Transfer of SDS-proteins from gel electrophoretic zones into mass spectrometry, using electroelution of the band into buffer without sectioning of the gel

Five SDS-proteins, ranging in molecular weight from 14 to 66 kDa, were detected without covalent fluorescent labeling by the automated gel electrophoresis apparatus with intermittent fluorescence scanning (HPGE apparatus, LabIntelligence) during electrophoresis in barbiturate buffer in the presence of Cascade Blue. The SDS-proteins were electroeluted from the gel into 220 microl of buffer by a modification of the procedure of Gombocz and Cortez. The electroeluate was freed of SDS, ultrafiltered and subjected to MALDI-TOF mass spectrometry. The masses of the five native proteins were found to be maintained after electrophoresis and electroelution in the presence of the potential contaminants SDS, barbituric acid and Cascade Blue. The procedure of protein transfer from SDS-PAGE into mass spectrometry, without excision of bands, gel maceration and protein recovery by diffusion, therefore is shown to be suitable for the identification by mass of intact proteins derived from gel electrophoretic bands.     

A simple monolithic column electroelution for protein recovery from gel electrophoresis

Protein recovery from gel electrophoresis plays an important role in functional genomics and proteomics but faces a series of issues (e.g., complex procedure, low recovery, long experimental time). In this study, a monolithic column electroelution (MCE) was developed for protein recovery from gel electrophoresis. With the model proteins of bovine serum albumin (BSA), hemoglobin (Hb), and myoglobin (Mb), the developed device and method were compared with common electroelution procedures in agarose gel electrophoresis (AGE). The comparative experiments revealed that (i) the protein recovery achieved with the developed device was greater than 83%, much higher than the 41% to 50% achieved with the common devices; (ii) the running time to obtain 70% recovery was approximately 15min, evidently shorter than the 240min with the common devices; and (iii) the device and procedure were simple and less time-consuming as compared with those of the common devices. It was observed that the serum protein bands cut from polyacrylamide gel electrophoresis could be transferred into solution in 15 to 30min with 82% yield. The device, along with its relevant procedure, has potential use in protein extraction and proteomics as well as in DNA studies.     

Separation and purification of small quantitites of specific RNA species by polyacrylamide gel electrophoresis using prestained RNAs as markers.

A method is described for the separation and purification of different molecular species of RNA in microquantities using polyacrylamide gel electrophoresis. The experimental procedure consists of the following steps; (i) partial prestaining of RNA with methylene blue at a concentration of the dye which would not affect the electrophoretic migration of the RNA bands, but which would permit visual observation of the migrating bands during electrophoresis; (ii) use of short columns just sufficient to achieve separation of each species of RNA as a single compact band rather than a series of bands; (iii) trapping of each of the eluting RNA species from the gel on DEAE-cellulose dises in sequential order; and (iv) elution of the RNAs from the DEAE-discs by extraction with triethylammonium bicarbonate and recovery of the corresponding RNAs by lyophylization.     

Purification, amino terminal analysis, and peptide mapping of proteins after in situ postelectrophoretic fluorescent labeling

Proteins fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis were stained in situ with either 5-(dimethylamino)-1-naphthalene sulfonyl chloride (dansyl chloride) or fluorescein isothiocyanate. This staining procedure can be carried out in less than 30 min without previous fixation of the proteins. It is not dependent on such factors as charge or molecular weight of the proteins and can detect 50 ng of protein in a 10-mm-wide gel slot. Fluorescent staining with dansyl chloride was used to localize proteins after electrophoresis for subsequent electroelution, amino terminal analysis, and peptide mapping. The electroelution can be carried out in less than 3 h with yields approaching 100%. The staining of only one strip of a preparative gel allowed the electroelution of proteins without covalent modification. For amino terminal analysis, identical results were obtained when the hydrolysis step was carried out after electroelution or directly in the gel pieces. The peptide mapping can be carried out with the proteins in solution (after electroelution) or directly in the gel pieces. The amino terminal and peptide mapping analysis of each protein in a mixture can be completed within 30 h from the beginning of the electrophoretic fractionation. The method appears to be applicable to a wide range of proteins showing very different biochemical properties.     

