L-galactose metabolism in bacteroides vulgatus from the human gut microbiota

Article abstract of DOI:10.1021/bi500656m

A previously unknown metabolic pathway for the utilization of l-galactose was discovered in a prevalent gut bacterium, Bacteroides vulgatus. The new pathway consists of three previously uncharacterized enzymes that were found to be responsible for the conversion of l-galactose to d-tagaturonate. Bvu0219 (l-galactose dehydrogenase) was determined to oxidize l-galactose to l-galactono-1,5-lactone with k_cat and k_cat/K_m values of 21 s^-1 and 2.0 × 10⁵ M^-1 s ^-1, respectively. The kinetic product of Bvu0219 is rapidly converted nonenzymatically to the thermodynamically more stable l-galactono-1,4-lactone. Bvu0220 (l-galactono-1,5-lactonase) hydrolyzes both the kinetic and thermodynamic products of Bvu0219 to l-galactonate. However, l-galactono-1,5-lactone is estimated to be hydrolyzed 300-fold faster than its thermodynamically more stable counterpart, l-galactono-1,4-lactone. In the final step of this pathway, Bvu0222 (l-galactonate dehydrogenase) oxidizes l-galactonate to d-tagaturonate with k_cat and k_cat/K _m values of 0.6 s^-1 and 1.7 × 10⁴ M ^-1 s^-1, respectively. In the reverse direction, d-tagaturonate is reduced to l-galactonate with values of k_cat and k_cat/K_m of 90 s^-1 and 1.6 × 10 ⁵ M^-1 s^-1, respectively. d-Tagaturonate is subsequently converted to d-glyceraldehyde and pyruvate through enzymes encoded within the degradation pathway for d-glucuronate and d-galacturonate.

Full text of DOI:10.1021/bi500656m

Article
pubs.acs.org/biochemistry
Open Access on 06/25/2015
L‑Galactose Metabolism in Bacteroides vulgatus from the Human Gut
Microbiota
Merlin Eric Hobbs,^‡ Howard J. Williams,^§ Brandan Hillerich,^# Steven C. Almo,^#
and Frank M. Raushel*^,§,‡
§
^‡Department of Biochemistry and Biophysics, Department of Chemistry, Texas A&M University, College Station, Texas 77843,
United States
^#Albert Einstein College of Medicine, 1300 Morris Park Avenue, Bronx, New York 10461, United States
S
* Supporting Information
ABSTRACT: A previously unknown metabolic pathway for the utilization of L-galactose was discovered in a prevalent gut
bacterium, Bacteroides vulgatus. The new pathway consists of three previously uncharacterized enzymes that were found to be
responsible for the conversion of ^L-galactose to D-tagaturonate. Bvu0219 (L-galactose dehydrogenase) was determined to oxidize
L-galactose to L-galactono-1,5-lactone with k_cat and k_cat/K_m values of 21 s⁻¹ and 2.0 × 10⁵ M⁻¹ s⁻¹, respectively. The kinetic
product of Bvu0219 is rapidly converted nonenzymatically to the thermodynamically more stable ^L-galactono-1,4-lactone.
Bvu0220 (^L-galactono-1,5-lactonase) hydrolyzes both the kinetic and thermodynamic products of Bvu0219 to L-galactonate.
However, ^L-galactono-1,5-lactone is estimated to be hydrolyzed 300-fold faster than its thermodynamically more stable
counterpart, ^L-galactono-1,4-lactone. In the final step of this pathway, Bvu0222 (L-galactonate dehydrogenase) oxidizes L-
galactonate to ^D-tagaturonate with k_cat and k_cat/K_m values of 0.6 s⁻¹ and 1.7 × 10⁴ M⁻¹ s⁻¹, respectively. In the reverse direction,
D-tagaturonate is reduced to L-galactonate with values of k_cat and k_cat/K_m of 90 s⁻¹ and 1.6 × 10⁵ M⁻¹ s⁻¹, respectively. D-
Tagaturonate is subsequently converted to ^D-glyceraldehyde and pyruvate through enzymes encoded within the degradation
pathway for ^D-glucuronate and D-galacturonate.
ost of the microorganisms that colonize the human body
M_{reside within the gastrointestinal tract and are}
collectively known as gut microbiota. These microorganisms
Figure 1. Genomic neighborhood of Bvu0220. Genes colored in
maroon have been functionally characterized by this investigation and
are as follows: Bvu0219 is ^L-galactose dehydrogenase, Bvu0220 is L-
are of particular interest for the role they play in metabolism
and human health.¹ While the human−microbiota relationship
is predominantly commensal, there are reports implicating
galactono-1,5-lactonase, and Bvu0222 is ^L-galactonate dehydrogenase.
these microbes in a wide range of pathologies, including
inflammatory bowel disease and colitis.² One important role for
these organisms is the degradation of poorly digestible plant
polysaccharides such as pectin, xylan, and cellulose.³ Bacteroides
species are prevalent in the microbiota, and these organisms
have been implicated as being partly responsible for the
degradation of these polysaccharides. The various species of
Bacteroides encode an unusually high number of glycoside
hydrolases and polysaccharide lyases. Bacteroides vulgatus is
thought to encode the largest number of enzymes targeting the
degradation of pectin.³⁻⁵
A cluster of genes that is likely responsible for an unknown
metabolic pathway for the catabolism of carbohydrates in B.
vulgatus is presented in Figure 1. Of the six genes identified in
this cluster, four of them likely function to code for enzymes
that utilize carbohydrate-based substrates. On the basis of
The genes in white are of unknown function. Bvu0217 is a putative
glycoside hydrolase, Bvu0218 is a putative transcription regulator, and
Bvu0221 is a putative sugar permease.
amino acid sequence identity to proteins of known function,
Bvu0217 is a putative glycoside hydrolase from cog3669,
Bvu0219 is a NAD⁺/NADP⁺-dependent oxidoreductase from
cog0667, Bvu0220 is a lactonase associated with cog3618, and
Bvu0222 is a Zn²⁺-dependent dehydrogenase from cog1063.
The two remaining proteins, Bvu0218 and Bvu0221, appear to
be a transcriptional regulator and a sugar permease from
Received: May 28, 2014
Revised: June 24, 2014
Published: June 25, 2014
© 2014 American Chemical Society
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cog0738, respectively. A potential metabolic pathway for these
enzymes involves the initial hydrolysis of a more complex
carbohydrate substrate (glycohydrolase), oxidation of the
aldose product to a lactone (dehydrogenase), hydrolysis of
the lactone to an acid sugar (lactonase), and the subsequent
oxidation of the acid sugar (dehydrogenase).
were not commercially available were synthesized according to
standard published procedures with the exception of 4-deoxy-^L-
fucono-1,5-lactone, which was enzymatically synthesized.^13,14
The noncommercial lactones included the following: L-fucono-
1,4-lactone, D-arabinono-1,4-lactone, L-xylono-1,4-lactone, L-
mannono-1,4-lactone, ^D-talono-1,4-lactone, D-allono-1,4-lac-
tone, ^L-rhamnono-1,4-lactone, D-lyxono-1,4-lactone, L-lyxono-
1,4-lactone, L-arabinono-1,4-lactone, D-xylono-1,4-lactone, L-
mannono-1,5-lactone, L-rhamnono-1,5-lactone, and 4-deoxy-L-
fucono-1,5-lactone. The sugar lactones that were obtained from
either CarboSynth or ChromaDex included the following
compounds: ^L-galactono-1,4-lactone, D-mannono-1,4-lactone,
D-galactono-1,4-lactone, D-ribono-1,4-lactone, D-glucurono-6,3-
lactone, D-erythronolactone, and L-glucono-1,5-lactone. Aldose
sugars were obtained from either Sigma-Aldrich or Carbosynth
and included L-fucose, L-galactose, L-glucose, D-altrose, D-
arabinose, ^L-xylose, L-rhamnose, D-mannose, L-allose, D-talose,
L-talose, D-allose, D-galactose, L-mannose, D-gulose, D-glucose, L-
arabinose, ^L-ribose, D-lyxose, L-lyxose, D-xylose, D-ribose, and 4-
deoxy-^L-fucose.
