MALDI imaging mass spectrometry: Discrimination of pathophysiological regions in traumatized skeletal muscle by characteristic peptide signatures

Due to formation of fibrosis and the loss of contractile muscle tissue, severe muscle injuries often result in insufficient healing marked by a significant reduction of muscle force and motor activity. Our previous studies demonstrated that the local transplantation of mesenchymal stromal cells into an injured skeletal muscle of the rat improves the functional outcome of the healing process. Since, due to the lack of sufficient markers, the accurate discrimination of pathophysiological regions in injured skeletal muscle is inadequate, underlying mechanisms of the beneficial effects of mesenchymal stromal cell transplantation on primary trauma and trauma adjacent muscle area remain elusive. For discrimination of these pathophysiological regions, formalin‐fixed injured skeletal muscle tissue was analyzed by MALDI imaging MS. By using two computational evaluation strategies, a supervised approach (ClinProTools) and unsupervised segmentation (SCiLS Lab), characteristic m/z species could be assigned to primary trauma and trauma adjacent muscle regions. Using “bottom‐up” MS for protein identification and validation of results by immunohistochemistry, we could identify two proteins, skeletal muscle alpha actin and carbonic anhydrase III, which discriminate between the secondary damage on adjacent tissue and the primary traumatized muscle area. Our results underscore the high potential of MALDI imaging MS to describe the spatial characteristics of pathophysiological changes in muscle.

[1]  Garry L Corthals,et al.  MSiMass list: a public database of identifications for protein MALDI MS imaging. , 2014, Journal of proteome research.

[2]  B. Cillero-Pastor,et al.  Matrix-assisted laser desorption ionization mass spectrometry imaging for peptide and protein analyses: a critical review of on-tissue digestion. , 2014, Journal of proteome research.

[3]  G. Duda,et al.  Improvement of Contraction Force in Injured Skeletal Muscle after Autologous Mesenchymal Stroma Cell Transplantation Is Accompanied by Slow to Fast Fiber Type Shift , 2013, Transfusion Medicine and Hemotherapy.

[4]  Stefan Heldmann,et al.  MRI-compatible pipeline for three-dimensional MALDI imaging mass spectrometry using PAXgene fixation. , 2013, Journal of proteomics.

[5]  M. Tegenthoff,et al.  Differential proteomic analysis of abnormal intramyoplasmic aggregates in desminopathy. , 2013, Journal of proteomics.

[6]  A. Walch,et al.  MALDI imaging mass spectrometry for direct tissue analysis. , 2013, Methods in molecular biology.

[7]  G. Duda,et al.  Intra-Arterial MSC Transplantation Restores Functional Capacity After Skeletal Muscle Trauma , 2012, The open orthopaedics journal.

[8]  Marius Ueffing,et al.  MALDI imaging mass spectrometry reveals COX7A2, TAGLN2 and S100-A10 as novel prognostic markers in Barrett's adenocarcinoma. , 2012, Journal of proteomics.

[9]  D. Swandulla,et al.  Mass spectrometry-based proteomic analysis of middle-aged vs. aged vastus lateralis reveals increased levels of carbonic anhydrase isoform 3 in senescent human skeletal muscle , 2012, International journal of molecular medicine.

[10]  Stefan Heldmann,et al.  Exploring three-dimensional matrix-assisted laser desorption/ionization imaging mass spectrometry data: three-dimensional spatial segmentation of mouse kidney. , 2012, Analytical chemistry.

[11]  Natalie I. Tasman,et al.  A Cross-platform Toolkit for Mass Spectrometry and Proteomics , 2012, Nature Biotechnology.

[12]  G. Vanderstraeten,et al.  Treatment of Skeletal Muscle Injury: A Review , 2012, ISRN orthopedics.

[13]  G. Duda,et al.  Mesenchymal stem cell therapy following muscle trauma leads to improved muscular regeneration in both male and female rats. , 2012, Gender medicine.

[14]  Orlando Guntinas-Lichius,et al.  MALDI-imaging segmentation is a powerful tool for spatial functional proteomic analysis of human larynx carcinoma , 2012, Journal of Cancer Research and Clinical Oncology.

[15]  R. Casadonte,et al.  Proteomic analysis of formalin-fixed paraffin-embedded tissue by MALDI imaging mass spectrometry , 2011, Nature Protocols.

[16]  Bernhard Spengler,et al.  Protein identification by accurate mass matrix-assisted laser desorption/ionization imaging of tryptic peptides. , 2011, Rapid communications in mass spectrometry : RCM.

[17]  M. Mann,et al.  Quantitative, high-resolution proteomics for data-driven systems biology. , 2011, Annual review of biochemistry.

[18]  K. Ohlendieck Skeletal muscle proteomics: current approaches, technical challenges and emerging techniques , 2011, Skeletal Muscle.

[19]  Theodore Alexandrov,et al.  Spatial segmentation of imaging mass spectrometry data with edge-preserving image denoising and clustering. , 2010, Journal of proteome research.

[20]  Sanjay Kumar,et al.  Therapeutic potential of adult bone marrow‐derived mesenchymal stem cells in diseases of the skeleton , 2010, Journal of cellular biochemistry.

[21]  N. Ahn,et al.  Quantifying the impact of chimera MS/MS spectra on peptide identification in large-scale proteomics studies. , 2010, Journal of proteome research.

[22]  K. Ohlendieck,et al.  Proteomic profiling of x-linked muscular dystrophy , 2009, Journal of Muscle Research and Cell Motility.

[23]  G. Duda,et al.  Dose-response relationship of mesenchymal stem cell transplantation and functional regeneration after severe skeletal muscle injury in rats. , 2009, Tissue engineering. Part A.

