Chemical modification of buried lysine residues of bovine serum albumin and its influence on protein conformation and bilirubin binding.

Using a double modification technique about 20% of the lysine residues of bovine serum albumin (BSA) which are not easily accessible in the native protein have been modified. The technique involved approximately 80% modification of lysine residues of BSA with citraconic anhydride followed by chemical modification of the remaining lysine residues with acetic anhydride, succinic anhydride, potassium cyanate, or O-methylisourea. Finally, these preparations were decitraconylated under mild acidic conditions to yield acetylated, succinylated, carbomylated or guanidinated BSA. All of these preparations were found to be homogeneous with respect to charge and size. The spectral, hydrodynamic and bilirubin binding properties of these preparations are described. In contrast to most of the highly modified proteins these preparations with the exception of succinylated BSA are very similar to native BSA in their spectral and hydrodynamic properties. However, the equilibrium association constant (Ka) with bilirubin measured by fluorescence quenching was decreased by about 100-fold in acetylated, carbamylated and succinylated BSA, but only 3-fold in guanidinated BSA. Since conformationally acetylated and carbamylated BSAs are identical to guanidinated BSA we conclude that the decrease in Ka in these preparations is solely due to loss of positive charge on 'critical' lysine residues. The results support a binding model for BSA in which bilirubin binding site is buried and the protein undergoes a series of relaxational changes in conformation upon interaction with bilirubin.     

A correlation between changes in conformation and molecular properties of bovine serum albumin upon succinylation

Using succinic anhydride, six succinylated derivatives of bovine serum albumin having percent modification in the range of 23-87% were prepared and their physicochemical and immunological properties were studied. Measurements of Stokes radius, frictional ratio, UV spectra, solvent perturbation, solubility, and immunological cross-reactivity against anti-bovine serum albumin antiserum revealed that the protein undergoes gradual changes in its native conformation with increase in the degree of succinylation. These changes were less marked below 50% modification but became pronounced above 50% modification. However, even the maximally modified preparation (87%) contained a significant amount of folded structure. Interestingly, though the measurements of various molecular properties revealed significant changes in 23-49% modified preparations, the solubility parameters for these preparations which were obtained at high ionic strength were indistinguishable from those of the native protein. The various results taken together suggest that at lower degrees of chemical modification, the conformational changes were produced mainly because of an increase in electrostatic free energy, whereas at higher degrees of modification, steric hindrance in addition to the electrostatic factor seems to make a substantial contribution to the conformational changes in the modified proteins.     

Influence of succinylation of bovine serum albumin on its conformation and bilirubin binding

In order to investigate the role of lysine residues in the interaction of bilirubin with bovine serum albumin, five succinylated preparations of albumin, namely: 23%, 39%, 49%, 55% and 87%, were prepared, and their conformational and bilirubin-binding properties were studied by the techniques of gel filtration, ultraviolet and visible spectroscopy, and fluorescence quenching. Gel filtration experiments performed at pH 7.0 and ionic strengths 0.15 and 1.0 suggested that the albumin molecule undergoes gradual disorganization with increase in succinylation. The Stokes radius and frictional ratio at ionic strength 0.15 increased from 3.7 nm and 1.36, respectively, for the native protein to 6.3 nm and 2.26 for maximally (87%) succinylated albumin. Interestingly, increase in ionic strength to 1.0 caused significant refolding in succinylated preparations as evidenced by a decrease in Stokes radius and frictional ratio (5.3 nm and 1.90 for 87% succinylated albumin). Progressive succinylation produced a steady decline in the intensity of bilirubin-induced fluorescence quenching, and in the visible spectral changes of the bilirubin-albumin complex at 480 nm. Both of these changes had a good correlation with increase in Stokes radius. Increase in ionic strength to 1.0 produced a significant reversal in these properties. From these results we conclude that probably none of the surface lysine residues is involved in bilirubin-albumin interaction, and that if lysine residues are involved in this interaction they must be buried in the protein interior.     

Effect of lysine modification on the conformation and indomethacin binding properties of human serum albumin.

