Imidazoles as well as thiolates in proteins bind technetium-99m.

99mTc is widely thought to directly bind proteins through thiolate groups of cysteine residues, resulting in Tc-cysteinyl-protein bonds. Chemical reduction of disulfide bonds in proteins is widely used to generate thiolates with the goal of increasing 99mTc binding. This strategy is used because most proteins contain no thiolates, but many do contain disulfide bonds. In this study, we have evaluated the hypothesis that imidazole groups of histidine are also involved in direct 99mTc binding to proteins. Human gamma-globulin was used as the model protein in these studies. The immunoglobulin was used (a) without reduction or was (b) treated with stannous ions to reduce disulfide bonds thereby increasing thiolate concentration. These proteins were used to evaluate the hypothesis that imidazole as well as thiolate groups bind Tc. The proteins were evaluated by (a) using free amino acids to compete with proteins for 99mTc and (b) by chemical modification of amino acid side chains. In addition, peptides known to contain either cysteine or histidine, but not both, were also successfully directly labeled with 99mTc. These results indicate that in proteins (and peptides) imidazole-containing groups as well as thiolate-containing groups bind Tc.     

Matrix-assisted laser desorption/ionization time of flight mass spectrometry peptide mass fingerprints and post source decay: a tool for the identification and analysis of phloem proteins from Cucurbita maxima Duch. separated by two-dimensional polyacrylamide gel electrophoresis

A combination of gel electrophoresis and mass spectrometry was used to analyze the soluble proteins from phloem sap of Cucurbita maxima Duch. Phloem proteins were separated using two-dimensional gel electrophoresis. Coomassie-stained spots were cut out and subjected to tryptic digestion. To identify proteins, peptide mass fingerprints were determined by matrix-assisted laser desorption/ionization time of flight (MALDI-TOF) mass spectrometry. In addition, MALDI-TOF post source decay measurements were used to obtain partial sequence information for the proteins. Results from both approaches were used for database searches. In this study, 17 proteins in the mass range 5-50 kDa were analyzed. Of these proteins six could be clearly identified, seven showed significant homologies to known plant proteins, and four were not significantly homologous to database entries. The present study suggests that the applied method is feasible for a large-scale analysis and identification of phloem proteins derived from different organs or from plants kept under various physiological conditions.     

Preparative high-performance liquid partition chromatography of proteins.

Methods for preparative high-performance liquid chromatography (hplc) of proteins are described. Both normal and reverse-phase chromatography were studied and adapted to the fractionation of proteins in quantities of up to 50 mg. Lichrosorb Diol was used as a “normal phase” for chromatography of hydrophobic proteins. Lichrosorb RP-8 was used for reversephase chromatography of proteins.     

Introduction of protein kinase recognition sites into proteins: a review of their preparation, advantages, and applications.

Labeled proteins are used in a variety of applications. This review focuses on methods that utilize genetic engineering to introduce protein kinase recognition sites into proteins. Many protein kinase recognition sites can be introduced into proteins and serve as useful tags for a variety of purposes. The introduction of protein kinase recognition sites into proteins can be achieved without modifying the essential structure or function of the proteins. Because proteins modified by these procedures retain their activity after phosphorylation, they can be used in many applications. The phosphorylatable proteins can be labeled easily to high specific activity with radioisotopes ((32)P, (33)P, or (35)S), or the nonradioactive (31)P can be used. The use of these radioisotopes provides a convenient and safe method for radiolabeling proteins. Moreover, the use of the nonradioactive (31)P with protein tyrosine kinase recognition sites permits the tagging of proteins and their detection with the many anti-phosphotyrosine antibodies available. Overall, the procedure represents a convenient, safe, and efficient method to label proteins for a variety of applications.     

基因工程抗体融合蛋白的构建

抗体融合蛋白可以具有抗体的特性和所融合的功能蛋白的活性,可广泛用于免疫治疗、免疫诊断、抗体纯化及抗体和抗原的分析定量等,特别可用于免疫导向药物的制备。基因工程抗体融合蛋白比传统的化学交联的抗体融合蛋白具有更多的优越性。本文就基因工程抗体融合蛋白的构建和性质做一综述 。     

The contribution of Pir protein family to yeast cell surface display

Proteins with internal repeats (Pir) in the Baker’s yeast are located on the cell wall and include four highly homologous members. Recently, Pir proteins have become increasingly used as anchor proteins in yeast cell surface display systems. These display systems are classified into three types: N-terminal fusion, C-terminal fusion, and inserted fusion. In addition to the GPI (glycosylphosphatidyl inositol) and the FL/FS anchor proteins, these three Pir-based systems significantly increase the choices for target proteins to be displayed. Furthermore, Pir proteins can also be used as a fusion partner for target proteins to be effectively secreted into culture medium. Here, we summarize the development and application of Pir proteins as anchor proteins.     