Manual N-terminal microsequencing of proteins electroeluted from polyacrylamide gel slices

A simple and rapid procedure for preparation of proteins for manual microsequencing using sodium dodecyl sulfate gel electrophoresis is described. The procedure involves pre-electrophoretic labeling of the protein amino groups with a coloured Edman reagent, disk electrophoresis for purification or fractionation of the proteins, and reversed electrophoretic transfer of the separated protein from gel slices into a small volume of buffer (100 to 150 microliter) using a discontinuous conductivity gradient to recover the proteins. The pre-electrophoretic labeling facilitates location of the separated proteins in the gel and the monitoring of their complete electroelution. The isolated proteins are separated from excess of salts by acetone precipitation and solvent partitioning in pyridine/water (1:1) and subjected to manual DABITC/PITC degradation.     

Phosphorylation polymorphism in the yolk protein 2 of Drosophila hawaiiensis

An intraspecific polymorphism in the electrophoretic migration pattern of the yolk proteins in D. hawaiiensis was established and characterized. The polymorphism includes yolk protein migration patterns of two, three, or four bands by polyacrylamide gel electrophoresis. Peptide mapping analysis demonstrates that in the two band migration pattern YP2 comigrates with YP3, whereas in the three and four band migration patterns YP2 migrates between YP1 and YP3 in addition to comigrating with YP3. It further demonstrates that the top two bands of the four band migration pattern consists of YP1. Phosphatase treatment of the yolk proteins establishes that the different electrophoretic migration patterns of YP2 are caused by different degrees of phosphorylation. It is suggested that the YP1 polymorphism is caused by a yp1 gene modification and that the YP2 polymorphism is caused by two different post-translational processing paths.     

Reevaluation of the electrophoretic migration behavior of soluble globular proteins in the native and detergent-denatured states in polyacrylamide gels

Although sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis is widely used for estimating molecular masses of proteins, considerable uncertainty still exists both about the structure of SDS-protein complexes and about their mechanism of electrophoretic migration. In this study, soluble globular proteins, with masses of 14-200 kDa, were heat-denatured in the presence of SDS and their relative total molecular volume and net charge were estimated from Ferguson plots of electrophoretic mobility vs acrylamide concentration. Native globular protein served as standards for overall molecular size and effective radii. Results revealed at least two independent electrophoretic migration mechanisms for the SDS-protein complexes: (i) for proteins in the 14-65 kDa range at <15% acrylamide, linear Ferguson plots suggested that they migrated ideally and that their effective radii could be estimated in this manner: (ii) concave plots at higher gel concentrations, and for complexes derived from larger proteins, indicated that migration in these cases could be described by reptation theory. Migration of the large proteins at lower gel concentrations and small proteins at higher gel concentrations was not well described by either theory, representing intermediate behavior not described by these mechanisms. These data support models in which all but the smallest SDS-protein complexes adopt a necklace-like structure in which spherical micelles are distributed along the unfolded polypeptide chain. Possible relations to recent alternative models of gel electrophoresis are also discussed.     

Visible fluorescent detection of proteins in polyacrylamide gels without staining

2,2,2-Trichloroethanol (TCE) incorporated into polyacrylamide gels before polymerization provides fluorescent visible detection of proteins in less than 5min of total processing time. The tryptophans in proteins undergo an ultraviolet light-induced reaction with trihalocompounds to produce fluorescence in the visible range so that the protein bands can be visualized on a 300-nm transilluminator. In a previous study trichloroacetic acid or chloroform was used to stain polyacrylamide gel electrophoresis (PAGE) gels for protein visualization. This study shows that placing TCE in the gel before electrophoresis can eliminate the staining step. The gel is removed from the electrophoresis apparatus and placed on a transilluminator and then the protein bands develop their fluorescence in less than 5min. In addition to being rapid this visualization method provides detection of 0.2microg of typical globular proteins, which for some proteins is slightly more sensitive than the standard Coomassie brilliant blue (CBB) method. Integral membrane proteins, which do not stain well with CBB, are visualized well with the TCE in-gel method. After TCE in-gel visualization the same gel can then be CBB stained, allowing for complementary detection of proteins. In addition, visualization with TCE in the gel is compatible with two-dimensional PAGE, native PAGE, Western blotting, and autoradiography.     

