Conformational changes induced by the transforming amino acid substitution in the transmembrane domain of theneu oncogene-encoded p185 protein

Theneu oncogene is frequently found in certain types of human carcinomas and has been shown to be activated in animal models by nitrosourea-induced mutation. The activating mutation in theneu oncogene results in the substitution of a glutamic acid for a valine at position 664 in the transmembrane domain of the encoded protein product of 185 kda (designated p185), which, on the basis of homology studies, is presumed to be a receptor for an as yet unidentified growth factor. It has been proposed that activating amino acid substitutions in this region of p185 lead to a conformational change in the protein which causes signal transduction via an increase in tyrosine kinase activity in the absence of any external signal. Using conformational energy analysis, we have determined the preferred three-dimensional structures for the transmembrane decapeptide (residues 658–667) of the p185 protein with valine and glutamic acid at the critical position 664. The results indicate that the global minimum energy conformation of the decapeptide from the normal protein with Val at position 664 is an α-helix with a sharp bend (CD* conformation at residues 664 and 665) in this region, whereas the global minimum conformation for the decapeptide from the mutant transforming protein with Glu at position 664 assumes an all α-helical configuration. Furthermore, the second highest energy conformation for the decapeptide from the normal protein is identical to the global minimum energy conformation for the decapeptide from the transforming protein, providing a possible explanation why overexpression of the normal protein also has a transforming effect. These results suggest there may be a normal and a transforming conformation for theneu-encoded p185 proteins which may explain their differences in transforming activity.     

Conformational effects of the substitution of Arg for Gly 13 in the ras oncogene-encoded P21 protein

The effect of the substitution of Arg for Gly 13 on the structure of the transforming region decapeptide (Leu 6-Gly 15) of the ras oncogene encoded P21 protein has been investigated using conformational energy analysis. A human malignancy has been identified that contains a ras gene with a single mutation in the thirteenth codon such that the encoded protein would have Arg substituted for Gly at this position, and transfection of cells in culture with this gene results in malignant transformation. Conformational analysis demonstrates that the Arg 13 decapeptide adopts a conformation identical to that for other peptides with substitutions at position 13 (Asp 13, Val 13) from transforming proteins that is distinctively different from that for peptides (Gly 13, Ser 13) from normal, nontransforming proteins. This is found to be an indirect effect resulting from changes in the conformation of Gly 12 produced by substitutions at position 13. These results are consistent with recent analysis of crystallographic data of proteins on conformational preferences for glycine in tripeptide sequences.     

An activating amino acid substitution in the c-abl oncogene protein fails to produce a local conformational change

Thebcr-abl chimeric gene of Philadelphia chromosome positive chronic myelogenous leukemias is only weakly transforming. This transformation activity is greatly enhanced by a Lys-for-Glu substitution at position 832 in the c-abl gene, as occurs in the highly transforming v-abl genes. It has been suggested that this mutation results in a significant structural change in the encoded protein product. Using conformational energy analysis, we have determined the allowed low-energy conformations for residues 828–836 of this protein with Lys and Glu at position 832. In both cases, the overwhelmingly preferred conformation for this region is a bend-helix motif. The helix terminates at residue 836, and there are no discernible differences in conformation between the Lys- and Glu-containing sequences. These results suggest that the activating amino acid substitution at position 832 in the c-abl protein product does not produce its effect via a local conformational change.     

