Proteomics - Technologies, Markets and Companies

Table of Contents

Part I: Technologies & Markets

Executive Summary  

1. Basics of Proteomics

• Introduction 
• History 
• Nucleic acids, genes and proteins 
• Genome
• DNA 
• RNA 
• MicroRNAs 
• Decoding of mRNA by the ribosome 
• Genes
• Alternative splicing
• Transcription 
• Gene regulation  
• Gene expression 
• Chromatin
• Golgi complex 
• Proteins 
• Functions of proteins 
• Proteasome 
• Spliceosome
• Inter-relationship of protein, mRNA and DNA
• Microproteins  
• Proteomics
• Endoplasmic reticulum
• Mitochondrial proteome 
• S-nitrosoproteins in mitochondria 
• Proteomics and genomics 
• Classification of proteomics 
• Levels of functional genomics and various "omics"  
• Glycoproteomics 
• Transcriptomics  
• Metabolomics  
• Cytomics
• Phenomics 
• Impact of the genetic factors on the human proteome 
• Proteomics and systems biology
• Proteomics and synthetic biology 
• Functional synthetic proteins  
• Synthetic proteomics for study of apoptosis  

2. Proteomic Technologies 

• Key technologies driving proteomics 
• Sample preparation 
• New trends in sample preparation 
• Pressure Cycling Technology  
• Protein separation technologies 
• High resolution 2DGE 
• Variations of 2D gel technology 
• Limitations of 2DGE and measures to overcome these 
• 1-D sodium dodecyl sulfate (SDS) PAGE 
• Capillary electrophoresis systems 
• Head column stacking capillary zone electrophoresis  
• Removal of albumin and IgG  
• SeraFILE™ separations platform 
• Companies with protein separation technologies  
• Protein purification 
• Technologies for protein purification 
• Applications of protein purification 
• Protein detection 
• Protein identification and characterization 
• Mass spectrometry 
• Electrospray ionization 
• Desorption electrospray ionization MS 
• Ion-mobility spectrometry-MS 
• Mirosaic 3500 MiD 
• Matrix-Assisted Laser Desorption/Ionization Mass Spectrometry 
• Cryogenic MALDI- Fourier Transform Mass Spectrometry  
• Stable-isotope-dilution tandem mass spectrometry 
• HUPO Gold MS Protein Standard 
• Companies involved in mass spectrometry 
• High performance liquid chromatography 
• Multidimensional protein identification technology (MudPIT) 
• Multiple reaction monitoring assays 
• Peptide mass fingerprinting 
• Current status and future prospects of clinical mass spectrometry 
• Combination of protein separation technologies with mass spectrometry 
• Combining capillary electrophoresis with mass spectrometry 
• 2D PAGE and mass spectrometry  
• Quantification of low abundance proteins 
• SDS-PAGE
• Proteomics quantification in complex samples  
• Antibodies and proteomics  
• Detection of fusion proteins
• Labeling and detection of proteins
• Bioorthogonal non-canonical amino-acid-tagging techniques 
• Stable-isotope labeling of amino acids in cell culture  
• Fluorescent labeling of proteins in living cells
• Combination of microspheres with fluorescence 
• Self-labeling protein tags 
• Analysis of peptides  
• C-terminal peptide analysis 
• Differential Peptide Display 
• Peptide analyses using NanoLC-MS  
• Protein sequencing 
• Real-time PCR for protein quantification
• Quantitative proteomics 
• MS-based quantitative proteomics 
• MS and cryo-electron tomography
• Selected reaction monitoring MS
• Functional proteomics: technologies for studying protein function
• Functional genomics by mass spectrometry
• LC-MS-based method for annotating the protein-coding genome 
• RNA-Protein fusions 
• Designed repeat proteins
• Application of nanobiotechnology to proteomics 
• Nanoproteomics 
• Nanoflow liquid chromatography 
• Nanopores for phosphoprotein analysis
• Nanotube electronic biosensor for proteomics 
• Protein nanocrystallography 
• Single-molecule mass spectrometry using a nanopore 
• Nanoelectrospray ionization
• Nanoproteomics for discovery of protein biomarkers in the blood 
• QD-protein nanoassembly 
• Nanoparticle barcodes  
• Biobarcode assay for proteins 
• Nanopore-based protein sequencing
• Nanoscale protein analysis  
• Nanoscale mechanism for protein engineering  
• Nanotube electronic biosensor 
• Nanotube-vesicle networks for study of membrane proteins 
• Qdot-nanocrystals 
• Resonance Light Scattering technology 
• Study of single membrane proteins at subnanometer resolution 
• Protein expression profiling
• Cell-based protein assays 
• Living cell-based assays for protein function 
• Companies developing cell-based protein assays 
• Determination of protein structure 
• X-Ray crystallography  
• Nuclear magnetic resonance
• Electron spin resonance 
• Prediction of protein structure 
• Protein tomography
• X-ray scattering-based method for determining the structure of proteins 
• Prediction of protein function 
• Three-dimensional proteomics for determination of function
• An algorithm for genome-wide prediction of protein function 
• Protein function studies
• Transcriptionally Active PCR 
• Protein-protein interactions 
• Bacterial protein interaction studies for assigning function 
• Bioluminescence Resonance Energy Transfer 
• Computational prediction of interactions 
• Detection Enhanced Ubiquitin Split Protein Sensor technology 
• Double Switch technology 
• Fluorescence Resonance Energy Transfer 
• In vivo study of protein-protein interactions  
• In vitro study of protein-protein interactions 
• Interactome 
• Membrane 1-hybrid method 
• Nanowire transistor for the detection of protein-protein interactions 
• Phage display  
• Protein affinity chromatography 
• Protein-fragment complementation system 
• Proximity-dependent hybridization chain reaction 
• Yeast 2-hybrid system  
• Companies with technologies for protein-protein interaction studies  
• Protein-DNA interaction 
• Monitoring protein function by expression profiling 
• Study of microprotein functions 
• Isotope-coded affinity tag peptide labeling 
• Differential Proteomic Panning 
• Cell map proteomics 
• Topological proteomics 
• Organelle or subcellular proteomics 
• SubCellBarCode  
• Nucleolar proteomics 
• Glycoproteomic technologies 
• High-sensitivity glycoprotein analysis  
• Fluorescent in vivo imaging of glycoproteins 
• Integrated approaches for protein characterization 
• Imaging mass spectrometry 
• IMS technologies 
• Applications of IMS 
• The protein microscope 
• Tag-Mass IMS
• Quantitative immunofluorescence for proteomics 
• Automation and robotics in proteomics 
• Western blot 
• Limitations of WB
• Innovations in WB
• Capillary electrophoresis and WB 
• Chemiluminescent western blotting 
• Fluorescent WB
• Microfluidics and WB  
• Multiplexing WB 
• Applications of Western blot 
• Research applications of Western blot
• Molecular diagnostic applications of Western blot  
• Companies involved in Western blotting technologies  
• Laser capture microdissection 
• Microdissection techniques used for proteomics 
• Uses of LCM in combination with proteomic technologies 
• Concluding remarks about applications of proteomic technologies
• NextGen Proteomics Platform  
• Precision proteomics  

