Evolution of ruminant headgear: a review

The horns, ossicones and antlers of ruminants are familiar and diverse examples of cranial appendages. We collectively term ruminant cranial appendages 'headgear'; this includes four extant forms: antlers (in cervids), horns (in bovids), pronghorns (in pronghorn antelope) and ossicones (in giraffids). Headgear evolution remains an open and intriguing question because phylogenies (molecular and morphological), adult headgear structure and headgear development (where data are available) all suggest different pictures of ruminant evolution. We discuss what is known about the evolution of headgear, including the evidence motivating previous hypotheses of single versus multiple origins, and the implications of recent phylogenetic revisions for these hypotheses. Inclusion of developmental data is critical for progress on the question of headgear evolution, and we synthesize the scattered literature on this front. The areas most in need of attention are early development in general; pronghorn and ossicone development in particular; and histological study of fossil forms of headgear. An integrative study of headgear development and evolution may have ramifications beyond the fields of systematics and evolution. Researchers in organismal biology, as well as those in biomedical fields investigating skin, bone and regenerative medicine, may all benefit from insights produced by this line of research.     

Water buffalo (Bubalus bubalis) hemoglobins: an electrophoretic and chromatographic study

1. Hemoglobins from three phenotypes of Italian water buffalo (Bubalus bubalis), named AA, AB and BB, were selected by starch gel electrophoresis at alkaline pH and analyzed using polyacrylamide gel isoelectric focusing and subsequent analysis of titration curves to reveal differences between two types of hemoglobin identified as Hb fast and Hb slow. 2. Globins from Hb fast and Hb slow were purified by fast protein liquid chromatography (FPLC). Electrophoretic differences were found in the respective alpha-chains using polyacrylamide gel disc-electrophoresis at acid pH, polyacrylamide gel isoelectric focusing and by subsequently analyzing titration curves. 3. The results suggest that the alpha chains of Hb fast and Hb slow, called I alpha and II alpha, respectively, differ in at least two aminoacid residues. Subsequently, these amino acids were identified as lysine and cysteine.     

Spectroscopic properties of the nitric oxide derivative of ferrous man, horse, and ruminant hemoglobins: a comparative study.

The spectroscopic (EPR and absorbance) properties of the nitric oxide derivative of ferrous man, horse, buffalo, deer, mouflon, musk ox, ox, and reindeer hemoglobin (HbNO) have been investigated in the absence of any allosteric effector at pH 6.5 (in 0.1 M 2-[N-morpholino]ethanesulphonic acid/NaOH chloride-free buffer system), as well as at 100 K and/or 20 degrees C. Man and horse HbNO show spectroscopic properties that are generally taken as typical of the high affinity state of ferrous tetrameric Hb's; on the other hand, the spectroscopic properties of ruminant (i.e., buffalo, deer, mouflon, musk ox, ox, and reindeer) HbNO are characteristic of the low affinity conformation. These results are in keeping with the functional properties of the mammalian Hb's considered and have been related to the peculiar low oxygen affinity of ruminant Hb's.     

Primary structure of alpha-globin chains from river buffalo (Bubalus bubalis L.) hemoglobins

Primary structure analysis of the four river buffalo -globin chains showed that haplotypes A and B differ from each other by a substitution at codon 64 that may encode Ala or Asn. The A haplotype encodes two -globin chains, ^I1 and ^II3, which differ at positions 129 and 131: ^I1 has 64 Ala, 129 Phe, 131 Asn; ^II3 has 64 Ala, 129 Leu, 131 Ser. The B haplotype encodes two -globin chains, ^I2 and ^II4, which differ at positions 10 and 11: ^I2 has 10 Ile, 11 Gln, 64 Asn; ^II4 has 10 Val, 11 Lys, 64 Asn. Apart from the Ala/Asn polymorphism at position 64, amino acid substitutions in allelic and nonallelic -globin chains seem to have arisen by single point mutations. Detection of electrophoretically silent mutations due to neutral amino acid substitutions and their influence on the isoelectric point are discussed. Furthermore, primary structures of river buffalo -globin chains are compared to other species of the Bovidae family to suggest evolutionary events that have characterized the amino acid substitutions of river buffalo hemoglobin.     

