Efficiency of Converting Iron into Hemoglobin as an Assay for Evaluating Iron Bioavailability

Whittaker, Paul

01 May 1983

The effect of iron absorption on subsequent hemoglobin regeneration was investigated by repletion and subsequent analysis of an anemic weanling rat model. Primary assay procedure in these studies was the Regeneration Efficiency method. As repletion or curative assay techniques form the central body of investigative research in iron utilization, the first subject of inquiry was the effect of repletion interval and degree of depletion upon the animals as monitored by physical indicators such as blood volume, growth and hematinic response. Percent blood volume is a particularly useful figure in the calculation of the amount of hemoglobin iron but was found to be relatively constant in a preliminary experiment. Accordingly, the effects of growth and anemia on hemoglobin response and blood volume were examined in 122 weanling male rats which had been depleted for seven days by low iron diet and phlebotomy, then repleted by feeding iron rich diet (47.1 ppm) for zero, five, 10 and 15 days. Percent blood volume proved to be rather constant at 7.5 in these pre-pubescent animals. The most severely depleted animals appeared to regenerate hemoglobin initially rather than replenish tissue iron. Regeneration Efficiency and AOAC assay methods were compared in a study involving the relative potency of two iron salts, ferrous sulfate and ferric orthophosphate, and three commercial cereal sources containing electrolytically reduced, hydrogen reduced or ferric orthophosphate supplements. These two assays utilized 202 albino male weanling rats. The superior availability of ferrous sulfate was evident in both regeneration efficiency and AOAC assays, as was the relative similarity of the dietary iron sources, yet the commercial sources in general provided more available iron in comparison to the reference ferrous sulfate than expected, possibly due to the influence of dietary components and processing variables. Bioavailability based on dietary iron concentration response correlated highly (r = 0.94) between animal groups analyzed using the Regeneration Efficiency and AOAC methods. Stress may have been a factor in animals assayed by the AOAC technique which used a 28 day depletion interval followed by a two week repletion. The Regeneration Efficiency method, which utilizes shorter depletion and repletion intervals also offered sufficient amounts of dietary iron for normal growth. The calculation of iron bioavailability also is dependent on such pertinent variables as dietary intake amount, body weight gain and percent blood volume.

Efficiency

converting iron

hemoglobin

assay

iron bioavailability

Food Science

Nutrition

It's in the blood : the varieties of Linus Pauling's work on hemoglobin and sickle cell anemia

Gormlet, Melinda (Melinda Brooke)

22 October 2003

Linus Pauling incorporated hemoglobin and a disease of the blood, sickle cell anemia, into many of his researches between the mid-1930s and mid-1970s. In the early 1930s Pauling became interested in organic chemistry and named hemoglobin as one of the first biochemical substances that he planned to analyze. In 1935 he published his first paper on hemoglobin, which determined the structure of the four hemes in hemoglobin. Pauling continued to study the structure of hemoglobin until the early 1950s when he proposed that it was an alpha-helix. In 1945 Pauling learned about sickle cell anemia and published an important paper in 1949 with Harvey A. Itano, S.J. Singer, and Ibert C. Wells titled "Sickle Cell Anemia, a Molecular Disease." Pauling investigated hemoglobin into the mid-1970s when he tried to find an orthomolecular therapy for sickle cell anemia. From the mid-1950s to early 1970s, Pauling also used sickle cell anemia to promote negative eugenics, point out the possible mutagenic effects caused by nuclear weapons testing, and propose an evolutionary theory. Additionally, in the final year of his life, Pauling wrote two forewords for books on sickle cell anemia, which were published in 1994, the year he died. Hemoglobin and sickle cell anemia can be considered a theme within Pauling's work. He often returned to normal and abnormal hemoglobin as his primary substance for examination, and his familiarity with hemoglobin and sickle cell anemia inspired new research. / Graduation date: 2004

