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Applied and Environmental Microbiology, March 2001, p. 1253-1261, Vol. 67, No. 3
Department of
Microbiology1 and Department of Food
Science,2 Southeast Dairy Foods Research Center,
North Carolina State University, Raleigh, North Carolina 27695
Received 29 September 2000/Accepted 8 January 2001
The gusA gene, encoding a new
The action of bacterial
Bacterial Lactobacillus gasseri ADH is a human intestinal isolate that
was identified by its ability to adhere to intestinal epithelial cells
(30). L. gasseri is one of a number of
indigenous lactobacilli that are commonly associated with the
microflora of a healthy human GI tract (38, 45). A number
of these lactobacilli are currently under investigation to determine
the mechanistic basis of a variety of proposed probiotic activities
(29). It remains an important objective to characterize
the physiological and enzymatic activities of this group of organisms
and ultimately to identify the genetic factors responsible for those
activities. Studies with various Lactobacillus species,
including L. gasseri, have consistently shown their ability
to reduce the amount of fecal This study describes the identification and cloning of a
Bacterial strains, plasmids, and growth conditions.
The
bacterial strains and plasmids used in this study are listed in Table
1. Lactobacilli were propagated
statically at 37°C in MRS (Difco, Detroit, Mich.) or on MRS
supplemented with 1.5% agar. When appropriate, erythromycin (ERY) was
added at a concentration of 5 µg/ml, and
5-bromo-4-chloro-3-indolyl-
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.3.1253-1261.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Identification and Cloning of gusA, Encoding
a New
-Glucuronidase from Lactobacillus gasseri
ADH
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-glucuronidase enzyme, has been cloned from Lactobacillus
gasseri ADH. This is the first report of a -glucuronidase gene
cloned from a bacterial source other than Escherichia coli.
A plasmid library of L. gasseri chromosomal DNA was
screened for complementation of an E. coli gus mutant. Two
overlapping clones that restored -glucuronidase activity in the
mutant strain were sequenced and revealed three complete and two
partial open reading frames. The largest open reading frame, spanning
1,797 bp, encodes a 597-amino-acid protein that shows 39% identity to
-glucuronidase (GusA) of E. coli K-12 (EC 3.2.1.31). The
other two complete open reading frames, which are arranged to be
separately transcribed, encode a putative bile salt hydrolase and a
putative protein of unknown function with similarities to MerR-type
regulatory proteins. Overexpression of GusA was achieved in a
-glucuronidase-negative L. gasseri strain by expressing
the gusA gene, subcloned onto a low-copy-number shuttle
vector, from the strong Lactobacillus P6 promoter. GusA was
also expressed in E. coli from a pET expression system.
Preliminary characterization of the GusA protein from crude cell
extracts revealed that the enzyme was active across an acidic pH range and a broad temperature range. An analysis of other lactobacilli identified -glucuronidase activity and gusA homologs in
other L. gasseri isolates but not in other
Lactobacillus species tested.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-glucuronidase in the gastrointestinal (GI) tract is an important
component in the enterohepatic circulation of many hydrophobic
xenobiotics and endogenous waste compounds. The human body detoxifies a
variety of these compounds via conjugation to D-glucuronic
acid, rendering them more water soluble and subject to excretion in the
bile or urine (18, 22). As long as these compounds remain
conjugated, they are poorly reabsorbed into the bloodstream and are
efficiently eliminated from the body. However, reduction of these
-D-glucuronides in the GI tract by bacterial
-glucuronidase activity frees the aglycone components, allowing them
to reenter the bloodstream. This cycling of compounds means that rather
than being eliminated from the body all at once, many physiologically
important compounds, including endogenous steroid hormones and
exogenously acquired xenobiotics, are maintained in the body for longer
periods of time. Additionally, bacterial -glucuronidase activity has
been implicated in the generation of toxic and carcinogenic metabolites
which may be important precursors to tumor initiation and large bowel
cancer in the gut (6, 36).
