Targeting oncogenic KRasG13C with nucleotide-based covalent inhibitors

Mutations within Ras proteins represent major drivers in human cancer. In this study, we report the structure-based design, synthesis, as well as biochemical and cellular evaluation of nucleotide-based covalent inhibitors for KRasG13C, an important oncogenic mutant of Ras that has not been successfully addressed in the past. Mass spectrometry experiments and kinetic studies reveal promising molecular properties of these covalent inhibitors, and X-ray crystallographic analysis has yielded the first reported crystal structures of KRasG13C covalently locked with these GDP analogues. Importantly, KRasG13C covalently modified with these inhibitors can no longer undergo SOS-catalysed nucleotide exchange. As a final proof-of-concept, we show that in contrast to KRasG13C, the covalently locked protein is unable to induce oncogenic signalling in cells, further highlighting the possibility of using nucleotide-based inhibitors with covalent warheads in KRasG13C-driven cancer.

The Pseudo‐Natural Product Rhonin Targets RHOGDI

For the discovery of novel chemical matter generally endowed with bioactivity, strategies may be particularly efficient that combine previous insight about biological relevance, e.g., natural product (NP) structure, with methods that enable efficient coverage of chemical space, such as fragment‐based design. We describe the de novo combination of different 5‐membered NP‐derived N‐heteroatom fragments to structurally unprecedented “pseudo‐natural products” in an efficient complexity‐generating and enantioselective one‐pot synthesis sequence. The pseudo‐NPs inherit characteristic elements of NP structure but occupy areas of chemical space not covered by NP‐derived chemotypes, and may have novel biological targets. Investigation of the pseudo‐NPs in unbiased phenotypic assays and target identification led to the discovery of the first small‐molecule ligand of the RHO GDP‐dissociation inhibitor 1 (RHOGDI1), termed Rhonin. Rhonin inhibits the binding of the RHOGDI1 chaperone to GDP‐bound RHO GTPases and alters the subcellular localization of RHO GTPases.

KRasG12C inhibitors in clinical trials: a short historical perspective

Short historical perspective of the development of promising KRasG12C inhibitors that have recently entered clinical trials.

KRas is the most frequently mutated oncogene in human cancer, and even 40 years after the initial discovery of Ras oncogenes in 1982, no approved drug directly targets Ras in Ras-driven cancer. New information and approaches for direct targeting of mutant Ras have fueled hope for the development of direct KRas inhibitors. In this review, we provide a comprehensive historical perspective of the development of promising KRasG12C inhibitors that covalently bind to the mutated cysteine residue in the switch-II pocket and trap the protein in the inactive GDP bound state. After decades of failure, three covalent G12C-specific inhibitors from three independent companies have recently entered clinical trials and therefore represent new hope for patients suffering from KRasG12C driven cancer.

Mutant-Specific Targeting of Ras G12C Activity by Covalently Reacting Small Molecules

In this review we discuss and compare recently introduced molecules that are able to react covalently with an oncogenic mutant of KRas, KRas G12C. Two different classes of compounds in question have been developed, both leading to the mutant being locked in the inactive (guanosine diphosphate [GDP]-bound) state. The first are compounds that interact reversibly with the switch-II pocket (S-IIP) before covalent interaction. The second class interact in a competitive manner with the GDP/guanosine triphosphate (GTP) binding site. The fundamental physico-chemical principles of the two inhibitor classes are evaluated. For GDP/GTP-competing molecules, we show that special attention must be paid to the influence of guanine nucleotide exchange factors (GEFs) and their elevated activity in cells harboring abnormally activated Ras mutants. A new approach is suggested involving compounds that interact with the guanine binding site of the GTPase, but in a manner that is independent of the interaction of the GTPase with its cognate GEF.

Assays for Nucleotide Competitive Reversible and Irreversible Inhibitors of Ras GTPases

Although the Ras protein has been seen as a potential target for cancer therapy for the past 30 years, there was a tendency to consider it undruggable until recently. This has changed with the demonstration that small molecules with a specificity for (disease related mutants of) Ras can indeed be found, and some of these molecules form covalent adducts. A subgroup of these molecules can be characterized as competing with binding of the natural ligands GTP and GDP. Because of the distinct properties of Ras and related GTPases, in particular the very high nucleotide affinities and associated very low dissociation rates, assays for characterizing such molecules are not trivial. This is compounded by the fact that Ras family GTPases tend to be thermally unstable in the absence of a bound nucleotide. Here, we show that instead of using the unstable nucleotide-free Ras, the protein can be isolated as a 1:1 complex with a modified nucleotide (GDP-β-methyl ester) with low affinity to Ras. With this nucleotide analogue bound to the protein, testing of inhibitors is made experimentally more convenient and we present assays that allow the rapid assessment of the kinetic constants describing the inhibition process.

