From genome to proteome: protein map of Haemophilus influenzae

High-resolution two-dimensional (2-D) polyacrylamide gel electrophoresis allows the separation of complex biological mixtures (i.e., several hundred proteins from a bacterial cell lysate) in a single experiment. In this report proteins from Haemophilus influenzae were separated by 2-D gels and analyzed by peptide mass fingerprinting and/or amino acid analysis. By comparing the peptide mass profiles and the amino acid composition with the Haemophilus influenzae database, 119 protein spots were identified. The combination of amino acid analysis and peptide mass fingerprinting is a powerful tool for a rapid and economical identification of a large number of proteins resolved by 2-D gels. Studies on gene regulation and changes of protein expression upon drug treatment require quick and serial analysis techniques to efficiently identify potential new drug targets.     

Identification and characterization of heat shock protein 27 protein species in human myocardial two-dimensional electrophoresis patterns

Immunostaining of heat shock protein 27 (Hsp27) protein species on two-dimensional electrophoresis (2-DE) gels with enhanced sensitivity yields 59 spots reacting with anti-Hsp27 antibodies. Recombinant Hsp27 exists in 2-DE as two major protein species which comigrate in the human myocardial pattern with Hsp27 spots C754 and D899 as defined in the heart high-performance 2-DE database (http://www.mdc-berlin.de/emu/heart/). Preparative electrophoresis of human myocardial proteins and analysis of the enriched mass range 20-30 kDa by 2-DE revealed eight protein spots (C438, C582, C658, C697, C754, C595, C750) from the human myocardial database and a new spot not previously detected on silver-stained gels. These spots were identified as Hsp27 protein species by enzymatic in-gel-digestion and analysis by matrix assisted laser desorption-ionization (MALDI) peptide mass fingerprinting and, in part, MALDI-post source decay sequencing of single fragments. Possible post-translational modifications were investigated: immunostaining tests with anti-phospho-serine/-threonine/-tyrosine antibodies, although positive for other myocardial proteins, were negative for presumed Hsp27 protein species; likewise, periodate-glycostaining assays and biotinylation screening did not detect modifications in the investigated Hsp27 protein species.     

Towards an automated approach for protein identification in proteome projects

The development of automated, high throughput technologies for the rapid identification of proteins is essential for large-scale proteome projects. While a degree of automation already exists in some stages of the protein identification process, such as automated acquisition of matrix assisted laser desorption ionisation-time of flight (MALDI-TOF) mass spectra, efficient interfaces between different stages are still lacking. We report the development of a highly automated, integrated system for large scale identification of proteins separated by two-dimensional gel electrophoresis (2-DE), based on peptide mass fingerprinting. A prototype robotic system was used to image and excise 288 protein spots from an amido black stained polyvinylidene difluoride (PVDF) blot. Protein samples were enzymatically digested with a commercial automated liquid handling system. MALDI-TOF mass spectrometry was used to acquire mass spectra automatically, and the data analysed with novel automated peptide mass fingerprinting database interrogation software. Using this highly automated system, we were able to identify 95 proteins on the basis of peptide mass fingerprinting, isoelectric point and molecular weight, in a period of less than ten working days. Advantages, problems, and future developments in robotic excision systems, liquid handling, and automated database interrogation software are discussed.     

Two-dimensional mapping and microsequencing of lysosomal proteins from human placenta

