Formation of Fine Oil-in-Water Emulsions by the Gel Emulsification Method with Saccharide and Protein

An emulsification method using a gel-like phase of a saccharide and protein mixture has been developed. In the method, which is called a gel emulsification method, an oil is added to the highly concentrated saccharide solution containing protein to form a clear gel-like phase, which followed by dilution with water to form a fine oil-in-water emulsion. This emulsion was investigated as to its emulsifying activity and emulsion stability as compared with that obtained by high-shear equipment, which was called a homomixer method. The emulsifying activity of the emulsions prepared by the gel emulsification method was much higher than that of the emulsions prepared by the homomixer method.

The emulsions prepared by both methods were highly stable in terms of the stability against coalescence. On the other hand, the stability against creaming of the emulsions prepared by the gel emulsification method was much higher than that of the emulsions prepared by the homomixer method.

The surface hydrophobicity of the protein and the unfreezable water content in the highly concentrated saccharide solution containing protein were not correlated to the emulsifying properties of the emulsions prepared by the gel emulsification method, which appeared to be dependent on the viscosity of the highly concentrated saccharide solution containing protein.     

Metal Ion Binding and Conformational Transitions in Concanavalin A: A Structure-Function Study

Abstract

The affinity of the lectin Concanavalin A (Con A) for saccharides, and its requirement for metal ions such as Mn²⁺ and Ca²⁺, have been known for about 50 years. However the relationship between metal ion binding and the saccharide binding activity of Con A has only recently been examined in detail. Brown et al. (Biochemistry 16, 3883 (1977)) showed that Con A exists as a mixture of two conformational states: a “locked” form and an “unlocked” form. The unlocked form of the protein weakly binds metal ions and saccharide, and is the predominate conformation of demetallized Con A (apo-Con A) at equilibrium. The locked form binds two metal ions per monomer with the resulting complex(es) possessing full saccharide binding activity. Brown and coworkers measured the kinetics of the transition of the unlocked form to the fully metallized locked conformation containing Mn²⁺and Ca²⁺. They also demonstrated that Mn²⁺ alone could form a locked ternary complex with Con A, and that rapid removal of the ions resulted in a metastable form of apo-Con A in the locked conformation which slowly (hours at 25°C) reverted back to (predominantly) the unlocked conformation. The ability to form either conformation in the absence or presence of metal ions has thus allowed us to explore the relationship between metal ion binding and conformational transitions in Con A as determinants of the saccharide binding activity of the lectin.

Based on the kinetics of the transition of unlocked apo-Con A to fully metallized locked Con A, and X-ray crystallographic data, it appears that the transition between the two conformations of Con A involves a cis-trans isomerization of an Ala-Asp peptide bond in the backbone of the protein, near one of the two metal ion binding sites. The relatively large activation energy for the transition (～ 22 kcal M^?1) results in relatively slow interconversions between the conformations (from minutes to days), whereas the equilibria with metal ions and saccharide are rapid. Thus, many metastable complexes can be formed and a variety of transition pathways between the two conformations studied.

We have identified and characterized binary, ternary, and quaternary complexes of both conformations of Con A containing Mn²⁺ and saccharide, and have determined both metalion and saccharide dissociation constants for all of them, as well as equilibrium and kinetic values for the conformational transitions between them. The main finding is that saccharide binds very weakly (K_d～2 M) to unlocked apo-Con A and very tightly to the locked ternary Mn²⁺-Con A complex (K_d～ 10^?4 M). Saccharide binding increases along the various pathways connecting these two species in a nonadditive fashion. Thus, both conformation and metal ion binding determine the saccharide affinity of each complex, although the specificity of saccharide binding of the various species is maintained throughout.     

Glucosylation of membrane-bound proteins by lipid-linked glucose

Particulate preparations from Pisum sativum. were able to incorporate [¹⁴C]glucose from UDP-[¹⁴C]glucose into oligosaccharide-linked lipids was formed by an oligosaccharide chain containing 7-8 glucose residues linked to dolichol, presumably via a pyrophosphate. The polymer was identified as a membrane-bound glucoprotein that could be solubilized by Triton X-100. SDS gel electrophoresis showed that a polypeptide with an apparent molecular weight of 13,000 could be glucosylated from dolichyl-phosphate-glucose. This was coincident with the electrophoretic mobility of the subunit of the pea lectin in the same system. The glucosylated protein was solubilized from the membranes by sonication and showed the same carbohydrate-binding ability as pea lectins. These results strongly suggest that pea lectins can be glucosylated by the lipid intermediate pathway.Abbreviations BSA Bovine serum albumin - Dol dolichol - SDS sodium dodecyl sulfate     

