Hydration of protein-protein interfaces

We present an analysis of the water molecules immobilized at the protein-protein interfaces of 115 homodimeric proteins and 46 protein-protein complexes, and compare them with 173 large crystal packing interfaces representing nonspecific interactions. With an average of 15 waters per 1000 A2 of interface area, the crystal packing interfaces are more hydrated than the specific interfaces of homodimers and complexes, which have 10-11 waters per 1000 A2, reflecting the more hydrophilic composition of crystal packing interfaces. Very different patterns of hydration are observed: Water molecules may form a ring around interfaces that remain "dry," or they may permeate "wet" interfaces. A majority of the specific interfaces are dry and most of the crystal packing interfaces are wet, but counterexamples exist in both categories. Water molecules at interfaces form hydrogen bonds with protein groups, with a preference for the main-chain carbonyl and the charged side-chains of Glu, Asp, and Arg. These interactions are essentially the same in specific and nonspecific interfaces, and very similar to those observed elsewhere on the protein surface. Water-mediated polar interactions are as abundant at the interfaces as direct protein-protein hydrogen bonds, and they may contribute to the stability of the assembly.     

Immobilization of cross-linked tannase enzyme on multiwalled carbon nanotubes and its catalytic behavior

Immobilization of cross-linked tannase on pristine multiwalled carbon nanotubes (MWCNT) was successfully performed. Cross-linking of tannase molecules was made through glutaraldehyde. The immobilized tannase exhibited significantly improved pH, thermal, and recycling stability. The optimal pH for both free and immobilized tannase was observed at pH 5.0 with optimal operating temperature at 30°C. Moreover, immobilized enzyme retained greater biocatalytic activities upon 10 repeated uses compared to free enzyme in solution. Immobilization of tannase was accomplished by strong hydrophobic interaction most likely between hydrophobic amino acid moieties of the glutaraldehyde-cross-linked tannase to the MWCNT.     

Immobilization of Bacillus licheniformis α-amylase onto reactive polymer films

Alpha-amylase was covalently immobilized onto maleic anhydride copolymer films preserving activity. The initial activity of the immobilized layers strongly depended on the immobilization solution, and on the physicochemical properties of the copolymer film. Higher enzyme loading (quantified by amino acid analysis using HPLC) and activity (measured by following starch hydrolysis) were attainable onto hydrophilic, highly swelling 3-D poly(ethylene-alt-maleic anhydride) (PEMA) copolymer films, while immobilization onto hydrophobic poly(octadecene-alt-maleic anhydride) (POMA) copolymer films resulted in low content enzyme layers and lower activity. No significant activity was lost upon dehydration/re-hydration or storage of enzyme containing PEMA copolymer layers in deionised water for up to 48 h. In contrast, α-amylase decorated POMA films suffered a significant activity loss under those conditions. The distinct behaviours may be attributed to the different intrinsic physicochemical properties of the copolymer films. The compact, hydrophobic POMA films possibly favours hydrophobic interactions between the hydrophobic moieties of the protein and the surface, which may result in conformational changes, and consequent loss of activity. Surprisingly, residual activity was found after harsh treatments of active α-amylase PEMA based layers revealing that immobilization onto the hydrophilic polymer films improved the stability of the enzyme.     

Atomic force microscopy imaging of DNA covalently immobilized on a functionalized mica substrate.

A procedure for covalent binding of DNA to a functionalized mica substrate is described. The approach is based on photochemical cross-linking of DNA to immobilized psoralen derivatives. A tetrafluorphenyl (TFP) ester of trimethyl psoralen (trioxalen) was synthesized, and the procedure to immobilize it onto a functionalized aminopropyl mica surface (AP-mica) was developed. DNA molecules were cross-linked to trioxalen moieties by UV irradiation of complexes. The steps of the sample preparation procedure were analyzed with x-ray photoelectron spectroscopy (XPS). Results from XPS show that an AP-mica surface can be formed by vapor phase deposition of silane and that this surface can be derivatized with trioxalen. The derivatized surface is capable of binding of DNA molecules such that, after UV cross-linking, they withstand a thorough rinsing with SDS. Observations with atomic force microscopy showed that derivatized surfaces remain smooth, so DNA molecules are easily visualized. Linear and circular DNA molecules were photochemically immobilized on the surface. The molecules are distributed over the surface uniformly, indicating rather even modification of AP-mica with trioxalen. Generally, the shapes of supercoiled molecules electrostatically immobilized on AP-mica and those photocross-linked on trioxalen-functionalized surfaces remain quite similar. This suggests that UV cross-linking does not induce formation of a noticeable number of single-stranded breaks in DNA molecules.     

