Facilitation of Robust Growth of
            <i>Prochlorococcus</i>
            Colonies and Dilute Liquid Cultures by “Helper” Heterotrophic Bacteria

Morris, Jeffrey; Kirkegaard, R.D.; Szul, Martin J.; Johnson, Zackary I.; Zinser, Erik R.

doi:10.1128/aem.02479-07

Cited by 264 publications

(334 citation statements)

References 29 publications

Supporting

Mentioning

308

Contrasting

Unclassified

Order By: Relevance

“…Specifically, cysteine and methionine residues are especially sensitive to ROS (Arts et al, 2015). Although heterotrophic bacteria, including some Alteromonas strains, may scavenge ROS and thus reduce potential oxidative stress affecting Prochlorococcus (Morris et al, 2008;Morris et al, 2011), other marine heterotrophic bacteria, again including Alteromonads, in fact produce extracellular superoxide (Diaz et al, 2013). Additionally, the killing mechanism of many antibiotics ultimately involves the generation of ROS (reviewed by Dwyer et al, 2009).…”

Section: Resultsmentioning

confidence: 99%

“…Although significant advances have been made in understanding 'top down' control of Prochlorococcus populations by phage and grazers (for example, Worden and Binder, 2003;Avrani et al, 2011;Pasulka et al, 2015), as well as 'bottom up' control by nutrients, temperature and light (for example, Bouman et al, 2006;Johnson et al, 2006;Saito et al, 2014), studying how co-occurring heterotrophic microbes affect Prochlorococcus is still in its infancy. Several recent studies have shown that co-occurring heterotrophic bacteria can both enhance and inhibit the growth of Prochlorococcus in laboratory co-cultures (Morris et al, 2008;Sher et al, 2011). Furthermore, such interactions may have significant effects on the viability of Prochlorococcus in the oceans, for example through scavenging by heterotrophic bacteria of reactive oxygen species (ROS) produced by Prochlorococcus (Morris et al, 2011(Morris et al, , 2012.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Transcriptional response of Prochlorococcus to co-culture with a marine Alteromonas: differences between strains and the involvement of putative infochemicals

Aharonovich

Sher

2016

The ISME Journal

View full text Add to dashboard Cite

Interactions between marine microorganisms may determine the dynamics of microbial communities. Here, we show that two strains of the globally abundant marine cyanobacterium Prochlorococcus, MED4 and MIT9313, which belong to two different ecotypes, differ markedly in their response to coculture with a marine heterotrophic bacterium, Alteromonas macleodii strain HOT1A3. HOT1A3 enhanced the growth of MIT9313 at low cell densities, yet inhibited it at a higher concentration, whereas it had no effect on MED4 growth. The early transcriptomic responses of Prochlorococcus cells after 20 h in co-culture showed no evidence of nutrient starvation, whereas the expression of genes involved in photosynthesis, protein synthesis and stress responses typically decreased in MED4 and increased in MIT313. Differential expression of genes involved in outer membrane modification, efflux transporters and, in MIT9313, lanthipeptides (prochlorosins) suggests that Prochlorococcus mount a specific response to the presence of the heterotroph in the cultures. Intriguingly, many of the differentially-expressed genes encoded short proteins, including two new families of co-culture responsive genes: CCRG-1, which is found across the Prochlorococcus lineage and CCRG-2, which contains a sequence motif involved in the export of prochlorosins and other bacteriocin-like peptides, and are indeed released from the cells into the media.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Transcriptional response of Prochlorococcus to co-culture with a marine Alteromonas: differences between strains and the involvement of putative infochemicals

Aharonovich

Sher

2016

The ISME Journal

View full text Add to dashboard Cite

show abstract

“…N. yellowstonii and N. gargensis, the two cultivated thermophilic strains of AOA, also could not be established in pure culture (Hatzenpichler et al, 2008;de la Torre et al, 2008). This may be because there is a cooperative relationship between the bacteria and the archaea in these enrichment cultures, as has been reported in cultures of the marine chlorophyte Prochlorococcus (Morris et al, 2008), and low cell density dilutions that do not contain the associated heterotrophic bacteria are unable to grow. Interactions between the heterotrophic bacteria and autotrophic archaea in the enrichment, and in the ocean, will be an exciting area of future research.…”

Section: Phylogenymentioning

confidence: 94%

Enrichment and characterization of ammonia-oxidizing archaea from the open ocean: phylogeny, physiology and stable isotope fractionation