[24]  F. François,et al.  Mass spectrometry MALDI imaging of colon cancer biomarkers: a new diagnostic paradigm. , 2009, Biomarkers in medicine.

[25]  T. Monks,et al.  Improved MALDI-TOF imaging yields increased protein signals at high molecular mass , 2009, Journal of the American Society for Mass Spectrometry.

[26]  Andrea Urbani,et al.  Protein unlocking procedures of formalin‐fixed paraffin‐embedded tissues: Application to MALDI‐TOF Imaging MS investigations , 2008, Proteomics.

[27]  Sandra Rauser,et al.  MALDI imaging mass spectrometry for direct tissue analysis: a new frontier for molecular histology , 2008, Histochemistry and Cell Biology.

[28]  B. Fuchs,et al.  Upregulation of α‐skeletal muscle actin and myosin heavy polypeptide gene products in degenerating rotator cuff muscles , 2008, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[29]  H. Boulaiz,et al.  Role of α-actin in muscle damage of injured athletes in comparison with traditional markers , 2007, British Journal of Sports Medicine.

[30]  I. Fournier,et al.  Direct analysis and MALDI imaging of formalin-fixed, paraffin-embedded tissue sections. , 2007, Journal of proteome research.

[31]  H. Boulaiz,et al.  Role of alpha-actin in muscle damage of injured athletes in comparison with traditional markers. , 2007, British Journal of Sports Medicine.

[32]  Richard M Caprioli,et al.  New developments in profiling and imaging of proteins from tissue sections by MALDI mass spectrometry. , 2006, Journal of proteome research.

[33]  K. Schaser,et al.  Autologous bone marrow-derived cells enhance muscle strength following skeletal muscle crush injury in rats. , 2006, Tissue engineering.

[34]  A. Martínez-Amat,et al.  Release of α-actin into serum after skeletal muscle damage , 2005, British Journal of Sports Medicine.

[35]  D. Garry,et al.  Myogenic progenitor cells express filamin C in developing and regenerating skeletal muscle. , 2005, Stem cells and development.

[36]  J. Tidball Inflammatory processes in muscle injury and repair. , 2005, American journal of physiology. Regulatory, integrative and comparative physiology.

[37]  K. Schaser,et al.  Acute effects of N‐acetylcysteine on skeletal muscle microcirculation following closed soft tissue trauma in rats , 2005, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[38]  A. Martínez-Amat,et al.  Release of alpha-actin into serum after skeletal muscle damage. , 2005, British journal of sports medicine.

[39]  R. Lovering,et al.  Contractile function, sarcolemma integrity, and the loss of dystrophin after skeletal muscle eccentric contraction-induced injury. , 2004, American journal of physiology. Cell physiology.

[40]  M. Greaser,et al.  Binding of filamin isoforms to myofibrils , 2000, Journal of Muscle Research & Cell Motility.

[41]  K. Schaser,et al.  Temporal profile of microvascular disturbances in rat tibial periosteum following closed soft tissue trauma , 2003, Langenbeck's Archives of Surgery.

[42]  Matthias Chiquet,et al.  Tenascins: regulation and putative functions during pathological stress , 2003, The Journal of pathology.

[43]  R. Baron,et al.  Binding of Filamin to the C-terminal Tail of the Calcitonin Receptor Controls Recycling* , 2003, The Journal of Biological Chemistry.

[44]  M. Järvinen,et al.  Mechanical loading regulates the expression of tenascin-C in the myotendinous junction and tendon but does not induce de novo synthesis in the skeletal muscle , 2003, Journal of Cell Science.

[45]  N. Anderson,et al.  The Human Plasma Proteome: History, Character, and Diagnostic Prospects , 2003, Molecular & Cellular Proteomics.

[46]  J. Beckmann,et al.  Calpain 3 cleaves filamin C and regulates its ability to interact with gamma- and delta-sarcoglycans. , 2003, Muscle & nerve.

[47]  M. Mann,et al.  Large-scale Proteomic Analysis of the Human Spliceosome References , 2006 .

[48]  Kai Stühler,et al.  Genetic analysis of the mouse brain proteome , 2002, Nature Genetics.

[49]  P. Jones,et al.  The tenascin family of ECM glycoproteins: Structure, function, and regulation during embryonic development and tissue remodeling , 2000, Developmental dynamics : an official publication of the American Association of Anatomists.

[50]  C. Reggiani,et al.  Human skeletal muscle fibres: molecular and functional diversity. , 2000, Progress in biophysics and molecular biology.

[51]  M. Gautel,et al.  Characterization of muscle filamin isoforms suggests a possible role of gamma-filamin/ABP-L in sarcomeric Z-disc formation. , 2000, Cell motility and the cytoskeleton.

[52]  K. Schaser,et al.  In vivo analysis of microcirculation following closed soft‐tissue injury , 1999, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[53]  S. Werner,et al.  Cloning of Novel Injury-regulated Genes , 1999, The Journal of Biological Chemistry.

[54]  M. Chiquet,et al.  Regulation of extracellular matrix synthesis by mechanical stress. , 1996, Biochemistry and cell biology = Biochimie et biologie cellulaire.

[55]  M. Miller,et al.  Skeletal muscle injuries. , 1995, The Orthopedic clinics of North America.

[56]  E. Bandman Contractile protein isoforms in muscle development. , 1992, Developmental biology.

[57]  H. Väänänen,et al.  Carbonic anhydrase in the type I skeletal muscle fibers of the rat. An immunohistochemical study. , 1982, The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society.