Changes of the oligomeric structure of legumin from pea (Pisum sativum L.) after succinylation

The influence of various levels of succinylation on the structure of the legumin from pea seed has been studied by the techniques of sedimentation velocity, viscometry, fluorescence and circular dichroism spectroscopy, as well as dynamic light scattering. The protein dissociates gradually into the 3S subunit forming a 7S intermediate. At a level of 75-80% succinylation, sudden unfolding of the protein occurs characterized by drastic changes in viscometric and spectroscopic properties. The fluorescence spectra point to the formation of a novel organized structure at a moderate degree of modification before the molecular unfolding takes place. The succinylated subunit was shown to have a sedimentation coefficient of 3.2S, a diffusion coefficient of 5.03 x 10(-7) cm2 . s-1 a Stokes' radius of 4.24 nm, a partial specific volume of 0.703 ml/g, an intrinsic viscosity of 0.13 dl/g, a molar mass of 52.2 kDa and a frictional ratio of 1.74.     

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.     

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.     

Stepwise degradation of serum low denisty lipoprotein by sodium dodecyl sulfate.

The structure of human serum low density lipoprotein (LDL) was investigated by perturbing the LDL structure with sodium dodecyl sulfate (SDS). The change in LDL structure induced by the addition of SDS was monitored by sedimentation velocity measurements, ultraviolet difference spectroscopy, fluorescence spectroscopy and proteolytic digestion of apo-LDL with subtilisin BPN' [EC 3.4.21.14]. As the concentration of SDS was increased from 0.1 mg/ml to 3 mg/ml with LDL concentrations between 2.0 mg/ml and 4.4 mg/ml, the sedimentation coefficient of LDL changed in three distinct steps. It was found by chemical analyses that not more than 30% of the total lipid was lost from LDL in the second step, whereas the final step in the change of sedimentation coefficient corresponded to the complete removal of apo-LDL from the constituent lipids of LDL. The ultraviolet difference spectrum between the native and SDS-treated LDL and the quenching of LDL fluorescence underwent about 80% of the total change while the SDS concentration was only sufficient to cause the second of the three step changes in sedimentation coefficient. SDS-polyacrylamide gel electrophoresis of apo-LDL treated with subtilisin BPN' also showed that more than 70% of apo-LDL became susceptible to proteolysis under the same conditions. These results were interpreted as indicating that the solubilization of 20 to 30% of the lipids on the surface of LDL exposed nearly 80% or more of apo-LDL to the solvent. A small portion of apo-LDL was, however, still firmly anchored to the remaining lipid micelle as long as the concentration of SDS was less than that required to cause the final step of the change in sedimentation coefficient.     

Studies on pig serum lipoproteins. I. Separation and properties of low-density lipoproteins.

The low-density lipoproteins in pig serum were separated into two subclasses (LDL1 and LDL2) by 2 to 7% pore size gradient gel electrophoresis. Preparative gel electrophoresis in 2 to 4% gradient gel made it possible to isolate these components as distinct entities. After delipidation by chromatography on Sepharose 4B in the presence of SDS, both apo-LDL1 and apo-LDL2 were found to have a molecular weight of 2.6X10(5). However, when these apoproteins were incubated in 10% sodium dodecyl sulfate, fragmentation occurred and the minimum fragment molecular weight was estimated to be 2.4X10(4). No essential difference was found in the amino acid compositions or fragmentation patterns of the apoproteins. However, the amounts of carbohydrates in the two apoproteins were different (7.09% in apo-LDL1 and 5.08% in apo-LDL2). The carbohydrate composition was 0.8% sialic acid, 2.38% N-acetyl-glucosamine, and 4.01% neutral sugars in apo-LDL1 and 0.5, 1.75, and 2.83% in apo-LDL2, respectively. In both apoproteins, mannose, galactose, and fucose were present in almost the same molar ratio of 4-5 : 2-3 : 1.     