Conformational effects of amino acid substitutions at positions 10, 12, and 13 in the P21 protein

Substitutions of amino acids for Gly 12 or Gly 13 in theras oncogene-encoded P21 proteins have been demonstrated to produce unique structural changes in these proteins that correlate with their ability to produce cell transformation. For example, the P21 proteins with Arg 12 or Val 13 are both known to be actively transforming. Recent site-specific mutagenesis experiments on the transforming Arg 12 protein have found that the substitution of Val for Gly 10 has no effect on transforming activity whereas the substitution of Val for Gly 13 led to a loss of transforming activity. In this study, we examine the structural effects of these substitutions on the amino terminal hydrophobic decapeptide (Leu 6-Gly 15) of P21 using conformational energy analysis. The results show that the transforming proteins with Gly 10 and Arg 12 or Val 10 and Arg 12 can both adopt the putative malignancy-causing conformation, whereas, for the nontransforming protein with Arg 12 and Val 13, this conformation is energetically disallowed. These results further support the theory that due to structural changes the transforming P21 proteins are unable to bind to some regulatory cellular element which may be the recently identified binding protein responsible for the induction of increased GTPase activity in normal P21 compared with transforming mutants.     

Structural effects of amino acid substitutions on the P21 proteins: Evidence for a malignant conformation

The conformational effects of different amino acid substitutions for Gly at position 12 in theras-oncogene-encoded P21 proteins have been investigated using conformational energy calculations. Mutations that cause amino acid substitutions for Gly 12 result in a protein that produces malignant transformation of cells. It had previously been shown that substitution of Val, Lys, or Ser for Gly at position 12 results in a major conformational change, and that the preferred lowest energy structure for each of the substituted peptides is identical. It is now found that substitution for Gly 12 of other amino acids that have widely disparate helix-nucleating potentials and completely different side chains (Asp, Asn, Cys, Phe, Tle, Leu, and Ala) all produce this identical lowest energy conformation. This finding is consistent with the recent results of site-specific mutagenesis experiments showing that P21 proteins containing these amino acids at position 12 all promote malignant transformation of cells and suggests the existence of a malignancy-causing conformation for the P21 proteins.     

Conformation of the transmembrane domain of the c-erbB-2 oncogene-encoded protein in its monomeric and dimeric states

The human c-erbB-2 oncogene is homologous to the ratneu oncogene, both encoding transmembrane growth factor receptors. Overexpression and point mutations in the transmembrane domain of the encoded proteins in both cases have been implicated in cell transformation and carcinogenesis. In the case of theneu protein, it has been proposed that these effects are mediated by conformational preferences for an-helix in the transmembrane domain, which facilitates receptor dimerization, an important step in the signal transduction process. To examine whether this is the case for c-erbB-2 as well, we have used conformational energy analysis to determine the preferred three-dimensional structures for the transmembrane domain of the c-erbB-2 protein from residues 650 to 668 with Val (nontransforming) and Glu (transforming) at position 659. The global minimum energy conformation for the Val-659 peptide from the normal, nontransforming protein was found to contain several bends, whereas the global minimum energy conformation for Glu-659 peptide from the mutant, transforming protein was found to be-helical. Thus, the difference in conformational preferences for these transmembrane domains may explain the difference in transforming ability of these proteins. The presence of higher-energy-helical conformations for the transmembrane domain from the normal Val-659 protein may provide an explanation for the presence of a transforming effect from overexpression of c-erbB-2. In addition, docking of the oncogenic sequences in their-helical and bend conformations shows that the all--helical dimer is clearly favored energetically over the bend dimer.     

Constructing amino acid residue substitution classes maximally indicative of local protein structure

Using an information theoretic formalism, we optimize classes of amino acid substitution to be maximally indicative of local protein structure. Our statistically-derived classes are loosely identifiable with the heuristic constructions found in previously published work. However, while these other methods provide a more rigid idealization of physicochemically constrained residue substitution, our classes provide substantially more structural information with many fewer parameters. Moreover, these substitution classes are consistent with the paradigmatic view of the sequence-to-structure relationship in globular proteins which holds that the three-dimensional architecture is predominantly determined by the arrangement of hydrophobic and polar side chains with weak constraints on the actual amino acid identities. More specific constraints are imposed on the placement of prolines, glycines, and the charged residues. These substitution classes have been used in highly accurate predictions of residue solvent accessibility. They could also be used in the identification of homologous proteins, the construction and refinement of multiple sequence alignments, and as a means of condensing and codifying the information in multiple sequence alignments for secondary structure prediction and tertiary fold recognition. © 1996 Wiley-Liss, Inc.     

