(Received for publication, March 4, 1997, and in revised form, May 2, 1997)
From the Department of Molecular and Cell Biology,
University of California, Berkeley, California 94720-3206 and the
§ Department of Biochemistry, McGill University, Montreal,
Quebec H3G 1Y6, Canada
Ligands that are transported by the maltose transport system of Escherichia coli must first bind to the periplasmic maltose-binding protein (MBP). However, binding of a ligand does not always lead to its transport. As reported earlier, reduced or oxidized maltodextrins bind tightly to MBP but are not transported; some mutant MBPs, such as MalE254, bind maltodextrins tightly but cannot produce their transport. In this study, UV differential spectroscopy and fluorescence emission spectroscopy were used to study the modes by which various ligands bind to MBP. Maltose binding produced a red shift in the fluorescence emission spectrum of wild type MBP and a sharp hypochromatic trend below 265 nm in its UV spectrum (R mode (for red)). On the other hand, binding of reduced, oxidized, or cyclic maltodextrins produced a pronounced blue shift in the fluorescence emission spectrum of wild type MBP and a peak at about 250 nm in its UV difference spectrum (B mode (for blue). Binding of reducing maltodextrins to wild type MBP produced spectral changes that seemed to be a mixture of predominantly R mode binding and some B mode binding, whereas their binding to mutant MBP MalE254 produced changes indicative of pure B mode binding. Thus, the ligands that are bound exclusively via the B mode to either the wild type or MalE254 MBP are not transported.
Maltose and its higher homologs, the maltodextrins, are actively transported across the cytoplasmic membrane of Escherichia coli via a high affinity, periplasmic binding protein-dependent transport system (reviewed in Ref. 1). The periplasmic component of this transport system, the maltose-binding protein (MBP),1 is unusual in that it recognizes and tightly binds not only a disaccharide maltose, but also longer, linear maltodextrins and even cyclodextrins with Kd values in the micromolar range (2, 3). In wild type cells ligands must become bound to MBP to be transported (1). Ferenci et al. (4) showed that when the reducing glucose unit of linear maltodextrins were reduced, oxidized, or substituted, they were not transported into the cells, although they bound to MBP with good affinity. Similarly, "maltodextrin-negative" mutants of MBP show only a marginal decrease in affinity toward maltodextrins, yet they do not support the transport of maltodextrins in whole cells (5).
Because the ligand-binding site of MBP is exceptionally rich in
aromatic amino acid residues (6), binding induces major changes in both
the fluorescence (2) and UV absorption (7) spectra of MBP.
Interestingly, it has long been known that maltose binding produces a
red shift of the fluorescence emission spectrum of MBP, whereas binding
of the cyclic maltoheptaose (-cyclodextrin) produces a pronounced
blue shift (2). Similarly, binding of linear and cyclic maltodextrins
produced different changes in the UV absorption spectra of MBP (7). In
this study, we examined the binding of various ligands to MBP by
fluorescence and UV differential absorbance spectroscopy, to understand
why certain ligands are bound tightly to MBP but are not transported.
The results show that there are two ways in which a ligand can bind to
MBP, one causing a red shift of fluorescence emission spectrum of MBP
and a hypochromatic change in the region below 265 nm of its UV
absorption spectrum (R mode, for red) and another causing a
blue shift of the fluorescence emission spectrum of MBP and a peak
around 250 nm of its UV difference spectrum (B mode, for
blue). We found that those ligands that bound to MBP
exclusively via the B mode all failed to be transported.
The entire coding region of the
malE254 allele was sequenced. It was amplified by polymerase
chain reaction using genomic DNA of strain pop1153 (K-12 Hfr his
malE254) (5) as template and two 20-mer oligonucleotide primers
that bound to sites just outside the unique StuI and
EcoRI restriction sites. Three independently derived
polymerase chain reaction products were then subcloned into pBluescript
S/K (+ and ) (Stratagene Cloning Systems) by ligation between the
unique HincII and EcoRI sites. Single-stranded DNA was obtained by using M13KO7 helper phage (Stratagene Cloning Systems) and used as template for sequencing using the Sequenase version 2.0 DNA sequencing kit (U.S. Biochemical Corp.). One of the
recombinant plasmids, pEH1 (pBluescript S/K+ with malE254 insert), was used for subsequent malE254 MBP expression.