Structure of the tandem PX-PH domains of Bem3 from Saccharomyces cerevisiae

The structure of the tandem lipid-binding PX and pleckstrin-homology (PH) domains of the Cdc42 GTPase-activating protein Bem3 from Saccharomyces cerevisiae (strain S288c) has been determined to a resolution of 2.2 Å (Rwork = 21.1%, Rfree = 23.4%). It shows that the domains adopt a relative orientation that enables them to simultaneously bind to a membrane and suggests possible cooperativity in membrane binding.

Proximity-Triggered Covalent Stabilization of Low-Affinity Protein Complexes In Vitro and In Vivo

The characterization of low-affinity protein complexes is challenging due to their dynamic nature. Here, we present a method to stabilize transient protein complexes in vivo by generating a covalent and conformationally flexible bridge between the interaction partners. A highly active pyrrolysyl tRNA synthetase mutant directs the incorporation of unnatural amino acids bearing bromoalkyl moieties (BrCnK) into proteins. We demonstrate for the first time that low-affinity protein complexes between BrCnK-containing proteins and their binding partners can be stabilized in vivo in bacterial and mammalian cells. Using this approach, we determined the crystal structure of a transient GDP-bound complex between a small G-protein and its nucleotide exchange factor. We envision that this approach will prove valuable as a general tool for validating and characterizing protein-protein interactions in vitro and in vivo.

Nucleotide based covalent inhibitors of KRas can only be efficient in vivo if they bind reversibly with GTP-like affinity

Simple reversible competitive inhibition of nucleotide binding of GTP to Ras family GTPases has long been recognized as an unlikely approach to manipulating the activity of such proteins for experimental or therapeutic purposes. This is due to the high affinity of GTP to GTPases coupled with high cellular GTP concentrations, but also to problems of specificity for the highly conserved binding sites in GTPases. A recent approach suggested that these problems might be overcome by using GDP derivatives that can undergo a covalent reaction with disease specific mutants, in particular addressing inhibition of KRas_G12C using GDP equipped with an electrophilic group at the β-phosphate. We show here that a major drawback to this approach is a loss of reversible affinity of such β-modified derivatives for Ras of at least 10⁴ compared to GTP and GDP. With the help of a thorough kinetic characterization, we show that this leads to covalent reaction times that are too slow to make the compounds attractive for intracellular use, but that generation of a hypothetical reactive GDP derivative that retains the high reversible affinity of GDP/GTP to Ras might be a viable alternative.

Review: Ras GTPases and myosin: Qualitative conservation and quantitative diversification in signal and energy transduction

Most GTPases and many ATPases belong to the P‐loop class of proteins with significant structural and mechanistic similarities. Here we compare and contrast the basic properties of the Ras family GTPases and myosin, and conclude that there are fundamental similarities but also distinct differences related to their specific roles. © 2016 Wiley Periodicals, Inc. Biopolymers 105: 422–430, 2016.

Molecular control of Rab activity by GEFs, GAPs and GDI

Rab proteins are the major regulators of vesicular trafficking in eukaryotic cells. Their activity can be tightly controlled within cells: Regulated by guanine nucleotide exchange factors (GEFs) and GTPase activating proteins (GAPs), they switch between an active GTP-bound state and an inactive GDP-bound state, interacting with downstream effector proteins only in the active state. Additionally, they can bind to membranes via C-terminal prenylated cysteine residues and they can be solubilized and shuttled between membranes by chaperone-like molecules called GDP dissociation inhibitors (GDIs). In this review we give an overview of Rab proteins with a focus on the current understanding of their regulation by GEFs, GAPs and GDI.

Multivalency in Rab effector interactions

Rab proteins regulate vesicular transport in eukaryotic cells and establish connections to various cellular structures and processes by interacting with so-called effector molecules. Several of these effectors are known to not only bind a single Rab protein, but to be able to bind multiple different Rabs simultaneously. In this review we will give a short overview of effectors in general and (putative) functions of the aforementioned multivalent Rab:effector interactions.

bMERB domains are bivalent Rab8 family effectors evolved by gene duplication

In their active GTP-bound form, Rab proteins interact with proteins termed effector molecules. In this study, we have thoroughly characterized a Rab effector domain that is present in proteins of the Mical and EHBP families, both known to act in endosomal trafficking. Within our study, we show that these effectors display a preference for Rab8 family proteins (Rab8, 10, 13 and 15) and that some of the effector domains can bind two Rab proteins via separate binding sites. Structural analysis allowed us to explain the specificity towards Rab8 family members and the presence of two similar Rab binding sites that must have evolved via gene duplication. This study is the first to thoroughly characterize a Rab effector protein that contains two separate Rab binding sites within a single domain, allowing Micals and EHBPs to bind two Rabs simultaneously, thus suggesting previously unknown functions of these effector molecules in endosomal trafficking.

