Two-dimensional fluorescence difference gel electrophoresis for comparative proteomics profiling

Quantitative proteomics is the workhorse of the modern proteomics initiative. The gel-based and MuDPIT approaches have facilitated vital advances in the measurement of protein expression alterations in normal and disease phenotypic states. The methodological advance in two-dimensional gel electrophoresis (2DGE) has been the multiplexing fluorescent two-dimensional fluorescence difference gel electrophoresis (2D-DIGE). 2D-DIGE is based on direct labeling of lysine groups on proteins with cyanine CyDye DIGE Fluor minimal dyes before isoelectric focusing, enabling the labeling of 2-3 samples with different dyes and electrophoresis of all the samples on the same 2D gel. This capability minimizes spot pattern variability and the number of gels in an experiment while providing simple, accurate and reproducible spot matching. This protocol can be completed in 3-5 weeks depending on the sample size of the experiment and the level of expertise of the investigator.     

Two-dimensional fluorescence difference gel electrophoresis analysis of spermatogenesis in the rat

The molecular mechanisms underlying normal and pathological spermatogenesis remain poorly understood. We compared protein concentrations in different germ cell types to identify those proteins specifically or preferentially expressed at each stage of rat spermatogenesis. Crude cytosolic protein extracts and reversed-phase HPLC prefractionated cytosolic extracts from spermatogonia, pachytene spermatocytes, and early spermatids were subjected to two-dimensional difference gel electrophoresis (2-D DIGE). By comparing gels and carrying out statistical analyses, we were able to identify 1274 protein spots with relative abundances differing significantly between the three cell types. We found that 265 of these spots displaying highly differential expression (ratio > or = 2.5 between two cell types), identified by mass fingerprinting, corresponded to 123 nonredundant proteins. The proteins clustered into three clades, corresponding to mitotic, meiotic, and post-meiotic cell types. The differentially expressed proteins identified by 2-D DIGE were confirmed and validated by western blotting and immunohistochemistry, in the few cases in which antibodies were available. 2-D DIGE appears a relevant proteomics approach for studying rat germ cell differentiation, allowing the establishment of the precise expression profiles for a relatively large number of proteins during normal spermatogenesis.     

Two-dimensional agarose gel electrophoresis without gel manipulation

The apparatus and procedure to perform two-dimensional agarose gel electrophoresis without manipulating the gel used for the first electrophoresis (first-dimension gel) have been developed. The procedure is less complex, less damaging to first-dimension gels, and more precise than procedures that require manipulation of the first-dimension gel. When combined with gel-embedding techniques, the procedure presented can be used to perform the second electrophoresis in a gel different from the first-dimension gel. A first-dimension gel too dilute to be manipulated and a more concentrated gel for the second electrophoresis have been used to separate DNA open circles from a mixture of variable-length linear DNAs.     

Two-dimensional gel electrophoresis in bacterial proteomics

Two-dimensional gel electrophoresis (2-DE) is a gel-based technique widely used for analyzing the protein composition of biological samples. It is capable of resolving complex mixtures containing more than a thousand protein components into individual protein spots through the coupling of two orthogonal biophysical separation techniques: isoelectric focusing (first dimension) and polyacrylamide gel electrophoresis (second dimension). 2-DE is ideally suited for analyzing the entire expressed protein complement of a bacterial cell: its proteome. Its relative simplicity and good reproducibility have led to 2-DE being widely used for exploring proteomics within a wide range of environmental and medically-relevant bacteria. Here we give a broad overview of the basic principles and historical development of gel-based proteomics, and how this powerful approach can be applied for studying bacterial biology and physiology. We highlight specific 2-DE applications that can be used to analyze when, where and how much proteins are expressed. The links between proteomics, genomics and mass spectrometry are discussed. We explore how proteomics involving tandem mass spectrometry can be used to analyze (post-translational) protein modifications or to identify proteins of unknown origin by de novo peptide sequencing. The use of proteome fractionation techniques and non-gel-based proteomic approaches are also discussed. We highlight how the analysis of proteins secreted by bacterial cells (secretomes or exoproteomes) can be used to study infection processes or the immune response. This review is aimed at non-specialists who wish to gain a concise, comprehensive and contemporary overview of the nature and applications of bacterial proteomics.     