Mass spectrometric mapping of ion channel proteins (porins) and identification of their supramolecular membrane assembly

Mass spectrometric peptide mapping, particularly by matrix-assisted laser desorption-ionization (MALDI-MS), has recently been shown to be an efficient tool for the primary structure characterization of proteins. In combination with in situ proteolytic digestion of proteins separated by one- and two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), mass spectrometric peptide mapping permits identification of proteins from complex mixtures such as cell lysates. In this study we have investigated several ion channel membrane proteins (porins) and their supramolecular assembly in mitochondrial membranes by peptide mapping in solution and upon digestion in the gel matrix. Porins are integral membrane proteins serving as nonspecific diffusion pores or as specific systems for the transport of substrates through bacterial and mitochondrial membranes. The well-characterized porin from Rhodobacter capsulatus (R.c.-porin) has been found to be a native trimeric complex by the crystal structure and was used as a model system in this study. R.c.-porin was characterized by MALDI-MS peptide mapping in solution, and by direct in situ-gel digestion of the trimer. Furthermore, in this study we demonstrate the direct identification of the noncovalent complex between a mitochondrial porin and the adenine nucleotide translocator from rat liver, by MALDI-MS determination of the specific peptides due to both protein sequences in the SDS-PAGE gel band. The combination of native gel electrophoresis and mass spectrometric peptide mapping of the specific gel bands should be developed as a powerful tool for the molecular identification of protein interactions. Proteins Suppl. 2:63–73, 1998. © 1998 Wiley-Liss, Inc.     

Purification of phospholipase D from citrus callus tissue

Phospholipase D in extracts of soluble proteins from callus cultures derived from cotyledons of Citrus sinensis (L.) Osbeck is activated by Ca2+ and anionic detergents and has a pH optimum of 6.5. The enzyme was purified 703-fold over the crude protein extract with a yield of 15% by ammonium sulfate precipitation, ion exchange chromatography, gel filtration, hydrophobic interaction chromatography, and preparative acrylamide gel electrophoresis. Preparative electrophoresis was carried out using conventional slab gel equipment and electroelution of the sliced gel. Analytical sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the purified phospholipase revealed two bands of the same staining intensity running at 94.2K and 90.5K.     

Abnormal SDS-PAGE migration of cytosolic proteins can identify domains and mechanisms that control surfactant binding

The amino acid substitution or post-translational modification of a cytosolic protein can cause unpredictable changes to its electrophoretic mobility during SDS-PAGE. This type of "gel shifting" has perplexed biochemists and biologists for decades. We identify a mechanism for "gel shifting" that predominates among a set of ALS (amyotrophic lateral sclerosis) mutant hSOD1 (superoxide dismutase) proteins, post-translationally modified hSOD1 proteins, and homologous SOD1 proteins from different organisms. By first comparing how 39 amino acid substitutions throughout hSOD1 affected SDS-PAGE migration, we found that substitutions that caused gel shifting occurred within a single polyacidic domain (residues ~80-101), and were nonisoelectric. Substitutions that decreased the net negative charge of domain 80-101 increased migration; only one substitution increased net negative charge and slowed migration. Capillary electrophoresis, circular dichroism, and size exclusion chromatography demonstrated that amino acid substitutions increase migration during SDS-PAGE by promoting the binding of three to four additional SDS molecules, without significantly altering the secondary structure or Stokes radius of hSOD1-SDS complexes. The high negative charge of domain 80-101 is required for SOD1 gel shifting: neutralizing the polyacidic domain (via chimeric mouse-human SOD1 fusion proteins) inhibited amino acid substitutions from causing gel shifting. These results demonstrate that the pattern of gel shifting for mutant cytosolic proteins can be used to: (i) identify domains in the primary structure that control interactions between denatured cytosolic proteins and SDS and (ii) identify a predominant chemical mechanism for the interaction (e.g., hydrophobic vs. electrostatic).     

Two-dimensional electrophoresis for the isolation of integral membrane proteins and mass spectrometric identification

Acrylamide concentration, urea content, and the trailing ion used for sodium dodecyl sulfate (SDS)-gels modify electrophoretic protein mobilities in a protein-dependent way. Varying these parameters we coupled two SDS-gels to a two-dimensional (2-D) electrophoresis system. Protein spots in 2-D gels are dispersed around a diagonal. Hydrophobic proteins are well separated from water-soluble proteins which is the essential advantage of the novel technique. Mass spectrometric identification of previously unaccessible hydrophobic proteins is now possible.     

High-resolution Native-PAGE for membrane proteins capable of fluorescence detection and hydrodynamic state evaluation

An improved native polyacrylamide gel electrophoresis (PAGE) method capable of evaluating the hydrodynamic states of membrane proteins and allowing in-gel fluorescence detection was established. In this method, bis(alkyl) sulfosuccinate is used to provide negative charges for detergent-solubilized membrane proteins to facilitate proper electrophoretic migration without disturbing their native hydrodynamic states. The method achieved high-resolution electrophoretic separation, in good agreement with the elution profiles obtained by size exclusion chromatography. The applicability of in-gel fluorescence detection for tagged green fluorescent protein (GFP) facilitates the analysis of samples without any purification. This method might serve as a general analytical technique for assessing the folding, oligomerization, and protein complex formation of membrane proteins.     

