Distinctive properties of signal sequences from bacterial lipoproteins

We have compared a number of attributes (hydrophobicity, aminoacid size, charge and secondary structure propensities) of signalsequences from bacterial lipoproteins with the same attributesof signal peptides from other prokaryotic proteins (non-lipoproteins).Lipoprotein leader sequences tend to be shorter, more hydrophobicand bulky, and they have stronger conformational preferences,the most conspicuous being a predicted ß-turn comprisingpositions 2 or 3 of the mature protein. Another distinctivefeature is a maximum in the local energy profile between positions–1 and +2. With one exception (ß-lactamase III),the lipoproteins do not have Pro in their signal peptides, andthey tend to have fewer Ser and Thr but more Gly than non-lipoproteins.Lipoproteins also lack a net negative charge in the N-terminalregions of the mature proteins. The signal peptides of the bacteriocinplasmid-coded lysis proteins appear to be unique in that theyhave all the ascribed features of lipoprotein signals; thesecharacteristics can be used to guide signal peptide mutagenesisexperiments and to construct new secretion vehicles.     

Computational analysis of alpha-helical membrane protein structure: implications for the prediction of 3D structural models

Relatively little has been known about the structure of alpha-helical membrane proteins, since until recently few structures had been crystallized. These limited data have restricted structural analyses to the prediction of secondary structure, rather than tertiary folds. In order to address this, this paper describes an analysis of the 23 available membrane protein structures. A number of findings are made that are of particular relevance to transmembrane helix packing: (1) on average lipid-tail-accessible transmembrane residues are significantly more hydrophobic, less conserved and contain different residue types to buried residues; (2) charged residues are not always buried and, when accessible to membrane lipid tails, few are paired with another charge and instead they often interact with phospholipid head-groups or with other residue types; (3) a significant proportion of lipid-tail-accessible charged and polar residues form hydrogen bonds only with residues one turn away in the same helix (intra-helix); (4) pore-lining residues are usually hydrophobic and it is difficult to distinguish them from buried residues in terms of either residue type or conservation; and (5) information was gained about the proportion of helices that tend to contribute to lining a pore and the resulting pore diameter. These findings are discussed with relevance to the prediction of membrane protein 3D structure.     

A reliable sequence alignment method based on probabilities of residue correspondences

Probabilities of all possible correspondences of residues inaligning two proteins are evaluated by assuming that the statisticalweight of each alignment is proportional to the exponent ofits total similarity score. Based on such probabilities, a probabilityalignment that includes the most probable correspondences isproposed. In the cases of highly similar sequence pairs, theprobability alignments agree with the maximum similarity alignmentsthat correspond to the alignments with the maximum similarityscore. Significant correspondences in the probability alignmentsare those whose probabilities are >0.5. The probability alignmentmethod is applied to a few protein pairs, and results indicatethat such highly probable correspondences in the probabilityalignments are probably correct correspondences that agree withthe structural alignments and that incorrect correspondencesin the maximum similarity alignments are usually insignificantcorrespondences in the probability alignments. The root meansquare deviations in superimposition of corresponding residuestend to be smaller for significant correspondences in the probabilityalignments than for all correspondences in the maximum similarityalignments, indicating that incorrect correspondences in themaximum similarity alignments tend to be insignificant correspondencesin probability alignments. This fact is also confirmed in 109protein pairs that are similar to each other with sequence identitiesbetween 90 and 35%. In addition, the probability alignment methodmay better predict correct correspondences than the maximumsimilarity alignment method. Probability alignments do, of course,depend on a scoring scheme but are less sensitive to the valueof parameters such as gap penalties. The present probabilityalignment method is useful for constructing reliable alignmentsbased on the probabilities of correspondences and can be usedwith any scoring scheme.     

A strategy for generating polyglutamine 'length libraries' in model host proteins

Huntington's disease is one of nine known neurodegenerative diseases in which a disease-specific protein contains an unusually long polyglutamine (polyQ) stretch. The proteins associated with each disease are unrelated in sequence, size, structure, function or location of the mutation. In all cases, there is an apparent critical number of glutamines below which individuals do not develop disease. Expansion of the polyQ domain is closely associated with misfolding and aggregation of the protein. It is not yet well understood how the length of the polyQ tract, and its location within a given protein, is related to misfolding and to disease. In this work we developed a strategy for generating length libraries of polyQ-containing proteins, with the polyQ inserted at an arbitrary location. This strategy facilitates systematic, detailed study of the relationship among polyQ length, context and misfolding.     

