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1. Resuscitation-promoting factor (Rpf) terminates dormancy among diverse soil bacteria

   https://doi.org/10.1128/msystems.01517-24  

   Lennon, Jay T; Lehmkuhl, Brent K; Chen, Lingling; Illingworth, Melissa; Kuo, Venus; Muscarella, Mario E (May 2025, mSystems)

   Albright, Michaeline_B N (Ed.)

   ABSTRACT Microorganisms often inhabit environments that are suboptimal for growth and reproduction. To survive when challenged by such conditions, individuals engage in dormancy, where they enter a metabolically inactive state. For this persistence strategy to confer an evolutionary advantage, microorganisms must be able to resuscitate and reproduce when conditions improve. Among bacteria in the phylum Actinomycetota, dormancy can be terminated by resuscitation-promoting factor (Rpf), an exoenzyme that hydrolyzes glycosidic bonds in the peptidoglycan of cell walls. We characterized Rpf fromMicrococcusKBS0714, a bacterium isolated from agricultural soil. The protein exhibited high substrate affinityin vitro, even though resuscitation was maximized in live-cell assays at micromolar concentrations. Site-directed mutations at conserved catalytic sites significantly reduced or eliminated resuscitation, as did the deletion of repeating motifs in a lectin-encoding linker region. We then tested the effects of recombinant Rpf fromMicrococcusKBS0714 on a diverse set of dormant soil bacteria. Patterns of resuscitation mapped onto strain phylogeny, which reflected core features of the cell envelope. Additionally, the direction and magnitude of the Rpf effect were associated with functional traits, in particular, aspects of the moisture niche and biofilm production, which are critical for understanding dormancy and the persistence of microbial populations in soils. These findings expand our understanding of how Rpf may affect seed bank dynamics with implications for the diversity and functioning of microorganisms in terrestrial ecosystems. IMPORTANCEDormancy is a process whereby individuals enter a reversible state of reduced metabolic activity. In fluctuating environments, dormancy protects individuals from unfavorable conditions, enhancing fitness and buffering populations against extinction. However, waking up from dormancy is a critical yet risky decision. Some bacteria resuscitate stochastically, while others rely on environmental cues or signals from neighboring cells to transition back to active growth. Resuscitation-promoting factor (Rpf) is an exoenzyme that cleaves bonds in the peptidoglycan of bacterial cell walls, facilitating dormancy termination and enabling regrowth. Although this family of proteins has been well characterized in model organisms and clinically relevant strains, our study characterizes Rpf from a soil bacterium and examines its effects on resuscitation across a diverse collection of bacteria, linking it to functional traits that may influence dormancy dynamics in both natural and managed ecosystems. 

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2. Resuscitation of the microbial seed bank alters plant‐soil interactions

   https://doi.org/10.1111/mec.15932  

   Kuo, Venus; Lehmkuhl, Brent K.; Lennon, Jay T. (May 2021, Molecular Ecology)

   Abstract While microorganisms are recognized for driving belowground processes that influence the productivity and fitness of plant populations, the vast majority of bacteria and fungi in soil belong to a seed bank consisting of dormant individuals. However, plant performance may be affected by microbial dormancy through its effects on the activity, abundance, and diversity of soil microorganisms. To test how microbial seed banks influence plant‐soil interactions, we purified recombinant resuscitation promoting factor (Rpf), a bacterial protein that terminates dormancy. In a factorially designed experiment, we then applied the Rpf to soil containing field mustard (Brassicarapa), an agronomically important plant species. Plant biomass was ~33% lower in the Rpf treatment compared to plants grown with an unmanipulated microbial seed bank. In addition, Rpf reduced soil respiration, decreased bacterial abundance, and increased fungal abundance. These effects of Rpf on plant performance were accompanied by shifts in bacterial community composition, which may have diluted mutualists or resuscitated pathogens. Our findings suggest that changes in microbial seed banks may influence the magnitude and direction of plant‐soil feedbacks in ways that affect above‐ and belowground biodiversity and function. 

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3. Tersicoccus phoenicis (Actinobacteria), a spacecraft clean room isolate, exhibits dormancy

   https://doi.org/10.1128/spectrum.01692-25  

   Tirumalai, Madhan; Ali, Sahar; Fox, George E; Widger, William (August 2025, Microbiology Spectrum)

   Tischler, Dirk (Ed.)

