Structure and function of proteins involved in milk allergies

Allergy to milk proteins has been defined as any adverse reaction mediated by immunological mechanisms to one or several of proteins found in milk. The milk allergy has been classified according to the onset of symptoms as immediate or delayed type. The milk allergy seems to be manifested by three major proteins found in milk: α-lactalbumin, β-lactoglobulin and caseins. The structural comparison of allergenic sites in α-lactalbumin and β-lactoglobulin with the structure of lactoferrin has clearly shown that yet another major milk protein lactoferrin also possesses allergenic sites and thus may qualify to be an allergen. The heat treatment of milk proteins considerably reduces their allergenicity.     

Chemical modifications of tryptophan residues in peptides and proteins

Chemical protein modifications facilitate the investigation of natural posttranslational protein modifications and allow the design of proteins with new functions. Proteins can be modified at a late stage on amino acid side chains by chemical methods. The indole moiety of tryptophan residues is an emerging target of such chemical modification strategies because of its unique reactivity and low abundance. This review provides an overview of the recently developed methods of tryptophan modification at the peptide and protein levels.     

Age-dependent modifications of mitochondrial proteins in cerebral cortex and striatum of rat brain

The protein composition of free mitochondria purified from cerebral cortex and striatum during aging was analyzed by gel electrophoresis. Mitochondria were isolated from cerebral cortex and striatum of 4-, 12-, and 24-month-old rat brain. The percent amount of mitochondrial proteins after gel-electrophoretic separation was determined densitometrically. A significant decrease in the amount of two polypeptides (with molecular weights of 20 and 16 kDa, respectively) in both brain regions during aging was found. The decrease was higher in the striatum indicating a greater vulnerability of this brain area to the aging process. The age-dependent modifications of mitochondrial proteins observed may play an important role in several mitochondrial functions, such as energy transduction and transport processes as well as in structural changes occurring with age, causing altered membrane permeability and fluidity.     

Data requirements for reliable chemical shift assignments in deuterated proteins

The information required for chemical shift assignments in large deuterated proteins was investigated using a Monte Carlo approach (Hitchens et al., 2002). In particular, the consequences of missing amide resonances on the reliability of assignments derived from C and CO or from C and C chemical shifts was investigated. Missing amide resonances reduce both the number of correct assignments as well as the confidence in these assignments. More significantly, a number of undetectable errors can arise when as few as 9% of the amide resonances are missing from the spectra. However, the use of information from residue specific labeling as well as local and long-range distance constraints improves the reliability and extent of assignment. It is also shown that missing residues have only a minor effect on the assignment of protein-ligand complexes using C and CO chemical shifts and C inter-residue connectivity, provided that the known chemical shifts of the unliganded protein are utilized in the assignment process.     

Conformational Isomers of Denatured and Unfolded Proteins: Methods of Production and Applications

Conformational isomers of denatured-unfolded proteins are rich in numbers and varied in shapes. They represent an opulent resource of biological molecules that have remained unexploited. The major obstacle in utilizing this untapped potential is that it is inherently difficult to isolate and characterize pure conformational isomers, not only because of the excessive large number, but also because of their instability and rapid inter-conversion. Our lab has developed a method for trapping selected conformational isomers of denatured proteins that are amenable to isolation, characterization and further applications. The method has potential usefulness, ranging from the comprehensive structural characterization of denatured proteins, to the elucidation of pathways of protein unfolding–folding, to the production of unlimited structurally defined non-native protein isomers for biomedical applications.     

Interactions between bacterial flagellar axial proteins in their monomeric state in solution

The axial structure of the bacterial flagellum is composed of many different proteins, such as hook protein and flagellin, and each protein forms a short or long axial segment one after another in a well-defined order along the axis. Under physiological conditions, most of these proteins are stable in the monomeric state in solution, and spontaneous polymerization appears to be suppressed, as demonstrated clearly for flagellin, probably to avoid undesirable self-assembly in the cytoplasmic space. However, no systematic studies of the possible associations between monomeric axial proteins in solution have been carried out. We therefore studied self and cross-association between hook protein, flagellin and three hook-associated proteins, HAP1, HAP2 and HAP3, in all possible pairs, by gel-filtration and analytical centrifugation, and found interactions in the following two cases only. Flagellin facilitated HAP3 aggregation into beta-amyloid-like filaments, but without stable binding between the two. Addition of HAP3 to HAP2 resulted in disassembly of preformed HAP2 decamers and formation of stable HAP2-HAP3 heterodimers. HAP2 missing either of its disordered terminal regions did not form the heterodimer, whereas HAP3 missing either of its disordered terminal regions showed stable heterodimer formation. This polarity in the heterodimer interactions suggests that the interactions between HAP2 and HAP3 in solution are basically the same as those in the flagellar axial structure. We discuss these results in relation to the assembly mechanism of the flagellum.     