-glucuronidase activity has been considered for many years
to be almost unique to Escherichia coli and closely related
Enterobacteriaceae (53). However, evidence has
slowly been accumulating to indicate that -glucuronidase activity
can also be found in a limited number of other bacteria, particularly gram-positive inhabitants of the GI tract (3, 4, 23, 36). Despite reports of enzyme activity associated with other bacteria and
the physiological importance of -glucuronidase to human health, only
the genetic elements for the E. coli enzyme have been
identified and studied (26, 53).
-glucuronidase activity and lower the
occurrence of cancer indicators present in the GI tract (15, 27,
33, 37, 41). The mechanisms by which lactobacilli lower the
amount of -glucuronidase activity in the gut remain unknown but may
be the reflection of a variety of activities including, but not limited
to, the exclusion or antagonism of typically -glucuronidase-positive
enterobacteria. Because lactobacilli colonize the proximal region of
the small intestine, it is reasonable to expect them to be frequently
exposed to -D-glucuronides excreted via bile into the GI
tract. Indeed, their frequent exposure to bile is reflected in the
common occurrence of conjugated bile acid hydrolysis among different
species (12, 19). Lactobacilli themselves have not
traditionally been associated with -glucuronidase activity, however,
and there have been, to date, only two reports of
-glucuronidase-like activity in lactobacilli (37, 42).
It has been unclear, however, whether this -glucuronidase activity
was the result of a true -glucuronidase enzyme or reflected the
activity of some other enzyme. It was the objective of this study to
identify genetic determinants for -glucuronidase-like activity in lactobacilli.
-glucuronidase gene, gusA, from L. gasseri
ADH. The nucleotide and deduced amino acid sequences of the
gusA gene and surrounding DNA are described. Additionally,
GusA was expressed from the cloned gusA gene by a
constitutive promoter in L. gasseri ATCC 33323 and by
a regulated promoter in E. coli. Initial
characterization of GusA enzyme activity is also reported.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-D-glucuronide (X-glu) (Gold
Biotechnologies, St. Louis, Mo.) was added at a concentration of 100 or
200 µg/ml. For induction studies with X-glu and
methyl--D-glucuronide, L. gasseri ADH
cells were also grown in modified MRS (per liter: 10.0 g of
BactoPeptone, 5.0 g of yeast extract, 2.0 g of
K2HPO4, 5.0 g of sodium acetate, 2.0 g of sodium citrate, 0.2 g of MgSO4, 0.05 g of
MnSO4, 1.0 g of Tween 80 [pH 6.5]) supplemented with 2.0% of the appropriate sugar.
TABLE 1.
Bacterial strains and plasmids
DNA isolation, manipulations, and transformations. Lactobacillus genomic DNA was isolated according to the method of Walker and Klaenhammer (50). Small-scale E. coli plasmid preparations for screening transformants were performed by alkaline sodium dodecyl sulfate lysis (43). Larger preparations of plasmid DNA for sequencing and for transformation of lactobacilli were performed using the QIAprep Spin Miniprep kit (Qiagen, Valencia, Calif.). All of the DNA manipulations in this study were performed according to standard procedures (43). Restriction enzymes and T4 DNA ligase were purchased from Roche Molecular Biochemicals (Indianapolis, Ind.). Calf intestinal phosphatase and T4 DNA polymerase were purchased from New England Biolabs, Inc. (Beverly, Mass.). All enzymes were used according to the manufacturers' specifications. DNA fragments were purified from agarose gels using the QIAEX II gel extraction kit (QIAGEN). All PCRs were performed according to standard procedures (52) using either Taq DNA polymerase or the Expand High Fidelity PCR system (Roche Molecular Biochemicals). PCR primers were synthesized by Integrated DNA Technologies (Coralville, Iowa). When appropriate, restriction sites were designed in the 5' end of the primers to facilitate future cloning steps. PCR products were purified using the QIAquick PCR purification kit (Qiagen).
Electrocompetent E. coli ElectroMAX DH10B cells were purchased from Gibco-BRL and transformed with a gene pulser (Bio-Rad Laboratories, Hercules, Calif.) according to the manufacturer's specifications. Electrocompetent E. coli DH5
and KW1
cells were prepared and transformed as described by Dower et al.
