Complete amino acid sequence of the major component myoglobin from the goose-beaked whale, Ziphius cavirostris.

The complete primary structure of the major component myoglobin from the goose-beaked whale, Ziphius cavirostris, was determined by specific cleavage of the protein to obtain large peptides which are readily degraded by the automatic sequencer. Over 80% of the amino acid sequence was established from the three peptides resulting from the cleavage of the apomyoglobin at its two methionine residues with cyanogen bromide along with the four peptides resulting from the cleavage with trypsin of the citraconylated apomyoglobin at its three arginine residues. Further digestion of the central cyanogen bromide peptide with S. aureus strain V8 protease and the 1,2-cyclohexanedione-treated central cyanogen bromide peptide with trypsin enabled the determination of the remainder of the covalent structure. This myoglobin differs from the cetacean myoglobins determined to date at 12 to 17 positions. These large sequence differences reflect the distant taxonomic relationships between the goose-beaked whale and the other species of Cetacea the myoglobin sequences of which have previously been determined.

Complete amino acid sequence of the myoglobin from the Pacific spotted dolphin, Stenella attenuata graffmani.

The complete amino acid sequence of the major component myoglobin from the Pacific spotted dolphin, Stenella attenuata graffmani, was determined by the automated Edman degradation of several large peptides obtained by specific cleavage of the protein. The acetimidated apomyoglobin was selectively cleaved at its two methionyl residues with cyanogen bromide and at its three arginyl residues by trypsin. By subjecting four of these peptides and the apomyoglobin to automated Edman degradation, over 80% of the primary structure of the protein was obtained. The remainder of the covalent structure was determined by the sequence analysis of peptides that resulted from further digestion of the central cyanogen bromide fragment. This fragment was cleaved at its glutamyl residues with staphylococcal protease and its lysyl residues with trypsin. The action of trypsin was restricted to the lysyl residues by chemical modification of the single arginyl residue of the fragment with 1,2-cyclohexanedione. The primary structure of this myoglobin proved to be identical with that from the Atlantic bottlenosed dolphin and Pacific common dolphin but differs from the myoglobins of the killer whale and pilot whale at two positions. The above sequence identities and differences reflect the close taxonomic relationship of these five species of Cetacea.

Induction of metallothionein synthesis in cultured human trophoblasts by cadmium and zinc.

A system of primary cultures of human chorionic trophoblasts has been used for studying the effects of heavy metals on human reproductive tissue. Using this system, changes in cellular concentration of metallothionein (MT) in response to exposure to Cd or Zn were determined. Trophoblasts were isolated from term chorion leave, grown in RPMI-1640 medium, and exposed to Cd or Zn. Cellular content of MT was measured using the Cd/heme radioassay. MT increased in a concentration- and time-dependent manner after exposure to either metal. Cd increased the content of MT in trophoblasts at concentrations as low as 0.5 microM during a 24-h exposure. Moreover, extending exposure to Cd (2 microM) to 72 h resulted in a 3-4-fold increase in the concentration of MT. On a molar basis, Zn was not as potent a stimulus for MT synthesis as Cd, and required a concentration of 2.5 microM to increase the concentration of MT over a 24-h period. However, a 48- or 72-h exposure to Zn (10 microM) increased concentrations of MT nearly 8-fold over control values. Simultaneous exposure to Cd (2 microM) and inhibitors of protein synthesis, cycloheximide and actinomycin D, prevented the typical increase in MT concentration, suggesting that the metals act to increase the synthesis of MT. In another series of experiments, trophoblasts were exposed to Cd (2 microM) for 24 h, after which the cells were challenged with cytotoxic concentrations of Cd. Cells pretreated with Cd and then challenged with toxic concentrations of Cd had higher levels of MT and showed less toxicity, as indicated by leakage of lactic dehydrogenase. These results suggest that MT serves to sequester the metals in trophoblasts and reduce the toxicity of heavy metals. Thus, this system should be useful for studying the effects of heavy metals and characterizing the induction of MT in human reproductive tissue in vitro.

Separation and quantitation of metallothioneins by high-performance liquid chromatography coupled with atomic absorption spectrophotometry.

