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.     

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.     

Structural characterization of a chain termination mutant of human serum albumin

Mutant forms of human serum albumin have been detected on the basis of their abnormal electrophoretic mobility which is either faster or slower than that of normal albumin. In the present work we have studied the structure of a slow variant, referred to as albumin Ge/Ct, in order to define the cause of its genetic abnormality. The protein was isolated from the serum of a young healthy woman homozygous for the variant. Analysis of CNBr fragments by isoelectric focusing allowed us to localize the mutation to the COOH-terminal region of the molecule (residues 549-585). This fragment was isolated on a preparative scale and subjected to tryptic digestion. All tryptic peptides were purified by reverse-phase high performance liquid chromatography and characterized. Sequential analysis of three abnormal peptides revealed that albumin Ge/Ct has a shortened chain with the following COOH-terminal sequence: Leu-Val-Ala-Ala-Ser-Lys580-Leu-Pro. The presence of an additional lysine residue accounts for the electrophoretic behavior of the variant. It is likely that the variant may be caused by a single base deletion in the structural gene, a Cyt in mRNA codon 580, and the consequent shift in reading frame.     

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.     

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.     

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.     

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.     

Alloalbuminemia in North India.

Electrophoretic screening of sera from 550 individuals from Punjab, North India, revealed four cases of alloalbuminemia. Two albumin variants migrated slower and two migrated faster than the common albumin A. These variants were further analyzed by electrophoresis of their cyanogen bromide fragments to localize their molecular differences. One of the slow variants appears similar to, if not identical with, albumin B, with an altered cyanogen bromide fragment CNBr VII. The other slow variant appears to be a new variant (proposed name albumin Punjab) differing from albumin A in an altered fragment CNBr VI (which also occurs in albumins Kashmir and Adana) and in an altered fragment CNBr I. Among the fast variants, one has the same altered fragment CNBr V as albumin Naskapi, while the other appears to be a new variant (proposed name albumin Patiala) having an altered fragment CNBr VI. The presence of albumin Naskapi in Punjabis, North American Indians, and Eti Turks (previously reported) is consistent with the existence of a common ancestral population in which the mutation to Naskapi occurred before the migrations eastward and westward.     

Protein and DNA sequence analysis of a ‘private’ genetic variant: albumin Ortonovo (Glu-505 → Lys)

Albumin Ortonovo is a slow moving variant of human serum albumin which has been found only in people coming from the small villages of Ortonovo and Nicola (Liguria, Italy) and reaches polymorphic frequency (≥1%) in the poorly admixed population group living in that area. This is the first report of a ‘private’ varint detected in a Caucasin population. It probably originated as a mutation in a founder individual many generations ago. Isoelectric focusing analysis of CNBr fragments from the purified variant localized the mutation in fragment CNBr (residues 447–548). This fragment was isolated on a preparative scale by reversed-phase HPLC and subjected to V8 proteinase digestion. Sequence analysis of the abnormal V8 peptide revealed that the variant arises from a previously unreported substitution at position 505 where glutamic acid has been replaced by lysine. The protein data were confirmed by DNA sequence analysis which indicated a single nucleotide change of $\text{G}\text{AA}\text{→}\text{A}\text{AA}$ in the corresponding codon of the structural gene. Since the amino acid substitution found in albumin Ortonovo accords with its electrophoretic mobility on cellulose acetate, residue 505 is probably exposed to the solvent. The clustering of the mutations in the intersubdomain connection linking subdomains IIIA and IIIB (residues 492–511) accords with the fact that this region lies on the molecular surface and is accessible to solvent.     

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.     