(17). Electrocompetent Lactobacillus gasseri
ATCC 33323 cells were prepared using 3.5× SMEB as described by
Luchansky et al. (35).
Construction and screening of Lactobacillus gasseri
ADH genomic library.
L. gasseri ADH chromosomal
DNA was randomly sheared by nebulization and separated on a 1% agarose
gel. Four- to six-kilobase bands were gel purified and treated with T4
DNA polymerase to create blunt ends. These fragments were then ligated
to SmaI-bacterial alkaline phosphatase-treated pUC18. This
ligation reaction was first transformed into E. coli
DH10B to create an initial plasmid library. Transformants were selected
on LB plates plus 200 µg of carbenicillin/ml. PCR and restriction
analysis of 50 random transformants revealed that >90% of the
transformants contained a plasmid with an average insert size of 4.5 kb. In order to avoid a competitive enrichment step, plasmid DNA was
isolated from approximately 9,000 DH10B transformants that were pooled
directly from outgrowth plates. This plasmid library was then screened
for the presence of genes involved in -glucuronidase activity by
transformation of electrocompetent E. coli KW1 cells.
KW1 transformants were plated on LB plates supplemented with 200 µg
of carbenicillin/ml and 50 µg of X-glu/ml. Positive clones were
identified by the formation of blue colonies.
DNA sequencing and analysis.
DNA sequencing was performed at
the University of California
Davis Automated DNA Sequencing Facility
on an ABI Prism 377 DNA sequencer with a 96-lane upgrade (Applied
Biosystems, Foster City, Calif.). Assembly and analysis of DNA
sequences were performed with DNASIS for Windows (Hitachi Software) and
Clone Manager 5 (Scientific & Educational Software). Protein homology
searches were performed with the Basic Local Alignment Search Tool
(BLAST), version 2.1, at the website of the National Center for
Biotechnology Information (http://www.ncbi.nlm.nih.gov/), protein
motifs were identified by comparison to the PROSITE database
(http://www.expasy.ch/prosite/), and amino acid alignments
were performed with ClustalW (http://www.ebi.ac.uk/clustalw/).
Construction of the expression vector pTRK664. Plasmid pTRK563 was created by the ligation of a BglII-NheI PCR product amplified from pGK12 with primers 5'-AGTCAGATCTACAGCTCCAGATCGATTCAC-3' and 5'-AGTCGCTAGCTTACGAACTGGCACAGATGG-3' to a BglII-NheI PCR product amplified from pBluescript II KS(+) with primers 5'-AGTCAGATCTTTAATGCGCCGCTACAGG-3' and 5'-AGTCGCTAGCAATGCAGCAGCTGGCACGACAGG-3' (restriction sites are underlined). For the creation of plasmid pTRK664, the T7 terminator, Lactobacillus P6 promoter, and gusA gene were cloned sequentially into plasmid pTRK563. The T7 terminator was amplified from pET28a(+) as an XhoI-SalI fragment as described previously (51) and cloned into the SalI site. The Lactobacillus P6 promoter was amplified from pLA6 (16) using the primers 5'-AGAGTCGACTAATGAAGCTTGTTTTGTTTCAG-3' and 5'-ACTGAATTCTTCTTTAGTTAATGGCTCAG-3' and cloned as a SalI-EcoRI fragment. The gusA gene including the putative RBS was amplified using the primers 5'-GTCGAATTCTACTAGAAAGGAAAATCATC-3' and 5'-TGCTCTAGATAATTGAGCACGATTATTTG-3' and cloned as an EcoRI-XbaI fragment.
Enzyme assays.
