Rex-Centric Mutualism

doi:10.1128/JB.184.3.857-858.2002

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Journal of Bacteriology, February 2002, p. 857-858, Vol. 184, No. 3
0021-9193/01/$04.00+0 DOI: 10.1128/JB.184.3.857-858.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

Rex-Centric Mutualism

Roderick A. Slavcev and Sidney Hayes^*

Department of Microbiology and Immunology, College of Medicine, University of Saskatchewan, Saskatoon, Saskatchewan S7N 5E5, Canada

Received 6 September 2001/ Accepted 21 October 2001

ABSTRACT

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Abstract

Introduction

References

We asked whether Rex exclusion encoded by a lambda prophageconfers a protective or a cell-killing phenotype. We found thatthe Rex system can channel lysogenic cells into an arrestedgrowth phase that gives an overall protective ability to thehost despite some associated killing.

INTRODUCTION

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Abstract

Introduction

References

The term "Rex phenotype" connotes generalized phage exclusionby ${lambda}$ lysogens, a process that restricts plaque formation by rIImutants of T4 (4), certain T7 and T5 mutants, and particularvariants of lambdoid phages (12, 17). The rex locus of coliphage ${lambda}$ encoded by genes rexA and rexB (11) is cotranscribed as partof the p_M-cI-rexA-rexB-t_imm operon expressed by a repressed ${lambda}$ prophage (8). The model of Parma et al. (13) predicts thatRexB protein forms an inner membrane pore that is opened upondirect interaction with at least two RexA proteins, resultingin a cellular apoptotic response termed altruistic cell death.The degree of apoptosis was unreported. We asked if the Rexphenotype confers a protective or a cell-killing response tophage attack.

We utilized derivatives of Escherichia coli K-12 strains R594[F^- lac-3350 galK2 galT22 rpsL179 IN(rrnD-rrnE)1 ${lambda}$ ^-] (3), W3350A[F^- lac-3350 galK2 galT22 IN(rrnD-rrnE)1 ${lambda}$ ^-] (3), and SA500 [F^-his-87 relA1 strA181 tsx-83 ${lambda}$ ^-] to prepare lysogens. The ${lambda}$ wildtype was from our stock (no. 271), and ${lambda}$ rexB5A and ${lambda}$ rexA30A werefrom G. Gussin (11) via W. Szybalski. The phages T4rIIA (pointmutation in the rIIA gene of T4), T4rII ${Delta}$ 1589 (deletion spanningthe rIIA and rIIB genes), and T4D were obtained from G. Mosig.

Cellular viability was determined following T4rII infection(multiplicity of infection, 10) of the Rex⁺ lysogen R594( ${lambda}$ ),the Rex^- lysogens R594( ${lambda}$ rexA30A) and R594( ${lambda}$ rexB5A), and nonlysogenicR594 cells. Optimal infectivity occurred at temperatures between37 and 43°C, with a reduction of >10³-fold infectivityat 30°C, in agreement with the results of earlier studies(2, 6). The examination of spread plates from mock infectionswithout T4rII showed that virtually 100% of the CFU arose duringthe first 24 h of plate incubation at temperatures between 30and 43°C. No survivors were seen among the T4rII-infectedcells during the same interval. We continued incubation foran additional 24 h, during which the CFU from mock infectionsincreased in size, and tiny surviving CFU appeared between 36and 48 h among the T4rII-infected Rex⁺ lysogens, revealing aprolonged growth arrest. The CFU that survived T4rII infectionwere examined for retention of the Rex⁺ phenotype and sensitivityto T4. All CFU tested remained Rex⁺ and T4 sensitive. The Rex⁺R594( ${lambda}$ ) lysogens survived T4rII infections with $>=$ 40% viabilityat temperatures between 37 and 43°C. In contrast, we foundthat the viability of Rex^- R594 culture cells infected at temperaturesbetween 37 and 43°C was <0.001%. Similar results werefound for R594( ${lambda}$ rexA) and R594( ${lambda}$ rexB) lysogens. Identical infectionsof the Rex⁺ lysogens SA500( ${lambda}$ ) and W3350A( ${lambda}$ ) yielded the same levelof survivors as that of R594( ${lambda}$ ), whereas the viability of theirRex^- derivatives was <0.01%. This experiment revealed thatthe Rex⁺ phenotype can confer an enormous (>10⁴-fold) protectiveadvantage to infected ${lambda}$ lysogenic cells. We also monitored theviability of Rex⁺ and Rex-defective lysogenic and nonlysogeniccells infected in solution with T4 ${Delta}$ rII at a multiplicity of infectionof 5. Both R594 and R594( ${lambda}$ rex) culture cells were reduced intiter by more than 10³-fold (assay minimum) within the firsthour, and surviving CFU were not subsequently detected. By contrast,infected R594( ${lambda}$ ) cells showed a 10-fold drop in cell titer withinthe first hour of infection, a lag in cell growth, and a subsequentincrease in CFU. None of the surviving R594( ${lambda}$ ) CFU tested werefound to be resistant to T4. In all of the infection experiments,we observed that the surviving cells in aliquots removed fromcultures appeared as CFU after a prolonged lag in cell growthand were considerably smaller than the CFU arising from parallelmock infections.