In order to study the involvement of lysine residues of human serum albumin (HSA) in the binding of indomethacin, HSA was treated with different molar excess of acetic anhydride, succinic anhydride and O-methylisourea which resulted in differently modified preparations: 30%, 62% and 87% acetylated, 20%, 34%, 64% and 78% succinylated and 21%, 43% and 86% guanidinated HSAs. All the preparations were found to be homogeneous with respect to charge as well as size as judged by polyacrylamide gel electrophoresis and gel filtration on a Seralose-6B column. Hydrodynamic and circular dichroic results showed that pronounced conformational changes (both tertiary and secondary structures) were induced in the maximally acetylated (87%) and succinylated (78%) preparations. On the other hand, guanidinated preparations showed no expansion in the hydrodynamic volume. The percent decrease in alpha-helical content was 34% for 87% acetylated, 31% for 78% succinylated and 10% for 86% guanidinated HSAs. A significant increase in the values of Stokes radii and frictional ratios (from 3.43 nm and 1.29 for native HSA to 4.07 nm and 1.52 for 87% acetylated and 4.35 nm and 1.60 for 78% succinylated HSAs, respectively) was also noticed in these highly modified preparations. Fluorescence quench titration results obtained at pH 7.4 and ionic strength 0.15 showed that only 54.1% and 64.7% binding of indomethacin at 4:1 drug/protein molar ratio was retained by 87% acetylated and 78% succinylated HSAs, respectively, as compared to 91% retention in binding in 86% guanidinated preparation. No reversal in the binding of drug to 87% acetylated and 78% succinylated HSA preparations was observed on increasing the ionic strength to 1.0. Therefore, it seems that one or two critical lysine residue(s) that can form salt linkage with the carboxyl group of indomethacin, was (were) probably modified in these preparations. A small decrease in the binding of drug to the guanidinated preparation also confirms the involvement of positive charge, probably contributed by lysine residue(s), in the binding of indomethacin to HSA.     

Inhibition of ubiquitin-dependent proteolysis by non-ubiquitinatable proteins

The effect in reticulocyte lysates of proteins with blocked amino groups on the ATP-dependent degradation of casein and serum albumin was studied in order to assess the extent to which proteins with blocked and with free amino groups share common paths of proteolytic degradation. Completely acetylated or succinylated casein and acetylated or succinylated serum albumin (reduced and carboxymethylated), in addition to other amino-modified proteins, inhibited the ATP-dependent proteolysis of both casein and reduced carboxymethylated serum albumin. Inhibition of serum albumin degradation by acetylated serum albumin was competitive, whereas inhibition of casein degradation by acetylated casein was largely competitive with evidence of mixed kinetics. The different amino-blocked proteins studied, which were largely unfolded under assay conditions, were similarly effective as inhibitors on a weight basis, with Ki values in the range 0.2-0.6 mg/ml; there was no correlation between the ability of the blocked proteins to serve as proteolysis substrates and their effectiveness as inhibitors. Studies of the effects of acetylated proteins on the conjugation of ubiquitin to serum albumin and casein demonstrated that the acetylated proteins blocked formation of ubiquitin-albumin conjugates and of selected casein conjugates; the steady state concentration of selected conjugates of endogenous lysate proteins was increased in the presence of amino-blocked proteins. The results suggest that proteins with blocked amino groups, which cannot serve as substrates for ubiquitin conjugation, can compete for binding to those ubiquitin conjugation factors that recognize and ubiquitinate potential substrates of the ubiquitin pathway. The similar inhibitory properties of the different blocked proteins in turn suggest that a common factor in binding to these conjugation factors may be recognition of the polypeptide backbone.     

Streptavidin in antibody pretargeting. 3. Comparison of biotin binding and tissue localization of 1,2-cyclohexanedione and succinic anhydride modified recombinant streptavidin

