On-a-chip tryptic digestion of transthyretin: a step toward an integrated microfluidic system for the follow-up of familial transthyretin amyloidosis.

A microfluidic microreactor for trypsin mediated transthyretin (TTR) digestion has been developed as a step towards the elaboration of a fully integrated microdevice for the detection of a rare and disabling disease, the familial transthyretin amyloidosis (ATTR) which is related to specific TTR mutations. Therefore, an enzymatic microreactor coupled to an analytical step able to monitor the mutation of TTR on specific peptide fragments would allow an accurate monitoring of the treatment efficiency of ATTR. In this study, two types of immobilized trypsin microreactors have been investigated: a new miniaturized, microfluidic fluidized bed packed with trypsin functionalized magnetic particles (MPs), and a thiol-ene (TE) monolith-based chip. Their performances were first demonstrated with N-benzoyl-dl-arginine-4-nitroanilide hydrochloride BApNA, a low molecular weight substrate. High reaction yields (75.2%) have been reached within 0.6 min for the TE-based trypsin microreactor, while a lower yield (12.4%) was obtained for the micro-fluidized bed within a similar residence time. Transposition of the optimized conditions, developed with BApNA, to TTR digestion in the TE-based trypsin microreactor was successfully performed. We demonstrated that the TE-chip can achieve an efficient and reproducible digestion of TTR. This has been assessed by MS detection. In addition, TTR hydrolysis led to the production of a fragment of interest allowing the therapeutic follow-up of more than twenty possible ATTR mutations. High sequence coverage (90%), similar to those obtained with free trypsin, was achieved in a short time (2.4 min). Repeated experiments showed good reproducibility (RSD = 6.8%). These promising results open up the route for an innovative treatment follow-up dedicated to ATTR.

[1]  J. Macák,et al.  Advanced immunocapture of milk‐borne Salmonella by microfluidic magnetically stabilized fluidized bed , 2018, Electrophoresis.

[2]  M. Bartolini,et al.  Towards automation in protein digestion: Development of a monolithic trypsin immobilized reactor for highly efficient on-line digestion and analysis. , 2017, Talanta.

[3]  M. Fermigier,et al.  Magnetic fluidized bed for solid phase extraction in microfluidic systems. , 2017, Lab on a chip.

[4]  J. Kutter,et al.  Thiol-ene Monolithic Pepsin Microreactor with a 3D-Printed Interface for Efficient UPLC-MS Peptide Mapping Analyses. , 2017, Analytical chemistry.

[5]  G. Corthals,et al.  A cyclic-olefin-copolymer microfluidic immobilized-enzyme reactor for rapid digestion of proteins from dried blood spots. , 2017, Journal of chromatography. A.

[6]  J. Kelly,et al.  A current pharmacologic agent versus the promise of next generation therapeutics to ameliorate protein misfolding and/or aggregation diseases. , 2016, Current opinion in chemical biology.

[7]  Jérôme Champ,et al.  Microfluidic platform combining droplets and magnetic tweezers: application to HER2 expression in cancer diagnosis , 2016, Scientific Reports.

[8]  H. Katus,et al.  Diagnosis of cardiac involvement in systemic amyloidosis by state-of-the-art echocardiography: where are we now? , 2016 .

[9]  M. Benson,et al.  Diagnosis, Prognosis, and Therapy of Transthyretin Amyloidosis. , 2015, Journal of the American College of Cardiology.

[10]  F. Lisacek,et al.  Optimization of human dendritic cell sample preparation for mass spectrometry-based proteomic studies. , 2015, Analytical biochemistry.

[11]  J. Viovy,et al.  Magneto-immunocapture with on-bead fluorescent labeling of amyloid-β peptides: towards a microfluidized-bed-based operation. , 2015, The Analyst.

[12]  H. Steen,et al.  A High-Efficiency Cellular Extraction System for Biological Proteomics. , 2015, Journal of proteome research.

[13]  F. Chen,et al.  Diagnostic model of saliva peptide finger print analysis of oral squamous cell carcinoma patients using weak cation exchange magnetic beads , 2015, Bioscience reports.

[14]  Josiane P Lafleur,et al.  Rapid and simple preparation of thiol-ene emulsion-templated monoliths and their application as enzymatic microreactors. , 2015, Lab on a chip.

[15]  Shen-Liang Chen,et al.  Wnt3a signal pathways activate MyoD expression by targeting cis-elements inside and outside its distal enhancer , 2015, Bioscience reports.

[16]  F. Gonnet,et al.  Derivatization strategies for CE‐LIF analysis of biomarkers: Toward a clinical diagnostic of familial transthyretin amyloidosis , 2014, Electrophoresis.

[17]  G. Bayramoglu,et al.  Trypsin Immobilized on Magnetic Beads via Click Chemistry: Fast Proteolysis of Proteins in a Microbioreactor for MALDI-ToF-MS Peptide Analysis , 2014 .

[18]  J. Jänis,et al.  Microscale immobilized enzyme reactors in proteomics: latest developments. , 2014, Journal of chromatography. A.

[19]  Veit Schwämmle,et al.  Quantitative Assessment of In-solution Digestion Efficiency Identifies Optimal Protocols for Unbiased Protein Analysis* , 2013, Molecular & Cellular Proteomics.

