Effects of formaldehyde fixation on protein secondary structure: a calorimetric and infrared spectroscopic investigation

We investigated the effects of formaldehyde fixation on the secondary structure of isolated proteins (bovine serum albumin, ribonuclease A, and hemoglobin) using high-sensitivity differential scanning calorimetry and Fourier transform infrared spectroscopy. Whereas thermograms obtained by scanning calorimetry on unfixed purified proteins demonstrated denaturation transitions in the 70-90 degrees C temperature range, the thermograms showed no denaturation transitions in this temperature range when the proteins had been placed in formaldehyde solutions. Thus, fixation destroyed the denaturation transition of bovine serum albumin, ribonuclease A, and hemoglobin. Infrared spectra obtained on the unfixed and fixed proteins were essentially identical. This demonstrates that the "fixed" proteins retain the secondary structure present before fixation. We therefore conclude that the cross-linking of proteins that occurs in the process of formaldehyde fixation "locks in" the secondary structure of these protein molecules.     

An interspecies comparison of normal levels of glycosylated hemoglobin and glycosylated albumin

Aminophenylboronic acid affinity chromatography was used to measure glycosylated hemoglobin and glycosylated albumin levels in a variety of species. The highest glycosylated hemoglobin levels were found in man, the lowest in the chicken and the pig. The highest glycosylated albumin levels were found in avian species, the lowest in the mouse and the rat. A simple kinetic model was used to analyze the rates of formation of glycosylated hemoglobin and albumin in the various species. Rates of glycosylated albumin formation were very similar across the species while rates of glycosylated hemoglobin formation were quite different, presumably reflecting wide differences in erythrocyte permeability to glucose among the species.     

Cerebrovascular response to decreased hematocrit: effect of cell-free hemoglobin,plasma viscosity,and CO2

The effect of transfusing a nonextravasating, zero-link polymer of cell-free hemoglobin on pial arteriolar diameter, cerebral blood flow (CBF), and O2 transport (CBF x arterial O2 content) was compared with that of transfusing an albumin solution at equivalent reductions in hematocrit (approximately 19%) in anesthetized cats. The influence of viscosity was assessed by coinfusion of a high-viscosity solution of polyvinylpyrrolidone (PVP), which increased plasma viscosity two- to threefold. Exchange transfusion of a 5% albumin solution resulted in pial arteriolar dilation, increased CBF, and unchanged O2 transport, whereas there were no significant changes over time in a control group. Exchange transfusion of a 12% polymeric hemoglobin solution resulted in pial arteriolar constriction and unchanged CBF and O2 transport. Coinfusion of PVP with albumin produced pial arteriolar dilation that was similar to that obtained with transfusion of albumin alone. In contrast, coinfusion of PVP with hemoglobin converted the constrictor response to a dilator response that prevented a decrease in CBF. Pial arteriolar dilation to hypercapnia was unimpaired in groups transfused with albumin or hemoglobin alone but was attenuated in the largest vessels in albumin and hemoglobin groups coinfused with PVP. Unexpectedly, hypocapnic vasoconstriction was blunted in all groups after transfusion of albumin or hemoglobin alone or with PVP. We conclude that 1) the increase in arteriolar diameter after albumin transfusion represents a compensatory response that prevents decreased O2 transport at reduced O2-carrying capacity, 2) the decrease in diameter associated with near-normal O2-carrying capacity after cell-free polymeric hemoglobin transfusion represents a compensatory mechanism that prevents increased O2 transport at reduced blood viscosity, 3) pial arterioles are capable of dilating to an increase in plasma viscosity when hemoglobin is present in the plasma, 4) decreasing hematocrit does not impair pial arteriolar dilation to hypercapnia unless plasma viscosity is increased, and 5) pial arteriolar constriction to hypocapnia is impaired at reduced hematocrit independently of O2-carrying capacity.     

Various enzymatic and nonenzymatic pathways of acetaldehyde transformation

In blood acetaldehyde is bound to hemoglobin and serum albumin and interacts with low-molecular-weight components--cysteine, glutathione. The association constants for human serum albumin and human hemoglobin are about 30 M-1 and 410 M-1, respectively. The SH-groups of hemoglobin play an essential role in the interaction of protein with acetaldehyde. The reversible complexes of acetaldehyde with proteins can transform into stable adducts after long incubation with albumin, some other blood proteins but not with immunoglobulins. Acetaldehyde participates as a substrate in the reaction of acetoin formation in homogenates of different tissues. The rate of acetoin formation is about 15 +/- 3 mmol/min per 1 gram of the tissue and essentially increases in the presence of pyruvate.     

Hemoglobin & serum albumin: salt-mediated hydrophobic chromatography.

