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J. Biol. Chem., Vol. 275, Issue 40, 31121-31127, October 6, 2000
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From the Department of Physiology, University of Texas-Southwestern
Medical Center, Dallas, Texas 75390-9040
Received for publication, April 7, 2000, and in revised form, June 7, 2000
MscL, a mechanosensitive channel found in many
bacteria, protects cells from hypotonic shock by reducing intracellular
pressure through release of cytoplasmic osmolytes. First isolated from Escherichia coli, this protein has served as a model for
how a protein senses and responds to membrane tension. Recently the structure of a functionally uncharacterized MscL homologue from Mycobacterium tuberculosis was solved by x-ray diffraction
to a resolution of 3.5 Å. Here we demonstrate that the protein forms a
functional MscL-like mechanosensitive channel in E. coli
membranes and azolectin proteoliposomes. Furthermore, we show that
M. tuberculosis MscL crystals, when re-solubilized and
reconstituted, yield wild-type channel currents in patch clamp,
demonstrating that the protein does not irreversibly change
conformation upon crystallization. Finally, we apply functional clues
acquired from the E. coli MscL to the M. tuberculosis channel and show a mechanistic correlation between
these channels. However, the inability of the M. tuberculosis channel to gate at physiological membrane tensions,
demonstrated by in vivo E. coli expression and in
vitro reconstitution, suggests that the membrane environment or
other additional factors influence the gating of this channel.
Mechanosensation, the process of detecting a mechanical stimulus,
is integral to a vast array of sensory systems. These sensory systems
encompass a span from hearing to proprioception to osmoregulation, yet
are among the least understood at the molecular level. The advent of
patch clamp analysis revolutionized the study of mechanosensitive systems. Electrophysiological evidence quickly implicated
mechanosensitive (MS)1
channels as the primary transducing element in these sensory cascades
(1, 2). Soon, MS channel activities had been detected in more than 30 cell types (3) including embryonic chick skeletal muscle cells and frog
muscle, where they were first discovered (4, 5).
These systems have remained veiled because of the very low abundance of
the channels or the tissues that bear them. In addition, the lack of
tangible ligands for MS channels has hampered efforts to enrich a
population by biochemical means. This veil began to lift when MS
channel activities were detected in bacteria. Early studies in
Escherichia coli giant spheroplasts (6) showed MS conductances, and soon similar activities were detected in giant protoplasts of Bacillus subtilis (7) and Streptococcus
faecalis (8). At least three MS activities are now recognized in
E. coli: MscL (mechanosensitive
channel large conductance), MscS (Msc
small), and MscM (Msc mini) (9). Several
studies support a role for these bacterial MS channels in
osmoregulation, serving as "emergency relief valves" in response to
acute hypotonic shock (10-12).
Previously it was demonstrated that a 136-amino acid protein from
E. coli formed a homo-multimeric membrane-bound complex that
correlated with the large membrane conductance (13-15). This protein,
MscL, became the first MS channel to be cloned and subjected to
molecular dissection, presenting a simple, accessible system to assess
how tension in a lipid membrane can effect the gating of an MS channel
(16-24).
A great stride forward in our understanding of the MS phenomenon was
made as the crystal structure of a putative MscL homologue from
Mycobacterium tuberculosis (Tb-MscL) was solved to 3.5 Å (25). This structure agreed with earlier data in many important aspects
(24). Most importantly, the homomultimer was composed of
subunits bearing two transmembrane elements, with both termini residing
within the cytoplasm (13). Unfortunately, this homologue had not been
shown to encode an MS channel activity. Hence, it was unclear how much
of the knowledge gained about the functionally relevant residues and
domains of the E. coli model system would be applicable to
the structure derived from this putative orthologue.
Here we show by patch clamp analysis that the M. tuberculosis gene does indeed encode an MS channel activity.
Furthermore, some analogous mutations in the M. tuberculosis
channel lead to perturbation of channel gating as seen in the E. coli channel, strongly suggesting that these orthologues share a
common molecular mechanism for detecting and responding to membrane
tension. However, the insensitivity of the wild-type M. tuberculosis channel to membrane tension in the physiological
range, when expressed in heterologous systems, suggests differences in
environmental factors that normally contribute to the gating of this homologue.