Evolution and functional divergence of monocarboxylate transporter genes in vertebrates

Monocarboxylate transporters (MCTs) form a gene family with an ancient past. The identification of MCTs (MCHs) from bacteria, protozoa, fungi, invertebrates, as well as vertebrates, but not from plants and virus, allowed illuminating the phylogenetic and evolutionary history of this gene family. The significant expansion of vertebrate MCT genes should have primarily occurred after the divergence of vertebrates and invertebrates, but before the divergence time between ray-finned fish and mammals. The divergence of insect MCTs should have at least occurred in the common ancestor of fruit fly, beetle, and honeybee. Fungi monocarboxylate transporter homologues (MCHs) might evolve independently from an ancient ancestor. The results of functional divergence analysis provided statistical evidences for shifted evolutionary rate and/or changes of amino acid property after gene duplication. The sliding window analysis of the d(N)/d(S) ratio values showed that strong functional constraints must impose on the N- and C-terminal domains of vertebrate MCTs. These corresponding regions may play crucial roles for functionality of MCT proteins.     

Adaptive Evolution of p53 Thermodynamic Stability

The thermodynamic stability of a protein plays an important role during evolution and adaptation in order to maintain a folded and active conformation. p53 is a tumour suppressor involved in the regulation of numerous genes. Human p53 has an unusually low thermodynamic stability and is frequently inactivated by oncogenic missense mutations. Here, we examined the thermodynamic and kinetic stability of p53 DNA binding domains from selected invertebrate and vertebrate species by differential scanning calorimetry and equilibrium urea denaturation. There is a correlation in the apparent melting temperature of p53 with the body temperature of homeotherm vertebrates. We found that p53 from these organisms has a half-life for spontaneous unfolding at organismal body temperature of 10-20 min. We also found that p53 from invertebrates has higher stability, bearing more resemblance towards p63 and p73 from humans. Using structure-guided mutagenesis on the human p53 scaffold, we demonstrated that the amino acid changes on the protein surface and in the protein interior lead to the elevated stability of p53 orthologs. We propose a model in which the p53 DNA binding domain has been shaped by the complex interplay of different selective pressures and underwent adaptive evolution leading to pronounced effects on its stability. p53 from vertebrates has evolved to have a low thermodynamic stability and similarly short spontaneous half-life at organismal body temperature, which is related to function.     

Inheritance of structural alleles for goat hemoglobins: Site duplication and limited structural divergence for the alpha-chain locus

Four hemoglobin phenotypes have been detected among domestic goats by zonal electrophoresis. Breeding data indicate that two of these phenotypes represent animals homozygous at relevant structural loci and two represent heterozygotes. Electrophoresis of hemoglobin chains reveals both - and -chain variation. The phenotypes are interpreted in terms of genotypes which require a postulated duplication and subsequent divergence for the original -chain structural locus (see Fig. 5).This investigation was supported in part by Grants No. Am-10391 and Fr-07094 of the U.S. Public Health Service. In view of the current national situation for research support and its local effects, the authors will fill reprint requests only if the request is accompanied by a brief note explaining the anticipated utility of the reprint.     

Evolution and functional divergence of the anoctamin family of membrane proteins

Background  

The anoctamin family of transmembrane proteins are found in all eukaryotes and consists of 10 members in vertebrates. Ano1 and ano2 were observed to have Ca²⁺ activated Cl^- channel activity. Recent findings however have revealed that ano6, and ano7 can also produce chloride currents, although with different properties. In contrast, ano9 and ano10 suppress baseline Cl^- conductance when co-expressed with ano1 thus suggesting that different anoctamins can interfere with each other. In order to elucidate intrinsic functional diversity, and underlying evolutionary mechanism among anoctamins, we performed comprehensive bioinformatics analysis of anoctamin gene family.     

Kunitz-type proteinase inhibitors in sheep and ox.

1. Four protein proteinase inhibitors, belonging to the Kunitz family, were isolated and purified from several sheep organs. 2. Their structural, functional and immunological properties were determined and compared to those of similar inhibitors purified from bovine organs. 3. The Kunitz-type isoinhibitors appear differently distributed in the two species: BPTI, which is the prevailing form in bovids, is found only in minute amounts in sheep organs. 4. The presence of multiple forms of these inhibitors in sheep is discussed on the basis of the same biosynthetic and post-translational processes proposed for the molecules of bovine origin.     