Recombinant streptavidin (rSAv) is of interest as a carrier of alpha-emitting radionuclides in pretargeting protocols for cancer therapy. Due to the inherently high kidney localization of rSAv, modification of this protein is required before it can be useful in pretargeting. Previous studies (Wilbur, D. S., Hamlin, D. K. et al. (1998) Bioconjugate Chem. 9, 322-330) have shown that succinylation of rSAv using succinic anhydride decreases the kidney localization appreciably. In continuing studies, the biotin binding characteristics and biodistribution in mice of rSAv modified by reaction with succinic anhydride (amine modification) or 1,2-cyclohexanedione (arginine modification) have been compared. Modification of rSAv was conducted using 5-50 mol equiv of succinic anhydride and 60-200 mol equiv of 1,2-cyclohexanedione. Most studies were conducted using rSAv modified with the highest quantities of reagents. Succinylation of rSAv did not alter binding with biotin derivatives, but a small increase in the biotin derivative dissociation rate was noted for arginine-modified rSAv. Amino acid analysis of 1,2-cyclohexanedione-treated rSAv indicated about 40% of the arginine residues, or an average of 1.6 residues per subunit, were modified, whereas none of the lysine residues were modified. IEF analyses showed that the pI of the arginine-modified rSAv was 5.3-6, whereas the pI for the succinylated rSAv was approximately 4. Electrospray mass spectral analyses indicated that one to three conjugates of 1,2-cyclohexanedione, and two to three conjugates of succinic anhydride, were obtained per subunit. Both modification reactions resulted in greatly decreasing the kidney localization of rSAv (normally 20-25% ID/g at 4, 24, and 48 h pi). However, the kidney concentration for the succinylated rSAv continued to decrease (5% ID/g to 1.5% ID/g) from 4 to 48 h pi, whereas the concentration (5% ID/g) remained constant over that period of time for the arginine-modified rSAv. In contrast to this, the liver concentration appeared to be slightly higher (3% ID/g vs 2% ID/g) at the later time points for the succinylated rSAv. When less than 50 mol equiv of succinic anhydride were employed in the modification of rSAv, a correlation between increasing kidney localization with decreasing equivalents reacted was observed. Although the differences in the two modified rSAv are not substantial, succinylated rSAv appears to have more favorable properties for pretargeting studies.     

Effect of succinylation (3-carboxypropionylation) on the conformation and immunological activity of ovalbumin.

The epsilon-amino groups of ovalbumin were modified with succinic anhydride; as many as 16 lysine residues were succinylated (3-carboxypropionylated). The five succinylated derivatives thus prepared were homogeneous with respect to the extent of chemical modification as shown by electrophoretic and immunological data. Succinylation of the amino groups altered electrophoretic mobility and isoionic pH of ovalbumin in the expected direction. U.v.-absorption and fluorescence spectra suggested changes in the microenvironment of the chromophores in the modified proteins. The difference-spectral results showed greater exposure of tyrosine and tryptophan residues in the succinylated ovalbumin. Increase in susceptibility to tryptic digestion, Stokes radius and intrinsic viscosity of native ovalbumin, which was observed on successive increase in the chemical modification, demonstrated a conformational change that was proportional to the extent of modification. The loss of immunological reactivity caused by chemical modification also indicated a conformational change in succinylated ovalbumin. The fact that the intrinsic viscosity of maximally modified ovalbumin was less than one-third of that for the completely denatured protein in 6M-guanidinium chloride suggested that the modified protein contained significant residual native structure. The latter presumably accommodates some antigenic determinants accounting for 37% residual immunological activity observed with maximally succinylated ovalbumin.     

Preparation of sugarcane bagasse hemicellulosic succinates using NBS as a catalyst

The chemical modification of native sugarcane bagasse hemicelluloses with succinic anhydride using N-bromosuccinimide as a catalyst and N,N-dimethylacetamide/lithium chloride system as solvent was studied. The parameters optimised included succinic anhydride concentration by the molar ratio of succinic anhydride/anhydroxylose units in native hemicelluloses from 1:1 to 9:1, reaction time 0.5–6 h, NBS concentration 0.5–3.0%, and reaction temperature 25–85 °C required in the process. Results were also compared with other catalysts such as pyridine, DMAP, H₂SO₄, and other two tertiary amine catalysts, N-methyl pyrrolidine, and N-methyl pyrrolidinone. The degree of substitution of succinylated hemicelluloses ranged between 0.19 and 1.39, depending on the experimental conditions. FT-IR and ¹H and ¹³C NMR spectroscopic characterization of the esterified polymers indicated a monoester substitution. The thermal stability of the succinylated hemicelluloses decreased upon chemical modification.     

