The reaction of tetranitromethane with human chorionic gonadotropin.

The reaction of tetranitromethane with human chorionic gonadotropin and its subunits has been investigated. The hormone consists of two subunits, α and β, containing four and three tyrosyl residues, respectively. Introduction of 1 nitrated tyrosine residue into the native hormone was accompanied by a 20% loss in immunological reactivity and a 50% loss in biological activity. This initial reaction occurred at α Tyr-88 and/or α Tyr-89. Exhaustive nitration of the hormone modified α tyrosines 65, 88, and 89 and resulted in 75% inactivation biologically and 50% immunologically. Either nitrated α subunit obtained by dissociation of the nitrated hormone recombined with the native β subunit to give a hormone whose activity was in reasonable agreement with that of the corresponding nitrated monomer. These results indicate involvement of α Tyr-88 and/or α Tyr 89 in binding of the hormone to its receptor. These residues are not required for binding to the β subunit, however. Tyr-65 of the α subunit is probably not involved in binding to either the β subunit or the hormone receptor. The β subunit obtained from the exhaustively nitrated hormone was unmodified and recombined with native α to give fully active hormone. About 25% of the protein was recovered as polymeric material following nitration; lesser amounts of crosslinked monomer were formed. Both were biologically inactive. The polymer products retained about 30% of the native immunological competence.Nitration of the isolated α subunit fully converted the remaining tyrosine (Tyr-37) to 3-nitrotyrosine in a two-step reaction. The fully nitrated α subunit did not recombine well with the native β subunit and the recombinant hormone has 10% or less of the native activity. Involvement of α Tyr-37 in binding to the β subunit is suggested by these data. However, exposure of this residue by a conformational change in the α subunit after dissociation of the native hormone, while it seems unlikely in view of the high disulfide content, is also consistent with the data. Reaction of the free β subunit with tetranitromethane resulted in complete nitration of Tyr-37, 85% nitration of Tyr-59, and 25% nitration of Tyr-82. The nitrated β subunit did not recombine well with native α but the isolated recombinant had two-thirds of the native activity. From these data we conclude that β Tyr-37 and/or β Tyr-59 are possibly involved in binding to the α subunit but do not have a role in the biological activity. Tyr-82 of β is apparently not involved in either subunit interactions or hormone-receptor binding.     

Human pituitary thyrotropin: isolation and chemical characterization of its subunits

The subunits of human pituitary thyrotropin have been separated and purified by countercurrent distribution and exclusion chromatography. The NH₂-terminal sequence of the β subunit is identical to that of the β subunit of bovine thyrotropin. However, amino acid composition and peptide map of tryptic and chymotryptic digests as well as compositions of tryptic and chymotryptic peptides suggest that the amino acid sequence of the α subunit is identical to that of the α subunit of human interstitial cell stimulating hormone.     

Studies on pituitary follitropin. II. Isolation and characterization of the subunits of the ovine hormone.

The α and β subunits of highly potent ovine follitropin have been isolated by dissociation in 8 m urea, pH 7.5, and chromatography on DEAE-Sephadex A25. The isolated subunits display microheterogeneity on polyacrylamide gel electrophoresis and have very low activity in follitropin-specific radioreceptor and radioimmunoassays. The tryptophan fluorescence spectra of native follitropin and the isolated β subunit are different. The recombinant of follitropin α + β subunit had the same activity as the native hormone in the radioimmunoassay, but its activity in the radioreceptor and in vivo bioassay was about 65% of the intact hormone. Substitution of the follitropin α by ovine lutropin α subunit (prepared by a method not involving urea) to form the recombinant restored full activity in all the three assays investigated. The formation of recombined hormone proceeds at a rapid rate and is almost complete by 6 h. The α and β subunits of ovine follitropin differ from each other in amino acid composition. No significant differences were apparent in their carbohydrate composition. The amino acid composition of the ovine follitropin α and lutropin α subunits are very similar. The oxidized α subunit has phenylalanine at its NH₂-terminus while aspartic acid is present at this position in the oxidized β subunit.     

A simple procedure for separating the subunits of ovine and bovine pituitary interstitial cell stimulating hormone

A simple, effective procedure for separating ovine or bovine interstitial cell stimulating hormone into their subunits has been described with a yield of 70–80%. The β subunit isolated by the new procedure behaves differently from that obtained by the countercurrent distribution method, and is in a more native state. In addition, full biological activity is consistently restored upon recombination of the subunits isolated by the new procedure.     

