19 research outputs found
Ion Mobility-Mass Spectrometry Differentiates Protein Quaternary Structures Formed in Solution and in Electrospray Droplets
Electrospray ionization coupled to
mass spectrometry is a key technology for determining the stoichiometries
of multiprotein complexes. Despite highly accurate results for many
assemblies, challenging samples can generate signals for artifact
proteinâprotein binding born of the crowding forces present
within drying electrospray droplets. Here, for the first time, we
study the formation of preferred protein quaternary structures within
such rapidly evaporating nanodroplets. We use ion mobility and tandem
mass spectrometry to investigate glutamate dehydrogenase dodecamers
and serum amyloid P decamers as a function of protein concentration,
along with control experiments using carefully chosen protein analogues,
to both establish the formation of operative mechanisms and assign
the bimodal conformer populations observed. Further, we identify an
unprecedented symmetric collision-induced dissociation pathway that
we link directly to the quaternary structures of the precursor ions
selected
Robotically Assisted Titration Coupled to Ion Mobility-Mass Spectrometry Reveals the Interface Structures and Analysis Parameters Critical for Multiprotein Topology Mapping
Multiprotein complexes have three-dimensional
shapes and dynamic
functions that impact almost every aspect of biochemistry. Despite
this, our ability to rapidly assess the structures of such macromolecules
lags significantly behind high-throughput efforts to identify their
function, especially in the context of human disease. Here, we describe
results obtained by coupling ion mobility-mass spectrometry with automated
robotic sampling of different solvent compositions. This combination
of technologies has allowed us to explore an extensive set of solution
conditions for a group of eight protein homotetramers, representing
a broad sample of protein structure and stability space. We find that
altering solution ionic strength in concert with dimethylsulfoxide
content is sufficient to disrupt the proteinâprotein interfaces
of all of the complexes studied here. Ion mobility measurements captured
for both intact assemblies and subcomplexes match expected values
from available X-ray structures in all cases save two. For these exceptions,
we find that distorted subcomplexes result from extreme disruption
conditions, and are accompanied by small shifts in intact tetramers
size, thus enabling the removal of distorted subcomplex data in downstream
models. Furthermore, we find strong correlations between the relative
intensities of disrupted protein tetramers and the relative number
and type of interactions present at interfaces as a function of disrupting
agent added. In most cases, this correlation appears strong enough
to quantify various types of protein interfacial interactions within
unknown proteins following appropriate calibration
Ion Mobility-Mass Spectrometry Reveals a Dipeptide That Acts as a Molecular Chaperone for Amyloid β
Previously, we discovered and structurally
characterized a complex between amyloid β 1â40 and the
neuropeptide leucine enkephalin. This work identified leucine enkephalin
as a potentially useful starting point for the discovery of peptide-related
biotherapeutics for Alzheimerâs disease. In order to better
understand such complexes that are formed <i>in vitro</i>, we describe here the analysis of a series of site-directed amino
acid substitution variants of both peptides, covering the leucine
enkephalin sequence in its entirety and a large number of selected
residues of amyloid β 1â40 (residues: D1, E3, F4, R5,
H6, Y10, E11, H13, H14, Q15, K16, E22, K28, and V40). Ion mobilityâmass
spectrometry measurements and molecular dynamics simulations reveal
that the hydrophobic C-terminus of leucine enkephalin (Phe-Leu, FL)
is crucial for the formation of peptide complexes. As such, we explore
here the interaction of the dipeptide FL with both wildtype and variant
forms of amyloid β in order to structurally characterize the
complexes formed. We find that FL binds preferentially to amyloid
β oligomers and attaches to amyloid β within the region
between its N-terminus and its hydrophobic core, most specifically
at residues Y10 and Q15. We further show that FL is able to prevent
fibril formation
Chemical Probes and Engineered Constructs Reveal a Detailed Unfolding Mechanism for a Solvent-Free Multidomain Protein
Despite
the growing application of gas-phase measurements in structural
biology and drug discovery, the factors that govern protein stabilities
and structures in a solvent-free environment are still poorly understood.
