La proteómica en las biociencias

Protein power

Robert F. Service 

Ancient DNA may be entering its golden age, but some researchers have their eyes on another molecule that may offer new view of the past: protein, which has some advantages over its more famous cousin. Tissues are full of protein, making analysis easier. Proteins also resist the ravages of time far better than fragile DNA and so have the potential to look further back in time—researchers have identified 300 million year old proteins in fish fossils. Ancient proteins have already illuminated a few far-flung corners of past life, including identifying the family tree of strange, extinct South American mammals that flummoxed even Charles Darwin. The method appears particularly promising in archaeology, where it can reveal the diets and lifestyles of past cultures. Still, the technique has a long way to go before it reaches the maturity of paleogenetics, chiefly because methods to sequence amino acids lag behind DNA sequencing.

http://news.sciencemag.org/paleontology/2015/07/protein-power










Ancient human microbiomes

• Christina Warinner^a, 
• Camilla Speller^b, 
• Matthew J. Collins^b, 
• Cecil M. Lewis Jr

Very recently, we discovered a vast new microbial self: the human microbiome. Our native microbiota interface with our biology and culture to influence our health, behavior, and quality of life, and yet we know very little about their origin, evolution, or ecology. With the advent of industrialization, globalization, and modern sanitation, it is intuitive that we have changed our relationship with microbes, but we have little information about the ancestral state of our microbiome, and we therefore lack a foundation for characterizing this change. High-throughput sequencing has opened up new opportunities in the field of paleomicrobiology, allowing us to investigate the evolution of the complex microbial ecologies that inhabit our bodies. By focusing on recent coprolite and dental calculus research, we explore how emerging research on ancient human microbiomes is changing the way we think about ancient disease and how archaeological studies can contribute to a medical understanding of health and nutrition today.

Detecting the Immune System Response of a 500 Year-Old Inca Mummy 

Corthals A, et al. PLoS ONE7(7): e41244. doi:10.1371/journal.pone.0041244.Disease detection in historical samples currently relies on DNA extraction and amplification, or immunoassays. These techniques only establish pathogen presence rather than active disease. We report the first use of shotgun proteomics to detect the protein expression profile of buccal swabs and cloth samples from two 500-year-old Andean mummies. The profile of one of the mummies is consistent with immune system response to severe pulmonary bacterial infection at the time of death. Presence of a probably pathogenicMycobacterium sp. in one buccal swab was confirmed by DNA amplification, sequencing, and phylogenetic analyses. Our study provides positive evidence of active pathogenic infection in an ancient sample for the first time. The protocol introduced here is less susceptible to contamination than DNA-based or immunoassay-based studies. In scarce forensic samples, shotgun proteomics narrows the range of pathogens to detect using DNA assays, reducing cost. This analytical technique can be broadly applied for detecting infection in ancient samples to answer questions on the historical ecology of specific pathogens, as well as in medico-legal cases when active pathogenic infection is suspected.

Rewriting history trough proteins. 

Wiecek. A.S. BioTecniques 54:19-21. doi: 10.2144/000113975.
Today, researchers interested in exploring ancient samples and remains at the molecular level mainly rely on DNA. But proteins might tell us even more about history. Andrew Wiecek examines how protein analysis techniques are shedding new light on Inca history.

The Silk Road, Marco Polo, a bible and its proteome: A detective story. 

Lucia Toniolo, et al.  Journal of Proteomics. 2012, 75 (11), 3365–3373. http://dx.doi.org/10.1016/j.jprot.2012.03.051

Around the end of XIII century (at the time of young Marco Polo's first trip to China at the court of Khubilai Khan in Khan Baliq) a pocket Bible was delivered by a Franciscan friar to the Mogul Emperor, in the framework of the evangelization program of the Far East. Four centuries later, in 1685, this Bible was rediscovered by the Jesuit Philippe Couplet in the house of a rich Chinese in Nanchin and donated to Cosimo III, Grand Duke of Tuscany. This Bible was recently “unearthed” in the Biblioteca Medicea Laurenziana in Florence, wrapped up in a precious yellow silk cloth, in a rather ruined state. After two years of restoration, the Bible will return to China in 2012 for a celebration of its > 700 years of life and of its remarkable return trip on the Silk Road. On account of the thinness of the parchment (barely 80 μm thickness, the size of each foil being 16.5 × 11 cm) it was widely held that the pages were produced from foetal lambskins. On tiny fragments of the margins of a foil, after several unsuccessful attempts at digesting the vellum, we were able to obtain a tryptic peptide mixture, which, upon mass spectrometry analysis, yielded the identity of 8 unique proteins, belonging to the genus Bos taurus, thus confirming the origin of the vellum from calfskins rather than from foetal lambskins. Our results prove that it is possible to obtain reliable protein extraction and IDs from ancient parchment documents.