2011

View full text Add to dashboard Cite

Archaeal genes for ammonia oxidation are widespread in the marine environment, but direct physiological evidence for ammonia oxidation by marine archaea is limited. We report the enrichment and characterization of three strains of pelagic ammonia-oxidizing archaea (AOA) from the North Pacific Ocean that have been maintained in laboratory culture for over 3 years. Phylogenetic analyses indicate the three strains belong to a previously identified clade of water column-associated AOA and possess 16S ribosomal RNA genes and ammonia monooxygenase subunit a (amoA) genes highly similar (98-99% identity) to those recovered in DNA and complementary DNA clone libraries from the open ocean. The strains grow in natural seawaterbased liquid medium while stoichiometrically converting ammonia (NH 3 ) to nitrite (NO 2 À ). Ammonia oxidation by the enrichments is only partially inhibited by allylthiourea at concentrations known to completely inhibit cultivated ammonia-oxidizing bacteria. The three strains were used to determine the nitrogen stable isotope effect ( 15 e NH3 ) during archaeal ammonia oxidation, an important parameter for interpreting stable isotope ratios in the environment. Archaeal 15 e NH3 ranged from 13% to 41%, within the range of that previously reported for ammonia-oxidizing bacteria. Despite low amino acid identity between the archaeal and bacterial Amo proteins, their functional diversity as captured by 15 e NH3 is similar.

show abstract

“…Bulk chlorophyll fluorescence and flow cytometry samples were collected daily to monitor cell abundance; Prochlorococcus were counted based on chlorophyll fluorescence, and heterotrophs were enumerated following SYBR staining. The purity of axenic NATL2A cultures was verified before and after the experiment by testing for growth in three purity broths (ProAC, ProMM and MPTB (Saito et al, 2002;Morris et al, 2008;Berube et al, 2015)) and by flow cytometry. Transcriptome samples were collected by removing 10 ml of culture and placing it immediately into 30 ml of cold RNALater, then incubating these samples for 1-3 days at 4°C.…”

Section: Methodsmentioning

confidence: 99%

“…Growth of Prochlorococcus-the numerically dominant phytoplankter in the world's oceans (Flombaum et al, 2013)-in culture is improved by the presence of certain heterotrophs in terms of longevity, stationary phase cell density and ability to grow from low cell density (Sher et al, 2011). This phenomenon is attributable at least in part to the role of heterotrophs in reducing the levels of toxic reactive oxygen species such as hydrogen peroxide (Morris et al, 2008(Morris et al, , 2011. This is thought to compensate for the absence of catalase in the Prochlorococcus genome, indicating that interspecies interactions have clearly influenced the evolutionary selective pressures and processes acting upon this group of organisms (Morris et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Torn apart and reunited: impact of a heterotroph on the transcriptome of Prochlorococcus

2016

View full text Add to dashboard Cite

Microbial interactions, whether direct or indirect, profoundly affect the physiology of individual cells and ultimately have the potential to shape the biogeochemistry of the Earth. For example, the growth of Prochlorococcus, the numerically dominant cyanobacterium in the oceans, can be improved by the activity of co-occurring heterotrophs. This effect has been largely attributed to the role of heterotrophs in detoxifying reactive oxygen species that Prochlorococcus, which lacks catalase, cannot. Here, we explore this phenomenon further by examining how the entire transcriptome of Prochlorococcus NATL2A changes in the presence of a naturally co-occurring heterotroph, Alteromonas macleodii MIT1002, with which it was co-cultured for years, separated and then reunited. Significant changes in the Prochlorococcus transcriptome were evident within 6 h of initiating co-culture, with groups of transcripts changing in different temporal waves. Many transcriptional changes persisted throughout the 48 h experiment, suggesting that the presence of the heterotroph affected a stable shift in Prochlorococcus physiology. These initial transcriptome changes largely corresponded to reduced stress conditions for Prochlorococcus, as inferred from the depletion of transcripts encoding DNA repair enzymes and many members of the 'high light inducible' family of stress-response proteins. Later, notable changes were seen in transcripts encoding components of the photosynthetic apparatus (particularly, an increase in PSI subunits and chlorophyll synthesis enzymes), ribosomal proteins and biosynthetic enzymes, suggesting that the introduction of the heterotroph may have induced increased production of reduced carbon compounds for export. Changes in secretion-related proteins and transporters also highlight the potential for metabolic exchange between the two strains.

show abstract

Facilitation of Robust Growth of Prochlorococcus Colonies and Dilute Liquid Cultures by “Helper” Heterotrophic Bacteria

Cited by 264 publications

References 29 publications

Transcriptional response of Prochlorococcus to co-culture with a marine Alteromonas: differences between strains and the involvement of putative infochemicals

Transcriptional response of Prochlorococcus to co-culture with a marine Alteromonas: differences between strains and the involvement of putative infochemicals

Enrichment and characterization of ammonia-oxidizing archaea from the open ocean: phylogeny, physiology and stable isotope fractionation

Torn apart and reunited: impact of a heterotroph on the transcriptome of Prochlorococcus

Contact Info

Product

Resources

About