Here, we examine the solvent-free unfolding pathway for a group of
homologous serum albumins. Utilizing a combination of chemical probes
and noncovalent reconstructions, we draw new specific conclusions
regarding the unfolding of albumins in the gas phase, as well as more
general inferences regarding the sensitivity of collision induced
unfolding to changes in protein primary and tertiary structure. Our
findings suggest that the general unfolding pathway of low charge
state albumin ions is largely unaffected by changes in primary structure;
however, the stabilities of intermediates along these pathways vary
widely as sequences diverge. Additionally, we find that human albumin
follows a domain associated unfolding pathway, and we are able to
assign each unfolded form observed in our gas-phase data set to the
disruption of specific domains within the protein. The totality of
our data informs the first detailed mechanism for multidomain protein
unfolding in the gas phase, and highlights key similarities and differences
from the known solution-phase pathway
Free Radical-Based Sequencing for Native Top-Down Mass Spectrometry
Native top-down proteomics
allows for both proteoform
identification
and high-order structure characterization for cellular protein complexes.
Unfortunately, tandem MS-based fragmentation efficiencies for such
targets are low due to an increase in analyte ion mass and the low
ion charge states that characterize native MS data. Multiple fragmentation
methods can be integrated in order to increase protein complex sequence
coverage, but this typically requires use of specialized hardware
and software. Free-radical-initiated peptide sequencing (FRIPS) enables
access to charge-remote and electron-based fragmentation channels
within the context of conventional CID experiments. Here, we optimize
FRIPS labeling for native top-down sequencing experiments. Our labeling
approach is able to access intact complexes with TEMPO-based FRIPS
reagents without significant protein denaturation or assembly disruption.
By combining CID and FRIPS datasets, we observed sequence coverage
improvements as large as 50% for protein complexes ranging from 36
to 106 kDa. Fragment ion production in these experiments was increased
by as much as 102%. In general, our results indicate that TEMPO-based
FRIPS reagents have the potential to dramatically increase sequence
coverage obtained in native top-down experiments
Collision Induced Unfolding of Intact Antibodies: Rapid Characterization of Disulfide Bonding Patterns, Glycosylation, and Structures
Monoclonal antibodies
(mAbs) are among the fastest growing class
of therapeutics due to their high specificity and low incidence of
side effects. Unlike most drugs, mAbs are complex macromolecules (âź150
kDa), leading to a host of quality control and characterization challenges
inherent in their development. Recently, we introduced a new approach
for the analysis of the intact proteins based on ion mobility-mass
spectrometry (IM-MS). Our protocol involves the collision induced
unfolding (CIU) of intact antibodies, where collisional heating in
the gas-phase is used to generate unfolded antibody forms, which are
subsequently separated by IM and then analyzed by MS. Collisional
energy is added to the antibody ions in a stepwise fashion, and âfingerprint
plotsâ are created that track the amount of unfolding undergone
as a function of the energy imparted to the ions prior to IM separation.
In this report, we have used these fingerprints to rapidly distinguish
between antibody isoforms, possessing different numbers and/or patterns
of disulfide bonding and general levels of glycosylation. In addition,
we validate our CIU protocols through control experiments and systematic
statistical evaluations of CIU reproducibility. We conclude by projecting
the impact of our approach for antibody-related drug discovery and
development applications
Ion Mobility-Mass Spectrometry Analysis of Cross-Linked Intact Multiprotein Complexes: Enhanced Gas-Phase Stabilities and Altered Dissociation Pathways
Analysis of protein complexes by
ion mobility-mass spectrometry
is a valuable method for the rapid assessment of complex composition,
binding stoichiometries, and structures. However, capturing labile,
unknown protein assemblies directly from cells remains a challenge
for the technology. Furthermore, ion mobility-mass spectrometry measurements
of complexes, subcomplexes, and subunits are necessary to build complete
models of intact assemblies, and such data can be difficult to acquire
in a comprehensive fashion. Here, we present the use of novel mass
spectrometry cleavable cross-linkers and tags to stabilize intact
protein complexes for ion mobility-mass spectrometry. Our data reveal
that tags and linkers bearing permanent charges are superior stabilizers
relative to neutral cross-linkers, especially in the context of retaining
compact forms of the assembly under a wide array of activating conditions.