Two-dimensional difference gel electrophoresis (DIGE) analysis of sera from visceral leishmaniasis patients

Introduction  

Visceral leishmaniasis is a parasitic infection caused by Lesihmania donovani complex and transmitted by the bite of the phlebotomine sand fly. It is an endemic disease in many developing countries with more than 90% of the cases occurring in Bangladesh, India, Nepal, Sudan, Ethiopia and Brazil. The disease is fatal if untreated. The disease is conventionally diagnosed by demonstrating the intracellular parasite in bone marrow or splenic aspirates. This study was carried out to discover differentially expressed proteins which could be potential biomarkers.     

Two-dimensional fluorescence difference gel electrophoresis analysis of the urine proteome in human diabetic nephropathy

Urinary proteins may provide clues regarding pathogenesis of kidney disease as well as providing markers of disease activity. We employed two-dimensional differential in-gel electrophoretic analysis (2-D DIGE) to assess multiple urine samples in patients with diabetic nephropathy. Patient samples were collected as timed overnight collections. All the patients had longstanding diabetes, impaired renal function, and overt proteinuria. Control and patient urinary protein were analyzed by 2-D DIGE and DeCyder analysis. Ninety-nine spots were significantly regulated in the urine proteome of the diabetic samples, with 63 up- and 36 down-regulated. One spot corresponding to a pI 5-6 and a molecular weight between 45 and 66 kDa was consistently up-regulated by 19-fold across individuals in the diabetic group. Surface-enhanced laser desorption/ionization-time of flight analysis of in-gel tryptic digest of this spot identified this protein as alpha 1 antitrypsin (AAT). ELISA of urine samples from a separate group of patients and controls confirmed a marked increase of AAT in diabetic patients. Immunostaining of human diabetic kidneys revealed up-regulation of AAT in areas of renal fibrosis. In conclusion, we developed a method to analyze numerous urine samples from patients and allowed for detection and identification of regulated urine protein spots.     

Two-dimensional polyacrylamide gel electrophoresis of membrane proteins

Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) is one of the most powerful separation techniques for complex protein solutions. The proteins are first separated according to their isoelectric point, driven by an electric field across a pH gradient. The pH gradient necessary for the separation according to isoelectric point (pL) is usually established by electrophoresing carrier ampholytes prior to and/or concomitantly with the sample. The second dimension is usually a separation according to molecular size. Mostly this separation is performed after complete denaturation of the proteins by sodium dodecyl sulfate and 2-mercaptoethanol (SDS-PAGE). This standard method has considerable disadvantages when relatively hydrophobic membrane proteins are to be separated: cathodic drift, resulting in nonreproducible separation, and the denaturation of the protein, mostly making it impossible to detect native properties of the proteins after separation (e.g., enzymatic activity, antigenicity, intact multimers, and so on). The protocols presented here take care of most of these obstacles. However, there is probably no universal procedure that can guarantee success at first try for any mixture of membrane proteins; some experimentation will be necessary for optimization. Two procedures are each presented: a denaturing (with urea) and a nondenaturing method for IEF in immobilized pH gradient gels using Immobilines, and a denaturing (with SDS and 2-mercaptoethanol) and a nondenaturing technique (with CHAPS) for the second dimension. Essential tips and tricks are presented to keep frustrations of the newcomer at a low level.     

Comparative proteomics and difference gel electrophoresis

The goal of comparative proteomics is to analyze proteome changes in response to development, disease, or environment. This is a two-step process in which proteins within cellular extracts are first fractionated to reduce sample complexity, and then the proteins are identified by mass spectrometry. Two-dimensional electrophoresis (2DE) is the long-time standard for protein separation, but it has suffered from poor reproducibility and limited sensitivity. Difference gel electrophoresis (DIGE), in which two protein samples are separately labeled with different fluorescent dyes and then co-electrophoresed on the same 2DE gel, was developed to overcome the reproducibility and sensitivity limitations. In this essay, I discuss the principles of comparative proteomics and the development of DIGE.     