Stocks and Cultures--
All mscL genes initially
were ligated into the multiple cloning site of the vector pBluescript
II (Stratagene, La Jolla, CA) for sequence verification and
amplification and subsequently moved to the expression vector pB10b
(26). The mscL-null E. coli strain PB104 (13) was
used to host the intermediate cloning steps and the expression
constructs. For whole-cell physiology experiments, E. coli
strains Frag1 (27) and its derivative MJF455
(
Growth curves were generated from cultures of E. coli MJF455
expressing the MscL protein in trans. Cultures were
inoculated from a single colony to 15 ml of LB plus ampicillin and IPTG
and grown as above for the duration of the experiment.
Gene Cloning and Site-directed Mutagenesis of Tb-MscL--
The
cloned wild-type M. tuberculosis mscL gene was a gift from
D. Rees (25). Manipulations by polymerase chain reaction used
Pfu DNA polymerase (Stratagene) under standard reaction
conditions (28), and sequences were confirmed by analysis of both
strands. The published sequence data were used to design
oligonucleotide primers that encompassed the open reading frame and the
native Shine-Delgarno sequence. Linkers XbaI (5') and
XhoI (3') were added to facilitate the directional cloning
of the fragment into pB10b. The oligonucleotide primers used were: 5'
linker, AGA TCT AGA TCT GCA GAA AGG ACA TCG CAT GCT CAA AGG, and 3'
linker CTC GAG CTC GAG GCT ATT GCG ATT CTG TGC. The construction of the
amino-terminal, deca-histidine-tagged protein and crystallization
procedure has been described previously (25).
Site-directed mutagenesis of Tb-mscL was accomplished
by polymerase chain reaction using Pfu DNA polymerase in a
modified mega-primer protocol (29). The mutating primers used are:
A20G, GCC GAT TAC CAC CCC GAC AGC CAG GTC; V21A, TGT GCC GAT TAC CGC CGC GAC AGC CAG; V21D, TGT GCC GAT TAC ATC CGC GAC AGC CAG; and G24S,
CGT GAA CGC TGT GCT GAT TAC CAC CGC.
Single-channel Analysis--
E. coli giant
spheroplasts were generated and used in patch clamp experiments as
described previously (6), with modifications (16, 30, 31). Excised,
inside-out patches were examined at room temperature under symmetrical
conditions using a buffer composed of 200 mM KCl, 90 mM MgCl2, 10 mM CaCl2,
and 5 mM HEPES adjusted to pH 6.0. Records were gathered at
Purified amino-terminal histidine-tagged Tb-MscL protein was
incorporated into synthetic azolectin membranes as described previously
(30, 31). For the reconstitution of the crystallized protein, a single
crystal was washed three times in the mother liquor and dissolved in a
low salt buffer (20 mM NaCl, 20 mM Tris, pH
7.5) with 0.05% dodecyl-
Desiccated liposomes were rehydrated for at least 2 h in Buffer A
(150 mM KCl, 0.1 mM EDTA, 10 µM
CaCl2, 5 mM HEPES, pH 7.2) to a lipid
concentration of 90 mg/ml. Blisters suitable for access by patch clamp
were induced in the liposomes by incubation in Buffer A plus 30 mM MgCl2. Excised air-cleared patches were
clamped at +20 mV (pipette) and examined at room temperature under
symmetrical conditions in the same buffer. Data were acquired as above.
Assay of in Vivo Channel Function by Hypotonic Shock--
A
severe hypotonic shock was employed to discriminate any potential
phenotypic rescue by mutant channels more sensitive than Eco-MscL.
Although this protocol resulted in very high mortality for the
experimental and control populations (see Table I), the data are
paralleled by results achieved with wild-type Eco-MscL and Tb-MscL
using a more mild shock.2
A fresh overnight culture of E. coli strain MJF455 was
diluted 1:100 to LB plus ampicillin (100 µg/ml) and grown with
shaking (250 rpm) at 37 °C to A600 = 0.4-0.5. The culture was then combined with one volume of pre-warmed
LB plus 100 µg/ml ampicillin, 2 mM IPTG, and 1 M NaCl (500 mM final concentration) and grown
for 1 h at 37 °C with shaking.
Hypotonic shock was effected by a 103-fold dilution into
sterile double-distilled H2O, whereas the control was
diluted into LB plus 500 mM NaCl (LB-500) followed by a
20-min incubation at room temperature. All samples were then diluted to
the appropriate density in LB-500 and spread on LB plates with
ampicillin. Viability following the osmotic shock was assessed by
viable plate count.