Cloning, Expression and Purification of Bvu0220 from
B. vulgatus. The gene for Bvu0220 (gi|150002825; UniProt:
A6KWY3) was amplified from B. vulgatus ATCC 8482 genomic
DNA using 5′-TACTTCCAATCCATGATGGATTTTA-
ACATAATAGATGCACACTCC-3′ as the forward primer
and 5′-TATCCACCTTTACTGTTATTCTGACATGTTT-
TTTATGTAAGGAAGAGATATG-3′ as the reverse primer.
PCR was performed using KOD Extreme DNA Polymerase
(Novagen). The conditions were 2 min at 95 °C, followed by
40 cycles of 20 s at 95 °C, 20 s at 66 °C, and 20 s at 72 °C. The
amplified fragment was cloned into the N-terminal TEV
cleavable 6x-His-tag containing vector, pNIC28-BSA, by
ligation-independent cloning.¹⁵
Of the enzymes contained within this putative pathway for
the catabolism of an unknown carbohydrate, we were
particularly interested in the function of Bvu0220, a member
of the amidohydrolase superfamily (AHS). The AHS is a
diverse superfamily of enzymes that catalyzes a wide variety of
reactions including the hydrolysis of amide or ester bonds,
hydration, decarboxylation, and isomerization reactions.⁶⁻¹⁰
Most of the proteins in the AHS exhibit a distorted (β/α)₈-
barrel topology, with the active site located at the C-terminal
end of the β-barrel. Nearly all of the structurally characterized
enzymes contained within the AHS bind one to three divalent
cations, which are ligated to the protein via complexation with a
common set of conserved amino acid residues. However, the
structurally characterized lactonases from the AHS that are
contained within cog3618 do not function with a divalent
cation bound in the active site. The known lactonases from
cog3618 include 2-pyrone-4,6-dicarboxylate lactonase (LigI), 4-
sulfomuconolactonase (4-SML), ^L-rhamnonate-1,4-lactonase,
and ^L-fucono-1,5-lactonase (FucL).¹¹⁻¹³
A sequence similarity network (SSN) for cog3618 calculated
at a BLAST E-value of 10⁻³⁰ is provided in Figure 2. Each node
The recombinant plasmid containing Bvu0220 was trans-
formed into BL21 (DE3) cells (Novagen), via electroporation.
Five milliliter cultures of LB medium supplemented with 50
μg/mL kanamycin were inoculated with a single colony and
grown overnight at 37 °C. Overnight cultures were used to
inoculate 1 L of LB medium (50 μg/mL kanamycin) and
incubated at 37 °C until an OD₆₀₀ of 0.4−0.6 was achieved.
Gene expression was induced by the addition of 0.1 mM
isopropyl β-thiogalactoside (IPTG) at ambient temperature for
18 h. Cells were harvested via centrifugation at 8000 rpm at 4
°C. Cell pellets were resuspended in purification buffer (50 mM
HEPES, 500 mM NaCl, 40 mM imidazole, 0.1 mg/mL
phenylmethanesulfonyl fluoride, pH 7.5) and lysed via multiple
rounds of sonication. Nucleic acids were removed from the cell
lysate with the addition of 2% (w/v) protamine sulfate over 30
min at 4 °C, followed by centrifugation (8000 rpm). The
resulting supernatant was applied to a 5 mL HisTrap HP (GE
Healthcare) nickel affinity column. Protein was eluted from the
nickel affinity column with 50 mM HEPES (pH 7.5), 0.5 M
NaCl, and 500 mM imidazole over a gradient of 23 column
volumes.
Cloning, Expression, and Purification of Bvu0219 and
Bvu0222 from B. vulgatus. The gene for Bvu0219 (gi|
150002825; UniProt: A6KWY2) was cloned from B. vulgatus
ATCC 8482 with the primer pair 5′-ATGAATTACAATG-
AAATGGGAAAACCGGTATGCGGGTT-3′ and 5′-TGAA-
TTAGCCCAACTGATACGCATTTGTTTTCCGATAA-3′.
Restriction sites for Nhe1 and Xho1 were inserted into the
forward and reverse primers. The PCR product was purified
with a Promega PCR cleanup system and subsequently digested
Figure 2. Sequence similarity network for cog3618 at an E-value of
10⁻³⁰ where each node represents a protein and an edge represents an
E-value between two proteins of 10⁻³⁰ or smaller. The triangular nodes
represent an enzyme with experimentally verified function. Nodes are
color-coded as follows: LigI (red), 4-SML (orange), ^L-rhamnono-
lactonase (blue), FucL (green), and Bvu0220 (yellow).
within the sequence similarity network represents a unique
protein contained within cog3618, which are connected to each
other if they are related by an E-value of 10⁻³⁰ or less. At this
stringency level, cog3618 is subdivided into two primary
groups, arbitrarily designated as Class I and Class II. Most of
the enzymes within Class I are encoded adjacent to genes with
an apparent relationship to carbohydrate metabolism.¹³ At this
level of stringency, Bvu0220 is not associated with either Class I
or Class II enzymes. Here we identify a novel metabolic
pathway for the metabolism of ^L-galactose to D-tagaturonate. L-
Galactose is first oxidized to ^L-galactono-1,5-lactone and then
hydrolyzed to ^L-galactonate. This product is subsequently
oxidized to ^D-tagaturonate, which is further metabolized to
pyruvate and ^D-glyceraldehyde-3-phosphate.
MATERIALS AND METHODS
Materials. All chemicals and buffers were purchased from
Sigma-Aldrich, unless otherwise specified. Sugar lactones that
■
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with Nhe1 and HindIII. The resulting DNA product was ligated
into a pET-24a(+) vector (Novagen). The ligation reaction
mixture was transformed into BL21(DE3) cells via electro-
poration. A single colony containing the plasmid of interest was
used to inoculate 5 mL overnight cultures of LB (50 μg/mL
kanamycin) and incubated at 37 °C. One liter cultures of LB
containing 50 μg/mL kanamycin were inoculated with a 5 mL
overnight culture and then grown at 37 °C until an OD₆₀₀ of
0.4−0.6 was obtained. The cultures were transferred to ambient
temperature, and gene expression was initiated with the
addition of 1.0 mM isopropyl IPTG. Cells were harvested
after 18 h via centrifugation at 4 °C and suspended in 50 mM
HEPES (pH 7.5), 0.25 mM NaCl, and 0.1 mg/mL of PMSF.