Lysosomes degrade a wide range of macromolecules to yield monomer products which are exported out of the lysosome by a series of transporters. In addition, lysosomes perform a range of other functions which are cell or tissue specific. In order to gain insight into the tissue specific role of lysosomes, carrier-ampholyte two-dimensional electrophoresis (2-DE) was used in combination with N-terminal sequencing to identify the major proteins present in both the membrane and luminal space of placental lysosomes. From the 45 N-terminal peptide sequences generated, 14 luminal and five membrane proteins were identified while three other sequences were novel. The sequenced proteins were a mixture of lysosomal and non-lysosomal proteins. The lysosomal proteins consisted of gamma-interferon-inducible protein (IP-30), Saposin D, cathepsins B and D, beta-hexosaminidase, palmitoyl protein thioesterase, alpha-glucosidase, and LAMP-1. The non-lysosomal proteins were serum albumin, serotransferrin, haemoglobin gamma G chain, alpha-1-antitrypsin, placental lactogen, endoplasmin, peptide binding protein 74, p60 lymphocyte protein, p450 side chain cleavage enzyme and placental alkaline phosphatase. The 2-DE maps obtained in this study are the first to identify the major proteins in both the lumen and membrane of placental lysosomes through sequence analysis, and thus provide the basis upon which to build a complete 2-DE database of the lysosome. Furthermore, the identities of the proteins sequenced from the placental lysosomes suggest a role for lysosomes in the transport of nutrients across the trophoblastic layer.     

Proteins and their amino acid compositions: uniqueness, variability, and applications

Amino acid compositions (AAC) of proteins were analyzed in terms of their uniqueness and variability. Using several measures of convergence between the AACs of randomly chosen proteins versus those stored in protein data banks, it was established that certain families of proteins have unique AACs despite the mutations of their sequences which were imposed in the process of evolution. AACs may be used to establish the identities of many proteins which were sorted through various chromatographic media prior to their fractionation on two-dimensional (2D) gels. Subfractionations of proteins markedly enhance the chances for proper identification of low-abundant proteins which rest inaccessible if the total protein extract of an organ is analyzed on 2D gels. Although the amino acid composition versus protein identity (AAC-PI) method allows identification with high confidence of unique proteins resolved on monodimensional SDS-PAGE (1D) gels and arrays of protein isoforms resolved on two-dimensional (2D) gels, selective immunoblotting is still a more robust method. Thus, in principle, the AAC-PI method may allow limiting the number of "unknown" spots on 2D gels which could be further investigated by microsequencing and/or mass spectroscopy. However, to resolve certain ambiguities inherently linked with protein identities derived only from their AACs, the AAC-PI method must be sometimes aided by microsequencing and immunoblotting, especially in the construction of high-resolution 2D maps of proteins. A suite of algorithms which form the AAC-PI method are described in detail.     

Peptides from pigeon cerebrum: two-dimensional fingerprinting and amino acid analysis

The number and heterogeneity of endogenous peptides from pigeon cerebrum were studied by two-dimensional peptide fingerprinting. A highly consistent pattern of 8-9 peptides in the 1000-5000 molecular weight range was obtained from each cerebral sample. Amino acid analysis of the peptide material indicated that 30% of the identified residues were dicarboxylic amino acids and 30% were alphatic amino acids. There was no evidence for the presence of arginine or half-cystine in the peptide fraction.     

Evidence that atypical protein kinase C-lambda and atypical protein kinase C-zeta participate in Ras-mediated reorganization of the F-actin cytoskeleton

Liver fatty acid binding protein (L-FABP) appears to contain several different forms that may result from post-translational modification or bound ligand. To further assess this possibility, L-FABP was purified from rat liver homogenate and two putative isoforms separated using a sulfonyl column, a strong cation exchange resin. Fraction I eluted at 0.2 M NaCl, had a pI of 7.59, and following a final size exclusion step contained > 98% L-FABP. Fraction II eluted at 1.0 M NaCl, had a pI of 7.59, and following a final size exclusion step contained > 99% L-FABP. Both fractions contained approx. 0.15 moles of endogenous bound fatty acid per mole of protein, while L-FABP not subjected to the cation exchange step contained 0.75 moles of fatty acid per mole of protein. Fractions I and II had a greater proportion of saturated and monounsaturated fatty acids with a large reduction in polyunsaturated fatty acids compared to L-FABP not fractionated by cation exchange. Mass spectral analysis indicated the molecular mass of Fraction I was 14,315.02 +/- 0.35 Da and Fraction II was 14,315.86 +/- 0.34 Da. The peptide map for each fraction was determined by limited digestion of each fraction with either trypsin, Asp-N, or chymotrypsin to yield overlapping peptide fragments. Mass spectral analysis of these digests indicated the two proteins had identical amino acid fragments and that Cys69 was reduced and there were no Asn to Asp exchanges. Hence, these two forms of L-FABP were not isoforms and were not the result of differences in bound fatty acid. It is proposed that these two distinct forms of rat L-FABP were structural conformers based on two alternative folding pathways.     