Expression of M. tuberculosis mscL Yields an MS Channel
Activity--
As shown in Fig.
1A, the Tb-MscL structural
gene yields a mechanosensitive channel activity when expressed in
E. coli spheroplasts; no such channel activity was observed
in the absence of expressed protein. The relatively short open time and
large conductance of this channel were similar to several other MscL
orthologues (26). However, the large degree of membrane tension
required for gating distinguishes this channel from most of the other
characterized MscL channels. Quantitatively, Tb-MscL requires about
twice the tension needed to gate the
E. coli MscL (Eco-MscL) as shown in Table I
(Threshold). This "stiffness" elevates the gating threshold of the channel to the average lytic limit of the spheroplast membrane (Table I), making acquisition of extended records extremely
difficult.
Previous studies show that Eco-MscL MS channels gate at lower membrane
tensions in azolectin membranes (32). It therefore seemed likely that
extended electrophysiological records for the Tb-MscL would be more
easily obtained using this approach. Hence, purified amino-terminal
polyhistidine tagged Tb-MscL (25) was reconstituted in azolectin
liposomes (Fig. 1B). As expected, longer electrophysiological traces were obtained allowing for a more detailed
analysis of the activity. Note that the observation of channel
activities similar to those seen in spheroplasts suggest that addition
of the polyhistidine tag does not substantially alter the protein
mechanistically. The channel conductance, like other orthologues (26),
was about 2 nanosiemens and non-rectifying under symmetrical
buffer conditions (Fig. 1D). However, similar to
observations made in E. coli spheroplasts, the reconstituted Tb-MscL channels still required more than twice the gating pressure seen for most other MscL orthologues when assayed by this technique. Although reconstituted Eco-MscL gates at less than 100 mm of Hg pipette
pressure (13, 32), Tb-MscL typically requires ~200 mm Hg (Fig.
1).
To determine if the process used for crystallization of the Tb-MscL
disrupted the native folding of the protein, crystals of the Tb-MscL
were resolubilized, functionally reconstituted, and examined by patch
clamp analysis. The electrophysiological behavior of these
reconstituted channels was indistinguishable from that of the purified
polyhistidine-tagged Tb-MscL protein (Fig. 1C). These
results indicate that the crystallization procedure does not
irreversibly change the conformation of the Tb-MscL channel.
An in Vivo Assay of MS Channel Function Corroborates
Electrophysiological Evidence--
To test the functional nature of
MscL channels in vivo, an assay was designed to characterize
the ability of expressed MS channels to rescue E. coli cells
from an acute hypotonic shock. This assay used the E. coli
strain MJF455 ( Probing Tb-MscL Structure by Site-directed Mutation--
Although
the electrophysiological data suggested that the Tb-MscL is
functionally related to the Eco-MscL, it was not clear if the two
shared a deeper structural similarity. A common structure would imply a
common mechanism; mutations that make the Tb-MscL channel more
structurally similar to the Eco-MscL channel may also decrease its
gating threshold to approach that of the E. coli channel.
Furthermore, mutations that had been shown to affect the E. coli MscL (10, 16, 33) should yield analogous effects when applied
to the Tb-MscL channel. Therefore, to mechanistically correlate the two
channels, Eco-MscL and Tb-MscL, we generated several such site-directed
mutations in Tb-MscL.
A previous random mutagenesis study identified several mutations within
the Eco-MscL channel that, when expressed in E. coli, led to
a slow or no growth gain-of-function phenotype and channels with lower
gating thresholds in patch clamp (10, 16, 33). To determine if similar
lesions would change the gating properties of the Tb-MscL, analogous
mutations were generated at two of these sites. The first site chosen
for substitution was Val-21, which corresponds to the Eco-MscL residue
Val-23. As observed in the Tb-MscL structure, this residue projects
into the most constricted region of the pore. Substitution of this
residue in the Eco-MscL with a glycine, alanine, or aspartate led to a
more sensitive channel that could evoke significant cell death when
expressed in E. coli (33). As seen in Fig.