3. Protein biochip technology 

• Introduction 
• Types of protein biochips 
• ProteinChip 
• Applications and advantages of ProteinChip
• ProteinChip Biomarker System 
• Matrix-free ProteinChip Array  
• Aptamer-based protein biochip 
• Fluorescence planar wave guide technology-based protein biochips
• Lab-on-a-chip for protein analysis  
• Biochips for peptide arrays
• Microfluidic biochips for proteomics 
• Protein biochips and microarrays for high-throughput expression 
• Nucleic Acid-Programmable Protein Array
• High-density protein microarrays 
• HPLC-Chip for protein identification 
• Antibody microarrays 
• HuProt™ Human Proteome Microarrays
• Integration of protein array and image analysis 
• Tissue microarray technology for proteomics 
• Protein biochips in molecular diagnostics 
• A force-based protein biochip  
• L1 chip and lipid immobilization  
• Multiplexed Protein Profiling on Microarrays
• Live cell microarrays
• ProteinArray Workstation 
• Proteome arrays 
• The Yeast ProtoArray 
• ProtoArray Human Protein Microarray 
• TRINECTIN proteome chip
• Peptide arrays 
• Surface plasmon resonance technology 
• SPR Systems 
• FLEX CHIP 
• Combination of surface plasmon resonance and MALDI-TOF  
• Protein chips/microarrays using nanotechnology
• Nanoparticle protein chip  
• Protein nanobiochip
• Protein nanoarrays 
• Self-assembling protein nanoarrays
• Companies involved in protein biochip/microarray technology 