Two-dimensional gel electrophoresis in proteomics: a tutorial

Two-dimensional electrophoresis of proteins has preceded, and accompanied, the birth of proteomics. Although it is no longer the only experimental scheme used in modern proteomics, it still has distinct features and advantages. The purpose of this tutorial paper is to guide the reader through the history of the field, then through the main steps of the process, from sample preparation to in-gel detection of proteins, commenting the constraints and caveats of the technique. Then the limitations and positive features of two-dimensional electrophoresis are discussed (e.g. its unique ability to separate complete proteins and its easy interfacing with immunoblotting techniques), so that the optimal type of applications of this technique in current and future proteomics can be perceived. This is illustrated by a detailed example taken from the literature and commented in detail. This Tutorial is part of the International Proteomics Tutorial Programme (IPTP 2).     

Two-dimensional gel electrophoresis of wool intermediate filament proteins

Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) methods have been used to provide high-resolution separation of wool intermediate filament proteins (IFPs). An improved method of extraction was developed based on a previously published method. The improved method for extraction eliminates the use of dialysis and freeze-drying between the extraction and rehydration steps, allowing the extraction and rehydration for the first dimension gel to be achieved in one day. Improvements to the method for maintaining reducing conditions and chaotrope constitution, combined with low %T polyacrylamide gels, allowed the high-resolution separation of the two keratin IFP families and their individual family members. The IFPs were separated to produce a clearly defined spot pattern of higher intensity, with numerous minor spots not previously observed, and a marked improvement in the vertical resolution. Further work to analyse the composition of each of the protein spots has been made much easier by being able to separate the IFPs into discrete spots.     

Two-dimensional gel electrophoresis of neurosecretory polypeptides in crustacean eyestalk

Summary A knowledge of the precise location of neurosecretory cell bodies is a prerequisite for studying the synthesis and subsequent processing of neurosecretory polypeptides stored in axon terminals comprising the sinus gland of the crustacean eyestalk. Structural data establish that the X organ in the medulla terminalis ganglion (mtXo) of the crayfish eyestalk represents 90–95% of the cell bodies actively synthesizing neurosecretory vesicles stored in the neurohemal sinus gland (Fig. 4). These cell bodies transport rather than accumulate neurosecretory vesicles as judged by light and electron microscopy suggesting that neurohormone precursors, but not subsequently stored products, might be found there. Two-dimensional electrophoresis of sinus gland and mtXo homogenates support this hypothesis. In crayfish, lobster and blue crab, stained two-dimensional gels display a number of sinus gland-specific polypeptides whose high concentrations and low molecular weights are consistent with stored neurosecretory material (Table 1). These neuropeptides are not detected in mtXo homogenates or in non-neurosecretory neural tissue with Coomassie Blue staining. By decreasing the porosity of the second dimension, the two-dimensional gel technique has proven useful in determining the molecular weights of a variety of neurosecretory polypeptides stored in the sinus gland. The crayfish and lobster store several polypeptides of ca. 7,000 Dalton. The blue crab stores two 7,000, two 13,000 and three 20,000 Dalton sinus gland polypeptides detected in stained gels.Following a 4 h incubation in³H-labelled amino acids, predominantly labelled 19,000–21,000 Dalton polypeptides are detected in crayfish mtXo homogenates by 2-D gel autoradiography (Fig. 12). Concomitantly, three labelled polypeptides (4,000–10,000 Dalton) appear in the sinus gland (Fig. 13), suggesting that they are cleaved from 19,000–21,000 Dalton molecules. This study is the first to examine neurosecretory precursors and their putative cleavage products in the Crustacea.Abbreviations mtXo medulla terminalis X organ - NEPHGE non-equilibrium pH gradient electrophoresis - PAF paraldehyde fuchsin - SDS sodium dodecylsulfate     

Two-dimensional SDS-polyacrylamide gel electrophoresis of heat-modifiable outer-membrane proteins.

An examination has been made of the effect which temperature of solubilization has upon the subsequent migration in SDS-polyacrylamide gel electrophoresis of proteins from the cell envelopes of Escherichia coli K12 and Neisseria sicca ATCC 9913. Conventional electrophoresis in tubes revealed substantial differences in the staining patterns of gels, depending upon whether the envelope samples were solubilized at 37 degrees C or 100 degrees C; in the case of N. sicca at least 6 of 13 discernible bands displayed heat-modifiable behavior. The relationship of the bands produced by each of the two temperatures was investigated by a two-dimensional electrophoresis procedure, in which a sample was solubilized at 37 degrees C and run in a usual cylindrical gel; the entire gel was then resolubilized at 100 degrees C, and laid along an acrylamide slab for electrophoresis in the second dimension. It was found that "free endotoxin" of both organisms examined contained the same major proteins as the total envelope fraction, and that these free endotoxin proteins showed the same heat-modifiable properties as when present in total envelopes.     