Resuspended cells were lysed via multiple rounds of sonication,
and cell debris was removed via centrifugation at 4 °C. Nucleic
acids were removed from the supernatant solution with the
dropwise addition of 2% (w/v) protamine sulfate at 4 °C.
Protamine sulfate-bound DNA was removed by centrifugation.
Ammonium sulfate was added between 30 and 50% saturation,
and the precipitated protein was isolated by centrifugation. The
protein was resuspended in 20 mM HEPES (pH 7.5) and then
applied to a High Load 26/60 Superdex 200 gel filtration
column (GE Healthcare). Fractions containing the protein of
expected size were pooled and purified further by ion exchange
chromatography with a ResourceQ column (6 mL) at pH 7.5.
The gene coding for Bvu0222 (gi|149931251; UniProt:
A6KWY5) was determined to contain 19 rare codons using the
Rare Codon Calculator (RaCC) (nihserver.mbi.ucla.edu/
RACC/).¹⁶ A codon-optimized gene was purchased from
GenScript, which was ligated into a pUC57 cloning vector
containing Nde1 and HindIII restriction sites. The plasmid
harboring the gene of interest was digested with Nde1 and
HindIII at 37 °C for 3 h. The resulting gene was ligated into
pET-32a (+) (Novagen) and transformed into BL21(DE3)
cells via electroporation. The purification of Bvu0222 was
conducted in manner similar to that described for Bvu0219.
The isolation of uronate isomerase (URI) from Escherichia coli
and ^L-fucose dehydrogenase (FucD) from Burkholderia multi-
vorans (BmulJ_04919) was conducted as previously de-
scribed.^13,17
Measurement of Enzyme Activity. The enzymatic
hydrolysis of lactones by Bvu0220 was monitored with a
SpectraMax340 UV−visible using a colorimetric pH indicator
assay at 30 °C, as previously described.¹³ Protons released
during the hydrolysis of lactones were measured using the pH
indicator bromothymol blue. Reaction mixtures contained 2.5
mM MOPS (pH 7.1), 0.2 M NaCl, 0−0.5 mM lactone, and 0.1
mM bromothymol blue in a final volume of 250 μL. The final
concentration of DMSO was 1%. Changes in absorbance at 616
nm (ε = 1135 M⁻¹ cm⁻¹) were monitored in 96-well plates.
The background rate arising from acidification of the reaction
mixture by atmospheric CO₂ was subtracted from the initial
rates.
The dehydrogenase activities of Bvu0222 and Bvu0219 were
monitored by following the reduction of NAD⁺ or NADP⁺ at
340 nm (ε = 6220 M⁻¹ cm⁻¹) at 30 °C with a SpectraMax340
UV−visible spectrophotometer. Reaction assays for Bvu0219
were performed in 50 mM BICINE buffer (pH 8.0), varying
concentrations of substrate, and 0.5 mM NADP⁺. Reaction
assays for Bvu0222 were conducted in 50 mM phosphate buffer
at pH 7.5. Kinetic constants for NADP⁺ were determined with
200 μM substrate and variable concentrations of NADP⁺ (0−
1.5 mM).
The reductase activity of Bvu0222 was monitored using a
coupled assay system. The coupling system consisted of 8.0 μM
URI, ^D-galacturonate (0−4 mM), 50 mM phosphate buffer (pH
7.0), NADH (1.0 mM), and Bvu0222. The reactions were
allowed to incubate for 15 min in the absence of Bvu0222 at 30
°C to allow for the URI catalyzed isomerization of ^D-
galacturonate to ^D-tagaturonate. Reactions were initiated by
the introduction of Bvu0222 and monitored through the
oxidation of NADH at 340 nm at 30 °C, with a SpectraMax340
UV−visible spectrophotometer.
Data Analysis. The kinetic constants were determined from
a fit of the initial velocity data to eq 1 using SigmaPlot 9, where
v is the initial velocity, E_t is the total enzyme concentration, k_cat
is the turnover number, [A] is the substrate concentration, and
K_m is the Michaelis constant.
v/E_t = k_cat[A]/(K_m + [A])
(1)
Metal Analysis. The metal content of Bvu0220 and
Bvu0222 was determined using an Elan DRC II ICP-MS
instrument as previously described.¹⁸ Protein samples for ICP-
MS analysis were digested with HNO₃ and then refluxed for 30
min.¹⁹ All buffers were passed through a column of Chelex 100
(Bio-Rad) to remove trace metal contamination. EDTA and
1,10-phenanthroline (1.0 mM) were incubated with 1.0 μM
Bvu0220 in 50 mM buffer at various pH values ranging from 6
to 10 to remove divalent metal ions, as previously described.¹³
The following buffers were used: CHES (pH 6.0), HEPES (pH
7.0), BICINE (pH 8.0), and CHES (pH 9.0 and 10.0). The
effect of added divalent cations on the catalytic activity of
Bvu0220 was determined by supplementing Mn²⁺, Zn²⁺, Co²⁺,
Cu²⁺, or Ni²⁺ (0−500 μM) directly to the assay mixtures. The
purified enzyme was also incubated with 50−500 mol equiv of
these divalent cations for 24 h at 4 °C in 50 mM HEPES (pH
7.5) and subsequently assayed for catalytic activity.
Identification of Reaction Product of ^L-Galactose
Oxidation Catalyzed by Bvu0219. The product of the
reaction catalyzed by Bvu0219 was determined by ¹³C NMR
spectroscopy using a Bruker Avance III 500 MHz spectrometer
equipped with a 5 mm HCN cryoprobe. The reaction sample
contained 250 mM phosphate (pH 5.8), 10% D₂O, 10 mM
NAD⁺, 10 mM [¹³C-1]-L-galactose (Omicron Biochemicals)
and 10−50 μM Bvu0219 in a volume of 250 μL. The reaction
was initiated by the addition of Bvu0219 and terminated at 10
min by removal of the enzyme by passage through a 3 kDa
cutoff VWR centrifugal filter. The pH of the sample was
adjusted to 7.0 to facilitate the nonenzymatic transformation of
L-galactono-1,5-lactone to the thermodynamically more stable
L-galactono-1,4-lactone.
Hydrolysis of ^L-Galactono-1,5-Lactone by Bvu0220. L-
Galactono-1,5-lactone was identified as the preferred substrate
for Bvu0220 via ¹³C NMR spectroscopy. The reaction was
initiated by the addition of 50 μM Bvu0219 to a solution
containing 250 mM phosphate (pH 5.8), 10% D₂O, 10 mM
NAD⁺, and 10 mM [¹³C-1]-L-galactose. The reaction was
monitored by ¹³C NMR spectroscopy until the resonances for
the 1,4- and 1,5-lactones of ^L-galactose were approximately
equal. At this point, 1.0 μM Bvu0220 was added, and the ¹³C
NMR spectra were collected as a function of time.
Enzymatic Synthesis of Acid Sugars and Lactones.