DOI:http://dx.doi.org/10.7554/eLife.18675.001

Protease-Resistant and Cell-Permeable Double-Stapled Peptides Targeting the Rab8a GTPase

Small GTPases comprise a family of highly relevant targets in chemical biology and medicinal chemistry research and have been considered "undruggable" due to the persisting lack of effective synthetic modulators and suitable binding pockets. As molecular switches, small GTPases control a multitude of pivotal cellular functions, and their dysregulation is associated with many human diseases such as various forms of cancer. Rab-GTPases represent the largest subfamily of small GTPases and are master regulators of vesicular transport interacting with various proteins via flat and extensive protein-protein interactions (PPIs). The only reported synthetic inhibitor of a PPI involving an activated Rab GTPase is the hydrocarbon stapled peptide StRIP3. However, this macrocyclic peptide shows low proteolytic stability and cell permeability. Here, we report the design of a bioavailable StRIP3 analogue that harbors two hydrophobic cross-links and exhibits increased binding affinity, combined with robust cellular uptake and extremely high proteolytic stability. Localization experiments reveal that this double-stapled peptide and its target protein Rab8a accumulate in the same cellular compartments. The reported approach offers a strategy for the implementation of biostability into conformationally constrained peptides while supporting cellular uptake and target affinity, thereby conveying drug-like properties.

A pull-down procedure for the identification of unknown GEFs for small GTPases

Members of the family of small GTPases regulate a variety of important cellular functions. In order to accomplish this, tight temporal and spatial regulation is absolutely necessary. The two most important factors for this regulation are GTPase activating proteins (GAPs) and guanine nucleotide exchange factors (GEFs), the latter being responsible for the activation of the GTPase downstream pathways at the correct location and time. Although a large number of exchange factors have been identified, it is likely that a similarly large number remains unidentified. We have therefore developed a procedure to specifically enrich GEF proteins from biological samples making use of the high affinity binding of GEFs to nucleotide-free GTPases. In order to verify the results of these pull-down experiments, we have additionally developed two simple validation procedures: An in vitro transcription/translation system coupled with a GEF activity assay and a yeast two-hybrid screen for detection of GEFs. Although the procedures were established and tested using the Rab protein Sec4, the similar basic principle of action of all nucleotide exchange factors will allow the method to be used for identification of unknown GEFs of small GTPases in general.

Locking GTPases covalently in their functional states

GTPases act as key regulators of many cellular processes by switching between active (GTP-bound) and inactive (GDP-bound) states. In many cases, understanding their mode of action has been aided by artificially stabilizing one of these states either by designing mutant proteins or by complexation with non-hydrolysable GTP analogues. Because of inherent disadvantages in these approaches, we have developed acryl-bearing GTP and GDP derivatives that can be covalently linked with strategically placed cysteines within the GTPase of interest. Binding studies with GTPase-interacting proteins and X-ray crystallography analysis demonstrate that the molecular properties of the covalent GTPase–acryl–nucleotide adducts are a faithful reflection of those of the corresponding native states and are advantageously permanently locked in a defined nucleotide (that is active or inactive) state. In a first application, in vivo experiments using covalently locked Rab5 variants provide new insights into the mechanism of correct intracellular localization of Rab proteins.

The cellular function of small GTPases is regulated by switching between active (GTP-bound) and inactive (GDP-bound) states. Here the authors develop nucleotide analogues that can be covalently linked to GTPases via a strategically placed cysteine residue to lock the target GTPase in defined activation states.

α-Synuclein interacts with the switch region of Rab8a in a Ser129 phosphorylation-dependent manner

Alpha-synuclein (αS) misfolding is associated with Parkinson's disease (PD) but little is known about the mechanisms underlying αS toxicity. Increasing evidence suggests that defects in membrane transport play an important role in neuronal dysfunction. Here we demonstrate that the GTPase Rab8a interacts with αS in rodent brain. NMR spectroscopy reveals that the C-terminus of αS binds to the functionally important switch region as well as the C-terminal tail of Rab8a. In line with a direct Rab8a/αS interaction, Rab8a enhanced αS aggregation and reduced αS-induced cellular toxicity. In addition, Rab8 - the Drosophila ortholog of Rab8a - ameliorated αS-oligomer specific locomotor impairment and neuron loss in fruit flies. In support of the pathogenic relevance of the αS-Rab8a interaction, phosphorylation of αS at S129 enhanced binding to Rab8a, increased formation of insoluble αS aggregates and reduced cellular toxicity. Our study provides novel mechanistic insights into the interplay of the GTPase Rab8a and αS cytotoxicity, and underscores the therapeutic potential of targeting this interaction.