Wild type and malE254 MBPs
were prepared from strain HS2019 (K-12 F
araD139
lacU169 rpsL thi
malE444) (8)
containing pPD1 (malE+
bla+) (9) and from strain pop1153 or strain HS2019
containing pEH1, respectively. The strains were grown at 37 °C in LB
broth (1% Bacto-tryptone, 0.5% Bacto-yeast extract, and 0.5% NaCl)
containing 0.4% maltose and 100 µg/ml ampicillin when needed. MBP
was isolated from osmotic shock fluids by affinity chromatography (10).
Wild type MBP and malE254 MBP were eluted from the column by
the addition of 10 and 500 mM maltose, respectively. MBP,
precipitated with (NH4)2SO4 (90%
saturation), was then dissolved in 10 mM potassium phosphate buffer, pH 7.0, and bound maltose was removed either by
extensive dialysis (11) or by denaturation in 6 M
guanidine-HCl followed by renaturation through dialysis. Protein
concentrations were calculated using the UV extinction coefficient of
MBP of 1.7 (
1 cm0.1%) at 280 nm
(12).
Maltose (>99% pure, purchased
from Calbiochem), maltitol, maltotriose, maltotetraose, maltohexaose,
and -cyclodextrin (purchased from Sigma) were used without further
purification. Maltotetraose and maltohexaose were converted to their
glucitol derivatives via borohydride reduction (13). Maltohexaonic acid
was prepared by the oxidation of maltohexaose (14). Modifications were
apparently complete as judged by the absence of reducing
maltooligosaccharides on thin layer chromatography and the inability of
the modified products to reduce ferricyanide reagent (15).
Fluorescence spectra were obtained on a Perkin-Elmer MPF-44B spectrofluorometer in 10 mM potassium phosphate buffer, pH 7.0. Excitation was at 280 nm with a bandwidth of 6 nm, and emission was scanned from 285 to 380 nm with a bandwidth of 4 nm. The MBP concentration was 1 µM. Sugars and derivatives were used at a concentration of 100 µM for wild type MBP (maltitol was used at a concentration of 1 mM) and 1 mM for malE254 MBP (the concentration of maltose and maltitol when using the mutant MBP was 10 mM). Based on the Kd values of these MBPs (4, 5, 16),2 approximately 90% or more of MBP was expected to be liganded under these conditions, with the exception of the maltose/malE254 MBP combination.
UV difference spectroscopy was carried out on a Kontron Instruments Uvikon 860 spectrophotometer. For all difference spectra, MBP in 10 mM potassium phosphate buffer, pH 7.0, was added to both sample and reference cuvettes to a final concentration of 10 µM, and the base-line correction procedure was run. Sugars and derivatives were then added to the sample cuvette to a final concentration of 100 µM (for wild type MBP) or 1.0 mM (for malE254 MBP). Maltitol was added to 1.0 mM to wild type MBP, and both maltose and maltitol were added to a final concentration of 10 mM to the mutant MBP. Equal volumes of the buffer were added to control cuvettes. Spectra were obtained with a sampling interval of 0.5 nm and a bandwidth of 2 nm.
The emission maximum of
wild type MBP occurs at 348 nm. The addition of various ligands altered
the intrinsic fluorescence of this protein. Maltose induced a 2.5-nm
red shift, whereas -cyclodextrin caused a 6-nm blue shift (Fig.
1A), as reported earlier (2). These changes
can be taken as signatures for the two modes of ligand binding, the R
and B modes. Maltoheptaose induces a slight blue shift (2). We found
that both maltotetraose and maltohexaose produced very small blue
shifts (0.5-1 nm), while maltotriose caused a slight red shift (0.5 nm) (Fig. 1B and data not shown). These data suggest that
both the R and B binding modes are utilized by the maltodextrins and
that the R mode was important with shorter maltodextrins such as
maltotetraose and under our experimental conditions that included the
presence of excess ligands (see Ref. 12). All ligands also induced a
5-10% quenching of the fluorescence as well.
Nonreducing derivatives of linear maltodextrins, i.e. maltotetraitol, maltohexaitol, and maltohexaonic acid, caused marked blue shifts (2, 4, and 5 nm, respectively) and induced a 5-10% quenching (Fig. 1B), a result suggesting that these derivatives bind to MBP predominantly via the B mode. Maltitol produced only a small blue shift (~0.5 nm) and a 3% quenching (data not shown).
The malE254 allele was isolated during a search for mutants
that were able to grow on maltose but not on longer maltodextrins (5).