4. Bioinformatics in Relation to Proteomics 

• Introduction 
• Bioinformatic tools for proteomics
• Testing of SELDI-TOF MS Proteomic Data
• BioImagine’s ProteinMine  
• Bioinformatics for pharmaceutical applications of proteomics 
• In silico search of drug targets by Biopendium
• Compugen's LEADS 
• DrugScore 
• Proteochemometric modeling  
• Integration of genomic and proteomic data
• Proteomic databases: creation and analysis 
• Introduction  
• Proteomic databases  
• GenProtEC 
• Human Protein Atlas
• Human Proteomics Initiative
• Human proteome map 
• International Protein Index  
• MS-based draft of the human proteome
• Protein Structure Initiative Structural Genomics Knowledgebase  
• Protein Warehouse Database 
• Protein Data Bank 
• Repository for raw data from proteomics MS  
• Universal Protein Resource
• Protein interaction databases  
• Biomolecular Interaction Network Database 
• ENCODE 
• Functional Genomics Consortium 
• Human Proteinpedia 
• ProteinCenter 
• Databases of the National Center for Biotechnology Information  
• Application of bioinformatics for protein identification 
• Tandem MS for protein identification 
• Targeted MS for specific identification of proteins 
• Application of bioinformatics in functional proteomics 
• Use of bioinformatics in protein sequencing 
• Bottom-up protein sequencing
• Top-down protein sequencing  
• Integration of next generation proteomics and gene sequencing data 
• Protein structural database approach to drug design 
• Bioinformatics for high-throughput proteomics 
• Bioinformatics for protein-protein interactions
• Companies with bioinformatic tools for proteomics 

5. Research in Proteomics 

• Introduction 
• Applications of proteomics in biological research 
• Identification of novel human genes by comparative proteomics  
• Study of relationship between genes and proteins 
• Characterization of histone codes
• Structural genomics or structural proteomics
• Protein Structure Factory  
• Protein Structure Initiative 
• Studies on protein structure at Argonne National Laboratory 
• Structural Genomics Consortium 
• Protein knockout 
• Antisense approach and proteomics  
• RNAi and protein knockout 
• Total knockout of cellular proteins 
• Ribozymes and proteomics 
• Single molecule proteomics 
• Single-molecule photon stamping spectroscopy 
• Single nucleotide polymorphism determination by TOF-MS 
• Application of proteomic technologies in systems biology 
• Signaling pathways and proteomics
• Kinomics
• Combinatorial RNAi for quantitative protein network analysis 
• Proteomics in neuroscience research
• Stem cell proteomics 
• Comparative proteomic analysis of somatic cells, iPSCs and ESCs . 159 hESC phosphoproteome
• Proteomic studies of mesenchymal stem cells
• Proteomics of neural stem cells
• Proteome Biology of Stem Cells Initiative 
• Proteomic analysis of the cell cycle 
• Nitric oxide and proteomics 
• A proteomic method for identification of cysteine S-nitrosylation sites 
• Study of the nitroproteome  
• Study of the phosphoproteome 
• Study of the mitochondrial proteome 
• Proteomic technologies for study of mitochondrial proteomics  
• Cryptome 
• Study of protein transport in health and disease 
• Ancient proteomics 
• Proteomics research in the academic sector 
• Netherlands Proteins@Work 
• ProteomeBinders initiative
• Rutgers University’s Center for Integrative Proteomics Research 
• Vanderbilt University's Center for Proteomics and Drug Actions 

