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The Journal of Neuroscience, November 1, 2001, 21(21):8315-8318
Proteomics in Neuroscience: From Protein to Network
Seth G. N. Grant1 and Walter P. Blackstock2 1 Department of Neuroscience, University of Edinburgh, Edinburgh EH8-9JZ, United Kingdom, and 2 Cellzome GmbH, 69117 Heidelberg, Germany
ABSTRACT
TOP
ABSTRACT
ARTICLE
Proteomic tools offer a new platform for studies of complex biological functions involving large numbers and networks of proteins. Intracellular networks of proteins perform key functions in neurons and glia. The unicellular eukaryote Saccharomyces cerevisiae has been the prototype for eukaryotic proteomic studies, and when combined with genomics, microarrays, genetics, and pharmacology, new insights into the integrated function of the cell emerge. The anatomical complexity of the nervous system both in cell types and in the vast number of synapses introduces novel technical and biological issues regarding the subcellular organization of protein networks. Here we will discuss the technology of proteomics and its applications to the nervous system.
ARTICLE
What is proteomics?
The completion of the human genome sequence was a tour de force of technology and international cooperation, but it came as a surprise to many that at first sight we have barely more genes than the fly and worm. Our human complexity must therefore be sought elsewhere, and interest has shifted to studying gene function and the way gene products interact. The large-scale study of proteins encoded by a genome has become known as "proteomics." Proteomics has recently been expanded to include all manner of protein studies, from yeast two-hybrid protein interaction studies to structure determination by x-ray crystallography, but we suggest that it should be limited to its original interpretation, as part of functional genomics.
In this interpretation, proteomics is justified by two things: the development of high-sensitivity mass spectrometry techniques and the availability of large databases: originally protein databases, then expressed sequence tag (EST) databases, and now complete genome sequences. This combination means that with clever biology and sample preparation, proteins can be identified at the rate of several thousand per day. The problem of making sense of this wealth of information is only beginning to be addressed, but we and others have shown that powerful insights into function can be made.
Proteomics to date is anchored in mass spectrometry and bioinformatics and is about the analysis of many proteins in parallel. Importantly, in almost all cases proteins do not work alone but rather as part of larger complexes; thus proteomics lends itself to the study of the functions performed by these complexes. The proteome is dynamic and varies with time and with cellular location. Thus proteomics is a massive undertaking, and it is misleading to believe that it has an end point in the sense of completing a proteome. To bring clarity, we suggested that proteomics be divided into expression proteomics and interaction (Cell Map) proteomics.
Expression proteomics is the large-scale study of variations in protein expression and is analogous to differential gene expression. So far it is based on the relatively old technique of two-dimensional gel electrophoresis, revitalized by the ability to characterize almost all of the separated protein spots by mass spectrometry. A good gel can separate several thousand proteins, and robots are now commercially available for staining gels, spot excision, and subsequent proteolysis before mass spectrometry. Among the limitations, certain important classes of proteins, such as membrane proteins, do not readily enter gels, and because protein abundance varies over a huge range it is essential to have enrichment strategies if proteins other than "housekeeping" proteins are to be seen. As an alternative to gels, isotope-coded affinity tags (ICATs) and mass spectrometry (Gygi et al., 1999
; Ideker et al., 2001
In our opinion, using proteomic approaches to study protein complexes and signaling pathways is likely to provide a better route to understanding how proteins interact to form cellular machines. We termed this Cell Map proteomics, but it is also known as interaction or functional proteomics (Blackstock and Weir, 1999
Affinity enrichment is widely used in cell map proteomics, and this can be approached through the optimization of various affinity reagents with specificity toward the proteins within a complex of interest (e.g., NMDA receptor complex) (Husi and Grant, 2001a
Proteins isolated from gels or tagged with stable isotope labels or purified complexes are now rapidly analyzed by mass spectrometry. Proteins can be analyzed at the low femtomole level, which for protein complex purification requires 108-109 cells. Protein mass alone is insufficient to identify a protein, so samples are always subjected to proteolysis, usually with trypsin, and the pool of tryptic peptides is analyzed by one of two methods. If the protein is relatively pure, for example a single spot from a two-dimensional gel, then a peptide mass fingerprint generated by matrix-assisted laser desorption mass spectrometry (MALDI), may be sufficient. This approach has the advantage of being rapid but in reality is only successful for pure samples of high abundance and for fully sequenced genomes. It is also not suitable for defining post-translational modifications. Thus, MALDI is often used as a prescreen for the second and more powerful approach of low-flow HPLC tandem mass spectrometry. Here the peptide pool is partially separated by liquid chromatography (LC) and tandem mass spectrometry provides both mass and sequence information on many thousands of peptides, under complete automation. The approach is very powerful and is used for protein complexes, ICAT strategies, and, with additional LC, for the analysis of the whole yeast proteome in a single experiment (Washburn et al., 2001
As noted, proteomics relies on mass spectrometry and on the availability of large and ever-growing databases. Many excellent software packages are available for searching mass spectrometry data against protein, EST, and genome databases. Most current efforts are going into building integrated sample management and protein identification with intelligent decision-making. Our experience is that at very low levels, manual interaction with database-searching tools is essential. Proposed interactions need validating, and although large data sets are in some ways self-validating, there remains a gap between the rate at which proteins can be identified and the rate at which they can be validated.