Application of sensitive fluorescent dyes in linkage of laser microdissection and two-dimensional gel electrophoresis as a cancer proteomic study tool

The combination of laser microdissection and two-dimensional gel electrophoresis (2-D PAGE) has been developed to perform proteomic analysis on specific populations of cells in cancer tissues. However, as conventional low sensitivity silver staining was used for spot detection, the microdissection required to obtain an adequate amount of protein for 2-D PAGE is laborious and only a restricted number of protein spots could be visualized. As a consequence, this technology was impractical for direct clinical applications and had a limited impact on cancer studies. To solve these problems, we developed an application in which fluorescent dyes label the proteins extracted from microdissected tissues prior to 2-D PAGE separation. In this application, a small amount of protein, less than 6.6 microg, was enough to generate a 2-D profile with approximately 1500 protein spots. This technique was applied to compare the proteome of normal intestinal epithelium with that of adenoma in Min mice. Thirty-seven protein spots reproducibly showed significant differences in intensities. Mass spectrometric analysis and Western blotting identified eight of them, including prohibitin, 14-3-3zeta, tropomyosin 3 and Hsp84. These results indicate that fluorescence labeling of proteins from microdissected tissues prior to 2-D PAGE is a powerful cancer proteomic study tool.     

Fast electrotransfer of human serum proteins in their native state from polyacrylamide thin gradient gels reinforced by textiles to polyvinylidene difluoride membranes. Rapid electrotransfer from thin gradient gels reinforced by textiles.

A fast electroblotting technique of native molecules electrophoretically separated in thin (0.25 to 0.5 mm) gradient gels, onto a high capacity membrane of polyvinylidene difluoride is described. Omitting methanol during transfer, the equilibration step is avoided and the same buffer is used in electrophoresis and transfer. As the gel reinforced by fabric never swells nor shrinks, and as all the bands are blotted, the transfer matrix exactly reflects the protein pattern of the original gel. Autoradiography is enhanced and electroelution is homogeneous in all parts of the gels. Significant improvement is noticed in binding proteins of molecular weight from about 20 kDa to more than 700 kDa, as suggested by complete electroelution of all native serum components.     

Continuous free-flow electrophoresis separation of cytosolic proteins from the human colon carcinoma cell line LIM 1215: a non two-dimensional gel electrophoresis-based proteome analysis strategy

The conventional approach for analyzing the protein complement of a genome involves the combination of two-dimensional gel electrophoresis (2-DE) and mass spectrometric based protein identification technologies. While 2-DE is a powerful separation technique, it is severely limited by the insolubility of certain classes of proteins (e.g. hydrophobic membrane proteins), as well as the amount of protein that can be processed. Here, we describe a simple procedure for resolving complex mixtures of proteins that involves a combination of free flow electrophoresis (FFE), a liquid-based isoelectric focussing (IEF) method, and sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Resolved proteins were identified by peptide fragment sequencing using capillary column reversed-phase high performance liquid chromatography (RP-HPLC)/mass spectrometry (MS). An initial demonstration of the method was performed using digitonin/ethylenediaminetetraacetic acid EDTA extracted cytosolic proteins from the human colon carcinoma cell line, LIM 1215. Cytosolic proteins were separated by liquid-based IEF (pH range 3-10) into 96 fractions, and each FFE fraction was further fractionated by SDS-PAGE. Selected protein bands were excised from the SDS-PAGE gel, digested in situ with trypsin, and subsequently identified by on-line RP-HPLC/electrospray-ionization ion trap MS. Our results indicate that FFE is: (i) an extremely powerful liquid-based IEF method for resolving proteins; (ii) not limited by the amount of sample that can be loaded onto the instrument; and (iii) capable of fractionating intact protein complexes (a potentially powerful tool for cell-mapping proteomics). An up-to-date list of cytosolic proteins from the human colorectal carcinoma cell line LIM 1215 can be found in the Joint Protein Structure Laboratory (JPSL) proteome database. This information will provide an invaluable resource for future proteomics-based biological studies of colon cancer. The JPSL proteome database can be accessed through the World Wide Web (WWW) network (http://www.ludwig.edu.au/jpsl/jpslhome.html).     