6. Pharmaceutical Applications of Proteomics 

• Introduction 
• Current drug discovery process and its limitations 
• Role of omics in drug discovery 
• Genomics-based drug discovery 
• Metabolomics technologies for drug discovery 
• Role of metabonomics in drug discovery  
• Basis of proteomics approach to drug discovery 
• Proteins and drug action 
• Transcription-aided drug design 
• In vivo production of therapeutic proteins by mRNA 
• Role of proteomic technologies in drug discovery  
• Liquid chromatography-based drug discovery 
• Capture compound mass spectrometry 
• Protein-expression mapping by 2DGE 
• Protein-protein interactions and drug discovery 
• Role of MALDI mass spectrometry in drug discovery
• Structural proteomics and drug discovery 
• Tissue imaging mass spectrometry
• Oxford Genome Anatomy Project 
• Proteins as drug targets
• Monitoring drug target binding using the cellular thermal shift assay  
• Ligands to capture the purine binding proteome 
• Chemical probes to interrogate key protein families for drug discovery  
• Global proteomics for pharmacodynamics 
• ProteoCarta® proteomics platform
• ZeptoMARK protein profiling system  
• Role of proteomics in targeting disease pathways 
• Dynamic proteomics
• Identification of protein kinases as drug targets
• Mechanisms of action of kinase inhibitors
• G-protein coupled receptors as drug targets 
• Methods of study of GPCRs  
• Cell-based assays for GPCR  
• Companies involved in GPCR-based drug discovery  
• GPCR localization database  
• Matrix metalloproteases as drug targets  
• Oligodendrocyte proteome as a target for antipsychotics 
• PDZ proteins as drug targets 
• Proteasome as drug target 
• Serine hydrolases as drug targets  
• Targeting mTOR signaling pathway 
• Targeting caspase-8 for anticancer therapeutics 
• Drug design based on structural proteomics
• Protein crystallography for determining 3D structure of proteins  
• Automated 3D protein modeling 
• Drug targeting of flexible dynamic proteins 
• Companies involved in structure-based drug-design 
• Integration of genomics and proteomics for drug discovery 
• Ligand-receptor binding 
• Role of proteomics in study of ligand-receptor binding 
• Measuring drug binding of proteins 
• Aptamer protein binding 
• Systematic Evolution of Ligands by Exponential Enrichment  
• Aptamers and high-throughput screening
• Nucleic Acid Biotools  
• Aptamer beacons 
• Peptide aptamers 
• Riboreporters for drug discovery 
• Target identification and validation 
• Application of mass spectrometry for target identification  
• Gene knockout and gene suppression for validating protein targets
• Laser-mediated protein knockout for target validation 
• Integrated proteomics for drug discovery 
• High-throughput proteomics
• Companies involved in high-throughput proteomics 
• Drug discovery through protein-protein interaction studies 
• Protein-protein interaction as basis for drug target identification  
• Protein-PCNA interaction as basis for drug design 
• Two-hybrid protein interaction technology for target identification  
• Biosensors for detection of small molecule-protein interactions 
• Protein-protein interaction maps 
• ProNet (Myriad Genetics)  
• Hybrigenics' maps of protein-protein interactions  
• CellZome's functional map of protein-protein interactions  
• Mapping of protein-protein interactions by mass spectrometry 
• Protein interaction map of Drosophila melanogaster 
• Protein-interaction map of Wellcome Trust Sanger Institute  
• Protein-protein interactions as targets for therapeutic intervention 
• Inhibition of protein-protein interactions by peptide aptamers  
• Selective disruption of proteins by small molecules  
• Post-genomic combinatorial biology approach 
• Differential proteomics 
• Shotgun proteomics
• Hyper Reaction Monitoring 
• Targeted proteomics
• Chemogenomics/chemoproteomics for drug discovery 
• Chemoproteomics-based drug discovery  
• Companies involved in chemogenomics/chemoproteomics 
• Activity-based proteomics 
• Locus Discovery technology 
• Automated ligand identification system
• Expression proteomics: protein level quantification 
• Role of phage antibody libraries in target discovery 
• Analysis of posttranslational modification of proteins by MS 
• Phosphoproteomics for drug discovery
• Application of glycoproteomics for drug discovery 
• Role of carbohydrates in proteomics 
• Challenges of glycoproteomics 
• Companies involved in glycoproteomics 
• Microproteins as targets for drug discovery
• Role of protein microarrays/ biochips for drug discovery 
• Protein microarrays vs DNA microarrays for high-throughput screening 
• BIA-MS biochip for protein-protein interactions 
• ProteinChip with Surface Enhanced Neat Desorption
• Protein-domains microarrays 
• Some limitations of protein biochips  
• Concluding remarks about role of proteomics in drug discovery
• RNA versus protein profiling as guide to drug development 
• RNA as drug target 
• Combination of RNA and protein profiling 
• RNA binding proteins 
• Toxicoproteomics
• Hepatotoxicity  
• Nephrotoxicity  
• Cardiotoxicity 
• Neurotoxicity
• Protein/peptide therapeutics
• Alphabody technology for improving protein therapeutics
• Peptide-based drugs
• Phylomer® peptides
• Cryptein-based therapeutics
• Synthetic proteins and peptides as pharmaceuticals 
• Genetic immunization and proteomics 
• Role of proteomics in synthetic antivenoms
• Proteomics and gene therapy 
• Role of proteomics in clinical drug development
• Pharmacoproteomics  
• Role of proteomics in clinical drug safety 

