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Journal of Bacteriology, March 2000, p. 1346-1351, Vol. 182, No. 5
Department of Biochemistry and Molecular
Biology and the Center for Biological Resource Recovery, The
University of Georgia, Athens, Georgia 30602
Received 3 September 1999/Accepted 9 December 1999
The cellulosome of Clostridium thermocellum is a
multiprotein complex with endo- and exocellulase, xylanase,
Plant cell wall material composed
mainly of cellulose, hemicelluloses, and lignin is one of the largest
sources of renewable energy on earth. Arabinoxylan is one of the main
hemicelluloses. Its backbone structure is a chain of The cellulosome first discovered in Clostridium thermocellum
(2, 29) is a multiprotein complex with a molecular mass of
about 3,000 kDa. Cellulosomes are produced by several anaerobic bacteria (4) and anaerobic fungi (17, 32). The
core of the cellulosome is an enzymatically inactive cellulosome
integrating polypeptide (CipA) functioning as a scaffold. CipA of
C. thermocellum contains nine copies of a cohesin domain, a
type II dockerin domain, and a cellulose binding domain (CBD). At
present, 18 catalytic active subunits of the cellulosome have been
sequenced. They have endoglucanase, cellobiohydrolase (exoglucanase),
xylanase, chitinase, or In the present study, we show that UDs of XynY and XynZ have homology
with a feruloyl esterase (FaeA) (D. L. Blum, X.-L. Li, H. Z. Chen, and L. G. Ljungdahl, Abstr. 99th Gen. Meet. Am. Soc. Microbiol. 1999, abstr. K-153, 1999) from the anaerobic fungus Orpinomyces PC-2 (GenBank accession no. AF164351) and that these domains exhibit feruloyl esterase activity. Consequently, XynY
and XynZ are bifunctional enzymes with feruloyl esterase and xylanase
activities. The presence of feruloyl esterase in the cellulosome of
C. thermocellum points toward an additional ability of this
organelle to hydrolyze plant tissue.
(A preliminary report of this work was given at the Mie Bioforum in
1998 [5]).
Bacterial strains, vectors, and culture media.
C.
thermocellum JW20 was cultivated in prereduced liquid medium
(33) at 60°C under an atmosphere of nitrogen. For
isolation of cellulosomes and to obtain subfractions of C. thermocellum, 0.2% Avicel (a microcrystalline cellulose [0.2%,
wt/vol], 2- to 20-µm particle size; Baker TLC) and 0.5% (wt/vol)
cellobiose were used, respectively, as carbon sources.
Escherichia coli strain BL21(DE3) (Stratagene, La Jolla,
Calif.) and plasmid pRSET B (Invitrogen, La Jolla, Calif.) were used as
the host strain and the vector for protein expression, respectively.
Initial work was done with pRSET B, with which we obtained satisfactory
results, but these were improved considerably using pET-21b (Novagen,
Madison, Wis.). The work described uses these plasmids. Recombinant
E. coli cells were selected for by growing in Luria-Bertani
medium containing 100 µg of ampicillin per ml.
Amplification and cloning of sequences coding for different
domains of XynY and XynZ.
Genomic DNA was isolated from C. thermocellum as previously described (24). To clone
fragments of DNA corresponding to the UDs of XynY and XynZ and
deletions of the UD of XynZ, PCR primers were designed (Table
1) and synthesized on an Applied
Biosystems DNA synthesizer (PE Biosystems, Foster City, Calif.). To
facilitate the insertion of DNA sequence into pET-21b or pRSET B,
BamHI and HindIII sites were added to forward
and reverse primers, respectively (Table 1). PCRs were carried out on a
Perkin-Elmer 480 Thermocycler (Norwalk, Conn.) for 30 cycles, with each
cycle at 95°C for 1 min, 48°C for 1 min, and 72°C for 3 min. PCR
products and the plasmid were digested with BamHI and
HindIII, purified with a Geneclean Spin Kit (BIO 101, Inc., Vista, Calif.), and ligated with T4 ligase. E. coli
BL21(DE3) was transformed with the ligation mixture, and at least four
colonies of each construct were picked for analyzing feruloyl esterase
expression. The inserted sequences were sequenced to verify the lack of
unwanted mutations.