   ABSTRACT Space missions or spacecraft equipment destined for sensitive environments, such as Mars, Europa, or Enceladus, are required to be designed to avoid forward contamination. Spacecraft are assembled in clean rooms (SACs) employing treatments to eliminate microbial contamination. However, some organisms can survive the cleaning procedures. Characterization of these populations, through both culture-based and sequencing methods, reveals that the majority consists of spore-forming bacteria. However, a smaller group of non-spore-forming organisms, primarily classified within the orderMicrococcalesof the phylumActinobacteria(Actinomycetota), exists in some SACs. Despite their repeated occurrence and isolation, actinobacterial strains associated with SACs have not been studied for their dormancy potential. Here, we show for the first time that a non-spore-forming SAC isolate,Tersicoccus phoenicis(Micrococcales), enters dormancy under nutrient starvation. Dormancy inMicrococcus luteusinvolves a universal stress protein and a resuscitation-promoting factor (Rpf). Genes for these proteins are widely found in actinobacteria, includingT. phoenicis. We show that dormantT. phoenicis(Micrococcales) can be revived through the addition of the Rpf to the media. Dormancy, as observed in the SAC actinobacterial isolateT. phoenicis, could well be a common trait adopted by other actinobacterial strains under the stressful conditions of spacecraft clean rooms or the ISS (International Space Station). This has implications for the persistence, identification, and recovery of such microbes from cleanroom facilities.IMPORTANCENASA’s long-range goal of a human mission to the Mars surface raises issues relating to planetary protection. The concerns of forward contamination require that spacecraft assembly clean rooms (SACs) be maintained to inhibit microbial survival. However, despite these efforts, distinct microbial communities persist. Here, we show that a SAC isolate,T. phoenicis, exhibits dormancy, a state in which the cells are viable but not cultivable. Dormancy may help non-spore-forming organisms survive in the clean room environments utilized for space missions. This has implications for improving cleaning procedures. 

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4. Myxococcus xanthus fruiting body morphology is important for spore recovery after exposure to environmental stress

   https://doi.org/10.1128/aem.01660-24  

   Lall, Dave; Glaser, Maike M; Higgs, Penelope I (October 2024, Applied and Environmental Microbiology)

   Glass, Jennifer B (Ed.)

   ABSTRACT Environmental microorganisms have evolved a variety of strategies to survive fluctuations in environmental conditions, including the production of biofilms and differentiation into spores.Myxococcus xanthusare ubiquitous soil bacteria that produce starvation-induced multicellular fruiting bodies filled with environmentally resistant spores (a specialized biofilm). Isolated spores have been shown to be more resistant than vegetative cells to heat, ultraviolet radiation, and desiccation. The evolutionary advantage of producing spores inside fruiting bodies is not clear. Here, we examine a hypothesis that the fruiting body provides additional protection from environmental insults. We developed a high-throughput method to compare the recovery (outgrowth) of distinct cell types (vegetative cells, free spores, and spores within intact fruiting bodies) after exposure to ultraviolet radiation or desiccation. Our data indicate that haystack-shaped fruiting bodies protect spores from extended UV radiation but do not provide additional protection from desiccation. Perturbation of fruiting body morphology strongly impedes recovery from both UV exposure and desiccation. These results hint that the distinctive fruiting bodies produced by different myxobacterial species may have evolved to optimize their persistence in distinct ecological niches.IMPORTANCEEnvironmental microorganisms play an important role in the production of greenhouse gases that contribute to changing climate conditions. It is imperative to understand how changing climate conditions feedback to influence environmental microbial communities. The myxobacteria are environmentally ubiquitous social bacteria that influence the local microbial community composition. Defining how these bacteria are affected by environmental insults is a necessary component of predicting climatic feedback effects. When starved, myxobacteria produce multicellular fruiting bodies filled with spores. As spores are resistant to a variety of environmental insults, the evolutionary advantage of building a fruiting body is not clear. Using the model myxobacterium,Myxococcus xanthus, we demonstrate that the tall, haystack-shaped fruiting body morphology enables significantly more resistance to UV exposure than the free spores. In contrast, fruiting bodies are slightly detrimental to recovery from extended desiccation, an effect that is strongly exaggerated if fruiting body morphology is perturbed. These results suggest that the variety of fruiting body morphologies observed in the myxobacteria may dictate their relative resistance to changing climate conditions. 

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5. Phage-encoded sigma factors alter bacterial dormancy

   https://doi.org/10.1101/2021.11.12.468384  

   Schwartz DA, Lekmkuhl BK (January 2021, bioRxiv)

   By entering a reversible state of reduced metabolic activity, dormant microorganisms are able to tolerate suboptimal conditions that would otherwise reduce their fitness. Dormancy may also benefit bacteria by serving as a refuge from parasitic infections. Here we focus on dormancy in the Firmicutes, where endospore development is transcriptionally regulated by the expression of sigma factors. A disruption of this process could influence the survivorship and reproduction of phages that infect spore-forming hosts with implications for coevolutionary dynamics. Here, we characterized the distribution and diversity of sigma factors in nearly 3,500 phage genomes. Homologs of sporulation-specific sigma factors were identified in phages that infect spore-forming hosts. Unlike sigma factors required for phage reproduction, the sporulation-like sigma factors were non-essential for lytic infection. However, when expressed in the spore-forming Bacillus subtilis, sigma factors from phages activated the bacterial sporulation gene network and reduced spore yield. Our findings suggest that the acquisition of host-like transcriptional regulators may allow phages to manipulate a complex and ancient trait in one of the most abundant cell types on Earth. 

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