The structure of annelid and mollusc hemoglobins.

The polypeptide chain composition and the chemical properties of several annelid hemoglobins and chlorocruorins are presented. In agreement with earlier studies on the hemoglobin from Arenicola cristata (Waxman, L. (1971) J. Biol. Chem. 246, 7318-7327), nearly all of the pigments which have been examined consist of one or more different disulfide-linked polypeptide chains of 13,000 to 16,000 daltons, and the heme-protein stoichiometry suggests that more than one polypeptide is associated with each heme. Except for the prosthetic group, there is no outstanding chemical difference between the chlorocruorins and the hemoglobins, nor is ther any apparent differnce between those hemoglobins which show cooperative oxygen binding properties and those which do not. The results suggest that all these hemoglobins have similar structures. On the other hand, the polypeptide chains of mollusc hemoglobins have molecular weights of greater than 220,000. Each polypeptide binds many heme groups. Thus, annelids use small polypeptide chains while molluscs use giant polypeptides to carry O2.     

Comparative solubilities and electrophoresis of microtine hemoglobins.

1. The electrophoretic mobilities of the hemoglobins of 7 taxa of microtines were compared. Microtus oeconomus, M. pennsylvanicus pullatus and M. xanthognatus showed identical 2-band patterns on electrophoresis of their hemoglobins while M. pennsylvanicus tananaensis showed only a single hemoglobin corresponding to the major band of the others. Dicrostonyx rubricatus and D. stevensoni exhibited identical patterns different from the Microtus species. Lemmus sibiricus had a slow hemoglobin component with mobility slightly different from the slow ones of the Microtus species while the fast component appeared the same. 2. Electrophoresis of individual globin chains from hemolysates, purified hemoglobins, and isolated chains indicated a large degree of similarity between the species studied, although there were significant differences in hemoglobin patterns. 3. The minor hemoglobin band in Microtus seems to be the result of a second alpha chain locus as determined from the hemoglobins from hybrids of two subspecies. 4. Salting-out studies indicated differences between hemoglobins that were not detectable by electrophoresis of either whole hemoglobins or isolated chains. 5. M. xanthognathus hemolysate was considerably less soluble than those of M. oeconomus and M. pennsylvanicus pullatus which had essentially the same solubility. 6. The major hemoglobin components of M. pennsylvanicus pullatus and M. xanthognathus were considerably less soluble than either the corresponding unfractionated hemolysates or purified minor components.     

The structure and function of plant hemoglobins.

Plants, like humans, contain hemoglobin. Three distinct types of hemoglobin exist in plants: symbiotic, non-symbiotic, and truncated hemoglobins. Crystal structures and other structural and biophysical techniques have revealed important knowledge about ligand binding and conformational stabilization in all three types. In symbiotic hemoglobins (leghemoglobins), ligand binding regulatory mechanisms have been shown to differ dramatically from myoglobin and red blood cell hemoglobin. In the non-symbiotic hemoglobins found in all plants, crystal structures and vibrational spectroscopy have revealed the nature of the structural transition between the hexacoordinate and ligand-bound states. In truncated hemoglobins, the abbreviated globin is porous, providing tunnels that may assist in ligand binding, and the bound ligand is stabilized by more than one distal pocket residue. Research has implicated these plant hemoglobins in a number of possible functions differing among hemoglobin types, and possibly between plant species.     

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.     

Evolution of alu family repeats since the divergence of human and chimpanzee

Summary The DNA sequences of three members of the Alu family of repeated sequences located 5 to the chimpanzee 2 gene have been determined. The base sequences of the three corresponding human Alu family repeats have been previously determined, permitting the comparison of identical Alu family members in human and chimpanzee. Here we compare the sequences of seven pairs of chimpanzee and human Alu repeats. In each case, with the exception of minor sequence differences, the identical Alu repeat is located at identical sites in the human and chimpanzee genomes. The Alu repeats diverge at the rate expected for nonselected sequences. Sequence conversion has not replaced any of these 14 Alu family members since the divergence between chimpanzee and human.