7. Application of Proteomics in Human Healthcare  

• Introduction 
• Clinical proteomics 
• Definition and standards 
• Vermillion's Clinical Proteomics Program  
• Pathophysiology of human diseases 
• Diseases due to misfolding of proteins  
• Mechanism of protein folding 
• Nanoproteomics for study of misfolded proteins 
• Therapies for protein misfolding 
• Intermediate filament proteins 
• Significance of mitochondrial proteome in human disease  
• Proteome of Saccharomyces cerevisiae mitochondria
• Rat mitochondrial proteome 
• Proteomic approaches to biomarker identification
• The ideal biomarker 
• Proteomic technologies for biomarker discovery
• MALDI mass spectrometry for biomarker discovery  
• Protein biochips/microarrays and biomarkers 
• Affinity proteomics for discovery of biomarkers 
• Antibody array-based biomarker discovery 
• Discovery of biomarkers by MAb microarray profiling
• Tumor-specific serum peptidome patterns
• Search for protein biomarkers in body fluids
• Challenges and strategies for discovey of protein biomarkers in plasma 
• 3-D structure of CD38 as a biomarker  
• BD™ Free Flow Electrophoresis System 
• Isotope tags for relative and absolute quantification 
• N-terminal peptide isolation from human plasma  
• Plasma protein microparticles as biomarkers  
• Proteome partitioning 
• SISCAPA method for quantitating proteins and peptides in plasma  
• Stable isotope tagging methods  
• Technology to measure both the identity and size of the biomarker
• Biomarkers in the urinary proteome  
• Application of proteomics in molecular diagnosis 
• MassARRAY 
• Proximity ligation assay 
• Protein patterns 
• Proteomic tests on body fluids 
• Cyclical amplification of proteins 
• Applications of proteomics in infections 
• MALDI-TOF MS for microbial identification
• Recognition of microbial glycans by human lectins 
• Role of proteomics in virology 
• Interaction of proteins with viruses 
• Quantitative temporal viromics 
• Role of proteomics in bacteriology 
• Epidemiology of bacterial infections
• Proteomic approach to bacterial pathogenesis 
• Vaccines for bacterial infections  
• Protein profiles associated with bacterial drug resistance 
• Analyses of the parasite proteome 
• Application of proteomics in cystic fibrosis 
• Proteomics of cardiovascular diseases 
• Pathomechanism of cardiovascular diseases 
• Protein misfolding in cardiac dysfunction 
• Study of cardiac mitochondrial proteome in myocardial ischemia 
• Cardiac protein databases 
• Proteomics of dilated cardiomyopathy and heart failure  
• Proteomic biomarkers of cardiovascular diseases  
• Regulation of cardiac rhythmicity by Purkinje cell protein-4 
• Role of proteomics in cardioprotection  
• Role of proteomics in heart transplantation 
• Future of application of proteomics in cardiology
• Proteomic technologies for research in pulmonary disorders 
• Application of proteomics in renal disorders
• Diagnosis of renal disorders 
• Proteomic biomarkers of acute kidney injury  
• Cystatin C as biomarker of glomerular filtration rate
• Protein biomarkers of nephritis 
• Proteomics and kidney stones 
• Proteomics of eye disorders
• Proteomics of cataract 
• Proteomics of diabetic retinopathy 
• Retinal dystrophies 
• Use of proteomics in inner ear disorders 
• Use of proteomics in aging research 
• Alteration of glycoproteins during aging 
• Carbamylation of proteins with aging
• Proteomics of muscle aging  
• Removal of altered cellular proteins in aging  
• Role of protein aggregation in aging and degenerative diseases 
• Study of the role of Parkin in modulating aging 
• Study of proteins that protect against hypoxic injury in age-related disorders 
• Proteomics and nutrition 

