Article
Structural Determinants D
efining the AllostericInhibition of an Essential Antibiotic TargetGraphical Abstract
Highlights
d Crystal structure of L. pneumophilaDHDPS and lysine-bound
S. pneumoniae DHDPS
d DHDPS allosteric inhibition is not defined by Gram staining
d Glu or His at position 56 in DHDPS defines lysine binding
d DHDPS enzymes with Lys or Arg at position 56 are not
inhibited by lysine
Soares da Costa et al., 2016, Structure 24, 1282–1291August 2, 2016 ª 2016 Elsevier Ltd.http://dx.doi.org/10.1016/j.str.2016.05.019
Authors
Tatiana P. Soares da Costa,
Sebastien Desbois, Con Dogovski, ...,
Nathan E. Hall, Santosh Panjikar,
Matthew A. Perugini
In Brief
In some bacteria, lysine biosynthesis is
regulated by lysine-mediated allosteric
inhibition of the enzyme
dihydrodipicolinate synthase (DHDPS).
Soares da Costa et al. show that position
56 (E. coli numbering) defines DHDPS
allostery, dispelling the current dogma
that regulation is based on Gram staining.
Structure
Article
Structural Determinants Defining the AllostericInhibition of an Essential Antibiotic TargetTatiana P. Soares da Costa,1 Sebastien Desbois,1 Con Dogovski,1,2 Michael A. Gorman,3 Natalia E. Ketaren,2
Jason J. Paxman,1,8 Tanzeela Siddiqui,2 Leanne M. Zammit,1 Belinda M. Abbott,4 Roy M. Robins-Browne,5,6
Michael W. Parker,2,3 Geoffrey B. Jameson,7 Nathan E. Hall,1 Santosh Panjikar,8,9 and Matthew A. Perugini1,*1Department of Biochemistry and Genetics, La Trobe Institute for Molecular Science, La Trobe University, Bundoora, VIC 3086, Australia2Department of Biochemistry andMolecular Biology, Bio21Molecular Science andBiotechnology Institute, University ofMelbourne, Parkville,
VIC 3010, Australia3St Vincent’s Institute of Medical Research, Fitzroy, VIC 3065, Australia4Department of Chemistry and Physics, La Trobe Institute for Molecular Science, La Trobe University, Bundoora, VIC 3086, Australia5Department ofMicrobiology and Immunology, TheUniversity ofMelbourne at the Peter Doherty Institute for Infection and Immunity, Parkville,
VIC 3010, Australia6Murdoch Childrens Research Institute, Royal Children’s Hospital, Parkville, VIC 3052, Australia7Centre for Structural Biology, Institute of Fundamental Sciences, Massey University, Palmerston North 4442, New Zealand8Australian Synchrotron, Clayton, VIC 3168, Australia9Department of Biochemistry and Molecular Biology, Monash University, Clayton, VIC 3800, Australia
*Correspondence: [email protected]://dx.doi.org/10.1016/j.str.2016.05.019
SUMMARY
Dihydrodipicolinate synthase (DHDPS) catalyzes thefirst committed step in the lysine biosynthesispathway of bacteria. The pathway can be regulatedby feedback inhibition of DHDPS through the allo-steric binding of the end product, lysine. The currentdogma states that DHDPS from Gram-negative bac-teria are inhibited by lysine but orthologs from Gram-positive species are not. The 1.65-A resolution struc-ture of the Gram-negative Legionella pneumophilaDHDPS and the 1.88-A resolution structure of theGram-positive Streptococcus pneumoniae DHDPSbound to lysine, together with comprehensive func-tional analyses, show that this dogma is incorrect.We subsequently employed our crystallographicdata with bioinformatics, mutagenesis, enzyme ki-netics, and microscale thermophoresis to revealthat lysine-mediated inhibition is not defined byGram staining, but by the presence of a His or Gluat position 56 (Escherichia coli numbering). Thisstudy has unveiled the molecular determinantsdefining lysine-mediated allosteric inhibition of bac-terial DHDPS.
INTRODUCTION
Dihydrodipicolinate synthase (DHDPS) (EC 4.3.3.7) is an allo-
steric enzyme that catalyzes the first committed step in the lysine
biosynthesis pathway of bacteria and plants (Dogovski et al.,
2009, 2012; Soares da Costa et al., 2015) (Figure 1). This
pathway produces key building blocks for the synthesis of
housekeeping proteins, virulence factors, and the peptidoglycan
cell wall in bacteria (Dogovski et al., 2009, 2012; Soares da Costa
1282 Structure 24, 1282–1291, August 2, 2016 ª 2016 Elsevier Ltd.
et al., 2015). It is therefore not surprising that DHDPS is the prod-
uct of an essential bacterial gene (Becker et al., 2006; Dogovski
et al., 2013; Forsyth et al., 2002; Kobayashi et al., 2003). Given its
essentiality to pathogenic bacteria and absence in humans,
DHDPS is considered a promising antibiotic target (Hutton
et al., 2007). This has generated considerable interest in charac-
terizing the structure, function, and inhibition of this bacterial
enzyme.
DHDPS exists as dimers or tetramers with the dimeric unit
containing all the molecular requirements for catalysis and allo-
stery (Dobson et al., 2005b; Mirwaldt et al., 1995). However, tet-
ramers are more commonly observed in both Gram-negative
and Gram-positive bacteria, most likely because tetramerization
stabilizes conformational dynamics to afford optimal enzymatic
function (Griffin et al., 2008, 2010; Voss et al., 2010). By contrast,
dimeric forms of DHDPS have evolved to stabilize dynamics by
increasing the buried surface area at the dimeric interface
(Burgess et al., 2008a).
