Myxococcus xanthus cells move on a solid surface by gliding motility. Several genes required for gliding motility have been identified, including those of the A- and S-motility systems as well as the mgl and frz genes. However, the cellular defects in gliding movement in many of these mutants were unknown. We conducted quantitative, high-resolution single-cell motility assays and found that mutants defective in mglAB or in cglB, an A-motility gene, reversed the direction of gliding at frequencies which were more than 1 order of magnitude higher than that of wild type cells (2.9 min−1 for ΔmglAB mutants and 2.7 min−1 for cglB mutants, compared to 0.17 min−1 for wild-type cells). The average gliding speed of ΔmglAB mutant cells was 40% of that of wild-type cells (on average 1.9 μm/min for ΔmglAB mutants, compared to 4.4 μm/min for wild-type cells). The mglA-dependent reversals and gliding speeds were dependent on the level of intracellular MglA protein: mglB mutant cells, which contain only 15 to 20% of the wild-type level of MglA protein, glided with an average reversal frequency of about 1.8 min−1 and an average speed of 2.6 μm/min. These values range between those exhibited by wild-type cells and by ΔmglAB mutant cells. Epistasis analysis of frz mutants, which are defective in aggregation and in single-cell reversals, showed that a frzD mutation, but not a frzE mutation, partially suppressed the mglA phenotype. In contrast to mgl mutants, cglB mutant cells were able to move with wild-type speeds only when in close proximity to each other. However, under those conditions, these mutant cells were found to glide less often with those speeds. By analyzing double mutants, the high reversing movements and gliding speeds of cglB cells were found to be strictly dependent on type IV pili, encoded by S-motility genes, whereas the high-reversal pattern of mglAB cells was only partially reduced by a pilR mutation. These results suggest that the MglA protein is required for both control of reversal frequency and gliding speed and that in the absence of A motility, type IV pilus-dependent cell movement includes reversals at high frequency. Furthermore, mglAB mutants behave as if they were severely defective in A motility but only partially defective in S motility.
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机译:粘球菌黄腐细胞通过滑动运动在固体表面上移动。已经确定了滑动运动所需的几种基因,包括A-和S-运动系统的基因以及mgl和frz基因。然而,在许多这些突变体中滑行运动中的细胞缺陷是未知的。我们进行了定量,高分辨率的单细胞运动测定,发现在mglAB或c-glB(一种A活力基因)中有缺陷的突变体以比野生型高1个数量级的频率反转了滑行方向。细胞(ΔmglAB突变体为2.9 min -1 ,而cglB突变体为2.7 min -1 ,而野生型细胞为0.17 min -1 )。 ΔmglAB突变细胞的平均滑动速度是野生型细胞的40%(ΔmglAB突变体的平均滑动速度为1.9μm/ min,而野生型细胞为4.4μm/ min)。 mglA依赖的逆转和滑行速度取决于细胞内MglA蛋白的水平:mglB突变细胞,仅含有野生型MglA蛋白水平的15%至20%,滑行时的平均逆转频率约为1.8分钟< sup> -1 ,平均速度为2.6μm/ min。这些值介于野生型细胞和ΔmglAB突变细胞所显示的值之间。对聚集和单细胞逆转有缺陷的frz突变体的上位性分析表明,frzD突变(而非frzE突变)部分抑制了mglA表型。与 mgl 突变体相反, cglB 突变体细胞仅在彼此接近时才能够以野生型速度移动。但是,在这些条件下,发现这些突变细胞以这些速度滑动的频率较低。通过分析双突变体,发现 cglB 细胞的高反向运动和滑行速度严格依赖于由S运动基因编码的IV型菌毛,而的高反向模式mglAB 细胞仅通过 pilR 突变而部分还原。这些结果表明,MglA蛋白是控制逆转频率和滑行速度所必需的,并且在缺乏A运动的情况下,IV型菌毛依赖性细胞运动包括高频率逆转。此外, mglAB 突变体的行为就好像它们在A运动中严重缺陷,而在S运动中仅部分缺陷。
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