The kinetics of dissociation and reassociation of ovine pituitary interstitial cell stimulating hormone

The dissociation of ovine interstitial cell stimulating hormone and the reassociation of its subunits have been followed by circular dichroism and sedimentation velocity measurements. The dissociation was found to be a rapid, first-order reaction accompanied by the exposure of previously buried tyrosyl groups. The reassociation reaction begins as a rapid, probably second-order formation of a complex between the α and β subunits. This is followed by a much slower, first-order rearrangement of the conformation resulting in the reburying of at least two tyrosyl groups, one contributed by each subunit.     

Role of arginine residues in ovine lutropin: Reversible modification by 1,2-cyclohexanedione

The modification of arginine residues of ovine pituitary lutropin by 1,2-cyclohexanedione has been studied. This alteration did not disrupt the quaternary structure of the hormone. Modification of the first set of about five reactive arginines resulted in 50% loss of hormonal activity. Further alteration in which seven to eight residues of arginine were modified led to 85% loss in activity. Hydroxylamine treatment of the derivative restored a significant amount (70%) of biological activity. Modification of isolated subunits did not appear to affect recombination. Recombinants in which either the α or β subunit was modified showed approximately 30% of the activity of the native hormone. The recombinant in which both of the subunits were derivatized had about 10% hormonal activity.     

Studies on pituitary follitropin. V. Isolation of the subunits of the human hormone and reaction of the amino groups with acylating agents.

The alpha and beta subunits of human follitropin were isolated in a high state of purity. The tryptophan fluorescence of the native hormone and the isolated beta subunit are different. The N-terminus of the alpha and beta subunits was identified as valine and aspartic acid respectively. While recombination of the isolated alpha and beta subunits restores the electrophoretic mobility of the intact hormone, its receptor binding activity cannot be fully regenerated. Substitution of the human follitropin alpha by an ovine lutropin alpha subunit, to form a recombinant with the follitropin beta subunit, generates a complex with 2-3 receptor binding activity of the native human follitropin and the same activity as ovine follitropin. Acylation of the intact hormone does not disrupt the quaternary structure but leads to complete inactivation. Acylation studies with the subunits suggests the crucial role of the epsilon-amino groups of the alpha subunit in determining biological activity.     

The carboxylic acid groups of bovine luteinizing hormone. The effects of their modification on receptor site binding and subunit-subunit interaction.

The modification of the carboxyl groups of the subunits of bovine luteinizing hormone to neutral derivatives by carbodiimide-mediated coupling with glycine methyl ester has been studied. The modified alpha subunit, which has 8 residues of glycine methyl ester incorporated, will no longer recombine with native beta (hormone-specific) subunit, but the modified beta subunit, with 6 to 7 glycine methyl esters incorporated, will recombine with native alpha to yield a partially active hormone. Derivatization of the intact hormone results in dissociation to subunits together with formation of a major side product which is covalently cross-linked. Significant cross-linked product was not obtained during modification of individual subunits, thus indicating an orientation between an activated carboxyl group(s) and a nucleophile(s) in the intact hormone which favors coupling. Separation of subunits from the derivatized, noncross-linked fraction by countercurrent distribution reveals a heterogeneous preparation of the modified alpha subunit which also will not recombine with either a native or modified beta subunit. The beta subunit from the modified intact hormone was indistinguishable from the modified isolated beta subunit in amino acid composition and in ability to recombine with native alpha subunit. The results are consonant with data from this and other laboratories in which various modifications of the alpha chain, the subunit common to the glycoproteins, more seriously affect recombination than similar modifications of the beta subunits. The number of carboxyl groups modified in each subunit is compatible with but not in total agreement with assignments of amides reported from sequence studies.     

Chemical and biological properties of the subunits of pregnant mare serum gonadotropin

The two subunits (α and β) of pregnant mare serum gonadotropin have been dissociated and partially characterized. Recombination of the biologically inactive subunits results in the restoration of both the follicle stimulating and leuteinizing activities of pregnant mare serum gonadotropin. In addition, the α subunit of pregnant mare serum gonadotropin can be combined with the β subunit of either ovine luteinizing hormone, human chorionic gonadotropin, or follicle stimulating hormone with generation of the specific activity expected of the β subunit.     