Functionally, DHDPS catalyzes the condensation of pyruvate
and (S)-aspartate semialdehyde (ASA) to form the heterocyclic
product, hydroxytetrahydrodipicolinic acid (Figure 1). Not sur-
prisingly, traditional DHDPS inhibition strategies have focused
on developing small molecules with analogy to these substrates
and/or products (Boughton et al., 2008; Hutton et al., 2003, 2007;
Laber et al., 1992; Mitsakos et al., 2008; Turner et al., 2005a,
2005b). The most potent substrate-analog inhibitor discovered
to date is dipicolinic acid N-oxide, which has a half-maximal
inhibitory concentration (IC50) value of 0.8 mM (Couper et al.,
1994). The DHDPS structure also contains a ‘‘druggable’’ allo-
steric cleft that binds the natural inhibitor, lysine. This mediates
a canonical feedback inhibition response as depicted in Figure 1.
Lysine is a potent inhibitor of bacterial DHDPS, with IC50 values
ranging from 53 mM to 1mM (Bakhiet et al., 1984; Devenish et al.,
2009; Joerger et al., 2003; Laber et al., 1992; Skovpen and
Palmer, 2013; Soares da Costa et al., 2010; Tam et al., 2004; Yu-
gari and Gilvarg, 1965), providing scope to incorporate rational
drug design efforts to afford the discovery of high-affinity
Figure 1. Lysine Biosynthesis Pathway in Bacteria, Highlighting the
Allosteric Regulation of DHDPS by the End Product of the Pathway
DAP, diaminopimelate; DAPDC, diaminopimelate decarboxylase; DHDPR,
dihydrodipicolinate reductase; HTPA, hydroxytetrahydrodipicolinic acid;
THDP, tetrahydrodipicolinic acid.
Table 1. Purification Strategies Utilized to Produce Recombinant
DHDPS
DHDPS Vector Purification Strategy
L. pneumophila pET11a ion-exchange and hydrophobic
interaction chromatography
S. pneumoniae pET11a ion-exchange and hydrophobic
interaction chromatography
B. pseudomallei pET28a nickel-affinity chromatography
E. faecalis pRSET A nickel-affinity chromatography
C. burnetii pRSET A nickel-affinity chromatography
Campylobacter
sp. 17-4
pRSET A nickel-affinity chromatography
E. faecalis E56K pET28a nickel-affinity chromatography
allosteric inhibitors (Skovpen et al., 2016). In the allosteric bind-
ing site, two lysine molecules bind in a bis conformation in close
proximity (Ca atoms �4 A apart), with the side-chain 3-amino
groups projecting away from each other (Dobson et al.,
2005b). The bound lysine molecules are stabilized via a number
of hydrogen bonding interactions mediated primarily by Ser48,
Ala49, Leu51, His53, His56, Asn80, Glu84, and Tyr106 (Escheri-
chia coli DHDPS numbering) (Dobson et al., 2005b). The precise
nature of lysine-mediated inhibition is not fully understood, and
the same mechanism may not be shared by all lysine-inhibited
DHDPS enzymes. Previous studies suggest that lysine binding
changes the position of Tyr106 (E. coli numbering), which dis-
rupts the hydrogen bonding network involving the general
acid-base Tyr107 (E. coli numbering) and triggers changes in
conformational flexibility of substrate-binding active-site resi-
dues (Atkinson et al., 2013; Dobson et al., 2005b).
Surprisingly, not all bacterial DHDPS enzymes are allosteri-
cally inhibited by lysine (Dogovski et al., 2009, 2012; Soares
da Costa et al., 2015), with both dimeric and tetrameric forms
allosterically inhibited in some bacterial species but not in
others (Burgess et al., 2008a; Dobson et al., 2005a; Kaur
et al., 2011; Voss et al., 2010). This demonstrates that oligomer-
ization plays no role in allostery. Indeed, the current dogma sug-
gests that DHDPS from Gram-negative bacteria are inhibited by
lysine (Bakhiet et al., 1984; Devenish et al., 2009; Dobson et al.,
2005b; Joerger et al., 2003; Kaur et al., 2011; Laber et al., 1992;
Skovpen and Palmer, 2013; Soares da Costa et al., 2010; Tam
et al., 2004; Yugari and Gilvarg, 1965); whereas the enzymes
from Gram-positive bacteria are insensitive to allosteric regula-
tion (Burgess et al., 2008a; Cahyanto et al., 2006; Cremer et al.,
1988; Domigan et al., 2009; Halling and Stahly, 1976; Voss
et al., 2010; Webster and Lechowich, 1970; Yamakura et al.,
1974). The lack of lysine sensitivity in Gram-positive bacteria
has been attributed to the high lysine content of their cell walls
(Slade and Slamp, 1962).
Here we initially set out to compare the structure and function
of DHDPS from two common pneumonia-causing pathogens,
namely the Gram-negative bacterium Legionella pneumophila
(Lp) and the Gram-positive bacterium, Streptococcus pneumo-
niae (Sp). Strikingly, we show that SpDHDPS is the first example
of a DHDPS from a Gram-positive pathogen that is allosterically
inhibited by lysine. Conversely, we demonstrate that the ortholog
from L. pneumophila is the first DHDPS from a Gram-negative
pathogen that lacks allosteric inhibition. This prompted a re-
evaluation of the dogma and the identification of the molecular
determinants that define lysine-mediated allosteric inhibition of
DHDPS. As proof of concept, a selection of Gram-negative
(Burkholderia pseudomallei andCoxiella burnetii) andGram-pos-
itive (Enterobacter faecalis andCampylobacter sp. 17-4) DHDPS
enzymes that were predicted to be sensitive and insensitive to
lysine inhibition based on the newly identified determinants
were examined. Our predictions were confirmed by employing
a combination of bioinformatics, mutagenesis, protein biochem-
istry, biophysics, and enzymology. Thus we are now able to
reliably predict the presence or absence of lysine-mediated inhi-
bition of bacterial DHDPS.
RESULTS
Expression, Purification, andPrimary Structure Analysisof LpDHDPS and SpDHDPSThe dapA gene encoding DHDPS was amplified from genomic
DNA isolated from L. pneumophila and S. pneumoniae and
cloned into the pET11a expression vector, and the recombinant
DHDPS enzymes were overexpressed in E. coli and purified to
>98% homogeneity as described in Experimental Procedures
(Tables 1 and 2).