Correlation of structure with transforming activity of the P21 proteins with substitutions of L-amino acids for Gly at position 13

The effects of amino acid substitutions for Gly 13 on the structure of the transforming region (Leu 6-Gly 15) of the P21 proteins have been explored using conformational energy calculations. It has been found that the substitution of Asp for Gly at this position results in a protein capable of transforming cells into malignant ones. Proteins that contain Ser at position 13 (but no other substitutions), however, transform cells with a greatly reduced activity. The transforming peptide with Asp 13 adopts a conformation that is different from the one for the peptide from the normal protein (with Gly 12 and Gly 13) and that may result in expression of a higher energy malignancy-producing form. The Ser-containing peptide adopts as its lowest energy conformation one that is identical to that of the peptide from the normal protein, thus explaining its lack of transforming activity. From analysis of the interactions preventing the Asp 13-containing peptide from adopting the normal conformation, it is predicted that substitutions of amino acids with branched side chains atC , such as Val, Ile, and Thr, should promote cell transformation. This prediction with Val has recently been confirmed in genetic experiments.     

A thermodynamic model of protein structure evolution explains empirical amino acid substitution matrices

Proteins evolve under a myriad of biophysical selection pressures that collectively control the patterns of amino acid substitutions. These evolutionary pressures are sufficiently consistent over time and across protein families to produce substitution patterns, summarized in global amino acid substitution matrices such as BLOSUM, JTT, WAG, and LG, which can be used to successfully detect homologs, infer phylogenies, and reconstruct ancestral sequences. Although the factors that govern the variation of amino acid substitution rates have received much attention, the influence of thermodynamic stability constraints remains unresolved. Here we develop a simple model to calculate amino acid substitution matrices from evolutionary dynamics controlled by a fitness function that reports on the thermodynamic effects of amino acid mutations in protein structures. This hybrid biophysical and evolutionary model accounts for nucleotide transition/transversion rate bias, multi‐nucleotide codon changes, the number of codons per amino acid, and thermodynamic protein stability. We find that our theoretical model accurately recapitulates the complex yet universal pattern observed in common global amino acid substitution matrices used in phylogenetics. These results suggest that selection for thermodynamically stable proteins, coupled with nucleotide mutation bias filtered by the structure of the genetic code, is the primary driver behind the global amino acid substitution patterns observed in proteins throughout the tree of life.     

A structural dissection of amino acid substitutions in helical transmembrane proteins

The evolution of protein folds is under strong constraints from their surrounding environment. Although folding in water‐soluble proteins is driven primarily by hydrophobic forces, the nature of the forces that determine the folding and stability of transmembrane proteins are still not fully understood. Furthermore, the chemically heterogeneous lipid bilayer has a non‐uniform effect on protein structure. In this article, we attempt to get an insight into the nature of this effect by examining the impact of various types of local structure environment on amino acid substitution, based on alignments of high‐resolution structures of polytopic helical transmembrane proteins combined with sequences of close homologs. Compared to globular proteins, burying amino acid sidechains, especially hydrophilic ones, led to a lower increase in conservation in both the lipid‐water interface region and the hydrocarbon core region. This observation is due to surface residues in HTM proteins especially in the HC region being relatively highly conserved, suggesting higher evolutionary constraints from their specific interactions with the surrounding lipid molecules. Polar and small residues, particularly Pro and Gly, show a noticeable increase in conservation as they are positioned more towards the centre of the membrane, which is consistent with their recognized key roles in structural stability. In addition, the examination of hydrogen bonds in the membrane environment identified some exposed hydrophilic residues being better conserved when not hydrogen‐bonded to other residues, supporting the importance of lipid‐protein sidechain interactions. The conclusions presented in this study highlight the distinct features of substitution matrices that take into account the membrane environment, and their potential role in improving sequence‐structure alignments of transmembrane proteins. Proteins 2010; © 2010 Wiley‐Liss, Inc.     