Differential detergent fractionation for non-electrophoretic eukaryote cell proteomics

Differential detergent fractionation (DDF), which relies on detergents to sequentially extract proteins from eukaryotic cells, has been used to increase proteome coverage of 2D-PAGE. Here, we used DDF extraction in conjunction with the nonelectrophoretic proteomics method of liquid chromatography and electrospray ionization tandem mass spectrometry. We demonstrate that DDF can be used with 2D-LC ESI MS2 for comprehensive cellular proteomics, including a large proportion of membrane proteins. Compared to some published methods designed to isolate membrane proteins specifically, DDF extraction yields comprehensive proteomes which include twice as many membrane proteins. Two-thirds of these membrane proteins have more than one trans-membrane domain. Since DDF separates proteins based upon their physicochemistry and subcellular localization, this method also provides data useful for functional genome annotation. As more genome sequences are completed, methods which can aid in functional annotation will become increasingly important.     

Identification of novel Bacillus thuringiensis Cry1Ac binding proteins in Manduca sexta midgut through proteomic analysis

The crystal proteins of Bacillus thuringiensis are widely used in transgenic crops and commercially available insecticides. Manduca sexta, the tobacco hornworm, is the model insect for B. thuringiensis studies. Although brush border vesicles prepared from larval M. sexta midgut have been used in numerous mode-of-action studies of B. thuringiensis toxins, their protein components are mostly unknown. Vesicles prepared from the brush border of M. sexta midgut were analyzed using one- and two-dimensional gel electrophoresis to establish a midgut brush border proteome. Sub-proteomes were also established for B. thuringiensis Cry1Ac binding proteins and glycosylphosphatidyl inositol (GPI) anchored proteins. Peptide mass fingerprints were generated for several spots identified as Cry1Ac binding proteins and GPI-anchored proteins and these fingerprints were used for database searches. Results generally did not produce matches to M. sexta proteins, but did match proteins of other Lepidoptera. Actin and alkaline phosphatase were identified as novel proteins that bind Cry1Ac in addition to the previously reported aminopeptidase N. Aminopeptidase N was the only GPI-anchored protein identified. Actin, aminopeptidase N, and membrane alkaline phosphatase were confirmed as accurate protein identifications through western blots.     

Selective destruction of abnormal proteins by ubiquitin-mediated protein quality control degradation

Misfolded proteins are continuously produced in the cell and present an escalating detriment to cellular physiology if not managed effectively. As such, all organisms have evolved mechanisms to address misfolded proteins. One primary way eukaryotic cells handle the complication of misfolded proteins is by destroying them through the ubiquitin-proteasome system. To do this, eukaryotes possess specialized ubiquitin-protein ligases that have the capacity to recognize misfolded proteins over normally folded proteins. The strategies used by these Protein Quality Control (PQC) ligases to target the wide variety of misfolded proteins in the cell will likely be different than those used by ubiquitin-protein ligases that function in regulated degradation to target normally folded proteins. In this review, we highlight what is known about how misfolded proteins are recognized by PQC ubiquitin-protein ligases.     

DISC ELECTROPHORETIC SEPARATION OF PROTEINS IN NEURONAL, GLIAL AND SUBCELLULAR FRACTIONS FROM CEREBRAL CORTEX

Abstract— Soluble proteins were studied in preparations from rabbit brain cortex enriched in neuronal or glial cells and in subcellular cortical fractions. Analytical polyacrylamide gels were used for acidic (pH 9-5) and basic (pH 4-3) proteins and qualitative and quantitative differences are described. The isozymes of lactic dehydrogenase, brain specific proteins and radioactive labelling patterns were used to characterize some soluble proteins.     

