Isolation of mutants of<Emphasis Type="Italic"> Vibrio anguillarum</Emphasis> defective in haeme utilisation and cloning of<Emphasis Type="Italic"> huvA</Emphasis>, a gene coding for an outer membrane protein involved in the use of haeme as iron source

The isolation of Vibrio anguillarum mutants lacking the ability to use haemin and haemoglobin as the only iron sources, as well as the identification of a gene involved in haeme utilisation are described. One of the isolated mutants defective in haeme utilisation lacked an iron-regulated outer membrane protein of 79-kDa. Although growth on haeme as iron source was completely abolished, the haemin and haemoglobin binding activities remained intact in the mutant, suggesting that the absent protein is not the only one involved in haeme binding. The wild-type phenotype in this mutant was restored by transformation with a cosmid clone (pML1) containing a 21-kb DNA fragment isolated from a gene library derived from the parental strain of V. anguillarum. Sequence analysis of pML1 subclones led to the finding of an ORF, huvA, that codes for a 79-kDa protein (HuvA) and whose sequence shows high identity with haeme receptors from Vibrio choleare (HutA) and Vibrio vulnificus (HupA). The sequence of huvA from the V. anguillarum haeme-utilisation mutant revealed a single mutation, leading to the synthesis of a truncated HuvA protein of 70 kDa. The parental strain and the cosmid-complemented mutant showed a higher degree of virulence for fish than the mutant strain in experimental infections in which fish were previously overloaded with haemin. This finding suggests that haeme uptake plays an important role in V. anguillarum multiplication in fish tissues when free haeme is available.     

Haemoglobin biosynthesis site in rabbit embryo erythroid cells

Properly metabolized globin synthesis and iron uptake are indispensable for erythroid cell differentiation and maturation. Mitochondrial participation is crucial in the process of haeme synthesis for cytochromes and haemoglobin. We studied the final biosynthesis site of haemoglobin using an ultrastructural approach, with erythroid cells obtained from rabbit embryos, in order to compare these results with those of animals treated with saponine or phenylhydrazine. Our results are similar to those obtained in assays with adult mammals, birds, amphibians, reptiles and fish, after induction of haemolytic anaemia. Therefore, the treatment did not interfere with the process studied, confirming our previous findings. Immunoelectron microscopy showed no labelling of mitochondria or other cellular organelles supposedly involved in the final biosynthesis of haemoglobin molecules, suggesting instead that it occurs free in the cytoplasm immediately after the liberation of haeme from the mitochondria, by electrostatic attraction between haeme and globin chains.     

Corynebacterium diphtheriae genes required for acquisition of iron from haemin and haemoglobin are homologous to ABC haemin transporters

Corynebacterium diphtheriae and Corynebacterium ulcerans use haemin and haemoglobin as essential sources of iron during growth in iron-depleted medium. C. diphtheriae and C. ulcerans mutants defective in haemin iron utilization were isolated and characterized. Four clones from a C. diphtheriae genomic library complemented several of the Corynebacteria haemin utilization mutants. The complementing plasmids shared an approximately 3 kb region, and the nucleotide sequence of one of the plasmids revealed five open reading frames that appeared to be organized in a single operon. The first three genes, which we have termed hmuT, hmuU and hmuV, shared striking homology with genes that are known to be required for haemin transport in Gram-negative bacteria and are proposed to be part of an ABC (ATP-binding cassette) transport system. The hmuT gene encodes a 37 kDa lipoprotein that is associated with the cytoplasmic membrane when expressed in Escherichi coli and C. diphtheriae. HmuT binds in vitro to haemin- and haemoglobin-agarose, suggesting that it is capable of binding both haemin and haemoglobin and may function as the haemin receptor in C. diphtheriae. This study reports the first genetic characterization of a transport system that is involved in the utilization of haemin and haemoglobin as iron sources by a Gram-positive bacterium.     

