Enzyme-linked immunosorbent assay for riboflavin carrier protein and modified protein: application for epitope analysis.

Rabbit antibodies to native riboflavin carrier protein (RCP), are to a large extent directed towards the conformational epitopes and antibodies to disulphide bond reduced carboxymethylated riboflavin carrier protein (RCM-RCP) to the sequential epitopes. Taking advantage of this premise and in order to map the epitopes of RCP recognized by the antibodies, enzyme-linked immunosorbent assays were validated for RCP and RCM-RCP using the Avidin-Biotin system. The usefulness of these assays were illustrated when antigenicity of peptides derived from RCM-RCP following trypsinization were examined. Two major (T1,T2) and one minor peptide (T3) fractions were obtained when the tryptic peptides were fractionated on DEAE-cellulose. RCP has a blocked N-terminal. Tryptic peptides (T1 and T2) on microsequencing revealed the absence of an N-terminal amino acid, indicating that these fragments emanate from the N-terminal region of RCP. In support of this observation is the finding that antipeptide antibody to cRCP (10-24) of cRCP interacted with T1 as well as T2 indicating the presence of the sequential epitope (10-24) of cRCP in these fragments. In RCP-ELISA, only T2 displaced RCP and peptides T1 and T2 displaced RCM-RCP in RCM-RCP ELISA. Differences in the ability of these fragments (T1 and T2) to displace RCP and RCM-RCP reflect the subtle changes in the spatial structures of these epitopes in RCP and RCM-RCP.     

A solid-phase screen for protein kinase substrate selectivity.

Cassette mutagenesis was used to synthesize an Escherichia coli expression library of unique phosphorylation sites. The cassette encodes a central serine residue surrounded by every combination of Ala, Arg, Gln, Glu, Gly, and Pro residues over a 7-residue segment (a total of 6(7) approximately 2.8 x 10(5) sequences). The cassette was inserted into the gene of a suitable carrier protein and expressed in E. coli with the T7 expression system, and the resultant library was subjected to solid-phase protein phosphorylation assays on nitrocellulose filters. When the library was screened with TPK1 delta, the modified catalytic subunit of the Saccharomyces cerevisiae cAMP-dependent protein kinase, individual colonies that expressed substrates for this kinase were identified. By DNA sequencing through the cassette region of positive clones, the consensus recognition sequence for TPK1 delta was deduced and found to conform with the well-established substrate selectivity of its mammalian homolog (Arg-Arg-Xaa-Ser). Because a large number of clones can be sequenced rapidly, and the positions of invariant residues composing a recognition site identified, this approach may be useful as a general screen of protein kinase substrate selectivity.     

Phosphorylated TandeMBP: A unique protein substrate for protein phosphatase assay

To analyze a variety of protein phosphatases, we developed phosphorylated TandeMBP (P-TandeMBP), in which two different mouse myelin basic protein isoforms were fused in tandem, as a protein phosphatase substrate. P-TandeMBP was prepared efficiently in four steps: (1) phosphorylation of TandeMBP by a protein kinase mixture (Ca²⁺/calmodulin-dependent protein kinase Iδ, casein kinase 1δ, and extracellular signal-regulated kinase 2); (2) precipitation of both P-TandeMBP and protein kinases to remove ATP, Pi, and ADP; (3) acid extraction of P-TandeMBP with HCl to remove protein kinases; and (4) neutralization of the solution that contains P-TandeMBP with Tris. In combination with the malachite green assay, P-TandeMBP can be used to detect protein phosphatase activity without using radioactive materials. Moreover, P-TandeMBP served as an efficient substrate for PPM family phosphatases (PPM1A, PPM1B, PPM1D, PPM1F, PPM1G, PPM1H, PPM1K, and PPM1M) and PPP family phosphatase PP5. Various phosphatase activities were also detected with high sensitivity in gel filtration fractions from mouse brain using P-TandeMBP. These results indicate that P-TandeMBP might be a powerful tool for the detection of protein phosphatase activities.     