For lactobacilli, -glucuronidase activity
in cell extracts (CFEs) was measured by the hydrolysis of
para-nitrophenyl--D-glucuronide (PNPG)
(Sigma, St. Louis, Mo.) Cultures (10.0 ml each) were washed twice in
10.0 ml of GUS buffer (100 mM sodium phosphate-2.5 mM EDTA [pH 6.0])
and resuspended in 1.0 ml of the same. Cell suspensions were then added
to chilled tubes with silica beads and subjected to three 1-min cycles
at the highest setting in a Mini Bead Beater (Biospec Products,
Bartlesville, Okla.) with 1 min on ice in between cycles. Following
centrifugation to pellet beads and cell debris, the CFE was collected
and kept temporarily on ice until the start of the assays. Protein
concentrations were determined by the method of Bradford
(10) using the Sigma protein determination kit. For each
assay, the CFEs were warmed to the assay temperature and 200 µl of
sample was added to 800 µl of GUS buffer containing 12.5 mM PNPG and
incubated at 37°C (except during temperature experiments). The pH of
the GUS buffer was 6.0 except during pH experiments, when sodium
phosphate buffer at different pHs was used to prepare the GUS buffer.
The final concentration of PNPG in the assay buffer was 10.0 mM. At
appropriate time intervals, usually 5, 10, and 15 min, 100 µl of the
reaction mixture was added to 800 µl of 1.0 M
Na2CO3, and the optical density was measured at
405 nm (OD405). One unit of activity is defined as 1 nmol
of p-nitrophenol liberated per min per milligram of
protein. For the measurement of activity in E. coli
cells, assays were performed nearly identically, except that whole
cells disrupted with chloroform were used instead of cell extracts and
assays were done at a pH of 4.0 to reduce any potential interference by
the native E. coli -glucuronidase. Enzyme activity
for E. coli experiments is represented per
OD600. Each value presented is the average of results from at least three independent experiments.
Expression of gusA in E. coli.
In order to create the plasmid pTRK665, the gusA gene was
amplified using the primers GUS7F
5'-AGTCCATGGAATCTGCACTATATCCAATTC-3' and GUS6R
5'-ACTGGAATTCTAATTGAGCACGATTATTTG-3'. An
NcoI site (underlined) was designed in primer GUS7F to
include the start codon sequence. Cloning into the
NcoI-EcoRI sites of pET28a(+) resulted in
the translational fusion of the gusA gene to the T7 promoter
and E. coli ribosome binding site of the plasmid.
Plasmid pTRK665 was created in E. coli DH5 and
transformed into E. coli Tuner(DE3) to perform the
induction experiments. For induction experiments, cells at an
OD600 of 0.6 were induced with 1.0 mM
isopropyl--D-thiogalactopyranoside (IPTG) for 4 h.
Samples were removed at appropriate time points to measure growth and
-glucuronidase activity.
Southern hybridization. Southern hybridization of genomic DNA was performed using the Roche Molecular Biochemicals DIG nonradioactive nucleic acid labeling and detection system. A 776-bp internal gusA PCR product was amplified in the presence of digoxigenin-11-dUTP with the primers 5'-ACAGTTGACGAATACACAGAT-3' and 5'-AGGCGATGAGAAGAAGATAATG-3'. Hybridization was performed according to the manufacturer's specifications at 42°C in standard hybridization buffer plus 50% formamide, and detection was performed with a CSPD chemiluminescent substrate.
Nucleotide sequence accession numbers. The nucleotide sequences presented in this paper have been submitted to GenBank and assigned the accession number AF305888.
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Screening and identification of -glucuronidase-positive
lactobacilli.
The Lactobacillus spp. listed in
Table 2 were screened for
-glucuronidase activity by measuring their ability to hydrolyze the
chromogenic substrate X-glu on MRS plates (100 µg/ml) or in MRS broth
(200 µg/ml). Initially, only L. gasseri strains ADH and ATCC 33323 were included in the screening; however, upon
observation of -glucuronidase activity in strain ADH but not in ATCC
33323, 11 additional L. gasseri strains of human origin
were screened. These 11 strains had been previously identified as
unique strains of L. gasseri by 16S rRNA sequencing and
pulsed-field gel electrophoresis (32). In addition to
strain ADH, six other L. gasseri strains exhibited
activity towards X-glu as evidenced by the formation of blue colonies
or a blue color in broth media. None of the other Lactobacillus species tested showed activity (Table 2).