Depletion of hemoglobin and carbonic anhydrase from erythrocyte cytosolic samples by preparative clear native electrophoresis

Proteomic analysis of red cells is compromised by the presence of high-abundance proteins (hemoglobin and carbonic anhydrase-1), which completely obscure low-abundance species. The depletion method presented here involves performing native gel electrophoresis in a polyacrylamide gel tube using a modified electroelution cell. The electrophoretic run is interrupted intermittently to allow the recovery of at least three different liquid fractions, which can be analyzed by both native PAGE and 2D isoelectric focusing SDS-PAGE, or by shotgun mass spectrometry analysis after trypsin in-solution protein digestion. This low-cost, reproducible technique can be used to process large amounts of sample, and it increases the likelihood of detecting low-abundance proteins, thereby resulting in greater proteome coverage. The separation procedure takes approximately 6-7 h.     

Purification of rabbit and human serum paraoxonase.

Rabbit serum paraoxonase/arylesterase has been purified to homogeneity by Cibacron Blue-agarose chromatography, gel filtration, DEAE-Trisacryl M chromatography, and preparative SDS gel electrophoresis. Renaturation (Copeland et al., 1982) and activity staining of the enzyme resolved by SDS gel electrophoresis allowed for identification and purification of paraoxonase. Two bands of active enzyme were purified by this procedure (35,000 and 38,000). Enzyme electroeluted from the preparative gels was reanalyzed by analytical SDS gel electrophoresis, and two higher molecular weight bands (43,000 and 48,000) were observed in addition to the original bands. This suggested that repeat electrophoresis resulted in an unfolding or other modification and slower migration of some of the purified protein. The lower mobility bands stained weakly for paraoxonase activity in preparative gels. Bands of each molecular weight species were electroblotted onto PVDF membranes and sequenced. The gas-phase sequence analysis showed that both the active bands and apparent molecular weight bands had identical amino-terminal sequences. Amino acid analysis of the four electrophoretic components from PVDF membranes also indicated compositional similarity. The amino-terminal sequences are typical of the leader sequences of secreted proteins. Human serum paraoxonase was purified by a similar procedure, and ten residues of the amino terminus were sequenced by gas-phase procedures. One amino acid difference between the first ten residues of human and rabbit was observed.     

Fractionation of individual, biologically active factor VIII multimers

We have designed an electrophoretic system for the fractionation of individual, biologically active multimers of factor VIII. Human factor VIII, purified by gel filtration on Sepharose CL-2B from plasma cryoprecipitate, was submitted to electrophoresis without SDS on 2.0% polyacrylamide gels in 0.04 M Tris/0.06 M Tes buffer, pH 7.5. Staining with Coomassie blue revealed a series of protein bands. Measurement of electrophoretic mobility showed constant size intervals between adjacent bands. Electrophoresis in a second dimension, in the presence of SDS, resulted in an identical order of mobilities, suggesting that the different migration rates of factor VIII proteins in the first electrophoretic system were size- and not charge-dependent. After electrophoresis in the absence of SDS both factor VIII coagulant and ristocetin cofactor activities as well as factor VIII-related antigen were recovered by elution from gel slices. The distribution of activity peaks resembled that of Coomassie-stained factor VIII proteins found in control gels. We thus demonstrate that an electrophoretic fractionation of factor VIII multimers is possible even at neutral pH where factor VIII activities are retained.     

High resolution mass spectrometric alveolar proteomics: identification of surfactant protein SP-A and SP-D modifications in proteinosis and cystic fibrosis patients

In the present study, one- and two-dimensional gel electrophoresis combined with high resolution Fourier transform-ion cyclotron resonance mass spectrometry (FT-ICR MS) have been applied as powerful approaches for the proteome analysis of surfactant proteins SP-A and SP-D, including identification of structurally modified and truncation forms, in bronchoalveolar lavage fluid from patients with cystic fibrosis, chronic bronchitis and pulmonary alveolar proteinosis. Highly sensitive micropreparation techniques were developed for matrix-assisted laser desorption/ionization (MALDI) FT-ICR MS analysis which provided the identification of surfactant proteins at very low levels. Owing to the high resolution, FT-ICR MS was found to provide substantial advantages for the structural identification of surfactant proteins from complex biological matrices with high mass determination accuracy. Several protein bands corresponding to SP-A and SP-D were identified by MALDI-FT-ICR MS after electrophoretic separation by one- and two-dimensional gel electrophoresis, and provided the identification of structural modifications (hydroxy-proline) and degradation products. The high resolution mass spectrometric proteome analysis should facilitate the unequivocal identification of subunits, aggregations, modifications and degradation products of surfactant proteins and hence contribute to the understanding of the mechanistic basis of lung disease pathogenesis.