8. Oncoproteomics

• Introduction 
• Proteomic technologies for study of cancer 
• Application of CellCarta technology for oncology 
• Accentuation of differentially expressed proteins using phage technology 
• Cancer tissue proteomics  
• Dynamic cell proteomics in response to a drug  
• Desorption electrospray ionization for cancer diagnosis
• Id proteins as targets for cancer therapy 
• Identification of oncogenic tyrosine kinases using phosphoproteomics 
• Laser capture microdissection technology and cancer proteomics 
• Mass spectrometry for identification of oncogenic chimeric proteins
• Proteomic analysis of cancer cell mitochondria
• Proteomic study of p53  
• Human Tumor Gene Index 
• Integration of cancer genomics and proteomics 
• Role of proteomics in study of cancer stem cell biology 
• Single-cell protein expression analysis by microfluidic techniques
• Use of proteomics in cancers of various organ systems 
• Proteomics of brain tumors  
• Malignant glial tumors 
• Meningiomas 
• DESI-MS for intraoperative diagnosis of brain tumors  
• Proteomics of breast cancer 
• Integration of proteomic and genomic data for breast cancer 
• Proteomics of colorectal cancer
• Proteomics of esophageal cancer 
• Proteomics of hepatic cancer 
• Proteomics of leukemia 
• Proteomics of lung cancer 
• Proteomics of pancreatic cancer 
• Proteomics of prostate cancer 
• Proteomics of renal cancer 
• Diagnostic use of cancer biomarkers 
• Proteomic technologies for tumor biomarkers 
• Nuclear matrix proteins (NMPs)  
• Antiannexins as tumor markers in lung cancer
• NCI’s Network of Clinical Proteomic Technology Centers
• Proteomics and tumor immunology 
• Proteomics and study of tumor invasiveness 
• Anticancer drug discovery and development 
• Anticancer drug targeting: functional proteomics screen of proteases 
• Kinase-targeted drug discovery in oncology
• Protein-drug interactions in cancer 
• Role of proteomics in studying drug resistance in cancer
• Small molecule inhibitors of cancer-related proteins 
• Future prospects of oncoproteomics 
• International oncoproteomic initiatives 
• Clinical Proteomic Tumor Analysis Consortium 
• Companies involved in application of proteomics to oncology 

9. Neuroproteomics 

• Introduction  
• Application of proteomics for the study of nervous system 
• Proteomics of prion diseases 
• Normal function of prions in the brain
• Detection of protein aggregates and prions 
• Diseases due to pathological prion protein  
• Transmissible spongiform encephalopathies 
• Creutzfeld-Jakob disease  
• Bovine spongiform encephalopathy 
• Variant Creutzfeldt-Jakob disease  
• Protein misfolding/aggregation in neurodegenerative disorders
• Alzheimer disease 
• Amyotrophic lateral sclerosis 
• Common denominators of Alzheimer and prion diseases 
• Detection of misfolded proteins in neurodegenerative disorders 
• Ion channel link for protein-misfolding disease  
• Modulation of proteostasis in neurodegenerative disorders 
• Neurodegenerative disorders with protein abnormalities 
• Parkinson disease 
• Proteomics and glutamate repeat disorders 
• Proteomics and Huntington's disease
• Targets to limit protein aggregation in neurodegenerative diseases 
• Aggregate contactome
• Clusterin for clearance of aggregating misfoded proteins
• Proteomics and demyelinating diseases 
• Proteomics of neurogenetic disorders 
• Fabry disease 
• GM1 gangliosidosis 
• Quantitative proteomics and familial hemiplegic migraine  
• Proteomics of spinal muscular atrophy 
• Proteomics of CNS trauma 
• Proteomics of traumatic brain injury 
• Chronic traumatic encephalopathy and ALS 
• Proteomics of cerebrovascular disease 
• Pathogenesis of cerebral small vessel disease
• Proteomics of CNS aging
• Protein aggregation as a biomarker of aging
• Neuroproteomics of psychiatric disorders
• Schizophrenia
• Anxiety disorders 
• Depression ans suicidal behavior
• Neuroproteomic of cocaine addiction 
• Neurodiagnostics based on proteomics
• Disease-specific proteins in the cerebrospinal fluid 
• Tau proteins 
• CNS tissue proteomics 
• Diagnosis of CNS disorders by examination of proteins in urine 
• Diagnosis of CNS disorders by examination of proteins in the blood
• Serum pNF-H as biomarker of CNS damage 
• Intraoperative application of proteomics in surgery of brain tumors
• Proteomics of BBB 
• Future of neuroproteomics in neurology 
• HUPO’s Pilot Brain Proteome Project  

