A HaloTag-TEV genetic cassette for mechanical phenotyping of proteins from tissues

Single-molecule methods using recombinant proteins have generated transformative hypotheses on how mechanical forces are generated and sensed in biological tissues. However, testing these mechanical hypotheses on proteins in their natural environment remains inaccesible to conventional tools. To address this limitation, here we demonstrate a mouse model carrying a HaloTag-TEV insertion in the protein titin, the main determinant of myocyte stiffness. Using our system, we specifically sever titin by digestion with TEV protease, and find that the response of muscle fibers to length changes requires mechanical transduction through titin’s intact polypeptide chain. In addition, HaloTag-based covalent tethering enables examination of titin dynamics under force using magnetic tweezers. At pulling forces < 10 pN, titin domains are recruited to the unfolded state, and produce 41.5 zJ mechanical work during refolding. Insertion of the HaloTag-TEV cassette in mechanical proteins opens opportunities to explore the molecular basis of cellular force generation, mechanosensing and mechanotransduction

Nanomechanical Phenotypes in Cardiac Myosin-Binding Protein C Mutants That Cause Hypertrophic Cardiomyopathy.

Hypertrophic cardiomyopathy (HCM) is a disease of the myocardium caused by mutations in sarcomeric proteins with mechanical roles, such as the molecular motor myosin. Around half of the HCM-causing genetic variants target contraction modulator cardiac myosin-binding protein C (cMyBP-C), although the underlying pathogenic mechanisms remain unclear since many of these mutations cause no alterations in protein structure and stability. As an alternative pathomechanism, here we have examined whether pathogenic mutations perturb the nanomechanics of cMyBP-C, which would compromise its modulatory mechanical tethers across sliding actomyosin filaments. Using single-molecule atomic force spectroscopy, we have quantified mechanical folding and unfolding transitions in cMyBP-C domains targeted by HCM mutations that do not induce RNA splicing alterations or protein thermodynamic destabilization. Our results show that domains containing mutation R495W are mechanically weaker than wild-type at forces below 40 pN and that R502Q mutant domains fold faster than wild-type. None of these alterations are found in control, nonpathogenic variants, suggesting that nanomechanical phenotypes induced by pathogenic cMyBP-C mutations contribute to HCM development. We propose that mutation-induced nanomechanical alterations may be common in mechanical proteins involved in human pathologies.J.A.C. acknowledges funding from the Ministerio de Ciencia e Innovación (MCIN) through grants BIO2014– 54768-P, BIO2017–83640-P (AEI/FEDER, UE), EIN2019–102966, RYC-2014–16604, and BFU2017–90692­ REDT, the European Research Area Network on Cardiovascular Diseases (ERA-CVD/ISCIII, MINOTAUR, AC16/00045), and the Comunidad de Madrid (consortium Tec4Bio-CM, S2018/NMT-4443, FEDER). This work was supported by NIH grants RM1 GM33289 and HL117138 to J.A.S.; a Stanford Dean’s Postdoctoral Fellowship to D.P. and N.N.; and a Stanford Maternal and Child Health Research Institute (MCHRI) Postdoctoral Fellowship (1220552–140-DHPEU) to N.N. Financial support to D.D.S. comes from Eusko Jaurlaritza (Basque Government) through the project IT1254–19, and grants RYC-2016–19590 and PGC2018–099321-B-I00 from the MCIN (FEDER). The CNIC is supported by the Instituto de Salud Carlos III (ISCIII), MCIN, and the Pro CNIC Foundation and was a Severo Ochoa Center of Excellence (SEV-2015–0505). We acknowledge funding from ISCIII to the Centro de Investigación Biomédica en Red (CIBERCV), CB16/11/00425. C.S.C. is the recipient of an FPI-SO predoctoral fellowship, BES-2016–076638. M.R.P. was the recipient of a Ph.D. fellowship from the Italian Ministry of Education, Universities and Research (MIUR). C.P.L. was a recipient of a CNIC Master Fellowship. We thank N. Vicente for excellent technical support (through grant PEJ16/MED/TL-1593 from Consejería de Educación, Juventud y Deporte de la Comunidad de Madrid and the European Social Fund). We thank the Spectroscopy and Nuclear Magnetic Resonance Core Unit at CNIO for access to CD instrumentation and discussion about protein binding assays. We thank A. Thompson and S. Day for their insights. We thank all members of the Molecular Mechanics of the Cardiovascular System team for helpful discussions and the contribution of five anonymous reviewers.S

Basal oxidation of conserved cysteines modulates cardiac titin stiffness and dynamics