Solubilization and Sedimentation Analysis of Muscarinic Acetylcholine Receptors

Abstract

To investigate if G-protein-receptor interactions can be characterized using sucrose density gradients (SDG) we have determined the experimental conditions for muscarinic acetylcholine receptor (mAChR) solubilization and analysis on SDG. Solubilization of 65–80% of [³H]QNB bound mAChR was accomplished with 1% of detergent. Analysis of solubilized receptors on SDG containing 0.4M KCl and 0.1% detergent demonstrated that the physical properties of the receptor-detergent complexes are influenced by the solubilizing detergent as well as detergents included in the SDG. Neither GTPγS nor NaF and AlCl₃ altered the sedimentation properties of mAChR, suggesting that the solubilized mAChR is no longer associated with G-protein under these conditions. Receptors bound to [³H]oxotremorine and [³H]QNB had similar sedimentation properties, suggesting that, once solubilized, mAChRs do not remain associated with G-proteins. Covalent labeling with [³H]PrBCM followed by solubilization and analysis on SDS-gel electrophoresis demonstrated the presence of intact receptor molecule. These observations suggest that the changes in the sedimentation properties of detergent-receptor complexes are independent of G-protein interactions and are influenced by the nature of the detergent associated with the mAChR during analysis.     

DSC Measurement of Frozen Water in Liquid Foods

We investigated the state of water in frozen liquid foods, supposed to influence the performance of freeze-drying, by DSC. The amount of unfreezable water in milk was constant irrespective of the initial water content. As expected from the phase equilibrium, the water content of the non-ice part of CAS was constant among the samples with different initial water contents. The volume fraction of ice crystals, which should be known in the analysis of the freeze-drying rate, was significantly smaller at the low initial water content than the one usually estimated with the assumption that the water was all freezable.     

Solvent-free lipase-catalysed synthesis of saccharide-fatty acid esters: closed-loop bioreactor system with in situ formation of metastable suspensions

Abstract

Saccharide-fatty acid esters – biodegradable, biocompatible and non-ionic bio-based surfactants derived from inexpensive renewable agricultural sources, utilized in foods, cosmetics and pharmaceuticals, have been synthesized under solvent-free conditions using a closed-loop system operated under continuous recirculation consisting of a reservoir, a peristaltic pump and a packed-bed bioreactor containing immobilized Rhizomucor miehei lipase (RML). Metastable suspensions of saccharide crystals were formed through continuous stirring in the reservoir with an in-line filter of 180 µm normal size preventing larger crystals from clogging the tubing. The initial reaction medium consisted of oleic acid/fructose-oleic acid esters 95/5 w/w, with saccharide added periodically to the reservoir to replace consumed acyl acceptor substrate. The liquid-phase water concentration was retained at a previously determined optimal value of ～0.4 wt % through free evaporation of the co-product, water, in the reservoir during the initial phase of the reaction, and N₂(g) bubbling and vacuum pressure after 40 h of reaction. After 200 h, the reaction mixture contained 84 wt % ester, of which 90% of the ester consisted of monoester. Equivalently, the productivity was 0.195 mmol_Ester h^??1 g_RML^??1. The resultant technical grade product can potentially be used directly, without further purification. A mathematical model based on mass balances and a zeroth-order kinetic model was successfully developed to predict the concentration of substrates (oleic acid and saccharide) in the reservoir during the time course of reaction.     

The structure of the carbohydrate units of the carboxyl-terminal peptide of procollagen as elucidated by 500 MHz 1H-NMR spectroscopy

The oligosaccharides of chick embryo type I procollagen were isolated from the carboxyl-terminal propeptide fragment by exhaustive digestion with papain and pronase, and then purified as a mixture of glycopeptides. The structures of the oligosaccharides were established by high-resolution ¹H-NMR spectroscopy and found to be a mixture with respect to the non-reducing terminal residues as shown below:

The percentages refer to the relative amount of those mannose residues present in the mixture. The data suggest that the oligosaccharides are a microheterogeneous mixture of high-mannose type glycans containing between six and nine mannose residues per carbohydrate unit. Such carbohydrate chains, although not uncommon for glycoproteins, had never been found before for collagen or collagen-related compounds.     

Solubilization of lipids from hamster bile-canalicular and contiguous membranes and from human erythrocyte membranes by conjugated bile salts.