The acid sugars of ^L-galactose and L-glucose were synthesized
enzymatically from ^L-galactono-1,4-lactone and L-glucono-1,5-
lactone using Bvu0220 as the catalyst. Reaction conditions were
as follows: 50 mM lactone, 50 mM carbonate buffer (pH 9.5),
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Scheme 1
Table 1. Catalytic Constants for Bvu0220, Bvu0219, and Bvu0222
enzyme
substrate
k_cat (s⁻¹
)
K_m (μM)
k_cat/K_m (M⁻¹ s⁻¹
)
a
Bvu0220
L-glucono-1,5-lactone (1)
L-galactono-1,4-lactone (2)
L-fucono-1,4-lactone (3)
4-deoxy-L-fucono-1,5-lactone (12)
L-xylono-1,4-lactone (5)
38
34
23
23
1
3
2
1
500 40
(8.0 0.5) × 10⁴
1950 310
1320 210
(1.8 0.2) × 10⁴
(1.8 0.2) × 10⁴
(7.2 0.8) × 10⁵
(9.3 0.4) × 10²
(5.0 0.3) × 10²
32
4
5.3 0.4
1.0 0.1
5500 550
1700 140
D-arabino-1,4-lactone (4)
b
Bvu0219
L-galactose (6)
21
1
109
ND
ND
ND
ND
4
(2.0 0.1) × 10⁵
(2.0 0.2) × 10²
(7.1 0.1) × 10¹
(3.4 0.1) × 10¹
(1.3 0.1) × 10¹
(8.0 0.4) × 10⁶
(9.0 0.1) × 10³
e
L-glucose (7)
ND
ND
ND
ND
22
D-arabinose (8)
L-fucose (9)
D-altrose (10)
NADP⁺ (with L-galactose)
NAD⁺ (with L-galactose)
1
1
3.0 0.5
25
3000 200
c
Bvu0222
4
L-galactonate (13)
L-gluconate (14)
L-fuconate
0.6 0.1
0.2 0.1
ND
36
3
(1.7 0.1) × 10
(3.9 0.6) × 10²
(2.0 0.1) × 10²
(1.6 0.2) × 10⁵
510 70
ND
d
D-tagaturonate (15)
90 0.6
550 50
a
b
Bromothymol blue pH indicator assay and MOPS (pH 7.1). 50 mM BICINE buffer (pH 8.0), varying concentrations of substrate and 0.5 mM
c
d
NADP⁺. 50 mM phosphate buffer (pH 7.5) varying concentrations of substrate and 0.5 mM NAD⁺. 50 mM phosphate buffer (pH 7.0) varying
e
concentrations and 1.0 mM NADH. ND, did not determine because the enzyme was not saturated at the highest substrate concentration employed.
and 20 μM Bvu0220 were incubated together overnight. 4-
Deoxy-^L-fucono-1,5-lactone was synthesized enzymatically from
4-deoxy-^L-fucose using FucD as previously described.¹³ The
reaction was conducted in 50 mM phosphate buffer (pH 7.0)
containing 15 mM 4-deoxy-^L-fucose, and 15 mM NAD⁺ in a
final volume of 1.0 mL for 20 min.
Sequence Similarity Network for cog3618. Approx-
imately 2000 proteins belonging to cog3618 were identified
from the NCBI protein database using the query “cog3618”.
The proteins within cog3618 were subjected to an all-by-all
BLAST at a specified E-value (10⁻⁵⁰, 10⁻⁶⁰, etc.) using the
NCBI standalone BLAST program. The BLAST files were
opened and visualized in the similarity network program
Cytoscape.^20,21
have been shown previously to hydrolyze γ- and δ-lactones of
acid sugars, Bvu0220 was incubated with a small library of 25
acid sugar lactones as a preliminary test of catalytic activity. Of
the compounds tested, hydrolysis was detected only with ^L-
glucono-1,5-lactone (1), ^L-galactono-1,4-lactone (2), L-fucono-
1,4-lactone (3), ^D-arabino-1,4-lactone (4), and L-xylono-1,4-
lactone (5). The structures of these compounds are illustrated
in Scheme 1. The activity of Bvu0220 was not affected by the
addition of chelating agents, or the addition of Mn²⁺, Zn²⁺,
Co²⁺, Cu²⁺, or Ni² directly to the assay mixture. From these
results, we concluded that Bvu0220 is not dependent on the
binding of divalent cations for catalytic activity and that the
function of this enzyme is to hydrolyze lactones of acid sugars.
The kinetic constants for the hydrolysis of lactones 1 through 5
by Bvu0220 are presented in Table 1. ^L-Glucono-1,5-lactone
was the best of these substrates with a value of k_cat/K_m of 8 ×
10⁴ M⁻¹ s⁻¹.
Functional Characterization of Bvu0219. The gene for
Bvu0219 is adjacent to the gene for Bvu0220. This protein is
currently annotated as an “oxidoreductase” from cog0667, and
the functionally characterized enzymes from cog0667 include
dehydrogenases for the oxidation of ^L-fucose and D-arabinose.
Bvu0219 also shares significant sequence identity (42−46%) to
L-galactose dehydrogenase from two plants species, ornamental
tobacco (Nicotiana langsdorffii x Nicotiana sandera) and
Arabidopsis thaliana. It was therefore predicted that Bvu0219
would oxidize a monosaccharide to the corresponding lactone
Multiple Sequence Alignment. FASTA sequence files
were obtained from the NCBI Protein database for Bvu0220,
LigI, and FucL. Multiple sequence alignments were prepared
using JalView 2.8.0.²²
RESULTS
■
Functional Characterization of Bvu0220. The gene
encoding Bvu0220 from B. vulgatus was cloned and expressed
in E. coli, and the protein purified to homogeneity. The as-
purified Bvu0220 contained ∼0.3 mol equiv of Mn²⁺, 0.1 mol
equiv of Fe²⁺, and 0.3 mol equiv of Ni²⁺. The metal ions were
removed by incubation of the enzyme with EDTA and o-
phenanthroline overnight. Since other enzymes from cog3618
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Scheme 2
and that the product of the reaction catalyzed by Bvu0219
would be the physiological substrate for the lactonase activity of
Bvu0220. Bvu0219 was screened against a substrate library of
23 commercially available pentose and hexose sugars by
following the reduction of NADP⁺ at 340 nm. Catalytic activity
was observed for L-galactose (6), L-glucose (7), D-arabinose (8),
L-fucose (9), and D-altrose (10) using NADP⁺ as the oxidant.
The structures of these compounds are presented in Scheme 2,
and the kinetic constants are presented in Table 1. ^L-Galactose
is the best substrate identified for Bvu0219 with a value of k_cat/
K_m of 2 × 10⁵ M⁻¹ s⁻¹. The rate constants for the other
substrates are reduced by more than 3 orders of magnitude.
Identification of the Initial Reaction Product of
Bvu0219. Previous reports have suggested that the reaction
product for the oxidation of ^L-galactose is L-galactono-1,4-
lactone (2) rather than L-galactose-1,5-lactone (11).²³⁻²⁶ L-
Galactose dehydrogenase activity has previously been reported
in plant species, where this reaction is important for the
biosynthesis of ascorbic acid.²⁷ It is likely that the initial
product is actually ^L-galactono-1,5-lactone (11) since the
pyranose form of L-galactose is the predominant configuration
in solution.²⁸ However, L-galactono-1,5-lactone (11) has not
been observed previously due to its chemical instability and
nonenzymatic rearrangement to ^L-galactono-1,4-lactone (2).
We therefore attempted to determine the structure of the initial
oxidation product in the reaction catalyzed by Bvu0219 by
NMR spectroscopy using [¹³C-1]-L-galactose. The enzymatic
reaction was conducted at pH 5.8 to help stabilize the initial
oxidation product.¹³
Figure 3. ¹³C NMR spectra for [¹³C-1]-L-galactose and the
nonenzymatic transformation of ^L-galactono-1,5-lactone (11) to L-
galactono-1,4-lactone (2). (A) The four ¹³C-resonances correspond to
the anomeric carbon for each of the four anomers of ^L-galactose (6).