10. Proteomics Markets 

• Introduction 
• Potential markets for proteomic technologies 
• Bioinformatics markets for proteomics  
• Markets for protein separation technologies 
• Markets for 2D gel electrophoresis 
• Market trends in protein separation technolgies 
• Protein purification markets 
• Mass spectrometry markets 
• Markets for MALDI for drug discovery 
• Markets for nuclear magnetic resonance spectroscopy 
• Market for structure-based drug design 
• Markets for protein biomarkers 
• Markets for cell-based protein assays 
• Protein biochip markets 
• Western blot markets 
• Geographical distribution of proteomics technologies markets  
• Business and strategic considerations 
• Cost of protein structure determination 
• Opinion surveys of the scientist consumers of proteomic technologies 
• Opinions on mass spectrometry  
• Opinions on bioinformatics and proteomic databases 
• Systems for in vivo study of protein-protein interactions
• Perceptions of the value of protein biochip/microfluidic systems
• Small versus big companies 
• Expansion in proteomics according to area of application 
• Growth trends in cell-based protein assay market 
• Challenges for development of cell-based protein assays 
• Future trends and prospects of cell-based protein assays 
• Strategic collaborations 
• Analysis of proteomics collaborations according to types of companies  
• Types of proteomic collaborations  
• Proteomics collaborations according to application areas
• Analysis of proteomics collaborations: types of technologies 
• Collaborations based on protein biochip technology  
• Concluding remarks about proteomic collaborations 
• Proteomic patents 
• Market drivers in proteomics 
• Needs of the pharmaceutical industry 
• Need for outsourcing proteomic technologies 
• Funding of proteomic companies and research
• Technical advances in proteomics  
• Changing trends in healthcare in future 
• Challenges facing proteomics 
• Magnitude and complexity of the task
• Technical challenges
• Limitations of proteomics  
• Limitations of 2DGE
• Limitations of mass spectrometry techniques 
• Complexity of the pharmaceutical proteomics 
• Unmet needs in proteomics  

11. Future of Proteomics  

• Genomics to proteomics 
• Faster technologies 
• FLEXGene repository  
• Need for new proteomic technologies
• Emerging proteomic technologies
• Detection of alternative protein isoforms 
• Direct protein identification in large genomes by mass spectrometry  
• Proteome identification kits with stacked membranes  
• Vacuum deposition interface
• In vitro protein biosynthesis 
• Proteome mining with adenosine triphosphate 
• Proteome-scale purification of human proteins from bacteria
• Proteostasis network  
• Single cell proteomics
• Fluorescent proteins for live-cell imaging 
• Live cell proteomics
• Microfluidics for cell proteomics  
• Nanoscale study of cell proteomics 
• Membrane proteomics 
• Identification of membrane proteins by tandem MS of protein ions 
• Solid state NMR for study of nanocrystalline membrane proteins 
• Subcellular proteomics  
• Multiplex proteomics  
• High-throughput for proteomics  
• Future directions for protein biochip application 
• Bioinformatics for proteomics  
• High-Throughput Crystallography Consortium
• Study of protein folding by IBM’s Blue Gene 
• Study of proteins by atomic force microscopy 
• Population proteomics 
• Comparative proteome analysis
• Human Proteome Organization 
• Cell-based Human Proteome Project 
• Human Salivary Proteome 
• Academic-commercial collaborations in proteomics 
• Indiana Centers for Applied Protein Sciences  
• Role of proteomics in the healthcare of the future
• Proteomics and molecular medicine
• Proteodiagnostics
• Proteomics and personalized medicine  
• Targeting the ubiquitin pathway for personalized therapy of cancer
• Protein patterns and personalized medicine
• Personalizing interferon therapy of hepatitis C virus 
• Protein biochips and personalized medicine 
• Combination of diagnostics and therapeutics  
• Future prospects 

