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1. 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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2. The biocontrol potential of endophyte Bacillus velezensis to reduce post-harvest tomato infection caused by Rhizopus microsporus

   https://doi.org/10.1128/spectrum.01064-25  

   Kock, Alicia; Napo, Mmanoko; Viviers, Dionné; Akinmoladun, Oluwakemi V; Alayande, Kazeem A; Yusuf, Abdullahi; Uehling, Jessie; Pawlowska, Teresa E; Adeleke, Rasheed A (October 2025, Microbiology Spectrum)

   Hockett, Kevin Loren (Ed.)

   ABSTRACT Rhizopus microsporusis a necrotrophic post-harvest pathogen that causes significant economic losses in the agricultural sector. To explore alternatives to conventional management strategies for the mitigation of post-harvest infections, we investigated the potential of two previously identified endophyticBacillus velezensisstrains as biological control agents. Throughin vitroandin vivoexperiments, we examined the mechanisms of biocontrol displayed by twoB. velezensisstrains (KV10 and KV15) against threeR. microsporusstrains (W2-50, W2-51, and W2-58).In vitroassays assessed co-cultivability and the inhibitory effects ofB. velezensisagainstR. microsporus. The results demonstrated strain-specific antifungal activity with a reduction in fungal growth across treatments. Further analysis revealed that volatile organic compounds produced byB. velezensiscontributed to its antifungal properties. To evaluate the biocontrol efficacyin vivo, tomato fruits were inoculated withR. microsporusand subsequently treated withB. velezensis. The results support the strain-specific reduction in tomato spoilage, yielding various spoilage rates observed across treatments. Our findings highlight the potential ofB. velezensisas a promising biocontrol agent for the management ofR. microsporuspost-harvest infections in tomatoes. Further research is warranted to optimize the applicationof B. velezensisas a sustainable and environmentally friendly approach for controlling post-harvest diseases in tomatoes.IMPORTANCEOur study shows the significance of improving sustainable agriculture by offering an alternative to the use of chemical fungicides in post-harvest applications. Opportunistic fungal pathogens likeRhizopus microsporuscan have detrimental effects on post-harvest commodities like tomatoes. Post-harvest fungal infections are mainly controlled by chemical fungicides that pose health risks to humans and the environment. Utilizing biocontrol agents provides an environmentally safe alternative. Understanding the mechanisms of biocontrol employed by beneficial bacteria likeBacillus velezensison fungal pathogens gives insight into safer, more environmentally friendly alternatives to protect food crops. Our results suggest that targeted microbial solutions can mitigate post-harvest losses. 

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3. High microbial diversity, functional redundancy, and prophage enrichment support the success of the yellow pencil coral, Madracis mirabilis, in Curaçao’s coral reefs

   https://doi.org/10.1128/msystems.01208-25  

   Wallace, Bailey A; Varona, Natascha S; Stiffler, Alexandra K; Vermeij, Mark_J A; Silveira, Cynthia (October 2025, mSystems)

   Adriaenssens, Evelien M (Ed.)

   ABSTRACT Coral reefs have undergone extensive coral loss and shifts in community composition worldwide. Despite this, some coral species appear naturally more resistant, such asMadracis mirabilis(hereinMadracis).Madracishas emerged as the dominant hard coral in Curaçao, comprising 26% of coral cover in reefs that declined by 78% between 1973 and 2015. Although life history traits and competitive mechanisms contribute toMadracis’s success, these factors alone may not fully explain it, as other species with similar traits have not shown comparable success. Here, we investigated the potential role of microbial communities in the success ofMadracison Curaçao reefs by leveraging a low-bias bacterial and viral enrichment method for metagenomic sequencing of coral samples, resulting in 77 unique bacterial metagenome-assembled genomes and 2,820 viral genomic sequences. Our analyses showed thatMadracis-associated bacterial and viral communities are 12% and 20% richer than the communities of five sympatric coral species combined. TheMadracis-associated bacterial community was dominated byRuegeriaandSphingomonas, genera that have previously been associated with coral health, defense against pathogens, and bioremediation. These communities also displayed higher functional redundancy, which is often associated with ecological resilience. The viral community exhibited a 50% enrichment of proviruses relative to other corals. These proviruses had the genomic capacity to laterally transfer genes involved in antibiotic resistance, central metabolism, and oxidative stress responses, potentially enhancing the adaptive capacity of theMadracismicrobiome and contributing toMadracis’s success on Curaçao’s reefs. IMPORTANCEUnderstanding why some coral species persist and thrive while most are in fast decline is critical.Madracis mirabilisis increasingly dominant on degraded reefs in Curaçao, yet the role of microbial communities in its success remains underexplored. This study highlights the potential role ofMadracis-associated bacterial and viral communities in supporting coral resilience and competitive success. By identifying key microbial partners and viral genes that may enhance host stress tolerance and defense against pathogens, we broaden the understanding of how the coral holobiont contributes to species persistence under environmental stress. These insights are valuable for predicting key microbial community players in reef interactions and may inform microbiome-based strategies to support coral conservation and restoration. 