Solid-phase extraction of N-linked glycopeptides

Protein glycosylation is a common post-translational modification and has been increasingly recognized as one of the most prominent biochemical alterations associated with malignant transformation and tumorigenesis. N-linked glycosylation is prevalent in proteins on the extracellular membrane, and many clinical biomarkers and therapeutic targets are glycoproteins. Here, we describe a protocol for solid-phase extraction of N-linked glycopeptides and subsequent identification of N-linked glycosylation sites (N-glycosites) by tandem mass spectrometry. The method oxidizes the carbohydrates in glycopeptides into aldehydes, which can be immobilized on a solid support. The N-linked glycopeptides are then optionally labeled with a stable isotope using deuterium-labeled succinic anhydride and the peptide moieties are released by peptide-N-glycosidase. In a single analysis, the method identifies hundreds of N-linked glycoproteins, the site(s) of N-linked glycosylation and the relative quantity of the identified glycopeptides.     

A novel method for the incorporation of glycoprotein-derived oligosaccharides into neoglycopeptides.

We describe a new method for the transfer of carbohydrate moieties to polypeptides in which complex carbohydrate, in the form of glycosyl amino acid, is removed from an available glycoprotein, derivatized, and reacted with a polypeptide via an iodoacetylated alpha-amino group. A family of oligomannose chains, N-linked to the side chain of Asn, was obtained from ovalbumin by pronase digestion and purified as previously described. A reactive sulfhydryl group was specifically placed on these molecules by reaction of 2-iminothiolane with the Asn alpha-amino group. Separately, the alpha-amino group of the peptide GGYR was specifically iodoacetylated by reaction with iodoacetic anhydride at pH 6. Reaction of the thiol-containing carbohydrate with iodoacetylated peptide at pH 8 gave in high yield the corresponding oligomannosyl-peptides, whose structures were confirmed by mass spectrometry. A peptide inhibitor of HIV protease was also oligomannosylated by this procedure. The principle advantage of this method is the efficiency of the reaction even when performed with stoichiometric amounts of the two molecules at low concentration. It should be feasible to extend this chemistry to larger polypeptides.     

Carbonic anhydrase inhibitors: synthesis and inhibition against isozymes I, II and IV of topically acting antiglaucoma sulfonamides incorporating cis-5-norbornene-endo-3-carboxy-2-carboxamido moieties

Sulfonamides incorporating cis-5-norbornene-endo-3-carboxy-2-carboxamido moieties in their molecules were prepared by reaction of cis-5-norbornene-endo-2,3-dicarboxylic anhydride with aromatic/heterocyclic sulfonamides possessing free amino, hydrazino, or imino groups. Some of these compounds showed very good CA II and CA IV inhibitory properties, with affinities for the enzymes in the low nanomolar range. Some of the most active CA II inhibitors reported here have been formulated as aqueous solutions for topical administration as antiglaucoma agents in normotensive rabbits. Some of the derivatives incorporating cis-5-norbornene-endo-3-carboxy-2-carboxamido and aromatic sulfonamide moieties (as sodium salts) showed effective and longer lasting intraocular pressure (IOP) lowering as compared to dorzolamide, a widely used topical antiglaucoma drug. Compounds incorporating cis-5-norbornene-endo-2,3-carboximido moieties, although stronger in vitro CA inhibitors as compared to the corresponding cis-5-norbornene-endo-3-carboxy-2-carboxamido-;derivatives, showed no topical IOP lowering properties, probably due to their very poor water solubility.     