Direct sequencing of neuropeptides in biological tissue by MALDI-PSD mass spectrometry

Dissected tissue pieces of the pituitary pars intermedia from the amphibian Xenopus laevis was directly subjected to matrix-assisted laser desorption/ionization (MALDI) mass analysis. The obtained MALDI peptide profile revealed both previously known and unexpected processing products of the proopiomelanocortin gene. Mass spectrometric peptide sequencing of a few of these neuropeptides was performed by employing MALDI combined with postsource decay (PSD) fragment ion mass analysis. The potential of MALDI-PSD for sequence analysis of peptides directly from unfractionated tissue samples was examined for the first time for the known desacetyl-alpha-MSH-NH2 and the presumed vasotocin neuropeptide. In addition, the sequence of an unknown peptide which was present in the pars intermedia tissue sample at mass 1392.7 u was determined. The MALDI-PSD mass spectrum of precursor ion 1392.7 u contained sufficient structural information to uniquely identify the sequence by searching protein sequence databases. The determined amino acid sequence corresponds to the vasotocin peptide with a C-terminal extension of Gly-Lys-Arg ("vasotocinyl-GKR"), indicating incomplete processing of the vasotocin precursor protein in the pituitary pars intermediate of X. laevis. Both vasotocin and vasotocinyl-GKR are nonlinear peptides containing a disulfide (S-S) bridge between two cysteine residues. Interpretation of the spectra of these two peptides reveals three different forms of characteristic fragment ions of the cysteine side chain: peptide-CH2-SH (regular mass of Cys-containing fragment ions), peptide-CH2-S-SH (regular mass + 32 u) and peptide = CH2 (regular mass -34 u) due to cleavage on either side of the sulfur atoms.     

Metal binding properties and secondary structure of the zinc-binding domain of Nup475

Nup475 is a nuclear zinc-binding protein of unknown function that is induced in mammalian cells by growth factor mitogens. Nup475 contains two tandemly repeated sequences YKTELCX8CX5CX3H (Cys3His repeats) that are thought to be zinc-bindin domains. Similar sequences have been found in a number of proteins from various species of eukaryotes. To determine the metal binding properties and secondary structure of the putative zinc-binding domains of Nup475, we have used synthetic or recombinant peptides that contain one or two domain sequences. The peptide with a single domain bound 1.0 +/- 0.1 equivalents of Co2+, and the peptide with two domains bound 1.7 +/- 0.4 equivalents of Co2+. Both peptides bound Co2+ and Zn2+ with affinities similar to those of classical zinc finger peptides. In each case, the Co2+ complex exhibited strong d-d transitions characteristic of tetrahedral coordination. For structural studies by nuclear magnetic resonance spectroscopy, we used a more soluble two-domain peptide that had a single amino acid substitution in a nonconserved amino acid residue in the second Cys3His repeat. The mutant peptide unexpectedly showed loss of one of its metal binding sites and displayed ordered structure for only the first Cys3His sequence. On the basis of the nuclear magnetic resonance data, we propose a structure for the Nup475 metal-binding domain in which the zinc ion is coordinated by the conserved cysteines and histidine, and the conserved YKTEL motif forms a parallel sheet-like structure with the C terminus of this domain. This structure is unlike that of any previously described class of metal binding domain.     