A rapid, reproducible, and sensitive high-performance liquid chromatography (HPLC) method for the determination of the concentrations of metallothionein-I (MT-I) and metallothionein-II (MT-II) in rat liver has been developed. Metallothioneins (MTs) were separated and quantitated by anion-exchange high-performance liquid chromatography coupled with atomic absorption spectrophotometry (AAS). Purified rat liver MT-I and MT-II, used as standards for developing the method, were easily resolved, eluting at 7.5 and 10.4 min, respectively. To establish standard curves, protein concentrations of solutions of the purified MTs were determined by the Kjeldahl method for the determination of nitrogen, after which the standards were saturated with Cd (final concentration of 50 ppm Cd). Rat liver cytosols obtained from untreated and Cd- or Zn-treated rats were prepared for HPLC-AAS analysis by saturation with Cd (50 ppm Cd) followed by heat denaturation (placing in a boiling water bath for 1 min). Based on the method of standard additions, recovery of MTs exceeded 95% and repeated injection of a sample yielded a coefficient of variance of approximately 2%. A detection limit of 5 micrograms MT/g liver was established for the method. Only MT-II was detected in untreated rats, whereas following exposure to Cd or Zn, both forms of MTs were detected. Concentrations of total MTs in liver of untreated and Cd- or Zn-treated rats were also determined by the Cd/hemoglobin radioassay (which fails to distinguish MT-I from MT-II) and indicated that results obtained with the HPLC-AAS method compared favorably to the Cd/hemoglobin radioassay. Thus, the HPLC-AAS method for quantitating MT-I and MT-II offers the advantage of determining the concentrations of both proteins in tissues and should be useful for studying the regulation of MT-I and MT-II.

Dosage-dependent disposition of cadmium administered orally to rats.

This study was designed to determine whether the disposition of Cd is dependent on dose. Rats received a single dosage of Cd either orally (1, 10, 100, 1000, or 10,000 micrograms/kg) or intravenously (0.01, 0.1, 10, 100, or 1000 micrograms/kg) and were killed 7 days later to determine concentration of Cd in various organs. When administered intravenously, the concentration of Cd in tissues increased proportionally with dosage and the percentage of dose in each organ remained constant. However, when Cd was administered orally, the concentration of Cd in tissues increased more than the increase in dosage. Moreover, the percentage of the po dosage retained 7 days after administration increased from 0.40% at the 1 microgram/kg dosage to 1.65% at the 100 micrograms/kg and higher dosages. In addition, when administered orally, low dosages of Cd (1 and 10 micrograms/kg) distributed preferentially to the kidney suggesting that Cd may be absorbed as a Cd-metallothionein complex at low dosages. To determine the gastrointestinal absorption of Cd, rats were given an oral dosage of Cd (1 or 10,000 micrograms/kg) and 3 hr later organs were removed to determine Cd content. Concentrations of Cd in tissues increased more than the increase in dosage and the percent of dosage absorbed was dosage-dependent (0.35 and 1% at the 1 and 10,000 micrograms/kg dosages, respectively). At the 1 microgram Cd/kg dosage, approximately 60% of Cd in intestinal cytosol was bound to metallothionein (MT) whereas at the 10,000 micrograms Cd/kg dosage, approximately 50% of the Cd was bound to MT. These results indicate that retention of Cd following oral administration is dosage-dependent and results from increased absorption of Cd at higher dosages.

Induction of hepatic metallothionein following administration of urethane.

Induction of hepatic metallothionein (MT) by urethane (ethyl carbamate) was characterized. Male CF-1 mice were treated with urethane (0, 0.5, 1.0, 1.5, and 2 g/kg; ip) and 18 hr later hepatic MT concentrations were determined with the Cd-hemoglobin radioassay. Urethane (1 g/kg and higher) significantly increased hepatic MT levels, resulting in a 14-fold increase after 2 g/kg. Time-course experiments indicated that MT levels were increased significantly at 6 hr after administration of urethane (1.5 g/kg) and reached a maximum between 12 and 24 hr. Gel filtration, anion-exchange chromatography, and ultraviolet spectral analysis were used to characterize the protein induced by urethane. Pretreatment with actinomycin-D prevented induction of MT by urethane. Administration of equimolar dosages (20 mmol/kg) of urethane, N-hydroxyurethane, and methyl carbamate indicated that urethane and N-hydroxyurethane induce MT but that methyl carbamate does not. MT induction was also not observed with other commonly used anesthetics (pentobarbital and phenobarbital). In conclusion, urethane induces hepatic MT but this effect is not related to its anesthetic action, nor is it a common property of all carbamates.

Metallothionein gene regulation in the preimplantation rabbit blastocyst.

Expression of metallothionein (MT) genes in the preimplantation rabbit blastocyst was analysed by determination of the levels of MT mRNA and relative rates of MT synthesis. MT was found to be constitutively expressed at low levels in the blastocyst. Exposure of the day-6 blastocyst to zinc ions in vitro rapidly increased the level of MT gene expression in a dose-dependent manner, with a ten-fold induction in the relative rate of synthesis at 400 microM-Zn2+. Ion-exchange chromatography of pulse-labelled blastocyst protein showed that the relative rates of synthesis of both MT-I and MT-II were markedly increased following zinc treatment, with MT-I being the predominant isometallothionein. Zinc induction of MT synthesis in the blastocyst was also detected on day 4 of gestation just after the morula-to-blastocyst transition. In contrast to the zinc effects on MT, in vitro exposure to 10 microM-Cd2+ resulted in a large induction of MT mRNA but only a modest increase in the relative rate of MT synthesis. Cadmium was found to be toxic to the day-6 blastocyst, and 10 microM-Cd2+ induced an acute stress response as indicated by a dramatic induction of heat-shock protein (HSP-70) gene expression.