Proteomic Analysis of a Pleistocene Mammoth Femur Reveals More than One Hundred Ancient Bone Proteins. 

Enrico Cappellini, et al. J. Proteome Res. 2012, 11, 917–926
http://pubs.acs.org.pbidi.unam.mx:8080/doi/pdf/10.1021/pr200721u
We used high-sensitivity, high-resolution tandem mass spectrometry to shotgun sequence ancient protein remains extracted from a 43 000 year old woolly mammoth (Mammuthus primigenius) bone preserved in the Siberian permafrost. For the first time, 126 unique protein accessions, mostly low-abundance extracellular matrix and plasma proteins, were confidently identified by solid molecular evidence. Among the best characterized was the carrier protein serum albumin, presenting two single amino acid substitutions compared to extant African (Loxodonta africana) and Indian (Elephas aximus) elephants. Strong evidence was observed of amino acid modifications due to postmortem hydrolytic and oxidative damage. A consistent subset of this permafrost bone proteome was also identified in more recent Columbian mammoth (Mammuthus columbi) samples from temperate latitudes, extending the potential of the approach described beyond subpolar environments. Mass spectrometry-based ancient protein sequencing offers new perspectives for future molecular phylogenetic inference and physiological studies on samples not amenable to ancient DNA investigation. This approach therefore represents a further step into the ongoing integration of different high-throughput technologies for identification of ancient biomolecules, unleashing the field of paleoproteomics.

Paleoproteomic study of the Iceman’s brain tissue. 

Maixner et al. 

New insights into the Tyrolean Iceman's origin and phenotype as inferred by whole-genome sequencing

http://www.nature.com/ncomms/journal/v3/n2/full/ncomms1701.html

Cell Mol Life Sci. 2013 Jun 6. [Epub ahead of print]
http://link.springer.com/article/10.1007%2Fs00018-013-1360-y

The Tyrolean Iceman, a Copper-age ice mummy, is one of the best-studied human individuals. While the genome of the Iceman has largely been decoded, tissue-specific proteomes have not yet been investigated. We studied the proteome of two distinct brain samples using gel-based and liquid chromatography-mass spectrometry-based proteomics technologies together with a multiple-databases and -search algorithms-driven data-analysis approach. Thereby, we identified a total of 502 different proteins. Of these, 41 proteins are known to be highly abundant in brain tissue and 9 are even specifically expressed in the brain. Furthermore, we found 10 proteins related to blood and coagulation. An enrichment analysis revealed a significant accumulation of proteins related to stress response and wound healing. Together with atomic force microscope scans, indicating clustered blood cells, our data reopens former discussions about a possible injury of the Iceman's head near the site where the tissue samples have been extracted.

2D gels still have a niche in proteomics

Adelina Rogowska-Wrzesinska, 

Marie-Catherine Le Bihan, 

Morten Thaysen-Andersen, 

Peter Roepstorff.

 http://dx.doi.org/10.1016/j.jprot.2013.01.010. 

With the rapid advance of MS-based proteomics one might think that 2D gel-based proteomics is dead. This is far from the truth. Current research has shown that there are still a number of places in the field of protein and molecular biology where 2D gels still play a leading role. The aim of this review is to highlight some of these applications. Examples from our own research as well as from other published works are used to illustrate the 2D gel driven research in the areas of: 1) de novo sequencing and protein identification from organisms with no or incomplete genome sequences available; 2) alternative detection methods for modification specific proteomics; 3) identification of protein isoforms and modified proteins. With an example of the glycoprotein TIMP-1 protein we illustrate the unique properties of 2D gels for the separation and characterisation of multiply modified proteins. We also show that careful analysis of experimental and theoretical protein mass and pI can lead to the identification of unanticipated protein variants modified by for example proteolytic cleavage. Together this shows that there is an important niche for 2D gel-based proteomics, which compliments traditional LC-MS techniques for specific protein research purposes.

Sitios WEB y algunas revistas de apoyo al curso

TED Fellow Christina Warinner is an expert on ancient diets. So how much of the diet fad the "Paleo Diet" is based on an actual Paleolithic diet? The answer is not really any of it.