Chemical shifts are as follows: α-pyranose (92.3 ppm), β-pyranose
(96.5 ppm), α-furanose (95.0 ppm), and β-furanose (101.0 ppm). (B)
(I) The carbonyl region of ^L-galactose (6) is presented at time 0. (II)
Bvu0219 added with ^L-galactono-1,5-lactone (11) as the predominate
species (174.1 ppm). The enzyme was removed and the pH adjusted
to 7. (III) The resonance signal for ^L-galactono-1,5-lactone decreases
as the signal for ^L-galactono-1,4-lactone (175.9 ppm) increases in the
absence of enzyme. (IV) After 10 min the predominant species is ^L-
galactono-1,4-lactone (2). (V) After 15 min all of the ^L-galactono-1,5-
lactone has been converted to ^L-galactono-1,4-lactone.
The ¹³C NMR spectrum for [¹³C-1]-L-galactose is presented
in Figure 3A. The four resonances correspond to C-1 for each
of the four anomers of ^L-galactose. The chemical shifts of the α-
and β-pyranose forms are observed at 96.5 and 92.3 ppm,
respectively. The α- and β-furanose anomers are found at 95.0
and 101.0 ppm, respectively. The anomeric ratios are consistent
with data reported by Angyal and Pickles: β-pyranose (64%), α-
pyranose (29%), β-furanose (4%), and α-pyranose (3%).²⁸
After Bvu0219 is added to a mixture of NAD⁺ and [¹³C-1]-L-
galactose at pH 5.8, a new resonance begins to appear at 174.1
ppm. Over a period of 15 min, the resonance at 174.1 ppm
diminishes and a new resonance begins to appear at 175.9
(Figure 3B). The resonance at 175.9 ppm is assigned to that of
L-galactono-1,4-lactone (2) based on a direct comparison with
the chemically synthesized material. The transient resonance
that appears at 174.1 ppm is that of ^L-galactono-1,5-lactone
(11). Therefore, the initial product of the reaction catalyzed by
Bvu0220 is L-galactono-1,5-lactone (11). This unstable product
is nonenzymatically converted to ^L-galactono-1,4-lactone (2)
with an estimated rate constant of ∼0.2 min⁻¹ at pH 7.0.
Identification of the Physiological Substrate for
Bvu0220. The best substrate for Bvu0219 is clearly ^L-galactose,
but the best substrate for Bvu0220 is not the corresponding L-
galactono-1,4-lactone (2). To determine if the best substrate
for Bvu0220 is actually the chemically unstable L-galactono-1,5-
lactone (11), Bvu0219 was incubated with [¹³C-1]-L-galactose
and NAD⁺ at pH 5.8, and the reaction was monitored via ¹³C
NMR spectroscopy (Figure 4). After 15 min the resonances for
both lactones were approximately equal in intensity (Figure
4C). Bvu0220 was then added to the reaction mixture, and the
¹³C NMR spectrum was monitored as a function of time
(Figure 4D). The resonance at 174.1 ppm, corresponding to ^L-
galactono-1,5-lactone (11), disappeared rapidly, and a new
resonance appeared at 179.4 ppm, which corresponds to the
hydrolysis product, ^L-galactonate (13). Similarly, when both
enzymes (Bvu0219 and Bvu0220) were added to a mixture of
NAD⁺ and [¹³C-1]-L-galactose at pH 5.8, the resonance for L-
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Figure 4. ¹³C NMR analysis of the reactions catalyzed by Bvu0219 and Bvu0220 utilizing [¹³C-1]-L-galactose as substrate. (A) The carbonyl region
of [¹³C-1]-L-galactose. (B) The predominate species after the addition of Bvu0219 is L-galactono-1,5-lactone (174.1 ppm, red asterisk). (C) 10 min
after the addition of Bvu0219 the resonances corresponding to C-1 of ^L-galactono-1,5-lactone and L-galactono-1,4-lactone (175.9 ppm, blue asterisk)
are approximately equal. At this point Bvu0220 was added to the reaction mixture. (D) 5 min after the addition of Bvu0220, ^L-galactono-1,5-lactone
has disappeared. A new resonance with a chemical shift of 179.4 ppm appeared, which corresponds to ^L-galactonate (green asterisk).
galactono-1,4-lactone (2) was not observed. The only
resonance that was observed was that for ^L-galactonate (13)
at 179.4 ppm (data not shown). We estimate by NMR
spectroscopy that Bvu0220 hydrolyzes ^L-galactono-1,5-lactone
(11) 300 times faster than ^L-galactono-1,4-lactone (2).
Therefore, the likely physiological substrate for Bvu0220 is ^L-
galactono-1,5-lactone (11) that results from the oxidation of ^L-
galactose (6) by Bvu0219 (Scheme 3).
experimentally determined catalytic function is LgnH (gi|
425703034, UniProt K7ZKU8) from Paracoccus sp. 43P, with a
sequence identity of 46%. The gene for LgnH is contained in an
operon for the catabolism of the rare sugar ^L-glucose. LgnH has
been reported to oxidize ^L-galactonate (13) and L-gluconate
(14) at approximately the same rate.²⁹ Bvu0222 catalyzes the
oxidation of ^L-galactonate (13), L-gluconate (14), and L-
fuconate (15); however, the value of k_cat/K_m for the oxidation
of ^L-galactonate (13) is 2 orders of magnitude greater than the
oxidation of ^L-gluconate (14) (Table 1). D-Arabinonate and L-
xylonate were also assayed for activity; however, no oxidation
was detected. The oxidation product of ^L-galactonate (13) by
Bvu0222 was confirmed to be ^D-tagaturonate (16). D-
Tagaturonate (16) was prepared by the isomerization of D-
galacturonate (17) by the enzyme uronate isomerase.¹⁷ The
kinetic constants for the reduction of D-tagaturonate (16) are
presented in Table 1, and the structures of compounds 13
through 17 are presented in Scheme 4.
Scheme 3
To further investigate the preferential hydrolysis of 1,5-
lactones by Bvu0220, 4-deoxy-^L-fucono-1,5-lactone (12) was
synthesized enzymatically using ^L-fucose (9) and L-fucose
dehydrogenase (FucD). This lactone is missing the hydroxyl
group at C-4 and therefore cannot rearrange to a 1,4-lactone.
The enzymatic product, 4-deoxy-^L-fucono-1,5-lactone (12), was
Scheme 4
1
confirmed through H NMR spectroscopy (data not shown).
The 4-deoxy-^L-fucono-1,5-lactone (12) was isolated, and the
kinetic constants for the hydrolysis by Bvu0220 were
determined at pH 7.1. The value of k_cat/K_m for the hydrolysis
of 4-deoxy-^L-fucono-1,5-lactone (12) is approximately an order
of magnitude greater than that for ^L-glucono-1,5-lactone (1)
and almost 2 orders of magnitude greater than for ^L-fucono-1,4-
lactone (3).