Hydrolysis and amino acid composition of proteins

Amino acid composition analysis is a classical protein analysis method, which finds a wide application in medical and food science research and is indispensable for protein quantification. It is a complex technique, comprising two steps, hydrolysis of the substrate and chromatographic separation and detection of the residues. A properly performed hydrolysis is a prerequisite of a successful analysis. The most significant developments of the technology in the last decade consist in the (i) reduction of the hydrolysis time by the use of microwave radiation energy; (ii) improvement in the sensitivity of the residue detection, the quantification of the sensitive residues and separation of the enantiomeric forms of the amino acids; (iii) application of amino acid analysis in the large-scale protein identification by database search; and (iv) gradual replacement of the original ion exchange residue separation by reversed-phase high-performance liquid chromatography. Amino acid analysis is currently facing an enormous competition in the determination of the identity of proteins and amino acid homologs by the essentially faster mass spectrometry techniques. The amino acid analysis technology needs further simplification and automation of the hydrolysis, chromatography and detection steps to withstand the pressure exerted by the other technologies.     

Major antigenic proteins of the agent of human granulocytic ehrlichiosis are encoded by members of a multigene family

Western blot analysis of proteins from a cell culture isolate (USG3) of the human granulocytic ehrlichiosis (HGE) agent has identified a number of immunoreactive proteins, including major antigenic proteins of 43 and 45 kDa. Peptides derived from the 43- and 45-kDa proteins were sequenced, and degenerate PCR primers based on these sequences were used to amplify DNA from USG3. Sequencing of a 550-bp PCR product revealed that it encodes a protein homologous to the MSP-2 proteins of Anaplasma marginale. Concurrently, an expression library made from USG3 genomic DNA was screened with granulocytic Ehrlichia (GE)-positive immune sera. Analysis of two clones showed that they contain one partial and three full-length highly related genes, suggesting that they are part of a multigene family. Amino acid alignment showed conserved amino- and carboxy-terminal regions which flank a variable region. The conserved regions of these proteins are also homologous to the MSP-2 proteins of A. marginale; thus, they were designated GE MSP-2A (45 kDa), MSP-2B (34 kDa), and MSP-2C (38 kDa). The PCR fragment obtained as a result of peptide sequencing was completely contained within the msp-2A clone, and all of the sequenced peptides were found in the GE MSP-2 proteins. Recombinant MSP-2B protein and an MSP-2A fusion protein were expressed in Escherichia coli and reacted with human sera positive for the HGE agent by immunofluorescence assay. These data suggest that the 43- and 45-kDa proteins of the HGE agent are encoded by members of the GE MSP-2 multigene family.     

The oestrogen receptor regulates NFkappaB and AP-1 activity in a cell-specific manner

It has recently been identified the PEPT2 cDNA encodes the high affinity proton-coupled peptide transporter in rabbit kidney cortex. PEPT2 represents a 729 amino acid protein with 12 putative transmembrane domains that mediates H+/H3O+ dependent electrogenic transmembrane transport of di- and tripeptides and of selected peptidomimetics. Here the functional expression of PEPT2 in the methylotropic yeast Pichia pastoris is described under the control of a methanol inducible promoter. Western blot analysis of Pichia cell membranes prepared from a recombinant clone identified a protein with an apparent molecular mass of about 85-87 kDa. Peptide uptake into cells expressing PEPT2 was up to 80 times higher than in control cells. Cells of recombinant clones showed a saturable peptide transport activity for the hydrolysis resistant dipeptide 3H-D-Phe-Ala with an app. K0.5 of 0.143 +/- 0.016 mM. Inhibition of 3H-D-Phe-Ala uptake by selected di- and tripeptides and beta-lactam antibiotics revealed the same substrate specificity as obtained in renal membrane vesicles or for PEPT2 when expressed in Xenopus laevis oocytes. A novel fluorescence based assay for assessing transport function based on a coumarin-labeled fluorescent peptide analogue has also been developed. Moreover, using a histidyl auxotrophe strain a PEPT2 expressing cell clone in which transport function can be monitored by a simple yeast growth test was established. In conclusion, this is one of only a few reports on successful functional expression of mammalian membrane transport proteins in yeast. The high expression level will provide a simple means for future studies either on the structure-affinity relationship for substrate interaction with PEPT2 or for selection of mutants generated by random mutagenesis.     

