Integral membrane proteins carry out essential functions in the cell, and their activities are often modulated by specific protein-lipid interactions in the membrane. Here, we elucidate the intricate role of cardiolipin (CDL), a regulatory lipid, as a stabilizer of membrane proteins and their complexes. Using the in silico-designed model protein TMHC4_R (ROCKET) as a scaffold, we employ a combination of molecular dynamics simulations and native mass spectrometry to explore the protein features that facilitate preferential lipid interactions and mediate stabilization. We find that the spatial arrangement of positively charged residues as well as local conformational flexibility are factors that distinguish stabilizing from non-stabilizing CDL interactions. However, we also find that even in this controlled, artificial system, a clear-cut distinction between binding and stabilization is difficult to attain, revealing that overlapping lipid contacts can partially compensate for the effects of binding site mutations. Extending our insights to naturally occurring proteins, we identify a stabilizing CDL site within the E. coli rhomboid intramembrane protease GlpG and uncover its regulatory influence on enzyme substrate preference. In this work, we establish a framework for engineering functional lipid interactions, paving the way for the design of proteins with membrane-specific properties or functions.

• Keywords
• E. coli, lipid binding, mass spectrometry, membrane protein, molecular biophysics, structural biology,
• MeSH
• DNA-Binding Proteins MeSH
• Endopeptidases metabolism   chemistry   genetics   MeSH
• Escherichia coli metabolism   genetics   MeSH
• Cardiolipins * metabolism   chemistry   MeSH
• Membrane Proteins * metabolism   chemistry   genetics   MeSH
• Protein Engineering * MeSH
• Escherichia coli Proteins * metabolism   chemistry   genetics   MeSH
• Molecular Dynamics Simulation MeSH
• Protein Binding MeSH
• Publication type
• Journal Article MeSH
• Names of Substances
• DNA-Binding Proteins MeSH
• Endopeptidases MeSH
• GlpG protein, E coli MeSH Browser
• Cardiolipins * MeSH
• Membrane Proteins * MeSH
• Escherichia coli Proteins * MeSH

Rhomboid proteases are ubiquitous intramembrane serine proteases that can cleave transmembrane substrates within lipid bilayers. They exhibit many and diverse functions, such as but not limited to, growth factor signaling, immune and inflammatory response, protein quality control, and parasitic invasion. Human rhomboid protease RHBDL4 has been demonstrated to play a critical role in removing misfolded proteins from the endoplasmic reticulum and is implicated in severe diseases such as various cancers and Alzheimer's disease. Therefore, RHBDL4 is expected to constitute an important therapeutic target for such devastating diseases. Despite its critical role in many biological processes, the enzymatic properties of RHBDL4 remain largely unknown. To enable a comprehensive characterization of RHBDL4's kinetics, catalytic parameters, substrate specificity, and binding modality, we expressed and purified recombinant RHBDL4 and employed it in a Förster resonance energy transfer-based cleavage assay. Until now, kinetic studies have been limited mostly to bacterial rhomboid proteases. Our in vitro platform offers a new method for studying RHBDL4's enzymatic function and substrate preferences. Furthermore, we developed and tested potential inhibitors using our assay and successfully identified peptidyl α-ketoamide inhibitors of RHBDL4 that are highly effective against recombinant RHBDL4. We utilize ensemble docking and molecular dynamics simulations to explore the binding modality of substrate-derived peptides bound to RHBDL4. Our analysis focused on key interactions and dynamic movements within RHBDL4's active site that contributed to binding stability, offering valuable insights for optimizing the nonprime side of RHBDL4 ketoamide inhibitors. In summary, our study offers fundamental insights into RHBDL4's catalytic activities and substrate preferences, laying the foundation for downstream applications such as drug inhibitor screenings and structure-function studies, which will enable the identification of lead drug compounds for RHBDL4.

• Keywords
• endoplasmic reticulum stress, endoplasmic-reticulum-associated protein degradation, enzyme inhibitor, enzyme kinetics, enzyme purification, enzyme structure, protein misfolding, rhomboid protease, serine protease,
• MeSH
• Kinetics MeSH
• Humans MeSH
• Membrane Proteins * metabolism   chemistry   genetics   antagonists & inhibitors   MeSH
• Recombinant Proteins chemistry   metabolism   genetics   MeSH
• Fluorescence Resonance Energy Transfer MeSH
• Serine Endopeptidases * chemistry   metabolism   genetics   MeSH
• Substrate Specificity MeSH
• Check Tag
• Humans MeSH
• Publication type
• Journal Article MeSH
• Names of Substances
• Membrane Proteins * MeSH
• Recombinant Proteins MeSH
• Serine Endopeptidases * MeSH

Rhomboid proteases play a variety of physiological roles, but rhomboid protease inhibitors have been mostly developed for the E. coli model rhomboid GlpG. In this work, we screened different electrophilic scaffolds against the human mitochondrial rhomboid PARL and found 4-oxo-β-lactams as submicromolar inhibitors. Multifaceted computations suggest explanations for the activity at the molecular scale and provide models of covalently bound complexes. Together with the straightforward synthesis of the 4-oxo-β-lactam scaffold, this may pave the way toward selective, nonpeptidic PARL inhibitors.

• Publication type
• Journal Article MeSH

Rhomboid proteases are ubiquitous intramembrane serine proteases that can cleave transmembrane substrates within lipid bilayers. They exhibit many and diverse functions, such as but not limited to, growth factor signaling, immune and inflammatory response, protein quality control, and parasitic invasion. Human rhomboid protease RHBDL4 has been demonstrated to play a critical role in removing misfolded proteins from the Endoplasmic Reticulum and is implicated in severe diseases such as various cancers and Alzheimer's disease. Therefore, RHBDL4 is expected to constitute an important therapeutic target for such devastating diseases. Despite its critical role in many biological processes, the enzymatic properties of RHBDL4 remain largely unknown. To enable a comprehensive characterization of RHBDL4's kinetics, catalytic parameters, substrate specificity, and binding modality we expressed and purified recombinant RHBDL4, and employed it in a Förster Resonance Energy Transfer-based cleavage assay. Until now, kinetic studies have been limited mostly to bacterial rhomboid proteases. Our in vitro platform offers a new method for studying RHBDL4's enzymatic function and substrate preferences. Furthermore, we developed and tested potential inhibitors using our assay and successfully identified peptidyl α-ketoamide inhibitors of RHBDL4 that are highly effective against recombinant RHBDL4. We utilize ensemble docking and molecular dynamics (MD) simulations to explore the binding modality of substrate-derived peptides bound to RHBDL4. Our analysis focused on key interactions and dynamic movements within RHBDL4's active site that contributed to binding stability, offering valuable insights for optimizing the non-prime side of RHBDL4 ketoamide inhibitors. In summary, our study offers fundamental insights into RHBDL4's catalytic activities and substrate preferences, laying the foundation for downstream applications such as drug inhibitor screenings and structure-function studies, which will enable the identification of lead drug compounds for RHBDL4.

• Keywords
• endoplasmic reticulum stress, endoplasmic-reticulum-associated protein degradation, enzyme inhibitor, enzyme kinetics, enzyme purification, enzyme structure, protein misfolding, rhomboid protease, serine protease,
• Publication type
• Journal Article MeSH
• Preprint MeSH