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Feruloyl Esterase Activity of the Clostridium
thermocellum Cellulosome Can Be Attributed to Previously Unknown
Domains of XynY and XynZ
ABSTRACT
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
-glucanase, and acetyl xylan esterase activities. XynY and XynZ,
components of the cellulosome, are composed of several domains
including xylanase domains and domains of unknown function (UDs).
Database searches revealed that the C- and N-terminal UDs of XynY and
XynZ, respectively, have sequence homology with the sequence of a
feruloyl esterase of strain PC-2 of the anaerobic fungus
Orpinomyces. Purified cellulosomes from C. thermocellum were found to hydrolyze FAXX (O-{5-O-[(E)-feruloyl]-
-L-arabinofuranosyl}-(1
3)-O--D-xylopyranosyl-(14)-D-xylopyranose) and FAX3
(5-O-[(E)-feruloyl]-[O--D-xylopyranosyl-(12)]-O--L-arabinofuranosyl-[13]}-O--D-xylopyranosyl-(14)-D-xylopyranose), yielding ferulic acid as a product, indicating that they have feruloyl
esterase activity. Nucleotide sequences corresponding to the UDs of
XynY and XynZ were cloned into Escherichia coli, and the
expressed proteins hydrolyzed FAXX and FAX3. The
recombinant feruloyl esterase domain of XynZ alone
(FAEXynZ) and with the adjacent cellulose binding domain
(FAE-CBDXynZ) were characterized. FAE-CBDXynZ
had a molecular mass of 45 kDa that corresponded to the expected
product of the 1,203-bp gene. Km and
Vmax values for FAX3 were 5 mM and
12.5 U/mg, respectively, at pH 6.0 and 60°C. PAX3, a
substrate similar to FAX3 but with a
p-coumaroyl group instead of a feruloyl moiety was
hydrolyzed at a rate 10 times slower. The recombinant enzyme was active
between pH 3 to 10 with an optimum between pH 4 to 7 and at
temperatures up to 70°C. Treatment of Coastal Bermuda grass with the
enzyme released mainly ferulic acid and a lower amount of
p-coumaric acid. FAEXynZ had similar
properties. Removal of the 40 C-terminal amino acids, residues 247 to
286, of FAEXynZ resulted in protein without activity. Feruloyl esterases are believed to aid in a release of lignin from
hemicellulose and may be involved in lignin solubilization. The
presence of feruloyl esterase in the C. thermocellum
cellulosome together with its other hydrolytic activities demonstrates
a powerful enzymatic potential of this organelle in plant cell wall decomposition.
INTRODUCTION
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
(14)-linked
xylose moieties to which are attached side chains, including arabinose,
acetate, and methyl-glucuronic acid (7, 40). The arabinose
has ester-linked ferulic acid and p-coumaric acid. Ferulic
acid links hemicellulose to lignin (39). Since feruloyl
esterases hydrolyze the bond between the arabinose and ferulic acid,
they may release the covalently bound lignin from hemicelluloses and
aid in the degradation of plant cell walls. Feruloyl esterases have
been found in bacteria and fungi (44).
-glucanase (lichenase) activity
(2). All enzymatically active subunits have multidomain
structures that include at least a catalytic domain and a dockerin
domain which binds to the cohesins of CipA. Other domains present in
some of the catalytic subunits include CBDs, immunoglobulin-like
domains, serine- and threonine- or proline-rich linkers, and domains of
unknown functions (UDs). Examples of subunits having UDs are XynY
(20) and XynZ (22) (see Fig. 2). Starting with
the N terminus, XynY has xylanase (glycosyl hydrolase family 10), a
domain characterized as a thermostability domain, a dockerin, and a UD.