Auditory system plasticity in children after long periods of complete deafness

Separation and identification of proteins by two-dimensional (2-D) electrophoresis can be used for protein-based gene expression analysis. In this report single protein spots, from polyvinylidene difluoride blots of micropreparative E. coli 2-D gels, were rapidly and economically identified by matching their amino acid composition, estimated pI and molecular weight against all E. coli entries in the SWISS-PROT database. Thirty proteins from an E. coli 2-D map were analyzed and identities assigned. Three of the proteins were unknown. By protein sequencing analysis, 20 of the 27 proteins were correctly identified. Importantly, correct identifications showed unambiguous "correct" score patterns. While incorrect protein identifications also showed distinctive score patterns, indicating that protein must be identified by other means. These techniques allow large-scale screening of the protein complement of simple organisms, or tissues in normal and disease states. The computer program described here is accessible via the World Wide Web at URL address (http:@expasy.hcuge.ch/).     

Rapid assessment of early glycation products by mass spectrometry

In order to detect the early glycation products, we have reacted a model peptide (t-boc-lys-ala-ala) with L-threose (a degradation product of ascorbic acid) and analyzed the reaction products by a combination of HPLC and mass spectrometry. Amino group modification, as observed by a fluorescamine assay, indicated complete modification after 3 days of incubation with a 10-fold excess of threose. As much as 60% of the adducts were acid labile and only 4% of the adducts could be observed by amino acid analysis. However, Fast atom bombardment mass spectrometry (FABMS) of the samples incubated for 6 hr showed relative molecular masses consistent with the formation of adducts corresponding to the addition of one and two molecules of L-threose to the peptide. Likewise, samples incubated for 12 hr showed peptide adducts with two and three L-threoses. The number of threose molecules added to the peptide was also confirmed from the FABMS analysis by using [1-13C]-threose as the glycating agent.     

Partial characterization of two serologically related DNA-binding proteins specified by the cottontail rabbit herpesvirus CTHV

We have previously described two serologically related DNA-binding phosphoproteins of different apparent molecular mass (75 kDa and 35 kDa) produced in cottontail rabbit herpesvirus (CTHV)-infected cells. The 75 kDa protein appeared before the 35 kDa protein in the infectious cycle. Here, we extend the characterization of these proteins. Protease V8 fingerprints of methionine-labelled 35 kDa protein showed four major peptide products, three of which co-migrated with major peptides from digests of the 75 kDa protein. The fourth peptide, with an estimated mass of 10 kDa, reacted with an antiserum recognizing both proteins. In vitro translation of total or poly A-containing RNA isolated from infected cells at 24 h to 72 h post-infection produced only the 75 kDa protein as measured by immunoprecipitation with anti-75/35 kDa serum, suggesting that the 35 kDa protein is derived from the 75 kDa protein by proteolytic cleavage. Virus-specific RNA obtained by prehybridization to CTHV DNA also produced the 75 kDA protein, confirming its viral origin. The putative gene for the 75 kDa protein was localized to a region on the CTHV DNA restricted by PvuII.     