We have demonstrated in vitro the efficacy of the taurine-conjugated dihydroxy bile salts deoxycholate and chenodeoxycholate in solubilizing both cholesterol and phospholipid from hamster liver bile-canalicular and contiguous membranes and from human erythrocyte membrane. On the other hand, the dihydroxy bile salt ursodeoxycholate and the trihydroxy bile salt cholate solubilize much less lipid. The lipid solubilization by the four bile salts correlated well with their hydrophobicity: glycochenodeoxycolate, which is more hydrophobic than the tauro derivative, also solubilized more lipid. All the dihydroxy bile salts have a threshold concentration above which lipid solubilization increases rapidly; this correlates approximately with the critical micellar concentration. The non-micelle-forming bile salt dehydrocholate solubilized no lipid at all up to 32 mM. All the dihydroxy bile acids are much more efficient at solubilizing phospholipid than cholesterol. Cholate does not show such a pronounced discrimination. Lipid solubilization by chenodeoxycholate was essentially complete within 1 min, whereas that by cholate was linear up to 5 min. Maximal lipid solubilization with chenodeoxycholate occurred at 8-12 mM; solubilization by cholate was linear up to 32 mM. Ursodeoxycholate was the only dihydroxy bile salt which was able to solubilize phospholipid (although not cholesterol) below the critical micellar concentration. This similarity between cholate and ursodeoxycholate may reflect their ability to form a more extensive liquid-crystal system. Membrane specificity was demonstrated only inasmuch as the lower the cholesterol/phospholipid ratio in the membrane, the greater the fractional solubilization of cholesterol by bile salts, i.e. the total amount of cholesterol solubilized depended only on the bile-salt concentration. On the other hand, the total amount of phospholipid solubilized decreased with increasing cholesterol/phospholipid ratio in the membrane.     

Mechanism of protein extraction from the solid state by water-in-oil microemulsions

The extraction of solid-phase alpha-chymotrypsin, bovine serum albumin (BSA), and lysozyme by water-in-oil microemulsion (w/o-ME) solution containing Aerosol-OT (AOT) was thoroughly examined as a means to maximize protein solubilization in organic solvent media. Protein extraction occurred simultaneously with the adsorption of water and AOT by the solid protein. Water and AOT were desorbed at nearly equal rates, suggesting that both materials were desorbed together as micreomulsions. The solubilization of protein increased linearly with the ratio of solid protein to extractant solution except at a high value of the ratio, where most protein-containing microemulsions were desorbed. Based on our results, a mechanistic model was developed to describe the solid-phase extraction procedure. First, microemulsions are desorbed from solution by the solid protein, resulting in the formation of a solid protein-AOT-water aggregate. Second, when a protein in the solid phase binds to a sufficient number of microemulsions, the resulting aggregate's increased hydrophobicity drives its solubilization into lipophilic solvent. Third, through the exchange of materials between the solubilized precipitate and the remaining microemulsions, protein-containing w/o-MEs are formed. The presence of adsorption is further indicated by an isotherm existing between the water, AOT, and protein content of the resulting solid phase for each protein. The driving force behind adsorption is either AOT-protein interactions or the protein's affinity for microemulsion-encapsulated water, depending on the properties of the protein and the size of the microemulsions, in agreement with the model of P. L. Luisi [Chimia, 44: 270-282 (1990)]. The second step of our model is mass transfer limited for the extraction of solid alpha-chymotrypsin and BSA. The extraction of solid lysozyme was limited by the occurrence of an irreversible precipitation process. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 53: 583-593, 1997.     

Location of sugars in barley seeds during germination by NMR microscopy

The distribution and fluctuation of sugars in germinating barley seeds were examined by ¹³C nuclear magnetic resonance (NMR) spectroscopy, ¹H-NMR imaging and ¹H-NMR localized spectroscopy in relation to morphology. Maltose, sucrose, fructose and oils were detected in intact imbibed seeds by ¹³C-NMR spectra. During the first 6 d of germination, the maltose content increased and the oil content gradually decreased, whilst the levels of sucrose and fructose remained constant. Sugars were located by ¹H-NMR images and ¹H-NMR localized spectra in the vascular bundle of the seeds as well as in the solubilized endosperm. They were also detected in the shoots. The sugars detected in an 80% ethanol shoot extract were sucrose and glucose, which were located in the vascular bundles but not in the mesophyll cells of the coleoptile. They were also located in the basal part of the shoot, but not above 7 mm from the scutellum. The data suggest that the sugars are primarily transported through the vascular bundles and, at the same time, rapidly incorporated into mesophyll cells in the leaves.     