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4. Rival phytoplankton contribute to the cross protection of Prochlorococcus from oxidative stress

   https://doi.org/10.1128/aem.01128-24  

   Calfee, Benjamin C; Bowden, Emily C; Zinser, Erik R (May 2025, Applied and Environmental Microbiology)

   Bose, Arpita (Ed.)

   ABSTRACT The marine cyanobacteriumProchlorococcusnumerically dominates the phytoplankton communities in all lower latitude, open ocean environments. Having lost the catalase gene,Prochlorococcusis highly susceptible to exogenous hydrogen peroxide (H₂O₂) produced at the ocean’s surface. Protection by H₂O₂-scavenging heterotrophic “helper” bacteria has been demonstrated in laboratory cultures and implicated as an important mechanism ofProchlorococcussurvival in the ocean. Importantly, some other phytoplankton can also scavenge H₂O₂, suggesting these competing microbes may inadvertently protectProchlorococcus. In this study, we assessed the ability of co-occurring phytoplankton, the cyanobacteriumSynechococcusand picoeukaryotesMicromonasandOstreococcus, to protectProchlorococcusfrom H₂O₂exposure when cocultured at ecologically relevant abundances. All three genera could significantly degrade H₂O₂and diminishProchlorococcusmortality during H₂O₂exposures simulating photochemical production and rainfall events. We suggest that these phytoplankton groups contribute significantly to the H₂O₂microbial sink of the open ocean, thus complicating their relationships with and perhaps contributing to the evolutionary history ofProchlorococcus.IMPORTANCEThe marine cyanobacteriumProchlorococcusis the most abundant photosynthetic organism on the planet and is crucially involved in microbial community dynamics and biogeochemical cycling in most tropical and subtropical ocean waters. This success is due, in part, to the detoxification of the reactive oxygen species hydrogen peroxide (H₂O₂) performed by “helper” organisms. Earlier work identified heterotrophic bacteria as helpers, and here, we demonstrate that rival cyanobacteria and picoeukaryotic phytoplankton can also contribute to the survival ofProchlorococcusduring exposure to H₂O₂. Whereas heterotrophic bacteria helper organisms can benefit directly from promoting the survival of carbon-fixingProchlorococcuscells, phytoplankton helpers may suffer a twofold injury: production of H₂O₂degrading enzymes constrains already limited resources in oligotrophic environments, and the activity of these enzymes bolsters the abundance of their numerically dominant competitor. These findings build toward a better understanding of the intricate dynamics and interactions that shape microbial community structure in the open ocean. 

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5. Diverse Sulfuriferula spp. from sulfide mineral weathering environments oxidize ferrous iron and reduced inorganic sulfur compounds

   https://doi.org/10.1128/aem.00216-25  

   Hobart, Kathryn K; Walker, Gabriel M; Feinberg, Joshua M; Bailey, Jake V; Jones, Daniel S (July 2025, Applied and Environmental Microbiology)

   Spear, John R (Ed.)

   ABSTRACT Microorganisms are important catalysts for the oxidation of reduced inorganic sulfur compounds. One environmentally important source of reduced sulfur is metal sulfide minerals that occur in economic mineral deposits and mine waste. Previous research found thatSulfuriferulaspp. were abundant and active in long-term weathering experiments with simulated waste rock and tailings from the Duluth Complex, Northern Minnesota. We, therefore, isolated several strains ofSulfuriferulaspp. from these long-term experiments and characterized their metabolic and genomic properties to provide insight into microbe-mineral interactions and the microbial biogeochemistry in these and other moderately acidic to circumneutral environments. TheSulfuriferulastrains are all obligate chemolithoautotrophs capable of oxidizing inorganic sulfur compounds and ferrous iron. The strains grew over different pH ranges, but all grew between pH 4.5 and 7, matching the weathering conditions of the Duluth Complex rocks. All strains grew on the iron-sulfide mineral pyrrhotite (Fe_{1 −x}S, 0 <x< 0.125) as the sole energy source, as well as hydrogen sulfide and thiosulfate, which are products of sulfide mineral breakdown. Despite their metabolic similarities, each strain encodes a distinct pathway for the oxidation of reduced inorganic sulfur compounds as well as differences in nitrogen metabolism that reveal diverse genomic capabilities among the group. Our results show thatSulfuriferulaspp. are primary producers that likely play a role in sulfide mineral breakdown in moderately acidic to circumneutral mine waste, and the metabolic diversity within the genus may explain their success in sulfide mineral-rich and other sulfidic environments. IMPORTANCEMetal sulfide minerals, such as pyrite and pyrrhotite, are one of the main sources of reduced sulfur in the global sulfur cycle. The chemolithotrophic microorganisms that break down these minerals in natural and engineered settings are catalysts for biogeochemical sulfur cycling and have important applications in biotechnological processes such as biomining and bioremediation.Sulfuriferulais a recently described genus of sulfur-oxidizing bacteria that are abundant primary producers in diverse terrestrial environments, including waste rock and tailings from metal mining operations. In this study, we explored the genomic and metabolic properties of new isolates from this genus, and the implications for their ecophysiology and biotechnological potential in ore and waste from economic mineral deposits. 

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