Immobilized phospholipase A2 from cobra venom. Prevention of substrate interfacial and activator effects

The activation of cobra venom phospholipase A2 by activators (containing phosphorylcholine moieties) appears to depend upon the aggregation state of the enzyme, and the presence of a lipid-water interface. The characteristics of this activation were studied by comparing the behavior of the enzyme immobilized on an agarose gel to that of the soluble enzyme. The immobilized enzyme displays only a few per cent of the soluble enzyme activity toward micellar dipalmitoyl-phosphatidylcholine (PC). However, the relative loss of activity is much less with micellar dipalmitoylphosphatidylethanolamine or soluble diheptanoyl-PC. The affinity for Ca2+ is increased about 10-fold by immobilization while the apparent pKa of the enzyme is decreased by 0.5-0.8 pH units. Activation energies are similar for the two enzyme forms and are independent of the physical state of the substrate used. Catalytic constants of the enzyme toward monomeric PC are not changed by immobilization. Yet, activators of the soluble enzyme have negligible effect on the immobilized enzyme, either in the presence or absence of an interface. Monomeric activators promote the binding of the soluble enzyme to the immobilized form. Apparently, immobilization mainly produces monomerically constrained enzyme which cannot be activated under any condition, whereas normally, activators in the presence of lipid-water interfaces induce the formation of enzyme dimers or possibly higher order aggregates.     

Application of immobilized lipase to regio-specific interesterification of triglyceride in organic solvent

Summary Lipase from Rhizopus delemar was immobilized by entrapment with photo-crosslinkable resin prepolymers or urethane prepolymers or by binding to various types of porous silica beads. The immobilized lipase preparations thus obtained were examined for their activity in converting olive oil to an interesterified fat (cacao butter-like fat), whose oleic acid moieties at 1- and 3-positions were replaced with stearic acid moieties, in the reaction solvent n-hexane. Although all of the immobilized preparations exhibited some activity, lipase adsorbed on Celite and then entrapped with a hydrophobic photo-crosslinkable resin prepolymer showed the highest activity, about 75% of that of lipase simply adsorbed onto Celite. Entrapment markedly enhanced the operational stability of lipase.Dedicated to Professor H. Holzer, Freiburg University, on his 60th birthday (June 13, 1981)     

Engineered fusion molecules at chelator lipid interfaces imaged by reflection interference contrast microscopy (RICM)

In molecular biology, biotechnology, and protein-engineering, the expression of histidine fusion proteins is a very powerful technique for the identification and one-step purification based on the interaction of the histidine stretch with immobilized metal complexes. By synthesis of a novel class of chelator lipids, this technique was combined with the concept of self-assembly leading to interfaces for immobilization and orientation of histidine-tagged biomolecules (Schmitt et al., 1994). Here, these chelator lipid layers were transferred onto solid substrate by vesicle fusion and Langmuir-Blodgett-techniques. Specific binding of a peptide containing an oligohistidine sequence to these functionalized interfaces was demonstrated by reflection interference contrast microscopy (RICM). Due to the phase separation behaviour of lipid mixtures, the chelator lipid interface could be further structured in two dimensions. Binding and organization of histidine-tagged molecules at these two-dimensional recognition arrays was imaged by RICM with a layer thickness resolution of 0·2 nm, and 0·5 μm laterally. Specific docking can be triggered by adding nickel ions and disrupted by EDTA. This concept opens up possibilities for reversible immobilization, enrichment and organization of histidine fusion proteins at interfaces and their application in biosensing.     