Further characterization of the ovine lutropin alpha and beta subunits prepared by the salt precipitation method.

The subunits of ovine lutropin prepared by acid dissociation and salt precipitation were characterized by end group analysis, tryptic peptide mapping, SDS gel electrophoresis and biological activity. No evidence of internal peptide cleavage was found in the alpha subunit. The subunits possessed low activity. The alpha and beta subunits recombined effectively to generate a complex that had full receptor binding activity and in vitro biological activity. The recombinants of subunits prepared by countercurrent distribution showed only 50% activity in both assays. The salt precipitation method alpha subunit could be completely reduced and reoxidized in the absence of denaturants. The reoxidized alpha subunit combines with the native beta subunit generating full activity. However, this recombined hormone tends to lose activity with time, suggesting that the reoxidation may not fully restore the native structur of the reduced alpha subunit. The native lutropin alpha subunit effectively combined with follitropin beta subunit generating complete follitropin activity.     

The structure of the large regulatory α subunit of phosphorylase kinase examined by modeling and hydrogen‐deuterium exchange

Phosphorylase kinase (PhK), a 1.3 MDa regulatory enzyme complex in the glycogenolysis cascade, has four copies each of four subunits, (αβγδ)₄, and 325 kDa of unique sequence (the mass of an αβγδ protomer). The α, β and δ subunits are regulatory, and contain allosteric activation sites that stimulate the activity of the catalytic γ subunit in response to diverse signaling molecules. Due to its size and complexity, no high resolution structures have been solved for the intact complex or its regulatory α and β subunits. Of PhK's four subunits, the least is known about the structure and function of its largest subunit, α. Here, we have modeled the full‐length α subunit, compared that structure against previously predicted domains within this subunit, and performed hydrogen‐deuterium exchange on the intact subunit within the PhK complex. Our modeling results show α to comprise two major domains: an N‐terminal glycoside hydrolase domain and a large C‐terminal importin α/β‐like domain. This structure is similar to our previously published model for the homologous β subunit, although clear structural differences are present. The overall highly helical structure with several intervening hinge regions is consistent with our hydrogen‐deuterium exchange results obtained for this subunit as part of the (αβγδ)₄ PhK complex. Several low exchanging regions predicted to lack ordered secondary structure are consistent with inter‐subunit contact sites for α in the quaternary structure of PhK; of particular interest is a low‐exchanging region in the C‐terminus of α that is known to bind the regulatory domain of the catalytic γ subunit.     

Studies on modification of tryptophan, methionine, tyrosine and arginine residues of human follicle-stimulating hormone and its subunits.

Based on the regeneration of the hormonal activity following recombination, the alpha and beta subunits of human follicle-stimulating hormone have been designated as 'functional' or 'nonfunctional'. Chemical modifications of the tryptophan, methionine, tyrosine and arginine residues of human follicle-stimulating hormone, luteinizing hormone, and the 'functional' human follicle-stimulating hormone alpha and beta subunits have indicated that the tryptophan in human follicle-stimulating hormone-beta and human luteinizing hormone-beta is essential for the biological activity. The iodination of human follicle-stimulating hormone-alpha did not interfere with the hormonal activity. The modification of arginine abolishes the biological activity of the hormones. The accessibility of tyrosine and methionine in human follicle-stimulating hormone-alpha, of arginine in both native hormones and subunits, and the non-availability of the tryptophan residues to 2-hydroxy 5-nitrobenzyl bromide suggest that the alpha subunit lies on the surface of the native molecule.     

Deglycosylation of ovine pituitary lutropin subunits: Effects on subunit interaction and hormone activity

Brief exposure of the isolated α and β subunits of ovine lutropin to anhydrous liquid HF resulted in effective but incomplete removal of the oligosaccharide moiety. Fucose and hexoses were completely eliminated while hexosamine content was considerably reduced. The partially deglycosylated subunits (pDGα and pDGβ) retained their capability to recognize the native counterparts as well as each other. Both partially deglycosylated subunits retained full activity in specific radioimmunoassays. The pDGα + native β as well as native α + pDGβ recombinants showed full receptor binding activity, but the former had approximately 60% less in vitro bioactivity. The recombinant of native α + pDGβ showed full bioactivity in vitro. The receptor binding and biological activities of pDGα + pDGβ were comparable to that of deglycosylated lutropin. These two derivatives antagonized the action of intact lutropin as assessed by steroidogenesis in dispersed rat Leydig cells in vitro. The results suggest an important role for the oligosaccharide moiety in the expression of full hormone function.     