Membrane glycophorins in Sta blood group erythrocytes

Structural and immunochemical studies of glycophorins isolated from erythrocytes of an individual homozygous for the M Sta blood group phenotype are described. Reactivities with specific monoclonal antibodies indicated that two major M and N glycophorins were present. The M and N Sta glycophorins were resolved by Lens culinaris lectin affinity chromatography. The N species was not held on the lectin but the M species, like control alpha glycophorins, was retained and could be eluted with alpha-methylmannoside. The two proteins were present in almost equimolar amounts. Studies of the CNBr fragments provided evidence that the structure of M Sta glycophorin is the same as that of the usual M alpha glycophorin but that the N Sta glycophorin is a variant. The amino-terminal octapeptides of the M and N species were similar in amino acid and carbohydrate composition to those isolated, respectively, from M and N alpha glycophorins. The studies focused on CNBr glycopeptide B that, in control alpha glycophorins, extends from amino acid residues 9 to 81. The fragment from the M species exhibited properties identical to those of the corresponding fragment of control alpha glycophorins in terms of size, chromatographic behavior, amino acid and carbohydrate contents and compositions, the presence of O-glycosidically linked saccharides and a single Asn-linked carbohydrate unit. The structures of the O-linked units were inferred experimentally to be NeuAc(alpha 2,3)Gal-(beta 1,3)GalNAc and NeuAc(alpha 2,3)Gal(beta 1,3) [NeuAc(alpha 2,6)]GalNAc, present in a ratio similar to that found in controls; and the Asn-linked unit also appeared to be as in the control. The tryptic glycopeptide pattern of the M Sta glycophorin CNBr fragment B was identical to the pattern of the corresponding control fragment, and the composition of the tryptic peptides suggested sequence identity with the control fragment. In contrast, the N Sta glycophorin yielded two CNBr glycopeptides B; both contained fewer amino acid residues and virtually lacked Man and GlcNAc, indicating the absence of the Asn-linked carbohydrate. The much decreased levels of these carbohydrates in the intact N protein, corroborated the latter finding. The O-glycosidic saccharides appeared similar to those found in control alpha glycophorins. However, the tryptic glycopeptide pattern of the variant differed from control M or N alpha glycophorins, suggesting a deletion of a large segment of the molecule near residues 40-61 and/or a substitution of methionine for a residue upstream from residue 40.(ABSTRACT TRUNCATED AT 400 WORDS)     

Phlorizin and Trilobatin,Sweet Dihydrochalcone-Glucosides from Leaves of Lithocarpus litseifolius (Hance) Rehd. (Fagaceae)

To determine the primary structure of the α-amylase produced by Bacillus subtilis var. amylosacchariticus, we have reported the isolation of thirty-four tryptic peptides and eight CNBr fragments from the enzyme. Since the alignment of the eight CNBr fragments was made by matching with six methionine-containing tryptic peptides, the order of tryptic peptides within each CNBr fragment was determined. In the case of four small CNBr fragments, sequence analyses using an automated sequence analyzer established the peptide orders within these fragments. For larger fragments, further fragmentation was done using chymotrypsin or staphylococcal protease V8 and the resultant peptides were isolated and sequenced. Consequently, the peptide orders within three out of four large CNBr fragments were established.     

Isolation and properties of a fragment of human serum albumin demonstrating the absence of a methionine residue from some of the albumin molecules.

1. A fragment designated D was isolated from human serum albumin degraded by CNBr. Its properties show that it is made up of the B and C fragments isolated by McMenamy et al. (1971) (J. Biol. Chem., 246, 4744-4750). 2. Reduction of fragment D gives rise to two chains, one of which consists of the second subfragment of reduced fragment B linked to fragment C by an amino acid different from methionine. It thus demonstrates the existence of albumin molecules from which the second methionine residue located between fragments B and C is missing.     

The molecular abnormality of albumin Parklands: 365 Asp----His

An electrophoretically slow albumin variant was isolated from the plasma of a patient with bisalbuminemia. Reverse-phase peptide mapping revealed a single altered peak when tryptic digests of the normal and variant albumin were compared. After rechromatography and amino acid analysis, a sequence/composition of Cys-Cys-Ala-Ala-Ala-His-Pro,His,Glu,Cys,Tyr,Ala,Lys was obtained for the mutant peptide, while a sequence of Cys-Cys-Ala-Ala-Ala-Asp-Pro-His-Glu-Cys-Tyr,Ala,Lys was obtained for the normal peptide. This establishes the mutation as 365 Asp----His and the new albumin has been named albumin Parklands. Interestingly, this mutation results in the loss of the single Asp-Pro bond that is normally present between residues 365 and 366. Predictably, this confers on albumin Parklands a greater resistance to partial acid hydrolysis, a feature which, when employed together with SDS-gel electrophoresis, can be used as a diagnostic test for the presence of this variant.     

