47 research outputs found
Building a Molecular Trap for a Serine Protease from Aptamer and Peptide Modules
In drug development, molecular intervention
strategies are usually
based on interference with a single protein function, such as enzyme
activity or receptor binding. However, in many cases, protein drug
targets are multifunctional, with several molecular functions contributing
to their pathophysiological actions. Aptamers and peptides are interesting
synthetic building blocks for the design of multivalent molecules
capable of modulating multiple functions of a target protein. Here,
we report a molecular trap with the ability to interfere with the
activation, catalytic activity, receptor binding, etc. of the serine
protease urokinase-type plasminogen activator (uPA) by a rational
combination of two RNA aptamers and a peptide with different inhibitory
properties. The assembly of these artificial inhibitors into one molecule
enhanced the inhibitory activity between 10- and 10,000-fold toward
several functions of uPA. The study highlights the potential of multivalent
designs and illustrates how they can easily be constructed from aptamers
and peptides using nucleic acid engineering, chemical synthesis, and
bioconjugation chemistry. By aptamer to aptamer and aptamer to peptide
conjugation, we created, to the best of our knowledge, the first trivalent
molecule which combines three artificial inhibitors binding to three
different sites in a protein target. We hypothesize that by simultaneously
preventing all of the functional interactions and activities of the
target protein, this approach may represent an alternative to siRNA
technology for a functional knockout
Allosteric Inactivation of a Trypsin-Like Serine Protease by An Antibody Binding to the 37- and 70-Loops
Serine
protease catalytic activity is in many cases regulated by
conformational changes initiated by binding of physiological modulators
to exosites located distantly from the active site. Inhibitory monoclonal
antibodies binding to such exosites are potential therapeutics and
offer opportunities for elucidating fundamental allosteric mechanisms.
The monoclonal antibody mU1 has previously been shown to be able to
inhibit the function of murine urokinase-type plasminogen activator
in vivo. We have now mapped the epitope of mU1 to the catalytic domain’s
37- and 70-loops, situated about 20 Ă… from the S1 specificity
pocket of the active site. Our data suggest that binding of mU1 destabilizes
the catalytic domain and results in conformational transition into
a state, in which the N-terminal amino group of Ile16 is less efficiently
stabilizing the oxyanion hole and in which the active site has a reduced
affinity for substrates and inhibitors. Furthermore, we found evidence
for functional interactions between residues in uPA’s C-terminal
catalytic domain and its N-terminal A-chain, as deletion of the A-chain
facilitates the mU1-induced conformational distortion. The inactive,
distorted state is by several criteria similar to the E* conformation
described for other serine proteases. Hence, agents targeting serine
protease conformation through binding to exosites in the 37- and 70-loops
represent a new class of potential therapeutics
Ligand binding modulates the structural dynamics and activity of urokinase-type plasminogen activator: A possible mechanism of plasminogen activation
<div><p>The catalytic activity of trypsin-like serine proteases is in many cases regulated by conformational changes initiated by binding of physiological modulators to exosites located distantly from the active site. A trypsin-like serine protease of particular interest is urokinase-type plasminogen activator (uPA), which is involved in extracellular tissue remodeling processes. Herein, we used hydrogen/deuterium exchange mass spectrometry (HDXMS) to study regulation of activity in the catalytic domain of the murine version of uPA (muPA) by two muPA specific monoclonal antibodies. Using a truncated muPA variant (muPA<sup>16-243</sup>), containing the catalytic domain only, we show that the two monoclonal antibodies, despite binding to an overlapping epitope in the 37s and 70s loops of muPA<sup>16-243</sup>, stabilize distinct muPA<sup>16-243</sup> conformations. Whereas the inhibitory antibody, mU1 was found to increase the conformational flexibility of muPA<sup>16-243</sup>, the stimulatory antibody, mU3, decreased muPA<sup>16-243</sup> conformational flexibility. Furthermore, the HDXMS data unveil the existence of a pathway connecting the 70s loop to the active site region. Using alanine scanning mutagenesis, we further identify the 70s loop as an important exosite for the activation of the physiological uPA substrate plasminogen. Thus, the data presented here reveal important information about dynamics in uPA by demonstrating how various ligands can modulate uPA activity by mediating long-range conformational changes. Moreover, the results provide a possible mechanism of plasminogen activation.</p></div
Dissecting the Effect of RNA Aptamer Binding on the Dynamics of Plasminogen Activator Inhibitor 1 Using Hydrogen/Deuterium Exchange Mass Spectrometry
RNA
aptamers, selected from large synthetic libraries, are attracting
increasing interest as protein ligands, with potential uses as prototype
pharmaceuticals, conformational probes, and reagents for specific
quantification of protein levels in biological samples. Very little
is known, however, about their effects on protein conformation and
dynamics. We have employed hydrogen/deuterium exchange (HDX) mass
spectrometry to study the effect of RNA aptamers on the structural
flexibility of the serpin plasminogen activator inhibitor-1 (PAI-1).
The aptamers have characteristic effects on the biochemical properties
of PAI-1. In particular, they are potent inhibitors of the structural
transition of PAI-1 from the active state to the inactive, so-called
latent state. This transition is one of the largest conformational
changes of a folded protein domain without covalent modification.
