Site-specific PEGylation of hemoglobin at Cys-93(beta): correlation between the colligative properties of the PEGylated protein and the length of the conjugated PEG chain.

Increasing the molecular size of acellular hemoglobin (Hb) has been proposed as an approach to reduce its undesirable vasoactive properties. The finding that bovine Hb surface decorated with about 10 copies of PEG5K per tetramer is vasoactive provides support for this concept. The PEGylated bovine Hb has a strikingly larger molecular radius than HbA (1). The colligative properties of the PEGylated bovine Hb are distinct from those of HbA and even polymerized Hb, suggesting a role for the colligative properties of PEGylated Hb in neutralizing the vasoactivity of acellular Hb. To correlate the colligative properties of surface-decorated Hb with the mass of the PEG attached and also its vasoactivity, we have developed a new maleimide-based protocol for the site-specific conjugation of PEG to Hb, taking advantage of the unusually high reactivity of Cys-93(beta) of oxy HbA and the high reactivity of the maleimide to protein thiols. PEG chains of 5, 10, and 20 kDa have been functionalized at one of their hydroxyl groups with a maleidophenyl moiety through a carbamate linkage and used to conjugate the PEG chains at the beta-93 Cys of HbA to generate PEGylated Hbs carrying two copies of PEG (of varying chain length) per tetramer. Homogeneous preparations of (SP-PEG5K)(2)-HbA, (SP-PEG10K)(2)-HbA, and (SP-PEG20K)(2)-HbA have been isolated by ion exchange chromatography. The oxygen affinity of Hb is increased slightly on PEGylation, but the length of the PEG-chain had very little additional influence on the O(2) affinity. Both the hydrodynamic volume and the molecular radius of the Hb increased on surface decoration with PEG and exhibited a linear correlation with the mass of the PEG chain attached. On the other hand, both the viscosity and the colloidal osmotic pressure (COP) of the PEGylated Hbs exhibited an exponential increase with the increase in PEG chain length. In contrast to the molecular volume, viscosity, and COP, the vasoactivity of the PEGylated Hbs was not a direct correlate of the PEG chain length. There appeared to be a threshold for the PEG chain length beyond which the protection against vasoactivity is decreased. These results suggest that the modulation of the vasoactivity of Hb by PEG could be a function of the surface shielding afforded by the PEG, the latter being a function of the disposition of the PEG chain on the protein surface, which in turn is a function of the length of the PEG chain. Thus, the biochemically homogeneous PEGylated Hbs described in the present study, surface-decorated with PEG chains of appropriate size, could serve as potential candidates for Hb-based oxygen carriers.

Activation of the low oxygen affinity-inducing potential of the Asn108(beta)-->Lys mutation of Hb-Presbyterian on intramolecular alpha alpha-fumaryl cross-bridging.

The Asn108 beta-->Lys mutation in hemoglobin (HbPresbyterian mutation) endows a low O(2) affinity-inducing propensity to the protein. Introduction of a fumaryl cross-bridge between its two alpha 99 lysine residues also induces a low O(2) affinity into HbA. We have now engineered an alpha alpha-fumaryl cross-bridge into Hb-Presbyterian to determine the synergy or additivity, if any, that can be achieved between these two low O(2) affinity-inducing structural perturbations. Despite the presence of the additional epsilon-amino group of Lys108(beta) within the central cavity, the epsilon-amino group of Lys99(alpha alpha) of deoxy Hb-Presbyterian retained high selectivity for alpha alpha-fumaryl cross-bridging, with an overall efficiency comparable to that with HbA. The alpha alpha-fumaryl cross-linking of Hb-Presbyterian reduced its O(2) affinity much more significantly than that observed with HbA, indicating a synergy between the two low O(2) affinity-inducing structural perturbations. Apparently, the alpha alpha-fumaryl cross-bridge in Hb-Presbyterian activates part of the latent low O(2) affinity-inducing potential of Lys108(beta) that is generally activated in the presence of chloride. The synergy between the Asn108(beta)-->Lys mutation and the alpha alpha-fumaryl cross-bridging was conserved in the presence of chloride, but not in the presence of DPG. Furthermore, in the presence of chloride and DPG, alpha alpha-fumaryl Hb-Presbyterian accessed a low O(2) affinity T-state that is accessed by HbA, alpha alpha-HbA and Hb-Presbyterian only in the presence of IHP. Isoelectric focusing analysis suggested that the alpha alpha-fumaryl cross-linking of Hb-Presbyterian induces changes in the ionization behavior of one or more of the functional groups neighboring Lys99(alpha) and Lys108(beta) [presumably His103(alpha) and/or Glu101(beta)] to compensate for the extra positive charge of Lys108(beta). Molecular modeling studies identified two potential chloride binding sites per alpha beta dimer within the middle of the central cavity of alphaalpha-fumaryl HbA involving residues His103(alpha), Arg104(beta) and Asn108(beta). The affinity of these sites is increased in alpha alpha-fumaryl Hb-Presbyterian as a result of the Asn108(beta)-->Lys mutation. Thus, the results of the present study suggest that the enhanced neutralization of the positive charges in the middle of the central cavity of Hb achieved by these two electrostatic modifications, one (the alpha alpha-fumaryl cross-bridge) acting directly and the other (the Presbyterian mutation) acting indirectly through the mediation of chloride ion binding, facilitates the alpha alpha- fumaryl-Hb Presbyterian to access a low O(2) affinity T-state structure much more readily than either Hb-Presbyterian or alpha alpha-fumaryl HbA.

