Linking Mass Spectrometry and Slab-Polyacrylamide Gel Electrophoresis by Passive Elution of Lipopolysaccharides from Reverse-Stained Gels: Analysis of Gel-Purified Lipopolysaccharides from Haemophilus influenzae Strain Rd

Revisit of Imidazole-Zinc Reverse Stain for Protein Polyacrylamide Gel Electrophoresis

Imidazole-zinc reverse stain (ZN stain) is known for high sensitivity, ease of use, and cost-effective feature. ZN stain is compatible to many experiments of which those are proteomics-related in particular. Here, we describe the ZN staining procedures and the subsequent procedures incorporated in detail, along with the improvements of setup in aspects of visualization and documentation for postprocessing ZN stained gel images.

Structural characterization of bacterial lipopolysaccharides with mass spectrometry and on- and off-line separation techniques

The focus of this review is the application of mass spectrometry to the structural characterization of bacterial lipopolysaccharides (LPSs), also referred to as "endotoxins," because they elicit the strong immune response in infected organisms. Recently, a wide variety of MS-based applications have been implemented to the structure elucidation of LPS. Methodological improvements, as well as on- and off-line separation procedures, proved the versatility of mass spectrometry to study complex LPS mixtures. Special attention is given in the review to the tandem mass spectrometric methods and protocols for the analyses of lipid A, the endotoxic principle of LPS. We compare and evaluate the different ionization techniques (MALDI, ESI) in view of their use in intact R- and S-type LPS and lipid A studies. Methods for sample preparation of LPS prior to mass spectrometric analysis are also described. The direct identification of intrinsic heterogeneities of most intact LPS and lipid A preparations is a particular challenge, for which separation techniques (e.g., TLC, slab-PAGE, CE, GC, HPLC) combined with mass spectrometry are often necessary. A brief summary of these combined methodologies to profile LPS molecular species is provided.

Intact rough- and smooth-form lipopolysaccharides from Escherichia coli separated by preparative gel electrophoresis exhibit differential biologic activity in human macrophages

We established a new preparative separation procedure, based on DOC/PAGE, to isolate intact lipopolysaccharide (LPS) fractions from natural LPS preparations of Escherichia coli. Analysis of the chemical integrity of LPS fractions by MS showed that no significant chemical modifications were introduced by the procedure. Contamination with toll-like receptor 2 (TLR2)-reactive cell-wall components present in the natural LPS mixture was effectively removed by the procedure, as determined by the absence of reactivity of the purified fractions in a HEK293-TLR2 cell line. Biologic analysis of LPS fractions derived from E. coli O111 in human macrophages demonstrated that the rough (R), semirough (SR) and smooth (S) LPS fractions were highly active at inducing tumor necrosis factor-alpha (TNF-α) in the presence of human serum; however, on a weight basis the R-LPS and SR-LPS fractions were more active, by a factor of 10-100, than was the S-LPS fraction. Under serum-free conditions, the natural LPS mixture, as well as the R-LPS and SR-LPS fractions, showed dose-dependent activation of macrophages, although the response was attenuated by about 10- to 100-fold. In contrast, the S-LPS fraction failed to induce TNF-α. Remarkably, the dose-response of the natural LPS mixture resembled that of the R-LPS and SR-LPS fractions, supporting that short-chain (R and SR) forms of LPS dominate the innate immune response of human macrophages to LPS in vitro. Biologic activity to the S-LPS fraction under serum-free conditions could be restored by the addition of recombinant lipopolysaccharide-binding protein (LBP). In contrast, soluble cluster of differentiation antigen 14 was not able to confer activity of the S-LPS fraction, indicating a crucial role of LBP in the recognition of S-LPS by human macrophages.