Spectroscopy on the wing: Naturally inspired SERS substrates for biochemical analysis

We show that naturally occurring chitinous nanostructures found on the wings of the Graphium butterfly can be used as substrates for surface‐enhanced Raman scattering when coated with a thin film of gold or silver. The substrates were found to exhibit excellent biocompatibility and sensitivity, making them ideal for protein assaying. An assay using avidin/biotin binding showed that the substrates could be used to quantify protein binding directly from changes in the surface‐enhanced Raman scattering (SERS) spectra and were sensitive over a concentration range comparable with a typical enzyme‐linked immunosorbent assays (ELISA) assay. A biomimetic version of the wing nanostructures produced using a highly reproducible, large‐scale fabrication process, yielded comparable enhancement factors and biocompatibility. The excellent biocompatibility of the wings and biomimetic substrates is unparalleled by other lithographically produced substrates, and this could pave the way for widespread application of ultrasensitive SERS‐based bioassays. (© 2009 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Rous sarcoma virus integrase protein: mapping functions for catalysis and substrate binding.

Rous sarcoma virus (RSV), like all retroviruses, encodes an integrase protein that is responsible for covalently joining the reverse-transcribed viral DNA to host DNA. We have probed the organization of functions within RSV integrase by constructing mutant derivatives and assaying their activities in vitro. We find that deletion derivatives lacking the amino-terminal 53 amino acids, which contain the conserved H-X(3-7)-H-X(23-32)-C-X(2)-C (HHCC) Zn(2+)-binding motif, are greatly impaired in their ability to carry out two reactions characteristic of integrase proteins: specific cleavage of the viral DNA termini and DNA strand transfer. Deletion mutants lacking the carboxyl-terminal 69 amino acids are also unable to carry out these reactions. However, all deletion mutants that retain the central domain are capable of carrying out disintegration, an in vitro reversal of the normal DNA strand transfer reaction, indicating that the catalytic center probably lies within this central region. Another conserved motif, D-X(39-58)-D-X(35)-E, is found in this central domain. These findings with RSV integrase closely parallel previous findings with human immunodeficiency virus integrase, indicating that a modular catalytic domain is a general feature of this family of proteins. Surprisingly, and unlike results obtained so far with human immunodeficiency virus integrase, efficient strand transfer activity can be restored to a mutant RSV integrase lacking the amino-terminal HHCC domain by fusion to various short peptides. Furthermore, these fusion proteins retain the substrate specificity of RSV integrase. These data support a model in which the integrase activities required for strand transfer in vitro, including substrate recognition, multimerization, and catalysis, all lie primarily outside the amino-terminal HHCC domain.     

Molecular analysis of pleckstrin: the major protein kinase C substrate of platelets

Activation of protein kinase C (PKC) in platelets causes the immediate phosphorylation of pleckstrin, an apparent Mr 40-47,000 protein previously called 40K or P47. Pleckstrin presumably plays an important but as yet unknown role in mediating cellular responses evoked by agonist-induced phosphoinositide turnover. We have cloned the cDNA for pleckstrin from the HL-60 human promyelocytic leukemia cell line by immunological screening of a lambda gt11 expression library (Tyers et al.: Nature 333:470-473, 1988) and now report further analysis of the pleckstrin sequence. Pleckstrin has a deduced Mr of 40,087 and is encoded by a 1,050-bp open reading frame which is preceded by a short open reading frame that terminates before the correct initiator methionine. A single polymorphic site was found in the coding region. An unusual pattern of sequence heterogeneity occurred about a poly(A) tract in the 3' untranslated region. The 3.0-kb pleckstrin mRNA induced upon differentiation of HL-60 cells apparently has heterogeneous 5' ends which undergo differential regulation during HL-60 cell maturation. Analysis by multiple sequence alignment with known PKC substrates identified a strong candidate site for phosphorylation by PKC and a potential Ca2+-binding EF-hand motif. No other similarities to proteins in current databases were found.     