This and other "maltodextrin-negative" malE mutant(s), producing altered MBP, are able to grow on maltose but not on maltodextrins, although their MBPs have poor affinity for maltose and
good affinity for maltodextrins. With the malE254 MBP,
Kd values for maltodextrins are between 10 and 40 µM, while those for maltotriose and maltose are
approximately 300 µM and 2.0 mM, respectively
(5). This phenotype has remained an enigma until now. The emission
spectrum of the malE254 MBP had a maximum at 346 nm (Fig.
1C), showing a 2-nm blue shift in comparison with wild type
MBP. As was the case with the wild type protein, the malE254
MBP emission spectrum was red-shifted by 2 nm by maltose and
blue-shifted by approximately 3.5 nm by -cyclodextrin (Fig. 1C). The nonreducing derivatives of maltodextrin
(maltotetraitol, maltohexaose, maltohexaitol, and maltohexaonic acid)
similarly produced marked blue shifts (ranging from 3 to 4 nm) (Fig.
1D and data not shown). However, unmodified maltodextrins
(maltotriose, maltotetraose, and maltohexaose), which caused only
marginal blue shifts in the wild type MBP (Fig. 1B),
produced large blue shifts with the mutant MBP (Fig. 1D and
results not shown). These observations suggest that the mutant MBP
binds both reducing and nonreducing maltodextrin derivatives only in
the B mode. Maltitol caused a slight red shift of 0.5 nm but caused no
observable fluorescence quenching (data not shown), in contrast to all
other ligands that produced approximately 5% quenching.
The UV absorbance
spectrum of wild type MBP was altered upon binding of maltose,
maltohexaose, and -cyclodextrin (Fig. 2A). The difference spectra were very similar to those reported previously (7). The first derivatives were also calculated (Fig. 2B). The spectra differed mainly in two regions: below 265 nm and between 310 and 280 nm.
In the region below 265 nm, both maltose and maltohexaose (Fig.
2A) caused sharp hypochromatic trends. In contrast, the
difference spectrum of -cyclodextrin lacked this hypochromatic trend
and instead had a peak at 250 nm (Fig. 2A). This feature was
also seen clearly in the first derivative spectra (Fig. 2B)
and resulted in the curve crossing the x axis at 250 nm in
the spectrum of
-cyclodextrin. In this region, difference curves
generated in the presence of maltodextrin derivatives (maltotetraitol,
maltohexaitol, and maltohexaonic acid) were drastically different from
those of unmodified maltodextrins, showing a peak around 255 nm (or a
crossing of the x axis near 255 nm in the first derivatives (Fig. 2B)) much like that found with
-cyclodextrin.
The region between 310 and 280 nm is quite complex and is best compared
in the first derivative spectra. With maltose, the first derivative had
peaks at 310, 294, and 286 nm (Fig. 2B). The latter two
peaks appeared to have been blue-shifted in the presence of
maltohexaose to 291 and 282 nm (Fig. 2B). With
-cyclodextrin, the 294-nm peak was blue-shifted even more (to 290 nm), and a new peak appeared at 296 nm. There was also a marked
flattening (and an apparent red shift) of the peak located close to 310 nm (Fig. 2B). Maltotetraitol, maltohexaitol, and
maltohexaonic acid produced first derivative curves that had many of
the signatures of the
-cyclodextrin spectrum, such as the prominent
peak around 290-291 nm, the additional shoulder around 296 nm, and
also a characteristic flattening of the 310-nm peak (Fig.
2B).
The binding of ligands thus caused characteristic changes in the UV difference spectra. Those ligands that bind predominantly via the R mode, such as maltose and maltodextrins, produced hypochromatic changes in the region below 265 nm, and also characteristic changes in the region between 280 and 310 nm. In contrast, ligands that bind exclusively via the B mode, such as reduced, oxidized, or cyclic maltodextrins, produced a peak around 250-255 nm without the hypochromatic changes in the region below 265 nm, as well as another set of characteristic changes in the region between 280 and 310 nm.
The addition of maltitol to MBP produced a difference curve that was, for the most part, featureless (data not shown). A possible reason may be that maltitol cannot interact effectively with MBP either via the R or the B mode. Indeed, the Kd of maltitol is ~50 µM, while that of maltose is 1 µM (4).
UV Difference Spectra of malE254 MBPThe difference spectra
generated for maltose and -cyclodextrin bound to this mutant MBP
were similar to those with the wild type MBP (Fig.