Perturbation of the intermolecular contact regions (molecular surface) of hemoglobin S by intramolecular low-O2-affinity-inducing central cavity cross-bridges.

The general assumption among researchers on hemoglobin is that the intramolecular central cavity cross-bridging of Hb does not result in any generalized perturbations at the protein surface. A corollary of this is that central cavity cross-bridges are unlikely to influence the polymerization of deoxy HbS, since polymerization is a protein surface phenomenon involving the participation of multiple protein surface amino acid residues. In an attempt to evaluate this experimentally, we have introduced two low-O2-affinity-inducing central cavity cross-bridges into HbS, beta(beta)-sebacyl [between the two Lys-82(beta) residues] and alpha(alpha)-fumaryl [between the two Lys-99(alpha) residues], and investigated their influence on the polymerization of the deoxy protein. The O2 affinities of the cross-bridged HbS exhibited sensitivity toward the buffer ions and pH in a cross-link-specific fashion. The modulation of the O2 affinity of these cross-bridged HbS in the presence of allosteric effectors, DPG and L-35, is also very distinct, reflecting the differences in the conformational features these two cross-bridges induce within the central cavity at the respective effector-binding domains. In addition, the alpha(alpha)-fumaryl cross bridge inhibited the polymerization, reflecting the perturbation of the microenvironment of one or more intermolecular contact residues, protein surface residues, as a consequence of the central cavity cross-bridge. On the other hand, the beta(beta)-sebacyl cross-bridge exerted a slight potentiating effect on the polymerization of HbS. This reflects the fact that the perturbations at the protein surface are limited and favor polymerization. The results presented demonstrate that the structural changes induced by the central cavity cross-bridges are very specific and not simply restricted to the sites of modification, but are propagated to distant sites/domains, both within and outside the central cavity. It is conceivable that other surface regions that are not involved in the polymerization could also experience similar structural/conformational consequences. These results should be taken into consideration in designing intramolecularly cross-bridged asymmetric hybrid HbS for mapping the contribution of the intermolecular contact residues in the cis and trans dimers of deoxy HbS during polymerization.

Interspecies hybrid HbS: complete neutralization of Val6(beta)-dependent polymerization of human beta-chain by pig alpha-chains.

Interspecies hybrid HbS (alpha(2)(P)beta(2)(S)), has been assembled in vitro from pig alpha-globin and human beta(S)-chain. The alpha(2)(P)beta(2)(S) retains normal tetrameric structure (alpha(2)beta(2)) of human Hb and an O(2) affinity comparable to that of HbS in 50 mM Hepes buffer; but, its O(2) affinity is slightly higher than that of HbS in the presence of allosteric effectors (chloride, DPG and phosphate). The (1)H-NMR spectroscopy detected distinct differences between the heme environments and alpha(1)beta(1) interfaces of pig Hb and HbS, while their alpha(1)beta(2) interfaces appear very similar. The interspecies hybrid alpha(2)(H)beta(2)(P) resembles pig Hb; the pig beta-chain dictated the conformation of the heme environment of the human alpha-subunit, and to the alpha(1)beta(1) interfaces of the hybrid. In the alpha(2)(P)beta(2)(S) hybrid, beta(S)-chain dictated the conformation of human heme environment to the pig alpha-chain in the hybrid; but the conformation of alpha(1)beta(1) interface of this hybrid is close to, but not identical to that of HbS. On the other hand, the alpha(1)beta(2) interface conformation is identical to that of HbS. More important, the alpha(2)(P)beta(2)(S) does not polymerize when deoxygenated; pig alpha-chain completely neutralizes the beta(S)-chain dependent polymerization. The polymerization inhibitory propensity of pig alpha-chain is higher when it is present in the cis alpha(P)beta(S) dimer relative to that in a trans alpha(P)beta(A) dimer. The semisynthetically generated chimeric pig-human and human-pig alpha-chains by exchanging the alpha(1-30) segments of human and pig alpha-chains have established that the sequence differences of pig alpha(31-141) segment can also completely neutralize the polymerization. Comparison of the electrostatic potential energy landscape of the alpha-chain surfaces of HbS and alpha(2)(P)beta(2)(S) suggests that the differences in electrostatic potential energy surfaces on the alpha-chain of alpha(2)(P)beta(2)(S) relative to that in HbS, particularly the ones involving CD region, E-helix and EF-corner of pig alpha-chain are responsible for the polymerization neutralization activity. The pig and human-pig chimeric alpha-chains can serve as blueprints for the design of a new generation of variants of alpha-chain(s) suitable for the gene therapy of sickle cell disease.