Production of biologically active recombinant goose FSH in a single chain form with a CTP linker sequence

FSH is a glycoprotein hormone secreted by the pituitary gland that is essential for gonadal development and reproductive function. In avian reproduction study, especially in avian reproduction hormone study, it is hindered by the lack of biologically active FSH. In order to overcome this shortcoming, we prepared recombinant goose FSH as a single chain molecule and tested its biological activities in the present study. Coding sequences for mature peptides of goose FSH α and β subunits were amplified from goose pituitary cDNA. A chimeric gene containing α and β subunit sequences linked by the hCG carboxyl terminal peptide coding sequence was constructed. The recombinant gene was inserted into the pcDNA3.1-Fc eukaryotic expression vector to form pcDNA-Fc-gFSHβ-CTP-α and then transfected into 293-F cells. A recombinant, single chain goose FSH was expressed and verified by SDS-PAGE and western blot analysis, and was purified using Protein A agarose affinity and gel filtration chromatography. Biological activity analysis results showed that the recombinant, chimeric goose FSH possesses the function of stimulating estradiol secretion and cell proliferation, in cultured chicken granulosa cells. These results indicated that bioactive, recombinant goose FSH has been successfully prepared in vitro. The recombinant goose FSH will have the potential of being used as a research tool for studying avian reproductive activities, and as a standard for developing avian FSH bioassays.     

Effects of beta subunit acylation on lutropin receptor site binding.

The effects of various modifications on the beta subunit of lutropin have been studied using the binding characteristics of the reconstituted hormone in the rat testicular radioligand assay. Conditions for iodinating lutropin and lutropin derivatives were determined which resulted in 15 per cent specific binding when tested immediately and retention of 6 to 7 per cent specific binding even after storage for 6 months. Acetimidinyl, acetyl, and carbamyl derivatives of the beta subunit were prepared and combined with unmodified alpha subunit to form reconstituted lutropin. Modification of the beta subunit was shown to have no effect on the time course of binding to testicular receptors or, with one exception, on the extent of receptor saturation. Very high concentrations of lutropin reconstituted with acetylated beta subunit showed an anomalous binding behavior. Scatchard plots of the binding data support the view that the native hormone has a unique receptor affinity which is irreversibly disrupted by separation of subunits and that derivatization of the beta subunit does not alter this parameter further. These data also suggest that there are no significant differences in the amino groups modified on the beta subunit. Competition and preincubation tests for receptor sites that reacted only with modified lutropin and not with the native hormone were negative.     

Modification of isolated α and β chains of human hemoglobin by the metal tetrasulfonated phthalocyanines. Studies on hybrid phthalocyanine-heme intermediates

α and β chains of hemoglobin have been modified with cobalt(II) tetrasulfonated phthalocyanine in place of heme. They display properties very similar to those of iron(II) phthalocyanine modified α and β chains. Mixed together they form tetrameric cobalt(II) phthalocyanine hemoglobin.Incorporation of Co(II)L into α and β globins results in stabilization of the protein structure, which is shown by a marked increase in its helicity content. Cobalt phthalocyanine substituted α and β chains are able to combine reversibly with oxygen giving more stable oxygenated species than their native analogues. The rate of both processes is lower in the case of the modified α chain. Recombination of the phthalocyanine α and β chains with the alternate heme containing chains give tetrameric hybrid hemoglobins. These comprise two phthalocyanine modified subunits and two heme containing subunits. The helicity content of the tetrameric hybrid hemoglobin calculated for one subunit is lower that the arithmetic mean of helicities for its isolated subunits. This suggests a destabilizing chain-chain interaction within the tetramer. Unlike in the separated subunits, oxygen binding by hybrid hemoglobins is irreversible. Deoxygenation by argon bubbling leads to the formation of inactive species which in oxygen atmosphere undergo irreversible oxidation with destruction of the complex.     

