Structural characterization of two genetic variants of human serum albumin

In the present paper we report the structural characterization of two genetic mutants of human serum albumin: albumin Vanves, a very rare, electrophoretically fast variant of French origin, and albumin Verona, a slow-migrating variant which is the most frequently observed in Italy and which possesses the same electrophoretic mobility as albumin B. Both variants were isolated from the sera of healthy heterozygous subjects. Analysis of CNBr fragments by isoelectric focusing allowed us to localize the mutation to the COOH-terminal region of the molecule (residues 549-585) in both cases. The modified fragments were then isolated on a preparative scale by HPLC and subjected to tryptic digestion. Sequential analysis of the abnormal tryptic peptide, purified by HPLC, established the mutation responsible for albumin Vanves as 574 Lys----Asn and the molecular defect of albumin Verona as 570 Glu----Lys, both probably due to point mutations in the structural genes. The amino-acid substitutions found in albumins Verona and Vanves are consistent with the electrophoretic mobilities observed for the native proteins at pH 8.6.     

The molecular defect of albumin Tagliacozzo: 313 Lys----Asn

Albumin Tagliacozzo is a fast-moving genetic variant of human serum albumin found in 19 unrelated families. The protein was isolated from the serum of a heterozygous healthy subject. Analysis of CNBr fragments by isoelectric focusing allowed us to localize the mutation to CNBr fragment IV (residues 299-329). This fragment was isolated on a preparative scale and subjected to tryptic digestion. Sequential analysis of the abnormal tryptic peptide, purified by RP-HPLC, revealed the variant was caused by 313 Lys----Asn substitution, probably due to a point mutation in the structural gene. The lack of a lysine residue accounts for the electrophoretic behavior of albumin Tagliacozzo.     

Two alloalbumins with identical electrophoretic mobility are produced by differently charged amino acid substitutions.

We describe the amino acid substitutions of albumins Sondrio and Paris 2, two slow moving variants of human serum albumin, which show an identical electrophoretic mobility on cellulose acetate at three different pH values. These variants have been found in several instances in a wide geographic area including Northern Italy and France. Both alloalbumins were isolated from the sera of heterozygous subjects. Isoelectric focusing analysis of CNBr fragments from the purified variants allowed us to localize the mutation of albumin Sondrio in fragment CNBr V (residues 330-446) and that of albumin Paris 2 in CNBr VII (residues 549-585). Sequential analysis of the variant CNBr VII established the molecular defect of albumin Paris 2 as 563 Asp----Asn. Fragments CNBr V from normal and Sondrio albumins were isolated on a preparative scale and subjected to tryptic and V8 proteinase digestion. Sequence determination of the abnormal tryptic and V8 peptides revealed that the variant arises from the substitution of glutamic acid 333 by lysine. Thus, a +1 change in the C-terminal region of the albumin molecule produces a variant with the same electrophoretic mobility as an alloalbumin with a +2 substitution in the central domain, suggesting a higher degree of exposure to the solvent of the C-terminal tailpiece. Both amino acid substitutions are consistent with a G----A transition in the first position of the corresponding codon in the structural gene.     

Albumin Hawkes Bay; a low level variant caused by loss of a sulphydryl group at position 177

A slow migrating minor albumin component, representing 5% of total circulating albumin, was detected by routine serum protein electrophoresis and immunofixation. After treatment with 5 mM dithiothreitol the abnormal component was found to migrate normally suggesting the attachment of some component to the free thiol at position 34. However, purification and analysis by SDS-PAGE showed that the abnormal component had a slightly lower apparent molecular weight than normal albumin. Limited tryptic cleavage indicated the abnormal site to be in the N-terminal third of the molecule. HPLC analysis of tryptic peptides from this domain showed the presence of a new peptide of sequence Ala-Ala-Phe-Leu-Leu-Pro-Lys, indicating either a point mutation of 177 Cys → Phe or the deletion of residues 166–177. DNA sequencing of PCR-amplified DNA confirmed the former Cys → Phe substitution by indicating a point mutation of C to A at nucleotide position 5185. It appears that the aberrant electrophoretic mobility of the variant might be due to a gross conformational change associated with the formation of a new disulphide bond between Cys-168 and Cys-124.     