Spatial profiling of protein hydrophobicity: native vs. decoy structures

A recent study of 30 soluble globular protein structures revealed a quasi-invariant called the hydrophobic ratio. This invariant, which is the ratio of the distance at which the second order hydrophobic moment vanished to the distance at which the zero order moment vanished, was found to be 0.75 +/- 0.05 for 30 protein structures. This report first describes the results of the hydrophobic profiling of 5,387 non-redundant globular protein domains of the Protein Data Bank, which yields a hydrophobic ratio of 0.71 +/- 0.08. Then, a new hydrophobic score is defined based on the hydrophobic profiling to discriminate native-like proteins from decoy structures. This is tested on three widely used decoy sets, namely the Holm and Sander decoys, Park and Levitt decoys, and Baker decoys. Since the hydrophobic moment profiling characterizes a global feature and requires reasonably good statistics, this imposes a constraint upon the size of the protein structures in order to yield relatively smooth moment profiles. We show that even subject to the limitations of protein size (both Park & Levitt and Baker sets are small protein decoys), the hydrophobic moment profiling and hydrophobic score can provide useful information that should be complementary to the information provided by force field calculations.     

From peptide to protein: comparative analysis of the substrate specificity of N-linked glycosylation in C. jejuni

The gram-negative bacterium Campylobacter jejuni was recently discovered to contain a general N-linked protein glycosylation pathway. Central to this pathway is PglB, a homologue of the Stt3p subunit of the eukaryotic oligosaccharyl transferase (OT), which is involved in the transfer of an oligosaccharide from a polyisoprenyl pyrophosphate carrier to the asparagine side chain of proteins within the conserved glycosylation sites D/E-X1-N-X2-S/T, where X1 and X2 can be any amino acids except proline. Using a library of peptide substrates and a quantitative radioactivity-based in vitro assay, we assessed the amino acids at each position of the consensus glycosylation sequence for their impact on glycosylation efficiency, whereby the sequence DQNAT was found to be the optimal acceptor substrate. In the context of a full-length folded protein, the differences between variations of the glycosylation sequences were found to be consistent with the trends observed from their peptidyl counterparts, though less dramatic because of additional influences. In addition to characterizing the acceptor preferences of PglB, we also assessed the selectivity toward the glycan donor. Interestingly, despite recent reports of relaxed selectivity toward the glycan donor, PglB was not found to be capable of utilizing glycosyl donors such as dolichyl-pyrophosphate-chitobiose, which is the minimum substrate for the eukaryotic OT process.     

Influence of temperature on growth rate and competition between two psychrotolerant Antarctic bacteria: low temperature diminishes affinity for substrate uptake.

The growth kinetics of two psychrotolerant Antarctic bacteria, Hydrogenophaga pseudoflava CR3/2/10 (2/10) and Brevibacterium sp. strain CR3/1/15 (1/15), were examined over a range of temperatures in both batch culture and glycerol-limited chemostat cultures. The maximum specific growth rate (mu max) and Ks values for both bacteria were functions of temperature, although the cell yields were relatively constant with respect to temperature. The mu max values of both strains increased up to an optimum temperature, 24 degrees C for 2/10 and 20 degrees C for 1/15. Strain 1/15 might therefore be considered to be more psychrophilic than strain 2/10. For both bacteria, the specific affinity (mu max/Ks) for glycerol uptake was lower at 2 than at 16 degrees C, indicating a greater tendency to substrate limitation at low temperature. As the temperature increased from 2 to 16 degrees C, the specific affinity of 1/15 for glycerol increased more rapidly than it did for 2/10. Thus 1/15, on the basis of this criterion, was less psychrophilic than was 2/10. The steady-state growth kinetics of the two strains at 2 and 16 degrees C imply that 1/15 would be able to outgrow 2/10 only at relatively low substrate concentrations (< 0.32 g of glycerol.liter-1) and high temperatures (> 12 degrees C), which suggests that 1/15 has a less psychrotolerant survival strategy than does 2/10. Our data were compared with other data in the literature for bacteria growing at low temperatures. They also showed an increase of substrate-specific affinity with increasing temperature.(ABSTRACT TRUNCATED AT 250 WORDS)     

cAMP-dependent protein kinase: crystallographic insights into substrate recognition and phosphotransfer.