Cys-93-betabeta-succinimidophenyl polyethylene glycol 2000 hemoglobin A. Intramolecular cross-bridging of hemoglobin outside the central cavity.

Bis(maleidophenyl)-PEG2000 (Bis-Mal-PEG2000), a new bifunctional protein cross-linker targeted to sulfhydryl groups, introduces intra-tetrameric cross-links into oxy-HbA in nearly quantitative yields. Structural as well as crystallographic analyses of the cross-linked species, Bis-Mal-PEG2000 HbA, identified Cys-93(beta) as the site of intramolecular cross-linking. The cross-bridging had only a limited influence on the O(2) affinity and cooperativity of HbA in 50 mM BisTris acetate, pH 7.4. However, the Bohr effect was reduced by approximately 60%. Bis-Mal-PEG2000 HbA retained sensitivity to the presence of allosteric effectors 2, 3-diphosphoglycerate, IHP, and chloride, albeit to a lesser degree compared with HbA. Crystallographic analysis revealed the overall structure of deoxy-Bis-Mal-PEG2000 HbA to be similar to deoxy-HbA but for the loss of the salt bridge between Asp-94(beta) and His-146(beta). The large influence of the cross-bridging on the alkaline Bohr effect of HbA is consistent with the loss of this salt bridge. Unlike the "central cavity cross-bridges" described previously, the cross-link introduced by Bis-Mal-PEG2000 into HbA is an "outside the central cavity cross-bridge." In view of its oxy-conformational specificity and limited influence on O(2) affinity, this new cross-linking strategy holds promise for the stabilization of new designer low O(2) affinity Hbs generated by recombinant DNA technology for applications as Hb based therapeutics.

Probing the diphosphoglycerate binding pocket of HbA and HbPresbyterian (beta 108Asn --> Lys).

HbPresbyterian (beta 108Asn --> Lys, HbP) contains an additional positive charge (per alpha beta dimer) in the middle of the central cavity and exhibits a lower oxygen affinity than wild-type HbA in the presence of chloride. However, very little is known about the molecular origins of its altered functional properties. In this study, we have focused on the beta beta cleft of the Hb tetramer. Recently, we developed an approach for quantifying the ligand binding affinity to the beta-end of the Hb central cavity using fluorescent analogues of the natural allosteric effector 2, 3-diphosphoglycerate (DPG) [Gottfried, D. S., et al. (1997) J. Biol. Chem. 272, 1571-1578]. Time-correlated single-photon counting fluorescence lifetime studies were used to assess the binding of pyrenetetrasulfonate to both HbA and HbP in the deoxy and CO ligation states under acidic and neutral pH conditions. Both the native and mutant proteins bind the probe at a weak binding site and a strong binding site; in all cases, the binding to HbP was stronger than to HbA. The most striking finding was that for HbA the binding affinity varies as follows: deoxy (pH 6.35) > deoxy (pH 7.20) > CO (pH 6.35); however, the binding to HbP is independent of ligation or pH. The mutant oxy protein also hydrolyzes p-nitrophenyl acetate, through a reversible acyl-imidazole pathway linked to the His residues of the beta beta cleft, at a considerably higher rate than does HbA. This implies a perturbation of the microenvironment of these residues at the DPG binding pocket. Structural consequences due to the presence of the new positive charge in the middle of the central cavity have been transmitted to the beta beta cleft of the protein, even in its liganded conformation. This is consistent with a newly described quaternary state (B) for liganded HbPresbyterian and an associated change in the allosteric control mechanism.

Correct assembly of human normal adult hemoglobin when expressed in transgenic swine: chemical, conformational and functional equivalence with the human-derived protein.