Identification of oxidized plasma proteins in Alzheimer's disease

The modification of proteins by reactive oxygen species is central to the pathology of Alzheimer's disease (AD). Previously, we have observed specific oxidized proteins in blood plasma of AD subjects [Biochem. Biophys. Res. Commun. 275 (2000) 678]. Plasma from AD subjects and age-matched controls was subjected to two-dimensional gel electrophoresis (2-DE). Oxidized proteins with new carbonyl groups were detected by reaction with 2,4-dinitrophenylhydrazine, followed by Western blotting with anti-DNP antibody. Seven principal oxidized protein spots (isoelectric point=4.7-5.5; molecular mass=45-65 kDa) were observed, with varying levels of oxidation in plasma samples from both AD and non-AD subjects. Matrix-assisted laser desorption mass spectroscopy (MALDI-TOF/MS) revealed that these oxidized proteins were isoforms of fibrinogen gamma-chain precursor protein and of alpha-1-antitrypsin precursor. These proteins exhibited a two- to sixfold greater specific oxidation index in plasma from AD subjects when compared to controls. Both these proteins have been previously implicated in the pathology of the disease. It is possible that oxidized isoforms of these proteins may serve as biomarkers for AD.     

Rapid chemical reaction techniques developed for use in investigations of membrane-bound proteins (neurotransmitter receptors)

New techniques for investigating chemical reactions on cell surfaces in the microsecond-to-millisecond time region are described. Reactions mediated by membrane-bound neurotransmitter receptors that control signal transmission between 10¹² cells of the nervous system are taken as an example. Cells with receptors on their plasma membrane are equilibrated with photolabile, biologically inactive precursors of the neurotransmitters. Photolysis of these compounds releases free neurotransmitter that interacts with the receptors, leading to the transient opening of transmembrane receptor-formed channels that are permeant to small inorganic ions. The current thus induced can be measured. The technique can be used to measure the elementary steps of the receptor-mediated reactions. To illustrate the approach it was shown that an understanding of the mechanism of inhibition of the nicotinic acetylcholine receptor by the drug cocaine was obtained and led to the first proof that compounds exist that alleviate the inhibition.     

Lateral organization of proteins in the chromatophore membrane ofRhodospirillum rubrum studied by chemical cross-linking

The organization of proteins in the chromatophore membrane, particularly of the reaction center and the light-harvesting polypeptide, was examined by the use of a hydrophobic and a hydrophilic cross-linking reagent, namely DSP (dithiobis-succinimidyl propionate) and glutaraldehyde. The linkage of proteins was studied by SDS polyacrylamide pore gradient electrophoresis. DSP was shown to link proteins within the core of the membrane. The subunit H of the reaction center is linked with DSP at a low concentration, either with itself or with other membrane proteins but not to the subunits M and L. In isolated reaction centers the subunits H are exclusively linked with each other. With increasing concentrations of DSP the bands of the subunits M, L, and the light-harvesting polypeptide disappear simultaneously from the gel, suggesting that these proteins are linked together. This hypothesis is supported by the finding that reaction centers isolated from chromatophores treated with DSP retain an appreciable amount of light-harvesting polypeptide. With increasing concentrations of the hydrophilic cross-linking reagent glutaraldehyde, the bands of all the three subunits of the reaction center, H, M, and L, progressively disappear from the gel, suggesting that they are linked together. The light-harvesting polypeptide remains free when this reagent is used.     

Expression and interaction of small heat shock proteins (sHsps) in rice in response to heat stress