The crystal structure of ternary and binary substrate complexes of the catalytic subunit of cAMP-dependent protein kinase has been refined at 2.2 and 2.25 A resolution, respectively. The ternary complex contains ADP and a 20-residue substrate peptide, whereas the binary complex contains the phosphorylated substrate peptide. These 2 structures were refined to crystallographic R-factors of 17.5 and 18.1%, respectively. In the ternary complex, the hydroxyl oxygen OG of the serine at the P-site is 2.7 A from the OD1 atom of Asp 166. This is the first crystallographic evidence showing the direct interaction of this invariant carboxylate with a peptide substrate, and supports the predicted role of Asp 166 as a catalytic base and as an agent to position the serine -OH for nucleophilic attack. A comparison of the substrate and inhibitor ternary complexes places the hydroxyl oxygen of the serine 2.7 A from the gamma-phosphate of ATP and supports a direct in-line mechanism for phosphotransfer. In the binary complex, the phosphate on the Ser interacts directly with the epsilon N of Lys 168, another conserved residue. In the ternary complex containing ATP and the inhibitor peptide, Lys 168 interacts electrostatically with the gamma-phosphate of ATP (Zheng J, Knighton DR, Ten Eyck LF, Karlsson R, Xuong NH, Taylor SS, Sowadski JM, 1993, Biochemistry 32:2154-2161). Thus, Lys 168 remains closely associated with the phosphate in both complexes. A comparison of this binary complex structure with the recently solved structure of the ternary complex containing ATP and inhibitor peptide also reveals that the phosphate atom traverses a distance of about 1.5 A following nucleophilic attack by serine and transfer to the peptide. No major conformational changes of active site residues are seen when the substrate and product complexes are compared, although the binary complex with the phosphopeptide reveals localized changes in conformation in the region corresponding to the glycine-rich loop. The high B-factors for this loop support the conclusion that this structural motif is a highly mobile segment of the protein.     

A synthetic peptide substrate for selective assay of protein kinase C.

Among various phosphate acceptor proteins and peptides so far tested, a synthetic peptide having the sequence surrounding Ser(8) of myelin basic protein, Gln-Lys-Arg-Pro-Ser(8)-Gln-Arg-Ser-Lys-Tyr-Leu, (MBP4-14), is the most specific and convenient substrate which can be used for selective assay of protein kinase C. This peptide is not phosphorylated by cyclic AMP-dependent protein kinase, casein kinases I and II, Ca2+/calmodulin-dependent protein kinase II, or phosphorylase kinase, and can be routinely used for the assay of protein kinase C with low background in the crude tissue extracts. The Km value is considerably low (7 microM) with a Vmax value of twice as much as that for H1 histone.     

Gaussia princeps luciferase: a bioluminescent substrate for oxidative protein folding

Gaussia princeps luciferase (GLuc) generates an intense burst of blue light when exposed to coelenterazine in the absence of ATP. Here we show that this 5‐disulfide containing enzyme can be used as a facile and convenient substrate for studies of oxidative protein folding. Reduced GLuc (rGLuc), with 10 free cysteine residues, is completely inactive as a luciferase but >60% bioluminescence activity, compared to controls, can be recovered using a range of oxidizing regimens in the absence of the exogenous shuffling activity of protein disulfide isomerase (PDI). The sulfhydryl oxidase QSOX1 can be assayed using rGLuc in a simple bioluminescence plate reader format. Similarly, low concentrations of rGLuc can be oxidized by millimolar levels of dehydroascorbate, hydrogen peroxide or much lower concentrations of sodium tetrathionate. The oxidative refolding of rGLuc in the presence of a range of glutathione redox buffers is only marginally accelerated by micromolar levels of PDI. This modest rate enhancement probably results from a relatively simple disulfide connectivity in native GLuc; reflecting two homologous domains each carrying two disulfide bonds with a single interdomain disulfide. When GLuc is reoxidized under denaturing conditions the resulting scrambled protein (sGLuc) can be used in a sensitive bioluminescence assay for reduced PDI in the absence of added exogenous thiols. Finally, the general facility by which rGLuc can recover bioluminescent activity in vitro provides a sensitive method for the assessment of inhibitors of oxidative protein folding.     

