Department of Microbiology, Immunology, and
Preventive Medicine, Iowa State University, Ames, Iowa
500111;
Department of Civil and
Environmental Engineering2 and
Department of Chemistry,3 University of
Kansas, Lawrence, Kansas 66045;
Department of Microbiology,
University of Iowa, Iowa City, Iowa 522424;
and
Department of Biological Sciences, Wichita State
University, Wichita, Kansas 672605
Two copper-binding compounds/cofactors (CBCs) were isolated from
the spent media of both the wild type and a constitutive soluble
methane monooxygenase (sMMOC) mutant, PP319 (P. A. Phelps et al., Appl. Environ. Microbiol. 58:3701-3708, 1992),
of Methylosinus trichosporium OB3b. Both CBCs are small
polypeptides with molecular masses of 1,218 and 779 Da for
CBC-L1 and CBC-L2, respectively. The amino acid
sequence of CBC-L1 is S?MYPGS?M, and that of
CBC-L2 is SPMP?S. Copper-free CBCs showed absorption maxima
at 204, 275, 333, and 356 with shoulders at 222 and 400 nm.
Copper-containing CBCs showed a broad absorption maximum at 245 nm. The
low-temperature electron paramagnetic resonance (EPR) spectra of
copper-containing CBC-L1 showed the presence of a copper
center with an EPR splitting constant between those of type 1 and type
2 copper centers (g
= 2.087, g = 2.42 G,
|A| = 128 G). The EPR spectrum of CBC-L2
was more complex and showed two spectrally distinct copper centers. One signal can be attributed to a type 2 Cu2+ center
(g = 2.073, g = 2.324 G,
|A| = 144 G) which could be saturated at higher
powers, while the second shows a broad, nearly isotropic signal near
g = 2.063. In wild-type strains, the concentrations of
CBCs in the spent media were highest in cells expressing
the pMMO and stressed for copper. In contrast to wild-type strains,
high concentrations of CBCs were observed in the extracellular fraction
of the sMMOC mutants PP319 and PP359 regardless of the
copper concentration in the culture medium.
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INTRODUCTION |
In methanotrophs, the relationship
between the concentration of copper and expression of the two different
methane monooxygenases (MMOs) is well characterized (8, 11, 45,
49, 50). Under low copper-to-biomass ratios, methane oxidation
activity is observed in the soluble fraction, and the enzyme is
referred to as the soluble methane monooxygenase (sMMO). At higher
copper-to-biomass ratios, methane oxidation activity is observed in the
membrane fraction, and the enzyme is referred to as the
membrane-associated or particulate methane monooxygenase (pMMO).
The polypeptides and structural genes for both enzymes have been
characterized (4, 18-22, 24, 25, 32, 34-40, 43-45, 47-49, 51,
62, 63). In addition to expression of the two MMOs, four other
physiological traits have been identified in cells expressing the pMMO
that are affected by the copper concentration in the culture medium. First, the concentration of copper in the culture media is directly related to pMMO activity in cell-free fractions, although the levels of
expression of pMMO polypeptides vary in different methanotrophs (1, 8, 30, 36, 50, 63). For example, the expression levels
of the three pMMO polypeptides in Methylococcus capsulatus Bath remained constant with varying copper concentrations (8, 36), whereas in Methylomicrobium albus BG8, the
expression level of the putative pMMO polypeptides increased with
increased copper in the culture medium (8). Second, the
concentrations of membrane-associated copper and iron show a
proportional increase as the copper concentration in the culture medium
is increased (36, 63). Third, the formation and level of
intracytoplasmic membranes in cells cultured in copper-supplemented media are dependent on the copper concentration in the culture media
(8, 11, 40, 48). Lastly, the Ks for
methane oxidation by pMMO is altered by the copper concentration in the
culture media (33a).
Berson and Lidstrom (1) have recently noted that in spite of
the central role of copper in the physiology of methanotrophs, the
mechanism(s) of copper acquisition remains vague. Although true, a few
studies have suggested the existence of a specific copper acquisition
system in M. capsulatus Bath and M. trichosporium OB3b. The first indication of a specific
copper uptake system was provided from phenotypic characterization of
the constitutive sMMO mutants (sMMOC) isolated by Phelps et
al. (42). Fitch et al. (17) found that in
M. trichosporium OB3b, these sMMOC
mutants were defective in copper uptake and showed preliminary evidence
for an extracellular copper-complexing agent. Working with the same
mutants, Téllez et al. partially purified this copper-complexing agent and determined that it was a small
molecule with a molecular mass of approximately 500 Da with an
association constant with copper of 1.4 × 1016
M
1 (55). Other evidence for a specific copper
uptake system was provided by the copper-binding cofactor (CBC) from
M. capsulatus Bath (63). During the
isolation of the pMMO from M. capsulatus Bath, CBC was
identified in association with the purified enzyme, in the washed
membrane fraction, and in the extracellular fraction. The CBC was
determined to be a small polypeptide with a molecular mass of 1,232 Da.
