Evolution of the Self-reproducing System to the Biosynthesis of the Membrane: An Approach from the Amino Acid Sequence Similarity in Proteins

In order to study the problem of how the biomembrane synthesis started in the evolutionary process of the self-reproducing system, we carry out an extensive similarity search of the sequence data stored in databases, using the acetyl-CoA carboxylase, fatty acid synthase and the enzyme proteins leading to the combination ofsn-glycerol 3-phosphate and fatty acid as the query sequences. With the use of the FASTA program (Pearson & Lipman, 1988), the proteins that carry an amino acid sequence showing similarity to any of the query sequences are picked up under the criterion of statistical significance of more than 6.0 for the homology, then classified according to the functional blocks where they operate. Finally they are filtered to the enzyme proteins in the metabolic pathways and to the DNA-or RNA-interacting proteins in the translation, transcription and replication apparatuses by eliminating proteins such as membrane proteins, lipase etc. which seem to have been generated after the appearance of the biomembrane. The distribution of the proteins thus selected shows a clear pattern that the amino acid sequences showing considerable similarity to the biomembrane synthetic proteins are concentrically found in the enzyme proteins in and around the section of glycolytic pathway from glyceraldehyde 3-phosphate to pyruvate while the DNA- or RNA-interacting proteins similar to the query sequences are distributed sparsely over the translation, transcription and replication systems. The assignment of similarity regions ascertains that considerable regions of most biomembrane synthetic proteins are covered by the enzyme proteins in and around the glycolytic pathway. Although acetyl-CoA carboxylase and fatty acid synthase are full of variety in the constitution of active domains depending on species, the above-mentioned pattern is also obtained by using either the monofunctional or the multifunctional type of proteins as the query sequences. Thus, the evolution towards biomembrane synthesis may be positioned as an event following the establishment of a section of glycolytic pathway from glyceraldehyde 3-phosphate to pyruvate. The causality of this evolution from the glycolytic pathway to the biomembrane synthesis is also discussed in connection with the absorption of protons released in the glycolytic process.