Significant heterogeneity in the monomer fraction of Glycera dibranchiata hemoglobins. Detection, partial isolation and characterization of several protein components

Nonvertebrate hemoglobins: functions and molecular adaptations

Hemoglobin (Hb) occurs in all the kingdoms of living organisms. Its distribution is episodic among the nonvertebrate groups in contrast to vertebrates. Nonvertebrate Hbs range from single-chain globins found in bacteria, algae, protozoa, and plants to large, multisubunit, multidomain Hbs found in nematodes, molluscs and crustaceans, and the giant annelid and vestimentiferan Hbs comprised of globin and nonglobin subunits. Chimeric hemoglobins have been found recently in bacteria and fungi. Hb occurs intracellularly in specific tissues and in circulating red blood cells (RBCs) and freely dissolved in various body fluids. In addition to transporting and storing O(2) and facilitating its diffusion, several novel Hb functions have emerged, including control of nitric oxide (NO) levels in microorganisms, use of NO to control the level of O(2) in nematodes, binding and transport of sulfide in endosymbiont-harboring species and protection against sulfide, scavenging of O(2 )in symbiotic leguminous plants, O(2 )sensing in bacteria and archaebacteria, and dehaloperoxidase activity useful in detoxification of chlorinated materials. This review focuses on the extensive variation in the functional properties of nonvertebrate Hbs, their O(2 )binding affinities, their homotropic interactions (cooperativity), and the sensitivities of these parameters to temperature and heterotropic effectors such as protons and cations. Whenever possible, it attempts to relate the ligand binding properties to the known molecular structures. The divergent and convergent evolutionary trends evident in the structures and functions of nonvertebrate Hbs appear to be adaptive in extending the inhabitable environment available to Hb-containing organisms.

Anomalously slow cyanide binding to Glycera dibranchiata monomer methemoglobin component II: implication for the equilibrium constant

In comparison to sperm whale metmyoglobin, metleghemoglobin a, methemoglobins, and heme peroxidases, the purified Glycera dibranchiata monomer methemoglobin component II exhibits anomalously slow cyanide ligation kinetics. For the component II monomer methemoglobin this reaction has been studied under pseudo-first-order conditions at pH 6.0, 7.0, 8.0, and 9.0, employing 100-250-fold mole excesses of potassium cyanide at each pH. At 20 degrees C, with micromolar protein concentrations, kobsd varies between 9.11 x 10(-5) s-1 at pH 6.0, 100-fold KCN mole excess, and 1.12 x 10(-2) s-1 at pH 9.0, 250-fold KCN mole excess. Our analysis shows that the concentration-independent bimolecular rate constant (k1app) is small in comparison to those of the other heme proteins. For example, at pH 7.0 it is 0.491 M-1 s-1, compared to 1.1 x 10(5) M-1 s-1 for cytochrome c peroxidase; 111 M-1 s-1 for guinea pig methemoglobin; approximately 400 M-1 s-1 for sperm whale metmyoglobin; and 692 M-1 s-1 for soybean metleghemoglobin a, at the same pH and similar temperatures. Furthermore, our results show that the dissociation rate is extremely slow, with k-1app no larger than 10(-6) s-1. Separation of the bimolecular rate constant into contributions from kCN- (the rate constant for CN- binding) and from kHCN (the rate constant for HCN binding) shows that the former is approximately 90 times greater. These results indicate that cyanide ligation reactions are not instantaneous for this protein, which is important for those attempting to study the ligand-binding equilibria.(ABSTRACT TRUNCATED AT 250 WORDS)