Solution Properties of LpDHDPS and SpDHDPSHaving confirmed the identity of recombinant LpDHDPS and
SpDHDPS, we assessed the secondary structure of the proteins
using circular dichroism (CD) spectroscopy. The CD spectra of
the recombinant enzymes show broad double minima spanning
210–225 nm, which is consistent with the (b/a)8 or TIM-barrel to-
pology reported for DHDPS enzymes from different species (At-
kinson et al., 2014; Blickling et al., 1997; Burgess et al., 2008a;
Dogovski et al., 2013; Griffin et al., 2008, 2012; Mirwaldt et al.,
1995; Voss et al., 2010) (Figure S1). To compare the quaternary
Structure 24, 1282–1291, August 2, 2016 1283
Table 2. Electrospray Ionization Time-of-Flight Mass
Spectrometry Results of Purified Recombinant DHDPS
DHDPS
Predicted
Molecular
Mass (Da)
Experimental
Molecular
Mass (Da)
L. pneumophila 31,581.0 31,580.4
S. pneumoniae 33,780.5 33,780.2
B. pseudomallei 31,665.0 31,664.7
E. faecalis 35,659.8 35,659.8
C. burnetii 35,742.9 35,740.9
Campylobacter sp. 17-4 35,972.9 35,973.6
E. faecalis E56K 34,942.1 34,941.2
The deconvoluted mass spectra reveal that the predominant peaks are
consistent with the theoretical molecular mass for each protein.
structure of LpDHDPS and SpDHDPS in solution, we performed
sedimentation velocity studies in the analytical ultracentrifuge.
The results show that LpDHDPS (Mr = 31,581.0) sediments as
a single species with a standardized sedimentation coefficient
(s20,w) of 4.3 S (Figure S2A). This value compares well with the
4.2 S observed for theStaphylococcus aureus (Sa) DHDPSdimer
(Burgess et al., 2008a). Conversion of the c(s) profile to a c(M)
distribution reveals an apparent molar mass of 61.4 kDa, consis-
tent with the theoretical mass of an LpDHDPS dimer. In compar-
ison, SpDHDPS (Mr = 33,780.54) sediments as 7.4 S with a
molecular mass of 131 kDa, consistent with a tetramer as previ-
ously described (Dogovski et al., 2013) (Figure S2B). We were
therefore interested in comparing the catalytic function of the
LpDHDPS dimer and SpDHDPS tetramer.
Functional Comparison of LpDHDPS and SpDHDPSEnzyme kinetics were performed in the absence and presence of
(S)-lysine using the quantitative DHDPS-DHDPR coupled assay
(Dobson et al., 2005b). Regarding SpDHDPS, the resulting ki-
netic analysis of LpDHDPS in the absence of lysine demon-
strates that the enzyme catalyzes the condensation of (S)-ASA
and pyruvate via a typical bibi ping-pong mechanism with no
substrate inhibition (Table 3). However, in the presence of
increasing concentrations of (S)-lysine, LpDHDPS surprisingly
maintains 100% catalytic activity even up to the non-physiolog-
ical concentration of 5 mM (Figure 2A). This is the first DHDPS
enzyme from a Gram-negative pathogen to show a lack of lysine
feedback inhibition. By contrast, the Gram-negative control,
E. coli (Ec) DHDPS, is inhibited by lysine with an IC50 of
0.18 mM (R2 = 0.988), agreeing with previously published data
(Soares da Costa et al., 2010) (Figure 2A). Even more striking is
the observation that SpDHDPS is inhibited by lysine, which is
the first case of lysine feedback inhibition reported for a Gram-
Table 3. Kinetic Constants for LpDHDPS and SpDHDPS
DHDPS kcat (s�1) KM
PYR (mM)
LpDHDPS 101 0.241 ± 0.013
SpDHDPS 22.2a 2.55 ± 0.05a
See also Figure S3.aKinetic properties from Dogovski et al. (2013).
1284 Structure 24, 1282–1291, August 2, 2016
positive bacterium (Table 3, Figure 2B). For comparison, the ac-
tivity of DHDPS from theGram-positive control,S. aureus, shows
no dose response (Figure 2B). Subsequent in-depth kinetic ana-
lyses showed that the mechanism of inhibition for SpDHDPS is
mixed with respect to both substrates, resulting in inhibition con-
stants (Ki) for (S)-ASA of Kic = 0.031mM and Kiu = 0.026mM; and
for pyruvate of Kic = 0.054 mM and Kiu = 0.012 mM (Figure S3).
This demonstrates that the inhibition of SpDHDPS by lysine is
at least 3-fold more potent compared with EcDHDPS (Ghislain
et al., 1990; Karsten, 1997; Soares da Costa et al., 2010). Given
these surprising results, we were interested in determining and
comparing the high-resolution crystal structures of apo (i.e., un-
liganded) LpDHDPS and SpDHDPS bound to lysine.
Crystal Structure DeterminationTo provide insight into the structural determinants that define the
presence or absence of lysine-mediated allosteric inhibition of
DHDPS, we determined the crystal structures of apo LpDHDPS
(PDB: 4NQ1) and lysine-bound SpDHDPS (PDB: 4FHA) to 1.65-A
and 1.88-A resolution, respectively, using themolecular replace-
ment method. The data collection, processing, scaling, and
refinement statistics are presented in Table 4. The overall
sequence identity between the two orthologs is 36% and the
root-mean-square deviation (rmsd) over 290 residues between
the structures is 1.6 A.