Solubilization and characterization of 3H-spiroperidol binding sites of calf caudate

The effectiveness of several extraction procedures in solubilizing ³H-spiroperidol receptor sites was examined. Of the solubilizing agents tested, digitonin and lysolecithin were both effective in solubilization of the receptor. Lysolecithin, however, yielded four times as many receptor sites as that obtained with digitonin. The soluble receptor retained the essential characteristics of the membrane bound sites. Butaclamol stereospecificity inhibited the uptake of 2 × 10^?9M, ³H-spiroperidol solubilized receptor at an IC₅₀ value similar to that of intact membrane. Stereospecifically of butaclamol antagonism was not maintained, however, when a cerebellum, or heat inactivated caudate preparation was used. The solubilized preparations were sensitive to the effects of the specific dopamine agonist 6,7-dihydroxy-2-aminotetralin (ADTN) which inhibited ³H-spiroperidol binding with low IC₅₀ values similar to those obtained with intact membrane receptor. Displacement of ³H-spiroperidol from ³H-spiroperidol receptor complex was produced by butaclamol stereospecifically, and for other competitive antagonists including haloperidol, spiroperidol and R 1187 in a manner similar to that of the intact membrane receptor. Both microsomes and synaptosomes could be similarly solubilized with digitonin and retained stereospecific reversibility of binding in the presence of butaclamol. Chromatography of solubilized lysolecithin calf caudate, ³H-spiroperidol receptor complex reveals a single peak of radioactivity which was eluted just prior to rabbit gamma globulin, suggesting an estimated molecular weight of 150,000 to 200,000 daltons.     

Solubilization of rock phosphates byRhizobium andBradyrhizobium

The ability ofRhizobium andBradyrhizobium strains to solubilize phosphate from hydroxyapatite was determined in a medium containing NH₄Cl or KNO₃. The presence of NH₄ ⁺ in the medium resulted in higher solubilization of phosphate as compared to the presence of KNO₃, with the exception ofR. leguminosarium bv. viceae strain TAL 1236 and 1402 which solubilized comparable amounts of phosphate in a medium containing either KNO₃ or NH₄Cl. These results suggest that the strains employ two different mechanisms for phosphate solubilization, one depending on the presence of NH₄ ⁺, the other not requiring its presence. Temperature and aeration (O₂ demand) optima were 30°C and 4.2 Hz (shaking frequency), respectively. In nonsterile soil the tested strain (R. meliloti TAL 1236) was very effective in solubilizing rock phosphate.     

An NMR Study of the Conformations of N-terminal Substance P Fragments and Antagonists

Abstract

Three N-terminal fragments of the neurotransmitter Substance P as well as two antagonist heptapeptides containing D-amino-acid residues were studied using different ID and 2D NMR techniques. Total nonexchangeable ¹H-NMR assignments were carried out in D₂O and the NH protons were assigned in H₂O by means of COSY experiments. The spectral data indicates that there are no preferred conformations for the backbone. The N-terminal tetrapeptide SP_1–4-OH exists as a mixture of cis/trans isomers and this effect was studied as a function of pH.     

Combining Next Generation Sequencing with Bulked Segregant Analysis to Fine Map a Stem Moisture Locus in Sorghum (Sorghum bicolor L. Moench)

Sorghum is one of the most promising bioenergy crops. Stem juice yield, together with stem sugar concentration, determines sugar yield in sweet sorghum. Bulked segregant analysis (BSA) is a gene mapping technique for identifying genomic regions containing genetic loci affecting a trait of interest that when combined with deep sequencing could effectively accelerate the gene mapping process. In this study, a dry stem sorghum landrace was characterized and the stem water controlling locus, qSW6, was fine mapped using QTL analysis and the combined BSA and deep sequencing technologies. Results showed that: (i) In sorghum variety Jiliang 2, stem water content was around 80% before flowering stage. It dropped to 75% during grain filling with little difference between different internodes. In landrace G21, stem water content keeps dropping after the flag leaf stage. The drop from 71% at flowering time progressed to 60% at grain filling time. Large differences exist between different internodes with the lowest (51%) at the 7^th and 8^th internodes at dough stage. (ii) A quantitative trait locus (QTL) controlling stem water content mapped on chromosome 6 between SSR markers Ch6-2 and gpsb069 explained about 34.7-56.9% of the phenotypic variation for the 5^th to 10^th internodes, respectively. (iii) BSA and deep sequencing analysis narrowed the associated region to 339 kb containing 38 putative genes. The results could help reveal molecular mechanisms underlying juice yield of sorghum and thus to improve total sugar yield.     