Two-dimensional map of membrane proteins from human erythrocytes

Human erythrocyte membrane proteins were analyzed by a modified two-dimensional electrophoresis performed according to O'Farrell. This method was used to construct a two-dimensional map of human erythrocyte membrane proteins. The map plotted in the coordinates "relative molecular mass versus relative electrophoretic mobility during IEF" was used for the characterization of 189 proteins. The position of major membrane proteins in the map was determined on the basis of their Mr, pI as well as literature data. Carboanhydrase was positioned by coelectrophoresis. A comparative analysis of erythrocyte membrane and cytosol preparations by two-dimensional protein mapping revealed that some of erythrocyte proteins have dual localization.     

Emerging Technologies to Map the Protein Methylome

Protein methylation plays an integral role in cellular signaling, most notably by modulating proteins bound at chromatin and increasingly through regulation of non-histone proteins. One central challenge in understanding how methylation acts in signaling is identifying and measuring protein methylation. This includes locus-specific modification of histones, on individual non-histone proteins, and globally across the proteome. Protein methylation has been studied traditionally using candidate approaches such as methylation-specific antibodies, mapping of post-translational modifications by mass spectrometry, and radioactive labeling to characterize methylation on target proteins. Recent developments have provided new approaches to identify methylated proteins, measure methylation levels, identify substrates of methyltransferase enzymes, and match methylated proteins to methyl-specific reader domains. Methyl-binding protein domains and improved antibodies with broad specificity for methylated proteins are being used to characterize the “protein methylome”. They also have the potential to be used in high-throughput assays for inhibitor screens and drug development. These tools are often coupled to improvements in mass spectrometry to quickly identify methylated residues, as well as to protein microarrays, where they can be used to screen for methylated proteins. Finally, new chemical biology strategies are being used to probe the function of methyltransferases, demethylases, and methyl-binding “reader” domains. These tools create a “system-level” understanding of protein methylation and integrate protein methylation into broader signaling processes.     

Prediction of mitochondrial proteins of malaria parasite using bi-profile Bayes feature extraction

Mitochondrial proteins of Plasmodium falciparum are considered as attractive targets for anti-malarial drugs, but the experimental identification of these proteins is a difficult and time-consuming task. Computational prediction of mitochondrial proteins offers an alternative approach. However, the commonly used subcellular location prediction methods are unsuited for P. falciparum mitochondrial proteins whereas the organism and organelle-specific methods were constructed on the basis of a rather small dataset. In this study, a novel dataset termed PfM233, which included 108 mitochondrial and 125 non-mitochondrial proteins with sequence similarity below 25%, was established and the methods for predicting mitochondrial proteins of P. falciparum were described. Both bi-profile Bayes and split amino acid composition were applied to extract the features from the N- and C-terminal sequences of these proteins, which were then used to construct two SVM based classifiers (PfMP-N25 and PfMP-30). Using PfM233 as the dataset, PfMP-N25 and PfMP-30 achieved accuracies (MCCs) of 90.13% (0.80) and 90.99% (0.82). When tested with the commonly used 40 mitochondrial proteins in PfM175 and the 108 mitochondrial proteins in PfM233, these two methods obviously outperformed the existing general, organelle-specific and organism and organelle-specific methods.     

Extraction of proteins from the large subunit of bovine mitochondrial ribosomes under nondenaturing conditions

The 55 S mammalian mitochondrial ribosome (referred to hereafter as "mitoribosome") is protein-rich, containing nearly twice as much protein as the Escherichia coli ribosome. In order to produce soluble mitochondrial proteins and protein-deficient subribosomal particles for use in functional and structural studies, the proteins of bovine mitoribosomes were extracted by washing in a series of buffers containing increasing concentrations of LiCl as the only chaotropic agent. LiCl disruption is used in order to preserve the solubilized proteins in a substantially "native" configuration. The extraction mixtures were characterized by sucrose density gradient analysis and the compositions of the stripped protein and residual pellet fractions were determined by two-dimensional polyacrylamide gel electrophoresis. In order to analyze the behavior or individual proteins, the intensity of Coomassie blue stain for each protein was normalized against the intensity of stain for the same protein in a control sample. Buffers with 1, 2, and 4 M LiCl each extract a specific subset of mitoribosomal proteins, while another group of proteins remains in the residual pellet fraction. Although very few proteins are detected in only one condition, most proteins are specifically enriched in one fraction. This LiCl procedure, therefore, produces fractionated groups of mitoribosomal proteins which can be used directly as a source for those proteins in which they are enriched, or they can be used as a starting point in further purification procedures. In contrast to results with E. coli ribosomes, several mitoribosomal proteins remain core-associated, indicating a different structural organization in these ribosomes.     