In addition, when cross-linked protein complexes are collisionally
activated in the gas phase, a larger proportion of the product ions
produced are often more compact and reflect native protein subcomplexes
when compared with unmodified complexes activated in the same fashion,
greatly enabling applications in structural biology
IMTBX and Grppr: Software for Top-Down Proteomics Utilizing Ion Mobility-Mass Spectrometry
Top-down
proteomics has emerged as a transformative method for
the analysis of protein sequence and post-translational modifications
(PTMs). Top-down experiments have historically been performed primarily
on ultrahigh resolution mass spectrometers due to the complexity of
spectra resulting from fragmentation of intact proteins, but recent
advances in coupling ion mobility separations to faster, lower resolution
mass analyzers now offer a viable alternative. However, software capable
of interpreting the highly complex two-dimensional spectra that result
from coupling ion mobility separation to top-down experiments is currently
lacking. In this manuscript we present a software suite consisting
of two programs, IMTBX (âIM Toolboxâ) and Grppr (âGrouperâ),
that enable fully automated processing of such data. We demonstrate
the capabilities of this software suite by examining a series of intact
proteins on a Waters Synapt G2 ion-mobility equipped mass spectrometer
and compare the results to the manual and semiautomated data analysis
procedures we have used previously
IMTBX and Grppr: Software for Top-Down Proteomics Utilizing Ion Mobility-Mass Spectrometry
Top-down
proteomics has emerged as a transformative method for
the analysis of protein sequence and post-translational modifications
(PTMs). Top-down experiments have historically been performed primarily
on ultrahigh resolution mass spectrometers due to the complexity of
spectra resulting from fragmentation of intact proteins, but recent
advances in coupling ion mobility separations to faster, lower resolution
mass analyzers now offer a viable alternative. However, software capable
of interpreting the highly complex two-dimensional spectra that result
from coupling ion mobility separation to top-down experiments is currently
lacking. In this manuscript we present a software suite consisting
of two programs, IMTBX (âIM Toolboxâ) and Grppr (âGrouperâ),
that enable fully automated processing of such data. We demonstrate
the capabilities of this software suite by examining a series of intact
proteins on a Waters Synapt G2 ion-mobility equipped mass spectrometer
and compare the results to the manual and semiautomated data analysis
procedures we have used previously
Collision-Induced Unfolding Reveals Disease-Associated Stability Shifts in Mitochondrial Transfer Ribonucleic Acids
Ribonucleic acids (RNAs) remain challenging
targets for
structural
biology, creating barriers to understanding their vast functions in
cellular biology and fully realizing their applications in biotechnology.
The inherent dynamism of RNAs creates numerous obstacles in capturing
their biologically relevant higher-order structures (HOSs), and as
a result, many RNA functions remain unknown. In this study, we describe
the development of native ion mobilityâmass spectrometry and
collision-induced unfolding (CIU) for the structural characterization
of a variety of RNAs. We evaluate the ability of these techniques
to preserve native structural features in the gas phase across a wide
range of functional RNAs. Finally, we apply these tools to study the
elusive mitochondrial encephalopathy, lactic acidosis, and stroke-like
episodes-associated A3243G mutation. Our data demonstrate that our
experimentally determined conditions preserve some solution-state
memory of RNAs via the correlated complexity of CIU fingerprints and
RNA HOS, the observation of predicted stability shifts in the control
RNA samples, and the retention of predicted magnesium binding events
in gas-phase RNA ions. Significant differences in collision cross
section and stability are observed as a function of the A3243G mutation
across a subset of the mitochondrial tRNA maturation pathway. We conclude
by discussing the potential application of CIU for the development
of RNA-based biotherapeutics and, more broadly, transcriptomic characterization