Pauling, Linus, 1901-1994

Hemoglobin

Sickle cell anemia

Evaluation of desiccation-induced oxidative injury in human red blood cells

Kanias, Tamir

11 1900

The current practice of red blood cell banking for transfusion medicine relies primarily on a six-week liquid storage. A growing demand for red blood cell (RBC) products has prompted the search for alternative preservation methods including dry storage. Being desiccation sensitive, attempts to recover RBCs from the dry state have failed. This dissertation offers a new mechanistic understanding of desiccation-induced cellular injury that is correlated with the oxidative state of the hemoglobin. The general hypothesis states that RBC desiccation is accompanied with non-physiological oxidation of hemoglobin and, consequently, the release of toxic products capable of compromising cellular recovery through oxidative injury. Data acquired for this dissertation demonstrates that water loss induces a drastic increase in the rate of hemoglobin oxidation, formation of intracellular reactive oxygen species (ROS), and hemolysis. Pharmacological treatments of the hemoglobins oxygen binding site reveal that hemoglobin-induced cellular injury is more prominent in RBC samples that are partially dehydrated (about 3.5 to 5.5 g H2O/g dry weight) than in samples that are relatively dry ( 2 g H2O/g dry weight). Furthermore, partially dehydrated RBC samples contain higher levels of oxidized lipids than more fully dried samples. This dissertation also examined the role that glucose and glutathione play in enhancing desiccation tolerance of RBCs. Glucose treatment (5 mmol/L) significantly reduced ROS formation and hemolysis levels in partially dehydrated RBC samples (5.8 0.3 g H2O/g dry weight), but not in samples that are relatively dry (2.8 0.5 g H2O/g dry weight). Treating RBCs with DL-buthionine-(S,R)-sulfoximine, a glutathione depleting agent, was correlated with reduced levels of desiccation-induced hemolysis. This study suggests that desiccation-induced oxidative injury in RBCs is water dependent corresponding to earlier stages of water loss, in which cells can retain metabolic activity. Pharmacological treatments at this stage can significantly affect cell recovery as demonstrated with modifying the hemoglobins oxygen binding site, glutathione depletion, and glucose supplementation. On the other hand, increased cytoplasmatic viscosity compromises biochemical reactions at lower residual moisture contents, and cellular injury is likely the result of physical and mechanical stress. These differences should be taken into consideration in the design of innovative approaches to RBC preservation.

dessication

hemoglobin oxidation

reactive oxygen species

red blood cells

Ligand Diffusion Pathways and Mechanisms for Regulating Oxygen Affinity in Two Model Invertebrate Globins: The E7 Gate and Apolar Tunnel

January 2011

The major pathway for O 2 binding to mammalian myoglobins (Mbs) and hemoglobins (Hbs) involves transient outward movements of the distal histidine (HisE7), which allows ligand migration into the distal portion of the heme pocket. This E7 gate pathway appears dominant in vertebrate Hbs and Mbs. However, a number of invertebrate globins, including the dimeric hemoglobin from the blood clam Scapharca inaequivalvis (ScHbI), have an inverted quaternary structure in which an EF:FE dimer interface appears to block the HisE7 gate. Another set of globins, including the mini-hemoglobin from the Nemertean sea worm Cerebratulus lacteus (CerHb), are missing the N-terminal A-helix, which results in an internal tunnel between the E- and H-helices. This apolar channel has been suggested to represent an alternative to the HisE7 gate pathway. To determine the roles of the E7 gate and alternative pathways, we have systematically examined the effects of mutations at the E7 position in ScHbI and CerHb and at 21 other positions along the polar channel in CerHb. As was observed for SwMb and HbA, there is a progressive decrease in the bimolecular rate constants for O 2 binding to ScHbI as the size of the amino acid at position E7 is increased from Ala to Trp. This pattern is unaffected when ScHbI is completely converted to the R- or high affinity quaternary state by the F97Y mutation or when the dimer interface is completely disrupted by the K30D mutation. In contrast, E7 mutations have little affect on the rates of ligand entry and escape in CerHb. Instead, ligands diffuse through the apolar channel between the E- and H-helices as judged by decreases in both overall association and dissociation rate constants and increases in the extent of geminate recombination when the channel is blocked by small to large amino acid mutations. In SwMb, these trends are only observed when the small to large mutations are constructed at or near the E7 gate or directly in the distal pocket where ligands are captured. Thus, it is clear that globins have evolved more than one pathway for rapid O 2 uptake and release.