Structural and functional investigations of recombinant human hemoglobin A (HbA) isolated from the erythrocytes of transgenic swine coexpressing human alpha- and beta-globins have been carried out to authenticate its correct expression, post-translational processing and assembly. The HbA expressed in transgenic swine (TgHbA) is indistinguishable from the human-derived HbA in terms of its isoelectric pH, mass and elution pattern on a Mono S column. The chemical identity of the alpha- and beta-globin chains of TgHbA with the corresponding chains from human-derived HbA has been established by tryptic peptide mapping and amino acid sequencing. The proton NMR spectra of TgHbA have demonstrated that the conformational aspects of the protein around the heme pocket are indistinguishable from those of the control sample of HbA. The equivalence of the hydrogen bond pattern of TgHbA (in particular the inter-subunit surfaces) with that of authentic HbA has also been established by NMR studies. Consistent with these structural and conformational analyses, the TgHbA also exhibits complete functional equivalence with the human-derived HbA with respect to oxygen affinity, cooperativity, Bohr effect and allostery. Hence the studies presented here demonstrate that the transgenic swine system correctly transcribes the alpha- and beta-globin transgenes, translates the respective alpha- and beta-globin mRNA to generate the corresponding globin chains, carries out the correct cotranslational processing of the translated globin chains, inserts the heme into the globin chains in the same orientation as in the human-derived HbA and assembles the alpha- and beta-subunits into a functionally cooperative tetramer that exhibits a response to allosteric effectors identical with that of human-derived HbA. Thus, in the transgenic swine system, in vitro chemical manipulation steps such as those needed in the Escherichia coli and the yeast systems, to convert the rHbA expressed in these systems into forms functionally identical with that of the human-derived protein, are not needed. An additional advantage of the transgenic swine system is the stability of the transgenes over many generations. Hence the transgenic swine could serve as an excellent system for the production of human HbA (or its variants) for structure-function studies and for therapeutic applications.

Chronic dosing with aminoguanidine and novel advanced glycosylation end product-formation inhibitors ameliorates cross-linking of tail tendon collagen in STZ-induced diabetic rats.

Solubility of tail tendon collagen from normal, streptozotocin-induced diabetic Lewis rats, and diabetic animals treated with aminoguanidine and two novel advanced glycosylation end products (AGE)-formation inhibitors was investigated by limited pepsin digestion under acidic conditions. Assays were conducted using tail tendon collagen from Lewis rats obtained from two different vendors, Harlan and Charles River Laboratories. Collagen solubility was assessed by following the kinetics of pepsin digestion. The data revealed that the rate of digestion for diabetic animals is markedly slow relative to that of normals. More strikingly, the kinetics of the diabetic animals showed the feature of a lag in digestion regardless of the animal source. Experiments designed to optimize the difference in solubility between normal and diabetic animals demonstrated that Charles River animals exhibit a greater window of solubility than the Harlan animals. More importantly, a pronounced effect of aminoguanidine, an AGE-formation inhibitor, was observed in Charles River animals, but not in the Harlan animals, presumably because of the larger window of solubility between the normal and the diabetic animals in the former. These data indicated that the Charles River Lewis rats are an animal model that demonstrates greater efficacy in this assay. Analysis of in vivo screens designed to test efficacy of aminoguanidine and two novel AGE-formation inhibitors, ALT 462 and ALT 486, demonstrated that monitoring an in vivo dose response is highly dependent on the enzyme concentration as well as the time of digestion, and that 1.5 h of digestion and 10 microg/ml pepsin (5 pg pepsin/mg collagen) appeared optimal. Under these conditions, a 29% normalization of solubility was observed with aminoguanidine at 100 mg/kg body wt, whereas a similar normalization was observed at 10 mg/kg body wt for both ALT 462 and ALT 486. Thus, on a molar basis, ALT 462 and ALT 486 are at least 20 times more potent than aminoguanidine. This is the first demonstration of dose-dependent efficacy for AGE-formation inhibitors in animal models, and as such, this assay provides a method with which to assess the in vivo efficacy of other such inhibitors.

Chimeric hemoglobins--hybrids of human and swine hemoglobin: assembly and stability of interspecies hybrids.

Transgenic swine expressing human HbA contained only one of two types of the anticipated interspecies hybrids, namely H alpha 2 P beta 2 (H = human, P = swine). In an attempt to establish whether the absence of the swine alpha and human beta (P alpha 2 H beta 2) hybrid in vivo is a reflection of the lack of complementarity between the interspecies chains to generate appropriate interfaces, we have undertaken the in vitro assembly of swine alpha and human beta chimeric tetramer. In contrast to the in vivo transgenic swine system, in vitro the hybrid of swine alpha human beta chain is assembled readily and the hybrid exhibits normal cooperative oxygen binding. Both the swine alpha human beta and the human alpha swine beta interspecies hybrids are stable around neutral pH and do not segregate into parent tetramers even when mixed together. On the other hand, nearly complete exchange of P alpha chain of P alpha 2 H beta 2 hybrid occurs in the presence of H alpha chain at pH 6.0 and room temperature, resulting in the formation of HbA. However, very little of such an exchange reaction takes place at pH 7.0. These results suggest that the thermodynamic stability of P alpha 2 H beta 2 hybrid is lower compared to that of HbA. In contrast, P beta chain of H alpha 2 P beta 2 hybrid is refractory to exchange with H beta chain at pH 7.0 as well as at pH 6.0, suggesting that the stability of H alpha 2 P beta 2 is higher compared to that of HbA (H alpha 2 H beta 2). The swine alpha human beta chimeric Hb undergoes subunit exchange reaction with human alpha-chain in the presence of 0.9 M MgCl2, at pH 7.0. This demonstrates the lower thermodynamic stability of the intradimeric interactions of the heterodimer even at neutral pH. A synergistic coupling of the intra- and interdimeric interactions of the swine alpha and human beta chain heterodimer is essential for the thermodynamic stability of the chimeric Hb under the physiological conditions. Accordingly, we speculate that the lower thermodynamic stability of P alpha H beta heterodimer (compared to the homodimers H alpha H beta and P alpha P beta) facilitates its segregation into the homodimers by subunit exchange reaction involving either H alpha or P beta. This molecular aspect by itself or possibly along with other cellular aspects of the swine system results in the absence of P alpha 2 H beta 2 hybrid in transgenic swine expressing HbA.