Molecular weights of apoprotein B obtained from human low-density lipoprotein (apoprotein B-PI) and from rat very low density lipoprotein (apoprotein B-PIII)

Human low-density lipoproteins (LDL) were isolated from single donors by differential centrifugation between densities of 1.020 and 1.050 g/mL. The LDL were reduced and alkylated in 7 M guanidine hydrochloride, and the lipid was removed by multiple extractions in the cold with a mixture of diethyl ether and ethanol. Sedimentation studies on the resultant human apoprotein B (apoprotein B-PI) at low concentrations in 6.00 M guanidine hydrochloride showed a single sharp boundary with a sedimentation coefficient of 2.15 +/- 0.04 S at 25 degrees C, uncorrected for viscosity or density. Diffusion experiments performed in the same solvent at low speeds in the analytical ultracentrifuge gave a D25 = 0.694 +/- 0.043 Fick. Combining these values with an apparent specific volume of 0.703 mL/g yielded a molecular weight of 387 000, indistinguishable from that obtained by sedimentation equilibrium analysis in 7 M guanidine hydrochloride. Similar values were also obtained by calibrated sedimentation analysis, by Sepharose 2B chromatography in guanidine hydrochloride, and by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Rat very low density lipoproteins (VLDL), isolated from sera of Triton WR1339 treated animals, were used as the source of rat apoprotein B-PIII. The delipidated VLDL were solubilized in sodium dodecyl sulfate, and apoprotein B-PIII was isolated by Sepharose 4B chromatography. With appropriate corrections for density and viscosity, the behavior of rat apoprotein B-PIII was identical, upon analytical ultracentrifugation, in 6 and 7.7 M guanidine hydrochloride, corresponding to sedimentation and diffusion coefficients of 1.47 S and 0.92 Fick, respectively, in 6 M guanidine hydrochloride. These data may be combined to yield a molecular weight of 210 000. Similar values were obtained by calibrated sedimentation analysis, by Sepharose 2B chromatography in guanidine hydrochloride, and by polyacrylamide gel electrophoresis in sodium dodecyl sulfate.     

Short peptide receptor mimics for atherosclerosis risk assessment of LDL

Short peptides sequences were selected that showed binding selectivity towards healthy or oxidised (unhealthy) low density lipoprotein (LDL), respectively. These were investigated for application in atherosclerosis risk monitoring. Comparison was also made with the LDL receptor ligand repeat peptide (LR5). The peptides were immobilised on a gold surface plasmon resonance surface and LDL binding detected as a shift in the resonance. 3.7x10(7) (+/-5.6x10(6)) LDL/mm(2)/microg/ml solution LDL were bound on GlySerAspGlu-OH and 6.8x10(7) (+/-9.2x10(6)) LDL/mm(2)/microg/ml on GlyCystineSerAspGlu, compared with approximately 10(8) LDL/mm(2)/microg/ml on LR5. In this first group, binding of LDL decreased with oxidation level and a good correlation was found between LDL binding and residual amino groups on the apoprotein of the LDL following oxidation, or the change in relative electrophoretic mobility (REM) of LDL. The decrease in binding was 1.1x10(7) LDL particles/mm(2) per% oxidation for GlySerAspGlu-OH, 1.8x10(7) LDL particles/mm(2) per% oxidation for GlyCystineSerAspGlu and 2.4x10(7) LDL particles/mm(2) per% oxidation for LR5. A second group of three peptides were also selected showing increased binding with LDL oxidation: GlyCystineCysCys (1.5x10(7) LDL/mm(2) per microg/ml), GlyLysLysCys-SH (10(7) LDL/mm(2) per microg/ml) and GlyLysLys-OH (5.6x10(7) LDL/mm(2) per microg/ml). The latter gave a linear increase in LDL binding with oxidation level (1.2x10(7) LDL particles/mm(2) per% oxidation). LDL concentration is around 2-3 mg/ml in plasma compared with the low detection levels with this method (1-10 microg/ml), allowing a strategy to be developed requiring the minimum sample volume and diluting with physiological buffer prior to assay. By using a comparative reading between LDL adsorption on surfaces from the first and second group of peptides (e.g. GlyCystineSerAspGlu and GlyLysLys-OH, respectively), LDL oxidation could be determined without knowledge of LDL concentration. Higher binding was seen on GlyCystineSerAspGlu than GlyLysLys-OH below 30% LDL oxidation, whereas above 30% oxidation the binding on the latter surface was greater. Simple correlation of this form could provide good tests for atherosclerosis risk.     