Activation of human T4 cells by cross-linking class I MHC molecules

These studies examined whether cross-linking class I MHC molecules results in functional or biochemical responses in human T4 cells. The initial studies demonstrated that cross-linking class I MHC molecules either by culturing highly purified T4 cells with immobilized mAb to class I MHC Ag or reacting the T4 cells with mAb to class I MHC Ag and then cross-linking the mAb with goat antimouse Ig (GaMIg) enhanced T4 cell proliferation induced by an immobilized mAb to CD3, OKT3. More-over, immobilized but not soluble mAb to class I MHC Ag enhanced T4 cell proliferation induced by the combination of two mAb to CD2, OKT11, and D66.2. Finally, T4 cells reacted with mAb to CD3 and class I MHC Ag proliferated in the presence of IL-2 when cross-linked with GaMIg more vigorously than T4 cells reacted with either mAb alone. Cross-linking class I MHC molecules was also found to stimulate T4 cells directly. T4 cells reacted with mAb to class I MHC Ag or beta 2 microglobulin and cross-linked with GaMIg proliferated vigorously in the presence of IL-2 or PMA. In addition, it was demonstrated that cross-linking class I MHC molecules by culturing T4 cells with immobilized mAb to class I MHC Ag induced T4 cell proliferation in the presence of IL-2. T4 cell proliferation in the presence of IL-2 and PMA could also be induced by reacting the cells with specific mAb to polymorphic determinants on class I MHC molecules and cross-linking with GaMIg. Cross-linking mAb to CD4 or CD11a did not have a similar functional effect on T4 cells. Finally it was demonstrated that adding GaMIg to T4 cells reacted with mAb to class I MHC Ag but not CD11a resulted in an increase in intracellular calcium concentration. The data demonstrate that cross-linking class I MHC molecules results in the generation of at least one activation signal, a rise in intracellular calcium concentration, and, thereby, stimulates human T4 cells.     

New antibody immobilization method via functional liposome layer for specific protein assays

A specific protein assay system based on functional liposome-modified gold electrodes has been demonstrated. To fabricate such assay system, a liposome layer was initially grown on top of a gold layer. The liposome layer contained two kinds of functional molecules: biotin molecules for the binding sites of streptavidin and N-(10,12-pentacosadiynoic)-acetylferrocene molecules for the facile redox probe in electrochemical detections. Then, streptavidin was attached on the functional liposme-modified layer using the interaction of streptavidin-sbiotin complex. On the streptavidin-attached surface, antibody molecules, anti-human serum albumin antibodies could be immobilized without any secondary antibodies. AFM imaging of the streptavidin-attached liposome surface revealed a uniform distribution of closely packed streptavidin molecules. In situ quartz-crystal microbalance and electrochemical measurements demonstrated that the wanted antibody-antigen reactions should occur with high specificity and selectivity. Our specific antibody assay system, based on a functional liposome modified electrode, can be developed further to yield sophisticated structures for numerous protein chips and immunoassay sensors.     

Biocatalyst engineering exerts a dramatic effect on selectivity of hydrolysis catalyzed by immobilized lipases in aqueous medium

It has been found that enantioselectivity of lipases is strongly modified when their immobilization is performed by involving different areas of the enzyme surface, by promoting a different degree of multipoint covalent immobilization or by creating different environments surrounding different enzyme areas. Moreover, selectivity of some immobilized enzyme molecules was much more modulated by the experimental conditions than other derivatives. Thus, some immobilized derivatives of Candida rugosa (CRL) and C. antarctica-B (CABL) lipases are hardly enantioselective in the hydrolysis of chiral esters of (R,S)-mandelic acid under standard conditions (pH 7.0 and 25°C) (E<2). However, other derivatives of the same enzymes exhibited a very good enantioselectivity under nonstandard conditions. For example, CRL adsorbed on PEI-coated supports showed a very high enantio-preference towards S-isomer (E=200) at pH 5. On the other hand, CABL adsorbed on octyl-agarose showed an interesting enantio-preference towards the R-isomer (E=25) at pH 5 and 4°C. These biotransformations are catalyzed by isolated lipase molecules acting on fully soluble substrates and in the absence of interfacial activation against external hydrophobic interfaces. Under these conditions, lipase catalysis may be associated to important conformational changes that can be strongly modulated via biocatalyst and biotransformation engineering. In this way, selective biotransformations catalyzed by immobilized lipases in macro-aqueous systems can be easily modulated by designing different immobilized derivatives and reaction conditions.     