Consistent with our analytical ultracentrifuge data showing
that LpDHDPS exists as a dimer in solution, two molecules of
LpDHDPS are observed in the asymmetric unit (Figure 3A), as
the canonical DHDPS dimer. The extensive interface comprises
a total of 17 hydrogen bonds and a buried interface area of
1,418 A2. Comparison of the LpDHDPS and EcDHDPS demon-
strates a high degree of conservation in the spatial orientation
of almost all active-site residues (Figure S4). The exception is
Tyr106, which shows�90� rotation relative to its E. coli counter-
part, an effect also observed for the dimeric SaDHDPS (Burgess
et al., 2008a; Girish et al., 2008) (PDB: 3DAQ and 3DI0). Shown in
Figure 3B is an overlay of the L. pneumophila (green) and E. coli
(purple) DHDPS allosteric sites. Depicted in orange is a lysine
ligand bound to the E. coli site (PDB: 1YXD), which makes key
contacts with His56, Tyr106, and Glu84. In LpDHDPS (PDB:
4NQ1) these residues are replaced with Lys55, Ala105, and
Asp83, respectively. The side chain of Lys55 lies in close prox-
imity to the 3-amino moiety of the bound lysine in the E. coli
enzyme. This introduces potential electrostatic repulsion and
steric hindrance that would prevent lysine binding into the
LpDHDPS cleft. Furthermore, the carboxyl group of the lysine
molecule is coordinated by the phenolic hydroxyl group of
Tyr106 in EcDHDPS. A substitution to alanine eliminates this sta-
bilizing interaction. Finally, Glu84 in EcDHDPS participates in a
hydrogen bonding network with Ala49 and Asn80 to secure the
KMASA (mM) IC50
Lysine (mM)
0.186 ± 0.010 no inhibition
0.0442 ± 0.0028a 0.630 ± 0.006
Figure 2. Inhibition Curves of DHDPS Enzymes in the Presence of Lysine
(A) Activity remains constant for Gram-negative LpDHDPS (triangles) in the presence of increasing lysine concentration. This is in contrast to Gram-negative
EcDHDPS (diamonds), which displays an IC50 of 0.18 mM. Data represent mean ± SEM (N = 3, n = 3).
(B) Activity remains constant for Gram-positive SaDHDPS (squares) in the presence of increasing lysine concentration. This is in contrast to Gram-positive
SpDHDPS (circles), which displays an IC50 of 0.06 mM. Data represent mean ± SEM (N = 3, n = 3).
a-amino of the inhibitory lysine. An overlay of Asp83 and Glu84
reveals a significant rotation, as well as displacement, in their
respective side chains (Figure 3B). Importantly, the side chain
of Asp83 is orientated so that it cannot interact with either bound
lysine or other allosteric site residues.
The crystal structure of SpDHDPS in the presence of lysine
(PDB: 4FHA) was next assessed. The lysine-bound enzyme
forms a tetramer (Figure 4A), consistent with the apoenzyme
(Dogovski et al., 2013), with one lysine bound per subunit (Fig-
ure 4B). Similar to EcDHDPS, two molecules of lysine are
observed bound in a bis conformation in the allosteric cleft
formed at the dimer interface adjacent to the active site. How-
ever, unlike EcDHDPS, substantial conformational changes are
observed when comparing the apo and lysine-bound struc-
tures, including significant rotations of His59 (His53, E. coli
numbering) and Asp90 (Glu84, E. coli numbering). This results
in significant movement, or ‘‘tensing,’’ of the two monomers
closer together at the dimer interface, as well as an increase
in the number of non-covalent interface contacts (Figure 4B).
This may serve to decrease the accessibility of the substrates
to the active site and/or the products from exiting. In addition,
an electrostatic contact between bound lysine and Glu62
is observed in the SpDHDPS structure (Figure 4B), which is
absent in the lysine-bound structure of EcDHDPS. Thus, the
presence of this interaction may contribute to the tighter bind-
ing of lysine observed for SpDHDPS, consequently inhibiting
catalysis.
Identification of the DHDPS Molecular DeterminantsDefining Lysine BindingGiven our surprising results demonstrating for the first time that
lysine allosteric inhibition is not related to Gram staining as pre-
viously thought, we set out to characterize the structural deter-
minants that define DHDPS-lysine interactions. Structural ana-
lyses comparing the sequence and chemical composition of
allosteric site residues from DHDPS enzymes shown to be in-
hibited by lysine (e.g., PDB: 3M5V, 1YXD, 3FLU, and 4FHA) al-
lowed the mapping of key residues that form interactions with
the allosteric ligand. In E. coli (PDB: 1YXD), 16 residues (eight
from each subunit) surround the two lysine molecules bound
in the allosteric cleft, namely Ser48, Ala49, Leu51, His53,
His56, Asn80, Glu84, and Tyr106. These residues form a series
of hydrogen bonds either directly with the bound ligand or via
coupled networks with the side-chain or backbone moieties
of nearby residues. When compared with allosteric DHDPS en-
zymes from other Gram-negative species, it is noted that the
ortholog from Campylobacter jejuni (PDB: 3M5V) has an allo-
steric site identical to that of the E. coli DHDPS, whereas the
enzyme from Neisseria meningitidis (PDB: 3FLU) differs only
at a single position, with Val replacing His53 (Figure S5). By
contrast, there are some notable differences in the allosteric
site of DHDPS from the Gram-positive lysine-sensitive
SpDHDPS, with Pro, Glu, and Asp replacing Ala49, His56,
and Glu84. Despite these differences, a similar hydrogen
bonding network is formed between the allosteric site residues
and the ligand in S. pneumoniae and E. coli DHDPS enzymes.
Interestingly, comparison of DHDPS protein sequences from
species known to be insensitive to lysine allostery (Bacillus an-
thracis, Clostridium botulinum, L. pneumophila, and S. aureus)
shows good conservation in the allosteric cleft, except for po-
sition 56 (E. coli numbering), which is a basic (i.e., Lys) residue
(Figure S5). We therefore hypothesize that DHDPS sequences
containing His or Glu at position 56 will be allosterically in-
hibited by lysine, whereas those containing a basic (i.e., Lys
or Arg) residue at this position will be insensitive to lysine-medi-
ated allostery.