Physicochemical properties of apolipoprotein(a) and lipoprotein(a-) derived from the dissociation of human plasma lipoprotein (a)

Chemical reduction of human plasma lipoprotein(a) (Lp(a)) yielded two water-soluble products which were separated by rate zonal ultracentrifugation. Apolipoprotein(a) (apo(a)) was completely recovered from the bottom of the gradient, whereas lipoprotein(a-) (Lp(a-)), which contained all of the lipids and apo-B100 of Lp(a), floated. By the techniques of circular dichroism and viscometry Lp(a-) was identical to low density lipoprotein (LDL). Lp(a-) was slightly larger in mass than autologous LDL and contained proportionally more triglyceride. The difference in mass between Lp(a) and Lp(a-) was accounted for by the loss of 2 molecules of apo(a) from the Lp(a) particle. The molecular weight of reduced and carboxymethylated apo(a) was 281,000 as determined by sedimentation equilibrium in 6 M guanidine HCl. By circular dichroism the structure of apo(a) was mostly random (71%) with the remainder representing 8% alpha-helix and 21% beta-sheet; its intrinsic viscosity, 28.3 cm3/g, was consistent with an extended flexible coil. The amino acid composition was characterized by an unusually high content of proline (11.4 mol %) as well as tryptophan, tyrosine, arginine, threonine, and a low amount of lysine, phenylalanine, and isoleucine. Apo(a) contained 28.1% carbohydrate by weight represented by mannose, galactose, galactosamine, glucosamine, and sialic acid in an approximate molar ratio of 3:7:5:4:7, respectively. Overall, the structure of Lp(a) appears to be consistent with a rigid spherical LDL-like core particle which, as a consequence of its association with a flexible glycoprotein such as apo(a), favors the entrapment of significant amounts of hydrodynamically associated solvent. Furthermore, the Lp(a-) remnant generated by the removal of apo(a) from Lp(a) was similar in structure but not identical to autologous LDL.     

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.     

Loss of apoB-100 secondary structure and conformation in hydroperoxide rich, electronegative LDL(-).

A subpopulation of low-density lipoproteins (LDL) is present in human plasma that contains lipid hydroperoxides and is more negatively charged (LDL(-)) than normal native LDL. By circular dichroism and tryptophan lifetime measurements we found that apoB-100 secondary structure is markedly decreased and its conformation is severely altered in LDL(-). The low tryptophan fluorescence intensity confirms the oxidative degradation of the lipoprotein, and the very long lifetime value of one of its decay components indicates a low polarity environment for the remaining unbleached residues. Either a peculiar folding or, most likely, a sinking of the apoB-100 into the lipid core can account for the observed long lifetime component. Oxidation in vitro produces a similar unfolding of the apolipoprotein but the lifetime of tryptophan fluorescence is shifted to lower values, indicating that the denatured apoprotein remains at the hydrophilic surface of the lipoprotein particle. A disordering and an increased polarity of the LDL(-) surface lipids was demonstrated by measuring the generalized polarization of 2-dimethylamino-6-lauroylnaphthalene (Laurdan). The looser monolayer packing apparently favors the new conformation of apoB-100 and its sinking into a more hydrophobic environment, possibly accounting for it reduced receptor binding properties.     

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.     

The molecular size and shape of the Folch-Pi apoprotein in aqueous and organic solvents.

In 1% acetic acid, sedimentation velocity measurements and equilibrium ultracentrifuge experiments demonstrate that the Folch-Pi apoprotein is not monodisperse. The weight-average molecular weight calculated from ultracentrifuge experiments and combining sedimentation coefficient and viscosity measurements, ranged from 64000 to 80000. The intrinsic viscosity value suggests an asymetric shape for the apoprotein if a low value of hydration is considered. In dioxan/1% acetic acid (2:3, v/v) a smaller sedimentation coefficient was found, the intrinsic viscosity value remaining identical to that in 4% acetic acid. In pure 2-chloroethanol, light-scattering experiments led to a molecular weight of 165000 indicating that even in this solvent the protein is not monomeric. Intrinsic viscosity and light scattering measurements on the one hand, primary sequence on the other hand (six proline residues per monomer of Mr 23500) suggest that the molecule in 2-chloroethanol may consist of rod-like segments with flexible junctions.     

DNA binding studies of tartrazine food additive

The interaction of native calf thymus DNA with tartrazine in 10?mM Tris-HCl aqueous solution at neutral pH 7.4 was investigated. Tartrazine is a nitrous derivative and may cause allergic reactions, with a potential of toxicological risk. Also, tartrazine induces oxidative stress and DNA damage. Its DNA binding properties were studied by UV-vis and circular dichroism spectra, competitive binding with Hoechst 33258, and viscosity measurements. Tartrazine molecules bind to DNA via groove mode as illustrated by hyperchromism in the UV absorption band of tartrazine, decrease in Hoechst-DNA solution fluorescence, unchanged viscosity of DNA, and conformational changes such as conversion from B-like to C-like in the circular dichroism spectra of DNA. The binding constants (K(b)) of DNA with tartrazine were calculated at different temperatures. Enthalpy and entropy changes were calculated to be +37 and +213 kJ mol(-1), respectively, according to the Van't Hoff equation, which indicated that the reaction is predominantly entropically driven. Also, tartrazine does not cleave plasmid DNA. Tartrazine interacts with calf thymus DNA via a groove interaction mode with an intrinsic binding constant of 3.75?×?10(4) M(-1).     