2, a substitution of either a charge or a
smaller non-polar residue at valine 21 resulted in a Tb-MscL channel
activity with a markedly lower gating threshold (see "Experimental
Procedures" for the details of threshold determination). Replacement
of this valine with alanine lowered the gating threshold nearly 2-fold
compared with the wild-type Tb-MscL (Fig. 2, top; Table I)
and yielded channel kinetics with long open-dwell times similar to
those observed in Eco-MscL. Introduction of a charged residue,
aspartate, at this position lowered the gating threshold in a similar
fashion but altered the channel kinetics to dwell in a flickery
sub-conducting state (Fig. 2, middle; Table I). Both
mutations conferred a mild gain-of-function (GOF) phenotype when
expressed in E. coli (Fig. 3).
In contrast to the E. coli analogous mutation (33),
neither mutation led to a severe phenotype; the phenotype is primarily
observed in high density cultures. In addition, as depicted in Fig.
4, when host viability (black bars) is compared with the channel sensitivity (gray
bars), the Tb-MscL Val-21 mutants are also not competent for
rescue of the host cell. However, the ability of these mutations to
yield a more sensitive channel suggests that the Eco- and Tb-MscL share similar underlying molecular mechanisms for sensing and gating in
response to membrane tension.
Another site chosen was glycine 24. A substitution of serine for
glycine at the analogous site in E. coli MscL yielded a very severe GOF phenotype (33). Although, in the Tb-MscL channel, this
mutation did reduce the gating threshold appreciably (Fig. 2,
bottom; Table I), it did not perturb cell growth (Fig. 3). These results are corroborated by in vivo experiments that
show that not only did expression of this mutant in E. coli
not lead to a GOF phenotype but that this mutant was unable to rescue
the MJF455 host strain from hypotonic shock (Fig. 4; Table I).
In a previous study, glycine 22 of the E. coli MscL was
substituted with the full range of common amino acids (34). That study
found that placement of an alanine in this position led to a much
higher gating threshold. Interestingly, the wild-type Tb-MscL contains
an alanine at the corresponding position (Ala-20). Of the homologues
that had been assayed previously for MS channel activity (26), only the
MscL from Synechocystis contains an alanine rather than the
highly conserved glycine at this site. The Synechocystis
MscL is also the only other characterized homologue to have a gating
threshold significantly higher than the rest of the orthologues (26).
We therefore wanted to determine whether a single substitution of
glycine for alanine at position 20 would reduce the gating threshold of
the Tb-MscL channel. However, within the resolution of the assay, no
substantial changes in channel sensitivity were observed (Table I).
Furthermore, as seen in Fig. 4 and in agreement with the
electrophysiological data, the A20G mutant was unable to rescue the
host strain from hypotonic shock. Although the data suggest that the
pressure sensitivity of the A20G mutant is not statistically different
from that of the wild-type channel, the small population (n)
of events observed for the wild-type channel reserves the possibility
that the actual opening threshold is higher than that calculated. In
fact, comparison of the wild-type Tb-MscL threshold with that of the
A20G mutant shows that, at pressure levels at least 2.4 times the MscS
threshold, Tb-MscL A20G activity was observed in 80% of successful
patches as compared with only 15% for the wild-type channel. This
would be possible if the events observed represent a sub-population of
channels or channel openings that occurred at lower a membrane tension
than the average. This is especially likely given that the gating
threshold of these channels, particularly the wild-type, lies close to
the average lytic limit of the membrane.
Tb-MscL Encodes a MS Channel Activity Resembling the E. coli
MscL--
Although the Eco-MscL channel has been studied for some time
(6, 13, 15, 35, 36), only recently has the Tb-MscL channel emerged as a
model system (25). Although the solved structure was consistent with
models previously developed from biochemical, biophysical, and genetic
clues (13, 18, 22), there was no evidence that this homologue actually
encoded an MS channel activity. Such evidence was necessary before the
Tb-MscL structure could be used to direct experiments aimed at the
mechanism(s) of mechanosensitive channel gating. We therefore
demonstrated functional channel activity for the Tb-MscL using a
three-pronged approach. First, we patch-clamped E. coli
spheroplasts expressing the native Tb-MscL in a heterologous expression
system previously used for the study of other MscL orthologues (26).
Second, we reconstituted purified Tb-MscL protein into synthetic
azolectin liposomes for patch clamp analysis. And finally, we
re-solubilized Tb-MscL crystals and reconstituted the protein into
azolectin liposomes for electrophysiological characterization. All
three approaches unequivocally demonstrated that Tb-MscL is indeed a mechanosensitive channel. In addition, the latter observation demonstrates that the crystallization procedure does not irreversibly change the conformation of the Tb-MscL channel.