12. References

Tables

Table 1-1: Landmarks in the evolution of proteomics  
Table 1-2: Comparison of DNA and protein 
Table 1-3: Comparison of mRNA and protein 
Table 1-4: Methods of analysis at various levels of functional genomics 
Table 2-1: Proteomics technologies
Table 2-2: Protein separation technologies of selected companies 
Table 2-3: Companies supplying mass spectrometry instruments 
Table 2-4: Companies involved in cell-based protein assays  
Table 2-5: Methods used for the study of protein-protein interactions 
Table 2-6: A selection of companies involved in protein-protein interaction studies 
Table 2-7: Companies involved in Western blotting 
Table 2-8: Proteomic technologies used with laser capture microdissection 
Table 3-1: Applications of protein biochip technology  
Table 3-2: Selected companies involved in protein biochip/microarray technology  
Table 4-1: Proteomic databases and other Internet sources of proteomics information  
Table 4-2: Protein interaction databases available on the Internet 
Table 4-3: Bioinformatic tools for proteomics from academic sources  
Table 4-4: Selected companies involved in bioinformatics for proteomics 
Table 5-1: Applications of proteomics in basic biological research 
Table 5-2: A sampling of proteomics research projects in academic institutions 
Table 6-1: Pharmaceutical applications of proteomics
Table 6-2: Selected companies relevant to MALDI-MS for drug discovery
Table 6-3: Selected companies involved in GPCR-based drug discovery  
Table 6-4: Companies involved in drug design based on structural proteomics 
Table 6-5: Proteomic companies with high-throughput protein expression technologies 
Table 6-6: Selected companies involved in chemogenomics/chemoproteomics 
Table 6-7: Companies involved in glycoproteomic technologies 
Table 7-1: Applications of proteomics in human healthcare 
Table 7-2: Eye disorders and proteomic approaches 
Table 8-1: Large scale international oncoproteomic initiatives 
Table 8-2: Companies involved in applications of proteomics to oncology  
Table 9-1: Neurodegenerative diseases with underlying protein abnormality 
Table 9-2: Disease-specific proteins in the cerebrospinal fluid of patients
Table 10-1: Potential markets for proteomic technologies 2020-2030 
Table 10-2: Geographical distribution of markets for proteomic technologies 2020-2030  
Table 11-1: Role of proteomics in personalizing strategies for cancer therapy  

Figures

Figure 1-1: A schematic miRNA pathway 
Figure 1-2: Relationship of DNA, RNA and protein in the cell
Figure 1-3: Protein production pathway from gene expression to functional protein  
Figure 1-4: Parallels between functional genomics and proteomics 
Figure 2-1: Proteomics: flow from sample preparation to characterization
Figure 2-2: The central role of spectrometry in proteomics 
Figure 2-3: Electrospray ionization (ESI) 
Figure 2-4: Ion-mobility spectrometry-MS  
Figure 2-5: Matrix-Assisted Laser Desorption/Ionization (MALDI)
Figure 2-6: Scheme of bio-bar-code assay  
Figure 2-7: A diagrammatic presentation of yeast 2-hybrid system 
Figure 2-8: A schematic view of SubCellBarCode  
Figure 3-1: ProteinChip System 
Figure 3-2: Surface plasma resonance (SPR)
Figure 4-1: Role of bioinformatics in integrating genomic/proteomic-based drug discovery  
Figure 4-2: Bottom-up and top-down approaches for protein sequencing 
Figure 6-1: Drug discovery process 
Figure 6-2: Regulatory changes induced by drugs and implemented at the proteins level
Figure 6-3: Relation of proteome to genome, diseases and drugs 
Figure 6-4: The mTOR pathways 
Figure 6-5: Steps in shotgun proteomics  
Figure 6-6: Chemogenomic approach to drug discovery (3-Dimensional Pharmaceuticals) 
Figure 8-1: Relation of oncoproteomics to other technologies 
Figure 9-1: Identification of protein targets in neurodegenerative disorders  
Figure 9-2: Clusterin bringing misfolded proteins into cells to be degraded by lysosomes 
Figure 9-3: A scheme of proteomics applications in CNS drug discovery and development 
Figure 10-1: Types of companies involved in proteomics collaborations  
Figure 10-2: Types of collaborations: R & D, licensing or marketing 
Figure 10-3: Proteomics collaborations according to application areas 
Figure 10-4: Proteomics collaborations according to technologies 
Figure 10-5: Unmet needs in proteomics  
Figure 11-1: A scheme of the role of proteomics in personalized management of cancer

Part II: Companies

13. Companies involved in developing proteomics

• Introduction 
• Profiles of selected companies
• Collaborations

Tables

Table 13-1: Companies with proteomics as the main activity/service
Table 13-2: Selected companies with equipment and laboratory services for proteomics
Table 13-3: Biotechnology and drug discovery companies involved in proteomics 
Table 13-4: Bioinformatics companies involved in proteomics 
Table 13-5: Biopharmaeutical companies with in-house proteomic technologies 
Table 13-6: Major players in proteomics 
Table 13-7: Selected collaborations of companies in the area of proteomics  

Samples