Intramolecular cross-linking of oxy hemoglobin by bis sulfosuccinimidyl suberate and sebacate: generation of cross-linked hemoglobin with reduced oxygen affinity.

The sulfosuccinimidyl esters of suberic and sebacic acids readily introduce intramolecular crosslinks into oxy HbA at pH 7.4, the relative efficiency of crosslinking by the suberate ester being slightly higher than that of sebacate. Nearly quantitative intramolecular crosslinking of HbA (0.5 mM) is achieved at pH 7.4 and 4 degrees C by using 5 and 10 fold molar excess of the suberic and sebacic acid, respectively. In contrast to the facile crosslinking reaction seen with the bis sulfosuccinimidyl sebacate, bis sulfosuccinimidyl sebacate and bis (3:5 dibromo salicyl) sebacate did not introduce any crosslinking into HbA despite the fact that the 'crosslinking arm' of the two bifunctional reagents is the same. The discrepant reactivity of the two reagents demonstrates the 'steering' influence of the negative charge of the leaving group of the reagent, namely sulfo succinimidyl moiety to specific domains of HbA rich in positively charged groups. A second advantage is also anticipated in the use of the sulfosuccinimidyl esters of aliphatic dicarboxylic acids. We speculate that the intermediate in the crosslinking reaction mimics the structural aspects of the low oxygen affinity 'psuedo crosslinked Hb'. Conversion of the low oxygen affinity 'psuedocrosslinked Hb' into crosslinked Hb by the formation of the second isopeptide bond may lead to the 'freezing in' of the elements of low oxygen affinity structure. Consistent with this speculation, the suberate crosslinked Hb indeed exhibited low oxygen affinity even though the crosslinking reaction was carried out in the oxy state.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of the chemical nature of side chain at beta 108 of hemoglobin A on the modulation of the oxygen affinity by chloride ions. Low oxygen affinity variants of human hemoglobin expressed in transgenic pigs: hemoglobins Presbyterian and Yoshizuka.

Hemoglobin A (HbA) and two low oxygen affinity variants of HbA, HbPresbyterian and HbYoshizuka, were produced in transgenic pigs and purified to homogeneity by ion-exchange chromatography. These two variants contain either lysine (HbPresbyterian) or aspartic acid (HbYoshizuka) instead of the normal asparagine residue at position beta 108 in HbA. Transgenic pigs expressed these variants at a level up to 11% and were healthy. Both HbPresbyterian and HbYoshizuka exhibited low O2 affinity (P50 of 21.2 and 18.9, respectively, compared with control HbA value of 11.8 in 0.1 M NaCl, pH 7.5) and retained normal cooperativity with Hill coefficients of 2.9 and 2.5, respectively. HbPresbyterian exhibited Bohr effect comparable with HbA. In contrast, HbYoshizuka had a diminished response to changes in pH. Thus the structural basis of reduced O2 affinity of these variants appears to be distinct: the consequence of mutation at beta 108 is a function of the chemical nature of the side chain. This is further confirmed by the sensitivity of the O2 affinity of the variants to the presence of Cl-. The O2 affinity of HbYoshizuka is insensitive to changes in Cl- concentration, whereas the O2 affinity of HbPresbyterian exhibited a pronounced and dramatic chloride effect. In fact, P50 of HbPresbyterian was identical to that of HbA at very low Cl- concentrations, and the P50 increased to >40 at 0.5 M Cl-. The chloride effect was completely abolished when HbPresbyterian was stabilized at the 2,3-diphosphoglycerate pocket by interdimeric cross-linking. Molecular modeling studies demonstrate that in HbPresbyterian, Cl- can bridge the epsilon-amino group of Lys beta 108 with either the guanidino group of Arg beta 104 or the epsilon-amino group of Lys alpha 99, resulting in the stabilization of the "T" structure. The utility of these low O2 affinity hemoglobins as cell-free oxygen carriers is discussed.

High-efficiency synthesis of human alpha-endorphin and magainin in the erythrocytes of transgenic mice: a production system for therapeutic peptides.