Kinetics and localisation of haemin-induced lipoprotein oxidation

Abstract

Haemin (iron (III)-protoporphyrin IX) is a degradation product of haemoglobin in circulating erythrocytes. Haemin may play a key oxidising agent for lipoprotein oxidation in patients with haemolytic anaemia. In this study, kinetic changes in chemical composition and target sites of haemin-induced LDL and HDL oxidation were investigated. Haemin initially induced the loss of α-tocopherol, followed by accumulation of lipid hydroperoxide (LP) and alteration of core lipid fluidity. The absence of LP in HDL was explained by the antioxidant activity of PON in addition to α-tocopherol. The target site of haemin was evaluated by ESR spin labelling with 5- and 16-doxyl steric acids. In the presence of t-BuOOH and haemin, ESR signal decay of the doxyl moiety demonstrated the initiation phase and the propagation phase of lipid peroxidation. The results of the lag time and the rate of signal decay indicated that haemin is located near the 16th carbon atom of the fatty acid chain in the phospholipid layer. The analyses of motion parameters, order parameter (S) of 5-DS and rotational correlation time (τ) of 16-DS, supported the observation that the lipid properties changed near the hydrophobic region rather than at the surface region of lipoproteins. Moreover, ESR spin labelling demonstrated that haemin molecules but not iron ions caused lipoprotein oxidation. In conclusion, haemin is a potent inducer of lipoprotein oxidation, and the target site for this oxidation is near the hydrophobic core of the lipoprotein leading to the loss of antioxidant activities and changes in lipid composition and physical properties.     

Chronic hemorrhagic iron deficiency. Sources of hemorrhage, blood loss and systematic iron substitution

In only 121/436 (28 per cent) patients with chronic haemorrhagic iron deficiency bleeding sources could be removed by appropriate management or healed spontaneously. In 61 per cent of all cases the disease lasted from 1 year to greater than 20 years. The fall of haemoglobin per month correlated closely with blood losses per month as calculated by determinations of 59Fe whole body iron loss. Over prolonged periods estimations of the magnitude of blood loss (range 1- greater than 721 per year) based on changes of the iron status under normal diets and under systematic iron substitution. Oral iron administration with appraisable bioavailability was able to compensate blood losses up to 151 and with increasing doses up to 361 per year with maintenance of normal or borderline haemoglobin values. However, side reactions increased considerably after years and with rising doses. Under such circumstances combinations of i.v. iron, oral iron and blood transfusions were successful over prolonged periods.     

The hmu locus of Yersinia pestis is essential for utilization of free haemin and haem-protein complexes as iron sources

Yersinia pestis strains utilize haem and several haem-protein complexes as sole sources of iron. In this study, the haemin uptake locus (hmu) of Y. pestis KIM6+ was selected from a genomic library by trans-duction into an Escherichia coli siderophore synthesis (entC) mutant. Recombinant plasmids containing a common 16 kb BamHI insert were isolated that allowed E. coli entC to use haemin as an iron source. An 8.6 kb region of this insert was found to be essential for haemin utilization and encoded at least five proteins with molecular masses of 79/77, 44, 37, 35, and 30/27.5 kDa. A 10.9 kb Clal fragment containing the hmu locus showed varying degrees of homology to genomic DNA from Yersinia pseudotuberculosis, Yersinia enter-ocolitica, and other genera of Enterobacteriaceae. An E. coli hemA aroB strain harbouring cloned hmu genes used haemin as both an iron and porphyrin source but only on iron-poor medium, suggesting that haemin uptake is tightly iron regulated. Additionally, haemoglobin and myoglobin were used as iron sources by an E. coli entC (pHMU2.2) strain. Deletion of the hmu locus from Y. pestis KIM6+ chromosome generated a mutant that grew poorly on iron-depleted medium containing free haemin as well as mammalian haem-protein complexes including haemoglobin, haemoglobin-haptoglobin, myoglobin, haem-haemopexin, and haem-albumin unless it was complemented with cloned hmu genes.     

The Neisseria meningitidis haemoglobin receptor: its role in iron utilization and virulence

The Neisseris meningitidis haemoglobin receptor gene, hmbR, was cloned by complementation in a porphyrin-requiring Escherichia coli mutant. hmbR encodes an 89.5 kDa outer membrane protein which shares amino acid homology with the TonB-dependent receptors of Gram-negative bacteria. HmbR had the highest similarity to Neisseria transferrin and lactoferrin receptors. The utilization of haemoglobin as an iron source required internalization of the haemin moiety by the cell. The mechanism of haemin internalization via the haemoglobin receptor was TonB-dependent in E. coli. A N. meningitidis hmbR mutant was unable to use haemoglobin but could still use haemin as a sole iron source. The existence of a second N. meningitidis receptor gene, specific for haemin, was shown by the isolation of cosmids which did not hybridize with the hmbR probe, but which were able to complement an E. coli hemA aroB mutant on haemin-supplemented plates. The N. meningitidis hmbR mutant was attenuated in an infant rat model for meningococcal infection, indicating that haemoglobin utilization is important for N. meningitidis virulence.     