In M. capsulatus Bath, the cellular location of the CBC
varied depending on the copper concentration in the culture medium and
on the expression of the pMMO.
This paper ties together and extends these observations on specific
copper acquisition systems in M. trichosporium
OB3b and M. capsulatus Bath. Here we describe the
initial isolation and characterization of two copper-complexing agents,
called CBC-L1 and CBC-L2, from the
M. trichosporium OB3b wild type and
sMMOC mutant PP319. CBC-L1 from M. trichosporium OB3b was identical to the CBC previously
identified during the isolation of the pMMO from M. capsulatus Bath. This paper is also the first report of a second
CBC, CBC-L2, which may have been present as a contaminant in previous CBC preparations from M. capsulatus Bath.
One or both of the CBCs appear to be the same copper-complexing agent
partially purified by Téllez et al. (55). Lastly,
this report describes the effect of the copper concentration in the
culture medium on copper uptake, the expression of both MMOs, and
extracellular concentration of the CBC in wild-type and
sMMOC mutant strains of M. trichosporium OB3b.
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MATERIALS AND METHODS |
Organisms and cultivation.
Wild-type M. trichosporium OB3b and sMMOC mutants PP319 and
PP358 were grown at 30°C in nitrate mineral salts (NMS) medium (9, 10) plus 0.0 or 5.0 µM CuSO4 under an
atmosphere of 25% (vol/vol) methane and 75% (vol/vol) air. All cells
were cultured by semicontinuous methods using a 3-liter fermentor
(BIOFLO 3000; New Brunswick) sparged with methane and air in excess to
maintain ambient oxygen concentrations at 75% saturation in air. A
typical cell-culturing sequence involved culturing the cells in
copper-free medium (no copper added) to an optical density at 600 nm
(OD600) of between 0.6 and 0.7. The culture was then
diluted with fresh medium to an OD600 of approximately 0.15 and cultured again to an OD of 0.7 to 0.75 before harvesting of 90% of
the culture. At ODs of 0.6 and above, sMMO activities were measured
prior to harvesting.
After harvesting, the remaining 10% of the culture was diluted with
copper-free medium to an OD600 of about 0.15, and the concentration of copper in the culture medium was raised to 5.0 µM
for the subsequent copper-amended experiments. The culture was then
grown to an OD600 of 0.8 and diluted at least twice with medium containing 5 µM copper as described above prior to harvesting. The sMMO activity was monitored intermittently over this period. Wild-type cultures were harvested as before when no sMMO activity was
detected for one dilution/growth cycle. Alternately, mutant cultures,
which continually expressed sMMO activity in the presence of copper,
were typically harvested after two dilution/growth cycles.
M. capsulatus Bath was grown in nitrate mineral salts
medium plus 0 or 5 µM CuSO4 as previously described
(63).
Induction of CBC in wild-type strains.
Wild-type
M. trichosporium OB3b and M. capsulatus Bath were cultured in 12-liter fermentors sparged at
flow rates of 100 to 150 ml of methane per min and 2,000 to 2,500 ml of
air per min in NSM plus 5 µM CuSO4 at 30°C for
M. trichosporium OB3b or NMS plus 5 µM
CuSO4 at 42°C for M. capsulatus Bath.
When the culture reached an OD600 of 0.8 to 1.1, 8 liters
of the culture medium was removed and replaced with 8 liters of
low-copper medium. If the culture developed a visual yellow color when
cells reached an OD600 of 0.8 to 1.2, the cells were
harvested; if it did not, 8 liters of the culture was harvested and
replaced with 8 liters of low-copper medium. These procedures were
repeated until the medium developed a yellow color indicating the
presence of CBC in the extracellular fraction.
Harvesting media and cells.
Cells were harvested by
centrifugation for 30 min at 9,000 × g. The
supernatant was decanted, collected, and filtered through a
0.22-µm-pore-size filter. The filtrate was either lyophilized or
loaded on Sep-Pak cartridges (Millipore Corp., Bedford, Mass.) which
had been pretreated with 10 ml each of ethanol, dichloromethane, ethanol, and H2O. Both CBCs bound to the Sep-Pak cartridges
and were washed with 30 ml of H2O and 30 ml of 25 mM
Tris-HCl-1 M urea and eluted with 0.2% (vol/vol) trifluoroacetic
acid-99.8% (vol/vol) acetonitrile; the sample was then lyophilized.
Isolation of the CBC from spent medium. (i) Method I.