The complete amino acid sequence of the major component myoglobin of dwarf sperm whale (Kogia simus).

The complete amino acid sequence of the major component myoglobin from the dwarf sperm whale, Kogia simus, was determined by specific cleavage of the protein to obtain large peptides which are readily degraded by the automatic sequenator. Three easily separable peptides were obtained by cleaving the protein at its two methionine residues, and five peptides were obtained from the methyl acetimidated protein by cleavage with trypsin at the four arginine residues. Sequenator analysis of these fragments and the apomyoglobin provided over 80% of the covalent structure of the protein. The remainder of the primary structure was determined by further digestion of the two larger cyanogen bromide fragments with trypsin and staphylococcal protease. To reconfirm many of the substitutions found in this protein, the apomyoglobin was treated with 1,2-cyclohexanedione, and the resulting arginine protected protein was cleaved at its lysine residues with trypsin. This myoglobin differs from that of the sperm whale at 6 positions, and from the other cetacean myoglobins at about 16 positions. The appearance of a histidine residue at position 35 has no precedent in any myoglobin. The substitutions seen at positions 21, 51, and 132 are unique to date for cetacean myoglobins.

Complete amino acid sequence of the myoglobin from the Atlantic bottlenosed dolphin, Tursiops truncatus.

The complete amino acid sequence of the major component myoglobin from the Atlantic bottlenosed dolphin, Tursiops truncatus, was determined by specific cleavage of the protein to obtain large peptides that are readily degraded by the automatic sequencer. Three easily separable peptides were obtained by cleaving the protein with cyanogen bromide at the 2 methionine residues and 4 peptides were obtained by cleaving the methyl acetimidated protein with trypsin at the 3 arginine residues. By subjecting 4 of these peptides and the apomyoglobin to automatic Edman degradation, over 80% of the covalent structure of the protein was obtained. The remainder of the primary structure was determined by further digestion of the central cyanogen bromide peptide with trypsin and staphylococcal protease. This myoglobin differs from that of the sperm whale, Physter catodon, at 15 positions, from that of the California gray whale, Eschrichtius gibbosus, at 14 positions, from that of the common porpoise, Phocoena phocoena, at 6 positions, and from the myoglobin of the Black Sea dolphin, Delphinus delphis and the Amazon River dolphin, Inia goeffrensis, at 5 and 7 positions, respecitvely. All substitutions observed in this sequence fit easily into the tertiary structure of sperm whale myoglobin.

The complete amino acid sequence of the major component myoglobin of Amazon river dolphin (Inia geoffrensis).

The complete amino acid sequence of the major component myoglobin from Amazon River dolphin, Inia geoffrensis, was determined by specific cleavage of the protein to obtain large peptides which are readily degraded by the automatic sequencer. Three easily separable peptides were obtained by cleaving the protein with cyanogen bromide at the methionine residues and four peptides were obtained by cleaving the methyl-acetimidated protein with trypsin at the arginine residues. From these peptides over 85% of the sequence was completed. The remainder of the sequence was obtained by fragmentation of the large cyanogen bromide peptide with trypsin. This protein differs from that of the common porpoise, Phocoena phocoena, at seven positions, from that of the common dolphin, Delphinus delphis, at 11 positions, and from that of the sperm whale, Physeter catodon, at 15 positions. By comparison of this sequence with the three-dimensional structure of sperm whale myoglobin it appears that those residues close to the heme group are most conserved followed by those in nonhelical regions and lastly by those in the helical segments. All of the substitutions observed in this sequence fit easily into the three-dimensional structure of the sperm whale myoglobin.

Complete primary structure of the major component myoglobin of California gray whale (Eschrichtius gibbosus).

The complete primary structure of the major component myoglobin from the California gray whale, Eschrichtius gibbosus, was determined by specific cleavage of the protein to obtain large peptides for degradation by the automatic sequenator. Cleavage at the two methionine residues of the apomyoglobin with cyanogen bromide and at the three arginine residues of the methyl acetimidated protein with trypsin resulted in three and four easily separable peptides, respectively, which when sequenced accounted for 85% of the primary structure. The remainder of the covalent structure was obtained by further digestion of the central cyanogen bromide peptide with trypsin and S. aureus strain V8 protease. This protein differs from that of the sperm whale, Physeter catodon, at 12 positions, from that of the common porpoise, Phocoena phocoena, and the Black Sea dolphin, Delphinus delphis, at 14 positions, and from that of the Amazon River dolphin, Inia geoffrensis, at 7 positions. All substitutions observed in this sequence fit easily into the tertiary structure of sperm whale myoglobin.