The inherent immobility of rice (Oryza sativa L.) limited their abilities to avoid heat stress and required them to contend with heat stress through innate defense abilities in which heat shock proteins played important roles. In this study, Hsp26.7, Hsp23.2, Hsp17.9A, Hsp17.4 and Hsp16.9A were up-regulated in Nipponbare during seedling and anthesis stages in response to heat stress. Subsequently, the expressing levels of these five sHsps in the heat-tolerant rice cultivar, Co39, were all significantly higher than that in the heat-susceptible rice cultivar, Azucena. This indicated that the expressive level of these five sHsps was positively related to the ability of rice plants to avoid heat stress. Thus, the expression level of these five sHsps can be regarded as bio-markers for screening rice cultivars with different abilities to avoid heat stress. Hsp18.1, Hsp17.9A, Hsp17.7 and Hsp16.9A, in the three rice cultivars under heat stress were found to be involved in one protein complex by Native-PAGE, and the interactions of Hsp18.1 and Hsp 17.7, Hsp18.1 and Hsp 17.9A, and Hsp17.7 and Hsp16.9A were further validated by yeast 2-hybridization. Pull down assay also confirmed the interaction between Hsp17.7 and Hsp16.9A in rice under heat stress. In conclusion, the up-regulation of the 5 sHsps is a key step for rice to tolerate heat stress, after that some sHsps assembled into a large hetero-oligomeric complex. In addition, through protein–protein interaction, Hsp101 regulated thiamine biosynthesis, and Hsp82 homology affected nitrogen metabolism, while Hsp81-1 were involved in the maintenance of sugar or starch synthesis in rice plants under heat stress. These results provide new insight into the regulatory mechanism of sHsps in rice.     

广谱抗真菌转基因水稻植株化学成分与结构动态变化

【背景】种植广谱抗真菌水稻可能会带来一定的环境生物安全问题,对其植株的化学成分进行实质等同性分析是转基因水稻安全性评价的重要内容之一。【方法】以表达广谱抗真菌蛋白转基因水稻转品1和转品8及其相应非转基因水稻七丝软粘的秸秆为研究材料,采用化学法和扫描电镜技术分析外源基因的导入对水稻秸秆化学成分以及组织显微结构的影响。【结果】（1）在整个生长发育过程中,广谱抗真菌转基因水稻转品1和转品8与其非转基因水稻七丝软粘叶片、叶鞘和茎的纤维素、半纤维素、木质素以及粗蛋白含量的变化趋势基本一致,且品种间化学成分的含量不存在显著差异。（2）广谱抗真菌转基因水稻叶片表皮的硅质瘤状结构以及气孔的形状和致密程度与其非转基因水稻七丝软粘相似;茎壁、厚壁组织、薄壁组织以及大小维管束的形态和分布情况未发生明显变化。【结论与意义】表达广谱抗真菌蛋白转基因水稻秸秆的化学成分和组织显微结构与非转基因水稻基本一致。这为广谱抗真菌转基因水稻的环境安全性评估提供了依据。     

Distinguishing specific and nonspecific interdomain interactions in multidomain proteins

Multidomain proteins account for over two-thirds of the eukaryotic genome. Although there have been extensive studies into the biophysical properties of isolated domains, few have investigated how the domains interact. Spectrin is a well-characterized multidomain protein with domains linked in tandem array by contiguous helices. Several of these domains have been shown to be stabilized by their neighbors. Until now, this stabilization has been attributed to specific interactions between the natural neighbors, however we have recently observed that nonnatural neighboring domains can also induce a significant amount of stabilization. Here we investigate this nonnative stabilizing effect. We created spectrin-titin domain pairs of both spectrin R16 and R17 with a single titin I27 domain at either the N- or the C-terminus and found that spectrin domains are significantly stabilized, through slowed unfolding, by nonnative interactions at the C-terminus only. Of particular importance, we show that specific interactions between natural folded neighbors at either terminus confer even greater stability by additionally increasing the folding rate constants. We demonstrate that it is possible to distinguish between natural stabilizing interactions and nonspecific stabilizing effects through examination of the kinetics of well chosen mutant proteins. This work adds to the complexity of studying multidomain proteins.     

Controlling kinesin motor proteins in nanoengineered systems through a metal-binding on/off switch

A significant challenge in utilizing kinesin biomolecular motors in integrated nanoscale systems is the ability to regulate motor function in vitro. Here we report a versatile mechanism for reversibly controlling the function of kinesin biomolecular motors independent of the fuel supply (ATP). Our approach relied on inhibiting conformational changes in the neck-linker region of kinesin, a process necessary for microtubule transport. We introduced a chemical switch into the neck-linker of kinesin by genetically engineering three histidine residues to create a Zn(2+)-binding site. Gliding motility of microtubules by the mutant kinesin was successfully inhibited by >/=10 microM Zn(2+), as well as other divalent metals. Motility was successfully restored by removal of Zn(2+) using a number of different chelators. Lastly, we demonstrated the robust and cyclic nature of the switch using sequential Zn(2+)/chelator additions. Overall, this approach to controlling motor function is highly advantageous as it enables control of individual classes of biomolecular motors while maintaining a consistent level of fuel for all motors in a given system or device.     