Although electrophysiological characterization of Tb-MscL in
E. coli spheroplasts proved to be extremely
difficult due to the very high pipette pressures required to gate this
channel, channel events that were observed demonstrated that the
channel is gated by membrane tension and has about the same conductance observed in other MscL orthologues (26). When reconstituted into
liposomes, the inherent compliance of the azolectin bilayer allowed
observation of extended channel records without patch rupture, nicely
corroborating the sparse data gleaned from spheroplasts. Even in the
liposome system, however, the gating pressures were ~2-fold higher
than those required to gate other MscL orthologues that have been
studied similarly (26).
Live-cell Physiology Studies Implicate Environmental Factors in the
Regulation of MS Channel Gating--
Recent works by several groups
demonstrate that mechanosensitive channels play a role in
osmoregulation by protecting the cell from acute hypotonic distress
(11, 12, 24, 37). Here, we have exploited this vital cell system to
develop an assay to canvass the ability of a given protein to protect
the cell from hypotonic shock. This assay provides a rapid, efficient
screen for MscL homologs and MS channels in general and permits the
discrimination of apparent orthologues that may have broadly different
properties in vivo. Using a strain deficient in both of the
predominant MS channels of the E. coli membrane, the
majority of MscS, and totality of MscL activities, we have shown that
expression of either E. coli or B. subtilis MscL
will rescue these cells from acute hypotonic shock. Both of these
channels have been shown previously to be very similar in both gating
threshold and conductance (26). These results show that not only will
re-expression of the native channel protect these cells but also that
orthologues with similar properties, even from a Gram-positive
organism, are competent to effect such a rescue.
In contrast, as is clearly apparent in Fig. 4, expression of the
Tb-MscL channel is not sufficient to rescue these cells, presumably
because the channel is not able to open before the cell envelope
bursts. We know from electrophysiological evidence that the Tb-MscL
channel is expressed and functional in the membrane of this strain;
therefore, the observed phenotype is probably a direct consequence of
the properties of the channel, i.e. its extremely high
gating threshold in these membranes.
The observed differences in gating behavior of these MS channels might
reflect not only the intrinsic properties of the channel protein but
also peculiarities of the native environment of the channels. For
instance, the Tb-MscL channel may have a much lower gating threshold
when expressed in M. tuberculosis membranes. Such a shift
could be due to the lipid environment or to diffusible modulators that
interact with the channels. Indeed, the marked conservation in portions
of the carboxyl-terminal region (26), which apparently plays no
measurable role in MS channel activity in vitro (16, 17,
35), invites such a speculation.
Mutagenesis Suggests That the Tb-MscL and the E. coli MscL Are
Structurally and Mechanistically Similar--
An alignment and
comparison of the Tb-MscL and Eco-MscL primary sequence shows that
these proteins are remarkably similar and share 37% identity (see
supplemental data for alignment), so it would be likely that the two
share similar secondary and tertiary structures. This likelihood was
functionally explored by generation of site-directed mutations at three
different residues of the Tb-MscL protein as shown in Figs. 4 and
5.
The A20G mutation was invoked because alignment of 15 MscL orthologues
showed nearly all bearing a glycine at the corresponding residue. A
deviation, also an alanine, was in the previously characterized Synechocystis orthologue. Notably, the opening threshold of
this channel is also 2-3-fold higher than the balance of the surveyed Eco-MscL-like orthologues (26). Furthermore, another study that focused
on the analogous residue in the E. coli channel showed that
the relative hydrophilicity of the resident amino acid affected the
gating threshold of the channel (34). Interestingly, when the glycine
of the E. coli channel was substituted with an alanine, the
mutant channel achieved the highest gating threshold of all mutants in
the series. The A20G substitution was made in the Tb-MscL channel in
order to address this apparent coincidence. Although a slight decrease
in gating threshold may have occurred, as indicated in Table I and Fig.
4, this one-step attempt to lower the gating threshold of the Tb-MscL
channel was unsuccessful. The A20G channel still required high pipette
pressures, like the wild-type Tb-MscL, to achieve the gating threshold
and was unable to rescue cells from hypotonic shock. Hence, the high
threshold for gating of the Tb-MscL channel cannot be attributed to
this single difference between proteins.
