Quantitative analysis of the amino-terminal residues of spectrin by use of the transamination reaction

Erythrocyte spectrin is comprised of many homologous triple helical segments

Spectrin is an alpha beta heterodimeric protein (molecular weight (Mr) = 460,000) which is a major component of the erythrocyte membrane skeleton. The membrane skeleton also includes actin (band 5) and is attached to the membrane via non-covalent associations with two linking proteins. Recently we have reported the amino acid sequence of a peptide of molecular weight 80,000 which comprises the NH2-terminal one-third of the alpha subunit. This alpha-subunit peptide contains multiple homologous non-identical sequences with a periodicity of 106 amino acids and an approximate molecular weight of 12,000. It was also established that spectrin is not related to any other proteins whose sequence was known. We now report additional amino acid sequence of peptides representative of other domains of both spectrin subunits. The results suggest that most of the human erythrocyte spectrin molecule is comprised of homologous segments with a 106 amino acid (Mr 12,000) length per segment. Each homologous 106-amino acid segment may be folded into a triple helical structure with a short non-helical region connecting adjacent units.

Spectrin domains: proteolytic susceptibility as a probe of protein structure

Mild treatment of human erythrocyte spectrin with trypsin produces discrete intermediate-sized peptides. The effects of buffer composition, enzyme-substrate ratio, temperature, and other experimental parameters on the resulting peptide pattern have been examined. Spectrin is capable of regaining its proteolytic resistance after NaDodSO4-induced denaturation, permitting the use of isolated subunits to study spectrin structure and function. Tryptic digestion of isolated subunits also has greatly facilitated the identification of the subunit origin of the intermediate-sized peptides. Isolated subunits could also be recombined to form functional units similar but not identical to the native dimeric form of the regions or domains connected by small protease sensitive segments. The structural integrity and accessibility of these sites is minimally affected by oligomeric state or proteolytic digestion conditions. The similarities of sizes, isoelectric points, and amino acid compositions of many intermediate-size peptides from areas of both subunits suggest that at least part of spectrin's structure may have evolved via replication of a single gene. A possible structural repeat of approximately 50,000 daltons is hypothesized.

Identification of proteolytically resistant domains of human erythrocyte spectrin

Digestion of purified human erthrocyte spectrin with proteolytic enzymes at 0 degrees C results in the production of intermediate-size peptides that resist further cleavage at 0 degrees C. By two-dimensional peptide analysis of these intermediate peptides it has been determined that five unique peptides are produced by tryptic cleavage of the alpha subunit of spectrin (band 1); these have apparent molecular weights of 80,000, 46,000, 46,000, 41,000, and 30,000 and account for 97% of the alpha subunit. Similarly, four unique peptides having apparent molecular weights of 74,000, 65,000, 33,000, and 38,000 account for 90% of the beta subunit (band 2). By examining larger peptide fragments, the linear alignment of the unique peptides along each of the spectrin subunits has been established. These results indicate that spectrin is composed of two nonidentical subunits, each containing multiple proteolytically resistant domains. These domains, which may be largely alpha-helical, seem to be connected by small protease-sensitive segments. The proteolytic resistance of these domains is not influenced by the multimeric state of the spectrin molecule.