Autonomous Sequences in Myoglobin Emerging from X-ray Structure of Holomyoglobin

[Image: see text] The proposed continuous folding structure units are fundamental to analyze protein structure. Here, we could elucidate for the first time two types of hydrophobic core networks in apomyoglobin using continuous folding structure units. In myoglobin, two autonomous sequences emerged clearly. We could thus characterize the autonomous sequences using well-defined hydrophobic core networks within respective semifolds. A hydrophobic core is defined as a pair of topology-local hydrophobic amino acids in different folding structures. Hydrophobic core formation is indispensable to stabilize the different folding structures via an efficient hydrophobic interaction. Autonomous sequences in myoglobin encode tertiary structure information for semifolds. These sequences fold autonomously into small sets of continuous folding structure units to grow separate semifolds on each separate framework. The autonomous sequence can be defined as the local sequence assigned to the small set of continuous folding structure units. They create the discrete hydrophobic region in a semifold by assembly of their hydrophobic regions. Semifolds were characterized by discrete hydrophobic regions stabilized by respective type I hydrophobic core networks, which were present within each semifold. The discrete hydrophobic region of a semifold propagated itself with that of a different semifold by hydrophobic interactions in type II hydrophobic core network, which was present between different semifolds, as observed by the X-ray structures of semifolds. The most significant feature of semifolds in apomyoglobin was that they could be verified by the X-ray structure of holomyoglobin regardless of the instability of folds characteristic to autonomous sequence fragments. This work presents the first description of autonomous sequences.