Reaction of yeast phosphofructokinase with succinic and maleic anhydride.

Modification of yeast phosphofructokinase by succinic and maleic anhydride influences the catalytic activity and the allosteric behaviour of the enzyme. Depending on the degree of succinylation and maleinylation a decrease of maximum activity, an increase of the apparent affinity for fructose-6-phosphate, a decrease of the Hill-coefficient and a diminution of ATP-inhibition are observed. Up to about 40% of the lysyl residues could be succinylated without dissociation of the hexameric protein, however with a decrease of the enzyme activity. More extensive succinylation or maleinylation causes a dissociation into subunits. The sedimentation coefficient is lowered from 20 S to about 3 S. The molecular weight of the smallest dissociation product was determined to 50 000 (+/- 10 000) by the sedimentation equilibrium method. The number of bound succinyl groups, as determined from radioactivity incorporation, exceeds the content of lysyl groups of the enzyme, indicating that the modifying reagent is also reacting with other amino acid residues.     

Integrity of polypeptide chains of spectrin from human erythrocytes.

The suggestion that the high molecular weight erythrocyte membrane protein, spectrin, consists of subunits resistant to dissociation by both sodium dodecyl sulfate and 6 m guanidine hydrochloride has been reevaluated. By gel electrophoresis in dodecyl sulfate and thin-layer gel filtration in 6 m guanidine hydrochloride as well as in the much more powerful denaturant guanidine thiocyanate, and by sedimentation velocity in 6 m guanidine hydrochloride, the molecular weight emerges in the range 2–2.5 × 10⁵. Denaturation profiles as a function of guanidine hydrochloride concentration, observed by circular dichroism, reveal that the spectrin conformation is unusually labile, with a mid-point for the unfolding process at a denaturant concentration near 1 m. Complete acylation with succinic anhydride, as well as reaction with citraconic anhydride, leaves the molecular weight unchanged even in 6 m guanidine hydrochloride. The possibility of measuring molecular weights of proteins by viscosity determination in trifluoroacetic acid was explored. A calibration with a series of proteins gave a Mark-Houwink plot with high scatter, which did not result from low precision of viscosity determination or protein degradation. Evidence is adduced from infrared spectra that the scatter is due to a variable degree of protonation of the polypeptide backbone in the acid, leading to altered hydrodynamic characteristics. Within the semiquantitive limits of the method, spectrin is not further disaggregated in trifluoroacetic acid. The presence of refractory noncovalent interactions and of covalent cross-links has been variously invoked to explain an apparent microheterogeneity in spectrin preparations. The results here described appear to render the former explanation untenable.     

Equilibrium and kinetic studies of the interactions of a porphyrin with low-density lipoproteins

Low-density lipoproteins (LDL) play a key role in the delivery of photosensitizers to tumor cells in photodynamic therapy. The interaction of deuteroporphyrin, an amphiphilic porphyrin, with LDL is examined at equilibrium and the kinetics of association/dissociation are determined by stopped-flow. Changes in apoprotein and porphyrin fluorescence suggest two classes of bound porphyrins. The first class, characterized by tryptophan fluorescence quenching, involves four well-defined sites. The affinity constant per site is 8.75 x 10(7) M(-1) (cumulative affinity 3.5 x 10(8) M(-1)). The second class corresponds to the incorporation of up to 50 molecules into the outer lipidic layer of LDL with an affinity constant of 2 x 10(8) M(-1). Stopped-flow experiments involving direct LDL porphyrin mixing or porphyrin transfer from preloaded LDL to albumin provide kinetic characterization of the two classes. The rate constants for dissociation of the first and second classes are 5.8 and 15 s(-1); the association rate constants are 5 x 10(8) M(-1) s(-1) per site and 3 x 10(9) M(-1) s(-1), respectively. Both fluorescence and kinetic analysis indicate that the first class involves regions at the boundary between lipids and the apoprotein. The kinetics of porphyrin-LDL interactions indicates that changes in the distribution of photosensitizers among various carriers could be very sensitive to the specific tumor microenvironment.     

Physicochemical characterization of Rhesus low density lipoproteins.