L. gasseri ADH was chosen to be the subject of further
experiments because it was the best characterized of all the
-glucuronidase-positive strains.
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-glucuronidase activity by induction with 10.0 mM X-glu or
10.0 mM methyl--D-glucuronide, both of which are known
inducers of the E. coli -glucuronidase enzyme (53). In addition, to address the possibility that
catabolite repression by glucose is involved in regulating
-glucuronidase expression, these experiments were performed on
cultures grown in MRS or in modified MRS with the alternative carbon
source galactose, lactose, or sucrose. Each inducer was added at
different times during growth and allowed to incubate for time periods
ranging from 15 min to overnight. However, even in the absence of
glucose, no induction of -glucuronidase activity was observed for
any treatment with X-glu or methyl--D-glucuronide (data
not shown).
Cloning of the gusA gene.
In order to identify the
gene(s) responsible for -glucuronidase activity in L. gasseri ADH, a random genomic library was created in pUC18 and
screened in E. coli KW1 (
gus) cells.
Eight positive clones were identified by the formation of dark blue colonies on LB plates supplemented with 200 µg carbenicillin/ml and
50 µg of X-glu/ml. Each clone contained a single plasmid which complemented the gus mutation upon retransformation into
strain KW1. Preliminary restriction analysis revealed that each
plasmid contained one of four different overlapping inserts (data
not shown). Further confirmation of one clone, designated
pTRK666, was obtained by subcloning its 4.5-kb insert as an
EcoRI-PstI fragment into the gram-positive
shuttle vector, pTRK563, and introducting the resulting plasmid
(pTRK668) into L. gasseri ATCC 33323 by electroporation. ERY-resistant transformants, plated on MRS plus X-glu
(100 µg/ml), were converted to a -glucuronidase-positive phenotype
as evidenced by the formation of blue colonies. The 4.5-kb insert of
pTRK666 was then completely sequenced on both strands. Another plasmid,
pTRK667, containing an overlapping fragment of 4.9 kb, was later used
to determine the nucleotide sequence of an additional 1,013 bp of
flanking DNA (Fig. 1).
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Analysis of nucleotide and amino acid sequences.
In all, a
total of 5,438 bp was sequenced from plasmids pTRK666 and pTRK667 to
reveal the presence of three complete and two partial open reading
frames (ORFs) (Fig. 1). The predominant ORF of 1,797 bp begins with an
ATG initiation codon at nucleotide 1663 and ends with a TAA codon at
nucleotide 3457. The ATG codon is preceded at a distance of 9 bp by the
putative ribosome binding site AGAAAGGA. The sequence is capable of
coding for a polypeptide of 597 amino acids with a predicted molecular
mass of 69.8 kDa. Comparison of the predicted amino acid sequence to
previously known sequences by BLAST analysis revealed the highest
similarities to -glucuronidase (GusA) of E. coli
K-12 (39% identity) (26) and to several synthetic GUS
constructs. High similarities (30 to 35% identity) were also found to
many mammalian -glucuronidase enzymes. An alignment of the predicted
GusA amino acid sequence with the E. coli K-12
GusA sequence revealed the largest areas of homology in the
carboxy-terminal end of the enzymes (Fig.
2). Recently Islam et al.
(25), studying active site residues of human
-glucuronidase, presented evidence for Glu540 as the
nucleophile residue, for Glu451 as the acid-base residue,
and for the involvement of Tyr504 in the active site.
Analysis of the predicted amino acid sequence encoded by
gusA reveals that the residues corresponding to the human
-glucuronidase Glu540, Glu451, and
Tyr504 residues are conserved in the L. gasseri ADH enzyme (Fig. 2). All of the currently known
-glucuronidase enzymes from E. coli, plant, and
animal sources belong to the glycosyl hydrolase family 2. Comparison of
the predicted amino acid sequence with the PROSITE database
revealed the presence of two motifs that could be identified as the two
signature sequences proposed for this family (Fig. 2). The first motif
showed 100% identity to signature 1 (PS00719), and the second motif,
49 residues downstream, showed identity at 12 out of 15 positions to
signature 2 (PS00608). More information about these signatures can be
found at the ExPASy Molecular Biology Server
(http://expasy .cbr.nrc.ca/cgi-bin/nicedoc.pl?PDOC00531). Immediately downstream
of the gusA gene is a large, imperfect inverted repeat capable of forming a hairpin structure with a predicted G
of 
37.6 kcal/mol. The presence of this potential terminator structure and the arrangement of genes around gusA indicate that it is
most likely transcribed as a monocistronic unit. Lack of a sequence resembling a signal sequence in the amino-terminal region of the enzyme
implies that it has an intracellular location.
