Chemistry (Sep 2023)

Structure, Stability and Binding Properties of Collagen-Binding Domains from <i>Streptococcus mutans</i>

  • Akari Nishi,
  • Hikaru Matsui,
  • Azumi Hirata,
  • Atsushi Mukaiyama,
  • Shun-ichi Tanaka,
  • Takuya Yoshizawa,
  • Hiroyoshi Matsumura,
  • Ryota Nomura,
  • Kazuhiko Nakano,
  • Kazufumi Takano

DOI
https://doi.org/10.3390/chemistry5030130
Journal volume & issue
Vol. 5, no. 3
pp. 1911 – 1920

Abstract

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Collagen-binding proteins (CBP), Cnm and Cbm, from Streptococcus mutans are involved in infective endocarditis caused by S. mutans because of their collagen-binding ability. In this study, we focused on the collagen-binding domain (CBD), which is responsible for the collagen-binding ability of CBP, and analyzed its structure, binding activity, and stability using CBD domain variants. The CBD consists of the N1 domain, linker, N2 domain, and latch (N1-N2~) as predicted from the amino acid sequences. The crystal structure of the Cnm/CBD was determined at a 1.81 Å resolution. N1_linker_N2 forms a ring structure that can enfold collagen molecules, and the latch interacts with N1 to form a ring clasp. N1 and N2 have similar immunoglobulin folds. The collagen-binding activities of Cbm/CBD and its domain variants were examined using ELISA. N1-N2~ bound to collagen with KD = 2.8 μM, and the latch-deleted variant (N1-N2) showed weaker binding (KD = 28 μM). The linker-deleted variant (N1N2~) and single-domain variants (N1 and N2) showed no binding activity, whereas the domain-swapped variant (N2-N1~) showed binding ability, indicating that the two N-domains and the linker are important for collagen binding. Thermal denaturation experiments showed that N1-N2 was slightly less stable than N1-N2~, and that N2 was more stable than N1. The results of this study provide a basis for the development of CBD inhibitors and applied research utilizing their collagen-binding ability.

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