Dr. Christina Warinner has excavated around the world, from the Maya jungles of Belize to the Himalayan mountains of Nepal, and she is pioneering the biomolecular investigation of archaeological dental calculus (tartar) to study long-term trends in human health and diet. She is a 2012 TED Fellow, and her work has been featured in Wired UK, the Observer, CNN.com, Der Freitag, and Sveriges TV. She obtained her Ph.D. from Harvard University in 2010, specializing in ancient DNA analysis and paleodietary reconstruction.

http://tedxtalks.ted.com/video/Debunking-the-Paleo-Diet-Christ

UniProt:

http://www.uniprot.org/

The mission of UniProt is to provide the scientific community with a comprehensive, high-quality and freely accessible resource of protein sequence and functional information.

ExPASy

http://www.expasy.org/tools/

ExPASy is the SIB Bioinformatics Resource Portal which provides access to scientific databases and software tools (i.e., resources) in different areas of life sciences including proteomics, genomics, phylogeny, systems biology, population genetics, transcriptomics etc. (see Categories in the left menu). On this portal you find resources from many different SIB groups as well as external institutions.

Unimod

http://www.unimod.org/login.php?message=expired (Login as guest)

Unimod is a public domain database, distributed under a copyleft licence: "a copyright notice that permits unrestricted redistribution and modification, provided that all copies and derivatives retain the same permissions."

The aim is to create a community supported, comprehensive database of protein modifications for mass spectrometry applications. That is, accurate and verifiable values, derived from elemental compositions, for the mass differences introduced by all types of natural and artificial modifications. Other important information includes any mass change, (neutral loss), that occurs during MS/MS analysis, and site specificity, (which residues are susceptible to modification and any constraints on the position of the modification within the protein or peptide).

Prosite

http://prosite.expasy.org/

PROSITE consists of documentation entries describing protein domains, families and functional sites as well as associated patterns and profiles to identify them [More details / References / Commercial users].
PROSITE is complemented by ProRule, a collection of rules based on profiles and patterns, which increases the discriminatory power of profiles and patterns by providing additional information about functionally and/or structurally critical amino acids [More details].

Virtual Proteomics Laboratory

http://iitb.vlab.co.in/?sub=41&brch=118

The Proteomics Virtual Laboratory provides in-depth information about modern, high-throughput proteomic techniques available and their application to various proteomic studies. The field of proteomics has gained popularity following the successful completion of several genome sequencing projects and large amounts of gene data being made available to researchers. The genome, however, represents only the first step towards understanding complex biological processes. Significant amount of information regarding molecular and cellular processes can be obtained from the products of gene expression – the proteins. “Proteomics” is the study of the entire protein complement of a cell, organ or organism at a given time including the set of protein isoforms and all its complements. The high-throughput analysis of several proteins simultaneously requires robust platforms that can detect extremely small quantities of proteins with high sensitivity and specificity. The Proteomics Virtual Laboratory aims to provide students a first-hand experience of commonly used proteomic techniques with the help of animations and video footage of actual lab experiments. In addition to this, users will be provided reading material to enhance their theoretical knowledge about these techniques, which find wide applications such as discovery of biomarkers, immunological studies, protein-protein interaction studies etc. There has been a surge in the number of proteomics techniques developed over the last decade which have increasingly facilitated proteomics studies. The data generated through these experiments will also be made available, which will enable researchers and students to carry out data analysis and interpretation with the help of suitable software

Human Proteome Map

Kim et al. A draft map of the human proteome. 2014. Nature.  509, 575-581. [PubMed]

The Human Proteome Map (HPM) portal is an interactive resource to the scientific community by integrating the massive peptide sequencing result from the draft map of the human proteome project. The project was based on LC-MS/MS by utilizing of high resolution and high accuracy Fourier transform mass spectrometry. All mass spectrometry data including precursors and HCD-derived fragments were acquired on the Orbitrap mass analyzers in the high-high mode. Currently, the HPM contains direct evidence of translation of a number of protein products derived from over 17,000 human genes covering >84% of the annotated protein-coding genes in humans based on >290,000 non-redundant peptide identifications of multiple organs/tissues and cell types from individuals with clinically defined healthy tissues. This includes 17 adult tissues, 6 primary hematopoietic cells and 7 fetal tissues. The HPM portal provides an interactive web resource by reorganizing the label-free quantitative proteomic data set in a simple graphical view. In addition, the portal provides selected reaction monitoring (SRM) information for all peptides identified. 