Lyophilized spent medium or lyophilized material extracted from Sep-Pak
cartridges was resuspended in a minimal volume of 20 mM Tris-HCl (pH
8.0) plus 3 M urea and loaded on a 2.6- by 60-cm Superdex 30 (Pharmacia, Uppsala, Sweden) column equilibrated with 20 mM Tris-HCl
(pH 8.0)-3 M urea. The yellow-colored sample migrated in three
fractions with molecular masses of approximately 2,000 (P1), 1,000 (P2), and 500 (P3) Da (Fig. 1). Each
colored fraction was concentrated in a stirred cell (YC05 filter) and individually loaded on a 2.6- by 60-cm Superdex 30 column equilibrated with 20 mM Tris-HCl (pH 8.0)-3 M urea. The CBCs were then loaded separately on a 1- by 10-cm 15RPC (Pharmacia) column equilibrated with
2 mM ammonium phosphate (pH 7.0) buffer. The sample was washed with
four column volumes of 2 mM ammonium phosphate (pH 7.0) buffer, and the
concentration of 2% (vol/vol) trifluoroacetic acid in acetonitrile
increased to 75% over a 200-ml linear gradient. The CBC eluted at
approximately 15% trifluoroacetic acid-2% acetonitrile mixture. The
sample was lyophilized, resuspended in a minimal volume of
H2O, and run a second time on the 1- by 10-cm 15RPC column.
The sample was then lyophilized and resuspended in H2O.
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FIG. 1.
Elution profile of the YM10 filtrate fraction separated
on a Superdex 30 column. Fractions were monitored at 280 nm ( ) and
for conductivity
(······).
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(ii) Method II.
Lyophilized spent medium or lyophilized
material extracted from Sep-Pak cartridges was resuspended in a minimal
volume of 20 mM Tris-HCl (pH 7.5)-50 mM KCl (buffer A) and loaded on a
2.6- by 20-cm Chelating Sepharose Fast Flow (FF) (Pharmacia Biotech) column equilibrated with buffer A. Prior to sample addition, the first
1.0 cm of the column was charged with CuCl2, followed by a
washing step with 2 column volumes of buffer A as described by Donat et
al. (13). CBC-L2 bound to the column, and the
sample was washed with 2 column volumes of buffer A. The concentration of buffer A plus 500 mM imidazole buffer (buffer B) was increased to
100% buffer B over a 500-ml linear gradient; CBC-L2 eluted at approximately 150 mM imidazole. The CBC column fractions were dialyzed and concentrated on a stirred cell (YC05 filter) and isolated
individually following the column steps described for method I.
Isolation of the CBC from the washed membrane fraction.
Both
CBCs were also extracted from the washed membrane by using a 0.1%
(vol/vol) HCl-N,N'-dimethyl formamide solution as
previously described (63). The extraction was repeated until
the extraction solution was clear. Following 0.1%
HCl-N,N'-dimethyl formamide extraction, the
N,N'-dimethyl formamide was evaporated under
vacuum and the sample was resuspended in a minimal volume of 20 mM
Tris-HCl (pH 8.0)-3 M urea and purified as described for method II.
Reconstitution of CBCs with copper.
As isolated by method
II, CBC-L2 contained two copper ions. CBCs isolated from
the spent medium by method I were copper free. To these samples, copper
was added as CuCl2 solutions (1 to 200 µM) by titration,
monitoring saturation by UV-visible absorption or electron paramagnetic
resonance (EPR) spectroscopy.
Enzyme activity.
sMMO activity was determined by using a
modified version of the naphthalene assay described by Brusseau et al.
(3), as follows. Between 3.0 and 20.0 ml of cells was
centrifuged for 15 min at 9,000 × g and resuspended in
10 mM phosphate buffer (pH 7.0) plus 10 mM formate to an
OD600 of between 0.6 and 0.7. Reaction mixtures contained
the cell suspension (2.5 ml) plus 50 µl of aqueous
o-dianisidine (5 mg/ml), and the reaction was initiated by
the addition of 50 mg of crushed naphthalene crystals to the sample
cuvettes. After naphthalene addition, the amended cuvette was hand
shaken aggressively for 10 s. Following stabilization of the
cell-naphthalene suspension (approximately 15 s), color formation
was monitored for 20 min at 525 nm. Activities were normalized to the
cell dry weight of the assay suspension.
Copper analysis.
Samples were collected for copper analysis
in conjunction with each sample-harvesting event. Sample preparation
for copper analysis was determined as described by Fitch et al.
(17) except that the incubation time of cells in the EDTA
extraction step was increased from 10 min to 3 h. Copper
concentrations were measured in triplicate, and coefficients of
variation were less than 0.1 in all experiments reported.
Mass spectroscopy.
Molecular masses of the CBCs were
determined by time-of-flight mass spectrometry on a Finnigan
(matrix-assisted laser desorption ionization [MALDI]) mass
spectrometer, using sinapinic acid as the matrix, and on a Finnigan
972947 electrospray mass spectrometer as previously described
(63). The molecular mass of CBC-L2 was also
determined by fast atom bombardment (FAB)-mass spectrometry in the
positive ion mode on a Finnigan TSQ-700, using a matrix of
3-nitrobenzyl alcohol in acetonitrile.
