Abstract
Lsr2 is a small DNA-binding protein present in mycobacteria and related actinobacteria that regulates gene expression and influences the organization of bacterial chromatin. Lsr2 is a dimer that binds to AT-rich regions of chromosomal DNA and physically protects DNA from damage by reactive oxygen intermediates (ROI). A recent structure of the C-terminal DNA-binding domain of Lsr2 provides a rationale for its interaction with the minor groove of DNA, its preference for AT-rich tracts, and its similarity to other bacterial nucleoid-associated DNA-binding domains. In contrast, the details of Lsr2 dimerization (and oligomerization) via its N-terminal domain, and the mechanism of Lsr2-mediated chromosomal cross-linking and protection is unknown. We have solved the structure of the N-terminal domain of Lsr2 (N-Lsr2) at 1.73 Å resolution using crystallographic ab initio approaches. The structure shows an intimate dimer of two ß–ß–a motifs with no close homologues in the structural databases. The organization of individual N-Lsr2 dimers in the crystal also reveals a mechanism for oligomerization. Proteolytic removal of three N-terminal residues from Lsr2 results in the formation of an anti-parallel β-sheet between neighboring molecules and the formation of linear chains of N-Lsr2. Oligomerization can be artificially induced using low concentrations of trypsin and the arrangement of N-Lsr2 into long chains is observed in both monoclinic and hexagonal crystallographic space groups. In solution, oligomerization of N-Lsr2 is also observed following treatment with trypsin. A change in chromosomal topology after the addition of trypsin to full-length Lsr2-DNA complexes and protection of DNA towards DNAse digestion can be observed using electron microscopy and electrophoresis. These results suggest a mechanism for oligomerization of Lsr2 via protease-activation leading to chromosome compaction and protection, and concomitant down-regulation of large numbers of genes. This mechanism is likely to be relevant under conditions of stress where cellular proteases are known to be upregulated.
Highlights
Bacterial nucleoid-associated proteins (NAPs) play important roles in chromosome organization and gene regulation [1,2,3,4]
Lsr2 from M. tuberculosis is a small, basic protein (Mr = 12.1 kDa, pI = 10) that is highly conserved in mycobacteria and related actinobacteria [9]
The lsr2 gene is essential for Mycobacterium tuberculosis and is implicated in the regulation of a broad range of cellular processes including cell-wall biosynthesis and the response to antibiotics [20]
Summary
Bacterial nucleoid-associated proteins (NAPs) play important roles in chromosome organization and gene regulation [1,2,3,4]. Histone nucleoid structuring protein (H-NS) is an abundant nonspecific DNA-bridging NAP in the Enterobacteriaceae and is thought to have a role in global gene expression [1]. NAPs such as the histone like protein, H-NS and Lsr have been identified and studied in some detail from Mycobacterium tuberculosis and Mycobacterium smegmatis [6,7,8]. Lsr from M. tuberculosis is a small, basic protein (Mr = 12.1 kDa, pI = 10) that is highly conserved in mycobacteria and related actinobacteria [9]. Lsr orthologues have been identified in a number of mycobacteriophage genomes [13,14]
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