Titin, as the main protein responsible for the passive stiffness of the sarcomere, plays a key role in diastolic function and is a determinant factor in the etiology of heart disease. Titin stiffness depends on unfolding and folding transitions of immunoglobulin-like (Ig) domains of the I-band, and recent studies have shown that oxidative modifications of cryptic cysteines belonging to these Ig domains modulate their mechanical properties in vitro. However, the relevance of this mode of titin mechanical modulation in vivo remains largely unknown. Here, we describe the high evolutionary conservation of titin mechanical cysteines and show that they are remarkably oxidized in murine cardiac tissue. Mass spectrometry analyses indicate a similar landscape of basal oxidation in murine and human myocardium. Monte Carlo simulations illustrate how disulfides and S-thiolations on these cysteines increase the dynamics of the protein at physiological forces, while enabling load- and isoform-dependent regulation of titin stiffness. Our results demonstrate the role of conserved cysteines in the modulation of titin mechanical properties in vivo and point to potential redox-based pathomechanisms in heart disease.This work was supported by the Ministerio de Ciencia e Innovación grants BIO2014-54768-P, BIO2017-83640-P, RYC-2014-16604 to JAC and PGC2018-097019-B-I00 to JV, the Regional Government of Madrid grants S2018/NMT-4443 and PEJ16/MED/TL-1593 to JAC and the Instituto de Salud Carlos III (Fondo de Investigación Sanitaria grant PRB3 (PT17/0019/0003- ISCIII-SGEFI /ERDF, ProteoRed), and “la Caixa” Banking Foundation (project code HR17-00247) to JV. We acknowledge funding from the European Research Area Network on Cardiovascular Disease through grant MINOTAUR to SS (The Austrian Science Fund – FWF, I3301) and JAC (ISCIII-AC16/00045). The CNIC is supported by ISCIII, the Ministerio de Ciencia e Innovación and the Pro CNIC Foundation, and was a Severo Ochoa Center of Excellence (SEV-2015-0505). IMM was the recipient of a CNIC-ACCIONA Masters Fellowship and holds a fellowship from “La Caixa” Foundation (ID 100010434, fellowship code LCF/BQ/DR20/11790009). CSC is the recipient of an FPI-SO predoctoral fellowship BES-2016-076638. We thank Wolfgang A. Linke and Pablo García-Pavía for critical feedback. We are also thankful for the insights of three anonymous reviewers.S

Titin Missense Variants as a Cause of Familial Dilated Cardiomyopathy.

S

Reducing the environmental impact of surgery on a global scale: systematic review and co-prioritization with healthcare workers in 132 countries

Abstract Background Healthcare cannot achieve net-zero carbon without addressing operating theatres. The aim of this study was to prioritize feasible interventions to reduce the environmental impact of operating theatres. Methods This study adopted a four-phase Delphi consensus co-prioritization methodology. In phase 1, a systematic review of published interventions and global consultation of perioperative healthcare professionals were used to longlist interventions. In phase 2, iterative thematic analysis consolidated comparable interventions into a shortlist. In phase 3, the shortlist was co-prioritized based on patient and clinician views on acceptability, feasibility, and safety. In phase 4, ranked lists of interventions were presented by their relevance to high-income countries and low–middle-income countries. Results In phase 1, 43 interventions were identified, which had low uptake in practice according to 3042 professionals globally. In phase 2, a shortlist of 15 intervention domains was generated. In phase 3, interventions were deemed acceptable for more than 90 per cent of patients except for reducing general anaesthesia (84 per cent) and re-sterilization of ‘single-use’ consumables (86 per cent). In phase 4, the top three shortlisted interventions for high-income countries were: introducing recycling; reducing use of anaesthetic gases; and appropriate clinical waste processing. In phase 4, the top three shortlisted interventions for low–middle-income countries were: introducing reusable surgical devices; reducing use of consumables; and reducing the use of general anaesthesia. Conclusion This is a step toward environmentally sustainable operating environments with actionable interventions applicable to both high– and low–middle–income countries

An Abl-FBP17 mechanosensing system couples local plasma membrane curvature and stress fiber remodeling during mechanoadaptation