Dependence of interfacial properties of normal and transformed 3T3 cell membranes on treatment with factors modifying proliferation

Interfacial properties of the outer cell membrane of normal and transformed in vitro cultures of mouse 3T3 cells have been investigated. The contact angles of sessile drops on dried cell preparations were measured and the interfacial tensions derived using the thermodynamic approach introduced by Neumann. Interfacial tensions were found to be within an order of magnitude of those determined for other cell and model membranes. Treatment of cells with calf serum, a stimulant to proliferation, resulted in a decrease in the interfacial tension of normal and transformed cells, whereas use of concanavalin A and its succinylated derivative lead to an increase of interfacial tensions of both cell types. These and further results show a detailed correlation between the growth-regulating effects and the effects on interfacial properties of these proliferation-modifying factors. An inter-pretation of the results of serum depression of the interfacial tension in terms of a binding equilibrium dependent on the concentration of humoral growth factors in the medium is attempted.     

Changes in conformation and immunological activity of ovalbumin during its modification with different acid anhydrides.

In order to probe the cause and nature of conformational changes induced by the chemical modification of amino groups in proteins, five acylated derivatives of ovalbumin namely 21% acetylated, 32% succinylated, 90% butyrated 92% succinylated, and 95% acetylated ovalbumins were prepared and their molecular and immunological properties were systematically investigated. As evidenced by the ultraviolet difference spectral, solvent perturbation, gel filtration, and viscosity data, acylation of the amino groups produced a definite conformational change in native ovalbumin whose extent was higher for higher degrees of chemical modification. The solvent pertubation data showed an exposure of 0.5 tryptophan and 3 tyrosine residues in native ovalbumin; the exposure increased to 1 tryptophan and about 5 tyrosine residues in the maximally modified proteins (i.e. 90% butyrated, 92% succinylated, and 95% acetylated ovalbumins). The Stokes radius (2.7 nm) and intrinsic viscosity (3.9 ml/g) of ovalbumin increased, respectively, to about 3.4 nm and 7.7 ml/g upon acylation of its 18 lysine residues; the intrinsic viscosity of 95% acetylated ovalbumin was 7.2 ml/g. The reduced viscosity of ovalbumin (4.2 ml/g) which remained unaltered on raising the pH to pH 11.2, increased to 7.9 ml/g on succinylation of 18 lysine residues. On raising the ionic strength from 0.15 to 1.0, the value decreased from 7.9 to 6.2 ml/g. These observations taken together with the fact that the intrinsic viscosities of 92% succinylated and 90% butyrated ovalbumins are identical, argue against the presently prevalent proposal that electrostatic effects alone are responsible for the disruption of native protein conformation during chemical modification. The immunological activity of ovalbumin towards rabbit anti-ovalbumin expectedly decreased with acylation of its amino groups but the three maximally modified ovalbumins retained 40% immunological activity. This taken along with the spectral and viscosity data showed substantial native structure (format) in the three maximally acylated derivatives. The rabbit antiserum against 95% acetylated ovalbumin did not cross-react with acetylated lysozyme and reacted poorly with the native and 92% succinylated ovalbumins suggesting that the antigenic make-up of the three maximally modified ovalbumins is different.     

Conformational destabilization of Bacillus licheniformis α-amylase induced by lysine modification and calcium depletion

Bacillus licheniformis α-amylase (BLA) was chemically modified using 100-fold molar excess of succinic anhydride over protein or 0.66 M potassium cyanate to obtain 42 % succinylated and 81 % carbamylated BLAs. Size and charge homogeneity of modified preparations was established by Sephacryl S-200 HR gel chromatography and polyacrylamide gel electrophoresis. Conformational alteration in these preparations was evident by the larger Stokes radii (3.40 nm for carbamylated and 3.34 nm for succinylated BLAs) compared to 2.43 nm obtained for native BLA. Urea denaturation results using mean residue ellipticity (MRE) as a probe also showed conformational destabilization based on the early start of transition as well as ΔG(D)(H(2)O) values obtained for both modified derivatives and Ca-depleted BLA. Decrease in ΔG(D)(H(2)O) value from 5,930 cal/mol (for native BLA) to 3,957 cal/mol (for succinylated BLA), 3,336 cal/mol (for carbamylated BLA) and 3,430 cal/mol for Ca-depleted BLA suggested reduced conformational stability upon modification of amino groups of BLA or depletion of calcium. Since both succinylation and carbamylation reactions abolish the positive charge on amino groups (both α- and ε- amino), the decrease in conformational stability can be ascribed to the disruption of salt bridges present in the protein which might have released the intrinsic calcium from its binding site.     