Chemical synthesis of peptides, though feasible, is hindered by considerations of cost, purity, and efficiency of synthesizing longer chains. Here we describe a transgenic system for producing peptides of therapeutic interest as fusion proteins at low cost and high purity. Transgenic hemoglobin expression technology using the locus control region was employed to produce fusion hemoglobins in the erythrocytes of mice. The fusion hemoglobin contains the desired peptides as an extension at the C end of human alpha-globin. A protein cleavage site is inserted between the C end of the alpha-globin chain and the N-terminal residue of the desired peptide. The peptide is recovered after cleavage of the fusion protein with enzymes that recognize this cleavage signal as their substrate. Due to the selective compartmentalization of hemoglobin in the erythrocytes, purification of the fusion hemoglobin is easy and efficient. Because of its compact and highly ordered structure, the internal sites of hemoglobin are resistant to protease digestion and the desired peptide is efficiently released and recovered. The applicability of this approach was established by producing a 16-mer alpha-endorphin peptide and a 26-mer magainin peptide in transgenic mice. Transgenic animals and their progeny expressing these fusion proteins remain health, even when the fusion protein is expressed at > 25% of the total hemoglobin in the erythrocytes. Additional applications and potential improvements of this methodology are discussed.

Recombinant hemoglobin A produced in transgenic swine: structural equivalence with human hemoglobin A.

Recombinant human hemoglobin A produced by coexpressing human alpha and beta globin genes in swine, and purified from the lysate of transgenic swine has been subjected to detailed protein chemical analysis. These structural studies involving laser desorption mass spectrometry, separation of globin chains by RPHPLC, amino terminal sequence analysis of the isolated globin chains, the tryptic peptide mapping of the purified globin chains and the amino acid composition analysis of the purified tryptic peptides of globin chains have established the primary structural equivalence of the globin chains of the transgenic swine derived hemoglobin A with that of human hemoglobin A. These results demonstrate that the transgenic swine system correctly translates the human alpha and beta globin m-RNA; carries out the correct cotranslational processing of globin chains, and does not introduce any unwanted post translational modifications into the mature chains. Thus, the transgenic swine expression system is an excellent approach for the production of HbA for developing an effective hemoglobin based oxygen carrier.

Bissulfosuccinimidyl esters of aliphatic dicarboxylic acids: a new class of 'affinity directed' beta beta crosslinkers of HbA.

The potential of sulfosuccinimidyl ester of suberic acid as an intramolecular crosslinker of HbA, directed to the positive charge rich domain of the protein (DPG pocket) has been investigated. The suberate ester introduced crosslinks between the beta-chains and inhibited the dissociation of HbA into alpha beta dimers. The facile crosslinking reaction seen with this suberate ester as compared to the absence of crosslinking with the diaspirin derivative of suberic acid suggests the strong 'steering' influence of the sulfosuccinimidyl moiety of the reagent to the targeted site. The application of this crosslinking approach in the preparation of Hb based blood substitutes is discussed.

Purification and characterization of polyphosphate kinase from Neisseria meningitidis.

The important human pathogens Neisseria meningitidis and Neisseria gonorrhoeae accumulate phosphate in the form of polyphosphate (A. Noegel and E. C. Gotschlich, J. Exp. Med. 157:2049-2060, 1983), and the localization of more than half of this long-chain polymer on the exterior of the cells suggests a function as a protective, capsule-like coating. To enable further genetic investigation of the role of polyphosphate in Neisseria spp., the enzyme polyphosphate kinase (PPK), which catalyzes the synthesis of polyphosphate from ATP, was purified from N. meningitidis BNCV. The activity is dependent on Mg2+ and phosphate or polyphosphate and is inhibited by ADP. The Km for ATP is 1.5 mM, and the turnover number is 47 phosphate residues per polypeptide per s. Analysis of PPK labelled with [gamma-32P]ATP indicates that the enzyme is phosphorylated during the reaction, probably at an arginine residue. N-terminal and two internal amino acid sequences were derived from the purified protein and will allow the design of synthetic oligonucleotides for cloning and genetic manipulation of the ppk gene.

Restriction in the conformational flexibility of apoproteins in the presence of organic cosolvents: a consequence of the formation of "native-like conformation".