Binding of the aptamers to PAI-1 is associated with substantial and
widespread protection against deuterium uptake in PAI-1. The aptamers
induce protection against exchange with the solvent both in the protein-aptamer
interface as well as in other specific areas. Interestingly, the aptamers
induce substantial protection against exchange in α-helices
B, C and I. This observation substantiates the relevance of structural
instability in this region for transition to the latent state and
argues for involvement of flexibility in regions not commonly associated
with regulation of latency transition in serpins
Relative deuterium uptake plots for peptides in <i>apo</i>- muPA<sup>16-243</sup> versus FabmU1:muPA<sup>16-243</sup> and FabmU3:muPA<sup>16-243</sup>.
<p>The figure shows uptake plots from peptides covering the 37s and 70s. Peptide sequence, masses and residues numbers are shown for each peptide. The Y-axis is scaled to show the theoretical maximum deuterium uptake of the corresponding peptide. Error bars, s.d. (n = 3 independent measurements).</p
Hydrogen/Deuterium Exchange Mass Spectrometry Reveals Specific Changes in the Local Flexibility of Plasminogen Activator Inhibitor 1 upon Binding to the Somatomedin B Domain of Vitronectin
The native fold of plasminogen activator inhibitor 1
(PAI-1) represents
an active metastable conformation that spontaneously converts to an
inactive latent form. Binding of the somatomedin B domain (SMB) of
the endogenous cofactor vitronectin to PAI-1 delays the transition
to the latent state and increases the thermal stability of the protein
dramatically. We have used hydrogen/deuterium exchange mass spectrometry
to assess the inherent structural flexibility of PAI-1 and to monitor
the changes induced by SMB binding. Our data show that the PAI-1 core
consisting of β-sheet B is rather protected against exchange
with the solvent, while the remainder of the molecule is more dynamic.
SMB binding causes a pronounced and widespread stabilization of PAI-1
that is not confined to the binding interface with SMB. We further
explored the local structural flexibility in a mutationally stabilized
PAI-1 variant (14-1B) as well as the effect of stabilizing antibody
Mab-1 on wild-type PAI-1. The three modes of stabilizing PAI-1 (SMB,
Mab-1, and the mutations in 14-1B) all cause a delayed latency transition,
and this effect was accompanied by unique signatures on the flexibility
of PAI-1. Reduced flexibility in the region around helices B, C, and
I was seen in all three cases, which suggests an involvement of this
region in mediating structural flexibility necessary for the latency
transition. These data therefore add considerable depth to our current
understanding of the local structural flexibility in PAI-1 and provide
novel indications of regions that may affect the functional stability
of PAI-1
Relative deuterium uptake plots for peptides in <i>apo</i>-muPA<sup>16-243</sup> versus FabmU1:muPA and FabmU3:muPA.
<p>The figure shows uptake plots from peptides covering <b>(A)</b> the 180s loop, <b>(B)</b> the 220s loop, <b>(C)</b> the 140s loop, <b>(D)</b> the 170s loop and the β9-strand. Peptide sequence, masses and residues numbers are shown for each peptide. The Y-axis is scaled to show the theoretical maximum deuterium uptake of the corresponding peptide. Error bars, s.d. (n = 3 independent measurements).</p
Hydrogen/Deuterium Exchange Mass Spectrometry Reveals Specific Changes in the Local Flexibility of Plasminogen Activator Inhibitor 1 upon Binding to the Somatomedin B Domain of Vitronectin
The native fold of plasminogen activator inhibitor 1
(PAI-1) represents
an active metastable conformation that spontaneously converts to an
inactive latent form. Binding of the somatomedin B domain (SMB) of
the endogenous cofactor vitronectin to PAI-1 delays the transition
to the latent state and increases the thermal stability of the protein
dramatically. We have used hydrogen/deuterium exchange mass spectrometry
to assess the inherent structural flexibility of PAI-1 and to monitor
the changes induced by SMB binding. Our data show that the PAI-1 core
consisting of β-sheet B is rather protected against exchange
with the solvent, while the remainder of the molecule is more dynamic.
SMB binding causes a pronounced and widespread stabilization of PAI-1
that is not confined to the binding interface with SMB. We further
explored the local structural flexibility in a mutationally stabilized
PAI-1 variant (14-1B) as well as the effect of stabilizing antibody
Mab-1 on wild-type PAI-1. The three modes of stabilizing PAI-1 (SMB,
Mab-1, and the mutations in 14-1B) all cause a delayed latency transition,
and this effect was accompanied by unique signatures on the flexibility
of PAI-1. Reduced flexibility in the region around helices B, C, and
I was seen in all three cases, which suggests an involvement of this
region in mediating structural flexibility necessary for the latency
transition. These data therefore add considerable depth to our current
understanding of the local structural flexibility in PAI-1 and provide
novel indications of regions that may affect the functional stability
of PAI-1
Generation and characterization of FabmU1 and FabmU3.
<p><b>(A)</b> SDS-PAGE analysis of the whole IgG and papain-cleaved IgG after protein A affinity chromatography. <b>(B)</b> The effect of FabmU1 (left) and FabmU3 (right) to the catalytic activity of muPA<sup>16-243</sup> towards the small chromogenic substrate Glu-Gly-Arg-pNA (CS-61(44)). Error bars, s.d. (n = 3 independent measurements).</p
Kinetic analysis for hydrolysis of a chromogenic substrate CS-61(44) by full-length muPA and variants.
<p>Kinetic analysis for hydrolysis of a chromogenic substrate CS-61(44) by full-length muPA and variants.</p