Pure sciences

Hemoglobin

Ligand diffusion

Oxygen binding

Biochemistry

The effects of carbonated beverages on arterial oxygen saturation, serum hemoglobin concentration and maximal oxygen consumption

Waibler, Max

21 August 1991

Elite milers, Sir Roger Bannister and Joseph Falcon, have stated that the consumption of carbonated beverages hinders the performance of aerobic events. Oxygen transport is purportedly impaired by the consumption of carbonated beverages. The research on carbonated beverages has been limited to the effects on the digestive system, gastric emptying, and thermal heat stress in animals. The purpose of this study was to investigate the effects of consuming 28 ounces of carbonated beverages per day, for three weeks, on arterial oxygen saturation (Sa0₂), serum hemoglobin concentrations (Hb), and maximal oxygen consumption (VO₂max) in experienced cyclists. Nine competitive cyclists and triathletes (aged 19-24 years, M = 21.67 years), with average weights and percent body fat of 76.51 kg and 11.4 percent respectively, were randomly assigned to a three week period of consuming 28 ounces of carbonated water or a three week period of no carbonated beverages. At the end of each three week period, a 5 c.c. blood sample was taken for Hb determination and the subjects performed a test of maximal oxygen consumption on a cycle ergometer while Sa0₂ was being monitored. The groups then crossed-over with respect to their treatment, and after another three week period, the same variables were measured. The Student's t statistic was used to compare Sa0₂, Hb, and VO₂max. The results showed no significant differences between the carbonated period (C) and the noncarbonated period (NC) in Sa0₂ (94.00 vs 93.22 %, p= 0.21), Hb (13.71 vs 14.12 g/dl, p= 0.11), and VO₂max (4.63 vs 4.65 Imin, p= 0.92). From this study, it appears that the consumption of carbonated beverages does not affect the variables associated with the oxygen carrying capacity of blood (Sa0₂ and Hb) or the test of aerobic performance (V0₂max) / Graduation date: 1992

Carbonated beverages

Oxygen -- Physiological transport

Hemoglobin

Oxygen in the body

Development of a Multiphoton Photoacoustic Microscope

Shelton, Ryan 1983-

14 March 2013

Cellular/subcellular imaging of biological tissue is an important tool for understanding disease mechanisms. Many current techniques for subcellular absorption contrast imaging, such as two-photon excited fluorescence (TPEF), require exogenous contrast agents to gain access to many naturally occurring biomolecules. Non-fluorescent biomolecules must have a fluorescent marker (tag) chemically bound in order to be observed by TPEF. Contrast agents and markers, while effective, are not an optimal solution because they can change the local environment in the biological system and require FDA approval for human use. Photoacoustic microscopy (PAM) is an imaging modality with high endogenous absorption contrast and penetration depth due to its ability to detect acoustic waves, which are attenuated much less than light in tissue. However, this technique suffers from poor axial resolution, precluding it from consideration for subcellular imaging. This manuscript describes the author's efforts to improve the axial resolution of traditional PAM by merging it with pump-probe spectroscopy. Pump-probe spectroscopy is a non-linear optical technique that exploits a physical process called transient absorption, providing spatial resolution equivalent to two-photon microscopy and access to molecular-specific traits, such as the ground state recovery time and transient absorption spectrum. These traits provide molecular contrast to the imaging technique, which is highly desirable in a complex, multi-chromophore biological system. In this manuscript, a novel technique called transient absorption ultrasonic microscopy (TAUM) is designed and characterized in detail. A second-generation TAUM system is also described, which improves speed and sensitivity of TAUM by up to 1000-fold. This system is validated by collecting volumes of red blood cells in blood smears and tissue samples. These results constitute the first time single cells have been fully resolved using a photoacoustic microscope. Finally, the TAUM system is modified to measure chromophore ground state recovery times. This technique is validated by measuring the recovery time of Rhodamine 6G, which matches well with published values of the fluorescence lifetime. Recovery times of oxidized and reduced forms of hemoglobin are also measured and shown to statistically differ from one another, suggesting the possibility of subcellular measurements of oxygen saturation in future iterations of TAUM.

ultrahigh resolution

hemoglobin

blood

transient absorption

microscopy

photoacoustic

Evaluation of a Flow Cytometry Method for Identifying and Quantifying Fetal Red Blood Cells in Maternal Blood

Nilsson, Camilla

January 2011

Hemoglobin is an oxygen binding protein in erythrocytes. Hemoglobin is composed of four polypeptide chains. During the fetal stage the type of hemoglobin called fetal hemoglobin (HbF) dominates. After birth HbF is replaced by adult hemoglobin (HbA). HbF persists in concentrations less than 1%. Elevated concentration of HbF in adults exists in different conditions, Talassemi for example. When the uterus is damaged and the fetus doesn’t feel well its blood can pass the placenta barrier and enter the blood stream of the mother. A venous blood sample from the mother is analyzed to determine the status of the fetus. Laboratory Medicine Västernorrland already has two methods for analyzing HbF, one routine and one on call. The routine method needed to be replaced and the possibility to use flow cytometry was investigated. In this study, results from flow cytometry using Fetal Cell Count™ kit was compared to the results from the presently used methods, Kleihauer-Betke and HPLC. Cord blood was diluted with venous blood from an adult with the same blood group in various concentrations. A number of tests were performed and showed a fairly good correlation between the different methods. However more tests will be necessary to draw any clear conclusion.