3A), although in the region between 310 and
290 nm the peaks were slightly blue-shifted (Fig. 3B). When
the nonreducing derivatives of maltodextrins were added, the changes
were similar to those seen with the wild type MBP and included the 282- and 290-nm peaks as well as the 296-nm shoulder and the flattening of
307 nm peak, the latter two features reminiscent of the
-cyclodextrin spectrum (Fig. 3B). However, in contrast to
the situation with wild type MBP, practically the same spectra of B
type binding were produced by the addition of reducing maltodextrins,
such as maltohexaose (Fig. 3). These results suggest that the
malE254 MBP binds reducing maltodextrins exclusively in the
B mode, although it can bind maltose (at high concentrations) in
the R mode.
Sequence of the malE254 Allele
DNA sequencing showed that the
malE254 allele contained a single base substitution, a G-C
to A-T transition, which replaced an aspartic acid at position 65 of
the mature protein with an asparagine (GAC to AAC). Asp65
lies within the binding pocket of MBP and makes direct contacts with
both maltose and -cyclodextrin (6, 17). In the case of maltose,
Asp65 makes strong hydrogen bond contacts with the hydroxyl
groups at the 2- and 3-positions of the nonreducing glucose unit (18). The phenotype of the MalE254 MBP will be examined in more detail under
"Discussion."
An interesting feature of the maltose transport system is that it transports not only maltose, a disaccharide, but also maltodextrins at least up to maltoheptaose (1). Previous studies showed that the binding of various ligands to MBP resulted in different changes in its intrinsic fluorescence emission spectra (2) and UV absorption spectra (7). As described in the Introduction, we define the binding mode that produces a red shift in the fluorescence emission spectrum and a hypochromatic effect in the UV absorption spectrum below 265 nm as the "R mode," and the one producing a blue shift and a 250-nm peak, respectively, as the "B mode."
In this study we examined the binding of those ligands that are not
transported into the cytoplasm. Previously it was observed that
nonreducing derivatives of maltodextrins, such as reduced or oxidized
maltodextrins, or methyl glycosides, were often bound by MBP with high
affinity but were not transported (4). Since these derivatives were
recognized by LamB, the outer membrane channel for maltodextrins, and
inhibited the transport of maltose (4), they apparently had little
difficulty in reaching the periplasm. When we examined the mode of
binding of these derivatives, we found that both reduced and oxidized
derivatives of maltodextrins bound to MBP nearly exclusively via the B
mode. Thus, both the UV difference and fluorescence spectra of wild
type MBP bound to these derivatives were very similar to those of the
-cyclodextrin-MBP complex. In contrast, binding of unmodified
maltodextrins to wild type MBP produced spectra between those of
MBP-maltose and MBP-
-cyclodextrin complexes, suggesting that they
bound partly via the R mode and partly via the B mode (Figs. 1 and 2).
Especially with UV difference spectra, the R mode seemed to
predominate, since there were only very small differences between the
spectra of maltose-MBP and maltohexaose-MBP complexes in the region
below 265 nm (Fig. 2A). These results thus suggest that
those substrates that are successfully transported bind to MBP at least
partly via the R mode, whereas substrates that bind exclusively by the
B mode are not transported. The latter is thus a physiologically
inactive mode of binding.
This conclusion was reinforced by the study of the malE254 mutant MBP. Mutants of this class (5) can transport maltose but not maltodextrins. Yet this mutant MBP binds maltose rather poorly and paradoxically binds maltodextrins with good affinity (5). These results can now be explained if the mutant MBP binds maltodextrins always in the inactive, B mode. We found indeed that the malE254 MBP bound maltodextrins (and their derivatives) exclusively by the B mode (Figs. 1D and 3). The mutant MBP, however, appeared to bind maltose in the R mode when maltose was present at high concentrations (Fig. 3). The present results thus solve the long-standing puzzle that this mutant MBP was incapable of producing an active transport of maltodextrins despite its high affinity to them (5); the overall binding affinity of ligands to MBP may be misleading, since what matters is only the binding through the R mode.
We have so far defined the R and B modes of binding operationally.