Functional Characterization of Bvu0222. The gene for
Bvu0222 is adjacent to Bvu0219 and Bvu0220, and this protein
is currently annotated as a Zn²⁺-dependent oxidoreductase
from cog1063. Functionally characterized members of cog1063
include ^L-threonine dehydrogenase, L-idonate dehydrogenase,
and sorbitol dehydrogenase. The closest homologue with an
DISCUSSION
■
Novel Metabolic Pathway for L-Galactose. The three
enzymes from B. vulgatus examined in this study function to
form a previously unknown pathway for the metabolism of ^L-
galactose (6). The first enzyme in the pathway, Bvu0219,
preferentially oxidizes ^L-galactose (6) to L-galactono-1,5-lactone
(11) using NADP⁺ as the oxidant with a k_cat/K_m of >10⁵ M⁻¹
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Scheme 5
Scheme 6
Figure 5. Sequence alignment of Bvu0220, LigI (gi|374074685), and BmulJ_04915 (L-fucono-1,5-lactonase. Residues highlighted in maroon are
conserved active site residues important for catalysis. Black arrows represent β-strands that make up the (β/α)₈-barrel.
s⁻¹. The next best substrate, L-glucose (7), is oxidized 3 orders
of magnitude less efficiently. The ^L-galactono-1,5-lactone (11)
is chemically unstable and rapidly isomerizes to ^L-galactono-1,4-
lactone (2). We suggest that Bvu0219 be called ^L-galactose
dehydrogenase and that the corresponding gene be designated
as lgaA. In the subsequent step, Bvu0220 hydrolyzes ^L-
galactono-1,5-lactone (11) to ^L-galactonate (13). The substrate
specificity of Bvu0220 is broader than that of Bvu0219, but the
two 1,5-lactones (^L-glucono-1,5-lactone (1) and 4-deoxy-L-
fucono-1,5-lactone (12)) are hydrolyzed about an order of
magnitude faster than any of the 1,4-lactones, including ^L-
galactono-1,4-lactone (2). However, the clear preference for the
hydrolysis of ^L-galactono-1,5-lactone (11) by Bvu0220 was
demonstrated with NMR spectroscopy using Bvu0219 to
rapidly oxidize [¹³C-1]-L-galactose to L-galactono-1,5-lactone
(11). We suggest that this enzyme be named ^L-galactono-1,5-
lactonase and the corresponding gene be denoted as lgaB. In
the final step, Bvu0222 oxidizes ^L-galactonate (13) at C-5 to
form ^D-tagaturonate (16). We propose that Bvu0222 be called
L-galactonate dehydrogenase and the gene that encodes this
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protein be labeled as lgaC. The overall reaction pathway is
presented in Scheme 5.
share the same substrate profile as Bvu0222 (Table S3,
Supporting Information).
Metabolism of ^D-Tagaturonate. What is the probable fate
of ^D-tagaturonate? In bacteria such as E. coli, the keto group at
C2 of ^D-tagaturonate (16) is reduced to form D-altronate (18)
by UxaB, followed by the UxaA catalyzed dehydration of ^D-
altronate to 2-keto-3-deoxygluconate (KDG) (19). This
product is then phosphorylated by KDG kinase (KdgK) to
form 2-keto-3-deoxygluconate-6-phosphate (20) and then
cleaved by an aldolase (KdgA) to generate pyruvate and D-
glyceraldehyde-3-phosphate. These steps are illustrated in
Scheme 6. In B. vulgatus, the four proteins needed for the
metabolism of ^D-tagaturonate can be identified with high
probability based on their sequence similarity to the
experimentally characterized enzymes from E. coli. Bvu3075 is
46% identical to D-tagaturonate reductase (UxaB), Bvu3053 is
46% identical to ^DD-altronate dehydratase (UxaA), Bvu3055 is
25% identical to KdgK and Bvu3056 is 33% identical to KdgA.
Therefore, it appears that B. vulgatus can metabolize ^L-galactose
to pyruvate and ^D-glyceraldehyde by a pathway that consists of
seven steps.
Bvu0219 and Other Enzymes in cog0667. Experimen-
tally verified members of cog0667 include the following
enzymes: ^L-glyceraldehyde phosphate reductase, D-arabinose
dehydrogenase, ^L-fucose dehydrogenase, and L-galactose
dehydrogenase.^24,30−32 As previously mentioned, Bvu0219
shares approximately 42% sequence identity with L-galactose
dehydrogenase from A. thaliana. We have predicted that at least
35 proteins in the NCBI protein database share the same
substrate profile as Bvu0219. This prediction is based on
significant sequence identity (>40%) and if the protein of
interest is encoded adjacent to homologues of Bvu0220 and
Bvu0222.
Bvu0220 and Other Enzymes in cog3618. We have
previously determined the three-dimensional structures of two
enzymes from cog3618, FucL (PDB id: 4DNM) and LigI (PDB
id: 4D8L). LigI catalyzes the hydrolysis of 2-pyrone-4,6-
dicarboxylate in the degradation of lignin. Bvu0220 shares
approximately 28% and 15% sequence identity with FucL and
LigI, respectively. Despite the relatively low sequence identity
to other members of cog3618, Bvu0220 conserves important
catalytic active site residues (Figure 5). These include the HxH
motif from β-strand 1, histidine from β-strand 6, arginine from
β-strand 4, and aspartate from β-strand 8. A total of 12 proteins
in the SSN for cog3618 (Figure 2) are predicted to share the
same substrate profile as Bvu0220. In addition, there are
approximately 35 proteins in the NCBI protein database (not
represented in the SSN) that are predicted to share this
substrate profile (Table S1, Supporting Information).
Bvu0222 and Other Enzymes in cog1063. Cog1063
contains primarily oxidoreductase enzymes including ^D-glucose
dehydrogenase, ^L-idonate dehydrogenase, L-arabinitol dehydro-
genase, ^L-threonine dehydrogenase, D-xylulose dehydrogenase,
sorbitol dehydrogenase, and ^L-gluconate dehydrogenase.³³⁻³⁹
As mentioned, the closest homologue of verified function is L-
gluconate dehydrogenase (LgnH) from Paracoccus sp. 43P,
which shares 46% sequence identity. LgnH was reported to
oxidize both L-gluconate and L-galactonate with k_cat/K_m values
> 10⁴ M⁻¹ s⁻¹. Conversely, Bvu0222 oxidizes L-galactonate with
a k_cat/K_m value approximately 2 orders of magnitude greater
than that for ^L-gluconate. As many as 35 protein sequences
have been identified within the NCBI database and predicted to
Metabolic Pathways for ^L-Galactose. L-Galactose is most
notable as an intermediate in the biosynthesis of ascorbic acid
in higher plants. For ascorbic acid biosynthesis, ^L-galactose is
produced through a series of reactions, beginning with ^D-
glucose-6-phosphate, which is ultimately converted to GDP-^D-
mannose. GDP-^D-mannose is then transformed to GDP-L-
galactose through epimerization at C3 and C4 of the sugar
moiety. Phosphorolysis of this product yields GDP and ^L-
galactose-1-phosphate, which is subsequently dephosphorylated
to ^L-galactose.²⁷ L-Galactose was first isolated from flaxseed oil
in 1903, and it was later identified to be a component of certain
pectins.⁴¹ Since then, L-galactose has been identified as a
component of agar, galactagen, agaropectin, and rhamnoga-
lacturonan II (RG-II).⁴¹ RG-II is a structural component of
plant cell walls, which makes up approximately 10% of the total
pectin in the biosphere. 6-Deoxy-^L-galactose (L-fucose) is a
known component of RG-II. It has recently been discovered
that ^L-galactose is naturally substituted for L-fucose in RG-I.⁴¹
For example, 24% of RG-II in red wine and 14% in carrots
(Daucus carota) is substituted with ^L-galactose.