Expression cloning of a human brain neuropeptide Y Y2 receptor

The 36-amino acid peptide, neuropeptide Y (NPY), is a member of a peptide family that includes the endocrine peptides, peptide YY (PYY), and pancreatic polypeptide (PP). NPY receptors have been broadly subdivided into postsynaptic Y1 receptors and presynaptic Y2 receptors based on the preference of Pro34-substituted analogues for the Y1 receptors and carboxyl-terminal fragments for the Y2. A Y1 receptor has been cloned, and this receptor appears to mediate several effects of NPY, including vasoconstriction and anxiolysis in animal models. We report the cloning of a human brain Y2 receptor from a human brain library. Pools of clones were transiently expressed in COS-1 cells, and 125I-PYY binding pools were identified by autoradiography. After a single positive pool was detected in the original screening, a single clone was isolated by four rounds of sequential enrichment. The clone encoded a 381-amino acid protein of the heptahelix (seven TM) type. Amino acid identity of this receptor with the Y1 receptor was 31% overall with 40% identity in the TM regions. Comparison with the human PP1 receptor indicated 33% overall amino acid identity with 42% identity in the TM regions. Pharmacologically, the receptor exhibited high affinity for NPY, PYY, and carboxyl-terminal fragments of NPY and PYY. In addition, Pro34-substituted analogues had very low affinity. With the use of Northern blot analysis, high levels of Y2 mRNA were detected in a variety of brain regions with little expression in peripheral tissues. Thus, the receptor protein has the pharmacological properties and distribution of the human Y2 receptor.     

A secretory cellulose-binding protein cDNA cloned from the root-knot nematode (Meloidogyne incognita)

A cDNA encoding a secretory cellulose-binding protein was cloned from the root-knot nematode (Meloidogyne incognita) with RNA fingerprinting. The putative full-length cDNA, named Mi-cpb-1, encoded a 203 amino acid protein containing an N-terminal secretion signal peptide. The C-terminal sequence of the putative MI-CBP-1 was similar to a bacterial-type cellulose-binding domain, whereas the N-terminal sequence did not show significant similarity to any proteins in data bases. Recombinant MI-CBP-1 lacked cellulase activity, but bound to cellulose and plant cell walls. In Southern blot hybridization, Mi-cbp-1 hybridized with genomic DNA from M. incognita, M. arenaria, and M. javanica, but not M. hapla, Heterodera glycines, or Caenorhabditis elegans. Polyclonal antibodies raised against recombinant MI-CBP-1 strongly labeled secretory granules in subventral gland cells of second-stage juveniles in indirect immunofluorescence microscopy. Enzyme-linked immunosorbent assay detection of MI-CBP-1 in stylet secretions of second-stage juveniles with the polyclonal antibodies indicated MI-CBP-1 could be secreted through the nematodes' stylet, suggesting that the cellulose-binding protein may have a role in pathogenesis.     

Impact of hepatitis G virus co-infection on the course of hepatitis C virus infection before and after liver transplantation

Large-scale DNA sequencing is creating a sequence infrastructure of great benefit to protein biochemistry. Concurrent with the application of large-scale DNA sequencing to whole genome analysis, mass spectrometry has attained the capability to rapidly, and with remarkable sensitivity, determine weights and amino acid sequences of peptides. Computer algorithms have been developed to use the two different types of data generated by mass spectrometers to search sequence databases. When a protein is digested with a site-specific protease, the molecular weights of the resulting collection of peptides, the mass map or fingerprint, can be determined using mass spectrometry. The molecular weights of the set of peptides derived from the digestion of a protein can then be used to identify the protein. Several different approaches have been developed. Protein identification using peptide mass mapping is an effective technique when studying organisms with completed genomes. A second method is based on the use of data created by tandem mass spectrometers. Tandem mass spectra contain highly specific information in the fragmentation pattern as well as sequence information. This information has been used to search databases of translated protein sequences as well as nucleotide databases such as expressed sequence tag (EST) sequences. The ability to search nucleotide databases is an advantage when analyzing data obtained from organisms whose genomes are not yet completed, but a large amount of expressed gene sequence is available (e.g., human and mouse). Furthermore, a strength of using tandem mass spectra to search databases is the ability to identify proteins present in fairly complex mixtures.