Cytotoxicity of human RNase-based immunotoxins requires cytosolic access and resistance to ribonuclease inhibition

Immunotoxins are targeted therapeutics designed to kill cancer cells. The targeting moiety of an immunotoxin selectively binds to a tumor cell and targets it for death via an attached toxin. Because the toxins are typically of plant or bacterial origin, their clinical use is limited by immunogenicity and nonspecific toxicity. To circumvent these problems, we have begun to engineer immunotoxins containing human pancreatic ribonuclease. Here we describe the generation of ribonuclease mutants designed to evade a ubiquitous cytosolic inhibitor that would otherwise block cytotoxicity. Two mutants retained catalytic activity and were relatively resistant to the inhibitor. To deliver them to human T leukemic cells, these ribonuclease variants were fused to a single chain Fv fragment specific for CD 7.The ribonuclease-sFv fusion proteins bound CD 7(+) T cells and were internalized yet were not cytotoxic. Transfection of the proteins directly into the cytosol reduced cell viability, suggesting that the failure of the immunotoxins to kill cells when added externally resulted from the inability of the ribonuclease moiety to access the cytosol efficiently. Our results indicate appropriate intracellular routing, as well as resistance to inhibition, is critical to the cytotoxicity of human ribonuclease-based immunotoxins.     

The role of tyrosine residues in the DNA-binding site of the Pf1 gene 5 protein

The 144 amino acid gene 5 protein of bacteriophage Pf1 bindstightly and cooperatively to single-stranded DNA during replicationof the phage genome. It has been suggested that aromatic aminoacid side chains are important for this interaction, probablythrough base stacking with the DNA. We have analysed the accessibilityof tyrosine residues in the DNA—protein complex, and theirimportance to the DNA-binding activity of the protein, by chemicalmodification and protection experiments using tetranitromethane.Tyrosines 21, 30 and 55 are surface accessible in the free proteinbut are protected from modification in the complex with phageDNA. Moreover, modification of these residues in the free proteinabolishes the ability to bind to DNA or oligonucleotides, asjudged by fluorescence spectroscopy and gel retardation analysis.Modification of the protein also results in the formation ofan intersubunit covalent cross-link between Tyr55 and Phe76,suggesting that Phe76 is located within the DNA-binding cleftof the protein. It is proposed that residues 17–34 ofthe Pf1 gene 5 protein form a beta-hairpin analogous to the‘DNA-binding wing’ of the fd and Ike gene 5 proteins.We suggest the existence of a single-stranded DNA binding motif,in which Tyr30 of the Pf1 protein is equivalent to the functionallyimportant Tyr26 of the fd gene 5 protein.     

The importance of loop length in the folding of an immunoglobulin domain

Immunoglobulin (Ig)-like proteins have been shown to fold following formation of a nucleus comprising interactions between residues that are distant in the primary sequence. What role do the loops connecting these nucleus residues play? Here, the importance of loops connecting beta-strands in different sheets of the Ig fold is investigated, by insertion of five glycine residues into the B-C loop of an Ig domain from human titin, TI I27. The folding pathway of this elongated 'pseudo wild-type' TI I27 is probed using protein engineering and Phi-value analysis. The Phi-values calculated for mutants within the pseudo wild-type protein indicate that the folding nucleus in wild-type TI I27 is conserved, supporting the hypothesis that the inter-sheet loop is not critical to the formation of a long-range folding nucleus.     