Nanoaggregates of micropurified lipopolysaccharide identified using dynamic light scattering, zeta potential measurement, and TLR4 signaling activity

Nanoaggregates composed of selected glycoforms from Escherichia coli 055:B5 lipopolysaccharide (LPS) were prepared by combining sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, zinc-imidazole reverse staining, zinc chelation after cutting gel slices, elution with either 0.5% triethylamine (TEA) or 0.4% to 0.5% surfactant (SDS or deoxycholate [DOC]) from extrusion-generated gel microparticles, and centrifugal diafiltration after appropriate surfactant dilution. Dynamic light scattering allows detecting these aggregates, giving a size distribution from 10 to 100nm in diameter. The formation of the aggregates prepared with selected DOC-eluted LPS glycoforms was notably improved over those prepared with TEA-eluted glycoforms. As the O-side chain length increased in the composition of the former aggregates, there was a gradual decrease in the electrophoretic mobility (from -1.2 to 0.0110(-8)m(2)/Vs), giving a calculated zeta potential from -15 to 0.1mV at pH6.8. These aggregates were further characterized for their abilities to elicit agonistic effects on human Toll-like receptor 4, as shown by in vitro activation of nuclear factor kappa light chain enhancer of activated B cells (NF-κB) in engineered HEK293 cells.

Revisit of imidazole-zinc reverse stain for protein polyacrylamide gel electrophoresis

Imidazole-zinc reverse stain (ZN stain) is known for its high sensitivity, ease of use, and cost-effective feature. ZN stain is compatible to many experiments of which those are proteomics-related in particular. Here, we describe the ZN staining procedures and the subsequent procedures incorporated in detail, along with the improvements of setup in aspects of visualization and documentation for post-processing ZN-stained gel images.

Isolation of smooth-type lipopolysaccharides to electrophoretic homogeneity

Polyacrylamide slab gel electrophoresis in the presence of sodium dodecyl sulfate or sodium deoxycholate (SDS- or DOC-slab-PAGE) is a powerful technique for the separation of smooth(S)-type bacterial lipopolysaccharides (LPS). In order to recover the individual LPS species from the polyacrylamide gel for subsequent analyses, a sensitive, nondestructive reverse staining of slab-PAGE-separated LPS has been developed. The individual reverse-stained LPS bands can be rapidly and efficiently recovered into an aqueous 5% triethylamine solution when they are extruded to produce fine gel microparticles. Based on these principles, an isolation methodology that combines preparative slab-PAGE, reverse staining, extrusion, and passive elution can be used to isolate, to electrophoretic homogeneity, micrograms to hundreds of micrograms of individual LPS species successfully from smooth-type LPS mixtures.

Genes required for the synthesis of heptose-containing oligosaccharide outer core extensions in Haemophilus influenzae lipopolysaccharide

Heptose-containing oligosaccharides (OSs) are found in the outer core of the lipopolysaccharide (LPS) of a subset of non-typable Haemophilus influenzae (NTHi) strains. Candidate genes for the addition of either l-glycero-d-manno-heptose (ld-Hep) or d-glycero-d-manno-heptose (dd-Hep) and subsequent hexose sugars to these OSs have been identified from the recently completed genome sequences available for NTHi strains. losA1/losB1 and losA2/losB2 are two sets of related genes in which losA has homology to genes encoding glycosyltransferases and losB to genes encoding heptosyltransferases. Each set of genes is variably present across NTHi strains and is located in a region of the genome with an alternative gene organization between strains that contributes to LPS heterogeneity. Dependent upon the strain background, the LPS phenotype, structure and serum resistance of strains mutated in these genes were altered when compared with the relevant parent strain. Our studies confirm that losB1 and losB2 usually encode dd-heptosyl- and ld-heptosyl transferases, respectively, and that losA1 and losA2 encode glycosyltransferases that play a role in OS extensions of NTHi LPS.

Profiling LPS glycoforms of non-typeable Haemophilus influenzae by multiple-stage tandem mass spectrometry

Non-typeable (acapsular) Haemophilus influenzae (NTHi) is a major cause of otitis media accounting for 25-30% of all cases of the disease. Lipopolysaccharide (LPS) is an essential and exposed component of the H. influenzae cell wall. A characteristic feature of H. influenzae LPS is the extensive inter-strain and intra-strain heterogeneity of glycoform structure which is key to the role of the molecule in both commensal and disease-causing behavior of the bacterium. However, to characterize LPS structure unambiguously is a major challenge due to the extreme heterogeneity of glycoforms that certain strains express. A powerful tool for obtaining sequence and branching information is multiple-stage tandem ESI-MS (ESI-MS( n )) performed on dephosphorylated and permethylated oligosaccharide material using an ESI-quadrupole ion trap mass spectrometer. In general, permethylation increases the MS response by several orders of magnitude and sequence information is readily obtained since methyl tagging allows the distinction between fragment ions generated by cleavage of a single glycosidic bond and inner fragments resulting from the rupture of two glycosidic linkages. Using this approach we are now able to identify all isomeric glycoforms in very heterogeneous LPS preparations.