Reaction mechanism of adenylyltransferase DrrA from Legionella pneumophila elucidated by time-resolved fourier transform infrared spectroscopy

Modulation of the function of small GTPases that regulate vesicular trafficking is a strategy employed by several human pathogens. Legionella pneumophila infects lung macrophages and injects a plethora of different proteins into its host cell. Among these is DrrA/SidM, which catalyzes stable adenylylation of Rab1b, a regulator of endoplasmatic reticulum to Golgi trafficking, and thereby alters the function and interactions of this small GTPase. We employed time-resolved FTIR-spectroscopy to monitor the DrrA-catalyzed AMP-transfer to Tyr77 of Rab1b. A transient complex between DrrA, adenylylated Rab1b, and the pyrophosphate byproduct was resolved, allowing us to analyze the interactions at the active site. Combination of isotopic labeling and site-directed mutagenesis allowed us to derive the catalytic mechanism of DrrA from the FTIR difference spectra. DrrA shares crucial residues in the ATP-binding pocket with similar AMP-transferring enzymes such as glutamine synthetase adenylyltransferase or kanamycin nucleotidyltransferase, but provides the complete active site on a single subunit. We determined that Asp112 of DrrA functions as the catalytic base for deprotonation of Tyr77 of Rab1b to enable nucleophilic attack on the ATP. The study provides detailed understanding of the Legionella pneumophila protein DrrA and of AMP-transfer reactions in general.

18O-Exchange by Hydrolyzing Enzymes: An ab initio Calculation

Enzymes which hydrolyse ATP cause an exchange of 180 of labelled Pi in the presence of ADP. A theory for the evaluation of rate constants from an observation of the time dependence of the concentration of the various Pi species is presented. Application to the 180 exchange catalysed by myosin SI as observed by 31P-NMR shows excellent agreement with values of the rate constants determined earlier.

Direct targeting of Rab-GTPase-effector interactions

Small GTPases are molecular switches using GDP/GTP alternation to control numerous vital cellular processes. Although aberrant function and regulation of GTPases are implicated in various human diseases, direct targeting of this class of proteins has proven difficult, as GTPase signaling and regulation is mediated by extensive and shallow protein interfaces. Here we report the development of inhibitors of protein-protein interactions involving Rab proteins, a subfamily of GTPases, which are key regulators of vesicular transport. Hydrocarbon-stapled peptides were designed based on crystal structures of Rab proteins bound to their interaction partners. These modified peptides exhibit significantly increased affinities and include a stapled peptide (StRIP3) that selectively binds to activated Rab8a and inhibits a Rab8a-effector interaction in vitro.

Rab GTPase prenylation hierarchy and its potential role in choroideremia disease

Protein prenylation is a widespread post-translational modification in eukaryotes that plays a crucial role in membrane targeting and signal transduction. RabGTPases is the largest group of post-translationally C-terminally geranylgeranylated. All Rabs are processed by Rab geranylgeranyl-transferase and Rab escort protein (REP). Human genetic defects resulting in the loss one of two REP isoforms REP-1, lead to underprenylation of RabGTPases that manifests in retinal degradation and blindness known as choroideremia. In this study we used a combination of microinjections and chemo-enzymatic tagging to establish whether Rab GTPases are prenylated and delivered to their target cellular membranes with the same rate. We demonstrate that although all tested Rab GTPases display the same rate of membrane delivery, the extent of Rab prenylation in 5 hour time window vary by more than an order of magnitude. We found that Rab27a, Rab27b, Rab38 and Rab42 display the slowest prenylation in vivo and in the cell. Our work points to possible contribution of Rab38 to the emergence of choroideremia in addition to Rab27a and Rab27b.

The role of Cdc42 and Gic1 in the regulation of septin filament formation and dissociation

Septins are guanine nucleotide-binding proteins that polymerize into filamentous and higher-order structures. Cdc42 and its effector Gic1 are involved in septin recruitment, ring formation and dissociation. The regulatory mechanisms behind these processes are not well understood. Here, we have used electron microscopy and cryo electron tomography to elucidate the structural basis of the Gic1-septin and Gic1-Cdc42-septin interaction. We show that Gic1 acts as a scaffolding protein for septin filaments forming long and flexible filament cables. Cdc42 in its GTP-form binds to Gic1, which ultimately leads to the dissociation of Gic1 from the filament cables. Surprisingly, Cdc42-GDP is not inactive, but in the absence of Gic1 directly interacts with septin filaments resulting in their disassembly. We suggest that this unanticipated dual function of Cdc42 is crucial for the cell cycle. Based on our results we propose a novel regulatory mechanism for septin filament formation and dissociation.

DOI:http://dx.doi.org/10.7554/eLife.01085.001

Septins are proteins that provide structural support for cells as they divide. Yeast cells are known to have seven types of septins, which have been widely studied, and 13 different septins have been identified in human cells, although they all seem similar to those found in yeast. Mutations in the genes that carry the genetic code for septins lead to a range of debilitating conditions in humans, including neurodegenerative diseases and male infertility.

An enzyme called Cdc42 is thought to have a key role in the formation of ring-like structures by septins before a cell divides, and in the subsequent dismantling of these rings after the cell has divided. A pair of proteins, called Gic1 and Gic2, is known to be critical for the formation of the septin rings, but the details of the interactions between these two proteins, Cdc42 and the septins are sketchy.