Biochemical characterization of peptides from herpes simplex virus glycoprotein gC: loss of CNBr fragments from the carboxy terminus of truncated, secreted gC molecules.

A biochemical characterization of peptides from herpes simplex virus type 1 glycoprotein gC was carried out. We utilized simple micromethods, based on immunological isolation of biosynthetically radiolabeled gC, to obtain gC in pure form for biochemical study. CNBr fragments of gC were prepared, isolated, and characterized. These CNBr fragments were resolved into six peaks by chromatography on Sephacryl S-200 in 6 M guanidine hydrochloride. Only three of the CNBr fragments contained carbohydrate side chains, as judged from the incorporation of [14C]glucosamine. Radiochemical microsequence analyses were carried out on the gC molecule and on each of the CNBr fragments of gC. A comparison of this amino acid sequence data with the amino acid sequence predicted from the DNA sequence of the gC gene showed that the first 25 residues of the predicted sequence are not present in the gC molecule isolated from infected cells and allowed alignment of the CNBr fragments in the gC molecule. Glycoprotein gC was also examined from three gC mutants, synLD70, gC-8, and gC-49. These mutants lack an immunoreactive envelope form of gC but produce a secreted, truncated gC gene product. Glycoprotein gC from cells infected with any of these gC- mutants was shown to have lost more than one CNBr fragment present in the wild-type gC molecule. The missing fragments included the one containing the putative transmembrane anchor sequence. Glycoprotein gC from the gC-8 mutant was also shown, by tryptic peptide map analysis, to have lost more than five major arginine-labeled tryptic peptides arginine-labeled tryptic peptides present in the wild-type gC molecule and to have gained a lysine-labeled tryptic peptide not present in wild-type gC.     

Amino acid sequence of beta-galactosidase. XI. Peptide ordering procedures and the complete sequence.

The amino acid sequence of beta-galactosidase has been determined. The monomer contains 1,021 amino acid residues in a single polypeptide chain and has a molecular weight of 116,349. All 80 tryptic peptides as well as all 24 CNBr peptides have been isolated in pure form. Evidence is presented for the ordering of the CNBr peptides. The sequence determination was aided by analysis of cyanogen bromide peptides obtained from a polypeptide fragment produced by a lacZ termination mutant strain.     

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.     

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.     

Albumin Rugby Park: a truncated albumin variant caused by a G → C splice-site mutation in nitro 13

Three members of a family were found to be heterozygous for a fast albumin variant (Albumin Rugby Park) that made up only 8% of total serum albumin. Isoelectric focussing indicated an increased negative charge on the C-terminal CNBr peptide and C-terminal sequence analysis of the native protein showed an aberrant sequence of -Ser-Phe. Sequence analysis of PCR-amplified DNA indicated a G → C mutation at oposition 1 of the 13th intron and this was confirmed by restriction digestion. The replacement of the obligate GT sequence by CT at the exon/intron boundary prevents splicing of the 13th intron and translation continues for 21 nucleotides until a stop codon is reached. The new protein lacks the 14 amino acids coded for in the 14th exon (GKKLVAASQAALGH), but these are replaced by 7 new residues (LLQFSSF), giving a truncated albumin of 578 residues.     

Albumin Rugby Park: a truncated albumin variant caused by a G-->C splice-site mutation in intron 13.

Three members of a family were found to be heterozygous for a fast albumin variant (Albumin Rugby Park) that made up only 8% of total serum albumin. Isoelectric focussing indicated an increased negative charge on the C-terminal CNBr peptide and C-terminal sequence analysis of the native protein showed an aberrant sequence of -Ser-Phe. Sequence analysis of PCR-amplified DNA indicated a G-->C mutation at position 1 of the 13th intron and this was confirmed by restriction digestion. The replacement of the obligate GT sequence by CT at the exon/intron boundary prevents splicing of the 13th intron and translation continues for 21 nucleotides until a stop codon is reached. The new protein lacks the 14 amino acids coded for in the 14th exon (GKKLVAASQAALGH), but these are replaced by 7 new residues (LLQFSSF), giving a truncated albumin of 578 residues.