The three other site-directed mutants presented here were patterned
after lesions in the E. coli MscL channel that yielded the
GOF phenotype. These mutant channels, when examined by patch clamp,
were noted for their tendency to gate inappropriately or at lower than
usual membrane tensions. All three mutants represent the most severe
class recovered in the E. coli channel (33), but only the
V21X substitutions in the Tb-MscL channel led to detectable,
although mild, gain-of-function growth phenotypes (Fig. 3) when
expressed in E. coli. Although these Tb-MscL mutants did not
arrest growth, as observed with the Eco-MscL channel, the mature
colonies of these mutants were conspicuously less opaque than their
wild-type counterpart, and liquid cultures entered stationary phase at
lower densities than wild-type or non-induced strains (Fig. 3). Why
this phenotype is most pronounced at high density is, as yet,
unexplained but could be due to changes in lipid or cell wall
composition, sub-cellular localization, or other factors that are
present (or absent) primarily under these conditions. In contrast to
the V21X mutants, the G24S substitution increased the
channel sensitivity (Fig. 2) but did not confer a detectable
gain-of-function phenotype (Fig. 3). Although all of these
mutants had gating thresholds approaching that of E. coli, none of these mutants could effect a rescue from hypotonic shock (Fig. 4).
When records from the V21X mutants were studied, it was
noted that each mutant had a distinct behavior. Although both
substitutions led to a marked 2-fold reduction in the gating threshold,
a conservative substitution to alanine gave channels with wild-type
conductance but extended open-dwell kinetics. In contrast, substitution
by aspartate resulted in a noticeable perturbation of channel kinetics with an activity marked by many brief openings at a low probability of
opening (Po). This channel behavior appears to be a
response to the introduction of a charged residue, because this substitution is relatively conservative in terms of size.
Hydrophilicity, another distinction between these substitutions, has
been implicated as a critical factor in the behavior of other mutants.
A study that focused on the adjacent residue, glycine 22 in E. coli, noted a strong correlation between the hydrophilicity of the
residue and the gating threshold of the mutant channel (34). In
addition, a random mutagenesis study that screened for GOF mutants
found that 14 of 18 mutations were between amino acids 13 and 30 of the
Eco-MscL protein; all but one of these mutations were to more hydrophilic residues, and half were to charged amino acids (33).
Mutational Analysis of Tb-MscL Advances a Model for Channel
Gating--
The experimental observations suggest a model for MscL
channel gating that postulates a hydrophobic "lock" as the major
energy barrier between the closed and open conformations (20, 24, 25,
34). It is the transition of hydrophobic locking residues through an
exposed, aqueous state that defines this barrier. A likely candidate
for this aqueous environment is the vestibule of the opening channel.
This model predicts that the Tb-MscL valine 21 participates in this
lock. Consistent with this we find that Tb-MscL V21D, which adds a
charge within this lock (24), has a decreased energy barrier
(transition state), as demonstrated by the decreased open-dwell time;
once the open state is attained, the channel can more easily return to
the closed state, giving the activity a "flickery" nature. Note
that with the V21A substitution, both valine and alanine are
hydrophobic amino acids. Hence, the hydrophobic lock hypothesis alone
cannot predict how the energy barrier will be changed. For instance, an
analogous mutation in Eco-MscL leads to a flickery channel (33),
whereas for Tb-MscL it does not. However, the observation that the
Tb-MscL channel can become more sensitive to membrane tension without
significantly shortening the open dwell-time suggests that the closed
state of the V21A mutant can be destabilized without significantly
changing the energy barrier between closed and open states. The
apparent juxtaposition of these residues in the most constricted region of the closed channel (Fig. 5) implicates
the perturbation of van der Waal's interactions in the destabilization
of the closed state. The locations of the three mutated residues within
the tertiary structure of the Tb-MscL channel are depicted in Fig. 5.
These residues are clustered at an apparent convergence of the TM1
helices. Although the Ala-20 and Gly-24 residues form a girdle
surrounding the narrowest portion of the channel lumen, the Val-21
residues reach into the lumen, partially obstructing the pore. The
relative positions of these residues are paralleled by the severity of
the phenotype rendered by their mutation. The most severe substitutions
are, by far, at Val-21. The position of this residue and its
contribution to the channel sensitivity suggests a crucial role in
determining the gating transition energy barrier. Because similar
effects are seen when the analogous site is mutated in the E. coli MscL, it may be reasonable to designate this residue as the
"gate latch," controlling the earliest events of channel opening.