Testing the Newly Identified Determinant of LysineBindingA multiple sequence alignment of uncharacterized DHDPS
sequences from the Gram-negative intracellular pathogen
B. pseudomallei and the Gram-positive bacterium E. faecalis
shows that these sequences contain a histidine and a glutamate
at position 56, respectively, suggesting that these enzymes will
be sensitive to lysine-mediated allostery (Figure 5). In compari-
son, the DHDPS sequences from the Gram-negative intracellular
Structure 24, 1282–1291, August 2, 2016 1285
Table 4. Data Collection, Processing, and Refinement Statistics
for LpDHDPS and SpDHDPS Co-crystallized with (S)-lysine
LpDHDPS
(PDB: 4NQ1)
Lysine-Bound
SpDHDPS
(PDB: 4FHA)
Wavelength (A) 0.9537 0.9537
No. of images 129 720
Oscillations (�) 0.5 0.5
Space group P6122 P21212
Unit cell parameters (A) a = 89.31,
b = 89.31,
c = 290.18
a = 106.37,
b = 106.23,
c = 60.38
Resolution (A) 36.27–1.65
(1.74–1.65)
39.91–1.88
(1.92–1.88)
Observed reflections 376,126 (58,890) 772,032 (12,445)
Unique reflections 81,908 (11,872) 55,372 (2,700)
Completeness (%) 98.9 (99.8) 98.0 (77.0)
Rmergea 0.108 (0.343) 0.094 (0.481)
Rp.i.mb 0.055 (0.169) 0.026 (0.210)
Mean I/s(I) 9.1 (4.2) 20.6 (1.90)
Multiplicity 4.6 (5.0) 13.9 (4.6)
Wilson B value (A2) 11.8 21.7
Molecules per
asymmetric unit
2 2
VM (A3 Da�1) 2.64 2.55
Solvent content (%) 53.52 51.84
Rcryst/Rfree (%) 14.7/18.9 15.9/18.3
No. of atoms
Protein 4,919 4,757
Water 918 328
Rmsd
Bond length (A) 0.027 0.0073
Bond angles (�) 2.12 1.085
Average B factors (A2)
Protein overall 16.2 20.0
Main chain 14.4 20.4
Side chain 15.7 21.1
Solvent 31.5 23.0
Ligands 15.9 20.2
Ramachandran plot,
residues (%)
Favored region 92.4 90.8
Allowed region 7.2 7.2
Generously allowed region 0.0 0.2
Disallowed region 0.4 0.8
Values in parentheses are for the highest-resolution bin.aRmerge =
Phkl
Pi jIiðhklÞ � hIðhklÞij=Phkl
Pi IiðhklÞ
bRp:i:m =P
hkl ½1=ðN� 1Þ�1=2PijIiðhklÞ � hIðhklÞij=Phkl
Pi IiðhklÞ
where IiðhklÞ is the ith intensity measurement of reflection hkl and hIðhklÞiits average, and N is the redundancy of a given reflection.
pathogen C. burnetii, and the Gram-positive species Campylo-
bacter sp. 17-4, show that these orthologs contain a basic
residue (Lys or Arg) at position 56, suggesting these enzymes
1286 Structure 24, 1282–1291, August 2, 2016
will be insensitive to lysine inhibition (Figure 5). Recombinant
B. pseudomallei, E. faecalis, C. burnetii, and Campylobacter
sp. 17-4 DHDPS enzymes were overexpressed in E. coli,
purified, and characterized kinetically for lysine inhibition, as
described in Experimental Procedures, to confirm these
predictions. Lysine inhibition was initially examined using the
qualitative o-aminobenzaldehyde assay (Mitsakos et al., 2011;
Yugari and Gilvarg, 1965), which assesses DHDPS activity
based upon the formation of a purple chromophore.
As hypothesized, DHDPS fromGram-negativeB. pseudomallei
(BpDHDPS) and Gram-positive E. faecalis (EfDHDPS) are shown
to be inhibited by lysine, whereas the orthologs fromGram-nega-
tive C. burnetii (CbDHDPS) and Gram-positive Campylobacter
sp. 17-4 (CsDHDPS) are insensitive to lysine-mediated allostery
(Figure 6A). These data were validated quantitatively using the
coupled DHDPS-DHDPR assay to determine the IC50 values for
lysine of 120 mM (R2 = 0.9931) and 172 mM (R2 = 0.9939) for
BpDHDPS and EfDHDPS, respectively (Figure 6B).
Validation of the Lysine Binding DeterminantsTo confirm that the nature of the residue at position 56 dictates
lysine binding and inhibition, we mutated the naturally occurring
glutamate at position 56 in EfDHDPS to a lysine (EfDHDPS-
E56K). The mutant enzyme was expressed and purified as
described for the wild-type enzyme (see Experimental Proce-
dures). Lysine binding was then compared for the wild-type
andmutant enzymes usingmicroscale thermophoresis (Wienken
et al., 2010). The KD for EfDHDPS was determined to be 148 ±
10 mM, which agrees well with the IC50 value of 172 mM reported
earlier. On the other hand, themutant enzymewas unable to bind
lysine even at 10 mM concentration (Figure 7A). The thermody-
namic results for the mutant were confirmed kinetically using
the coupled assay, indicating that, although catalytically active,
EfDHDPS-E56K had become insensitive to lysine-mediated
inhibition (Figure 7B).
DISCUSSION
We show in this study that DHDPS from the Gram-negative
pathogen L. pneumophila and the Gram-positive bacterium
S. pneumoniae do not conform to the current dogma for lysine
inhibition. The underlying molecular basis for the lack of allostery
in L. pneumophila was investigated by determining the crystal
structure of the enzyme. Inspection of the allosteric pocket
confirmed the absence of three key residues; His56, Tyr106,
and Glu84 (E. coli numbering). Lysine-bound structures in the
PDB have demonstrated the importance of these residues in
binding and stabilizing lysine within the allosteric cleft. An overlay
of the DHDPS allosteric sites in L. pneumophila and E. coli
showed that residues involved in interacting with lysine were
replaced with those that would either hinder the binding or fail
to form the necessary contacts. Moreover, there are no compen-
sating residues, and the putative allosteric site in LpDHDPS is
significantly more open than the equivalent site in orthologs
that bind lysine.