Now Sadian et al. have used two imaging approaches—electron microscopy and cryo-electron tomography—to scrutinise the role of Gic1 in greater detail in yeast cells. Gic1 interacts with specific subunits within adjacent septins, and these interactions have the effect of crosslinking the septins and stabilizing them in long filaments. However, high concentrations of the enzyme Cdc42 block the interaction between the Gic1 proteins and the subunits, causing the filaments to be dismantled. A future challenge will be to elucidate the interaction of these proteins in molecular detail using other techniques, in particular X-ray crystallography.

DOI:http://dx.doi.org/10.7554/eLife.01085.002

How not to do kinetics: examples involving GTPases and guanine nucleotide exchange factors

Guanine nucleotide exchange factors (GEFs) are crucial regulators of the action of GTPases in signal transduction and cellular regulation. Although their basic mechanism of action has been apparent for almost 20 years, there are still misconceptions concerning their properties, and these are confounded by superficial or incorrect interpretation of experimental results in individual cases. Here, an example is described in which an incorrect mechanism was derived because of an inadequate analysis of kinetic results. In a second example, a case is discussed where certain GTP analogs were erroneously described as being able to function as low molecular mass GEFs. In both cases, a lack of distinction between rates, rate constants, and apparent rate constants, together with a disregard of relative signal amplitudes, led to the misinterpretations. In a final example, it is shown how the lack of an appropriate kinetic investigation led to the false conclusion that a secreted protein from Legionella pneumophila can act not only as a GEF towards eukaryotic Rab1 but also as a factor that is able to actively dissociate the stable complex between Rab1 and GDP dissociation inhibitor.

Intermediates in the guanine nucleotide exchange reaction of Rab8 protein catalyzed by guanine nucleotide exchange factors Rabin8 and GRAB

Small G-proteins of the Ras superfamily control the temporal and spatial coordination of intracellular signaling networks by acting as molecular on/off switches. Guanine nucleotide exchange factors (GEFs) regulate the activation of these G-proteins through catalytic replacement of GDP by GTP. During nucleotide exchange, three distinct substrate·enzyme complexes occur: a ternary complex with GDP at the start of the reaction (G-protein·GEF·GDP), an intermediary nucleotide-free binary complex (G-protein·GEF), and a ternary GTP complex after productive G-protein activation (G-protein·GEF·GTP). Here, we show structural snapshots of the full nucleotide exchange reaction sequence together with the G-protein substrates and products using Rabin8/GRAB (GEF) and Rab8 (G-protein) as a model system. Together with a thorough enzymatic characterization, our data provide a detailed view into the mechanism of Rabin8/GRAB-mediated nucleotide exchange.

Pressure modulation of Ras-membrane interactions and intervesicle transfer

Proteins attached to the plasma membrane frequently encounter mechanical stresses, including high hydrostatic pressure (HHP) stress. Signaling pathways involving membrane-associated small GTPases (e.g., Ras) have been identified as critical loci for pressure perturbation. However, the impact of mechanical stimuli on biological outputs is still largely terra incognita. The present study explores the effect of HHP on the membrane association, dissociation, and intervesicle transfer process of N-Ras by using a FRET-based assay to obtain the kinetic parameters and volumetric properties along the reaction path of these processes. Notably, membrane association is fostered upon pressurization. Conversely, depending on the nature and lateral organization of the lipid membrane, acceleration or retardation is observed for the dissociation step. In addition, HHP can be inferred as a positive regulator of N-Ras clustering, in particular in heterogeneous membranes. The susceptibility of membrane interaction to pressure raises the idea of a role of lipidated signaling molecules as mechanosensors, transducing mechanical stimuli to chemical signals by regulating their membrane binding and dissociation. Finally, our results provide first insights into the influence of pressure on membrane-associated Ras-controlled signaling events in organisms living under extreme environmental conditions such as those that are encountered in the deep sea and sub-seafloor environments, where pressures reach the kilobar (100 MPa) range.

RabGEFs are a major determinant for specific Rab membrane targeting

Analysis of three different Rab-RabGEF pairs reveals that RabGEFs contain the minimal targeting machinery for recruiting Rabs to specific membranes.

Eukaryotic cells critically depend on the correct regulation of intracellular vesicular trafficking to transport biological material. The Rab subfamily of small guanosine triphosphatases controls these processes by acting as a molecular on/off switch. To fulfill their function, active Rab proteins need to localize to intracellular membranes via posttranslationally attached geranylgeranyl lipids. Each member of the manifold Rab family localizes specifically to a distinct membrane, but it is unclear how this specific membrane recruitment is achieved. Here, we demonstrate that Rab-activating guanosine diphosphate/guanosine triphosphate exchange factors (GEFs) display the minimal targeting machinery for recruiting Rabs from the cytosol to the correct membrane using the Rab-GEF pairs Rab5A–Rabex-5, Rab1A-DrrA, and Rab8-Rabin8 as model systems. Specific mistargeting of Rabex-5/DrrA/Rabin8 to mitochondria led to catalytic recruitment of Rab5A/Rab1A/Rab8A in a time-dependent manner that required the catalytic activity of the GEF. Therefore, RabGEFs are major determinants for specific Rab membrane targeting.