Hydration of phospholipid bilayers in the presence and absence of cholesterol

The number of water molecules bound (unfreezable) by a molecule of dipalmitoyl phosphatidylserine (DPPS) or by a molecule of dipalmitoyl phosphatidylcholine (DPPC) alone or in mixtures with cholesterol was determined by differential scanning calorimetry (DSC). When the phospholipids are in the gel state and in the absence of cholesterol, molecule of DPPS binds about 3.5 molecules of water and molecule of DPPC binds about 6 molecules of water. Number of water molecules bound increases when cholesterol crystallites are formed in the bilayer. For DPPS-cholesterol mixture at X(chol) -0.5, as well as for DPPC-cholesterol mixture at X(chol) -0.5 about 7 water molecules are bound.     

Solubilization and enrichment of boar sperm membrane proteins

Boar sperm membranes are rather resistent to the solubilizing effect of some detergents. Deoxycholate, an ionic detergent, was efficient in solubilizing sperm proteins but some nonionic detergents like Triton X-100 displayed relatively poor capacity in rendering membrane proteins soluble. This may be due to sperm proteins being attached to submembraneous structures through bonds involving divalent cations, since mixtures of Triton X-100 and ethylenediamine tetraacetic acid (EDTA) were almost as efficient as deoxycholate in solubilizing membrane proteins. Since intact spermatozoa were directly treated with detergents the solubilized proteins comprised a mixture of intracellular and membrane components. To enrich for membrane proteins, affinity chromatography on columns containing different lectins was carried out. SDS polyacryiamide gel electrophoresis of sperm glycoproteins desorbed from the various lectin columns demonstrated that each lectin bound a unique set of components although most glycoproteins were recovered from two or more columns. Columns containing Lens culinaris hemagglutinin yielded more sperm glycoproteins than any of the other lectin columns examined. The predominant amount of the sperm proteins recovered from the Lens culinaris lectin column was membrane derived, as the majority of the proteins were integrated into liposomes. It is concluded that sperm membrane proteins are efficiently solubilized by detergent in the presence of a chelator and that most of the membrane glycoproteins can easily be enriched by affinity chromatography on a lectin column. Proteins obtained in this way should serve as excellent starting material for the isolation of individual sperm membrane proteins.     

Ceramide-1-Phosphate, in Contrast to Ceramide, Is Not Segregated into Lateral Lipid Domains in Phosphatidylcholine Bilayers

Sphingolipids are key lipid regulators of cell viability: ceramide is one of the key molecules in inducing programmed cell death (apoptosis), whereas other sphingolipids, such as ceramide 1-phosphate, are mitogenic. The thermotropic and structural behavior of binary systems of N-hexadecanoyl-D-erythro-ceramide (C₁₆-ceramide) or N-hexadecanoyl-D-erythro-ceramide-1-phosphate (C₁₆-ceramide-1-phosphate; C₁₆-C1P) with 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) was studied with DSC and deuterium nuclear magnetic resonance (²H-NMR). Partial-phase diagrams (up to a mole fraction of sphingolipids X = 0.40) for both mixtures were constructed based on DSC and ²H-NMR observations. For C₁₆-ceramide-containing bilayers DSC heating scans showed already at X_cer = 0.025 a complex structure of the main-phase transition peak suggestive of lateral-phase separation. The transition width increased significantly upon increasing X_cer, and the upper-phase boundary temperature of the mixture shifted to ∼65°C at X_cer = 0.40. The temperature range over which ²H-NMR spectra of C₁₆-ceramide/DPPC-d₆₂ mixtures displayed coexistence of gel and liquid crystalline domains increased from ∼10° for X_cer = 0.1 to ∼21° for X_cer = 0.4. For C16-C1P/DPPC mixtures, DSC and ²H-NMR observations indicated that two-phase coexistence was limited to significantly narrower temperature ranges for corresponding C1P concentrations. To complement these findings, C₁₆-ceramide/1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) and C16-C1P/POPC mixtures were also studied by ²H-NMR and fluorescence techniques. These observations indicate that DPPC and POPC bilayers are significantly less perturbed by C₁₆-C1P than by C₁₆-ceramide and that C₁₆-C1P is miscible within DPPC bilayers at least up to X_C1P = 0.30.     