This is the first pathway described for the transformation of
L-galactose to D-tagaturonate. Bioinformatics analysis reveal this
pathway to be prevalent in many Bacteroides species as well as
in other gut microbes, such as Paraprevotella clara, Para-
bacteroides goldsteinii, Paraprevotella xylaniphila, and Para-
bacteroides sp. CAG:409. In addition to gut microbes, the
pathway is found in Prevotella paludivivens and Proteiniphilum
acetatigenes isolated from a rice field in Japan and brewery
wastewater, respectively.
Discovery of Novel Metabolic Pathways. In this
investigation we identified and characterized a novel pathway
for the metabolism of ^L-galactose in bacteria that reside within
the human gut. This discovery was initiated by the
comprehensive application of bioinformatics and sequence
similarity networks for the identification of enzymes of
unknown function that are homologues to previously
characterized lactonases from the amidohydrolase superfamily
in cog3618. The gene for one of these enzymes of unknown
function, Bvu0220, was found clustered in an apparent operon
for carbohydrate metabolism. The catalytic properties of this
enzyme were elucidated through the utilization of a small, but
focused, library of potential sugar lactones. Sequence similarity
networks and small physical libraries of potential substrates
were strategically utilized to identify substrate profiles for two
other enzymes of unknown function in this putative operon for
the metabolism of ^L-galactose. Similar strategies can be readily
applied in a broader effort to annotate previously uncharac-
terized metabolic pathways.
ASSOCIATED CONTENT
■
S
* Supporting Information
Tables S1, S2, and S3. This material is available free of charge
via the Internet at http://pubs.acs.org.
AUTHOR INFORMATION
■
Corresponding Author
*Telephone: 979-845-3373; e-mail: raushel@tamu.edu.
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F. M. (2013) Discovery of an L-fucono-1,5-lactonase from cog3618 of
the amidohydrolase superfamily. Biochemistry 52, 239−253.
(14) Xiang, D. F., Kolb, P., Fedorov, A. A., Xu, C., Fedorov, E. V.,
Narindoshivili, T., Williams, H. J., Shoichet, B. K., Almo, S. C., and
Raushel, F. M. (2012) Structure-based function discovery of an
enzyme for the hydrolysis of phosphorylated sugar lactones.
Biochemistry 51, 1762−1773.
Funding
This work was supported in part by the Robert A. Welch
Foundation (A-840) and the National Institutes of Health (GM
71790 and GM 94662).
Notes
The authors declare no competing financial interest.
(15) Savitsky, P., Bray, J., Cooper, C. D. O., Marsden, B. D., Mahajan,
P., Burgess-Brown, N. A., and Gileadi, O. (2010) High-throughput
production of human proteins for crystallization: The SGC experience.
J. Struct. Biol. 172, 3−13.
(16) Schenk, P. M., Baumann, S., Mattes, R., and Steinbiss, H. H.
(1995) Improved high-level expression system for eukaryotic genes in
Escherichia coli using T7 RNA polymerase and rare ArgtRNAs.
BioTechniques 19, 196−180.
(17) Williams, L., Nguyen, T., Li, Y. C., Porter, T. N., and Raushel, F.
M. (2006) Uronate isomerase: a nonhydrolytic member of the
amidohydrolase superfamily with an ambivalent requirement for a
divalent metal ion. Biochemistry 45, 7453−7462.
(18) Hall, R. S., Fedorov, A. A., Marti-Arbona, R., Fedorov, E. V.,
Kolb, P., Sauder, J. M., Burley, S. K., Shoichet, B. K., Almo, S. C., and
Raushel, F. M. (2010) The hunt for 8-oxoguanine deaminase. J. Am.
Chem. Soc. 132, 1762−1763.
(19) Hall, R. S., Agarwal, R., Hitchcock, D., Sauder, J. M., Burley, S.
K., Swaminathan, S., and Raushel, F. M. (2010) Discovery and
structure determination of the orphan enzyme isoxanthopterin
deaminase. Biochemistry 49, 4374−4382.
(20) Atkinson, H. J., Morris, J. H., Ferrin, T. E., and Babbitt, P. C.
(2009) Using sequence similarity networks for visualization of
relationships across diverse protein superfamilies. PLoS One 4, e4345.
(21) Smoot, M. E., Ono, K., Ruscheinski, J., Wang, P.-L., and Ideker,
T. (2011) Cytoscape 2.8: new features for data integration and
network visualization. Bioinformatics 27, 431−432.
(22) Waterhouse, A. M., Procter, J. B., Martin, D. M. A., Clamp, M.,
and Barton, G. J. (2009) Jalview version 2a multiple sequence
alignment editor and analysis workbench. Bioinformatics 25, 1189−
1191.
(23) Zhu, Y., and Lin, E. C. (1987) Loss of aldehyde dehydrogenase
in an Escherichia coli mutant selected for growth on the rare sugar ^L-
galactose. J. Bacteriol. 169, 785−789.
(24) Gatzek, S., Wheeler, G. L., and Smirnoff, N. (2002) Antisense
suppression of ^L-galactose dehydrogenase in Arabidopsis thaliana
provides evidence for its role in ascorbate synthesis and reveals light
modulated l-galactose synthesis. Plant J.: Cell Mol. Biol. 30 (5), 541−
553.
(25) Mieda, T., Yabuta, Y., Rapolu, M., Motoki, T., Takeda, T.,
Yoshimura, K., Ishikawa, T., and Shigeoka, S. (2004) Feedback
inhibition of spinach ^L-galactose dehydrogenase by L-ascorbate. Plant
Cell Physiol. 45, 1271−1279.
(26) Momma, M., and Fujimoto, Z. (2013) Expression, crystallization
and preliminary X-ray analysis of rice ^L-galactose dehydrogenase. Acta
Crystallogr. 69, 809−811.
(27) Imai, T., Ban, Y., Terakami, S., Yamamoto, T., and Moriguchi, T.
(2009) l-Ascorbate biosynthesis in peach: cloning of six l-galactose
pathway-related genes and their expression during peach fruit
development. Physiol. Plant. 136, 139−149.
ABBREVIATIONS
■
AHS, amidohydrolase superfamily; LigI, 2-pyrone-4,6-dicarbox-
ylate; FucL, ^L-fucono-1,5-lactonase; FucD, L-fucose dehydro-
genase; SSN, sequence similarity network; IPTG, isopropyl β-
D-1-thiogalactopyranoside; PMSF, phenylmethylsulfonyl fluo-
ride; KDG, 2-keto-3-deoxygluconate; KdgK, KDG kinase;
KdgA, 2-keto-3-deoxygluconate-6-phosphate aldolase
REFERENCES
■
(1) Xu, J., Mahowald, M. A., Ley, R. E., Lozupone, C. A., Hamady,
M., Martens, E. C., Henrissat, B., Coutinho, P. M., Minx, P., Latreille,
P., Cordum, H., Van Brunt, A., Kim, K., Fulton, R. S., Fulton, L. A.,
Clifton, S. W., Wilson, R. K., Knight, R. D., and Gordon, J. I. (2007)
Evolution of symbiotic bacteria in the distal human intestine. PLoS
Biol. 5, e156.
