Electron microscopic studies of the interaction between a Bacillus subtilis alpha/beta-type small, acid-soluble spore protein with DNA: protein binding is cooperative, stiffens the DNA, and induces negative supercoiling.

Abstract

DNA within spores of Bacillus subtilis is complexed with a group of alpha/beta-type small acid-soluble spore proteins (alpha/beta-type SASPs), which have almost identical primary sequences and DNA binding properties. Here electron microscopic and cyclization studies were carried out on alpha/beta-type SASP-DNA complexes. When an alpha/beta-type SASP was incubated with linear DNA, the protein bound cooperatively, forming a helical coating 6.6 +/- 0.4 nm wide with a 2.9 +/- 0.3 nm periodicity. alpha/beta-Type SASP binding to an 890-bp DNA was weakest at an (A+T)-rich region that was highly bent, but binding eliminated the bending. alpha/beta-Type SASP binding did not alter the rise per bp in DNA but greatly increased the DNA stiffness as measured by both electron microscopic and cyclization assays. Addition of alpha/beta-type SASPs to negatively supertwisted DNA led to protein binding without significant alteration of the plectonemically interwound appearance of the DNA. Addition of alpha/beta-type SASPs to relaxed or nicked circular DNA led to molecules that by electron microscopy appeared similar to supertwisted DNA. The introduction of negative supertwists in nicked circular DNA by alpha/beta-type SASPs was confirmed by ligation of these molecules followed by topoisomer analyses using agarose gel electrophoresis.