Difference between revisions of "Part:BBa K1639005"

Revision as of 08:40, 21 September 2015

H-NS(T108I)

global DNA-binding transcriptional dual regulator H-NS mutant form.

Usage and Biology

Donato and Kawula investigated the effect on bacterial motility of random point mutations in the HNS protein. As a result of their Swarm plate assay and experiments for the determination of flagellar rotational speed, it was found that some random mutations (HSN-T108I and HNS-A18E) resulted in bacteria with a stronger and faster flagella as compared with wild type bacteria. This single amino acid change caused a 50% increase in the binding of HNS to FliG.. It was also shown that this single amino acid change in HNS resulted in an approximately 50% increase in flagellar rotation speed and about a 2-fold increase in the bacteria’s swarm size.

Figure 1: H-NS-FliG cross-linked complexes. Reactions were incubated at room temperature and equal amounts were electrophoresed on denaturing poly acrylamide gels. A, Coomassie-stained 4–20%SDSpolyacrylamidegradient gel; B, 12% SDS-polyacrylamide gel transferred to nitrocellulose, and probed with H-NS antiserum; C, second half of gel in B probed with FliG antiserum. Protein. Standard sizes are indicated by lines; lmw, low molecular weight markers; hmw, high molecular weight markers; protein monomers, dimers, and H-NS-FliG complexes are indicated by arrows. Reactions for all panels: 1, wild-type H-NS only; 2, H-NST108I only; 3, FliG only; 4, wild-type H-NS with cross-linker; 5, H-NST108I with cross-linker; 6, FliG with cross-linker;7, 1:1 molar ratio of wild-type H-NS to FliG with cross-linker; 8, 1:1molar ratio of H-NST108I to FliG with cross-linker.

Figure 2: Swarm plate assay. Fresh colonies from strains carrying the indicated alleles were inoculated onto semi-solid agar plates and grown at 30 °C. Growth was measured as the diameter of the bacterial swarm over several time points. Bacteria with swarm diameters under 10 mm at the end of 17 h incubation were considered non-motile. Data representative of three individual experiments. *, vector; f, hns2-tetR; ,,wild-type HNS; l, hnsT108I; l, hnsA18E..

Figure 5: Flagella propel bacteria by rotating motor-driven helical filaments (35, 36) whereby swimming speed is directly related to flagellar rotational speed (39). Gina M. Donato and Thomas H. Kawula1 , in another experiment which they tried to compare rotational speeds of mutant and wild-type bacteria, they concluded that hnsA18E and hnsT108I accelerated flagellar speeds 44–62% over wild-type levels.

In the results from fluorescence anisotropy and chemical cross-linking, Donato and Kawula showed that there is an interaction between HNS and FliG, the protein responsible for flagellar torque; and they show that the mutant form of HNS binds FliG 50% more often than does wild-type HNS: They explain the increase in the bacteria’s swarm rate and swim speed caused by mutant HNS thusly “We position H-NS at the interface between the rotor and stator, directly linked to the C terminus of FliG(Fig. 5 A). Tighter binding of mutant H-NST108I toFliG (Fig.5 B) may cause increases in flagellar speed by altering the conformation of FliG relative to the other rotor proteins and/or the MotA·B complex, thus, compacting the motor complex and allowing fast errotation by creating less friction within the surrounding stationary MotA·B ring complex (56).

This study having captured our attention, we decided to use mutant HNS to increase flagellar speed and torque power.

Sequence and Features