Future experiments on this region of the molecule will be focused on
understanding the cascade of events that culminate in the huge
open-pore conformation of MscL.
We thank Prof. Ian Booth for the kind gift of
E. coli strains Frag1 and MJF455 and Daniel Leong for
technical assistance. Furthermore, we are indebted to D. C. Rees,
G. Chang, and R. Spencer for gifts of DNA and Tb-MscL protein and
insightful discussion.
An important work (Maurer, J. A., Elmore,
D. E., Lester, H. A., and Dougherty, D. A. (2000) J. Biol.
Chem. 275, 22238-22244), published since the submission of
this manuscript, highlights additional gain-of-function mutants of the
Tb-MscL Channel.
*
This work was supported by American Heart Association Grant
9930193N and Robert A. Welch Foundation Grant I-1420.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Published, JBC Papers in Press, June 8, 2000, DOI 10.1074/jbc.M002971200
2
P. C. Moe and P. Blount unpublished results.
The abbreviations used are:
MS, mechanosensitive;
IPTG, isopropyl-
Correlating a Protein Structure with Function of a Bacterial
Mechanosensitive Channel*,
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
mscL::Cm, yggB) (12), were
utilized. Cultures were grown at 37 °C in Lennox Broth (LB) with
shaking at 250 rpm. For plasmid-bearing strains, ampicillin (100 µg/ml) was added, and expression was induced by addition of IPTG (1 mM) to mid-logarithmic phase cultures. Induced expression
times were 1 h for in vivo experiments and 2 h for
single channel analysis experiments.
20 mV for channel pressure response experiments and +30 mV to 50mV
for determination of the current-voltage relationship and
conductance. Data were acquired at a sampling rate of 20 kHz with a 5 kHz filtration using an AxoPatch 200B amplifier in conjunction with
Axoscope software (Axon). A piezoelectric pressure transducer (World
Precision Instruments) was used to measure the pressure response of the channels. The pressure threshold for activation of the Tb-MscL channel,
with respect to the activation threshold of MscS, was determined as
described previously (16). Briefly, the opening threshold for MscS was
defined as the pressure required to open simultaneously within 7 s
two or more channels. The MscL opening threshold was defined as the
pressure at which single channel openings were readily observed every
0.5 to 2 s.
-D-maltoside. Aliquots of the
purified protein were combined with azolectin vesicles at a mass ratio of 1:500 or greater and collected by a 20-min centrifugation at 30 p.s.i. in a Beckman Airfuge (Beckman Instruments). The pellet was
resuspended in 40 µl of 5% ethylene glycol, 10 mM MOPS,
pH 7.4, and desiccated overnight at 4 °C.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (19K):
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Fig. 1.
The M. tuberculosis mscL
gene product encodes a mechanosensitive channel activity
as assayed by patch-clamp. A, shown are traces from
wild-type Tb-MscL, expressed in E. coli spheroplasts,
examined in excised patches at 20mV. The closed state is defined as
c; openings of successive individual channels are designated
o1, o2 ... etc.
The activation pressure threshold (mm of Hg) is indicated above the
trace. B, a representative trace of enriched
polyhistidine-tagged Tb-MscL reconstituted into azolectin liposomes
using standard techniques and clamped at +20mV pipette. C,
Tb-MscL crystals were dissolved in a low salt buffer containing 0.05%
dodecyl--D-maltoside and reconstituted into azolectin
membranes and examined by patch clamp at +20-mV pipette. Note that
lower pressures are required to activate these channels in azolectin
membranes (B and C) as compared with spheroplast
membranes (A). D, the current-voltage
relationship of the Tb-MscL channel was determined from data obtained
from reconstituted purified protein (B).