A system for concomitant overexpression of four periplasmic folding catalysts to improve secretory protein production in Escherichia coli

Although Escherichia coli is in wide use for preparative protein expression, problems with the folding of the recombinant gene product and protein aggregation are frequently encountered. Apart from cytoplasmic expression, this is also true for secretion into the bacterial periplasm, the method of choice for the production of proteins that carry structural disulfide bonds. Here we report the construction of the helper plasmid pTUM4, which effects overexpression of four established periplasmic chaperones and folding catalysts: the thiol-disulfide oxidoreductases DsbA and DsbC that catalyze the formation and isomerization of disulfide bridges and the peptidyl-prolyl cis/trans-isomerases with chaperone activity, FkpA and SurA. pTUM4 carries a p15a origin of replication and a chloramphenicol resistance gene and, thus, it is compatible with many conventional expression vectors that use the ColEI origin and an ampicillin resistance. Its positive effects on the yield of soluble recombinant protein and the homogeneity of disulfide pattern are illustrated here using the human plasma retinol-binding protein as well as the extracellular carbohydrate recognition domain of the dendritic cell membrane receptor DC-SIGN. Hence, pTUM4 represents a novel helper vector which complements existing cytosolic chaperone coexpression plasmids and should be useful for the functional secretion of various recombinant proteins with hampered folding efficiency.     

Conservation of residue interactions in a family of Ca-binding proteins

In the TNC family of Ca-binding proteins (calmodulin, parvalbumin,intestinal calcium binding protein and troponin C) {small tilde}70 well-conserved amino acid sequences and six crystal structuresare known. We find a clear correlation between residue contactsin the structures and residue conservation in the sequences:residues with strong sidechain–sidechain contacts in thethree-dimensional structure tend to be the more conserved inthe sequence. This is one way to quantify the intuitive notionof the importance of sidechain interactions for maintainingprotein three-dimensional structure in evolution and may usefullybe taken into account in planning point mutations in proteinengineering.     

High-level bacterial expression, purification and characterization of human calreticulin

To investigate its cellular function and role in autoimmunedisease pathogenesis, we have bacterlally expressed human calreticulin,a major calcium-binding protein in the endoplasmic reticulumand a human autoantigen. This is the First report describingthe heterologous expression of calreticulin from any source.The recombinant calreticulin constituted {small tilde}32% ofthe soluble Escherichia coli proteins, and was purified to apparenthomogeneity by ion exchange and hydrophobic liquid chromatography.As does the bona fide protein, the recombinant calreticulinbinds calcium and undergoes changes in its conformation uponZn²⁺ binding. We take this as a strong indication that the foldingof the E.coli-expressed calreticulin is very similar, if notidentical, to that of the authentic protein. Moreover, the bacteriallyexpressed calreticulin readily reacted with anti-human and anti-rabbitantibodies, and the anti-recombinant calreticulin antibodiesimmunoreacted with HeLa calreticulin. The availability of thisexpression system will allow us to carry out site-specific anddeletion mutagenesis analysis in structure-function studiesof calreticulin.     

Polarity as a criterion in protein design

Hypothetical proteins can be tested computationally by determiningwhether or not the designed sequence-structure pair has thecharacteristics of a typical globular protein. We have developedsuch a test by deriving quantities with approximately constantvalue for all globular proteins, based on empirical analysisof the exposed and buried surfaces of 128 structurally knownproteins. The characteristic quantities that best appear tosegregate badly designed or deliberately misfolded proteinsfrom their properly folded natural relatives are the polar fractionof side chains on the protein surface and, independently, inthe protein interior. Three of the seven hypothetical structurestested here can be rejected as having too many polar side-chaingroups in the interior or too few on the protein surface. Inaddition, a recently designed nutritional protein is identifiedas being very much unlike globular proteins. These database-derivedcharacteristic quantities are useful in screening designed proteinsprior to experiment and may be useful in screening experimentallydetermined (X-ray, NMR) protein structures for possible errors.     

The creation of a novel fluorescent protein by guided consensus engineering

Consensus engineering has been used to increase the stability of a number of different proteins, either by creating consensus proteins from scratch or by modifying existing proteins so that their sequences more closely match a consensus sequence. In this paper we describe the first application of consensus engineering to the ab initio creation of a novel fluorescent protein. This was based on the alignment of 31 fluorescent proteins with >62% homology to monomeric Azami green (mAG) protein, and used the sequence of mAG to guide amino acid selection at positions of ambiguity. This consensus green protein is extremely well expressed, monomeric and fluorescent with red shifted absorption and emission characteristics compared to mAG. Although slightly less stable than mAG, it is better expressed and brighter under the excitation conditions typically used in single molecule fluorescence spectroscopy or confocal microscopy. This study illustrates the power of consensus engineering to create stable proteins using the subtle information embedded in the alignment of similar proteins and shows that the benefits of this approach may extend beyond stability.     