Thiol-directed immobilization of recombinant IgG-binding receptors

A genetic engineering approach is described for directed immobilization of IgG-binding receptors to a thiol-containing matrix using a single cysteine residue. The cysteine residue is introduced into the C-terminal part of receptors based on staphylococcal protein A. Receptors containing one, two or five IgG-binding domains were produced in Escherichia coli and subsequently immobilized on thiopropyl-Sepharose. A high amount, 5 mumol/ml gel (45 mg/ml), of recombinant receptor could be rapidly immobilized to the solid support and both the gel and the immobilized receptor could be regenerated by reduction and oxidation reactions. The gel was used for affinity purification of human IgG and analysis of IgG-binding capacity at different amounts of immobilized recombinant protein show the same maximal IgG-binding capacity (20-25 mg/ml) for all three immobilized receptors. However, at low substitution grade of receptors, the immobilized receptor molecules were shown to bind one (Z-Cys) and two (ZZ-Cys) IgG molecules, respectively. These results demonstrate that the immobilized protein molecules are in a functionally active form and that a two-domain receptor can bind two molecules of IgG without steric hindrance. Interestingly, the five-domain receptor (ZV-Cys), with a structure similar to native protein A, can only bind approximately two IgG molecules, despite the five-domain structure of the molecule.     

Anhydride Prodrug of Ibuprofen and Acrylic Polymers

The objective of this study was to synthesize anhydride prodrugs for carboxylic-acid-bearing agents such as non-steroidal anti-inflammatory drugs, shield the carboxylic acid group from irritative effects, and obtain sustained release patterns. Ibuprofen was used as a representative drug for anhydride derivatization. Conjugates of ibuprofen with carboxylic acid moieties of different acrylic polymers were prepared by dehydration reaction using acetic anhydride. Products were characterized by infrared spectroscopy, nuclear magnetic resonance, and scanning electron microscopy followed by preparation of microspheres with different sizes from the conjugate Eudragit® L-100-ibuprofen. The drug release was monitored by high-performance liquid chromatography. Ibuprofen was bound to the polymers via an anhydride bond in high reaction yields (75–95%) with drug loading of up to 30% (w/w). These anhydride derivatives hydrolyzed and release the drug at different periods ranging from 1 to 5 days, depending on the hydrophobicity and the cross-linking of the conjugates. The release of drug from the microspheres was correlated to their size and ranged from 2 to almost 8 days. This study demonstrates the promise of anhydride prodrug for extending drug action while shielding the carboxylic acid group.     

Carboxypeptidase a immobilization on activated styrene-maleic anhydride systems

The copolymer styrene-maleic anhydride (SMA) was activated to various forms to create enzyme coupling groups. Carboxypeptidase A (CPA) was Immobilized on these supports to enhance their thermal and chemical stability. Immobilized enzyme retained 60-70% of the original activity. When kept at 60 degrees C, while free enzyme was deactivated within 30 min, the immobilized enzyme retained 40% of initial activity at the end of 3 h. The half-life of free enzyme was only 21 min, while for immobilized enzyme it was enhanced up to 3 h. Also, the immobilized enzyme could be repeatedly used over 50 times retaining almost 50% of original activity.     

A bifunctional monolithic column for combined protein preconcentration and digestion for high throughput proteomics research

Enzymatic digestion of proteins is a key step in protein identification by mass spectrometry (MS). Traditional solution-based protein digestion methods require long incubation times and are limitations for high throughput proteomics research. Recently, solid phase digestion (e.g. trypsin immobilization on solid supports) has become a useful strategy to accelerate the speed of protein digestion and eliminate autodigestion by immobilizing and isolating the enzyme moieties on solid supports. Monolithic media is an attractive support for immobilization of enzymes due to its unique properties that include fast mass transfer, stability in most solvents, and versatility of functional groups on the surfaces of monoliths. We prepared immobilized trypsin monolithic capillaries for on-column protein digestion, analyzed the digested peptides through LC/FTICR tandem MS, and compared peptide mass fingerprinting by MALDI-TOF-MS. To further improve the digestion efficiency for low abundance proteins, we introduced C4 functional groups onto the monolith surfaces to combine on-column protein enrichment and digestion. Compared with immobilized trypsin monolithic capillaries without C4, the immobilized trypsin-C4 monolith showed improved digestion efficiency. A mechanism for increased efficiency from the combination of sample enrichment and on-column digestion is also proposed in this paper. Moreover, we investigated the effects of organic solvent on digestion and detection by comparing the observed digested peptide sequences. Our data demonstrated that all columns showed good tolerance to organic solvents and maintained reproducible enzymatic activity for at least 30 days.     