Formation of protoporphyrin from haemoglobin in vitro

1. The formation of protoporphyrin from red blood cells or purified haemoglobin in aqueous perchloric acid media without the prior isolation of haemin is described. The reaction is carried out in the absence of oxygen and in red light. Even traces of oxygen inhibit the reaction by oxidative destruction of protoporphyrin and by the oxidation of haem to haematin. 2. Perchloric acid releases iron and protoporphyrin from haemoglobin at similar rates, but the amount of protoporphyrin in the filtrate varies with the solubility of protoporphyrin in the concentration of perchloric acid used. The yield of protoporphyrin may reach 50–60%. Less than 5μg. of haemoglobin/ml. can be detected by measuring the fluorescence of the porphyrin released. 3. A porphyrin other than protoporphyrin is obtained in small amounts. Its possible identity is discussed. 4. If sodium sulphite is present as a reducing agent the exclusion of oxygen is not required, but the porphyrin formed is more polar and more soluble in water than protoporphyrin. The presence of oxygen appears to be necessary for the formation of this polar porphyrin.     

The antioxidant activity of haptoglobin towards haemoglobin-stimulated lipid peroxidation

Haemoglobin stimulates the peroxidation of lipids in two discernable phases. The first phase is inhibited by binding haemoglobin to the protein haptoglobin. The second phase is stimulated by complexable iron released from the haemoglobin molecule during the process of lipid peroxidation. This latter peroxidation is inhibitable by transferrin and the iron chelator desferrioxamine. Heat-denatured haemoglobin and haemin both stimulated lipid peroxidation but this is not inhibitable by haptoglobin. It is suggested that the haptoglobins play an important antioxidant role in vivo by preventing iron-stimulated formation of oxygen radicals.     

Haem utilization in Vibrio cholerae involves multiple TonB-dependent haem receptors

Vibrio cholerae has multiple iron transport systems, one of which involves haem uptake through the outer membrane receptor HutA. A hutA mutant had only a slight defect in growth using haemin as the iron source, and we show here that V. cholerae encodes two additional TonB-dependent haem receptors, HutR and HasR. HutR has significant homology to HutA as well as to other outer membrane haem receptors. Membrane fractionation confirmed that HutR is present in the outer membrane. The hutR gene was co-transcribed with the upstream gene ptrB, and expression from the ptrB promoter was negatively regulated by iron. A hutA, hutR mutant was significantly impaired, but not completely defective, in the ability to use haemin as the sole iron source. HasR is most similar to the haemophore-utilizing haem receptors from Pseudomonas aeruginosa and Serratia marcescens. A mutant defective in all three haem receptors was unable to use haemin as an iron source. HutA and HutR functioned with either V. cholerae TonB1 or TonB2, but haemin transport through either receptor was more efficient in strains carrying the tonB1 system genes. In contrast, haemin uptake through HasR was TonB2 dependent. Efficient utilization of haemoglobin as an iron source required HutA and TonB1. The triple haem receptor mutant exhibited no defect in its ability to compete with its Vib- parental strain in an infant mouse model of infection, indicating that additional iron sources are present in vivo. V. cholerae used haem derived from marine invertebrate haemoglobins, suggesting that haem may be available to V. cholerae growing in the marine environment.     

Haem as a multifunctional regulator

Haem has long been known as the prosthetic group of haemoproteins such as haemoglobin, catalase and the cytochromes. Its biosynthesis is regulated by feedback mechanisms that ensure its adequate production but prevent its overaccumulation, which is highly deleterious as diseases such as porphyrias attest. However, recent years have seen rapid strides in our understanding of how haem (or more accurately haemin, its oxidized form) itself acts as an intracellular regulator of a variety of other metabolic pathways for systems that utilize oxygen.     

The role of a 70 kDa nuclear protein in fetal haemoglobin synthesis in K562 cells

Abstract. Previously, we reported that a 70 kDa nuclear protein may regulate fetal haemoglobin gene expression in haemin treated K562 cells. To obtain further evidence of the specific role of this 70 kDa nuclear protein, we compared the nuclear fractions isolated from phenylacetate, hydroxyurea and haemin treated K562 cells. Both phenylacetate and hydroxyurea have been used to induce fetal haemoglobin synthesis in K562 cells. Cell growth was measured by biochemical events including DNA, RNA and protein synthesis. Differentiation of K562 cells was determined by both [³H]-leucine incorporation into fetal haemoglobin and scoring benzidine-stained positive cells. Unlike the haemin treated cells, phenylacetate and hydroxyurea induced growth arrest and increased fetal haemoglobin gene expression in K562 cells. After four days of treatment with phenylacetate and hydroxyurea more than 50% of the cells stained positive with benzidine. The SDS-Polyacrylamide gel electrophoretic analysis of nuclear proteins isolated from phenylacetate and hydroxyurea treated K562 cells showed that the 70 kDa protein was reduced in nuclear protein extract in both groups similar to haemin treated cells. These results suggest that the loss of the 70 kDa protein from a nuclear protein extract is not restricted to only haemin treated cells but also occurs in hydroxyurea and phenylacetate treated cells. Our results provide further evidence that the 70 kDa nuclear protein may be involved in regulating fetal haemoglobin expression through a negative control mechanism.     