However, two modes of ligand binding to MBP have been described also by
a method that allows some insight into the molecular details. Thus,
3H NMR studies using ligands tritiated on the anomeric
carbon of the reducing glucose residue showed that maltose binds to MBP only in a way causing a large upfield shift of the anomeric tritium resonance, whereas maltodextrins bind to MBP in this way as well as in
a different manner causing only a small upfield shift of this resonance
(12). Furthermore, only the former mode has a strong preference for
-anomers. Thus, the former mode seems to involve strong interaction
of the anomeric group of the reducing glucose with a group at the
binding site, whereas such an interaction is not important in the
latter mode. These two binding modes were therefore called "end-on"
and "middle" binding modes (12). (However, "end-on" does not
mean that nonreducing sugar moieties do not interact strongly with the
binding site, since the only atom that was observed by NMR was the
tritium on anomeric carbon). Maltose thus uses the end-on mode
exclusively. In contrast, at low ligand:protein ratios, after all of
the
-maltodextrin molecules have become bound through the high
affinity, end-on binding, the remaining unliganded MBP molecules bind
-anomers through the middle mode (12). The use of these two modes by
maltose and maltodextrins exactly parallels the use of R and B modes by
the same compounds, and R mode spectral changes are likely to be caused
by end-on binding, while B mode changes are probably caused by the
middle binding (7). In addition, compounds without the reducing glucose residue, such as
-cyclodextrin, or reduced or oxidized maltodextrins are expected to bind via the only possible mode, i.e. the
middle mode, and indeed they all produced nearly pure B mode spectral changes, further confirming this assignment. Reducing maltodextrins are
expected to bind the wild type MBP predominantly via the R mode (see
Fig. 2A), since the stoichiometric ratio between the ligand
and MBP was 10:1 (see "Experimental Procedures"), ensuring that
there were enough
-maltodextrins to saturate most of the binding
sites.
X-ray crystallographic studies on MBP have shown that upon binding
maltose, maltotriose, or maltotetraose MBP undergoes a global
conformational change in which its two domains close together (6, 19);
these are ligands that preferentially bind to MBP through the end-on
mode, especially when the maltodextrins are present in excess over MBP
(12), as they must have been during crystallization. In contrast, the
binding of -cyclodextrin, a presumed middle binder, to MBP was found
to prevent the closing of the two domains (17). Since reduced and
oxidized maltodextrins, which utilize the B (and presumably the middle)
mode exclusively (see above), produced both fluorescence emission and
UV difference spectra strongly resembling those of
-cyclodextrin, it
seems likely that the middle binding produces an MBP conformation
similar to that of
-cyclodextrin-bound, open cleft, MBP. By using
site-directed spin labeling of MBP, we show, in the next paper of this
series (20), that indeed the R and B modes of binding produce,
respectively, closed and open forms of the MBP-ligand complex.
The malE254 allele was found to contain a point mutation
leading to an active site substitution of Asp65 for Asn. In
the crystallographic structure of the MBP-maltose complex (6, 18),
Asp65 appears to interact with the nonreducing glucose
moiety.3 It also interacts with one of the
glucose residues (called g3) in the MBP--cyclodextrin complex (17).
If we assume, as described above, that the R and B modes correspond to
closed and open global conformations of MBP, the behavior of this
mutation can be explained. In the maltose-MBP structure, both of the
carboxyl oxygens of Asp65 are strongly hydrogen-bonded
(less than 3.0 Å) to O-2 and O-3 of the nonreducing glucose residue of
maltose. Furthermore, the surrounding area is tightly packed, with 12 other atoms present within a 4-Å radius of these two oxygen atoms in
addition to the atoms belonging to the Asp65 residue.
Clearly, substitution of Asn at this position will disturb the hydrogen
bonding scheme by converting one of the carboxyl oxygens into a
hydrogen-donor group and thus inhibit ligand binding in this manner. In
contrast, the corresponding area in the cyclodextrin-MBP complex (1DMB,
Brookhaven Protein Data Bank) is much more sparsely filled, and there
are only six atoms within the 4-Å radius of the carboxyl oxygen atoms
of Asp65 if we exclude the atoms of the Asp65
residue and the oxygen atoms of water molecules. Further, only one of
the Asp65 carboxyl oxygens is weakly hydrogen-bonded
(distances of 3.5-3.7 Å) to O-2 and O-3 of the closest glucose
residue (g3). Clearly, the ligand binding in this mode can tolerate the
substitution of Asp with Asn. The mutation will thus hinder the end-on
binding severely, without affecting much the middle binding, precisely the result that has been observed earlier (5) as well as in this
study.
We thank Cecile Wandersman, Pascale Duplay, and Howard Shuman for the gifts of pop1153, pPD1, and HS2019, respectively.