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Overexpression of GusA in L. gasseri ATCC 33323. A significant barrier to the preliminary characterization of the gusA gene product was its weak expression in wild-type ADH cells. Since no conditions were initially found to induce gusA expression in L. gasseri ADH, GusA was overproduced in L. gasseri ATCC 33323 by using the strong Lactobacillus P6 promoter (16). In order to facilitate cloning and expression in L. gasseri, plasmid pTRK563 was first created by modification of the low-copy-number, broad-host-range plasmid pGK12. The removal of the cat gene and addition of the lacZ multiple cloning site from pBluescript II KS(+) resulted in a smaller plasmid that had more cloning sites than the original plasmid pGK12. Using pTRK563 as a base vector, plasmid pTRK664 was then constructed for the heterologous, unregulated expression of GusA in lactobacilli.
Plasmid pTRK664 was introduced by electroporation into L. gasseri ATCC 33323, which was identified in this study as a-glucuronidase-negative strain. GusA expression was
observed in Ery-resistant transformants by the formation of blue
colonies on MRS plates supplemented with 100 µg of X-glu/ml. The
amount of -glucuronidase activity was determined for cells grown in
MRS broth. The activity of log-phase and stationary-phase cells was
1468 ± 97 and 2532 ± 220 U, representing a 277-fold and
26-fold increase in activity, respectively, over that of L. gasseri ADH. No hydrolysis of PNPG was observed in ATCC 33323 cells harboring the plasmid pTRK563.
Characterization of GusA.
CFEs of L. gasseri
ATCC 33323 cells harboring plasmid pTRK664 were used to measure the
effects of pH, temperature, and saccharic acid 1,4-lactone on
-glucuronidase activity. Figure 3
shows the results of pH and temperature optimization experiments. The
maximum activity was found at approximately pH 6.0 and at 65°C. While the activity dropped off quickly at pH values above 6.0, the enzyme retained more than 50% activity at a pH of 4.0 and approximately 33%
activity at pH 3.0. An approximately twofold increase in activity was
observed as the temperature was raised from 37 to 65°C.
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-glucuronidases examined to date from E. coli,
plants, and mammals (21). To determine the sensitivity of
L. gasseri GusA to SAL, -glucuronidase assays were
performed on CFEs in the presence of 0.5 or 1.0 mM SAL at 37°C and pH
6.0. The addition of 0.5 or 1.0 mM SAL resulted in the reduction of
-glucuronidase activity of the cell extracts by 80 and 88%, respectively.
Controlled expression of gusA in E. coli.
In order to further correlate -glucuronidase
activity with gusA expression, plasmid pTRK665 was
constructed to contain a translational fusion between the
gusA gene and the T7 promoter and ribosome binding site
of pET28a(+). Plasmid pTRK665 was transformed into E. coli Tuner(DE3), which carries a chromosomal copy of the T7 polymerase gene under the control of the inducible
lac promoter. GusA expression was induced in E. coli Tuner(DE3)::pTRK665 over 4 h by the addition of 1.0 mM
IPTG (Fig. 4). -Glucuronidase activity peaked in induced cells between 15 and 60 min and stayed relatively constant over the time course of 4 h. The growth of induced cells was not significantly different from that of uninduced cells.
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Screening other L. gasseri strains for
gusA homologues.