Also starting with the N terminus, XynZ has a UD, a proline-rich
linker, a CBD (family VI), a dockerin, and xylanase (glycosyl hydrolase
family 10).
MATERIALS AND METHODS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
TABLE 1.
Primer designs amplifying various regions of
xynY and xynZ of C. thermocellum
Isolation and analysis of cellulosomes and subfractions of C. thermocellum. Cellulosomes produced by C. thermocellum were isolated from 10 liters of culture fluid after complete Avicel exhaustion by the affinity digestion method (38). They were further purified by gel filtration with a fast protein liquid chromatography system with a Superose 6 column (Pharmacia, Piscataway, N.J.). The buffer used was 50 mM Tris-HCl and 100 mM NaCl at a flow rate of 0.2 ml/min. Fractions of 0.5 ml each were collected and stored at 4°C for further analysis. To prepare subfractions, C. thermocellum was grown on 0.5% cellobiose in 200 ml of culture. Cells were recovered by centrifugation, resuspended in 50 mM Tris-HCl buffer (pH 7.5), and sonicated. The cultural medium was concentrated to 5 ml with a PM10 Diaflo ultrafiltration membrane (Amicon, Inc., Beverly, Mass.). To remove cellulosomes from the medium, 0.5 mg of Avicel was added and the suspension was stirred at 4°C for 4 h. Avicel with bound cellulosomes was recovered by centrifugation, and the cellulosomes were released from the Avicel by elution with distilled water (33). All fractions were tested for avicelase, xylanase, and feruloyl esterase activity.
Enzyme assays.
Unless otherwise noted, enzyme assays were
performed at 60°C in 50 mM Na-citrate buffer, pH 6.0. One unit of
enzyme activity was defined as the amount of enzyme that releases 1 µmol of product min
1, and specific activity was given
in units per milligram of protein. Protein was determined by the method
of Bradford (9). Feruloyl esterase activity was measured
using a modified version of the assay described by Borneman et al.
(7). The appropriately diluted protein sample (25 µl) was
added to 400 µl of buffer containing 8 mM substrate. Samples were
incubated at 60°C for 5 min, and the reaction was stopped by adding
25 µl of 20% formic acid. Release of ferulic acid was measured via
high-performance liquid chromatography (HPLC) using a mobile phase of
10 mM Na formate (pH 3) and 30% (vol/vol) methanol. For routine
assays, FAXX and FAX3 purified from wheat bran were used as
substrates (7). Ethyl ferulate and
ethyl-p-coumarate esters were gifts from D. E. Akin
(U.S. Department of Agriculture, Athens, Ga.). The hydrolysis of these (10 mM) were determined similarly to that of FAXX, but the HPLC analyses were performed with 50% methanol. HPLC runs were done with a
Hewlett-Packard 1100 Series instrument (Wilmington, Del.) equipped with
an autosampler and diode array detector with a Hypersil octyldecyl
silane (125 by 4 mm) column. Ferulic acid and p-coumaric acid were used as standards. To determine the amount of feruloyl and
p-coumaroyl groups released from plant cell walls, wheat
bran and Coastal Bermuda grass were ground in a Thomas Wiley mill (VWR Scientific Products, Atlanta, Ga.) to pass through a 250-µm screen. Plant samples of 10 mg each were incubated for 1 h in 400 µl of 50 mM Na-citrate buffer (pH 6.0) plus 25 µl of enzyme. After the addition of 25 µl of 20% formic acid to stop the reaction, the samples were centrifuged at 16,000 × g in a
microcentrifuge and then assayed for ferulic and p-coumaric
acid by HPLC.
Enzyme purification.