The complete amino acid sequence of the major component myoglobin from the arctic minke whale, Balaenoptera acutorostrata.

The complete primary structure of the major component myoglobin from the Arctic minke whale, Balaenoptera acutorostrata, was determined by specific cleavage of the protein to obtain large peptides which are readily degraded by the automatic sequencer. Over 80% of the amino acid sequence was established from the three peptides resulting from the cleavage of the apomyoglobin at the two methionine residues with cyanogen bromide along with the four peptides resulting from the cleavage of the methylacetimidated apomyoglobin at the three arginine residues with trypsin. The further digestion of the central cyanogen bromide peptide with trypsin and S. aureus strain V8 protease enabled the determining of the remainder of the covalent structure. This myoglobin differs from that of the dwarf sperm whale, Kogia simus, at 16 positions, and the common dolphin, Delphinus delphis, at 14 positions, from that of the common porpoise, Phocaena phocaena, and the bottlenosed dolphin, Tursiops truncatus at 13 positions, from that of the Amazon River dolphin, Inia geoffrensis, at 10 positions, and from that of California gray whale, Eschrichtius gibbosus, at 3 positions- All of the substitutions observed in this sequence fit easily into the three-dimensional structure of the sperm whale myoglobin.

Evolution of the amino acid substitution in the mammalian myoglobin gene.

Multivariate statistical analyses were applied to 16 physical and chemical properties of amino acids. Four of these properties; volume, polarity, isoelectric point (charge), and hydrophobicity were found to explain adequately 96% of the total variance of amino acid attributes. Using these four quantitative measures of amino acid properties, a structural discriminate function in the form of a weighted difference sum of squares equation was developed. The discriminate function is weighted by the location of each particular residue within a given tertiary structure and yields a numerical discriminate or difference value for the replacement of these residues by different amino acids. This resulting discriminate value represents an expression of the perturbation in the local positional environment of a protein when an amino acid substitution occurs. With the use of this structural discriminate function, a residue by residue comparison of the known mammalian myoglobin sequences was carried out in an attempt to elucidate the positions of possible deviations from the known tertiary structure of sperm whale myoglobin. Only 11 of the 153 residue positions in myoglobin demonstrated possible structural deviations. From this analysis, indices of difference were calculated for all amino acid exchanges between the various myoglobins. All comparisons yielded indices of difference that were considerably lower than would be expected if mutations had been fixed at random, even if the organization of the genetic code is taken into consideration. On the basis of these results, it is inferred that some form of selection has acted in the evolution of mammalian myoglobins to favor amino acid substitutions that are compatible with the retention of the original conformation of the protein.

Complete amino acid sequence of the major component myoglobin from the humpback whale, Megaptera novaeangliae.

The complete primary structure of the major component myoglobin from the humpback whale, Megaptera novaeangliae, was determined by specific cleavage of the protein to obtain large peptides which are readily degraded by the automatic sequencer. Over 80% of the amino acid sequence was established from the three peptides resulting from the cleavage of the acetimidated apomyoglobin at the three arginine residues with trypsin. The further digestion of the central cyanogen bromide peptide with trypsin and S. aureus strain V8 protease enabled the determination of the remainder of the covalent structure. This myoglobin differs from that of sperm whale, Physeter catodon, at 12 positions, and dwarf sperm whale, Kogia simus, at 14 positions, finback whale Balaenoptera physalus at 3 positions, minke whale, Balaenoptera acutorostrata at 2 positions, and California gray whal Eschrichtius gibbosus, at 1 position. All of the substitutions observed in this sequence fit readily into the three-dimensional structure of sperm whale myoglobin.

Complete amino acid sequence of myoglobin from the pilot whale, Globicephala melaena.

The complete amino acid sequence of the major component myoglobin from the pilot whale, Globicephala melaena, was determined by specific cleavage of the protein to obtain large peptides which are readily degraded by the automatic sequencer. The apomyoglobin was selectively cleaved at the two methionyl residues with cyanogen bromide and the acetimidated apomyoglobin was cleaved at the three arginyl residues by trypsin. From the sequence analysis of four of these peptides and the apoprotein, over 90% of the covalent structure of the protein was obtained. The remainder of the primary structure was determined by sequence analysis of three of the tryptic peptides isolated from the central cyanogen bromide fragment after modification of its single arginyl residue with 1,2-cyclohexanedione. This myoglobin differs from that of the Black Sea dolphin at four positions and from the myoglobin of the killer whale, Pacific common dolphin, and Atlantic bottlenosed dolphin at two positions. The above differences reflect the close taxonomic relationship of these five species of Cetacea. This sequence determination was aided by the use of a Texas Instruments 980A minicomputer system which performed peak integrations for all samples subjected to amino acid analysis.