Out of 13 strains of L. gasseri screened in this study for -glucuronidase activity,
only 7 showed activity towards the chromogenic substrate X-glu. In
order to examine the distribution of gusA genes among these
13 strains, a 776-bp internal region of the gusA gene was
labeled with digoxigenin and used as a probe in a Southern blot
analysis. Genomic digests from each of the strains were separated by
electrophoresis and transferred to a nylon membrane. The membrane was
then hybridized at mild stringency with the labeled gusA
probe. With the exception of ATCC 33323, all of the strains tested
showed a positive hybridization to the gusA probe (Fig. 5).
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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In this work we report the identification and cloning of the
gusA gene of L. gasseri ADH by its ability
to complement an E. coli gus mutant. The
view that -glucuronidase activity is a trait unique to E. coli has been supported in large part by the lack of solid
evidence proving the existence of other -glucuronidase enzymes.
Previous studies have observed -glucuronidase activity in some
gram-positive inhabitants of the GI tract, including three species of
lactobacilli, but in no case have the genes responsible for these
activities been identified. Of the three Lactobacillus species previously studied, L. delbrueckii, L. fermentum, and L. rhamnosus, only the enzyme
activity from L. rhamnosus has been partially
characterized (37, 42). Thus, this report describes the
first gusA gene to be cloned from a bacterial source other than E. coli. The discovery of this new bacterial
gusA gene, some 20 years after the identification of the
E. coli gene, will provide a new context in which to
study the effects of bacterial -glucuronidase on gastrointestinal
health and disease.
The genetic organization of the L. gasseri gusA gene and the surrounding region is not conserved with respect to the E. coli gusA gene (53). The G+C composition (35%) of the gusA gene reflects the overall G+C composition of the L. gasseri chromosome (33 to 35%), indicating that it was not acquired recently by lateral transfer from enterobacteria. In E. coli, the gusA gene is transcribed as part of the gusRABC operon together with the genes coding for the repressor (gusR), the transporter (gusB), and a membrane-associated protein (gusC) of unknown function. However, in L. gasseri, the arrangement of the gusA gene with respect to flanking ORFs indicates that unlike the E. coli gene, it is transcribed as a monocistronic unit. Due to its position and nature, ORF-R is a good candidate for a regulatory protein with a role in the regulation of gusA; however, it is separately transcribed and cannot be directly linked to gusA without further study. The DNA surrounding the gusA gene did not reveal a gene encoding an obvious transport protein, indicating that L. gasseri utilizes either a specific transporter located elsewhere on the chromosome or an alternative transporter for glucuronide uptake. The close proximity of the bsh gene to the gusA gene is also very interesting and suggests that this region of the chromosome may be involved in the cellular response to bile secretion in the GI tract.
The reasons for a low level of expression of -glucuronidase in ADH
cells grown in MRS are still unknown, but this may result from
transcriptional regulation of the gusA gene. The
regulation of gusA has been well studied with E. coli, in which the predominant mechanisms are similar to
those of the well-known lac operon. Expression is
induced by a variety of glucuronides and is repressed in the presence
of alternative carbon sources. Regulation is controlled at the level of
transcription by the specific repressor GusR (40) and by
catabolite-responsive elements (26). Similar regulatory mechanisms have been identified for a variety of metabolic enzymes in
lactobacilli. In L. pentosus, -xylosidase expression
is induced by growth on xylose and is negatively regulated by the
repressor protein XyIR and the catabolite control protein, CcpA
(34). CcpA is a global regulator of low-G+C gram-positive
organisms that binds to catabolite-responsive elements (cre)
in promoter regions to control carbon catabolite repression
(47). A ccpA gene has been identified for a
number of lactobacilli, including L. pentosus,
L. casei, and L. delbrueckii (34,
39, 44), but not for L. gasseri. Additionally,
analysis of the region preceding the L. gasseri gusA
gene did not reveal sequences with high levels of similarity to the
currently proposed cre consensus, but regions of dyad
symmetry were observed in the promoter region.