Our findings suggest that the rex genes of ${lambda}$ confer symbioticprotection to the lysogenic host against secondary infection.Previous studies have shown that high cellular levels of Rexexpression restricts plaque formation by phages T2, T4, T5,T6, and T7 (15); thus, the advantage of the Rex phenotype inthe wild may be more widespread than is appreciated. However,mechanistically, it is far from clear that the Rex phenotypeevolved, is maintained, or functions in the wild for the purposeof host protection against secondary lytic infection. It isour view that the cellular manifestations of Rex exclusion thatare triggered upon infection may be severe enough to resultin cell death but may also provide the intolerable environmentnecessary to eliminate invading phage DNA. We found that boththe infection of ${lambda}$ rex⁺ lysogenic cells with T4rII and their transformationwith a rexA multicopy plasmid (data not shown) delayed the emergenceof CFU. The prolonged arrest in cell growth of prexA transformantsof R594( ${lambda}$ ) helped us to account for the results of Snyder andMcWilliams (16).

The question of how a Rex⁺ cell avoids lethal gene expressionfrom infecting T4rII remains unanswered. The stationary physiologicalphase of E. coli host cells has been shown to prevent the growthof T4 phage (7, 9), and these cells maintain a lower protonmotive force (10). Furthermore, during starvation, the stringentresponse prevents macromolecular synthesis (5, 14) and may leadto bacterial apoptosis (1). The Rex system acquired by lambdacan channel lysogenic cells into an arrested growth phase resemblingthe stationary phase or the stringent response, both of whichhave levels of cell killing associated with them; however, onthe whole, the responses of this system exhibit mutualism, conferringa protective ability to the host. The hypothesis that the ${lambda}$ Rexphenotype triggers an altruistic response in excluding the platingof T4rII requires that the rexB-rexA genes function as a suicidemodule. Our study does not support this model but rather suggeststhat Rex exclusion of invading phage is a protective mechanismwhich results in the increased survival of infected cells andin turn defends the cell population as a whole from subsequentphage exposure.

ACKNOWLEDGMENTS

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This study was supported by an NSERC operating grant to S. H.Roderick Slavcev received teaching fellowships from the Collegesof Medicine and Graduate Studies and Research, University ofSaskatchewan.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology and Immunology, College of Medicine, University of Saskatchewan, Saskatoon, Saskatchewan S7N 5E5, Canada. Phone: (306) 966-4307. Fax: (306) 966-4311. E-mail: hayess{at}duke.usask.ca.

REFERENCES

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References

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Bachmann, B. J. 1987. Derivations and genotypes of some mutant derivatives of Escherichia coli K-12, p.1190–1219. In F. C. Neidhardt, J. L. Ingraham, K. B. Low, B. Magasanik, M. Schaechter, and H. E. Umbarger (ed.), Escherichia coli and Salmonella typhimurium: cellular and molecular biology, vol. 2. American Society for Microbiology, Washington, D.C.

Benzer, S. 1957. The elementary units of heredity, p.70–93. In W. D. McElroy and B. Glass (ed.), The chemical basis of heredity. The Johns Hopkins Press, Baltimore, Md.

Borek, E., J. Rockenbach, and A. Ryan. 1956. Studies on a mutant of Escherichia coli with unbalanced ribonucleic acid synthesis. J. Bacteriol. 71:318–323.[Free Full Text]

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Hayes, S., H. Bull, and J. Tuloch. 1997. The rex phenotype of altruistic cell death following infection of a ${lambda}$ lysogen by T4rII mutants is suppressed by plasmids expressing OOP RNA. Gene 189:35–42.[CrossRef][Medline]

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