Conformational effects of amino acid substitutions in the P-glycoprotein of themdr 1 gene

The P-glycoprotein of themdr 1 gene is responsible for the phenomenon of multidrug resistance in human cells. The presumed drug-binding site of the wild-type P-glycoprotein contains a glycine at position 185. A mutant P-glycoprotein which contains valine at this position causes cells to retain resistance to colchichine, but to lose cross-resistance to other drugs such as the chemotherapeutic agents vinblastine and Adriamycin. This has been hypothesized to be due to a conformational change in the protein induced by the amino acid substitution. Using conformational energy analysis, we have determined the allowed three-dimensional structures for the wild-type and mutant proteins in the region of position 185. The results indicate that the wild-type protein adopts a unique left-handed conformation at position 185 which is energetically unfavorable for the protein withl-amino acids (including valine) at this position. This conformational change induced by amino acid substitutions for Gly 185 could explain the differences in binding to the P-glycoprotein of various drugs and, hence, the differences in drug resistance exhibited by various cell lines expressing these proteins.     

A radioimmunocytological quantitative method for the rapid detection of ras oncogene p21 protein in mammalian cells

In order to provide a sensitive and quantitative detection method of ras p21 at the cytological level, the monoclonal antibody Y 13 259 and iodinated protein A were used to locate theras protein in various mammalian cell lines. The subsequent autoradiograph can be analysed by a computer-assisted system which showed in these reported experiments that the relative levels of p21 detected in these cells corresponded to results obtained earlier using conventional biochemical methods.To whom correspondence should be addressed.     

Conformation of the metastasis-inhibiting laminin pentapeptide

The binding of cancer cells to the basement membrane glycoprotein laminin appears to be a critical step in the metastatic process. This binding can be inhibited competitively by a specific pentapeptide sequence (Tyr-Ile-Gly-Ser-Arg) of the laminin B1 chain, and this peptide can prevent metastasis formationin vivo. However, other similar pentapeptide sequences (e.g., Tyr-Ile-Gly-Ser-Glu) have been found to be much less active in metastasis inhibition, raising the possibility that such amino acid substitutions produce structural changes responsible for altering binding to the laminin receptor. In this study, conformational energy analysis has been used to determine the three-dimensional structures of these peptides. The results indicate that the substitution of Glu for the terminal Arg produces a significant conformational change in the peptide backbone at the middle Gly residue. These results have important implications for the design of drugs that may be useful in preventing metastasis formation and tumor spread.     

Correlation of structure with transforming activity of the P21 proteins with substitutions at positions 12 and 16

The structural effects of amino acid substitutions at positions 12 and 16 in the amino-terminal segment (Tyr 4-Ala 18) of the ras-oncogene-encoded P21 proteins have been investigated using conformational energy analysis. The P21 protein with Val at position 12 and Lys at position 16 is known to have high transforming ability, while the P21 protein with Val at position 12 and Asn at position 16 is known to have poor transforming ability, similar to that of the normal protein (with Gly at 12 and Lys at 16.) The current results demonstrate a significant conformational change at position 15 induced by the substitution of Asn for Lys at position 16, which could explain this alteration in transformation potential. These findings are consistent with previous results suggesting the existence of a normal and a malignancy-causing conformation for the P21 proteins and suggest that the critical transforming region may encompass residues 12–15.     