The binding of pure human serum albumin and pure human hemoglobin to L-phenylalinine Sepharose and aniline Sepharose columns, two chromatographic columns of differing hydrophobicity, has been investigated for various concentrations of ammonium sulfate salts.The binding of hemoglobin at a lower ammonium sulfate concentration than albumin in both hydrophobic support systems parallels the solubility and precipitation characteristics of these two proteins in solution and mirrors the phenomenon of salting out of proteins in solution. Both hemoglobin and albumin bind at lower concentrations on aniline Sepharose than on L-phenylalanine Sepharose, reflecting the greater efficiency of binding by the more hydrophobic support matrix.     

Binding of human hemoglobin by Haemophilus influenzae

Abstract Binding of biotinylated human hemoglobin to Haemophilus influenzae was detected when organisms were grown in heme-deplete, but not heme-replete, conditions. Hemoglobin binding was completely inhibited by a 100-fold excess of unlabelled human hemoglobin or human hemoglobin complexed with human haptoglobin. Binding was only partially inhibited by rat hemoglobin, bovine hemoglobin, human globin, and bovine globin, and not at all by heme, human serum albumin, bovine serum albumin, human transferrin, or myoglobin. Hemoglobin binding was saturable at 16–20 ng of hemoglobin per 10⁹ cfu. Binding of human hemoglobin was detected in serotypes a-f and serologically non-typable strains of H. influenzae , as well as Haemophilus haemolyticus but not Haemophilus parainfluenzae, Haemophilus aphrophilus, Haemophilus parahaemolyticus , or Escherichia coli .     

Primary structure of hemoglobin of the polar bear (Ursus maritimus, Carnivora) and the Asiatic black bear (Ursus tibetanus, Carnivora

The adult Polar and Asiatic Black Bear have one hemoglobin component each. The complete amino-acid sequences of their alpha- and beta-chains are presented. Their primary structures were determined by sequencing the tryptic and prolyl peptides. The alignment of these peptides was deduced from homology to human hemoglobin chains. The hemoglobin sequences of the two species proved to be identical. The evolutionary aspects of this result are discussed. A table of identical hemoglobin sequences from different species is given.     

Life-span and size of the trans-membrane channel formed by large doses of complement

To evaluate the life-span and size of trans-membrane channels in complement (C) treated membranes, resealed erythrocyte ghosts containing trapped native protein markers, as well as residual hemoglobin, were treated with anti-Forssman antibody and large doses of guinea pig C. Ovalbumin and hemoglobin were released slowly through the channels so produced, whereas human serum albumin was not. Release of hemoglobin was not blocked by extracellular bovine serum albumin. Release of hemoglobin continued for at least 72 hr at 4 degrees C. Semi-logarithmic plots of ovalbumin or hemoglobin release showed gradual diminution of the rate constant, which indicates slow loss of channels during the experimental period. These experiments demonstrate that the channels produced in erythrocyte ghost membranes by large C doses have a long, although finite, life-span. Their effective diameter is al least 55 A on the basis of ovalbumin and hemoglobin release, and not more than 150 A, since serum albumin was not released. However, an upper limit of 100 A would be more reasonable in light of electronmicroscopic observations by others. These results are compatible with the doughnut model.     

Two hemoglobin-binding proteins identified in the plasma of the amphibian Taricha granulosa

The plasma of the amphibian newt Taricha granulosa has been shown to be devoid of haptoglobin. Upon hemolysis, Taricha albumin and another protein associate with hemoglobin. The acute-phase response to inflammation observed in birds and mammals appears to be absent in Taricha. Taricha hemoglobin failed to bind to human haptoglobin. Taricha hemoglobin not only failed to dissociate into alpha beta dimers as did human Hb, but formed alpha beta octamers.     

Simplified elimination of rabbit anti-rat acute phase protein IgG that shows cross reactivity with albumin

Antibody preparations against rat acute phase proteins were tested for cross reactivity with other serum proteins, including rat albumin. Rabbit anti-rat a alpha1-acid glycoprotein and ceruloplasmin IgG purified on protein A-Sepharose did not show any cross reactivity with rat albumin, hemoglobin or transferrin. Rabbit anti-rat haptoglobin and -macroglobulin IgG purified on protein A-Sepharose showed a 39% and 30% cross reactivity with rat albumin and a 20% and 19% cross reactivity with rat hemoglobin. Because these proteins in whole serum were not adsorbed on Cibacron Blue F3-GA Sepharose, the albumin would be adsorbed on Cibacron Blue F3-GA Sepharose by the use of whole rat serum. Rabbit anti-rat haptoglobin and alpha2-macroglobulin IgG showing cross reactivity with albumin was simply eliminated.     

The preferential adsorption of hemoglobin to polyethylene.