Amino acid and sequence analysis.
Amino acid analysis was
carried out with an Applied Biosystems 420A derivatizer coupled to an
Applied Biosystems 130A separation system. Samples were hydrolyzed in 6 M HCl for 1 h in a vacuum at 150°C. After hydrolysis, norleucine
was added as an internal standard.
Amino acid sequence analyses were performed on samples bound to either
Prosorb or Sequelon AA (Millipore) membranes by Edman degradation with
an Applied Biosystems 492 protein sequencer coupled to a 140C analyzer.
Other methods.
Optical absorption spectroscopy, EPR spectra,
labeling with [U-14C]acetylene, protein determinations,
cytochrome c oxidase activity, electrophoresis, and
immunoblot analysis were determined as previously described (12,
16, 26, 27, 30, 33, 63).
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RESULTS |
Isolation of CBC.
Culture conditions for optimal production
and purification of CBC-L1 and CBC-L2 from the
spent media or from the washed membrane fractions of M. trichosporium OB3b are described in Materials and Methods.
In wild-type M. capsulatus Bath and M. trichosporium OB3b, the concentration of CBC in the spent
media was highest in cells expressing the pMMO and stressed for copper.
Under these conditions, the spent media have a light yellow color due
to the high concentration of CBC. Once the cells switch from expression of pMMO to expression of sMMO, the spent media become clear and the
concentrations of CBCs in the spent media decrease by over 75% (Table
1).
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TABLE 1.
Copper localization, extracellular CBC concentrations,
and sMMO activities in wild-type and copper uptake mutants
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The two M. trichosporium OB3b sMMOC
mutants, PP319 and PP358, have proven to be useful for the isolation of
both CBCs. In contrast to the wild-type strains, the concentrations of
both CBCs in the culture media of the two sMMOC mutants did
not significantly change with the concentration of copper in the
culture media (Table 1). The concentrations of CBCs in the mutant
strains remained similar (65 to 80%) to the levels observed in
wild-type M. trichosporium OB3b cultured in low-copper medium just before induction of the sMMO. Interestingly, also in contrast to wild-type strains, high concentrations of copper-containing CBCs could be isolated from the spent
copper-containing media of the two sMMOC mutants PP319 and
PP358. In cells cultured in high-copper media, the high concentration
of copper containing CBC in the medium of the two sMMOC
mutants was evident by a bright yellow color. The color of both CBCs
became more intense with the binding of copper.
Separation of the concentrated spent media by gel filtration on a
Superdex 30 column resulted in three distinct yellow-colored fractions
with approximate molecular masses of 2,000 to 2,500, 1,000 to 1,500, and 500 to 750 Da (Fig. 1; Table 2). The
concentration of each fraction varied with the preparation, but the
fraction migrating in the 1,000- to 1,500-Da fraction (P2) was
consistently the largest. The low-molecular-weight fraction (P3) showed
high conductivity (Fig. 1). Each fraction was collected and purified by
a second gel filtration and by reverse-phase chromatography as
described in Materials and Methods.
All three yellow-colored fractions isolated from the spent medium from
M. trichosporium OB3b bound iron as well as
copper. Based on the molecular weights, N-terminal amino acid
sequences, and spectral properties, the P1 and P3 fractions from the
Superdex 30 column were determined to be breakdown products of the
CBC isolated from the P2 fraction, CBC-L1 (Table 2). This
statement is based on the following observations. First, the results of N-terminal amino acid analysis for the P1 fraction were identical to
those for CBC-L1; however, the subunit molecular mass of P1 was 122 Da less than that of CBC-L1. P1 migrated as a dimer
on Superdex 30 gel filtration columns. Second, the lower molecular mass
of P3 and the similarity in the first three amino acids from P3 to the
first three amino acids of CBC-L1 suggest that P3 was the
N-terminal fragment of CBC-L1 (Table 2).
Solution properties of the CBCs varied with metal binding and pH. Under
acidic conditions (pH values below 6.5), both CBCs were very soluble
and did not stick to reverse-phase columns such as 15RPC or
C18. However, at neutral or alkaline pH values, or with the
addition of copper, the CBCs showed a tendency to bind to most
low-pressure column resins tested in the absence of high (2 to 3 M)
concentrations of urea.
CBC-L2 was not readily identified during purification by
method I. CBC-L2 comigrates on Superdex 30 columns with the
P3 fraction. However, CBC-L2 could be separated from
CBC-L1, as well as from the P1 and P3 fractions, on
Chelating Sepharose FF columns due to the higher affinity of
CBC-L2 for this resin. In contrast to CBC-L1,
CBC-L2 eluted from the Chelating Sepharose column
along with two copper atoms per CBC-L2 atom. Both copper
ions remained bound to CBC-L2 during the subsequent
purification steps. Removal of the copper ions from the iminodiacetic
acid group on the Chelating Sepharose FF resin suggests the formation
constant for CBC-L2 is greater than 11.1 (28).