Because of the paucity of versatile cloning vectors for organisms in
the Lactobacillus acidophilus complex, a new plasmid, pTRK563, was constructed for cloning and expressing the gusA
gene in L. gasseri ATCC 33323. This plasmid, based on
the well-characterized pWV01 replicon (49), maintains the
disadvantages of being low copy number and utilizing a rolling circle
mechanism of replication. However, it offers the benefits of a broad
host range, small size, multiple cloning site, and a lacZ
gene for screening transformants in E. coli. The
creation of this new plasmid offered more flexibility in creating the
expression vector pTRK664. In addition to L. gasseri ATCC 33323, expression of GusA from plasmid pTRK664 was observed in
L. acidophilus, L. johnsonii, and
L. lactis, all of which were shown previously to be
-glucuronidase negative.
The pH and temperature profiles for L. gasseri GusA are
similar to those obtained by Pham et al. (42) with
partially purified enzyme fractions from L. rhamnosus.
The results indicate that GusA is a very stable enzyme that is more
active at acidic pHs and higher temperatures. The
Lactobacillus enzyme is considerably more active at acidic
pHs than what has been reported for the E. coli enzyme
(5, 28). This difference is not entirely surprising considering that the lactic acid bacteria generally inhabit a more
acidic environment and maintain a lower intracellular pH than the
enterobacteria. It does, however, imply that the two -glucuronidases are active in different microenvironments in the GI
tract. This new information suggests that for detecting -glucuronidase activity, the use of fecal contents may not
adequately reflect the contributions of all organisms in vivo,
especially when assays are performed at higher pH values.
The discovery of GusA in L. gasseri is expected to
stimulate further research on the distribution of -glucuronidase
enzymes among other organisms. The unexpected discovery that a number of -glucuronidase-negative L. gasseri strains
possess a gusA homologue raises further questions. In fact,
the only strain to lack both -glucuronidase activity and a
gusA homologue was the type strain, ATCC 33323. These
results can be explained by a number of hypotheses. Feng and Lampel
(20) showed that isolates of E. coli
O157:H7 that did not exhibit -glucuronidase activity still carried
nucleotide sequences for the uidA (gusA) gene.
These genes carried a small number of mutations that resulted in the production of an inactive -glucuronidase enzyme which was still reactive with the anti--glucuronidase antibody. In a study
of -glucuronidase activity among human fecal E. coli isolates, Chang et al. (11) found three isolates
in which activity was minimal at 37°C but significant at 44.5°C. In
the case of E. coli K-12, -glucuronidase activity is
poorly induced by X-glu because of the failure of the
glucuronide-specific permease to concentrate it from the media
(53). These and other issues will have to be studied in
order to elucidate the true distribution and functionality of
gusA homologs.
Finally, it has yet to be determined what advantage GusA expression
provides L. gasseri. There is currently no evidence to support the ability of lactobacilli to utilize glucuronides for energy
production or to support the existence of a D-glucuronate catabolic pathway in lactobacilli. It also remains to be determined what the natural substrates of L. gasseri GusA are. A
number of important natural compounds, including bilirubin and
endogenous hormones, are routinely excreted as glucuronide conjugates
via bile into the GI tract. Perhaps knowing this information will provide clues to the significance of -glucuronidase activity, in
vivo, to L. gasseri and to the host.
| |
ACKNOWLEDGMENTS |
|---|
This research was supported by The Southeast Dairy Foods Research Center, Dairy Management Inc., and the North Carolina Dairy Foundation. W. Michael Russell was supported by a U.S. Department of Education GAANN Biotechnology Fellowship.
We thank Evelyn Durmaz and Michael Callanan for their help and critical reviews and Brian Dougherty for his advice on genomic library constructions.
| |
FOOTNOTES |
|---|
* Corresponding author. Mailing address: Department of Food Science, North Carolina State University, Box 7624, Raleigh, NC 27695. Phone: (919) 515-2972. Fax: (919) 515-7124. E-mail: klaenhammer{at}ncsu.edu.
Paper no. FSR-00-26 of the Journal Series of the Department of Food
Science, North Carolina State University, Raleigh, NC 27695-7624.
| |
REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Applied and Environmental Microbiology, March 2001, p. 1253-1261, Vol. 67, No. 3
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.3.1253-1261.2001
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