The molecular defect of albumin Castel di Sangro: 536 Lys----Glu

Albumin Castel di Sangro is a rare fast-moving variant of human serum albumin which has been discovered in heterozygous form in the serum of an 85-year-old woman living in Castel di Sangro (Abruzzo, Italy). Isoelectric focusing analysis of CNBr fragments from the purified variant allowed us to localize the mutation in fragment CNBr VI (residues 447-548). This fragment was isolated on a preparative scale and subjected to tryptic digestion. Sequential analysis of the abnormal tryptic peptide, purified by reverse-phase and cation-exchange HPLC, revealed that the variant arises from the substitution of lysine 536 by glutamic acid. This amino acid replacement, probably due to a single-base substitution in the structural gene, causes a change in the net charge of -2 units, which is in keeping with both the increased electrophoretic mobility of the native protein and the isoelectric point of the modified CNBr fragment.     

The molecular defect in a COOH-terminal-modified and shortened mutant of human serum albumin

Albumin Venezia is a fast migrating genetic variant of human serum albumin which, in heterozygous subjects, represents about 30% of the circulating protein. The molecular defect in this variant was studied in a subject possessing an atypical level of the mutant (80% of the total protein) and in other members of his family. Albumins, isolated from the sera of the propositus and his heterozygous relatives, were treated with CNBr and the resulting fragments analyzed by isoelectric focusing. The peptides were then isolated in a homogeneous form by reverse-phase high performance liquid chromatography and submitted to sequence analysis. The results show that albumin Venezia possesses a shortened polypeptide chain, 578 residues instead of 585, completely variant from residue 572 to the COOH-terminal end: sequence: (see text). This extensive modification may be accounted for by the deletion of exon 14 and translation to the first terminator codon of exon 15, which normally does not code for protein. The absence of a basic COOH-terminal dipeptide in the mature molecule can be explained by the probable action of serum carboxypeptidase N. Additional support for such action comes from examination of the remaining 20% of the total albumin of the propositus, which is found to contain an extra Arg at its COOH terminus, probably due to partial digestion by carboxypeptidase N. The low serum level of the variant in heterozygous subjects suggests that the COOH-terminal end of the molecule is critical for albumin stability.     

Localization of the amino acid substitution site in a fast migrating variant of human serum albumin

Albumin Mi/Fg is an Italian genetic variant of human serum albumin arising from a Lys----Glu substitution which has been located in a CNBr fragment (CNBr VII) corresponding to the -COOH terminal portion of the molecule [(1984) J. Chromatogr. 298, 336-344]. Tryptic peptides of CNBr VII from normal and Mi/Fg albumin have been purified by reverse-phase high-performance liquid chromatography (RP-HPLC) and submitted to comparative structural studies. The amino acid sequence of the tryptic peptide of Mi/Fg variant that differs from the corresponding fragment of the normal serum albumin shows that the Lys----Glu substitution responsible for this variant is located at position 573. This region of the albumin molecule is involved in the binding of long chain fatty acids.     

Studies on a genetically determined albumin dimer

An electrophoretic variant of human albumin has been characterized as a dimer involving both disulfide and noncovalent bonds. The variant protein was isolated by starch block electrophoresis and gel filtration and extensively investigated by gel electrophoresis and immunoelectrophoresis under a variety of conditions. No significant differences were found between normal albumin and the propositus's albumin in sulfhydryl reactivity or content or in the tryptic fingerprint.Contribution No. 140 from the Blood Research Laboratory, American National Red Cross.     

Structural differences between albumin A and albumin C of the house mouse,Mus musculus

Two albumins, albumin A from C3H mice and albumin C isolated from descendents of the wild mice in which the variant was first uncovered, were found to differ in their electrophoretic properties. Albumin C was shown to bind two more H⁺ ions than albumin A at pH 5.4. Peptide mapping after trypsin digestion revealed that albumin C had three peptides (TP-C1, TP-C2, and TP-C3) which were missing in albumin A. The latter likewise had a peptide (TP-A1) which was not found in albumin C. An amino acid analysis of the variant peptides suggests that TP-A1 had been split into TP-C1 and TP-C2 on digestion with trypsin, because a glutamic acid in TP-A1 was replaced by a lysine. This change would also appropriately alter the electrophoretic properties of albumin C. No obvious counterpart was discovered for TP-C3 of albumin C in albumin A.This work was supported by a grant from the National Research Council of Canada.     