Amino acid analysis, N-terminal sequence analysis, mass
spectrometry, and nuclear magnetic resonance (NMR) spectroscopy.
The molecular masses of the CBC-L1 isolated fractions of
wild-type M. trichosporium OB3b or
sMMOC mutant PP319 were 1,218 ± 36 Da by electrospray
mass spectroscopy and 1,236 ± 43 Da by MALDI mass spectroscopy.
The reason for the variability has not been determined, but it may be
due to the binding of ions in solution. The molecular mass of
CBC-L2 was determined to be 779 Da by FAB mass
spectroscopy. The molecular masses obtained from CBCs isolated from
either the extracellular fraction or membrane fractions were within the
range of intertrial error, indicating that the same molecule was
isolated from both sources. In addition, the amino acid sequences
of CBC-L1 and CBC-L2 isolated from the washed
membrane fraction and from spent media were identical.
Amino acid analysis of CBC-L1 detected only the presence of
S, G, P, Y, and M in a molar ratio of 2S:1G:1P:1Y:2M. Assuming a
molecular mass of approximately 1,220 Da, the amino acid composition of
CBC was 2 mol of S, 1 mol of G, 1 mol of P, 1 mol of Y, and 2 mol of M
per mol of CBC-L1, which was consistent with the N-terminal amino acid sequence of S?1MYPGS?2M. Based
on the molecular mass of CBC-L1 and on the ratio of amino
acids obtained from amino acid analysis, the sequence of
CBC-L1 appears to be complete. The molecular mass
determined from the identified amino acid composition or N-terminal
sequence was approximately 40% less than that determined by mass
spectroscopy. The difference may reflect the presence of unidentified
amino acids indicated as ?1 and ?2 (Table 2), modified amino acids, or the presence of additional side groups which
are commonly observed in small metal-binding polypeptides (20, 45,
53, 57, 58). The N-terminal amino acid sequence of
CBC-L2, SPMP?S, differed from that of CBC-L1.
The amino acid compositions of both CBCs show some similarity,
especially in the multiple S, to the iron-chelating pseudobactins,
ferribactins, and pyoverdins produced by some species of
Pseudomonas and Azotobacter (20, 53,
55) but showed no sequence similarities. Unlike many
iron-binding polypeptides, the identified amino acids
of both CBCs are all L-amino acids (20, 53, 58).
The amino acid sequences of CBC-L1 and
CBC-L2 also showed no sequence similarities to MMO
polypeptides.
Preliminary NMR results for CBC and for the P3 fragment in aqueous
solution at pH 3 indicate that the unknown functional group or amino
acid designated ?1 gives rise to three singlet resonances of equivalent intensity in the aromatic region of the proton spectrum (30). One of these singlet resonances disappears from the
spectrum of P3 in D2O solution, indicating that this
resonance results from an exchangeable nitrogen-bound proton. These NMR
results are consistent with a nitrogen-containing aromatic moiety and confirm that the ?1 functional group of CBC-L1
is retained in the P3 fragment. The presence of an aromatic amino acid
is consistent with the UV-visible absorption spectra of
CBC-L1 and CBC-L2 as well as of the P1 and P3
fractions (see below).
Spectral properties.
As observed with M. capsulatus Bath (63), the CBC-L1 isolated
from the spent media of wild-type M. trichosporium OB3b was copper free. In the absence of
copper, the CBC-L1 was EPR silent. The UV-visible
absorption spectrum of copper-free CBC-L1 showed absorption
maxima at 204, 275, 333, and 356 nm, with shoulders at 222 and
400 nm (Fig. 2). Addition of
Cu2+ to CBC-L1 resulted in the increased
absorption in the 200- to 290-nm range (Fig.
3). Copper titration experiments
also demonstrated that CBC-L1 bound one copper ion.
Previous reports of the CBC from M. capsulatus Bath
binding two or three copper ions was an overestimate (63).
As demonstrated below, previous purification procedures of CBC from
M. capsulatus Bath contained contaminating levels of
CBC-L2, P1, and P3. These lower-molecular-mass
copper-binding polypeptides resulted in the overestimation in the ratio
of copper to CBC in the earlier report (63).
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FIG. 2.
Absorption spectra of the CBC-L1
isolated from spent media of M. trichosporium
OB3b (15-mmol sample in 10 mM PIPES buffer [pH 7.0]).
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FIG. 3.
Absorption spectra of CBC-L1 (a) with 15 µmol of CuCl2, plus 2 (b), 4 (c), 6 (d), 8 (e), 10 (f),
and 12 (g) µmol of CuCl2.