X-ray crystallographic and mass spectrometric structure determination and functional characterization of succinylated porin from Rhodobacter capsulatus: implications for ion selectivity and single-channel conductance.

The role of charges near the pore mouth has been discussed in theoretical work about ion channels. To introduce new negative charges in a channel protein, amino groups of porin from Rhodobacter capsulatus 37b4 were succinylated with succinic anhydride, and the precise extent and sites of succinylations and structures of the succinylporins determined by mass spectrometry and X-ray crystallography. Molecular weight and peptide mapping analyses using matrix-assisted laser desorption-ionization mass spectrometry identified selective succinylation of three lysine-epsilon-amino groups (Lys-46, Lys-298, Lys-300) and the N-terminal alpha-amino group. The structure of a tetra-succinylated porin (TS-porin) was determined to 2.4 A and was generally found unchanged in comparison to native porin to form a trimeric complex. All succinylated amino groups found in a mono/di-succinylated porin (MS-porin) and a TS-porin are localized at the inner channel surface and are solvent-accessible: Lys-46 is located at the channel constriction site, whereas Lys-298, Lys-300, and the N-terminus are all near the periplasmic entrance of the channel. The Lys-46 residue at the central constriction loop was modeled as succinyl-lysine from the electron density data and shown to bend toward the periplasmic pore mouth. The electrical properties of the MS-and TS-porins were determined by reconstitution into black lipid membranes, and showed a negative charge effect on ion transport and an increased cation selectivity through the porin channel. The properties of a typical general diffusion porin changed to those of a channel that contains point charges near the pore mouth. The single-channel conductance was no longer a linear function of the bulk aqueous salt concentration. The substantially higher cation selectivity of the succinylated porins compared with the native protein is consistent with the increase of negatively charged groups introduced. These results show tertiary structure-selective modification of charged residues as an efficient approach in the structure-function evaluation of ion channels, and X-ray crystallography and mass spectrometry as complementary analytical tools for defining precisely the chemically modified structures.     

Activation of apoalkaline phosphatase by serum albumin with Zn2+ in rat hepatoma cells.

Reuber rat hepatoma cells (R-Y121B) cultured at 0.5% serum accumulated apoalkaline phosphatase in intact cells. When R-Y121B cells were cultured in the presence of bovine serum albumin, alkaline phosphatase activity increased in the cells, and the associated increase in enzyme activity differed amongst bovine serum albumin preparations. The treatment of bovine serum albumin with activated charcoal not only enhanced the effect of serum albumin on alkaline phosphatase activity, but also cancelled the differences due to different preparations of serum albumin. In contrast, no effect from serum albumin was observed in the increase of alkaline phosphatase activity in R-Y121B cell homogenates incubated at 37 degrees C. The activated-charcoal treatment of bovine serum albumin increased the amount of Zn2+ bound to the protein. When R-Y121B cells were cultured with bovine serum albumin, the concentration of Zn2+ in the cytosol fraction slightly increased. However, the effect of serum albumin on Zn2+ concentration in the cytosol fractions was independent of charcoal treatment. It was concluded that serum albumin with Zn2+ induces the activation of apoalkaline phosphatase due to Zn2+ binding.     

Binding of bromophenol blue to bovine serum albumin and its succinylated forms

Interaction of bromophenol blue with bovine serum albumin and its five succinylated forms was studied spectrophotometrically at three different ionic strengths, i.e. 0.04, 0.15 and 1.0 and at two different pH values, namely pH 7.0 and pH 5.0 respectively. Results showed a decrease in bromophenol blue binding on increasing succinylation at low ionic strengths. This decrease was more marked at pH 7.0 than pH 5.0. However, at both the pH values binding returned to a significant degree on increasing the ionic strength to 1.0. Succinylation also caused marked conformational changes at pH 7.0 and ionic strength 0.15 as evidenced by changes in hydrodynamic properties and reduction in antigen-antibody precipitin reaction. However, an increase in ionic strength to 1.0 or decrease in pH to 5.0 caused significant reversal in hydrodynamic parameters. These studies show that lysine residues of bovine serum albumin are not important in bromophenol blue binding.     