Proteomics 

http://onlinelibrary.wiley.com/journal/10.1002/(ISSN)1615-9861

2014 Reviews Issue - Free Online

This issue of PROTEOMICS contains the 2014 collection of review articles covering various aspects of proteomics technologies and their application in the biosciences — an excellent way for both relative newcomers and experts to keep abreast of developments in the field... All articles are freely available in 2014 Read the Special Issue now »

Proteomics clinical applications

http://onlinelibrary.wiley.com/doi/10.1002/prca.v8.1-2/issuetoc

Special Issue: Reviews 2014

February 20l4

Volume 8, Issue 1-2 Pages 1-126

Issue edited by Michael J. Dunn

Journal of Proteomics

http://www.journals.elsevier.com/journal-of-proteomics/

Journal of Proteomics is the official journal of the European Proteomics Association (EuPA) and is aimed at both European and international protein scientists and analytical chemists in the field of proteomics, biomarker discovery, protein analytics, plant proteomics, microbial and animal proteomics, human studies and protein bioinformatics. The journal welcomes papers in new and upcoming areas such as metabolomics, genomics, systems biology, toxicogenomics and pharmacoproteomics. Journal of Proteomics unifies both fundamental scientists and clinicians, and includes translational research.Suggestions for reviews, webinars and thematic issues are welcome. All manuscripts are strictly peer reviewed and conform the highest ethical standards. Journal of Proteomics also publishes official EuPA reports and participates in the International Proteomics Tutorial Programme with HUPO and other partners.

Proteome Science

http://www.proteomesci.com/

Proteome Science considers manuscripts based on all aspects of functional and structural proteomics. Proteome Science is an open access, peer-reviewed, online journal considering research in proteomics. The journal is specifically interested in manuscripts that integrate functional or structural proteomic analysis with cell or developmental biology. Proteome Science will consider studies in the area of structural biology, mass spectrometry, protein arrays, bioinformatics, HTS assays, protein chemistry, cell biology, signal transduction and physiology - as long as a component of the study relates to proteomics.

Molecular & Cellular Proteomics

http://www.mcponline.org/

In summary, Molecular & Cellular Proteomics will publish three types of original articles: research papers, database articles, and technology development articles. Mini-reviews and articles discussing important unresolved issues (perspective articles), as invited contributions, will also be published. Suggestions for appropriate topics will be welcome. Letters to the editor dealing with material published in MCP will be published at the discretion of the Editors.

Translational Proteomics

http://www.journals.elsevier.com/translational-proteomics


Translational Proteomics covers all areas of human proteomics using multi-disciplinary approaches to untangle complex disease processes. Emphasis is placed on linking basic sciences to clinical research (from patient to bench to bedside). It focuses on the rapid dissemination of novel discoveries. Topics included but not limited to are:

Translational Systems Biology and Integrative Bioinformatics
Clinical Proteomics and Personalized medicine
Comparative proteomics and drug development
Medical bioinformatics and biostatistics
Food and Health

Translational Proteomics is intended to academic, industrial and clinical researchers, physicians, pharmaceutical scientists, biochemists, clinical chemists, disease molecular biologists in the fields of applied human proteomics. Examples of diseases include oncology, neurology, immunity, cardiovascular disease, infectious diseases and any internal medicine disorder.

International Proteomics Tutorial Programme – supported by HUPO and EuPA

http://www.journals.elsevier.com/journal-of-proteomics/tutorials/international-proteomics-tutorial-programme/

The education committees of the Human Proteome Organisation (HUPO) and the European Proteomics Association (EuPA) together with their national counterparts have launched the International Proteomics Tutorial Programme to meet these needs. The programme is being led by Peter James (Sweden), Thierry Rabilloud (France) and Kazuyuki Nakamura (Japan). It involves collaboration between the leading proteomics journals: Journal of Proteome Research, Journal of Proteomics, Molecular and Cellular Proteomics, and Proteomics. The overall level is aimed at Masters/PhD level students who are starting out their research and who would benefit from a solid grounding in the techniques used in modern protein-based research. The tutorial program will cover core techniques and basics as an introduction to scientists new to the field. At a later stage the programme may be expanded with a series of more advanced topics focussing on the application of proteomics techniques to biological problem solving. The entire series of articles and slides will be made freely available for teaching use at the Journals and Organisations homepages and at a special website, www.proteomicstutorials.org