Evolution of ruminant hemoglobins. Thermodynamic divergence of ox and buffalo hemoglobins.

The ligand-binding properties of hemoglobins from two homozygote phenotypes (AA and BB) of water buffalo (Bubalus bubalis) have been characterized by equilibrium and kinetic techniques. In the case of the BB phenotype, the two constituent hemoglobins have been purified and separately analysed. Buffalo hemoglobins display the reduced sensitivity to organic phosphates characteristic of ruminant hemoglobins, their physiological effector probably being the chloride ion. In contrast to the other known hemoglobins from ruminants, all the hemoglobins from the water buffalo display a significant temperature sensitivity, the delta H for oxygen binding in the presence of physiological effectors approaching that of human hemoglobin (delta H = -30.5 kJ/mol O2). This discrepancy with the other ruminant hemoglobins (e.g. ox, delta H = -10.4 kJ/mol O2), whose primary structure is very similar to that of buffalo, hemoglobins might be correlated to the different habitat and phylogenetic history of the two subfamilies (Bos and Bubalus) of Bovidae.     

植物的血红蛋白

近几年来,植物血红蛋白的研究进展十分迅速,豆科植物中与共生固氮无关的血红蛋白基因和包括禾本科植物在内的许多非豆科植物血红蛋白基因的发现使人们对植物血红蛋白有了新的认识,进而把植物血红蛋白分为共生血红蛋白和非共生血红蛋白两种类型。对这两种血红蛋白的性质、功能、基因结构及表达等方面的研究不仅对共生固氮中植物与微生物的相互关系和固氮工程研究;而且对植物细胞的呼吸代谢和耐涝机理等研究有重要价值。     

De novo mutations producing unstable hemoglobins or hemoglobins M

Summary Hemoglobins M and unstable hemoglobins cause clinical syndromes that are transmitted in autosomal dominant fashion. Pedigrees of 50 probands with de novo mutations producing unstable Hb disease or Hb M disease were compiled. Cases were ascertained (1) by screening the relevant literature published from 1950 through 1980 and (2) through personal communication. Additional pedigree data on several published cases were collected, and a depository containing all available information rekated to de novo Hb mutants was established. The 50 probands were born in 14 countries between 1922 and 1976. Paternity was tested in 36% of the cases, and no instance of false paternity was noted.The data were used to test for an association of advanced parental age with the appearance of de novo mutants. Paternal ages at the probands' births ranged from 20 to 50 years, with a mean of 32.7 years. Maternal ages ranged from 18 to 43 years, with a mean of 28.5 years. For each year and country (or, where necessary, for the nearest possible year and/or a demographically similar country), the cumulative frequency distributions of the ages of parents who had a child in that country and year were computed; the ages of each proband's father and mother were then expressed as percentiles on these distributions. The distribution of paternal age percentiles was shifted toward the upper end of the range, with 11 of the 50 paternal ages falling between the 90th and 100th percentiles. The distribution of maternal age percentiles was more complex, with one peak (10 of 50 ages) falling between the 30th and 40th percentiles and a second peak (10 of 50 ages), between the 90th and 100th percentiles. These distributions, though suggestive of an association of advanced parental age and the appearance of de novo mutations that cause unstable Hb disease or methemoglobinemic cyanosis, were not significantly different from those uniform distributions expected in the absence of a parental age effect.     

Plants,humans and hemoglobins

New developments have forced a re-evaluation of our understanding of the structure and function of hemoglobins. Leghemoglobins regulate oxygen affinity through a mechanism different from that of myoglobin using a novel combination of heme pocket amino acids that lower the oxygen affinity. The hexacoordinate hemoglobins are characterized by intramolecular coordination of the ligand binding site at the heme iron, and were first identified in plants as the 'non-symbiotic plant hemoglobins'. They are now known to be present in animals and bacteria. Many of these proteins are upregulated in both plants and animals during hypoxia or similar stresses. Therefore, there might be a common physiological function for hexacoordinate hemoglobins in plants and animals.     