Profiling structural elements of short-chain lipopolysaccharide of non-typeable Haemophilus influenzae

Lipopolysaccharide (LPS) is a major virulence determinant of the human bacterial pathogen Haemophilus influenzae. A characteristic feature of H. influenzae LPS is the extensive intra- and inter-strain heterogeneity of glycoform structure which is key to the role of the molecule in both commensal and disease-causing behaviour of the bacterium. The chemical composition of non-typeable Haemophilus influenzae (NTHi) LPS is highly diverse. It contains a number of different monosaccharides (Neu5Ac, L-glycero-D-manno heptose, D-glycero-D-manno heptose, Kdo, D-Glc, D-Gal, D-GlcNAc, D-GalNAc) and non-carbohydrate substituents. Prominent non-carbohydrate components are O-acetyl groups, glycine and phosphates. We now know that sialic acid (N-acetylneuraminic acid or Neu5Ac) and certain oligosaccharide extensions are important in the pathogenesis of NTHi; however, the biological implications for many of the various features are still unknown. Electrospray ionization mass spectrometry in combination with separation techniques like CE and HPLC is an indispensable tool in profiling glycoform populations in heterogeneous LPS samples. Mass spectrometry is characterized by its extreme sensitivity. Trace amounts of glycoforms expressing important virulence determinants can be detected and characterized on minute amounts of material. The present review focuses on LPS structures and mass spectrometric methods which enable us to profile these in complex mixtures.

Application of capillary electrophoresis mass spectrometry and liquid chromatography multiple-step tandem electrospray mass spectrometry to profile glycoform expression during Haemophilus influenzae pathogenesis in the chinchilla model of experimental otitis media

Otitis media caused by nontypeable Haemophilus influenzae (NTHi) is a common and recurrent bacterial infection of childhood. The structural variability and diversity of H. influenzae lipopolysaccharide (LPS) glycoforms are known to play a significant role in the commensal and disease-causing behavior of this pathogen. In this study, we determined LPS glycoform populations from NTHi strain 1003 during the course of experimental otitis media in the chinchilla model of infection by mass spectrometric techniques. Building on an established structural model of the major LPS glycoforms expressed by this NTHi strain in vitro (M. Månsson, W. Hood, J. Li, J. C. Richards, E. R. Moxon, and E. K. Schweda, Eur. J. Biochem. 269:808-818, 2002), minor isomeric glycoform populations were determined by liquid chromatography multiple-step tandem electrospray mass spectrometry (LC-ESI-MS(n)). Using capillary electrophoresis ESI-MS (CE-ESI-MS), we determined glycoform profiles for bacteria from direct middle ear fluid (MEF) samples. The LPS glycan profiles were essentially the same when the MEF samples of 7 of 10 animals were passaged on solid medium (chocolate agar). LC-ESI-MS(n) provided a sensitive method for determining the isomeric distribution of LPS glycoforms in MEF and passaged specimens. To investigate changes in LPS glycoform distribution during the course of infection, MEF samples were analyzed at 2, 5, and 9 days postinfection by CE-ESI-MS following minimal passage on chocolate agar. As previously observed, sialic acid-containing glycoforms were detected during the early stages of infection, but a trend toward more-truncated and less-complex LPS glycoforms that lacked sialic acid was found as disease progressed.