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The UV-visible spectral properties of CBC-L2 were identical
to those of CBC-L1. The major difference between the
absorption spectra of CBC from M. trichosporium
OB3b and M. capsulatus Bath (59) and the
spectra from the iron-binding polypeptides (53, 58, 59)
was the lack of the 400-nm absorption maximum. In addition, with the
exception of the CBC-L1 fragment isolated from the P3
fraction (Fig. 1), the CBC was not fluorescent, which is a common
property of iron-binding polypeptides (20, 53, 58, 59).
The low-temperature X-band EPR spectrum of copper-containing
CBC-L1 showed the presence of a copper center with a
splitting constant between those for type 1 and type 2 centers
(g = 2.087, g = 2.42 G,
|A| = 128 G [Fig.
4]) (24, 52, 57). The
hyperfine signals of copper-containing samples isolated from both P1
and P3 were similar to those for CBC-L1, but less
defined and complex. As isolated, CBC-L2 contains two spectrally distinct copper centers (Fig.
5). One signal could be attributed to a
type 2 Cu2+ center (g = 2.073, g = 2.324 G |A| = 144 G) and can be
saturated at higher powers at low temperatures (8 K), while the second
(g = 2.063) is not. The individual EPR spectra of
CBC-L1 and CBC-L2 from M. trichosporium OB3b were less complex than originally
reported for CBC from M. capsulatus Bath (63). The difference can be accounted for by the improved
purification procedure which separates the sample into four
distinct fractions, CBC-L1,
CBC-L2, P1, and P3. Previous purification methods used Bio-Gel P-2 (Bio-Rad Laboratories, Hercules, Calif.) gel filtration columns which enriched for CBC-L1 but failed in the
complete separation of CBC-L1 for the three other
peptides (63). A mixture of the four CBC fractions
provides some of the spectral complexity previously noted in the
CBC isolated from the M. capsulatus Bath membrane fraction (63).
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FIG. 4.
EPR spectrum of CBC-L1 from wild-type
M. trichosporium OB3b isolated from spent
medium. Operating parameters were as follows: temperature, 8 K,
modulation frequency, 100 kHz; modulation amplitude, 12.5 G; time
constant, 100 ms. The microwave settings were a frequency of 9.42 GHz,
a gain of 3.3, and a microwave power of 0.2 mW.
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FIG. 5.
EPR spectra for CBC-L2 fraction from
wild-type M. trichosporium OB3b isolated from
spent media. Operating parameters were as follows: temperature, 8 K;
modulation frequency, 100 kHz; modulation amplitude, 12.5 G; time
constant, 100 ms. The microwave settings were a frequency of 9.42 GHz,
a gain of 3.3, and power increases from 0.063 (top trace) to 0.2 (second from top trace), 2.02 (third from top trace), and 20 (bottom
trace) mW.
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Properties of the CBC in sMMOC mutants PP319 and
PP358 and wild-type M. trichosporium
OB3b.
Although the phenotype was not well defined, several
sMMOC mutants isolated by Phelps et al. (42) may
provide keys to the mechanism of copper acquisition in M. trichosporium OB3b. Fitch et al. (17)
demonstrated the presence of sMMO polypeptides in the
sMMOC mutants in cells cultured under high- and low-copper
conditions but failed to verify the absence of pMMO
polypeptides. To address this question, we examined the
expression of both MMOs in sMMOC mutants PP319 and PP358.
Figure 6 shows the sodium dodecyl sulfate (SDS)-denaturing gels of the membrane fractions isolated from the wild
type and sMMOC mutant PP319 from M. trichosporium OB3b cultured in high- and low-copper media
and treated with [U-14C]acetylene. The results
demonstrate the absence of the pMMO 27,000-Da acetylene-binding
polypeptide in PP319 cells even when cultured in high-copper
medium (Fig. 6, lane G). Similar results were obtained with
sMMOC mutant PP358. Immunoblot analysis of
sMMOC mutants PP319 and PP358 and wild-type M. trichosporium OB3b cultured in low- and high-copper media
with antibodies against either pMMO (Fig.
7) or sMMO (results not shown) confirmed
the constitutive expression of the sMMO polypeptide and little to no
expression of the pMMO polypeptide in both sMMOC
mutants.
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FIG. 6.
SDS-polyacrylamide gel electrophoresis of the membrane
fractions from copper uptake mutant PP319 (lanes B, C, G, and H) and
wild-type (lanes D, E, I, and J) M. trichosporium OB3b cells treated with
[U-14C]acetylene, using formate as the reductant. The
cells were cultured under high (5 µM)-copper (lanes B, D, G, and I)
or low-copper (lanes C, E, H, and J) conditions. Lanes A through F were
stained for total protein with Coomassie brilliant blue R-250, and
lanes G through J are phosphorescence images of
[U-14C]acetylene-labeled polypeptides exposed for
3.5 days on a storage phosphorescence imaging screen. Bio-Rad low-range
molecular mass standards are shown in lanes A and F.
|
|
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[in this window]
[in a new window]
|
FIG. 7.