The function of hemoglobins

Haemoglobin is primarily responsible for the oxygen supply and a normal acid-base economy in mammals. An optimal loading of haemoglobin with oxygen in the lungs and a high desaturation in the periphery are ensured by a highly cooperative oxygen binding of 4 subunits as well as by different effectors--2,3 DPG, chloride, pH, temperature...-.A number of differently built-up haemoglobins will ensure a sufficient oxygen supply of individual ontogenetic stages of development in the human organism.     

Root effect hemoglobins

The Root effect describes an extreme pH sensitivity expressed in the hemoglobins of certain fish, in which it plays a unique physiological role. This review describes our general understanding of the effect of protons on the oxygen binding properties of hemoglobin and the particular properties which characterize Root effect proteins. The development of our understanding of the molecular origins of this effect is outlined and the role played by our ever expanding knowledge of protein structure is highlighted. The present state of our knowledge is detailed.     

Structure and reactivity of hexacoordinate hemoglobins

The heme prosthetic group in hemoglobins is most often attached to the globin through coordination of either one or two histidine side chains. Those proteins with one histidine coordinating the heme iron are called "pentacoordinate" hemoglobins, a group represented by red blood cell hemoglobin and most other oxygen transporters. Those with two histidines are called "hexacoordinate hemoglobins", which have broad representation among eukaryotes. Coordination of the second histidine in hexacoordinate Hbs is reversible, allowing for binding of exogenous ligands like oxygen, carbon monoxide, and nitric oxide. Research over the past several years has produced a fairly detailed picture of the structure and biochemistry of hexacoordinate hemoglobins from several species including neuroglobin and cytoglobin in animals, and the nonsymbiotic hemoglobins in plants. However, a clear understanding of the physiological functions of these proteins remains an elusive goal.     

Truncated hemoglobins and nitric oxide action

Truncated hemoglobins (trHbs) build a separate subfamily within the hemoglobin superfamily; they are scarcely related by sequence similarity to (non-)vertebrate hemoglobins, displaying amino acid sequences in the 115-130 residue range. The trHb tertiary structure is based on a 2-on-2 alpha-helical sandwich, which hosts a unique hydrophobic cavity/tunnel system, traversing the protein matrix, from the molecular surface to the heme distal site. Such a protein matrix system may provide a path for diffusion of ligands to the heme. In Mycobacterium tuberculosis trHbN the heme-bound oxygen molecule is part of an extended hydrogen bond network including the heme distal residues TyrB10 and GlnE11. In vitro experiments have shown that M. tuberculosis trHbN supports efficiently nitric oxide dioxygenation, yielding nitrate. Such a reaction would provide a defense barrier against the nitrosative stress raised by host macrophages during lung infection. It is proposed that the whole protein architecture, the heme distal site hydrogen bonded network, and the unique protein matrix tunnel, are optimally designed to support the pseudo-catalytic role of trHbN in converting the reactive NO species into the harmless NO3-.     

Radioimmunochemical characterization of hemoglobins Lepore and Kenya: unique antigenic determinants located on hybrid hemoglobins.

Antisera were produced in rabbits to the three known types of Lepore hemoglobins, which contain hybrid delta-beta non-alpha-chains, and to hemoglobin Kenya, which has a hybrid gamma-beta non-alpha-chain. By using a sensitive radioimmunoassay technique, the absorbed antisera were shown to contain an antibody population that was specific for the hybrid hemoglobin and did not cross-react with normal hemoglobins. However, with the absorbed Lepore-specific antisera, the three known types of Lepore hemoglobins were antigenically indistinguishable from each other, suggesting that antibodies are not produced to the primary structural differences which define the three non-alpha-chains of the Lepore hemoglobins. These studies demonstrate that the non-alpha-subunits of hemoglobins Lepore and Kenya possess unique antigenic determinant sites, evidently resulting from an altered polypeptide conformation.