Detection of a genetic variant, lysine→glutamic acid at position 372 of human serum albumin, by capillary electrophoresis and structural identification

A genetic variant of human serum albumin (alloalbumin) is detected by capillary electrophoresis (CE). Two albumin peaks, which were in the ratio of approximately one, were clearly separated. One of the peaks had the same migration time as normal albumin (Alb A) and the other (Alb X) had a longer migration time. SDS-polyacrylamide gel electrophoresis of CNBr fragments (CB) of Alb X indicated that the amino acid substitution was localized in the CB5 fragment (residue 330–446) of the molecule, because of anomalous migration of CB5 in the gel. The CE mapping of the tryptic peptides from the variant CB5 revealed clearly the existence of a new peptide, and the lack of two normal peptides. The sequence analysis of the variant peptide collected by CE micropreparation showed that the N-terminus of the variant peptide corresponded to that of T49 in Alb A. The substitution site, lysine→glutamic acid at the position 372, was revealed by sequence determination of the variant peptide purified by reversed-phase HPLC.     

A nucleotide insertion and frameshift cause albumin Kénitra, an extended and O-glycosylated mutant of human serum albumin with two additional disulfide bridges.

Albumin Kenitra is a new type of genetic variant of human serum albumin that has been found in two members of a family of Sephardic Jews from Kenitra (Morocco). The slow-migrating variant and the normal protein were isolated by anion-exchange chromatography and, after treatment with CNBr, the digests were analyzed by two-dimensional electrophoresis in a polyacrylamide gel. The CNBr peptides of the variant were purified by reverse-phase high performance liquid chromatography and submitted to sequence analysis. Albumin Kenitra is peculiar because it has an elongated polypeptide chain, 601 residues instead of 585, and its sequence is modified beginning from residue 575. DNA structural studies showed that the variant is caused by a single-base insertion, an adenine at nucleotide position 15 970 in the genomic sequence, which leads to a frameshift with the subsequent translation to the first termination codon of exon 15. Mass spectrometric analyses revealed that the four additional cysteine residues of the variant form two new S-S bridges and showed that albumin Kenitra is partially O-glycosylated by a monosialylated HexHexNAc structure. This oligosaccharide chain has been located to Thr596 by amino-acid sequence analysis of the tryptic fragment 592-597.     

Albumin associated with purified pig lymphocyte plasma membrane.

Plasma-membrane preparations purified from pig lymphocytes contained a major polypeptide component of mol.wt. about 68 000. This component was identified as pig albumin by the following comparisons with authentic pig serum albumin: (a) co-migration when analysed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis under reducing and non-reducing conditions; (b) identical isoelectric points; (c) similar "fingerprints" of arginine-containing tryptic peptides; (d) reactivity with anti-(pig albumin) serum. The albumin was bound tightly to the plasma membrane. Biosynthetic labelling of pig lymphocytes under a variety of conditions failed to provide evidence that albumin was synthesized by lymphocytes, suggesting that the plasma-membrane-associated albumin was of extraneous origin. Radiolabelled pig serum albumin, however, failed to bind to the plasma-membrane fraction when added before cell disruption. Although lymphocyte plasma membrane preparations from other species possessed a polypeptide of about 68 000 mol.wt., this was judged not to be albumin on the basis of electrophoretic mobility under non-reducing conditions; also, no polypeptide was precipitated by anti-albumin sera. It is concluded that pig lymphocyte plasma-membrane preparations possess albumin which, although firmly attached, was probably of extraneous origin. This association appeared not to be common to lymphocytes from other species.     