Kleihauer-Betke

Fetomaternal hemorrhage

Fetal hemoglobin

HPLC

Cord blood

Thermodynamic Investigations of Metalloproteins: Metal as Probe and Protein as Probe

Siburt, Claire Jarvis Parker

January 2010

<p>In this dissertation several metalloproteins, both metal transport proteins and the classic metalloprotein hemoglobin, are investigated using a variety of biophysical and electrochemical techniques. In each case, thermodynamic measurements provide insight into the role and mode of action of the metalloprotein under investigation. In Chapters 2 and 3, we focus on the thermodynamic properties of the metal while bound by the protein. In Chapter 4, we focus on the thermodynamic properties of the protein with and without the metal. In Chapter 5, we utilize both the metal and the protein as our probe.</p> <p>In Chapter 2, we probe the thermodynamic properties of the heme-bound iron to elucidate the structure-function relationships underlying two important physiological responses of hemoglobin (Hb): the Root Effect of hemoglobin from certain fish and the different nitrite reactivities of hemoglobins from clams. Hemoglobins of some fish exhibit significantly lowered oxygen affinity at low pH, allowing for proton-mediated release of O₂. This phenomenon, known as the Root Effect, serves as a proton-driven pump delivering O₂ to the swim bladders and eyes of the fish. The clam, ,<italic>L. pectinata</italic>, expresses functionally distinct Hb I that transports H₂S and Hb II that transports O₂. These two hemoglobins differ widely in their reactivity with nitrite, a reactant of great importance to the study of vasodilation in humans. The structural basis of the extreme pH-sensitivity of the Root Effect Hbs and the extreme reactivities of the <italic>Lucina Hbs</italic> with nitrite are debated. Focusing on the metal as the probe, we investigate the reduction potentials of these Hbs using spectroelectrochemistry and compare our findings with oxygen binding studies performed by our collaborators. In both cases, our data strongly suggest that steric hindrance is the determining factor governing the respective physiological response of each hemoglobin. </p> <p>In Chapter 3, we again use the metal as the probe to determine the reduction potential of titanium bound by transferrin (Tf). Tf is the human iron transport protein that can also bind titanium. To address the possible mechanisms of titanium transport through the hypothesized redox-mediated Fe₂-Tf transport pathway, a modified spectroelectrochemistry (SEC) method was developed to measure the electrochemical properties of metalloproteins with very negative potentials. However, the reduction potential of Ti₂-Tf is far too negative to access with our system. As an alternative approach, the redox properties of several model titanium and iron compounds were characterized in order to develop a linear free energy relationship (LFER) allowing us to estimate the reduction potential of Ti₂-Tf to be ca. -900 mV vs. NHE. Our results indicate that the reduction potential of Ti₂-Tf is too low to be reduced by biological reducing agents and suggest that transferrin-mediated titanium transport follows a different mechanism than iron transport.</p> <p>In Chapter 4, our focus shifts to the thermodynamic properties of the protein. Some pathogenic Gram-negative bacteria such as <italic>N. gonorrhoeae</italic> steal iron from their human host by expressing a receptor (TbpA/TbpB), which binds the human iron transport protein transferrin (Tf). Once iron crosses the outer membrane, ferric binding protein (FbpA) transports it across the periplasm to the cytosol. Focusing on the protein, we investigated the protein-protein interactions involved in this transport process and the roles that TbpA and TbpB play with the use of an H/D exchange and mass spectrometry based method termed SUPREX. We report herein the first direct measurement of periplasmic FbpA binding to the outer membrane protein TbpA and we demonstrate that both TbpA and TbpB individually can deferrate Tf without energy supplied from TonB, resulting in sequestration by apo-FbpA.</p> <p>In Chapter 5, we extend our investigation of the <italic>N. gonorrhoeae</italic> iron uptake system by using the metal as the probe in one case and the protein as the probe in another case. TbpA, the &#946;-barrel receptor protein that is required for utilization of Fe₂-Tf as an iron source, has a plug domain which we hypothesize binds iron and interacts with FbpA on the periplasmic side of the outer membrane. Utilizing SUPREX to monitor the thermodynamic properties of protein folding, we investigate 1) the possible interactions between the TbpA-plug and FbpA and 2) the ability of the TbpA-plug to bind iron. </p> <p>Focusing on the metal as the probe, we designed an experimental apparatus to investigate the possible thermodynamic effects of the TbpA/TbpB receptor on the release of iron from Tf. We report the use of a competitive iron chelator and equilibrium dialysis allows for the spectroscopic monitoring of iron release from Tf in the absence of FbpA, but in the presence of opaque bacterial membrane preparations containing the receptor.</p> / Dissertation