Removal of kinetic traps and enhanced protein folding by strategic substitution of amino acids in a model alpha-helical hairpin peptide

The presence of non-native kinetic traps in the free energy landscape of a protein may significantly lengthen the overall folding time so that the folding process becomes unreliable. We use a computational model alpha-helical hairpin peptide to calculate structural free energy landscapes and relate them to the kinetics of folding. We show how protein engineering through strategic changes in only a few amino acid residues along the primary sequence can greatly increase the speed and reliability of the folding process, as seen experimentally. These strategic substitutions also prevent the formation of long-lived misfolded configurations that can cause unwanted aggregations of peptides. These results support arguments that removal of kinetic traps, obligatory or nonobligatory, is crucial for fast folding.     

Changes in the amino acid composition and protein modification in phloem sap of rice

Pure phloem sap was collected from insects feeding on rice (Oryza sativa L.) leaves by a laser technique similar to the aphid stylet technique. Rapid circulation of nitrogen in the sieve tubes was demonstrated directly using ¹⁵N as a tracer. Application to the roots of the metabolic inhibitors of amino acids, aminooxyacetate and methioninesulfoximine, changed the amino acid composition in the sieve tubes. Feeding methionine to leaf tips resulted in its bulk transfer into the sieve tubes. In vitro experiments confirmed the existence of protein kinases in the pure rice phloem sap. The phosphorylation status of the sieve tube sap proteins was affected by the light regime. The possibility that changes in chemical composition or protein modification such as phosphorylation in the sieve tubes might affect plant growth are discussed.Analysis of pure phloem sap collected from rice plants by insect laser technique has shown dynamic changes in the chemical composition and the quality of proteins in the sap.     

Influence of drying treatment on three Sargassum species 2. Protein extractability, in vitro protein digestibility and amino acid profile of protein concentrates

The effects of different drying treatments (oven- andfreeze-drying) on protein extractability of three subtropical brownseaweeds, Sargassum hemiphyllum, S. henslowianum and S. patens, as well as in vitro protein digestibility and amino acid profileof their protein concentrates (PCs) were investigated. When comparedwith freeze-drying, oven-drying not only improved significantly (p <0.05, two-way ANOVA, Tukey-HSD) the protein extractability of thethree Sargassum species but also the protein quality (in vitroprotein digestibility) of their PCs. Therefore, oven-drying was found to bemore suitable for protein extraction of brown seaweeds. The relationshipsbetween the protein extractability and total phenolic content in seaweedsand between in vitro protein digestibility and total phenolic contentin PCs were also discussed.     

Determination and control of low-level amino acid misincorporation in human thioredoxin protein produced in a recombinant Escherichia coli production system

Escherichia coli is used extensively in the production of proteins within biotechnology for a number of therapeutic applications. Here, we discuss the production and overexpression of the potential biopharmaceutical human thioredoxin protein (rhTRX) within E. coli. Overexpression of foreign molecules within the cell can put an enormous amount of stress on the translation machinery. This can lead to a misfiring in the construction of a protein resulting in populations differing slightly in amino acid composition. Whilst this may still result in a population of active molecules being expressed, it does present significant problems with molecules that are destined for clinical applications. Amino acid misincorporation of this subset could potentially result in antibodies being raised to these unnatural proteins. Cross-reaction with a patient's endogenous thioredoxin could then lead to an autoimmune phenomena and serious health implications. Generally, the issue of misincorporation appears not to be a routine regulatory concern (see ICH Q6B guidelines). Therefore, amino acid misincorporation may not have been detected, much less explored in the clinic as the occurrence or absence of these random errors is not routinely reported. Using current technologies based on proteomics, the ability to find misincorporation critically depends upon the criteria for matching theoretical and experimental mass spectrometry data. Additionally, isolation and extraction of these mistranslated proteins from the production process is both difficult and expensive. Therefore, it is advantageous to find routes for removing their production during the upstream phase. In this study, we show how modern proteomic technology can be used to identify and quantify amino acid misincorporation. Using these techniques we have shown how manipulation of gene sequence and scoping of fermentation media composition can lead to the reduction and elimination of these misincorporations in rhTRX.