Study of the primary structures of the peptide core of bovine estrus cervical mucin. Possible existence of small similar subunits

Two populations of tryptic peptides were isolated from bovine estrus cervical mucin (BCM). One contained all the carbohydrate, and was rich in threonine and serine. These glycopeptides had, like the whole mucin, alanine as their NH2-terminal residues. Their COOH-terminal residues were arginine. The second population of peptides was rich in carboxylic amino acids, contained two cysteinyl residues, and had, like the whole mucin, leucine as COOH-terminal residues. Their NH2-terminal residues were aspartic acid. The sum of the residues of one glycopeptide plus one cysteinyl-containing peptide corresponded to the number of residues constituting a putative subunit of BCM. The amino acid sequence of the major cysteinyl peptide was determined. A cluster of hydrophobic residues was found in the COOH-terminal region. The amino acid sequences of two of the glycopeptides were found identical up to the 22nd residue. The small number of tryptic peptides, as well as the large amount of NH2- and COOH-terminal amino acids found in BCM indicate that this glycoprotein is made up of similar subunits with a molecular weight of about 22,000, one of the glycopeptides representing the NH2-terminal part, and one of the cysteinyl peptides, the COOH-terminal part. However, the existence of these subunits was not confirmed by ultracentrifugation of BCM in dithiothreitol and sodium dodecyl sulfate. BCM was polydisperse and had a mean molecular weight of 507,000.     

A new proalbumin variant: albumin Jaffna (-1 Arg----Leu)

Albumin Jaffna is an electrophoretically slowly moving genetic variant of human serum albumin found in two members of a Tamil family from Jaffna (Northern Sri Lanka), both heterozygous for the abnormal protein. Sequential analysis of albumin Jaffna, purified from serum by ion exchange chromatography on DEAE Sephadex and Mono Q columns, revealed that this variant is a new abnormal proalbumin, arising from a -1 Arg----Leu substitution, which prevents the proteolytic removal of the N-terminal hexapeptide and allows the mutated proalbumin to enter the circulation. The presence of two additional positive charges is in keeping with the decreased electrophoretic mobility of albumin Jaffna, as well as with its isoelectric point of 5.01, determined by chromatofocusing on a Mono P column. The variant is selectively cleaved by trypsin in vitro, leaving leucin -1 as N-terminal residue.     

Limited pepsin digestion of human plasma albumin.

Limited pepsin digestion of human plasma albumin at pH 3.5 and 0 degrees in the presence of octanoate caused cleavage at residue 307 of the albumin molecule to yield two fragments. Thw two fragments corresponding to the NH2- and the COOH-terminal halves of the molecule were isolated in yields of about 15%. The COOH-terminal fragment is a mixture in which about 85% of the molecules had an additional cleavage at residue 422 of the albumin molecule. The COOH-terminal fragment with the additional cleavage at residue 422 contains two peptides which are linked by a disulfide bridge at residues 391 and 437 of the albumin molecule. Both the NH2- and the COOH-terminal fragment of human albumin showed no detectable binding of octanoate anions, that is, less than 1/170 of the binding constant of the primary site of human albumin. These findings differ from earlier observations on limited pepsin digestion of bovine plasma albumin where the corresponding COOH-terminal fragment had the octanoate-binding activity, about 1/8 of the primary binding constant of bovine albumin, while the NH2-terminal fragment did not. The COOH-terminal fragment of bovine albumin did not have cleavage at residue 422 as in the corresponding fragment of human albumin. However, it is not clear that the loss of octanoate-binding activity of fragment C of human albumin is a direct consequence of the cleavage at residue 422.     

Studies on the structure of rabbit muscle aldolase: Amino acid sequence of cysteine-containing peptides

Five cysteine-containing peptides have been isolated in nearly stoichemometric yields from the tryptic digests of the NH₂^? and COOH-terminal BrCN peptides of rabhit muscle aldolase and their sequence determined. Peptides NS1, NS2, and NS3, from the NH₂-terminal part of the enzyme have the following sequences: NS1, Val-Asp-Pro-Cys-Ile-Gly-Gly-Val-Ile-Leu-Phe-His-Glu-Thr-Leu-Tyr-Gln-Lys; NS2, Cys-Val-Leu-Lys; NS3, Cys-Ala-Glu-Tyr-Lys. The two peptides isolated from the COOH-terminal region are: CS1, Ala-Leu-Ala-Asn-Ser-Leu-Ala-Cys-Gln-Gly-Lys and CS2, Cys-Pro-Leu-Leu-Trp-Pro-Lys-Ala-Leu-Thr-Phe-Ser-Tyr-Gly-Arg. The Lys-Ala bond in peptide CS2 was found to be resistant to tryptic hydrolysis. The results provide the basis for assigning the positions of cysteine residues in the polypeptide chain. Cys-72 in peptide NS1 and Cys-336 in peptide CS1 are the residues that form a disulfide bridge when the enzyme is inactivated by oxidation with an o-phenanthroline-Cu²⁺ complex; Cys-287 in peptide CS2 in one of the two exposed residues, while Cys-134 and Cys-149 in peptides NS2 and NS3, respectively, are buried in the native enzyme. All of eight cysteine-containing peptides of rabbit muscle aldolase have now been sequenced, and structural homology of the α and β subunits extended to these regions.     