The influence of n-propanol on the overall alpha-helical conformation of beta-globin, apocytochrome C, and the functional domain of streptococcal M49 protein (pepM49) and its consequence on the proteolysis of the respective proteins has been investigated. A significant amount of alpha-helical conformation is induced into these proteins at pH 6.0 and 4 degrees C in the presence of relatively low concentrations of n-propanol. The induction of alpha-helical conformation into the proteins increased as a function of the propanol concentration, the maximum induction occurring around 30% n-propanol. In the case of alpha-globin, the fluorescence of its tryptophyl residues also increased as a function of n-propanol concentration, the midpoint of this transition being around 20% n-propanol. Furthermore, concomitant with the induction of helical conformation into these proteins, the proteolysis of their polypeptide chain by V8 protease also gets restricted. The alpha-helical conformation induced into alpha- and beta-globin by n-propanol decreased as the temperature is raised from 4 to 24 degrees C. In contrast, the alpha-helical conformation of both alpha- and beta-chain (i.e., globin with noncovalently bound heme) did not exhibit such a sensitivity to this change in temperature. However, distinct differences exist between the n-propanol induced "alpha-helical conformation" of globins and the "alpha-helical conformation" of alpha- and beta-chains. A cross-correlation of the n-propanol induced increase in the fluorescence of beta-globin with the corresponding increase in the alpha-helical conformation of the polypeptide chain suggested that the fluorescence increase represents a structural change of the protein that is secondary to the induction of the alpha-helical conformation into the protein (i.e., an integration of the helical conformation induced to the segments of the polypeptide chain to influence the microenvironment of the tryptophyl residues). Presumably, the fluorescence increase is a consequence of the packing of the helical segments of globin to generate a "native-like structure." The induction of alpha-helical conformation into these proteins in the presence of n-propanol and the consequent generation of "native-like conformation" is not unique to n-propanol. Trifluoroethanol, another helix-inducing organic solvent, also behaves in the same fashion as n-propanol. However, in contrast to the proteins described above, n-propanol could neither induce an alpha-helical conformation into performic acid oxidized RNAse-A nor restrict its proteolysis by proteases.(ABSTRACT TRUNCATED AT 400 WORDS)

Helix formation in enzymically ligated peptides as a driving force for the synthetic reaction: example of alpha-globin semisynthetic reaction.

The alpha-globin semisynthetic reaction, namely, the ligation of the complementary fragments of alpha-globin, alpha 1-30 and alpha 31-141, in the presence of 30% l-propanol that is catalyzed by V8 protease is distinct as compared with the previously studied protease-catalyzed splicing of the discontinuity sites of the fragment complementing systems [Sahni et al. (1989) Biochemistry 28, 5456]. The complementary fragments of alpha-globin do not exhibit noncovalent interaction between them even in the presence of l-propanol, the organic cosolvent used to facilitate the alpha-globin semisynthetic reaction. Besides, a significant portion of the fragment alpha 31-141 does not contribute to the protease-catalyzed splicing reaction. Alpha 1-30 and alpha 31-40 are ligated by V8 protease to yield alpha 1-40 in much the same way as the splicing of alpha 1-30 with either alpha 31-141 or alpha 31-47 to yield alpha-globin or alpha 1-47, respectively. An equimolar mixture of alpha 1-30 and alpha 31-40 does not show any 'complexation' in the presence of 30% l-propanol, the medium used for the synthetic reaction. The splicing junction, i.e., Glu30-Arg31 peptide bond, is located in the middle of the B-helix (residues 20-35) of the parent protein. Most of the residues from the A-helix of the protein could also be deleted from segment alpha 1-30 without influencing the V8 protease-catalyzed splicing reaction.(ABSTRACT TRUNCATED AT 250 WORDS)

Heptad motifs within the distal subdomain of the coiled-coil rod region of M protein from rheumatic fever and nephritis associated serotypes of group A streptococci are distinct from each other: nucleotide sequence of the M57 gene and relation of the deduced amino acid sequence to other M proteins.

Streptococcal M protein, a dimeric alpha helical coiled-coil molecule, is an antigenically variable virulence factor on the surface of the bacteria. Our recent conformational analysis of the complete sequence of the M6 protein led us to propose a basic model for the M protein consisting of an extended central coiled-coil rod domain flanked by a variable N-terminal and a conserved C-terminal end domains. The central coiled-coil rod domain of M protein, which constitutes the major part of the M molecule, is made up of repeating heptads of the generalized sequence a-b-c-d-e-f-g, wherein "a" and "d" are predominantly apolar residues. Based on the differences in the heptad pattern of apolar residues and internal sequence homology, the central coiled-coil rod domain of M protein could be further divided into three subdomains I, II, and III. The streptococcal sequelae rheumatic fever (RF) and acute glomerulonephritis (AGN) have been known to be associated with distinct serotypes. Consistent with this, we observed that the AGN associated M49 protein exhibits a heptad motif that is distinct from the RF associated M5 and M6 proteins. Asn and Leu predominated in the "a" and "d" positions, respectively, in subdomain I of the M5 and M6 proteins, whereas apolar residues predominated in both these positions in the M49 protein. To establish whether the heptad motif of M49 is unique to this protein, or is a general characteristic of nephritis-associated serotypes, the amino acid sequence of M57, another nephritis-associated serotype, has now been examined. The gene encoding M57 was amplified by PCR, cloned into pUC19 vector, and sequenced. The C-terminal half of M57 is highly homologous to other M proteins (conserved region). In contrast, its N-terminal half (variable region) revealed no significant homology with any of the M proteins. Heptad periodicity analysis of the M57 sequence revealed that the basic design principles, consisting of distinct domains observed in the M6 protein, are also conserved in the M57 molecule. However, the heptad motif within the coiled-coil subdomain I of M57 was distinct from M5 and M6 but similar to M49. Similar analyses of the heptad characteristics within the reported sequences of M1, M12, and M24 proteins further confirmed the conservation of the overall architectural design of sequentially distinct M proteins.(ABSTRACT TRUNCATED AT 400 WORDS)

The amino-terminal region of group A streptococcal M protein determines its molecular state of assembly and function.