Crystal structure of the Rab binding domain of OCRL1 in complex with Rab8 and functional implications of the OCRL1/Rab8 module for Lowe syndrome

Mutations of the inositol-5-phosphatase OCRL1 cause Lowe syndrome. Lowe syndrome is an inherited disease characterized by renal dysfunction and impaired development of the eye and the nervous system. OCRL1 is a Rab effector protein that can bind to a large number of different Rab proteins. We have recently determined the X-ray structure of the Rab-binding domain of OCRL1 in complex with Rab8. Furthermore, we have characterized point mutations that abolish binding to Rab proteins and cause Lowe syndrome. Here we shortly review our recent biophysical and structural work and discuss possible functional implications of our finding that Rab8 binds with the highest affinity to OCRL1 among the Rab proteins tested. This could direct further work on OCRL1 leading to a better understanding of the complex disease mechanism of Lowe syndrome.

Mechanism of Rab1b deactivation by the Legionella pneumophila GAP LepB

Legionella pneumophila is an intracellularly surviving pathogen that releases about 270 different proteins into the host cell during infection. A set of secreted proteins takes control of the vesicular trafficking regulator Rab1. Legionella LepB inactivates Rab1 by acting as a GTPase-activating protein (GAP). We present the crystal structure of the Rab1b:LepB complex together with a thorough biochemical analysis and show that the GAP domain of LepB consists of an unusual fold. LepB acts by an atypical RabGAP mechanism that is reminiscent of classical GAPs and therefore sets the protein apart from mammalian TBC-like GAPs. Surprisingly, LepB can function as a GAP for Rab3, Rab8, Rab13 and Rab35, too, suggesting that it has a broader cellular role than previously thought.

Protein-DNA arrays as tools for detection of protein-protein interactions by mass spectrometry

Analysis of multiple protein-protein interactions using microarray technology remains challenging, and site-specific immobilization of functional proteins is a key step in these approaches. Here we establish the efficient synthesis of protein-DNA conjugates for several members of a small family of GTPases. The family of Rab/Ypt GTPases is intimately involved in vesicular trafficking in yeast and serves as a model for the much larger group of analogous human proteins, the Rab protein family, with more than 60 members. The Ypt-DNA hybrid molecules described here are used for DNA-directed immobilization on glass- and silica-based microarrays. Methods for the detection of protein-DNA conjugates, as well as approaches for nucleotide exchange and distinguishing between GDP- and GTP-bound Ypts on microarrays, are reported. The high specificity of different Rab/Ypt-effector interactions, which also depends on the bound nucleotide, is shown by fluorescence readout of microarrays. Furthermore, initial experiments demonstrate that direct readout by mass spectrometry can be achieved with commercially available instruments. These developments will significantly contribute to the elucidation of complex transport networks in eukaryotic cells.

A toolkit and benchmark study for FRET-restrained high-precision structural modeling

We present a comprehensive toolkit for Förster resonance energy transfer (FRET)-restrained modeling of biomolecules and their complexes for quantitative applications in structural biology. A dramatic improvement in the precision of FRET-derived structures is achieved by explicitly considering spatial distributions of dye positions, which greatly reduces uncertainties due to flexible dye linkers. The precision and confidence levels of the models are calculated by rigorous error estimation. The accuracy of this approach is demonstrated by docking a DNA primer-template to HIV-1 reverse transcriptase. The derived model agrees with the known X-ray structure with an r.m.s. deviation of 0.5 Å. Furthermore, we introduce FRET-guided 'screening' of a large structural ensemble created by molecular dynamics simulations. We used this hybrid approach to determine the formerly unknown configuration of the flexible single-strand template overhang.

Characterization of enzymes from Legionella pneumophila involved in reversible adenylylation of Rab1 protein

After the pathogenic bacterium Legionella pneumophila is phagocytosed, it injects more than 250 different proteins into the cytoplasm of host cells to evade lysosomal digestion and to replicate inside the host cell. Among these secreted proteins is the protein DrrA/SidM, which has been shown to modify Rab1b, a main regulator of vesicular trafficking in eukaryotic cells, by transfer of adenosine monophosphate (AMP) to Tyr(77). In addition, Legionella provides the protein SidD that hydrolytically reverses the covalent modification, suggesting a tight spatial and temporal control of Rab1 function by Legionella during infection. Small angle x-ray scattering experiments of DrrA allowed us to validate a tentative complex model built by combining available crystallographic data. We have established the effects of adenylylation on Rab1 interactions and properties in a quantitative way. In addition, we have characterized the kinetics of DrrA-catalyzed adenylylation as well as SidD-catalyzed deadenylylation toward Rab1 and have determined the nucleotide specificities of both enzymes. This study enhances our knowledge of proteins subverting Rab1 function at the Legionella-containing vacuole.