Isolation of cathepsin B inhibitory peptides,Cabin-A1 and -A2, from a tryptic and chymotryptic hydrolysate of human serum albumin

Two novel peptides that inhibit cathepsin B were isolated from a tryptic and chymotryptic hydrolysate of human serum albumin, and designated as Cabin-A1 and -A2. Cabin-A1 and -A2 were purified by reversed-phase HPLC and identified as Ser-Leu-His-Thr-Leu-Phe and Phe-Gln-Asn-Ala-Leu, respectively. These peptides correspond to f(65-70) and f(403-407) of human serum albumin. Human albutensin A (Ala-Phe-Lys-Ala-Trp-Ala-Val-Ala-Arg), which corresponds to f(210-218), was also isolated as a potent cathepsin B inhibitor. Synthetic Cabin-A1, -A2, and human albutensin A showed dose-dependent inhibition of cathepsin B, with K(i) values of 2.4, 290, and 3.8 microM, respectively.     

The amino acid sequence of fragment A, an enzymically active fragment of diphtheria toxin. II. The cyanogen bromide peptides.

Cyanogen bromide cleavage of Fragment A from diphtheria toxin at the four methionines present in each molecule resulted in five major peptides which were isolated and studied by sequence methods. These five peptides of 4, 11, 14, 63, and 101 residues account for all 193 residues in Fragment A and provide overlaps for the tryptic peptides from the maleylated protein. Two additional peptides were isolated and shown to be shorter forms (8 and 10 residues) of the COOH-terminal cyanogen bromide peptide (11 residues).     

Structural characterization, stability and fatty acid-binding properties of two French genetic variants of human serum albumin

Four bisalbuminemic, unrelated persons were found in Bretagne, France, and their variant and normal albumins were isolated by DEAE ion exchange chromatography, reduced, carboxymethylated and treated with CNBr. Comparative two-dimensional electrophoresis of the CNBr digests showed that three of the variants were modified in fragment CB4, whereas the fourth had an abnormal fragment CB1. These fragments were isolated, digested with trypsin and mapped by reverse-phase HPLC. Sequencing of altered tryptic peptides showed that the three variants modified in CB4 were caused by the same, previously unreported, amino acid substitution: Asp314-->Val (albumin Brest). The fourth, however, was a proalbumin variant with the change Arg-2-->Cys (albumin Ildut). Both amino acid substitutions can be explained by point mutations in the structural gene: GAT-->GTT (albumin Brest) and CGT-->TGT (albumin Ildut). The proalbumin Ildut is very unstable and already in vivo it is to a large extent cleaved posttranslationally to Arg-Albumin and normal albumin. Furthermore, we observed that during a lengthy isolation procedure the remaining proalbumin was changed to Arg-Albumin or proalbumin lacking Arg-6. In addition, part of normal albumin had lost Asp1. Gas chromatographic investigations using isolated proteins indicated that albumin Brest has improved in vivo fatty acid-binding properties, whereas the structural modification(s) of albumin Ildut does not affect fatty acid binding.     

Proteomic identification of a basic peroxidase stabilized within acetylated polymannan polysaccharide of Aloe barbadensis

Acetylated polymannan polysaccharide (ApmP) isolated from Aloe barbadensis Miller contains a stable peroxidase that was solubilized to investigate its biochemical, electrophoretic, immunological, and proteomic properties. In the electrophoretic band corresponding to the solubilized peroxidase, proteomic analysis detected seven tryptic peptides that matched homologous peptides covering one third of the ATP22a peroxidase of Arabidopsis thaliana. All the characteristics tested indicated that the activity stabilized within the ApmP pertains to the basic secretory peroxidase family, which includes members that have several biotechnological uses. Hence ApmP might yield a widely used peroxidase in stabilized form.