Cultures of 1 liter of the recombinant
E. coli containing pET-21b plus insert were grown in Luria
broth containing 100 µg of ampicillin per ml until an optical density
at 600 nm of 0.5 was reached and then grown an additional 4 to 6 h
after induction with 1 mM
isopropyl--D-thiogalactopyranoside, depending on the construct. Cells were harvested by centrifugation at 10,000 × g. They were resuspended at a concentration of 1 g per 3 ml of 50 mM Tris-HCl (pH 7.5) and lysed with a French press cell. Cell debris was removed by centrifugation at 100,000 × g.
The cell extract was heat treated at 70°C for 30 min. Denatured
protein was removed by centrifugation at 100,000 × g.
The supernatant was concentrated to a volume of 2 ml with a Centricon
10 concentrator (Amicon, Inc., Beverly, Mass.) and then applied to a
TSK 3000SW column (TosoHaas, Montgomeryville, Pa.), which was run with
50 mM Tris-HCl (pH 7.5) and 5% glycerol as solvent. The purified enzyme was stored at 4°C in the elution buffer and was stable for at
least 1 month with minimal loss.
Enzyme stability experiments. Purified enzyme at a concentration of 13 µg/ml in 50 mM Na-citrate (pH 6.0) was placed in a water bath at the appropriate temperature and incubated at intervals of 1 h. Enzyme aliquots (25 µl) were removed, and assays were performed in triplicate with FAX3 as a substrate as described above. FAE-CBDXynZ was tested at temperatures of 50, 60, and 70°C, while FAEXynZ was tested at 70, 80, and 90°C.
Other analytical procedures. Enzyme purity was monitored with sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels which were run by the method of Laemmli (28). Proteins were stained with Coomassie blue. The isoelectric point of the protein was determined by running the enzyme on a precast Serva IEF gel (Novex, San Diego, Calif.). The gel was run at 12 W of constant power for 45 min.
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RESULTS |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Demonstration of feruloyl esterase activity in the
cellulosome.
The initial indication of the presence of feruloyl
esterase in the cellulosome of C. thermocellum was obtained
from data bank search and sequence analysis using the Genetics Computer
Group package (University of Wisconsin Biotechnology Center, Madison) and the VAX/VMS system of the Bioscience Computing Resource of The
University of Georgia, Athens). This search showed that the catalytic
domain of Orpinomyces strain PC-2 FaeA was over 30% identical to sequences coding for the UD of XynY and the UD of XynZ.
(Fig. 1).
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Expression of the UDs of XynY and XynZ in E. coli.
Nucleotides corresponding to regions of DNA encoding amino acids in
XynZ (accession no. M22624) from residues 20 to 421 and in XynY
(accession no. X83269) from residues 795 to 1,077 were overexpressed in
E. coli using the pET and pRSET systems, respectively. The
XynZ sequence referred to as FAE-CBDXynZ incorporates the
family VI CBD (Fig. 2), while the XynY
protein designated FAEXynY contains only the catalytic
domain (Fig. 2). The cell extracts containing the expressed proteins
each hydrolyzed FAXX with release of ferulic acid, suggesting that
these proteins are feruloyl esterases. E. coli cells lacking
the plasmids or containing plasmids without C. thermocellum
DNA inserts did not hydrolyze FAXX. The expressed FAEXynY
and FAE-CBDXynZ had molecular masses of 31 and 45 kDa,
respectively, consistent with the sequence data. Since these proteins
had similar sequences and function and the XynZ protein had higher
expression levels than the XynY protein (data not shown), we focused on
the XynZ protein in subsequent experiments.
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Deletion analysis of FAE-CBDXynZ. Constructs were made which corresponded to proteins with amino acids from the original XynZ sequence of residues 20 to 307 (FAE287XynZ), 20 to 286 (FAEXynZ) and 20 to 247 (FAE227XynZ) (Fig. 2). FAE287XynZ is missing the CBD but contains the proline-rich linker which separates the CBD from the feruloyl esterase domain, while FAEXynZ does not contain this linker. When these constructs were expressed in E. coli in the same manner as FAE-CBDXynZ, they both exhibited feruloyl esterase activity, whereas FAE227XynZ was expressed but inactive. The data suggest that neither the CBD nor the linker is necessary for activity, but that C-terminal amino acids in the sequence from residues 247 to 286 of the FAE domain are necessary for activity.