Quantitative analysis of prenylated RhoA interaction with its chaperone, RhoGDI

Small GTPases of the Rho family regulate cytoskeleton remodeling, cell polarity, and transcription, as well as the cell cycle, in eukaryotic cells. Membrane delivery and recycling of the Rho GTPases is mediated by Rho GDP dissociation inhibitor (RhoGDI), which forms a stable complex with prenylated Rho GTPases. We analyzed the interaction of RhoGDI with the active and inactive forms of prenylated and unprenylated RhoA. We demonstrate that RhoGDI binds the prenylated form of RhoA·GDP with unexpectedly high affinity (K(d) = 5 pm). The very long half-life of the complex is reduced 25-fold on RhoA activation, with a concomitant reduction in affinity (K(d) = 3 nm). The 2.8-Å structure of the RhoA·guanosine 5'-[β,γ-imido] triphosphate (GMPPNP)·RhoGDI complex demonstrated that complex formation forces the activated RhoA into a GDP-bound conformation in the absence of nucleotide hydrolysis. We demonstrate that membrane extraction of Rho GTPase by RhoGDI is a thermodynamically favored passive process that operates through a series of progressively tighter intermediates, much like the one that is mediated by RabGDI.

Psoromic acid is a selective and covalent Rab-prenylation inhibitor targeting autoinhibited RabGGTase

Post-translational attachment of geranylgeranyl isoprenoids to Rab GTPases, the key organizers of intracellular vesicular transport, is essential for their function. Rab geranylgeranyl transferase (RabGGTase) is responsible for prenylation of Rab proteins. Recently, RabGGTase inhibitors have been proposed to be potential therapeutics for treatment of cancer and osteoporosis. However, the development of RabGGTase selective inhibitors is complicated by its structural and functional similarity to other protein prenyltransferases. Herein we report identification of the natural product psoromic acid (PA) that potently and selectively inhibits RabGGTase with an IC(50) of 1.3 μM. Structure-activity relationship analysis suggested a minimal structure involving the depsidone core with a 3-hydroxyl and 4-aldehyde motif for binding to RabGGTase. Analysis of the crystal structure of the RabGGTase:PA complex revealed that PA forms largely hydrophobic interactions with the isoprenoid binding site of RabGGTase and that it attaches covalently to the N-terminus of the α subunit. We found that in contrast to other protein prenyltransferases, RabGGTase is autoinhibited through N-terminal (α)His2 coordination with the catalytic zinc ion. Mutation of (α)His dramatically enhances the reaction rate, indicating that the activity of RabGGTase is likely regulated in vivo. The covalent binding of PA to the N-terminus of the RabGGTase α subunit seems to potentiate its interaction with the active site and explains the selectivity of PA for RabGGTase. Therefore, psoromic acid provides a new starting point for the development of selective RabGGTase inhibitors.

Flexible and general synthesis of functionalized phosphoisoprenoids for the study of prenylation in vivo and in vitro

Protein modification with isoprenoid lipids affects hundreds of signaling proteins in eukaryotic cells. Modification of isoprenoids with reporter groups is the main approach for the creation of probes for the analysis of protein prenylation in vitro and in vivo. Here, we describe a new strategy for the synthesis of functionalized phosphoisoprenoids that uses an aminederivatized isoprenoid scaffold as a starting point for the synthesis of functionalized phosphoisoprenoid libraries. This overcomes a long-standing problem in the field, where multistep synthesis had to be carried out for each individual isoprenoid analogue. The described approach enabled us to synthesize a range of new compounds, including two novel fluorescent isoprenoids that previously could not be generated by conventional means. The fluorescent probes that were developed using the described approach possess significant spectroscopic advantages to all previously generated fluorescent isoprenoid analogue. Using these analogues for flow cytometry and cell imaging, we analyzed the uptake of isoprenoids by mammalian cells and zebrafish embryos. Furthermore, we demonstrate that derivatization of the scaffold can be coupled in a one-pot reaction to enzymatic incorporation of the resulting isoprenoid group into proteins. This enables rapid evaluation of functional groups for compatibility with individual prenyltransferases and identification of the prenyltransferase specific substrates.