Duplicate copies of lic1 direct the addition of multiple phosphocholine residues in the lipopolysaccharide of Haemophilus influenzae

The genes of the lic1 operon (lic1A to lic1D) are responsible for incorporation of phosphocholine (PCho) into the lipopolysaccharide (LPS) of Haemophilus influenzae. PCho plays a multifaceted role in the commensal and pathogenic lifestyles of a range of mucosal pathogens, including H. influenzae. Structural studies of the LPS of nontypeable H. influenzae (NTHI) have revealed that PCho can be linked to a hexose on any one of the oligosaccharide chain extensions from the conserved inner core triheptosyl backbone. In a collection of NTHI strains we found several strains in which there were two distinct but variant lic1D DNA sequences, genes predicted to encode the transferase responsible for directing the addition of PCho to LPS. The same isolates were also found to express concomitantly two PCho residues at distinct positions in their LPS. In one such NTHI isolate, isolate 1158, structural analysis of LPS from lic1 mutants confirmed that each of the two copies of lic1D directs the addition of PCho to a distinct location on the LPS. One position for PCho addition is a novel heptose, which is part of the oligosaccharide extension from the proximal heptose of the LPS inner core. Modification of the LPS by addition of two PCho residues resulted in increased binding of C-reactive protein and had consequential effects on the resistance of the organism to the killing effects of normal human serum compared to the effects of glycoforms containing one or no PCho. When bound, C-reactive protein leads to complement-mediated killing, indicating the potential biological significance of multiple PCho residues.

Isolation of smooth-type lipopolysaccharides to electrophoretic homogeneity

The high structural heterogeneity of smooth-type lipopolysaccharides (LPS) enormously complicates the isolation of their constituent molecular species. Proof of concept is given here on the feasibility of using preparative slab-PAGE to isolate highly homogeneous smooth-type LPS glycoforms. LPS species (from 3.6 to 14.2 kDa) from Escherichia coli K-235 were separated by preparative slab-PAGE and recovered by utilizing the combined on-gel LPS reverse staining, extrusion, and passive elution techniques. As a result, 15 electrophoretically pure LPS fractions were obtained. The LPS content in the recovered fractions ranged from 280 ng (intermediate mobility glycoforms) to 411 mug (highest mobility glycoforms). The quantities of LPS fractions were sufficient to allow quantitation of the Limulus amebocyte lysate (LAL) activities of these distinct-molecular-mass LPS species, in the range from (1.1 +/- 0.1)x10(3) to (8.7 +/- 0.3)x10(5) endotoxin units (EU)/mL, by standard LAL assay. We have thus definitively demonstrated that slab-PAGE may be a suitable platform to more selectively purify individual glycoform fractions from smooth-type LPS.

Negative detection of biomolecules separated in polyacrylamide electrophoresis gels

Here we describe the protocols for negative or reverse detection of proteins, nucleic acids and lipopolysaccharides separated in polyacrylamide electrophoresis gels. These protocols are based on the selective synthesis and precipitation of a white imidazole-zinc complex in the gel, which is absent from those zones where biomolecules are located. These methods are highly sensitive (1-10 ng of biomolecules per band), very cheap as they use inexpensive, common laboratory reagents (imidazole and a Zn II salt), rapid (less than 20 min after gel washing), robust and simple (two steps). Reverse-stained biomolecules are reversibly fixed in the gel. After brief incubation in a zinc chelating agent, biomolecules can be recovered from the gel with the same efficiency as from unstained gels. In consequence, they are procedures of choice for micropreparative applications. References covering typical applications are included.

"Reverse-staining" of biomolecules in electrophoresis gels: analytical and micropreparative applications

Negative or reverse staining using imidazole and zinc salts for protein detection in electrophoresis gels was originally introduced in 1990. The method is based on the selective precipitation of zinc imidazolate in the gel except in the zones where proteins are located. The method was later adapted to allow high-sensitivity negative detection of nucleic acids and bacterial lipopolysaccharides. It provides a practically quantitative recovery of intact biomolecules and is a method of choice for micropreparative applications of gel electrophoresis to proteomics and similar structural studies. Zinc-mediated protein fixation in the gel is fully reversible and the eluted biomolecules are neither chemically modified nor contaminated with organic dyes. Here we present a detailed compilation of practical methods for implementing these techniques with emphasis in their analytical or micropreparative applications.