Chemistry, Biochemistry

Chemistry, Inorganic

Bioinorganic

Hemoglobin

Iron

Redox

Spectroelectrochemistry

Transferrin

Subunit Disassembly of Human Hemoglobin and the Site-specific Roles of Its Cysteine Residues

Kan, Heng-I

28 July 2012

Hemoglobin plays an important role in transporting oxygen in human beings and other mammals. Hemoglobin is a tetrameric protein composed of two alpha and two beta subunits. The £\ and £] subunits are both necessary and the stoichiometric ratio of the two dislike subunits is critical for hemoglobin to perform its oxygen-carrying function properly. To better understand the coupling between the £\ and £] subunits and the subunit disassembly pathway, p-hydroxymercuri-benzoate (PMB) has been used to react with the cysteine residues in hemoglobin. The hemoglobin tetramer becomes unstable and disassembles into £\ and £] subunits when the cysteine sites are perturbed upon reacting with PMB. There are three kinds of cysteine residues, £]93, £\104 and £]112, in human hemoglobin. The reactivity of different cysteine residues with PMB and their reaction sequence have been studied via the Matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS). The resonance Raman spectroscopy has been used to investigate the structural changes of hemoglobin accompanying the PMB-modification under the oxygenated and deoxygenated conditions. At last, a hemoglobin subunit disassembly mechanism is proposed and the site-specific roles of cysteine residues in human hemoglobin are discussed in detail.

resonance Raman spectroscopy

MALDI-TOF MS

Cysteine

Hemoglobin

Subunit disassembly

Design and Optimize a Two Color Fourier Domain Pump Probe Optical Coherence Tomography System

Jacob, Desmond

16 January 2010

Molecular imaging using fluorescence spectroscopy-based techniques is generally inefficient due to the low quantum yield of most naturally occurring biomolecules. Current fluorescence imaging techniques tag these biomolecules chemically or through genetic manipulation, increasing the complexity of the system. A technique capable of imaging these biomolecules without modifying the chromophore and/or its environment could provide vital biometric parameters and unique insights into various biological processes at a molecular level. Pump probe spectroscopy has been used extensively to study the molecular properties of poorly fluorescing biomolecules, because it utilizes the known absorption spectrum of these chromophores. Optical Coherence Tomography (OCT) is an optical imaging modality that harnesses the power of low coherence interferometry to measure the 3-D spatially resolved reflectivity of a tissue sample. We plan to develop a new molecular imaging modality that combines these techniques to provide 3-D, highresolution molecular images of various important biomolecules. The system uses a Fourier domain OCT setup with a modified sample arm that combines the "pump" and "probe" beams. The pump beam drives the molecules from the ground state to excited state and the probe interrogates the population change due to the pump and is detected interferometrically. The pump and the probe beam wavelengths are optimized to maximize absorption at the pump wavelength and maximize the penetration depth at the probe wavelength. The pump-probe delay can be varied to measure the rate at which the excited state repopulates the ground state, i.e., the ground state recovery time. The ground state recovery time varies for different chromophores and can potentially be used to identify different biomolecules. The system was designed and optimized to increase the SNR of the PPOCT signals. It was tested by imaging hemoglobin and melanin samples and yielded encouraging results. Potential applications of imaging hemoglobin using this technique include the mapping of tissue microvasculature and measuring blood-oxygen saturation levels. These applications could be used to identify hypoxic areas in tissue. Melanin imaging can provide means of demarcation of melanoma in various organs such as skin, eye and intestines.