AMPylation of small GTPases by Fic enzymes.

Small GTPases orchestrate numerous cellular pathways, acting as molecular switches and regulatory hubs to transmit molecular signals and because of this, they are often the target of pathogens. During infection, pathogens manipulate host cellular networks using post-translational modifications (PTMs). AMPylation, the modification of proteins with AMP, has been identified as a common PTM utilized by pathogens to hijack GTPase signalling during infection. AMPylation is primarily carried out by enzymes with a filamentation induced by cyclic-AMP (Fic) domain. Modification of small GTPases by AMP renders GTPases impervious to upstream regulatory inputs, resulting in unregulated downstream effector outputs for host cellular processes. Here, we overview Fic-mediated AMPylation of small GTPases by pathogens and other related PTMs catalysed by Fic enzymes on GTPases.

Fic-mediated AMPylation tempers the unfolded protein response during physiological stress.

The proper balance of synthesis, folding, modification, and degradation of proteins, also known as protein homeostasis, is vital to cellular health and function. The unfolded protein response (UPR) is activated when the mechanisms maintaining protein homeostasis in the endoplasmic reticulum become overwhelmed. However, prolonged or strong UPR responses can result in elevated inflammation and cellular damage. Previously, we discovered that the enzyme filamentation induced by cyclic-AMP (Fic) can modulate the UPR response via posttranslational modification of binding immunoglobulin protein (BiP) by AMPylation during homeostasis and deAMPylation during stress. Loss of fic in Drosophila leads to vision defects and altered UPR activation in the fly eye. To investigate the importance of Fic-mediated AMPylation in a mammalian system, we generated a conditional null allele of Fic in mice and characterized the effect of Fic loss on the exocrine pancreas. Compared to controls, Fic-/- mice exhibit elevated serum markers for pancreatic dysfunction and display enhanced UPR signaling in the exocrine pancreas in response to physiological and pharmacological stress. In addition, both fic-/- flies and Fic-/- mice show reduced capacity to recover from damage by stress that triggers the UPR. These findings show that Fic-mediated AMPylation acts as a molecular rheostat that is required to temper the UPR response in the mammalian pancreas during physiological stress. Based on these findings, we propose that repeated physiological stress in differentiated tissues requires this rheostat for tissue resilience and continued function over the lifetime of an animal.

Revisiting AMPylation through the lens of Fic enzymes.

AMPylation, a post-translational modification (PTM) first discovered in the late 1960s, is catalyzed by adenosine monophosphate (AMP)-transferring enzymes. The observation that filamentation-induced-by-cyclic-AMP (fic) enzymes are associated with this unique PTM revealed that AMPylation plays a major role in hijacking of host signaling by pathogenic bacteria during infection. Studies over the past decade showed that AMPylation is conserved across all kingdoms of life and, outside their role in infection, also modulates cellular functions. Many aspects of AMPylation are yet to be uncovered. In this review we present the advancement in research on AMPylation and Fic enzymes as well as other distinct classes of enzymes that catalyze AMPylation.

Specificity of AMPylation of the human chaperone BiP is mediated by TPR motifs of FICD.

To adapt to fluctuating protein folding loads in the endoplasmic reticulum (ER), the Hsp70 chaperone BiP is reversibly modified with adenosine monophosphate (AMP) by the ER-resident Fic-enzyme FICD/HYPE. The structural basis for BiP binding and AMPylation by FICD has remained elusive due to the transient nature of the enzyme-substrate-complex. Here, we use thiol-reactive derivatives of the cosubstrate adenosine triphosphate (ATP) to covalently stabilize the transient FICD:BiP complex and determine its crystal structure. The complex reveals that the TPR-motifs of FICD bind specifically to the conserved hydrophobic linker of BiP and thus mediate specificity for the domain-docked conformation of BiP. Furthermore, we show that both AMPylation and deAMPylation of BiP are not directly regulated by the presence of unfolded proteins. Together, combining chemical biology, crystallography and biochemistry, our study provides structural insights into a key regulatory mechanism that safeguards ER homeostasis.

Rab1-AMPylation by Legionella DrrA is allosterically activated by Rab1.

Legionella pneumophila infects eukaryotic cells by forming a replicative organelle - the Legionella containing vacuole. During this process, the bacterial protein DrrA/SidM is secreted and manipulates the activity and post-translational modification (PTM) states of the vesicular trafficking regulator Rab1. As a result, Rab1 is modified with an adenosine monophosphate (AMP), and this process is referred to as AMPylation. Here, we use a chemical approach to stabilise low-affinity Rab:DrrA complexes in a site-specific manner to gain insight into the molecular basis of the interaction between the Rab protein and the AMPylation domain of DrrA. The crystal structure of the Rab:DrrA complex reveals a previously unknown non-conventional Rab-binding site (NC-RBS). Biochemical characterisation demonstrates allosteric stimulation of the AMPylation activity of DrrA via Rab binding to the NC-RBS. We speculate that allosteric control of DrrA could in principle prevent random and potentially cytotoxic AMPylation in the host, thereby perhaps ensuring efficient infection by Legionella.

Identification of targets of AMPylating Fic enzymes by co-substrate-mediated covalent capture.

Various pathogenic bacteria use post-translational modifications to manipulate the central components of host cell functions. Many of the enzymes released by these bacteria belong to the large Fic family, which modify targets with nucleotide monophosphates. The lack of a generic method for identifying the cellular targets of Fic family enzymes hinders investigation of their role and the effect of the post-translational modification. Here, we establish an approach that uses reactive co-substrate-linked enzymes for proteome profiling. We combine synthetic thiol-reactive nucleotide derivatives with recombinantly produced Fic enzymes containing strategically placed cysteines in their active sites to yield reactive binary probes for covalent substrate capture. The binary complexes capture their targets from cell lysates and permit subsequent identification. Furthermore, we determined the structures of low-affinity ternary enzyme-nucleotide-substrate complexes by applying a covalent-linking strategy. This approach thus allows target identification of the Fic enzymes from both bacteria and eukarya.

Sortase-Mediated Quantifiable Enzyme Immobilization on Magnetic Nanoparticles.

Protein immobilization has gained high interest in recent years for its valuable applications in life sciences involving drug delivery and protein arrays. Herein, we combine sortase-mediated protein immobilization with the versatility of magnetic nanoparticles and a sensitive GFP-based quantification system. Using this method, we successfully immobilized and quantified the amount of coupled enzymes by fluorescence spectroscopy and assessed their activity by kinetic measurements. We show that sortase-mediated coupling of enzymes enables preparation of biological samples with a high demand of purity as demonstrated by single-molecule FRET. Here, we report that sortase-mediated protein ligation allows both N- and C-terminal site-specific protein immobilization. Additionally, we demonstrate that sortase-mediated protein immobilization is suitable for direct protein immobilization from complex lysates. Direct immobilization from lysate allows study of enzyme functionality without the need of time-consuming enzyme purification, while magnetic nanoparticles permit easy addition and removal of coupled enzymes to and from a reaction mixture.