Immunoblot analysis of copper uptake mutants 319 (lanes
B, C, I, and J) and 358 (lanes D, E, K, and L) and wild-type (lanes F,
G, M, and N) M. trichosporium OB3b cultured
under high (lanes B, D, F, I, K, and M)- and low (lanes C, E, G, J, L,
and N)-copper conditions. Lanes A through H are stained with Coomassie
brilliant blue R-250. Lanes I through N are probed with antibodies to
the 47,000-Da polypeptide of the pMMO.
|
|
Copper acquisition.
As previously observed by Fitch et al.
(17), sMMOC mutant strains PP319 and PP358 bound
less than 14% of the copper observed in the wild-type strains (Fig.
8). The copper uptake mutants also showed
an increase in the nonprecipitable copper in the culture media (Fig.
8). The copper-complexing agent described here can explain the
observations by Fitch et al. (17) and Téllez et al.
(55) of a potential copper-binding ligand. In this study, as
in these earlier studies, high concentrations of the copper-complexing agent or copper-free CBCs were observed in the spent media of cells
expressing the pMMO cultured in low-copper media, i.e., in
copper-stressed conditions. Cells cultured in high-copper media and
expressing the pMMO showed lower concentrations of CBC in the
extracellular media. In copper-containing solid media, the sMMOC mutants PP319 and PP358 produced a yellow halo around
each colony as a result of high concentrations of extracellular
copper-containing CBC.
View larger version (19K):
[in this window]
[in a new window]
|
FIG. 8.
Localization of copper in wild-type and
sMMOC mutant PP319 and PP358 cultures of M. trichosporium OB3b grown in culture medium containing
5 µM copper. Culture densities ranged from 300 to 330 mg (dry
weight)/liter. Nonprecipitable ( ) copper is copper
which is not cell associated; extractable copper ( )
is cell-associated copper which can be removed by NaEDTA washes;
perceptible ( ) copper is cell-associated copper which
cannot be removed by an NaEDTA wash.
|
|
| |
DISCUSSION |
In addition to regulating the expression of the two MMOs (11,
47, 52), the concentration of copper in the culture medium of
methanotrophs affects a number of physiological traits in cells expressing the pMMO, such as membrane development (8, 11, 41,
49), metal acquisition (1, 8, 37, 63), methane oxidation activity (11, 31, 37, 49, 63), expression of
membrane-associated polypeptides (2), and substrate
affinity (33a). The results presented here add the
extracellular concentration of the CBCs in M. trichosporium OB3b to this list. With respect to the
extracellular concentration of CBCs, the response of wild-type M. trichosporium OB3b was similar to that
observed in M. capsulatus Bath (63). The
highest concentrations of copper-free CBCs were observed in the spent
media of cells cultured under copper stress conditions just before the
cells switched from expressing the pMMO to expressing the sMMO. Cells
cultured in high-copper media and expressing the pMMO showed
lower concentrations of CBCs in the spent media. Under higher-copper
growth conditions, the majority of the CBCs were associated with
the membrane fraction and contained bound copper.
As previously observed by Phelps et al. (42), the
two sMMOC mutants PP319 and PP358 constitutively
expressed the sMMO regardless of the copper concentration in the
culture medium. The results presented here confirm the constitutive
expression of the sMMO and little to no expression of the three pMMO
polypeptides. With respect to the CBCs, the two
sMMOC mutants PP319 and PP358 differed from wild-type
M. trichosporium in a number of basic
properties. In contrast to wild-type M. trichosporium OB3b, the CBC isolated from the spent media
of sMMOC mutants cultured in high-copper media contained
copper. Also in contrast to the wild-type strain, no CBCs were detected
in the membrane fraction of sMMOC mutants regardless of the
culture conditions. The mutations in sMMOC mutants PP319
and PP358 appear to be in the regulation of either the pMMO, the pMMO
structural genes, or the copper acquisition system. Mutations in the
pMMO structural genes seem unlikely since all three structural genes of
the pMMO have been found in duplicate copies (51). Thus, the
mutation in PP319 and PP358 appears to be in the regulation of either
the two MMOs or a component of the copper acquisition system. The data
presented here indicate the mutations in PP319 and PP358 are in the
cellular mechanism utilized to bind copper-containing CBCs from the
extracellular fraction. Whether the pMMO itself is the
membrane-associated binding protein for copper-containing CBCs or
whether a different uptake protein is involved has not been
determined. Both mutants still acquire copper, but at only 15 to 20%
of the copper uptake level observed in wild-type M. trichosporium OB3b. With the exception of pMMO expression,
the mutants appear to show no negative effects of the lower
concentrations of cell-associated copper. For example, the terminal
oxidase activity in acetylene-treated PP319 or PP358, as measured by
ascorbate-N,N,N',N'-tetramethyl-p-phenylenediamine oxidase assay (results not shown), did not significantly differ from
that of acetylene-treated wild-type M. trichosporium OB3b expressing either MMO. Thus, CBCs do
not appear to be a general mechanism of copper acquisition but appear
to be associated with expression of the pMMO or a secondary copper
acquisition system.