Hemoglobin adsorption to foreign surfaces has not previously been considered in studies of blood-material interactions, despite the fact that hemoglobin is the most abundant protein present in blood. A hemoglobin-like protein was detected on a number of surfaces exposed to blood plasma, serum, and red cell suspensions. Hemoglobin adsorption to polyethylene from plasma was found to approximately equal the amount of adsorption of albumin and fibrinogen. The high relative affinity of hemoglobin for polyethylene was further confirmed by adsorption isotherm and direct competition experiments. The data from all four experimental methods support the following ranking of plasma protein affinity for polyethylene: Hemoglobin greater than fibrinogen greater than albumin congruent to gamma-globulin.     

Genetic analyses of proteolysis, hemoglobin binding, and hemagglutination of Porphyromonas gingivalis. Construction of mutants with a combination of rgpA, rgpB, kgp, and hagA.

Porphyromonas gingivalis produces arginine-specific cysteine proteinase (Arg-gingipain, RGP) and lysine-specific cysteine proteinase (Lys-gingipain, KGP) in the extracellular and cell-associated forms. Two separate genes (rgpA and rgpB) and a single gene (kgp) have been found to encode RGP and KGP, respectively. We constructed rgpA rgpB kgp triple mutants by homologous recombination with cloned rgp and kgp DNA interrupted by drug resistance gene markers. The triple mutants showed no RGP or KGP activity in either cell extracts or culture supernatants. The culture supernatants of the triple mutants grown in a rich medium had no proteolytic activity toward bovine serum albumin or gelatin derived from human type I collagen. Moreover, the mutants did not grow in a defined medium containing bovine serum albumin as the sole carbon/energy source. These results indicate that the proteolytic activity of P. gingivalis toward bovine serum albumin and gelatin derived from human type I collagen appears to be attributable to RGP and KGP. The hemagglutinin gene hagA of P. gingivalis possesses the adhesin domain regions responsible for hemagglutination and hemoglobin binding that are also located in the C-terminal regions of rgpA and kgp. A rgpA kgp hagA triple mutant constructed in this study exhibited no hemagglutination using sheep erythrocytes or hemoglobin binding activity, as determined by a solid-phase binding assay with horseradish peroxidase-conjugated human hemoglobin, indicating that the adhesin domains seem to be particularly important for P. gingivalis cells to agglutinate erythrocytes and bind hemoglobin, leading to heme acquisition.     

The primary structure of the hemoglobin of Malayan sun bear (Helarctos malayanus, Carnivora) and structural comparison to other hemoglobin sequences

The complete primary structure of the alpha- and beta-chains of the hemoglobin of Malayan Sun Bear (Helarctos malayanus) is presented. After cleavage of the heme-protein link and chain separation by RP-HPLC, amino-acid sequences were determined by Edman degradation in liquid- and gas-phase sequenators. An interesting result of this work is the demonstration that the hemoglobin of Malayan Sun Bear is identical to the hemoglobins of Polar Bear (Ursus maritimus) and Asiatic Black Bear (Ursus tibetanus). The paper gives an updated table of identical hemoglobin chains from different species. This paper may be considered as a compilation of work on the genetic relationship of Pandas.     

The transhemenation process of bovine and human hemoglobin polymers under conditions simulating the situation in the circulatory bed]

It was shown that transhemenation, i.e. the transfer of heme from hemoglobin to human serum albumin may have the great importance in metabolism of hemoglobin. It was noted that precipitation in the case of human pyridoxal-5'-phosphate modified polyhemoglobin met-derived incubation.     

Binding of 3-hydroxybenzo[a]pyrene to bovine hemoglobin and albumin

Previous studies examined the bioavailability and first-pass biotransformation of 3-hydroxy[(3)H]benzo[a]pyrene ([(3)H]-3-OHBaP) in an isolated perfused catfish intestinal model. This work showed that 3-OHBaP, or a metabolite formed in intestine, bound covalently to blood protein. In this study, the blood adducts were characterized in vitro by incubating bovine ferric hemoglobin or albumin with [(3)H]-3OHBaP under various conditions. Incubation of 2 microM [(3)H]-3-OHBaP with hemoglobin for 1 h resulted in 7.49 pmol bound/mg protein, while albumin binding was 1.37 pmol/mg protein. Mild acid hydrolysis released only 5% of the radioactivity from 3-OHBaP-hemoglobin adducts. After gel filtration, the 3-OHBaP-hemoglobin adducts were examined by HPLC analysis. A single peak of radioactivity was detected at the same retention time as the heme component of hemoglobin. Unbound 3-OHBaP was oxidized to BaP-3,6-dione during incubation with ferric hemoglobin. Treatment of hemoglobin with ascorbic acid decreased the formation of hemoglobin adducts by 33%, while hydrogen peroxide treatment increased adduct formation by 44%. Incubation of [(3)H]-BaP-3-beta-D-glucuronide (BaP-3G) with hemoglobin and beta-glucuronidase resulted in greater binding to hemoglobin than incubation with [(3)H]-3-OHBaP alone. The hemoglobin adduct obtained from [(3)H]-BaP-3G also co-migrated with heme. These results indicate that an oxidative process is involved in formation of the heme adduct and that 3-OHBaP or BaP-3G might be a precursor of the bound metabolite.     