Functional proteomics in neuroscience
As with the emergence of any new tool, the old chestnuts in neuroscience will be subject to another round of interrogation. We will briefly discuss some of the more obvious applications and raise issues specific to the nervous system. First, at the level of individual cells in the nervous system, by far the most attention has been historically focused on the electrical properties of neurons and their connections at synapses. And here the majority of this study has focused on ion channels and neurotransmitter receptor subunits, which are well known to be subject to regulatory phosphorylation. Identification of phosphorylation sites has traditionally been performed using radioisotope labeling, which is difficult in tissues. Mass spectrometry, which detects the mass of the phosphate group, is rapidly replacing isotopic methods (Larsen and Roepstorff, 2000
Simply identifying the presence of proteins in key compartments within neurons and glia will provide an essential framework for understanding function. The synaptosome fractionation method opened up biochemical approaches to purification of synaptic proteins (Cotman and Matthews, 1971
In the same way that mRNA microarray methods can be used for expression profiling in brain diseases, expression proteomics has similar applications. Microarrays are being widely used in disease profiling (Mirnics et al., 2001
Functional proteomics and molecular networks
The multiprotein complex of intracellular proteins associated with receptors and channels is well known to be involved with signal transduction both at the level of modulating the receptor/channel (Browning et al., 1985
As discussed above, proteomic methods can produce overwhelming quantities of data. These often take the form of lists of proteins such as those found in the NMDA receptor complex (Husi et al., 2000
One of the first surprises of this cell-wide study of yeast interactions was that a single large network of 2358 interactions between 1538 proteins was made and the next largest network contained only 19 proteins (Schwikowski et al., 2000
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Figure 1. Schematic of protein interaction networks in a simple cell. a, A simple hypothetical protein interaction map for 100 proteins. Each protein is shown as a black dot, and connections between pairs of proteins are indicated by single lines. This is a simple adaptation of a 1200 protein interaction map from Schwikowski et al. (2000)
These networks or maps of protein interactions and function have not been produced for neurons to date; however, they will need to take into consideration the dramatic contrast in spatial organization of the two cells, spherical yeast versus stellate neurons. Simply put, the synapse will be the location of specific networks (here referred to as synaptic networks), which are satellites connected to a single network at the soma (soma networks) (Fig. 2). The soma network may share many common features with that described from yeast because that is a generic cell. Moreover, the synaptic networks may have clusters of proteins (functional sets) that are also found within the soma network, such as those involved with vesicular transport, protein synthesis, or signal transduction.
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Figure 2. A hypothetical neuron interaction map. a, A map of a simple spherical cell as shown in Figure 1a. b, A map of interactions superimposed on the subcellular architecture of neurons. The soma network is the same as that for the spherical cell, and five individual synapse protein interaction maps are shown. The synapse networks could under many conditions behave autonomously, and under other conditions interact with the soma network. The spatial organization of neuronal architecture will present novel regulatory features as well as pose methodological challenges.
Molecular network maps of neurons with soma networks connected to synaptic networks will provide a wealth of interesting questions, many of which lend themselves to computational models. A diverse set of proteomic approaches is relevant to the study of protein networks in neurons. The levels of individual proteins, interactions, phosphorylation, and activity (enzyme assays) could be monitored and, where possible, preferably in live cells. The cell biology of protein networks will move away from the study of a single protein and move toward studies of multiple proteins simultaneously. Yeast studies suggest that a highly integrated approach to the study of networks is required where genetics, expression arrays, and proteomics are combined (Ideker et al., 2001
FOOTNOTES Correspondence should be addressed to Dr. Seth Grant, Department of Neuroscience, Edinburgh University, 1 George Square, Edinburgh EH8-9JZ, UK. E-mail: seth.grant{at}ed.ac.uk.
REFERENCES
- Blackstock WP, Weir MP (1999) Proteomics: quantitative and physical mapping of cellular proteins. Trends Biotechnol 17:121-127[Web of Science][Medline].