On the other hand, SpDHDPS is the first DHDPS from a Gram-
positive bacterium to be shown to be inhibited by the end prod-
uct of the lysine biosynthetic pathway. Furthermore, quantitative
inhibition assays demonstrate that SpDHDPS exhibits a high
Figure 3. Crystal Structure of LpDHDPS
(A) The dimer of LpDHDPS (PDB: 4NQ1) with
monomers shown in green and yellow. Note that
application of two-fold crystallographic symmetry
assembles a tetramer.
(B) Comparison of DHDPS allosteric sites by
overlaying LpDHDPS (green) with E. coli lysine-
bound DHDPS (purple, PDB: 1YXD). Lysine is de-
picted in orange and residues shown are in E. coli
numbering.
See also Figures S1, S2, and S4.
degree of sensitivity to the inhibitory effects of (S)-lysine
when compared with EcDHDPS (Dobson et al., 2004). The struc-
ture of SpDHDPS co-crystallized with (S)-lysine reveals a
marked conformational change including a large shift in the
orientation of His59 (SpDHDPS numbering). These conforma-
tional changes are not evident for EcDHDPS in the presence
of (S)-lysine compared with the apo structure. The additional
electrostatic contact between (S)-lysine and Glu62 observed in
the (S)-lysine-bound SpDHDPS structure may contribute to the
tighter binding.
In this study, a key position that defines whether a bacterial
DHDPS will allosterically bind lysine was identified. A multiple
DHDPS sequence alignment highlights a distinction in the nature
of the residue at position 56 that we propose is the major
determinant for lysine inhibition of DHDPS. We predict that the
presence of a histidine or glutamate at position 56 imbues
allosteric inhibition, whereas the presence of a basic residue re-
sults in no inhibition. Characterization of BpDHDPS, CbDHDPS,
CsDHDPS, and EfDHDPS in terms of lysine binding confirms our
hypothesis proposed here. In addition, mutation of the glutamate
at position 56 in EfDHDPS to a lysine completely abolished allo-
steric inhibition as assessed kinetically using the coupled assay
and thermodynamically employing microscale thermophoresis,
further validating our findings. We have therefore identified and
validated a key position that defines allosteric inhibition in
DHDPS from different bacterial species, providing insights into
the molecular evolution of enzyme allostery. The findings in this
study also provide insight into the targeted design of allosteric
inhibitors of DHDPS. However, the reason why some DHDPS
enzymes have evolved to be allosterically inhibited by lysine
remains to be understood. It may be that a bacterium’s environ-
ment and life cycle dictate the propensity for regulation by lysine.
Regulation at the gene level may also provide sufficient control of
this enzyme such that inhibition at the allosteric level is unneces-
sary. This remains to be explored in future studies.
EXPERIMENTAL PROCEDURES
Cloning, Expression, and Purification of DHDPS
Genomic DNA from L. pneumophila (strain Alcoy) and a clinical isolate of
S. pneumoniae (serotype 3) were used in this study. The procedures for ampli-
fying and cloning the dapA gene (encoding DHDPS) from L. pneumophila and
S. pneumoniae and for the overexpression and purification of recombinant
DHDPS were performed as described previously (Atkinson et al., 2011;
Burgess et al., 2008b; Dogovski et al., 2013; Sibarani et al., 2010; Siddiqui
et al., 2013). Briefly, dapA encoding DHDPSwas PCR-amplified from genomic
DNA and cloned into pET11a, pET28a, or pRSET A expression vector (Table 1).
The EfDHDPS-E56K mutant was commercially synthesized by Bioneer and
subcloned into the expression vector pET28a. Recombinant protein was pro-
duced in E. coli BL21-DE3 cells upon induction with 1 mM isopropyl b-D-1-thi-
ogalactopyranoside in Luria broth at 37�C or 16�C (L. pneumophila DHDPS).
Cells were harvested by centrifugation and sonicated in 20 mM Tris (pH 8.0).
Chromatography purification techniques were employed to yield >98% pure
recombinant protein (Table 3). Electrospray ionization time-of-flight mass
spectrometry confirmed the identity of the recombinant product (Table 2).
Circular Dichroism Spectroscopy
CD spectroscopy was performed using 1-mm quartz cuvettes in the Aviv
Model 420 CD spectrometer as previously described (Atkinson et al., 2014;
Burgess et al., 2008a; Dogovski et al., 2013; Griffin et al., 2008, 2012; Voss
et al., 2010). In brief, wavelength scans were conducted between 200 and
240 nm in 0.5-nm increments with 2-s averaging time at 20�C. Protein samples
were prepared in 20 mM Tris and 150 mM NaCl (pH 8.0) at 150 mg ml�1.
Figure 4. Crystal Structure of SpDHDPS
(A) The tetramer of SpDHDPS (PDB: 4FHA) with
each monomer depicted in a different color. The
solid line shows the dimer interface and the
tetramer interface is delineated by a dashed line.
(B) Comparison of DHDPS allosteric sites by over-
laying one molecule of apo SpDHDPS (green, PDB:
3VFL) with that of lysine-bound SpDHDPS structure
(blue, PDB: 4FHA). Oxygen and nitrogen atoms are
shown in red and blue, respectively, lysine is shown
in orange, and the blue mesh represents the elec-
tron density map (mFo� nFc) for lysine contoured at
2.0s. The overall B factor of lysine is 22.3 A2 with
100% occupancy. Conformational changes are
observed for residues His59 (�90� rotation) and
Asp90 (�45� rotation) upon binding of (S)-lysine.
Residues shown are in S. pneumoniae numbering.
See also Figures S1 and S2.
Structure 24, 1282–1291, August 2, 2016 1287
Figure 5. Sequence Alignment
Sequence alignment of the allosteric site residues
in DHDPS from Gram-positive (purple) and Gram-
negative (red) bacteria, including those character-
ized in this study. Numbering shown is for E. coli
DHDPS. See also Figure S5.