Isolation and performance evaluation of halotolerant phosphate solubilizing bacteria from the rhizospheric soils of historic Dagong Brine Well in China

The use of halotolerant phosphate solubilizing bacteria as inoculants to convert insoluble phosphorus of salt-affected soils to an accessible form is a promising strategy to improve the phosphorus ingestion of plants in salt-affected agriculture. A total of four aerobic isolates with biggest clear halos on the 10% NaCl NBRIP medium plate containing tricalcium phosphate were isolated from the rhizospheric soils of native plants growing on the wall of Dagong Ancinet Brine Well, located in Sichuan of China. And these four isolates were classified to the same strain, named QW10-11, and closely related to Bacillus megatherium var. phosphaticum DSM 3228 and B. megaterium ATCC 14581 according to their phenotype and 16S rRNA. However, the Molecular evolutionary evidences of 16S-23S rRNA ISR further suggested that QW10-11, DSM 3228 and ATCC 14581 have respectively fall into the different sub-divisions in intra specific phylogeny. Strain QW10-11 has significantly better ability of tricalcium phosphate solubilization than that of lecithin solubilization. When it grows under pH 4.8–8.0, 24–33°C and 5–10% NaCl, it can exhibit the higher values of solubilized tricalcium phosphate between 59.3 and 71.4 μg ml⁻¹. Furthermore, its tricalcium phosphate solubilizing activity was associated with the release of organic acids. Taken together, our results indicted that QW10-11 from the rhizospheric soils of halobiot of Dagong Ancinet Brine Well is attractive as efficient phosphate solubilizing candidates in the salt-affected agriculture.     

Components and fractions for differently bound water molecules of dipalmitoylphosphatidylcholine-water system as studied by DSC and H-NMR spectroscopy

Differently bound water molecules of dipalmitoylphosphatidylcholine (DPPC)-H₂O system were investigated with differential scanning calorimetry (DSC). According to a method previously reported by us, the ice-melting DSC curves of the DPPC-H₂O samples of varying water contents were deconvoluted into multiple components, and the ice-melting enthalpies for the individual deconvoluted components were used to estimate average molar ice-melting enthalpies for freezable interlamellar and bulk waters, respectively. With these average molar ice-melting enthalpies, the numbers of differently bound water molecules of the DPPC-H₂O system were calculated at varying water contents and were used to construct a water distribution diagram of this system. Furthermore, to evaluate the reliability of the present DSC deconvolution method, ²H-NMR T₁ measurements of DPPC-²H₂O system were carried out at 5 °C of the gel phase temperature, and components and fractions for differently bound water (²H₂O) molecules were estimated from the analysis of nonexponential magnetization recovery curves.     

Impacts of hydrophobicity and ionicity of phendione-based cobalt(II)/(III) complexes on binding with bovine serum albumin

Abstract

For efficient designing of metallodrugs, it is imperative to analyse the binding affinity of those drugs with drug-carrying serum albumins to comprehend their structure–activity correlation for biomedical applications. Here, cobalt(II) and cobalt(III) complexes comprising three phendione ligands, [Co(phendione)₃]Cl₂ (1) and [Co(phendione)₃]Cl₃ (2), where, phendione = 1,10-phenanthroline-5,6-dione, has been chosen to contrast the impact of their hydrophobicity and ionicity on binding with bovine serum albumin (BSA) through spectrophotometric titrations. The attained hydrophobicity values using octanol/water partition coefficient method manifested that complex 1 is more hydrophobic than complex 2, which could be attributed to lesser charge on its coordination sphere. The interaction of complexes 1 and 2 with BSA using steady state fluorescence studies revealed that these complexes quench the intrinsic fluorescence of BSA through static mechanism, and the extent of quenching and binding parameters are higher for complex 2. Further thermodynamics of BSA-binding studies revealed that complexes 1 and 2 interact with BSA through hydrophobic and hydrogen bonding/van der Waals interactions, respectively. Further, UV–visible absorption, circular dichroism and synchronous fluorescence studies confirmed the occurrence of conformational and microenvironmental changes in BSA upon binding with complexes 1 and 2. Molecular docking studies have also shown that complex 2 has a higher binding affinity towards BSA as compared to complex 1. This sort of modification of ionicity and hydrophobicity of metal complexes for getting desirable binding mode/strength with drug transporting serum albumins will be a promising pathway for designing active and new kind of metallodrugs for various biomedical applications.

Communicated by Ramaswamy H. Sarma