(2) Saitoh, S., Noda, S., Aiba, Y., Takagi, A., Sakamoto, M., Benno, Y.,
and Koga, Y. (2002) Bacteroides ovatus as the predominant commensal
intestinal microbe causing a systemic antibody response in
inflammatory bowel disease. Clin. Vac. Immunol, 9, 54−59.
(3) Wexler, H. M. (2007) Bacteroides the good, the bad, and the
nitty-gritty. Clin. Microbiol. Rev. 20, 593−621.
(4) Xu, J., Bjursell, M. K., Himrod, J., Deng, S., Carmichael, L. K.,
Chiang, H. C., Hooper, L. V., and Gordon, J. I. (2003) A genomic view
of the human-Bacteroides thetaiotaomicron symbiosis. Science 299,
2074−2076.
(5) Hooper, L. V., Midtvedt, T., and Gordon, J. I. (2002) How host-
microbial interactions shape the nutrient environment of the
mammalian intestine. Annu. Rev. Nutr. 22, 283−307.
(6) Seibert, C. M., and Raushel, F. M. (2005) Structural and catalytic
diversity within the amidohydrolase superfamily. Biochemistry 44,
6383−6391.
(7) Ghodge, S. V., Fedorov, A. A., Fedorov, E. V., Hillerich, B., Seidel,
R., Almo, S. C., and Raushel, F. M. (2013) Structural and mechanistic
characterization of ^L-histidinol phosphate phosphatase from the
polymerase and histidinol phosphatase family of proteins. Biochemistry
52, 1101−1112.
(8) Hara, H., Masai, E., Katayama, Y., and Fukuda, M. (2000) The 4-
Oxalomesaconate hydratase gene, involved in the protocatechuate 4,5-
cleavage pathway, is essential to vanillate and syringate degradation in
Sphingomonas paucimobilis SYK-6. J. Bacteriol. 182, 6950−6957.
(9) Peng, X., Masai, E., Kitayama, H., Harada, K., Katayama, Y., and
Fukuda, M. (2002) Characterization of the 5-carboxyvanillate
decarboxylase gene and its role in lignin-related biphenyl catabolism
in Sphingomonas paucimobilis SYK-6. Appl. Environ. Microbiol. 68,
4407−4415.
(10) Hitchcock, D. S., Fedorov, A. A., Fedorov, E. V., Dangott, L. J.,
Almo, S. C., and Raushel, F. M. (2011) Rescue of the orphan enzyme
isoguanine deaminase. Biochemistry 50, 5555−5557.
(11) Halak, S., Basta, T., Buerger, S., Contzen, M., Wray, V., Pieper,
D. H., and Stolz, A. (2007) 4-sulfomuconolactone hydrolases from
Hydrogenophaga intermedia S1 and Agrobacterium radiobacter S2. J.
Bacteriol. 189, 6998−7006.
(28) Angyal, S. J., Bethell, G. S., Cowley, D. E., and Pickles, V. A.
(1976) Equilibria between pyranoses and furanoses. IV. 1-Deoxyhexu-
loses and 3-hexuloses. Aust. J. Chem. 29, 1239−1247.
(29) Shimizu, T., Takaya, N., and Nakamura, A. (2012) An L-glucose
catabolic pathway in Paracoccus species 43P. J. Biol. Chem. 287, 40448−
40456.
(30) Desai, K. K., and Miller, B. G. (2008) A metabolic bypass of the
triosephosphate isomerase reaction. Biochemistry 47, 7983−7985.
(31) Amako, K., Fujita, K., Shimohata, T. A., Hasegawa, E.,
Kishimoto, R., and Goda, K. (2006) NAD+-specific D-arabinose
dehydrogenase and its contribution to erythroascorbic acid production
in Saccharomyces cerevisiae. FEBS Lett. 580, 6428−6443.
(12) Hobbs, M. E., Malashkevich, V., Williams, H. J., Xu, C., Sauder,
J. M., Burley, S. K., Almo, S. C., and Raushel, F. M. (2012) Structure
and catalytic mechanism of LigI: insight into the amidohydrolase
enzymes of cog3618 and lignin degradation. Biochemistry 51, 3497−
3507.
(13) Hobbs, M. E., Vetting, M., Williams, H. J., Narindoshvili, T.,
Kebodeaus, D. M., Hillerich, B., Seidel, R. D., Almo, S. C., and Raushel,
4669
dx.doi.org/10.1021/bi500656m | Biochemistry 2014, 53, 4661−4670

Biochemistry
Article
(32) Yew, W. S., Fedorov, A. A., Fedorov, E. V., Rakus, J. F., Pierce,
R. W., Almo, S. C., and Gerlt, J. A. (2006) Evolution of enzymatic
activities in the enolase superfamily: L-fuconate dehydratase from
Xanthomonas campestris. Biochemistry 45, 14582−14597.
(33) Nobelmann, B., and Lengeler, J. W. (1995) Sequence of the gat
operon for galactitol utilization from a wild-type strain EC3132 of
Escherichia coli. BBA-Gene Struct Expr. 1262, 69−72.
(34) Angelov, A., Futterer, O., Valerius, O., Braus, G. H., and Liebl,
W. (2005) Properties of the recombinant glucose/galactose
dehydrogenase from the extreme thermoacidophile. Picrophilus
torridus. FEBS J. 272, 1054−1062.
(35) Smith, L. D., Budgen, N., Bungard, S. J., Danson, M. J., and
Hough, D. W. (1989) Purification and characterization of glucose
dehydrogenase from the thermoacidophilic archaebacterium Thermo-
plasma acidophilum. Biochem. J. 261, 973−977.
(36) DeBolt, S., Cook, D. R., and Ford, C. M. (2006) L-Tartaric acid
synthesis from vitamin C in higher plants. P Natl. Acad. Sci. USA 103,
5608−5613.
(37) Epperly, B. R., and Dekker, E. E. (1991) ^L-Threonine
dehydrogenase from Escherichia coli. J. Biol. Chem. 266, 6086−6092.
(38) Aguayo, M. F., Ampuero, D., Mandujano, P., Parada, R., Munoz,
R., Gallart, M., Altabella, T., Cabrera, R., Stange, C., and Handford, M.
(2013) Sorbitol dehydrogenase is a cytosolic protein required for
sorbitol metabolism in Arabidopsis thaliana. Plant Sci. 205, 63−75.
(39) Kim, B., Sullivan, R. P., and Zhao, H. M. (2010) Cloning,
characterization, and engineering of fungal L-arabinitol dehydro-
genases. Appl. Microbiol. Biotechnol. 87, 1407−1414.
(40) Anderson, E. (1933) The preparation of ^L-galactose from
flaxseed mucilage. J. Biol. Chem. 100, 249−253.
(41) Pabst, M., Fischl, R. M., Brecker, L., Morelle, W., Fauland, A.,
Kofeler, H., Altmann, F., and Leonard, R. (2013) Rhamnogalacturonan
II structure shows variation in the side chains monosaccharide
composition and methylation status within and across different plant
species. Plant J.: Cell Mol. Biol. 76, 61−72.
4670
dx.doi.org/10.1021/bi500656m | Biochemistry 2014, 53, 4661−4670