Cells remodel their structure in response to mechanical strain. However, how mechanical forces are translated into biochemical signals that coordinate the structural changes observed at the plasma membrane (PM) and the underlying cytoskeleton during mechanoadaptation is unclear. Here, we show that PM mechanoadaptation is controlled by a tension-sensing pathway composed of c-Abl tyrosine kinase and membrane curvature regulator FBP17. FBP17 is recruited to caveolae to induce the formation of caveolar rosettes. FBP17 deficient cells have reduced rosette density, lack PM tension buffering capacity under osmotic shock, and cannot adapt to mechanical strain. Mechanistically, tension is transduced to the FBP17 F-BAR domain by direct phosphorylation mediated by c-Abl, a mechanosensitive molecule. This modification inhibits FBP17 membrane bending activity and releases FBP17-controlled inhibition of mDia1-dependent stress fibers, favoring membrane adaptation to increased tension. This mechanoprotective mechanism adapts the cell to changes in mechanical tension by coupling PM and actin cytoskeleton remodeling

Nanomechanical Phenotypes in Cardiac Myosin-Binding Protein C Mutants That Cause Hypertrophic Cardiomyopathy

Hypertrophic cardiomyopathy (HCM) is a disease of the myocardium caused by mutations in sarcomeric proteins with mechanical roles, such as the molecular motor myosin. Around half of the HCM-causing genetic variants target contraction modulator cardiac myosin-binding protein C (cMyBP-C), although the underlying pathogenic mechanisms remain unclear since many of these mutations cause no alterations in protein structure and stability. As an alternative pathomechanism, here we have examined whether pathogenic mutations perturb the nanomechanics of cMyBP-C, which would compromise its modulatory mechanical tethers across sliding actomyosin filaments. Using single-molecule atomic force spectroscopy, we have quantified mechanical folding and unfolding transitions in cMyBP-C domains targeted by HCM mutations that do not induce RNA splicing alterations or protein thermodynamic destabilization. Our results show that domains containing mutation R495W are mechanically weaker than wild-type at forces below 40 pN and that R502Q mutant domains fold faster than wild-type. None of these alterations are found in control, nonpathogenic variants, suggesting that nanomechanical phenotypes induced by pathogenic cMyBP-C mutations contribute to HCM development. We propose that mutation-induced nanomechanical alterations may be common in mechanical proteins involved in human pathologies

Protein haploinsufficiency drivers identify MYBPC3 variants that cause hypertrophic cardiomyopathy

Hypertrophic cardiomyopathy (HCM) is the most common inherited cardiac disease. Variants in MYBPC3, the gene encoding cardiac myosin-binding protein C (cMyBP-C), are the leading cause of HCM. However, the pathogenicity status of hundreds of MYBPC3 variants found in patients remains unknown, as a consequence of our incomplete understanding of the pathomechanisms triggered by HCM-causing variants. Here, we examined 44 nontruncating MYBPC3 variants that we classified as HCM-linked or nonpathogenic according to cosegregation and population genetics criteria. We found that around half of the HCM-linked variants showed alterations in RNA splicing or protein stability, both of which can lead to cMyBP-C haploinsufficiency. These protein haploinsufficiency drivers associated with HCM pathogenicity with 100% and 94% specificity, respectively. Furthermore, we uncovered that 11% of nontruncating MYBPC3 variants currently classified as of uncertain significance in ClinVar induced one of these molecular phenotypes. Our strategy, which can be applied to other conditions induced by protein loss of function, supports the idea that cMyBP-C haploinsufficiency is a fundamental pathomechanism in HCM.J. A.-C. acknowledges funding from the Ministerio de Ciencia e Innovación (MCIN) through grants BIO2014-54768-P ; BIO2017-83640-P/MINECO/AEI/FEDER , UE; EIN2019-102966 and RYC-2014-16604 , the European Research Area Network on Cardiovascular Diseases (ERA-CVD/ ISCIII , Spain MINOTAUR, AC16/00045), and the Comunidad de Madrid (consortium Tec4Bio-CM, S2018/NMT-4443, FEDER). The CNIC is supported by the ISCIII, MCIN, and the Pro CNIC Foundation and was a Severo Ochoa Center of Excellence (SEV-2015-0505). We acknowledge funding from ISCIII to the Centro de Investigación Biomédica en Red (CB16/11/00425). L. S. acknowledges funding from MCIN (BFU2015-63571-P). J. S. acknowledges funding from AEI (PID2019-107293GB-I00), Gobierno de Aragón (E45_17R), and ERDF-InterregV-A POCTEFA, Spain (PIREPRED-EFA086/15). C. S.-C. is the recipient of an FPI-SO predoctoral fellowship BES-2016-076638. M. R. P. was the recipient of a PhD fellowship from the Italian Ministry of Education, Universities and Research , Italy. H. G.-C. is the recipient of an FPU16/04232 doctoral contract from MCIN