Intein-mediated construction of a library of fluorescent Rab GTPase probes

Rab GTPases play a key role in the regulation of membrane trafficking. Post-translational geranylgeranylation is critical for their biological activity and is conferred by Rab geranylgeranyl transferease (RabGGTase), together with an accessory factor, Rab escort protein (REP). Mechanistic studies of Rab prenylation and identification of RabGGTase inhibitors require sensitive reporters of Rab prenylation. In the present work, a combination of protein engineering and expressed protein ligation was used to construct a library of semisynthetic Rab7 fluorescent conjugates. In order to avoid synthesis of a large number of fluorescently labeled peptides, we developed a strategy that combined thiol-reactive dye-labeling of cysteine with in vitro protein ligation. Application of this strategy required optimization of labeling and ligation conditions to promote thiol labeling and disfavor intramolecular cyclization. Using this approach, we constructed 46 fluorescent sensors with different spectral properties that reported on the interaction of Rab7 with RabGGTase, REP-1, and the overall prenylation reaction. Two constructs, Rab7Δ3CCK(NBD) and Rab7Δ2SCCC-dans, displayed 2.5- and 1.5-fold increase in fluorescence, respectively, upon prenylation. Moreover, dansyl-, NBD (4-nitro-benzofurazan)-, I-BA-, and I-SO-labeled Rab7 conjugates exhibited two- to tenfold change in fluorescence upon binding to REP or RabGGTase. These fluorescent sensors allowed us to monitor Rab prenylation in real time and to investigate the assembly of Rab-REP binary and Rab-REP-RabGGTase ternary complexes.

The original Michaelis constant: translation of the 1913 Michaelis-Menten paper

Nearly 100 years ago Michaelis and Menten published their now classic paper [Michaelis, L., and Menten, M. L. (1913) Die Kinetik der Invertinwirkung. Biochem. Z. 49, 333-369] in which they showed that the rate of an enzyme-catalyzed reaction is proportional to the concentration of the enzyme-substrate complex predicted by the Michaelis-Menten equation. Because the original text was written in German yet is often quoted by English-speaking authors, we undertook a complete translation of the 1913 publication, which we provide as Supporting Information . Here we introduce the translation, describe the historical context of the work, and show a new analysis of the original data. In doing so, we uncovered several surprises that reveal an interesting glimpse into the early history of enzymology. In particular, our reanalysis of Michaelis and Menten's data using modern computational methods revealed an unanticipated rigor and precision in the original publication and uncovered a sophisticated, comprehensive analysis that has been overlooked in the century since their work was published. Michaelis and Menten not only analyzed initial velocity measurements but also fit their full time course data to the integrated form of the rate equations, including product inhibition, and derived a single global constant to represent all of their data. That constant was not the Michaelis constant, but rather V(max)/K(m), the specificity constant times the enzyme concentration (k(cat)/K(m) × E(0)).

Atomic resolution structure of EhpR: phenazine resistance in Enterobacter agglomerans Eh1087 follows principles of bleomycin/mitomycin C resistance in other bacteria

BACKGROUND

The phenazines are redox-active secondary metabolites that a large number of bacterial strains produce and excrete into the environment. They possess antibiotic activity owing to the fact that they can reduce molecular oxygen to toxic reactive oxygen species. In order to take advantage of this activity, phenazine producers need to protect themselves against phenazine toxicity. Whereas it is believed that phenazine-producing pseudomonads possess highly active superoxide dismutases and catalases, it has recently been found that the plant-colonizing bacterium Enterobacter agglomerans expresses a small gene ehpR to render itself resistant towards D-alanyl-griseoluteic acid, the phenazine antibiotic produced by this strain.

RESULTS

To understand the resistance mechanism installed by EhpR we have determined its crystal structure in the apo form at 2.15 Å resolution and in complex with griseoluteic acid at 1.01 Å, respectively. While EhpR shares a common fold with glyoxalase-I/bleomycin resistance proteins, the ligand binding site does not contain residues that some related proteins employ to chemically alter their substrates. Binding of the antibiotic is mediated by π-stacking interactions of the aromatic moiety with the side chains of aromatic amino acids and by a few polar interactions. The dissociation constant KD between EhpR and griseoluteic acid was quantified as 244 ± 45 μM by microscale thermophoresis measurements.

CONCLUSIONS

The data accumulated here suggest that EhpR confers resistance by binding D-alanyl-griseoluteic acid and acting as a chaperone involved in exporting the antibiotic rather than by altering it chemically. It is tempting to speculate that EhpR acts in concert with EhpJ, a transport protein of the major facilitator superfamily that is also encoded in the phenazine biosynthesis operon of E. agglomerans. The low affinity of EhpR for griseoluteic acid may be required for its physiological function.

The versatile Legionella effector protein DrrA

The human pathogen Legionella pneumophila is a bacterium that infects human cells and interferes with intracellular signaling. The Legionella protein DrrA is one of the numerous effectors that the bacterium translocates into the host cytosol. DrrA binds to the Legionella containing vacuole (LCV), an organelle in which Legionella survives and replicates, and recruits and activates the vesicular trafficking regulator Rab1 to redirect vesicular trafficking between the endoplasmatic reticulum and the Golgi. After depositing Rab1 at the LCV, DrrA covalently modifies Rab1 with an AMP moiety at a specific tyrosine residue (Tyr77), which is centrally located in the functionally important switch II region. This adenylylation reaction interferes with the deactivation of Rab1 by GTPase activating proteins (GAPs), thereby presumably prolonging the active state of the protein at the LCV. Here, we summarize the versatile properties of DrrA and speculate on the effects of Rab1-adenylylation.