Group A streptococcal M protein, a major virulence factor, is an alpha-helical coiled-coil dimer on the surface of the bacteria. Limited proteolysis of type 57 streptococcus with pepsin released two fragments of the M57 molecule, with apparent molecular weights of 32,000 and 27,000 on SDS-PAGE. However, on gel filtration under nondenaturing conditions, each of these proteins eluted as two distinct molecular forms. The two forms corresponded to their dimeric and monomeric state as compared to the gel filtration characteristics of known dimeric coiled-coil proteins. The results of sedimentation equilibrium measurements were consistent with this, but further indicated that the "dimeric form" consisted of a dimer in rapid equilibrium with its monomer, whereas the "monomeric form" does not dimerize. The monomeric form was the predominant species for the 27 kD species, whereas the dimeric form predominated for the 32 kD species. Sequence analysis revealed the 27 kD species to be a truncated derivative of the 32 kD PepM57 species, lacking the N-terminal nonheptad region of the M57 molecule. These data strongly suggested that the N-terminal nonheptad region of PepM57 is important in determining the molecular state of the molecule. Consistent with this, PepM49, another nephritis-associated serotype, which lacks the nonheptad N-terminal region, also eluted as a monomer on gel filtration under nondenaturing conditions. Furthermore, removal of the N-terminal nonheptad segment of the dimeric PepM6 protein converted it into a monomeric form. The dimeric molecular form of both the 32 kD PepM57 and the 27 kD PepM57 did not represent a stable state of assembly, and were susceptible to conversion to the corresponding monomeric molecular forms by simple treatments, such as lyophilization. The 27 kD PepM57 exhibited a greater propensity than the 32 kD species to exist in the monomeric form. The 32 kD species contained the opsonic epitope of the M57 molecule, whereas the 27 kD species lacked the same. This is consistent with the previous reports on the importance of the N-terminal region of M protein for its opsonic activity. Together, these results strongly suggest that, in addition to its importance for the biological function, the N-terminal region of the M protein plays a dominant role in determining the molecular state of the M molecule, as well as its stability.

Domain structure and molecular flexibility of streptococcal M protein in situ probed by limited proteolysis.

Serologically distinct group A streptococcal M proteins, the antiphagocytic determinants of the bacteria, have a highly repetitive sequence and exhibit a heptad periodicity characteristic of alpha-helical coiled-coil proteins. Based on the differences in the pattern of hepatad periodicity, the coiled-coil region of the complete M molecule has been divided into three distinct domains: I, II, and III. Domains I and II together constitute the variable part of M protein, whereas domain III is conserved among serotypes. Pepsin treatment of the M5, M6, and M24 streptococci results in a preferential cleavage of their M molecules between the predicted domains II and III, releasing biologically active fragments of the respective M proteins. Thus, a pepsin cleavage site at the junction of their variable and conserved regions is conserved in the M5, M6, and M24 proteins. In contrast, in the case of the M49 streptococci, the primary site of pepsin cleavage was observed to be within the conserved region of the M49 molecule, rather than at the junction of its variable and conserved regions. Despite containing part of the conserved region, the PepM49 protein is significantly smaller than the pepsin fragments of the M5, M6, and M24 proteins, which contain only the variable regions. However, in addition to the major PepM49 species, the pepsin digest of the type-49 streptococci also contained a smaller fragment, PepM49/a, as a minor component. Its formation was extremely sensitive to the pH of pepsin digestion. PepM49/a, which retains both the propensity to attain an alpha-helical conformation and the opsonic antibody epitope of the M49 molecule, contains only domains I and II like the other PepM proteins. Thus, as in the M5, M6, and M24 proteins, a pepsin cleavage site at the junction of the variable and conserved regions is indeed present in the M49 molecule, but is much less accessible relative to the other serotypes. Thus, the pepsin cleavage sites in the M protein correlate quite well with the boundaries of structurally distinct domains reflected by the predictive analysis. These sites apparently represent the flexible/hinge regions of the molecule. PepM49/a is the least repetitive and the shortest of the M protein pepsin fragments isolated so far. These results suggest that the flexibility of the interdomain regions in M protein may be dependent on the molecular size of their variable domains.(ABSTRACT TRUNCATED AT 400 WORDS)