- Browning MD, Huganir R, Greengard P (1985) Protein phosphorylation and neuronal function. J Neurochem 45:11-23[Medline].
- Cotman CW, Matthews DA (1971) Synaptic plasma membranes from rat brain synaptosomes: isolation and partial characterization. Biochim Biophys Acta 249:380-394[Medline].
- Edgar PF, Douglas JE, Cooper GJ, Dean B, Kydd R, Faull RL (2000) Comparative proteome analysis of the hippocampus implicates chromosome 6q in schizophrenia. Mol Psychiatry 5:85-90[Medline].
- Gombos G, Morgan I, Breckenridge WC, Breckenridge JE, Vincedon G (1971) Isolation and biochemical structure of synaptosomal membrane (in French). C R Seances Soc Biol Fil 165:499-506[Medline].
- Grant SG, O'Dell TJ (2001) Multiprotein complex signaling and the plasticity problem. Curr Opin Neurobiol 11:363-368[Web of Science][Medline].
- Gygi SP, Rist B, Gerber SA, Turecek F, Gelb MH, Aebersold R (1999) Quantitative analysis of complex protein mixtures using isotope-coded affinity tags. Nat Biotechnol 17:994-999[Web of Science][Medline].
- Husi H, Grant SG (2001a) Isolation of 2000-kDa complexes of N-methyl-D-aspartate receptor and postsynaptic density 95 from mouse brain. J Neurochem 77:281-291[Medline].
- Husi H, Grant SG (2001b) Proteomics of the nervous system. Trends Neurosci 24:259-266[Medline].
- Husi H, Ward MA, Choudhary JS, Blackstock WP, Grant SG (2000) Proteomic analysis of NMDA receptor-adhesion protein signaling complexes. Nat Neurosci 3:661-669[Web of Science][Medline].
- Ideker T, Thorsson V, Ranish JA, Christmas R, Buhler J, Eng JK, Bumgarner R, Goodlett DR, Aebersold R, Hood L (2001) Integrated genomic and proteomic analyses of a systematically perturbed metabolic network. Science 292:929-934
[Abstract/Free Full Text] .- Larsen MR, Roepstorff P (2000) Mass spectrometric identification of proteins and characterization of their post-translational modifications in proteome analysis. Fresenius J Anal Chem 366:677-690[Medline].
- Levitan IB (1985) Phosphorylation of ion channels. J Membr Biol 87:177-190[Web of Science][Medline].
- Migaud M, Charlesworth P, Dempster M, Webster LC, Watabe AM, Makhinson M, He Y, Ramsay MF, Morris RG, Morrison JH, O'Dell TJ, Grant SG (1998) Enhanced long-term potentiation and impaired learning in mice with mutant postsynaptic density-95 protein. Nature 396:433-439[Medline].
- Mirnics K, Middleton FA, Marquez A, Lewis DA, Levitt P (2000) Molecular characterization of schizophrenia viewed by microarray analysis of gene expression in prefrontal cortex. Neuron 28:53-67[Web of Science][Medline].
- Mirnics K, Middleton FA, Lewis DA, Levitt P (2001) Analysis of complex brain disorders with gene expression microarrays: schizophrenia as a disease of the synapse. Trends Neurosci 24:479-486[Web of Science][Medline].
- Rigaut G, Shevchenko A, Rutz B, Wilm M, Mann M, Seraphin B (1999) A generic protein purification method for protein complex characterization and proteome exploration. Nat Biotechnol 17:1030-1032[Web of Science][Medline].
- Schwikowski B, Uetz P, Fields S (2000) A network of protein-protein interactions in yeast. Nat Biotechnol 18:1257-1261[Web of Science][Medline].
- Soifer D, Whittaker VP (1972) Morphology of subcellular fractions derived from the electric organ of Torpedo. Biochem J 128:845-846[Medline].
- Tucker CL, Gera JF, Uetz P (2001) Towards an understanding of complex protein networks. Trends Cell Biol 11:102-106[Web of Science][Medline].
- Walikonis RS, Jensen ON, Mann M, Provance Jr DW, Mercer JA, Kennedy MB (2000) Identification of proteins in the postsynaptic density fraction by mass spectrometry. J Neurosci 20:4069-4080
[Abstract/Free Full Text] .- Washburn MP, Wolters D, Yates III JR (2001) Large-scale analysis of the yeast proteome by multidimensional protein identification technology. Nat Biotechnol 19:242-247[Web of Science][Medline].
Copyright © 2001 Society for Neuroscience 0270-6474/01/21218315-04$05.00/0
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