Standard atomic volumes in double-stranded DNA and packing in protein--DNA interfaces

Standard volumes for atoms in double-stranded B-DNA are derived using high resolution crystal structures from the Nucleic Acid Database (NDB) and compared with corresponding values derived from crystal structures of small organic compounds in the Cambridge Structural Database (CSD). Two different methods are used to compute these volumes: the classical Voronoi method, which does not depend on the size of atoms, and the related Radical Planes method which does. Results show that atomic groups buried in the interior of double-stranded DNA are, on average, more tightly packed than in related small molecules in the CSD. The packing efficiency of DNA atoms at the interfaces of 25 high resolution protein-DNA complexes is determined by computing the ratios between the volumes of interfacial DNA atoms and the corresponding standard volumes. These ratios are found to be close to unity, indicating that the DNA atoms at protein-DNA interfaces are as closely packed as in crystals of B-DNA. Analogous volume ratios, computed for buried protein atoms, are also near unity, confirming our earlier conclusions that the packing efficiency of these atoms is similar to that in the protein interior. In addition, we examine the number, volume and solvent occupation of cavities located at the protein-DNA interfaces and compared them with those in the protein interior. Cavities are found to be ubiquitous in the interfaces as well as inside the protein moieties. The frequency of solvent occupation of cavities is however higher in the interfaces, indicating that those are more hydrated than protein interiors. Lastly, we compare our results with those obtained using two different measures of shape complementarity of the analysed interfaces, and find that the correlation between our volume ratios and these measures, as well as between the measures themselves, is weak. Our results indicate that a tightly packed environment made up of DNA, protein and solvent atoms plays a significant role in protein-DNA recognition.     

Oriented immobilization of biologically active proteins as a tool for revealing protein interactions and function

The advantages of oriented immobilization of biologically active proteins are good steric accessibilities of active binding sites and increased stability. This not only may help to increase the production of preparative procedures but is likely to promote current knowledge about how the living cells or tissues operate. Protein inactivation starts with the unfolding of the protein molecule by the contact of water with hydrophobic clusters located on the surface of protein molecules, which results in ice-like water structure. Reduction of the nonpolar surface area by the formation of a suitable biospecifc complex or by use of carbohydrate moieties thus may stabilize proteins. This review discusses oriented immobilization of antibodies by use of immobilized protein A or G. The section about oriented immobilization of proteins by use of their suitable antibodies covers immobilization of enzymes utilizing their adsorption on suitable immunosorbents prepared using monoclonal or polyclonal antibodies, preparation of bioaffinity adsorbent for the isolation of concanavalin A and immobilization of antibodies by use of antimouse immunoglobulin G, Fc-specific (i.e. specific towards the constant region of the molecule). In the further section immobilization of antibodies and enzymes through their carbohydrate moieties is described. Oriented immobilization of proteins can be also based on the use of boronate affinity gel or immobilized metal ion affinity chromatography technique. Biotin–avidin or streptavidin techniques are mostly used methods for oriented immobilization. Site-specific attachment of proteins to the surface of solid supports can be also achieved by enzyme, e.g., subtilisin, after introduction a single cysteine residue by site-directed mutagenesis.     

Bridging the electrochemical and biological worlds with hybrid nanocomposites

Recent discoveries arising from a combination of the biological, physical, chemical and materials sciences have resulted in the invention of numerous hybrid molecules that possess strengths inherent to each individual discipline. Nanocomposites that link biological molecules to inorganic moieties have led to a family of new reagents with unique capabilities for cellular imaging and macromolecule detection. A recent report has extended the applications of these hybrid molecules from their use as detection and scaffolding reagents into the realm of a biologically functional molecule.