Evaluation of compositional nonrandomness in proteins

Summary Cornish-Bowden and Marson have recently suggested that the finite sampling component of Q, a measure of nonrandomness in the amino acid composition of proteins, may have been underestimated because it was calculated on the basis of the genetic code table frequencies rather than on the basis of the average natural abundance with which the twenty amino acids actually occur in proteins. This underestimate would lead to an overestimate of Q_c a measure of selective effects above and beyond those imposed by the average natural abundance of the amino acids. In this paper the finite sampling component of Q is quantitatively estimated on the basis of these natural abundances and found to reduce Q_c from its previous average value of 24.3 to the lower value of 9.7, with the standard deviation of the population of Q_c values being 12.5. Individual Q_c values are given for 81 protein families of mean composition per 61 codons of Ala_5.3 Arg_2.4 Asn_3.0 Asp_3.6 Cys_1.5 Gln_2.6 Glu_3.5 Gly_4.7 His_1.3 Ile_3.4 Leu_4.5 Lys_4.2 Met_1.0 Phe_2.3 Pro_2.3 Ser_4.2 Thr_3.6 Trp_0.8 Tyr_2.6 Val_4.2. The mean Q_c value of 9.7 is notably small, and indicates that quantitatively minimal adjustments away from the average protein composition are necessary to maintain many different biological functions. This small value, however, is shown to differ significantly from the value of zero expected were the natural abundances of the amino acids the only selective constraint. These small deviations from the natural abundances are thus effectively selected for in the Darwinian sense.     

Molecular determinants for ATP-binding in proteins: a data mining and quantum chemical analysis

Adenosine 5'-triphosphate (ATP) plays an essential role in all forms of life. Molecular recognition of ATP in proteins is a subject of great importance for understanding enzymatic mechanism and for drug design. We have carried out a large-scale data mining of the Protein Data Bank (PDB) to analyze molecular determinants for recognition of the adenine moiety of ATP by proteins. Non-bonded intermolecular interactions (hydrogen bonding, pi-pi stacking interactions, and cation-pi interactions) between adenine base and surrounding residues in its binding pockets are systematically analyzed for 68 non-redundant, high-resolution crystal structures of adenylate-binding proteins. In addition to confirming the importance of the widely known hydrogen bonding, we found out that cation-pi interactions between adenine base and positively charged residues (Lys and Arg) and pi-pi stacking interactions between adenine base and surrounding aromatic residues (Phe, Tyr, Trp) are also crucial for adenine binding in proteins. On average, there exist 2.7 hydrogen bonding interactions, 1.0 pi-pi stacking interactions, and 0.8 cation-pi interactions in each adenylate-binding protein complex. Furthermore, a high-level quantum chemical analysis was performed to analyze contributions of each of the three forms of intermolecular interactions (i.e. hydrogen bonding, pi-pi stacking interactions, and cation-pi interactions) to the overall binding force of the adenine moiety of ATP in proteins. Intermolecular interaction energies for representative configurations of intermolecular complexes were analyzed using the supermolecular approach at the MP2/6-311 + G* level, which resulted in substantial interaction strengths for all the three forms of intermolecular interactions. This work represents a timely undertaking at a historical moment when a large number of X-ray crystallographic structures of proteins with bound ATP ligands have become available, and when high-level quantum chemical analysis of intermolecular interactions of large biomolecular systems becomes computationally feasible. The establishment of the molecular basis for recognition of the adenine moiety of ATP in proteins will directly impact molecular design of ATP-binding site targeted enzyme inhibitors such as kinase inhibitors.     

Prediction of the location of structural domains in globular proteins

The location of structural domains in proteins is predicted from the amino acid sequence, based on the analysis of a computed contact map for the protein, the average distance map (ADM). Interactions between residues i and j in a protein are subdivided into several ranges, according to the separation |i-j| in the amino acid sequence. Within each range, average spatial distances between every pair of amino acid residues are computed from a data base of known protein structures. Infrequently occurring pairs are omitted as being statistically insignificant. The average distances are used to construct a predicted ADM. The ADM is analyzed for the occurrence of regions with high densities of contacts (compact regions). Locations of rapid changes of density between various parts of the map are determined by the use of scanning plots of contact densities. These locations serve to pinpoint the distribution of compact regions. This distribution, in turn, is used to predict boundaries of domains in the protein. The technique provides an objective method for the location of domains both on a contact map derived from a known three-dimensional protein structure, the real distance map (RDM), and on an ADM. While most other published methods for the identification of domains locate them in the known three-dimensional structure of a protein, the technique presented here also permits the prediction of domains in proteins of unknown spatial structure, as the construction of the ADM for a given protein requires knowledge of only its amino acid sequence.