Radiation induced structural and functional modification of haemoglobin

An abnormality in the primary structure of dog haemoglobin was observed 1-20 days after their whole body irradiation with 190 keV X-rays (4.0 Gy). It consisted in a substitution of tryptophane residue in position 15 of the beta-chain for serine. The percentage of abnormal beta-chains in different time intervals after irradiation was determined. The structural changes have functional impact: an increasing haemoglobin affinity to oxygen. This could be explained on the basis of changes in the tertiary structure of haemoglobin, which may result from the substitution Trp 15----Ser15 in the beta-chain which may influence the haeme ability to bind oxygen.     

Inositol tripyrophosphate: a new membrane permeant allosteric effector of haemoglobin

Nine inositol tripyrophosphate (ITPP) salts have been synthesized. Their ability to act as allosteric effectors of haemoglobin (Hb) has been measured in vitro with free Hb and whole blood. All the synthesized compounds bound to free Hb and were also able to cross, to a certain extent, the plasma membrane of the red blood cells (RBCs) in whole blood samples, lowering the affinity of Hb for oxygen. The oxy-haemoglobin dissociation curves were significantly shifted towards higher values of oxygen partial pressures, both for free Hb and for intracellular Hb in whole blood.     

Some Effects of Protein Deficiency in Young Growing Pigs. III. Ferrokinetic Investigations

Ferrokinetic investigations have been carried out in pigs which had undergone protein starvation and rehabilitation. After long term protein deprivation haematocrit levels, blood haemoglobin levels, serum iron concentrations, serum total iron binding capacity and blood volume per kg body weight were all reduced in the deficient animals. The values for the rehabilitated animals were in the normal range. The erythrocytes of the protein starved pigs showed an increased rate of uptake of radioactive iron compared with the control pig. However, the turnover of iron as a whole was reduced greatly in the protein deprived group compared to the rehabilitated and control pigs. Accumulation of iron occurred in the livers, spleens and kidneys of the protein starved animals. The rehabilitated pigs had lower liver stores of iron than the control pig. On the basis of the data presented it has been concluded that these effects are mainly due to a shortage of amino acids for protein synthesis.     

Chemical and transient state kinetic studies on the formation and decomposition of horseradish peroxidase compounds XI and XII

Previous studies on the chlorination reaction catalyzed by horseradish peroxidase using chlorite as the source of chlorine detected the formation of a chlorinating intermediate that was termed Compound X (Shahangian, S., and Hager, L.P. (1982) J. Biol. Chem. 257, 11529-11533). These studies indicated that at pH 10.7, the optical absorption spectrum of Compound X was similar to the spectrum of horseradish peroxidase Compound II. Compound X was shown to be quite stable at alkaline pH values. This study was undertaken to examine the relationship between the oxidation state of the iron protoporphyrin IX heme prosthetic group in Compound X and the chemistry of the halogenating intermediate. The experimental results show that the optical absorption properties and the oxidation state of the heme prosthetic group in horseradish peroxidase are not directly related to the presence of the activated chlorine atom in the intermediate. The oxyferryl porphyrin heme group in alkaline Compound X can be reduced to a ferric heme species that still retains the activated chlorine atom. Furthermore, the reaction of chlorite with horseradish peroxidase at acidic pH leads to the secondary formation of a green intermediate that has the spectral properties of horseradish peroxidase Compound I (Theorell, H. (1941) Enzymologia 10, 250-252). The green intermediate also retains the activated chlorine atom. By analogy to peroxidase Compound I chemistry, the heme prosthetic group in the green chlorinating intermediate must be an oxyferryl porphyrin pi-cation radical species (Roberts, J. E., Hoffman, B. M., Rutter, R. J., and Hager, L. P. (1981) J. Am. Chem. Soc. 103, 7654-7656). To be consistent with traditional peroxidase nomenclature, the red alkaline form of Compound X has been renamed Compound XII, and the green acidic form has been named Compound XI. The transfer of chlorine from the chlorinating intermediate to an acceptor molecule follows an electrophilic (rather than a free radical) path. A mechanism for the reaction is proposed in which the activated chlorine atom is bonded to a heteroatom on an active-site amino acid side chain. Transient state kinetic studies show that the initial intermediate, Compound XII, is formed in a very fast reaction. The second-order rate constant for the formation of Compound XII is approximately 1.1 x 10(7) M-1 s-1. The rate of formation of Compound XII is strongly pH-dependent. At pH 9, the second-order rate constant for the formation of Compound XII drops to 1.5 M-1 s-1. At acidic pH values, Compound XII undergoes a spontaneous first-order decay to yield Compound XI.(ABSTRACT TRUNCATED AT 400 WORDS)     

