synthesis of CpApC was measured as mentioned above.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
ACKNOWLEDGEMENT
FOOTNOTES
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Anal. Biochem.
211,
94-101[Medline]
[Order article via Infotrieve]
Copyright © 1999 by The American Society for Biochemistry and Molecular Biology, Inc.
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