Background: ␣-Hemoglobin stabilizing protein (AHSP) modifies the redox properties of bound ␣-subunits. Results: Isolated hemoglobin subunits exhibit significantly different redox properties compared with HbA. A significant decrease in the reduction potential of ␣-subunits bound to AHSP results in preferential binding of ferric ␣. Conclusion: AHSP⅐␣-subunit complexes do not participate in ferric-ferryl heme redox cycling. Significance: AHSP binding to ␣-subunits inhibits subunit pseudoperoxidase activity.
Previous work suggested that hemoglobin (Hb) tetramer formation slows autoxidation and hemin loss and that the naturally occurring mutant, Hb Providence (HbProv; βK82D), is much more resistant to degradation by HO We have examined systematically the effects of genetic cross-linking of Hb tetramers with and without the HbProv mutation on autoxidation, hemin loss, and reactions with HO, using native HbA and various wild-type recombinant Hbs as controls. Genetically cross-linked Hb Presbyterian (βN108K) was also examined as an example of a low oxygen affinity tetramer. Our conclusions are: (a) at low concentrations, all the cross-linked tetramers show smaller rates of autoxidation and hemin loss than HbA, which can dissociate into much less stable dimers and (b) the HbProv βK82D mutation confers more resistance to degradation by HO, by markedly inhibiting oxidation of the β93 cysteine side chain, particularly in cross-linked tetramers and even in the presence of the destabilizing Hb Presbyterian mutation. These results show that cross-linking and the βK82D mutation do enhance the resistance of Hb to oxidative degradation, a critical element in the design of a safe and effective oxygen therapeutic.
Neisseria gonorrhoeae has the capacity to acquire iron from its human host by removing this essential nutrient from serum transferrin. The transferrin binding proteins, TbpA and TbpB constitute the outer membrane receptor complex responsible for binding transferrin, extracting the tightly bound iron from the host-derived molecule, and transporting iron into the periplasmic space of this Gram-negative bacterium. Once iron is transported across the outer membrane, ferric binding protein A (FbpA) moves the iron across the periplasmic space and initiates the process of transport into the bacterial cytosol. The results of the studies reported here define the multiple steps in the iron transport process in which TbpA and TbpB participate. Using the SUPREX technique for assessing the thermodynamic stability of protein-ligand complexes, we report herein the first direct measurement of periplasmic FbpA binding to the outer membrane protein TbpA. We also show that TbpA discriminates between apo- and holo-FbpA; i.e. the TbpA interaction with apo-FbpA is higher affinity than the TbpA interaction with holo-FbpA. Further, we demonstrate that both TbpA and TbpB individually can deferrate transferrin and ferrate FbpA without energy supplied from TonB.
Bordetella pertussis is the causative
agent of whooping cough. This pathogenic bacterium can obtain the
essential nutrient iron using its native alcaligin siderophore and
by utilizing xeno-siderophores such as desferrioxamine B, ferrichrome,
and enterobactin. Previous genome-wide expression profiling identified
an iron repressible B. pertussis gene
encoding a periplasmic protein (FbpABp). A previously reported
crystal structure shows significant similarity between FbpABp and previously characterized bacterial iron binding proteins, and
established its iron-binding ability. Bordetella growth studies determined that FbpABp was required for
utilization of not only unchelated iron, but also utilization of iron
bound to both native and xeno-siderophores. In this in vitro solution study, we quantified the binding of unchelated ferric iron
to FbpABp in the presence of various anions and importantly,
we demonstrated that FbpABp binds all the ferric siderophores
tested (native and xeno) with μM affinity. In silico modeling augmented solution data. FbpABp was incapable
of iron removal from ferric xeno-siderophores in vitro. However, when FbpABp was reacted with native ferric-alcaligin,
it elicited a pronounced change in the iron coordination environment,
which may signify an early step in FbpABp-mediated iron
removal from the native siderophore. To our knowledge, this is the
first time the periplasmic component of an iron uptake system has
been shown to bind iron directly as Fe3+ and indirectly
as a ferric siderophore complex.
Neisseria gonorrhoeae is an obligate pathogen that hijacks iron from the human iron transport protein, holo-transferrin (Fe2-Tf), by expressing TonB-dependent outer membrane receptor proteins, TbpA and TbpB. Homologous to other TonB-dependent outer membrane transporters, TbpA is thought to consist of a β-barrel with an N-terminal plug domain. Previous reports by our laboratories show that the sequence EIEYE in the plug domain is highly conserved among various bacterial species that express TbpA and plays a crucial role in iron utilization for gonococci. We hypothesize that this highly conserved EIEYE sequence in the TbpA plug, rich in hard oxygen donor groups, binds with Fe3+ through the transport process across the outer membrane through the β-barrel. Sequestration of Fe3+ by the TbpA-plug supports the paradigm that the ferric iron must always remain chelated and controlled throughout the transport process. In order to test this hypothesis here we describe the ability of both the recombinant wild-type plug, and three small peptides that encompass the sequence EIEYE of the plug, to bind Fe3+. This is the first report of the expression/isolation of the recombinant wild-type TbpA plug. Although CD and SUPREX spectroscopies suggest that a non-native structure is observed for the recombinant plug, fluorescence quenching titrations indicate that the wild-type recombinant TbpA plug binds Fe3+ with a conditional log Kd = 7 at pH 7.5, with no evidence of binding at pH 6.3. A recombinant TbpA plug with mutated sequence (NEIEYEN → NEIAAAN) shows no evidence of Fe3+ binding under our experimental set up. Interestingly, in silico modeling with the wild-type plug also predicts a flexible loop structure for the EIEYE sequence under native conditions which once again supports the Fe3+ binding hypothesis. These in vitro observations are consistent with the hypothesis that the EIEYE sequence in the wild-type TbpA plug binds Fe3+ during the outer membrane transport process in vivo.
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