Immunoprecipitation is inappropriate for the isolation of radiochemically pure albumin from tissues

Rats were given intravenous injections of l-[1-¹⁴C]leucine. Twelve minutes after injection, testes, kidneys, livers, and hepatomas were excised rapidly from one group of animals bearing Morris hepatoma 5123tc. From a second group of rats, the blood was removed 90 min after injection. Tissue extracts and serum were divided into three portions each, and albumin was isolated from each of the three portions by one of three different methods.The three different isolation procedures were the following: (A) pretreatment of the tissue extracts and serum with bovine serum albumin and its specific antiserum and subsequent immunoprecipitation of the rat serum albumin, (B) direct immunoprecipitation followed by dissolving the precipitated rat serum albumin in acid/ethanol, precipitation with ether, and ion-exchange chromatography of the redissolved albumin on CM-cellulose, and (C) a modification of a procedure published previously including fractionation with trichloroacetic acid, ethanol, ether, and ammonium sulfate, chromatography on Sephadex G-100 and DEAE-cellulose, and preparative disc electrophoresis in polyacrylamide gel at pH 10.3 and pH 2.7.With method (A), radiochemically pure albumin can be obtained only from serum. Even though testis and kidney do not synthesize albumin, albumin preparations isolated by this procedure from these organs contain significant amounts of radioactivity. Specific radioactivities measured in albumin prepared by method (A) from the four tissues examined are 5–19 times larger than those in preparations isolated by method (C). Thus, method (A) is inappropriate for the isolation of radiochemically pure albumin from the tissues studied.Procedure (B) is sufficient to obtain radiochemically pure albumin from the serum as well as from the other tissues examined except liver. With liver, this method yields an albumin preparation containing 53% more radioactivity than does albumin isolated with method (C).Method (C) is the only procedure yielding radiochemically pure albumin from all sources, including liver. In liver and hepatoma, the properties of the radioactive impurities are very similar to the properties of albumin itself. Therefore, several purification steps and a careful analysis of the distribution of radioactivity among the albumin fractions after chromatographies and electrophoreses are necessary to separate radioactive impurities from the albumin from homogenates of these two sources.     

Properties of succinylated wheat-germ agglutinin.

The physicochemical and binding properties of succinylated wheat germ agglutinin are described in comparison with these of unmodified wheat germ agglutinin. Succinylated wheat germ agglutinin is an acidic protein with a pI of 4.0 +/- 0.2 while the native lectin is basic, pI of 8.5. The solubility of succinylated wheat germ agglutinin is about 100 times higher than that of the unmodified lectin at neutral pH. Both lectins are dimeric at pH down to 5, and the dissociation occurs at pH lower than 4.5. The binding of oligosaccharides of N-acetylglucosamine to both lectins is very similar on the basis of fluorescence and phosphorescence studies. The minimal concentration required to agglutinate rabbit red blood cells is about 2 microgram/ml with both lectins and the concentrations of N-acetylglucosamine and di-N-acetylchitobiose which inhibit agglutination are similar with both lectins. The number of succinylated wheat germ agglutinin molecules bound to the surface of mouse thymocytes was ten times lower than that of the unmodified lectin although the apparent binding constant was only slightly different between the two lectins. The dramatic decrease of the apparent number of cell surface receptors upon succinylation of the lectin is discussed on the basis of the decrease of the isoelectric point and of the acidic properties of the cell surface.     

Dependence of interfacial properties of normal and transformed 3T3 cell membranes on treatment with factors modifying proliferation

Interfacial properties of the outer cell membrane of normal and transformed in vitro cultures of mouse 3T3 cells have been investigated. The contact angles of sessile drops on dried cell preparations were measured and the interfacial tensions derived using the thermodynamic approach introduced by Neumann. Interfacial tensions were found to be within an order of magnitude of those determined for other cell and model membranes. Treatment of cells with calf serum, a stimulant to proliferation, resulted in a decrease in the interfacial tension of normal and transformed cells, whereas use of concanavalin A and its succinylated derivative lead to an increase of interfacial tensions of both cell types. These and further results show a detailed correlation between the growth-regulating effects and the effects on interfacial properties of these proliferation-modifying factors. An interpretation of the results of serum depression of the interfacial tension in terms of a binding equilibrium dependent on the concentration of humoral growth factors in the medium is attempted.     