The serum low density lipoprotein (LDL; p 1.019-1.050 g/ml) of the normal Macaca mulatta monkey (rhesus), kept on a low-fat Purina primate chow diet, was isolated by ultracentrifugal flotation, and its physicochemical properties were compared with those previously reported for human LDL. Rhesus LDL was found to be chemically similar to human LDL. The values for the sedimentation (S25, w-O) and diffusion (D25,w-O) coefficients were 7.09 S and 2.50 times 10- minus-7 cm-2 sec- minus-1, respectively. The intrinsic viscosity was 3.40 ml g- minus-1. The partial specific volume of rhesus LDL, determined in an Anton Paar precision density meter, was 0.960 ml g- minus-1. Molecular weights, calculated from a combination of S-O and D-O and of S-O and [n], were in agreement with the weight-average molecular weight, Mw, of 2.29 times 10-6 obtained by high-speed sedimentation equilibrium. In addition, a Z-average molecular weight, Mz, of 2.73 times 10-6 was calculated because curvature in the graphs of log c vs. r-2 indicated that rhesus LDL was heterogeneous. From the frictional ratio of 1.02, a maximum hydration of 0.1 g of H2O/g of lipoprotein was obtained. On electron micrographs, rhesus LDL appeared spherical with a mean diameter of 196 A, which was substantiated by hydrodynamic analysis.     

Low density lipoprotein turnover in swine.

The catabolism of intravenously injected 125I-labelled low density lipoproteins (LDL) was followed in normal miniature swine for 2 weeks. When compared with the two-exponential model, the decay curve of the plasma radioactivity associated with the LDL fraction was best described by a three-exponential model. In this system, the half-lives were 4.5 +/- 3.7, 19.7 +/- 6.6, and 127 +/- 70 h (mean of four studies). Assuming a kinetic model with metabolism of LDL in the rapidly equilibrating compartment and two slower equilibrating compartments (a model requiring three exponentials), the mean fractional catabolic rate for apo-LDL was calculated to be 0.015 h-1. Therefore, if at steady state, the synthetic rate for apo-LDL in the same pigs would be 5.6 +/- 4.1 mg/h. Different kinetic models using two or three exponentials would provide different values for the synthetic rate of apo-LDL. However, in view of the known existence of at least three major equilibrating pools for LDL in plasma, liver, and lymph, and in view of the present results, the kinetic model for LDL metabolism should be better represented by a three-exponential system.     

Conformation of allantoicase in aqueous solution

1. The separation of 0.9-S and 10.8-S allantoicase with the aid of a 2H2O-H2O gradient was described. The resulting preparations were subjected to sedimentation equilibrium, optical rotatory dispersion (ORD), circular dichroism (CD) and infrared studies. 2. The molecular weight of 0.9-S allantoicase was determined to be about 1.1 x 10(4) g/mole in studies on the sedimentation behavior, the metal content and amino acid composition. The molecular weight of 10.8-S allantoicase was about 15.4 x 10(4) g/mole. 3. Optical rotatory dispersion, circular dichroism and infrared studies indicated that both molecules contain alpha-helix, beta conformation and random coil. A Cotton effect at 418 nm was ascribed to the asymmetric binding of Mn2+ to the enzyme. Competitive inhibitors decreased the absorption and circular dichroism bands at about 280 nm and 418 nm. These phenomena suggested that the aromatic groups may play an essential role in the binding of substrates and inhibitors by the Mn(2+)-enzyme complex. 4. Comparison of alpha-helical contents of metalloallantoicases showed that the enzymes with low helical contents exhibited high enzymic activities. 5. The nearly identical physicochemical behavior and specific enzymic activity of 0.9-S and 10.8-S allantoicase indicated that they are very similar in structure and conformation.     

Structural transition in chromatin induced by ions in solution

Structural transition in chromatin was measured as a function of counter ions in solution (NaCl or MgCl(2)) and of histones bound on the DNA. The addition of counter ions to aqueous solutions of chromatin, partially dehistonized chromatin, and DNA caused a drastic reduction in viscosity and a significant increase in sedimentation coefficient. Transitions occurred primarily at about 2 x 10(-3) M NaCl and 1 x 10(-5) M MgCl(2) and are interpreted as a change in structure of chromatin induced by tight binding of cations (Na(+) or Mg(++)) to DNA, either free or bound by histones, and is an intrinsic property of DNA rather than of the type of histone bound. At a given ionic condition, removal of histone H1 from chromatin had only a minor effect on the hydrodynamic properties of chromatin while removal of other histones caused a drastic change in these properties. An increase in the sedimentation coefficient of DNA was observed also for protamine. DNA complexes wherein the bound protein contains only unordered coil rather than the alpha-helices found in histones.