Purification and characterization of the FAE-CBDXynZ
and FAEXynZ.
The FAE-CBDXynZ polypeptide
was purified from E. coli cell extract by a single step of
heat treatment at 70°C for 30 min. Over 200 mg of homogeneous
FAE-CBDXnyZ (Fig. 3) was
obtained from 2.5 g of crude proteins (Table
3). There was no evidence for aggregation
of the esterase produced in E. coli or the presence of
inclusion bodies.
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1 mg1 and a
Km of 5 mM with FAX3 as substrate.
The enzyme had the highest activity towards FAXX but was almost as
active toward FAX3 (Table 4).
The protein was able to release low levels of ferulic acid from ethyl
ferulic acid, ground wheat bran, and Coastal Bermuda grass, and
p-coumaric acid from PAX3 and
ethyl-p-coumarate. The protein lacked activity toward
carboxymethyl cellulose, Avicel, p-nitrophenyl
(pNP)-arabinopyranoside, pNP-glucopyranoside, pNP-xylopyranoside, and
pNP-acetate. Isoelectric focusing indicated a pI of 5.8.
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1 and a
Km of 10.5 mM with FAX3 as
substrate. FAEXynZ was inhibited by ferulic acid but not by
xylose or arabinose. The FAEXynZ was most active between 50 and 60°C and had a high level of activity between pH 4 and 7. It and
FAE-CBDXynZ were stable at 70°C for 6 h. At 80°C,
FAEXynZ lost about 50% of the activity within 3 h and
all activity after 1 h at 90°C. FAE-CBDXynZ bound
weakly to acid-swollen cellulose, while the other constructs missing the CBD did not bind to acid-swollen cellulose.
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DISCUSSION |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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The cellulosome of C. thermocellum is a remarkable extracellular organelle of about 3,000 kDa that also exists as a polycellulosome of a mass approaching 100,000 kDa (12). The first assessment of the number of different subunits in the cellulosome indicated the presence of 14 subunits (30). Later, Kohring et al. (26) studying C. thermocellum strain JW20 observed 26 subunits. At least 19 cellulosomal polypeptides have been cloned and sequenced (2). They include CipA and 18 catalytic subunits with various glycosyl hydrolase activities. It is now clear that the cellulosome is capable of hydrolyzing not only cellulose and the backbone of hemicelluloses but also substituents of xylan. Recently Hayashi et al. (23) sequenced two homologous xylanases, XynA and XynB, from C. thermocellum and demonstrated that they contain a NodB domain in addition to a family II xylanase domain. A NodB domain of a multidomain xylanase from Cellulomonas fimi deacetylates acetyl xylan (31). A Ruminococcus flavefaciens xylanase has acetyl xylan esterase activity (25). These xylanases clearly are bifunctional enzymes. Conceivably, the xylanases and the acetyl xylan esterases work together in the hydrolysis of the xylan. A synergistic effect between a separate xylanase and an acetyl xylan esterase has been demonstrated (6).
The situation may be similar regarding XynY and XynZ. As shown in this paper, both contain feruloyl esterase and xylanase domains. The xylanase domain of XynZ has been well studied and crystallized, and its three-dimensional structure has been solved (16, 42). The feruloyl esterase and xylanase may well work together in the two bifunctional enzymes. The feruloyl esterase domain and the xylanase domain may form a dumbbell-like structure, and arabino xylan may be hydrolyzed in a multicutting event involving the xylose chain as well as the ester linkage between the arabinosyl and feruloyl moieties. As with xylanase and acetyl xylan esterase, a synergistic effect has been shown between a separate xylanase and a feruloyl esterase (8). It has been proposed also that feruloyl esterases are responsible for the hydrolysis of bonds between lignin and hemicelluloses (40, 42). The anaerobic fungus Neocallimastix patriciarum solubilizes lignin (36) and a xylanolytic Butyrivibrio sp. has phenolic esterase activity (35).