Emulsifying performance of modular beta-sandwich proteins: the hydrophobic moment and conformational stability

Our understanding of protein emulsifying properties is largely based on analysis of emulsifiers found in milk and seed. The 9th-10th type III fibronectin domain pair retains full biological activity following emulsification-encapsulation into polyester microspheres, for controlled delivery, but the conformational criteria determining emulsification efficiency (EE) are unknown. Here, we have generated a series of mutants of this beta-sandwich protein, changing the hydrophobic moment and conformational stability, to investigate the structure-emulsification relationship. Predictive modelling of the hydrophobic moment of beta-strands and mutations known to increase conformational stability were used to generate the series. The proteins were tested for their emulsion stability and EE for oil-in-water mixtures. We show that the stabilization of emulsions by beta-sandwich proteins is best predicted by conformational stability during equilibrium denaturation in ionic surfactant. In contrast, the EE of these proteins is inversely related to an increase in their surface hydrophobicity following unfolding in surfactant. We also describe a novel beta-sandwich emulsifier with strong EE. The requirement for interdomain flexibility to achieve maximum emulsion stability and EE is also shown. This work increases our understanding of the mechanisms involved in protein emulsification and will be of use to the microencapsulation of proteins into polyester microspheres via emulsion-extraction protocols.     

A strategy for high-level expression of soluble and functional human interferon alpha as a GST-fusion protein in E. coli

Escherichia coli is the most extensively used host for the production of recombinant proteins. However, most of the eukaryotic proteins are typically obtained as insoluble, misfolded inclusion bodies that need solubilization and refolding. To achieve high-level expression of soluble recombinant human interferon alpha (rhIFNalpha) in E. coli, we have first constructed a recombinant expression plasmid (pGEX-hIFNalpha2b), in which we merged the hIFNalpha2b cDNA with the glutathione S-transferase (GST) coding sequence downstream of the tac-inducible promoter. Using this plasmid, we have achieved 70% expression of soluble rhIFNalpha2b as a GST fusion protein using E. coli BL21 strain, under optimized environmental factors such as culture growth temperature and inducer (IPTG) concentration. However, release of the IFN moiety from the fusion protein by thrombin digestion was not optimal. Therefore, we have engineered the expression cassette to optimize the amino acid sequence at the GST-IFN junction and to introduce E. coli preferred codon within the thrombin cleavage site. We have used the engineered plasmid (pGEX-Delta-hIFNalpha2b) and the modified E. coli trxB(-)/gor(-) (Origami) strain to overcome the problem of removing the GST moiety while expressing soluble rhIFNalpha2b. Our results show the production of soluble and functional rhIFNalpha2b at a yield of 100 mg/l, without optimization of any step of the process. The specific biological activity of the purified soluble rhIFNalpha2b was equal to 2.0 x 10(8) IU/mg when compared with the WHO IFNalpha standard. Our data are the first to show that high yield production of soluble and functional rhIFNalpha2b tagged with GST can be achieved in E. coli.     

Development of a screening platform for directed evolution using the reef coral fluorescent protein ZsGreen as a solubility reporter

Soluble proteins, with high expression levels, are preferred candidates for structural and functional studies. In cases of low expression, aggregation or inclusion body formation, time-consuming searches for optimal expression or refolding conditions are required. We have developed a high-throughput solubility engineering and screening platform for proteins that are expressed in an insoluble form in Escherichia coli with the aim of obtaining a broad spectrum of best hits with increased solubility in difficult to express target proteins. This process has been developed using error-prone PCR to introduce random base changes in genes of interest. Expression of mutated proteins in fusion with the reef coral fluorescent protein ZsGreen as a solubility marker has enabled the selection of more soluble variants. We have used a colony picker to achieve high-throughput selection of E.coli expressing more soluble target protein-ZsGreen fusions, with increased fluorescence. The whole process enables us to complete one round of mutation, screening and analysis of 20,000 potential soluble clones within approximately 8 weeks. We describe the development of the methods using different model proteins and show one example, the kinase domain from the human EphB2 receptor, as a successful application of the whole platform.     

