Sigma Factor Displacement from RNA Polymerase during Bacillus subtilis Sporulation

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Journal of Bacteriology, August 1999, p. 4969-4977, Vol. 181, No. 16
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Sigma Factor Displacement from RNA Polymerase during Bacillus subtilis Sporulation

Jingliang Ju, Theresa Mitchell, Howard Peters III, and W. G. Haldenwang^*

Department of Microbiology, University of Texas Health Science Center at San Antonio, San Antonio, Texas 78284-7758

Received 14 October 1998/Accepted 2 June 1999

As Bacillus subtilis proceeds through sporulation, the principal vegetative cell $sigma$ subunit ( $sigma$ ^A) persists in the cell but is replaced in the extractable RNApolymerase (RNAP) by sporulation-specific $sigma$ factors. To explorehow this holoenzyme changeover might occur, velocity centrifugationtechniques were used in conjunction with Western blot analysesto monitor the associations of RNAP with $sigma$ ^A and two mother cell $sigma$ factors, $sigma$ ^E and $sigma$ ^K, which successively replace $sigma$ ^A on RNAP. Although the relative abundance of $sigma$ ^A with respect to RNAP remained virtually unchanged during sporulation,the percentage of the detectable $sigma$ ^A which cosedimented with RNAP fell from approximately 50% at theonset of sporulation (T₀) to 2 to 8% by 3 h into the process (T₃).In a strain that failed to synthesize $sigma$ ^E, the first of the mother cell-specific $sigma$ factors, approximately40% of the $sigma$ ^A remained associated with RNAP at T₃. The level of $sigma$ ^A-RNAP cosedimentation dropped to less than 10% in a strain whichsynthesized a $sigma$ ^E variant ( $sigma$ ^ECR119) that could bind to RNAP but was unable to direct $sigma$ ^E-dependent transcription. The E- $sigma$ ^E-to-E- $sigma$ ^K changeover was characterized by both the displacement of $sigma$ ^E from RNAP and the disappearance of $sigma$ ^E from the cell. Analyses of extracts from wild-type and mutantB. subtilis showed that the $sigma$ ^K protein is required for the displacement of $sigma$ ^E from RNAP and also confirmed that $sigma$ ^K is needed for the loss of the $sigma$ ^E protein. The results indicate that the successive appearanceof mother cell $sigma$ factors, but not necessarily their activities,is an important element in the displacement of preexisting $sigma$ factorsfrom RNAP. It suggests that competition for RNAP by consecutivesporulation $sigma$ factors may be an important feature of the holoenzymechangeovers that occur duringsporulation.

^* Corresponding author. Mailing address: Department of Microbiology, University of Texas Health Science Center at San Antonio,San Antonio, TX 78284-7758. Phone: (210) 567-3957. Fax: (210)567-6612. E-mail: Haldenwang{at}UTHSCSA.EDU.

Present address: Gene Regulation and Chromosome Biology Laboratory, ABL Basic Research Program, NCI-FCRDC, Frederick, MD21702.

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