Analytical Ultracentrifugation
Sedimentation velocity experiments were conducted in a model XL-A analyt-
ical ultracentrifuge (Beckman Coulter) using similar methods described previ-
ously (Atkinson et al., 2014; Burgess et al., 2008a; Dogovski et al., 2013; Griffin
et al., 2008, 2012; Voss et al., 2010). Cells were loaded with 400 ml of reference
buffer and 380 ml of DHDPS at a concentration of 150 mg ml�1 into double-
sector quartz cells equipped with charcoal-Epon centerpieces within a four-
hole An60 Ti or eight-hole An50 Ti rotor. Data were collected at a wavelength
of 280 nm, temperature of 20�C, and rotor speed of 40,000 rpm in continuous
mode employing a step size of 0.003 cm without averaging. Data at multiple
time points were fitted to a continuous mass or sedimentation coefficient dis-
tribution model using SEDFIT software (Schuck, 2000; Schuck et al., 2002).
SEDNTERP (Laue et al., 1992) was used to estimate solvent density, solvent
viscosity, and the partial specific volume of DHDPS for analysis. Standardized
weight-average sedimentation coefficients (s20,w) were also calculated in
SEDNTERP (Laue et al., 1992).
Enzyme Kinetics
For quantitative analysis of DHDPS enzymatic activity, this study employed
a coupled assay as described previously (Atkinson et al., 2014; Burgess
et al., 2008b; Dobson et al., 2005b; Dogovski et al., 2013; Griffin et al.,
BpDHDPS in the presence of lysine; well D3, CsDHDPS in the absence of lysine; well D4, CsDHDPS in the pres
lysine; well E2, CbDHDPS in the presence of lysine; well E3, EfDHDPS in the absence of lysine; well E4, EfD
(B) Lysine inhibition affinities (IC50) of DHDPS from newly characterized Gram-negative and Gram-positive b
1288 Structure 24, 1282–1291, August 2, 2016
2008, 2012; Voss et al., 2010). Substrate turn-
over was measured spectrophotometrically at
A340 nm ( 3340 nm = 6,220 M�1 cm�1) via the asso-
ciated oxidation of NADPH. Assays were pre-
pared in triplicate, incubated for 5 min at 30�Cin a temperature-controlled Cary 4000 UV/Vis
spectrophotometer (Varian), and initiated with
the substrate (S)-ASA. Initial velocities were
determined from the initial linear portion of the
reaction coordinate and averaged across tripli-
cate measurements. Initial velocity data were
analyzed using ENZFITTER (Biosoft) and fitted to the ping-pong mechanism
using Equation 1:
v = VmaxAB/(KM(B)A + KM(A)B + AB), (Equatio
n 1)where Vmax is the maximal velocity, KM(A) and KM(B) are the Michaelis-Menten
constants for each substrate, A and B are the substrate concentrations, and v
is the initial velocity.
To test for inhibition by lysine, we incubated all assay components except
(S)-ASA and lysine in a cuvette for 5min as described above. This was followed
by addition of lysine (final concentration range 0–5 mM) and a further 5-min in-
cubation. Reactions were initiated with (S)-ASA and rates were recorded as
described above. Data were fitted using Sigma Plot version 13.0.
o-Aminobenzaldehyde Assay
The o-aminobenzaldehyde (o-ABA) colorimetric activity assay (Yugari and Gil-
varg, 1965) was used to qualitatively determine DHDPS activity. Assays were
performed in 96-well plates with the addition of 100 ml of master mix solution
(200 mM Tris [pH 6.8], 30 mM pyruvate, 10 mM o-ABA, and 5 mM (S)-ASA)
in the presence or absence of 5 mM (S)-lysine. Appropriate controls of no
enzyme and no substrate were also included. Reactions were initiated with
5 mM of protein sample and incubated at 37�C for 20 min. Reactions were
Figure 6. Catalytic Activity of Gram-Positive
and Gram-Negative DHDPS Enzymes in the
Presence of (S)-Lysine(A) o-Aminobenzaldehyde assay showing the ac-
tivity of various DHDPS (5 mM) in the absence and
presence of 5 mM (S)-lysine. Purple color indicates
DHDPS activity. Well A1, no enzyme control in the
absence of lysine; well A2, no enzyme control in the
presence of lysine; well A3, no substrate control in
the absence of lysine; well A4, no substrate control
in the presence of lysine; well B1, EcDHDPS in the
absence of lysine; well B2, EcDHDPS in the pres-
ence of lysine; well B3, SaDHDPS in the absence
of lysine; well B4, SaDHDPS in the presence of
lysine; well C1, LpDHDPS in the absence of lysine;
well C2, LpDHDPS in the presence of lysine; well
C3, SpDHDPS in the absence of lysine; well
C4, SpDHDPS in the presence of lysine; well D1,
BpDHDPS in the absence of lysine; well D2,
ence of lysine; well E1, CbDHDPS in the absence of
HDPS in the presence of lysine.
acteria.
Figure 7. Thermodynamic and Kinetic Assays to Assess Lysine Binding and Inhibition
(A) Binding curves of lysine to wild-type EfDHDPS (squares) and EfDHDPS-E56K (circles) using the signal from Thermophoresis + T-jump microscale thermo-
phoresis experiments. Data represent mean ± SEM (N = 3).
(B) Inhibition curves of EfDHDPS (squares) and EfDHDPS-E56K (circles) in the presence of lysine. Data represented mean ± SEM (N = 3).
terminated by the addition of 100 ml of trichloroacetic acid (10% [v/v]). In the
presence of DHDPS activity a purple chromophore was observed, while in
its absence a pale yellow color was noted (Mitsakos et al., 2008).
Microscale Thermophoresis
Affinity measurements using microscale thermophoresis (MST) were carried
out with a Monolith NT.LabelFree instrument (NanoTemper Technologies).
Lysine diluted in water (20 mM to 2.44 mM) was mixed 1:1 with the enzyme,
yielding a final DHDPS concentration of 3 mM and a dilution series of 10 mM
to 1.22 mM for lysine. All experiments were incubated for 30min at 30�C, beforeapplying samples to Monolith NT Standard Treated Capillaries (NanoTemper
Technologies). Thermophoresis was measured at 30�C with laser off/on/off
times of 5 s/30 s/5 s. Experiments were conducted at 20% LED power and
40% MST IR laser power. Data from three independently performed experi-
ments were analyzed (NT.Analysis software version 1.5.41, NanoTemper
Technologies) using the signal from Thermophoresis + T-Jump.