Practical syntheses of dyes for difference gel electrophoresis

The three dyes (two indocyanine and one benzoxazolium) useful in difference gel electrophoresis-methyl Cy5 1, propyl Cy3 2, and the benzoxazolium dye Cy2 3--and their NHS esters have been prepared by efficient routes in good overall yield from inexpensive precursors.     

2D or not 2D. Two-dimensional gel electrophoresis

2D gel electrophoresis is the technology that everyone loves to hate-it requires manual dexterity and precision to reproduce precisely and is thus not well-suited as a high-throughput technology. Although almost everyone would like to replace it, the resolution and sensitivity it offers are exquisite and unsurpassed if one wants a global view of cellular activity. There have been several recent developments, for example, the detection of low abundance proteins, and the resolution possible with narrow-range IPG gels.     

Two-dimensional fluorescence difference gel electrophoretic analysis of Streptococcus mutans biofilms

Compared with traditional two-dimensional (2D) proteome analysis of Streptococcus mutans grown as a biofilm from a planktonic culture at steady state (Rathsam et al., Microbiol. 2005, 151, 1823-1837), the use of 2D fluorescence difference gel electrophoresis (DIGE) led to a 3-fold increase in the number of identified protein spots that were significantly altered in their level of expression (P < 0.050). Of the 73 identified proteins, only nine were up-regulated in biofilm grown cells. The results supported the previously surmised hypothesis that general metabolic functions were down-regulated in response to a reduction in growth rate in mature S. mutans biofilms. Up-regulation of competence proteins without any concomitant increase in stress-responsive proteins was confirmed, while the levels of glucosyltransferase C (GtfC), involved in glucan formation, O-acetylserine sulfhyrylase (cysteine synthetase A; CsyK), implicated in the formation of [Fe-S] clusters, and a hypothetical protein encoded by the open reading frame, SMu0188, were also up-regulated.     

Two-dimensional gel systems for rapid histone analysis for use in minislab polyacrylamide gel electrophoresis

Two two-dimensional polyacrylamide minislab gel systems were devised for the rapid analysis of histone modified species and variants. The first system consisted of an acetic acid-urea or acetic acid-urea-Triton X-100 minislab gel for the first-dimension electrophoresis followed by a polyacrylamide-sodium dodecyl sulfate minislab gel for the second-dimension electrophoresis. The second system consisted of a polyacrylamide-sodium dodecyl sulfate minislab gel for the first-dimension electrophoresis followed by either an acetic acid-urea or an acetic acid-urea-Triton X-100 minislab gel for second-dimension electrophoresis. Both systems offer distinct advantages for rapid high-resolution analysis of modified histone species and variants.     

Two-dimensional gel electrophoresis of proteins as a tool in wheat genetics

In this minireview are reported several genetic investigations undertaken on wheat with the use of two-dimensional gel electrophoresis of total proteins extracted mainly from etiolated seedlings or from green leaves. Differences between developmental stages or organs of one genotype and nuclear and cytoplasmic genetic variations between genotypes are revealed by this method. We have also localized on the chromosomes structural genes coding for the proteins revealed and assigned their subcellular location to many polypeptides. We obtained new information concerning the regulation of protein amounts as well as the phylogenetic and homeology relationships between the A, B and D genomes.     

Two-dimensional polyacrylamide gel electrophoresis: an improved method for ribosomal proteins

A two-dimensional electrophoresis system for analysis of ribosomal proteins with several advantages over previous systems is described. The general features of this system are: (1) first-dimension separation on the basis of mobility at pH 5.0 in 8 m urea and 4% polyacrylamide; (2) second-dimension separation on the basis of molecular weight using dodecyl sulfate detergent; (3) rapid electrophoretic shift between first- and second-dimension separation conditions; (4) high resolution separation can be obtained on 10-cm² slabs with proteins from approximately 100 μg of ribosomal subunits; (5) capacity for handling up to 10 samples at a time, with electrophoresis complete within about 10 hr; and (6) the apparatus is relatively simple and inexpensive to construct and use.