Although the molecular structures of both CBCs are still under
investigation, the results of N-terminal amino acid sequencing have
provided some structural information about CBC-L1,
CBC-L2, and the P1 and P3 fragment
polypeptides. The fact that N-terminal sequencing proceeded
normally suggests that the unknown residues, denoted by ?'s in Table
2, contain amino acid-like structural features. The known
portion of the primary structure consists of amino acids that are
not usually associated with the formation of strong copper complexes,
although the thioether group of Met, the phenol and phenolate groups of
Tyr, and the hydroxyl group of Ser are all metal-coordinating ligands
(24, 52, 57). This observation suggests that the unknown
functional groups may be responsible for siderophore properties of both
CBCs while the native amino acids probably contribute to the formation
of a conformation that facilitates copper complexation. In particular,
the amino acid sequence YPG is known to promote 
-turn formation in
short linear peptides (14). A stable folded -turn
conformation would explain the pH-dependent changes in the
hydrophobicity observed during the chromatographic purification of CBC
as well as the peptide's resistance to carboxypeptidase.
The physiological role of the CBCs in M. trichosporium OB3b or M. capsulatus
Bath is still unknown. Both CBCs showed siderophore-like properties,
but this activity was observed only in association with
expression of the pMMO and may prove to be a major component of a
pMMO-specific copper acquisition system. On the other hand, one or
both CBCs may be more directly involved in methane oxidation by the
pMMO. On SDS-denaturing gels, the purified pMMO consists of three
polypeptides with molecular masses of 47,000, 27,000, and
25,000 Da (38, 63). Depending on the report, metal analysis of the purified enzyme from M. capsulatus Bath
indicates the purified enzyme contains 0 to 2 nonheme iron and 12 to 15 copper atoms (38, 63). Depending on the current pMMO models,
the catalytic site involves either both iron and copper or just copper
(39, 63, 64). Solubilization of pMMO polypeptides in
Triton X-100 or
3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate followed
by separation on a sucrose gradient revealed that two to four of the
copper atoms are tightly associated with the two larger pMMO
polypeptides, which are believed to be the site of methane
oxidation by the pMMO (12, 46, 63). The X-band EPR spectra
of the coppers associated with the two larger polypeptides is
consistent with Cu2+ in a square planar configuration in
which the copper is bound to three or four nitrogen atoms (24, 52,
57, 63). The 11 histidines residues in the two larger pMMO
polypeptides can account for the ligation of the 2 to 4 tightly
associated copper ions but not for the remaining 10 to 12 copper ions.
The remaining copper ions are loosely associated with the three larger
polypeptides (39, 63). Nguyen et al. (39)
propose that the remaining copper ions are "ligated to the nitrogen
atoms in the peptide backbone or other side chain ligands, such as
carboxylates of glutamates and aspartates." In contrast, results from
this laboratory have suggested the loosely bound copper ions are
associated with the CBCs. Copurification with the pMMO and the loss of
methane oxidation activity with the removal of the CBCs from the three larger pMMO polypeptides indicate the CBCs may be a cofactor of the pMMO (63). The CBC may also provide a secondary function such as enzyme stabilization, protection from oxygen radicals as
observed with other Cu complexes (15), maintaining a
particular redox state, or sequestering copper.
Currently studies are focusing on the properties and structures of the
two CBCs and their roles in copper acquisition in methanotrophs and in
the environmental biochelation of metals. With respect to biochelation
of metals, the properties of the two CBCs are similar to those of the
copper-complexing ligands described by Gordon (21) and may
represent the first isolated examples of organic chelators believed to
be responsible for copper complexation in marine environments (5,
6, 13, 21).
We thank A. B. Hooper (University of Minnesota), J. D. Semrau (University of Michigan), and D. J. Thiele (University of
Michigan) for useful discussions, R. Arnold (University of Arizona) for providing unpublished data, R. S. Hanson (University of Minnesota) for antibodies to the reductase and B subunits of M. trichosporium OB3b sMMO, and J. Nott (ISU Protein
Facility) for technical assistance.
This work was supported by Department of Energy
02-96ER20237 (A.A.D.), the Iowa State University Office of
Biotechnology (A.A.D.), an Iowa State University Professional
Advancement Grant (J.A.Z.), and National Science Foundation BES 9504383 (D.W.G. and A.T.).
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Abstract
Introduction