Isolation and characterization of liver glycogen synthase from diabetic rats

NAD-specific pig heart isocitrate dehydrogenase is composed of three distinct types of subunits: α, β, and γ, which have molecular weights of about 40,000 but differ in amino acid composition and in isoelectric points. When the native enzyme is subjected to polyacrylamide gel electrophoresis under nondenaturing conditions, two major protein bands with M_r values of about 360,000 (band 1) and 100,000 (band 2) and two minor bands (bands 3 and 4) with M_r values of about 40,000 are consistently present. Enzymatic activity, as detected from NADH fluorescence, is distributed throughout the protein-staining region. Analytical isoelectric focusing in urea reveals that band 1 is composed of all three subunits in roughly the normal ratio of 2α:1β:1γ, and is probably an octamer, band 2 of an equal amount of α and β and is probably dimer, while bands 3 and 4 each consist of only the monomeric α subunit. The highest enzymatic specific activity is associated with a region intermediate between octamer and dimer, which includes the 160,000 tetramer. The protein pattern resulting from isoelectric focusing under nondenaturing conditions consists of protein bands comparable in pattern to those in the presence of urea along with bands of intermediate pI values, many of which are associated with enzymatic activity. Analysis of the subunit composition of these bands supports the activity of the α species in isolation and establishes the activity of the separated β component. No activity of the isolated γ subunit species has thus far been demonstrated. However, the highest apparent specific activity is observed when at least two types of subunits are present. These studies indicate that a range of oligomeric species of the enzyme are enzymatically active and that at least three of the four subunit chains comprising the minimum complete enzyme molecule (2α:1β:1γ) possess an active site.     

Tryptic proteol ysis of coupling factor-latent ATPase from Mycobacterium phlei. Theoretical modeling of structure-function relationships

Trypsin treatment of solubilized coupling factor-latent ATPase from Mycobacterium phlei alters its subunit structure and functional properties. This coupling factor exhibits ATPase activity following trypsin treatment. Concurrently, both the ability of the enzyme to rebind to membranes depleted of coupling factor and its capacity for coupled phosphorylation are lost. The native alpha (64 000 dalton) subunit undergoes limited proteolytic digestion, and the delta (14 000 dalton) subunit is partially lost. During the course of tryptic proteolysis, the coupling factor molecule may exist in one of ten unique structural states (e.g. the native, ATPase-inactive molecule exists in the ααα state). Rigorous analysis of the experimental data by theoretical modeling provided information concerning the intermediate structural states leading to the fully ATPase-activated α″α″α″ state under different conditions of trypsin treatment. The theoretical models of structure-function relationships that best-represented the experimental data predicted that the native coupling factor molecule contains three copies of the α (64 000 dalton) form of the alpha subunit, that the α″ (58 000 dalton) alpha subunit species contributes maximally and the α′ (61 000 dalton) form about half-maximally to ATPase activity, that membrane rebinding ability is proportional to the number of native alpha subunits in the enzyme, and that at least one native α subunit/molecule is required for full expression of coupled phosphorylation. These results indicate an essential role for the alpha subunit in the regulation of ATPase activity and in the ability of the solubilized coupling factor to rebind to depleted membranes.     

Pseudo-affinity chromatographic approach to probe heterogeneity in buffalo pituitary luteinizing hormone: probable pseudolectin-like behavior of immobilized Cibacron Blue 3GA

The alpha (α) and beta (β) subunits of buffalo pituitary luteinizing hormone (LH) were chromatographed on Cibacron Blue 3GA agarose and their immunoreactivity was quantitated using anti-α and anti-β anti sera. Subsequent analyses showed α subunits were relatively more hydrophilic than β subunits. Further, the naturally occurring free α and β subunits were more hydrophobic than their native counterparts which were dissociated and isolated from heterodimeric LH. The lesser sugar content in freely occurring α and beta subunits may be attributed for increased hydrophobicity and consequent upon the existence of their uncombined free forms. In order to ascertain putative sugar–dye interaction, crude LH carrying free subunits, pure LH, and non-glycosylated recombinant β subunit of LH were loaded separately on Cibacron Blue. Methyl mannoside was able to elute 33% of the bound protein in case of crude and pure LH, whereas there was little (3%) elution in case of recombinant LH β subunit. This study suggests a compositional heterogeneity in free and native subunits of LH from the buffalo pituitary. In addition, our findings reveal the pseudolectin-like behavior of Cibacron Blue.