Succinoylation of sugarcane bagasse under ultrasound irradiation

The chemical modification of sugarcane bagasse with succinic anhydride using pyridine as solvent after ultrasound irradiation was studied. The optimized parameters included ultrasound irradiating time 0-50 min, reaction time 30-120 min, succinic anhydride concentration by the ratio of dried sugarcane bagasse to succinic anhydride from 1:0.25 to 1:1.50, and reaction temperature 75-115 degrees C are required in the process. The extent of succinoylation was measured by the weight percent gain (WPG), which increased with increments of reaction time, succinic anhydride concentration, and reaction temperature. The ultrasound irradiation has a positive effect on bagasse succinoylation process. On the other hand, the ultrasonic pre-treatment application broke down the cell wall polymers, resulting in, therefore, a negative effect on the WPG. Evidences of succinoylation were also provided by FT-IR and CP MAS (13)C NMR and the results showed that the succinoylation at C-2 and C-3 occurred. The thermal stability of the succinylated bagasse decreased upon chemical modification.     

Properties of the abnormal human plasma lipoprotein (LP-X) characteristic of cholestasis after chemical modification with succinic anhydride

The abnormal human low-density lipoprotein class characteristic of biliary obstruction (LP-X) was reacted with [¹⁴C]succinic anhydride to an extent of 70–80 moles of succinyl groups incorporated per 10⁵ g of LP-X protein. The modified lipoprotein retained the typical morphology and ultracentrifugal flotation and sedimentation properties of LP-X but failed to react with antiserum to the native lipoprotein. On agar and agarose gel electrophoresis the succinylated lipoprotein had an increased mobility toward the anode relative to LP-X, as a result of the increased negative charge on the protein component.Partial delipidation of succinylated LP-X and ultracentrifugal fractionation of the protein into a fraction containing phospholipids plus at least three relatively small proteins (Apo-X) and an essentially lipid-free protein, chemically similar and immunologically identical with albumin, permitted us to evaluate the extent of reaction of these two protein classes with succinic anhydride in intact LP-X. On the average, the Apo-X fraction had 72 moles of succinyl groups incorporated per 10⁵ g of protein, whereas the albumin fraction incorporated 55 moles per 10⁵ g of protein.Extensive reaction of susceptible amino acid residues (mostly lysines) with succinic anhydride, without disruption of the lipoprotein structure, indicates that these protein groups are accessible to the reagent and are not involved in critical protein-lipid interactions. Elimination of immunoreactivity upon succinylation of LP-X implies that, at least for the Apo-X component, lysine residues participate in the interaction with LP-X antibodies. Also, the present results strongly support the view that albumin is not merely adsorbed to LP-X, and suggest, furthermore, that protein-protein interactions are not directly responsible for the characteristic stacking of LP-X discs as seen in the electron microscope.     

Enzymatic activity of chymopsin of various origin]

A number of enzymatic properties of fish pylochymopsin and bull chymopsin have been studied. Hydrolysis of synthetic ethers of N-benzoyl-L-tyrosine and N-benzoyl-L-arginine by these chymopsins depending at the time and concentration of preparations has been studied. It was found that bull chymopsin is the most active one. It was shown that concentrations of 2 to 6 micrograms/ml of bull chymopsin and of 15 to 20 micrograms/ml of fish enzyme were optimal for synthetic substrate BTME hydrolysis. The significant trypsin activity was revealed in the both preparations on a number of synthetic amides. In contrast to the bull chymopsin the treatment of fish pylochymopsin by TPCK did not completely remove the chymotryptic activity of pylochymopsin. It was shown that tryptic activity in the both preparations was completely removed with TLCK. The time and concentration dependence of the autolysis in both chymopsins has been studied. It should be noted that this process is negligible for fish pylochymopsin in contrast to bull chymopsin. Stabilization of both proteases in aqueous solution at room temperature has been studied. Stabilization of the chymopsins in solution is achieved by the addition of various protein preparations including casein and serum albumin. The degree of stabilization by these proteins was achieved at 2% concentration.