Osmotic downshock survival and channel-gating threshold
mscL yggB) that, lacking
both of the major MS channels, is subject to lysis upon a hypotonic
shock. Previously, it was demonstrated that yggB, which
correlates with the majority of MscS activity, suppressed this lysis
(12). Here, as seen in Table I, we demonstrated that wild-type Eco-MscL
channels, when expressed in trans, also suppress this lysis;
note that the suppression is complete, giving viability similar to the
Frag1 parental. In contrast, the wild-type Tb-MscL was shown to be
incapable of effecting such a rescue. These data are consistent with
the electrophysiological characterization of this homologue; the very
high gating threshold of the Tb-MscL channel, resting close to the
average lytic limit of the spheroplast bilayer as noted in Table I,
apparently allows the cells to lyse before the channel is able to gate
and effect a rescue. However, an alternative explanation would be that
homologues from other species are inherently unable to suppress the
lysis phenotype. We therefore performed this experiment using an MscL
orthologue from B. subtilis (26) and supplemental data
showing an alignment of the three MscL proteins used in this study. The
MscL channel of B. subtilis (Bs-MscL), when assayed by patch
clamp, was shown to have properties very similar to the E. coli MscL including the amount of tension required to gate the
channel (26). When tested by this in vivo assay, the Bs-MscL
channel was found to suppress lysis similar to Eco-MscL, demonstrating
that an orthologue from a Gram-positive organism can substitute for the
normal in vivo function of Eco-MscL (Table I). Hence,
although some orthologues can functionally substitute as a conduit for
solute efflux upon hypo-osmotic shock the Tb-MscL channel cannot,
likely due to a significantly higher gating threshold.
View larger version (28K):
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Fig. 2.
Site-directed Tb-MscL mutants V21A, V21D, and
G24S show perturbation of pressure sensitivity. Mutants were
expressed in trans in an mscL-null E. coli strain and examined in patches excised from giant
spheroplasts. The traces represent patches clamped at +20 mV pipette.
To show the pressure traces (below each channel trace), channel
openings of MscS (*) and MscL ( 
) are shown as upward events. The
typical threshold pressure values for these mutant channels are shown
adjacent to each trace. Kinetic analysis (right) reveals a marked
difference in open-dwell time between the V21A mutant and the V21D and
G24S mutants. Greater than 1000 events were analyzed for each mutant
and fit to a three-state model.
View larger version (14K):
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Fig. 3.
Two Tb-MscL V21X mutants
confer a gain-of-function phenotype. The mutants V21A and V21D
lead the host to enter stationary-phase growth at 3-fold or 6-fold
lower culture density, respectively. All cultures were inoculated from
single colonies to LB-ampicillin plus IPTG (1 mM) to induce
expression. The data for the V21A ( 
) and V21D (
) mutants
represent the average of three experiments ±S.E. The growth curves
represented by Eco-MscL (
), pB10b (
), and G24S (
) are
characteristic of wild-type and non-induced growth (not shown). The
growth rate of all strains was similar until the deviation to
stationary-phase growth.
View larger version (23K):
[in a new window]
Fig. 4.
Correlation of MscL channel pressure
sensitivity in vitro and function in
vivo. Several MscL orthologues and selected mutants of
Tb-MscL were assayed for their ability to rescue an
mscL 
yggB double-null
strain of E. coli from acute osmotic down-shock (black
bars). Pressure sensitivity (gray bars) is expressed as
the ratio of MscS to MscL opening thresholds ±S.E. The figure presents
the primary data, tabulated in Table I, normalized to the Bs-MscL, an
empty vector control (not shown) for survival, and Bs-MscL and Tb-MscL
for the sensitivity data.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (44K):
[in a new window]
Fig. 5.
A structural depiction of Tb-MscL channel,
derived from x-ray crystallographic analysis, showing the three
substitution sites examined in this paper. The A20G
(yellow), substitution had a minimal effect on the channel
properties. In contrast, substitutions at Val-21 (green) and
G24S (red) had a profound effect on the channel opening
threshold, reducing it nearly 2-fold as compared with the wild-type
channel. A central role for the Val-21 residue is reinforced by its
location at the constriction of the channel and the close association
of the subunits. Shown are the individual atoms of each residue. The
approximate positions of the inner (lower) and outer
(top) leaflets of the cytoplasmic membrane is depicted in
the left panel of the figure.
ACKNOWLEDGEMENTS
Note Added in Proof
FOOTNOTES
The on-line version of this article (available at
http://www.jbc.org) contains a supplemental figure.
To whom correspondence should be addressed: Dept. of Physiology,
University of Texas-Southwestern Medical Center, 5323 Harry Hines Blvd.
Dallas, TX 75390-9040. Tel.: 214-648-8445; Fax: 214-648-4771; E-mail:
pbloun@mednet.swmed.edu.
ABBREVIATIONS
-D-thiogalactoside;
GOF, gain-of-function;
MOPS, 4-morpholinepropanesulfonic acid;
LB, Lennox Broth.
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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