Release of iron from haemoglobin--a possible source of free radicals in diabetes mellitus

Increased blood glucose in diabetes mellitus stimulates nonenzymatic glycosylation of several proteins, including haemoglobin. Although iron is tightly bound to haemoglobin, it is liberated under specific circumstances yielding free reactive iron. Studies with purified haemoglobin from normal individuals and diabetic patients revealed that concentration of free iron was significantly higher in the latter cases and increased progressively with extent of the disease. In vitro glycosylation of haemoglobin also led to increase in release of iron from protein. This increase in free iron, acting as a Fenton reagent, might produce free radicals, which, in turn might be causing oxidative stress in diabetes.     

A realistic evaluation of the action of ozone on whole human blood

We have clarified the role of the ozone concentration in relation to the resistance of human erythrocytes in whole human blood or in blood diluted either in saline or in distilled water.

Spectrophotometric data related to haemoglobin were evaluated by exposing samples of fresh human blood directly to ozone doses (ratio 1:1 volume), within the therapeutic range (0.21–1.68 mM) and to one toxic dose (3.36 mM). Furthermore, the same determinations have been carried out after previous dilution of the same blood with either pure water or physiological saline (1 ml blood + 29 ml diluent) followed by ozonation with the above reported ozone doses. Addition of either saline or water implies a dilution of plasma antioxidants and also total haemolysis after water dilution. Particularly the latter case represents a most unphysiological situation because the osmotic shock causes the solubilization of the erythrocytic content. While it is possible to demonstrate that after haemolysis there is an ozone-concentration dependent transformation of some oxyhaemoglobin to methaemoglobin, no such process occurs after ozonation of whole blood.

The results of this study fully confirm our previous data that judicious ozone doses neither damage erythrocytes, nor induce oxidation of intracellular haemoglobin. We hope that our conclusions will definitively clarify the absence of toxicity of ozonetherapy.     

Iron acquisition systems for ferric hydroxamates, haemin and haemoglobin in Listeria monocytogenes

Listeria monocytogenes is a Gram-positive bacterium that causes severe opportunistic infections in humans and animals. We biochemically characterized, for the first time, the iron uptake processes of this facultative intracellular pathogen, and identified the genetic loci encoding two of its membrane iron transporters. Strain EGD-e used iron complexes of hydroxamates (ferrichrome and ferrichrome A, ferrioxamine B), catecholates (ferric enterobactin, ferric corynebactin) and eukaryotic binding proteins (transferrin, lactoferrin, ferritin, haemoglobin). Quantitative determinations showed 10-100-fold lower affinity for ferric siderophores (Km approximately 1-10 nM) than Gram-negative bacteria, and generally lower uptake rates. Vmax for [59Fe]-enterobactin (0.15 pMol per 10(9) cells per minute) was 400-fold lower than that of Escherichia coli. For [59Fe]-corynebactin, Vmax was also low (1.2 pMol per 10(9) cells per minute), but EGD-e transported [59Fe]-apoferrichrome similarly to E. coli (Vmax=24 pMol per 10(9) cells per minute). L. monocytogenes encodes potential Fur-regulated iron transporters at 2.031 Mb (the fur-fhu region), 2.184 Mb (the feo region), 2.27 Mb (the srtB region) and 2.499 Mb (designated hupDGC region). Chromosomal deletions in the fur-fhu and hupDGC regions diminished iron uptake from ferric hydroxamates and haemin/haemoglobin respectively. In the former locus, deletion of fhuD (lmo1959) or fhuC (lmo1960) strongly reduced [59Fe]-apoferrichrome uptake. Deletion of hupC (lmo2429) eliminated the uptake of haemin and haemoglobin, and decreased the virulence of L. monocytogenes 50-fold in mice. Elimination of srtB region genes (Deltalmo2185, Deltalmo2186, Deltalmo2183), both sortase structural genes (DeltasrtB, DeltasrtA, DeltasrtAB), fur and feoB did not impair iron transport. However, deletion of bacterioferritin (Deltafri, lmo943; 0.97 Mb) decreased growth and altered iron uptake: Vmax of [59Fe]-corynebactin transport tripled in this strain, whereas that of [59Fe]-apoferrichrome decreased 20-fold.