Major substrate for growth factor-activated protein-tyrosine kinases is a low-abundance protein.

A scarce, soluble, conserved protein was identified as the nonphosphorylated precursor of two related 42-kilodalton phosphoproteins that contain phosphotyrosine in mitogen-stimulated but not control fibroblasts.     

Current techniques in protein glycosylation analysis. A guide to their application.

The importance of glycosylation in biological events and the role it plays in glycoprotein function and structure is an area in which there is growing interest. In order to understand how glycosylation affects the shape or function of a protein it is however important to have suitable techniques available to obtain structural information on the oligosaccharides attached to the protein. For many years the complexity of the structures required sophisticated analytical techniques only available to a few specialist laboratories. In many cases these techniques were not available or required a large amount of material and therefore the number of glycoproteins which were fully characterised were relatively few. In recent years there have been substantial developments in the analysis of glycosylation which has significantly changed the capability to fully characterise molecules of biological interest. A number of different techniques are available which differ in terms of their complexity, the amount of information which is available from them, the skill needed to perform them and their cost. It is now possible for many laboratories who do not specialise in glycosylation analysis to obtain some information although this may be incomplete. These developments do, however, also make complete characterisation of a glycoprotein a much less daunting task and in many cases this can be performed more easily and with less starting material than was previously required. In this review a summary will be given of current techniques and their suitability for different types of analysis will be considered.     

Kinetic method for differentiating mechanisms for ligand exchange reactions: application to test for substrate channeling in glycolysis.

We have derived analytical expressions for the kinetics of the two mechanisms involved in ligand substitution reactions. These mechanisms are (i) a dissociative mechanism in which the leaving ligand is first dissociated prior to the binding of the incoming ligand and (ii) an associative mechanism where a ternary complex is formed between the incoming ligand and the complex containing the leaving ligand. The equations obtained provide the theoretical basis for differentiating these two mechanisms on the basis of their kinetic patterns of the displacement reactions. Analysis of these equations shows that an associative mechanism can only generate an increasing kinetic pattern for the observed pseudo-first-ordered rate constants as a function of increasing concentration of the incoming ligand and plateaus, in most cases, at a value higher than the off-rate constant of the leaving ligand. However, a dissociative mechanism can generate either an increasing or a decreasing (kapp decreases with increasing concentrations of the incoming ligand) kinetic pattern, depending on the magnitudes of the individual rate constants involved, and, in either case, it will plateau at kapp equal to the koff of the leaving ligand. Therefore, the decreasing kinetic pattern is a hallmark for a dissociative mechanism. This general method was used to settle the dispute of whether NADH is transferred directly via the enzyme-enzyme complex between glycerol-3-phosphate dehydrogenase (GPDH; EC 1.1.1.8) and L-lactate dehydrogenase (LDH; EC 1.1.1.27).(ABSTRACT TRUNCATED AT 250 WORDS)     

The PAUSE software for analysis of translational control over protein targeting: application to E. nidulans membrane proteins

The PAUSE software has been developed as a new tool to study translational control over protein targeting. This makes it possible to correlate the position of clusters of rare codons in a gene, predicted to cause a translational pause, with the position of hydrophobic stretches in the encoded protein, predicted to span a membrane or to act as a cleavable signal for targeting to the secretory pathway. Furthermore, this software gathers these correlations over whole sets of genes. The PAUSE software is described here, and its use is illustrated on a set of membrane proteins from the fungus Emericella nidulans. Preferential distances of about 45 codons and of about 70 codons between putative transmembrane domains and predicted translational pauses were observed. Given that approximately 30 residues are required to span the large ribosomal subunit, the predicted pauses would therefore occur when the hydrophobic domain starts protruding from the ribosome ('+45 pause'), or fully protrudes as a hairpin ('+70 pause'). Thus, these specific pauses might reflect a translational control over membrane protein targeting or early recognition ('+45 pause'), and over insertion or folding ('+70 pause').