[20]  Yukio Ando,et al.  Guideline of transthyretin-related hereditary amyloidosis for clinicians , 2013, Orphanet Journal of Rare Diseases.

[21]  F. Salvi,et al.  Disease profile and differential diagnosis of hereditary transthyretin-related amyloidosis with exclusively cardiac phenotype: an Italian perspective. , 2013, European heart journal.

[22]  Josiane P Lafleur,et al.  Rapid photochemical surface patterning of proteins in thiol-ene based microfluidic devices. , 2013, The Analyst.

[23]  J. Berk,et al.  Transthyretin (TTR) Cardiac Amyloidosis , 2012, Circulation.

[24]  Li Yang,et al.  A replaceable dual‐enzyme capillary microreactor using magnetic beads and its application for simultaneous detection of acetaldehyde and pyruvate , 2012, Electrophoresis.

[25]  Z. Bílková,et al.  New monodisperse magnetic polymer microspheres biofunctionalized for enzyme catalysis and bioaffinity separations. , 2012, Macromolecular bioscience.

[26]  E. Kumacheva,et al.  Digital microfluidic hydrogel microreactors for proteomics , 2012, Proteomics.

[27]  N. Dovichi,et al.  High efficiency and quantitatively reproducible protein digestion by trypsin-immobilized magnetic microspheres. , 2012, Journal of chromatography. A.

[28]  V. Planté-Bordeneuve,et al.  Familial amyloid polyneuropathy , 2019, Journal of the Neurological Sciences.

[29]  William R Freeman,et al.  Clinical evaluation and treatment accuracy in diabetic macular edema using navigated laser photocoagulator NAVILAS. , 2011, Ophthalmology.

[30]  L. Zhang,et al.  High throughput tryptic digestion via poly (acrylamide-co-methylenebisacrylamide) monolith based immobilized enzyme reactor. , 2011, Talanta.

[31]  Darryl B. Hardie,et al.  A quantitative study of the effects of chaotropic agents, surfactants, and solvents on the digestion efficiency of human plasma proteins by trypsin. , 2010, Journal of proteome research.

[32]  J. Schiller,et al.  The solubilisation of boar sperm membranes by different detergents - a microscopic, MALDI-TOF MS, 31P NMR and PAGE study on membrane lysis, extraction efficiency, lipid and protein composition , 2009, Lipids in Health and Disease.

[33]  F. Švec,et al.  Less common applications of monoliths: IV. Recent developments in immobilized enzyme reactors for proteomics and biotechnology. , 2009, Journal of separation science.

[34]  Frantisek Svec,et al.  Highly efficient enzyme reactors containing trypsin and endoproteinase LysC immobilized on porous polymer monolith coupled to MS suitable for analysis of antibodies. , 2009, Analytical chemistry.

[35]  G. Bayramoglu,et al.  Preparation of nanofibrous polymer grafted magnetic poly(GMA-MMA)-g-MAA beads for immobilization of trypsin via adsorption , 2008 .

[36]  Jean-Louis Viovy,et al.  Controlled proteolysis of normal and pathological prion protein in a microfluidic chip. , 2008, Lab on a chip.

[37]  Masaru Tomita,et al.  Phase transfer surfactant-aided trypsin digestion for membrane proteome analysis. , 2008, Journal of proteome research.

[38]  M. Benson,et al.  The molecular biology and clinical features of amyloid neuropathy , 2007, Muscle & nerve.

[39]  Jianmin Wu,et al.  Trypsin immobilization by direct adsorption on metal ion chelated macroporous chitosan-silica gel beads. , 2006, International journal of biological macromolecules.

[40]  Jean-Louis Viovy,et al.  Use of self assembled magnetic beads for on-chip protein digestion. , 2005, Lab on a chip.

[41]  E. Verpoorte,et al.  Chemically modified, immobilized trypsin reactor with improved digestion efficiency. , 2005, Journal of proteome research.

[42]  Catherine E Costello,et al.  Tabulation of human transthyretin (TTR) variants, 2003 , 2003, Amyloid : the international journal of experimental and clinical investigation : the official journal of the International Society of Amyloidosis.

[43]  Frantisek Svec,et al.  Enzymatic microreactor-on-a-chip: protein mapping using trypsin immobilized on porous polymer monoliths molded in channels of microfluidic devices. , 2002, Analytical chemistry.

[44]  D. Russell,et al.  Proteolysis in mixed organic-aqueous solvent systems: applications for peptide mass mapping using mass spectrometry. , 2001, Analytical chemistry.

[45]  L. Ceriotti,et al.  New adsorbed coatings for capillary electrophoresis , 2000, Electrophoresis.

[46]  K. László,et al.  Stability of hydrolytic enzymes in water-organic solvent systems , 1998 .

[47]  H. Swaisgood,et al.  Optimization of immobilized enzyme hydrolysis combined with high-performance liquid chromatography/thermospray mass spectrometry for the determination of neuropeptides. , 1990, Analytical biochemistry.

[48]  K. Sletten,et al.  Fibril in senile systemic amyloidosis is derived from normal transthyretin. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[49]  J. V. Staros,et al.  N-hydroxysulfosuccinimide active esters: bis(N-hydroxysulfosuccinimide) esters of two dicarboxylic acids are hydrophilic, membrane-impermeant, protein cross-linkers. , 1982, Biochemistry.