Multifunctional enzymes
one gene with more than one catalytic
domainwere discussed several years ago (43). Such enzymes with activities acting on the same substrate but different bonds may
have the advantage that the substrate does not have to be released from
the enzyme when undergoing two or more enzymatic reactions. Several
bifunctional enzymes in addition to xylanase-acetyl xylan esterase and
xylanase-feruloyl esterase are known. Also, trifunctional enzymes exist
with separate catalytic domains in a single polypeptide. Examples
include peroxidase-lipoxygenase from the sea whip coral Plexaura
homomalla (27), xylanase--(1,3-1,4)-glucanase from
R. flavefaciens (19), xylanase with two catalytic
domains from N. patriciarum (21),
methenyltetrahydrofolate cyclohydrolase-methylenetetrahydrofolate dehydrogenase from several clostridia (34), and the
trifunctional C1-tetrahydrofolate synthase from yeast and
liver (41).
The domains of xylanase and feruloyl esterase of XynZ and XynY are well separated in the polypeptides (Fig. 2). Separate expression of the domains in E. coli yielded active enzymes. As shown with the feruloyl esterase domain of XynZ, it is also active when the CBD and the linker regions are removed. Catalytic domains that are active without adjacent domains, such as CBD or dockerins, have been observed with many of the polypeptides from the C. thermocellum cellulosome. However, when amino acids 247 to 286 were removed from the C-terminal end of the feruloyl esterase domain of XynZ, the enzyme was inactive, indicating the requirement of this sequence for activity. An alignment of the feruloyl esterase domains of XynZ, XynY, and FaeA of Orpinomyces (Fig. 1) shows that these domains have substantial homology. This homology was not apparent with feruloyl esterases of Aspergillus niger and Aspergillus tubingensis (15), CinA and CinB from Butyrivibrio fibrisolvens (13, 14), and XylD from Pseudomonas fluorescens subsp. cellulosa (18). The sequence analysis implies that feruloyl esterases may be classified in families similar to cellulases and other glycohydrolyses. The Orpinomyces FaeA and the feruloyl esterase domains of XynZ and XynY have homology to a polypeptide of unknown function in E. coli (10) and to an unknown domain of the carboxy-terminal region of a xylanase from a Ruminococcus sp. (1). Feruloyl esterase activity is present in Ruminococcus spp. (40), whereas no feruloyl esterase activity has been demonstrated in E. coli. The E. coli gene may encode a dipeptidase instead, since homology exits between a dipeptidase of Aspergillus fumigatus and feruloyl esterase (Fig. 1) (3).
Removal of amino acids 247 to 286 (FAE227XynZ) resulted in an inactive protein. This was somewhat unexpected, since this region of the feruloyl xylan esterase has the least homology between the different enzymes (Fig. 1). It is possible that this region is important for the stability and configuration of the enzymes, but a short sequence of the Orpinomyces FaeA (PGGTHDFPVW; amino acids 437 to 446) has high homology to a C. thermocellum XynZ sequence (QGGGHDFNVW; amino acids 256 to 265). Similar sequences are also found in the other enzymes shown in Fig. 1. These sequence may be of importance for the catalytic activity of the feruloyl esterases.
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ACKNOWLEDGMENTS |
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This work was funded by grant DE-FG02-93ER20127 from the Department of Energy (L.G.L.) and by Aureozyme, Inc. (X.-L.L.) and Georgia Research Alliance (X.-L.L.)
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Biochemistry and Molecular Biology, A214 Life Sciences Building, The University of Georgia, Athens, GA 30602-7229. Phone: (706) 542-7640. Fax: (706) 542-2222. E-mail: larsljd{at}arches.uga.edu.
Present address: University of CaliforniaSan Diego, Department of
Medicine, La Jolla, CA 92093-0822.
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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