Isolation of nuclear encoded plastid ribosomal protein cDNAs

Summary A pea leaf cDNA library was constructed in the expression vector gt11 and screened with antisera raised against proteins extracted from 30S and 50S ribosomal subunits and 70S ribosomes prepared from isolated pea chloroplasts. Six recombinant phage were identified that encoded fusion proteins containing plastid ribosomal protein antigenic determinants. Phage-induced cell lysate proteins, containing the fusion proteins, were bound to nitrocellulose membranes and used as affinity matrices to prepare monospecific antibodies. These antibodies were then used to identify by Western blotting which plastid ribosomal protein shared antigenic determinants with the fusion proteins. cDNA inserts from the antigen-producing phage were used to hybrid-select complementary mRNAs. The cell-free translation products of these mRNAs were added to a pea chloroplast in vitro transport system and imported proteins analyzed by two-dimensional gel electrophoresis. The imported proteins comigrated with the plastid ribosomal proteins that were identified as being antigenically related to the fusion proteins produced by the corresponding recombinant phage. The imported proteins were 3,500–5,500 daltons smaller than their precursors.     

Putative high mobility group (HMG) non-histone chromosomal proteins from wheat germ. Isolation, characterisation and partial sequence analysis

Four proteins have been isolated from wheat germ by methods analogous to those used to isolate HMG proteins from animal tissue. All four proteins have been shown to be chromosomal in origin. Although amino acid analyses show that three of these proteins have compositions similar to those of the mammalian HMG proteins, N-terminal sequence analyses of these proteins show an absence of sequence homology with any of the mammalian HMG proteins.     

The isolation and purification of surface specific proteins of somatic and reproductive protoplasts of lily and rapeseed

The plasma membrane surface proteins of intact somatic (leaf) and reproductive (pollen, generative cell or sperm cell) protoplasts of lily ( Lilium longiflorum ) and rapeseed ( Brassica napus cv. Midas) were compared after probing with N-hydroxysuccinimido- (NHS) or sulfo-NHS-biotin. The plasma membranes of intact protoplasts are impermeable to these biotin probes, which bind covalently to the free amino groups of surface proteins. Enzyme-labelled streptavidin was used to detect membrane proteins after separation by SDS-PAGE and western blotting. In lily, six proteins specific to the surface membrane of leaf protoplasts were identified varying from 25–64 kDa, three proteins to pollen protoplasts in the range 35–64 kDa and two proteins to generative cell protoplasts, 63 and 67 kDa. In rapeseed leaf protoplasts, seven proteins in the range 22–69 kDa were detected, while in the sperm enriched fraction five proteins were present in the same kDa range. The proteins identified as membrane specific for generative cell protoplasts of lily have been isolated and were used as antigens for monoclonal antibody production. Preliminary results indicate the successful production of antibodies to surface antigens. These antibodies will be used to localise surface specific epitopes which are likely to be involved in cell-cell recognition at fertilization.     

A simplified method for purification of recombinant soluble DnaA proteins

An improved, simplified method for the purification of recombinant, tagged DnaA proteins is described. The presented protocol allowed us to purify soluble DnaA proteins from two different bacterial species: Helicobacter pylori and Streptomyces coelicolor, but it can most likely also be used for the isolation of DnaA proteins from other bacteria, as it was adapted for Mycobacterium tuberculosis DnaA. The isolation procedure consists of protein precipitation with ammonium sulphate followed by affinity chromatography. The composition of the buffers used at each purification step is crucial for the successful isolation of the recombinant DnaA proteins. The universality of the method in terms of its application to differently tagged proteins (His-tagged or GST-tagged) as well as different properties of purified proteins (e.g., highly aggregating truncated forms) makes the protocol highly useful for all studies requiring purified and active DnaA proteins.     

Affinity Purification of Human τ Proteins and the Construction of a Sensitive Sandwich Enzyme-Linked Immunosorbent Assay for Human τ Detection

Immunoaffinity chromatography with a monoclonal antibody produced against bovine tau protein was used to purify tau proteins from human brain. Fifty grams of brain tissue yielded approximately 2 mg of pure tau proteins. The affinity-purified human tau was used to produce a high-titered rabbit anti-human tau serum. The monoclonal anti-tau antibody and the polyclonal rabbit anti-tau serum were then used to construct a sandwich enzyme-linked immunosorbent assay for detection of human tau proteins, with a sensitivity of 1 ng/ml.