GANNPhos: a new phosphorylation site predictor based on a genetic algorithm integrated neural network

With the advance of modern molecular biology it has become increasingly clear that few cellular processes are unaffected by protein phosphorylation. Therefore, computational identification of phosphorylation sites is very helpful to accelerate the functional understanding of huge available protein sequences obtained from genomic and proteomic studies. Using a genetic algorithm integrated neural network (GANN), a new bioinformatics method named GANNPhos has been developed to predict phosphorylation sites in proteins. Aided by a genetic algorithm to optimize the weight values within the network, GANNPhos has demonstrated a high accuracy of 81.1, 76.7 and 73.3% in predicting phosphorylated S, T and Y sites, respectively. When benchmarked against Back-Propagation neural network and Support Vector Machine algorithms, GANNPhos gives better performance, suggesting the GANN program can be used for other prediction tasks in the field of protein bioinformatics.     

Analysis of protein conformational characteristics related to thermostability

The thermal stability of proteins was studied, 195 single aminoacid residue replacements reported elsewhere being analysedfor several protein conformational characteristics: type ofresidue replacement; conservative versus nonconservative substitution;replacement being in a homologous stretch of amino acid residues;change in hydrogen bond, van der Waals and secondary structurepropensities; solvent-accessible versus inaccessible replacement;type of secondary structure involved in the substitution; thephysico-chemical characteristics to which the thermostabilityenhancement can be attributed; and the relationship of the replacementsite to the folding intermediates of the protein, when known.From the above analyses, some general rules arise which suggestwhere amino acid substitutions can be made to enhance proteinthermostability: substitutions are conservative according tothe Dayhoff matrix; mainly occur on conserved stretches of residues;preferentially occur on solvent-accessible residues; maintainor enhance the secondary structure propensity upon substitution;contribute to neutralize the dipole moment of the caps of helicesand strands; and tend to increase the number of potential hydrogenbonding or van der Waals contacts or improve hydrophobic packing.     

The elusive role of the N-terminal extension of {beta}A3- and {beta}Al-crystallin

ß-Crystallins are structural lens proteins with aconserved two-domain structure and variable N- and C-terminalextensions. These extensions are assumed to be involved in quaternaryinteractions within the ß-crystallin oligomers orwith other lens proteins. Therefore, the production of ßA3-and ßAl-crystallin from the single ßA3/A1mRNA by dual translation initiation is of interest. These crystallinsare identical, except that ßAl has a much shorterN-terminal extension than ßA3. This rare mechanismhas been conserved for over 250 million years during the evolutionof the ßA3/A1 gene, suggesting that the generationof different N-terminal extensions confers a selective advantage.We therefore compared the stability and association behaviourof recombinant ßA3- and ßAl-crystallin.Both proteins are equally stable in urea- and pH-induced denaturationexperiments. Gel filtration and analytical ultracentrifugationestablished that ßA3 and ßA1 both form homodimers.In the water-soluble proteins of bovine lens, ßA3and ßA1 are present in the same molecular weight fractions,indicating that they oligomerize equally with other ß-crystallins.¹H-NMR spectroscopy showed that residues Met1 to Asn22 of theN-terminal extension of ßA3 have great flexibilityand are solvent exposed, excluding them from protein interactionsin the homodimer. These results indicate that the differentN-terminal extensions of ßA3 and ßA1 donot affect their homo- or heteromeric interactions.     

Solvent interactions with n ring systems in proteins

The interaction of water molecules with apolar amino acids isan important aspect of the hydrophobic effect and hence of proteinfolding. Our distributed multipole electrostatic model for waterinteracting with phenylalanine dipeptides shows that minimumenergy sites exist above the aromatic ring such that a solventmolecule can interact with the electrons, but only when thissite is not blocked by mainchain atoms or disturbed by main-chainpolar atoms. This is consistent with the experimental evidenceof others that water can hydrogen bond to aromatic n electrons.In contrast, our analysis of solvent interactions with phenylalanineresidues based on 48 high-resolution, well-refined protein structuresshows that the dominant interaction of solvent molecules iswith the edge of the ring and not with the 7i electrons. Asthe faces of phenylalanine rings tend to be buried, and solventinteractions with neighbouring polar atoms are more favourable,the interaction of water molecules with the faces of aromatic rings appears not to occur frequently in proteins