Crystallization, Structure Determination, and Refinement
X-Raydiffraction experimentswere carried out at theAustralianSynchrotronon
theMX1beamline (Cowieson et al., 2015) usingBlu-Ice (McPhillips et al., 2002).
LpDHDPS was crystallized using the hanging-drop vapor diffusion method as
previously described (Siddiqui et al., 2013). Crystals were soaked in reservoir
solution containing 20% (v/v) 2-methyl-2,4-pentanediol (MPD) prior to data
collection. Indexing and integration of the diffraction data were performed
using iMOSFLM (Battye et al., 2011) scaling using SCALA (Evans, 2006). The
crystal was found to belong to space group P6122. The Matthews coefficient
of 2.64 A3 Da�1 with an estimated solvent content of 53.5% indicated that there
were two monomers in the asymmetric unit. Molecular replacement was per-
formedusing PHASER (McCoy et al., 2007)with a single chain ofPseudomonas
aeruginosa DHDPS as the search model (PDB: 3QZE; 54% sequence identity).
Iterative model building of the structure and refinement was performed in
WINCOOT (Emsley and Cowtan, 2004) and REFMAC5 (Murshudov et al.,
1997; Winn et al., 2011), respectively. A lysine bonded to pyruvate as a Schiff
basewas built in sketcher from theCCP4 program suite (CollaborativeCompu-
tational Project, Number 4, 1994). This modified lysine was used to replace
Lys160 in the model and fitted to the 2Fo � Fc electron density. The MPD mol-
ecules were also built in sketcher. Babinet scaling in REFMAC5 was applied in
the final rounds of refinement. Structure quality was assessed by MolProbity
and WINCOOT (Chen et al., 2010; Davis et al., 2007).
SpDHDPS was co-crystallized with (S)-lysine using the hanging-drop vapor
diffusionmethod as previously described (Dogovski et al., 2013; Sibarani et al.,
2010), with (S)-lysine added to the protein solution in a 1:1 ratio (1 ml of concen-
trated (S)-lysine at 1 M added to 1 ml of concentrated protein solution at 8 mg
ml�1). Crystals were soaked in reservoir solution containing 0.2 M sodium fluo-
ride, 20% (w/v) polyethylene glycol 3350, 0.1 M bis-Tris propane (pH 6.0), and
15% (w/v) glycerol prior to data collection at 100 K. A 97.8% complete dataset
was integrated to 1.88-A resolution using XDS (Kabsch, 2010) and scaled
using SCALA (Evans, 2006). Data analysis using phenix.xtriage (Zwart et al.,
2005) revealed the presence of pseudo-merohedral twinning, which resulted
in a space-group change from P42212 to P21212 with a = 106.37 A,
b = 106.23 A, and c = 60.38 A, similar to the parent unliganded structure of
SpDHDPS (Dogovski et al., 2013). Molecular replacement was carried out
using the programPHASER (McCoy et al., 2007) with the structure of the native
form of SpDHDPS (PDB: 3VFL), using the most complete monomer as the
search model, which packed one molecule in the asymmetric unit. The struc-
ture was refined using REFMAC5 (Murshudov et al., 1997; Winn et al., 2011),
including TLS refinement (Winn et al., 2003). Iterative model building was
carried out using the program Coot (Emsley and Cowtan, 2004).
SUPPLEMENTAL INFORMATION
Supplemental Information includes five figures and can be found with this
article online at http://dx.doi.org/10.1016/j.str.2016.05.019.
AUTHOR CONTRIBUTIONS
Conceptualization, M.A.P. and T.P.S.C.; Methodology, T.P.S.C., C.D., B.M.A.,
M.W.P., S.P., and M.A.P; Investigation, T.P.S.C., S.D., N.E.K., T.S., J.J.P., and
L.M.Z.; Formal Analysis, T.P.S.C., M.A.G., J.J.P., R.M.R.B., M.W.P., G.B.J.,
N.E.H., S.P., and M.A.P.; Writing – Original Draft, T.P.S.C.; Writing – Review &
Editing, T.P.S.C.,S.D.,M.A.G.,M.W.P.,G.B.J., S.P., J.J.P., andM.A.P.; Funding
Acquisition, M.A.P.; Resources, M.A.P.; Supervision, M.A.P. and C.D.
ACKNOWLEDGMENTS
Wewould firstly like to acknowledge the support and assistance of the friendly
staff at the CSIRO Collaborative Crystallisation Center (www.csiro.au/C3),
Melbourne, Australia, and the beamline scientists at the Australian Synchro-
tron, VIC, Australia. We would also like to thank Prof. Elizabeth Hartland
(Department of Microbiology and Immunology, The University of Melbourne)
for providing genomic DNA from L. pneumophila and A/Prof. Geoffrey Hogg
(Microbiological Diagnostic Unit, University of Melbourne, Public Health Lab-
oratory Network, Department of Health and Aging, Australia) for providing
genomic DNA from S. pneumoniae. M.A.P. and S.P. acknowledge the Austra-
lian Research Council for funding support (DP150103313), and T.P.S.C. and
M.W.P. the National Health and Medical Research Council of Australia for
fellowship support (APP1091976 and APP1021645). J.J.P. was funded by an
Structure 24, 1282–1291, August 2, 2016 1289
Australian Synchrotron fellowship. Funding from the Victorian Government
Operational Infrastructure Support Scheme to St Vincent’s Institute is
acknowledged. We would also like to acknowledge the La Trobe University-
Comprehensive Proteomics Platform for providing infrastructure and exper-
tise. Finally, we thank all members of the Perugini laboratory for helpful discus-
sions during the preparation of the manuscript.
Received: January 6, 2016
Revised: April 22, 2016
Accepted: May 6, 2016
Published: July 14, 2016
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