Erythrocyte oxidative damage by myeloperoxidase. The protective action of serum proteins

Influence of main serum proteins (albumin, immunoglobulin G) and proteins-antioxidants (ceruloplasmin, transferrin, superoxide dismutase) on the oxidative damage of erythrocytes by myeloperoxidase and hypochlorite was investigated. The proteins were determined to act as protectors and decrease the degree of hemoglobin oxidation, ceruloplasmin and albumin possessing the highest antioxidant activity.     

Characterization of the heme of cytochrome P-450 using gas chromatography-mass spectrometry

The heme moieties of cytochromes P-450 and P₁-450 (P-448) have been characterized. CO-binding particles, devoid of cytochrome b₅, were prepared from normal or 3-methylcholanthrene-treated animals. Heme was removed by acid-acetone treatment of the CO-binding particles and crystallized. Heme isolated from hemoglobin of the corresponding animals served as a control. Reductive degradation (hydriodic acid) followed by gas chromatography/mass spectrometry analysis indicated the presence of opso-, crypto-, hemo-, and phyllopyrrole. Visible spectra of the iron-free tetrapyrroles isolated from microsomal heme and hemoglobin were identical and showed typical aetioporphyrin spectra. Finally, the mass spectra of the tetrapyrrole dimethyl esters isolated from microsomal heme and hemoglobin were identical to authentic protoporphyrin IX dimethyl ester. These data strongly suggest that the heme of cytochrome P-450 and P₁-450 are identical and are the same the same as that of hemoglobin, namely protoporphyrin IX.     

Oxygen binding and other physical properties of human hemoglobin made in yeast.

Wagenbach et al. (1991, BioTechnology, 9, 57-61) have recently developed a system for producing soluble recombinant tetrameric hemoglobin in yeast: hemoglobin begins to appear 4-5 h after induction with galactose, alpha- and beta-globin chains fold in vivo and endogeneously produced heme is incorporated into hemoglobin tetramers. We have further characterized the oxygen-binding properties, as well as the tetramer stability, of recombinant human Hb A made in yeast. After purification by ion-exchange chromatography, a single band at the same position as normal human Hb A was obtained using cellulose acetate electrophoresis. Although the oxy and deoxy forms of purified recombinant Hb A made in yeast were spectrophotometrically identical to native human Hb A, the oxygen-binding curve was shifted slightly left of that for native human Hb A. Further purification of recombinant hemoglobin by FPLC revealed two fractions: one (fraction B) with low cooperativity and high oxygen affinity, and the other (fraction A) with almost identical cooperativity and oxygen affinity compared with native human Hb A. The Bohr effect of fraction A was also identical to native human Hb A. Hemoglobin in fraction B with lowered cooperativity precipitated approximately 1.5 times faster than normal human Hb A during mechanical agitation, while hemoglobin in fraction A with normal cooperativity precipitated with kinetics identical to native human Hb A. These results suggest that some of the recombinant molecules made in yeast fold improperly, and that these molecules may exhibit decreased cooperativity for oxygen binding and decreased stability.(ABSTRACT TRUNCATED AT 250 WORDS)     

Preparative Gel Electrophoresis at High Sample Load. The Effect of Some Experimental Variables on Separation Performance

The separation of model protein pairs (hemoglobin/ albumin, trypsin/chymotrypsin, hemoglobin A/hemoglobin F) was studied in an apparatus for preparative gel electrophoresis at loads up to 40 mg/cm ²of the cross-sectional area of the gel bed. Separation was favored by higher ionic strength and by longer migration path. Under the conditions used and within the load range studied, increasing total protein load had no adverse effect but increased voltage gradient, temperature, or gel strength were all unfavorable.     

Transport properties of rigid, symmetrical oligomeric structures composed of prolate, ellipsoidal subunits

We have calculated translational and rotational diffusion coefficients and intrinsic viscosities of oligomeric structures composed of n identical subunits having a prolate ellipsoidal shape with axial ratio p. Results are presented for p = 1-6 for a variety of structures with n = 1-6. We compare our results with those obtained by a different modeling procedure, proposed by other workers, in which the monomeric subunit is represented as a string of touching, colinear spheres. If n and an estimate of p are known, the structure of the oligomer can be. in most cases, unambiguously determined by comparison of the experimental oligomer-to-monomer ratios of a given property with the numerical results of this work. As examples of the applicability of our results, we examine the relationship between structure and properties for neurophysin. bovine serum albumin, hemoglobin and phycocyanin.