Microbiome (@microbiomej) 's Twitter Profile
Microbiome

@microbiomej

A family of journals from @BioMedCentral that seek to unite investigators conducting microbiome research in environmental, agricultural, and biomedical arenas.

ID: 1097934120

linkhttp://microbiomejournal.biomedcentral.com calendar_today17-01-2013 11:49:37

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A Splash in the #Ocean - inspired by interest from our readers and authors, we highlight some of the marine microbiome papers published recently across the Microbiome Family tinyurl.com/54rs4a93

A Splash in the #Ocean - inspired by interest from our readers and authors, we highlight some of the marine microbiome papers published recently across the Microbiome Family tinyurl.com/54rs4a93
Microbiome (@microbiomej) 's Twitter Profile Photo

In #EnvironmentalMicrobiome 🔍Characterising plastisphere communities associated with a wastewater treatment plant in New Zealand 📢No substrate-specific microbial communities were found among glass & polymer types regardless of artificial aging 👉doi.org/pvb5

In #EnvironmentalMicrobiome

🔍Characterising plastisphere communities associated with a wastewater treatment plant in New Zealand

📢No substrate-specific microbial communities were found among glass & polymer types regardless of artificial aging

👉doi.org/pvb5
Microbiome (@microbiomej) 's Twitter Profile Photo

🌊A Splash in the Ocean: Inspired by interest from our readers and authors, we highlight some of the marine microbiome papers published recently across the Microbiome Family🦠 #OceanPlastics #AntimicrobialResistance #PlanktonicLife Find out more➡️ biomedcentral.com/collections/wm…

🌊A Splash in the Ocean:

Inspired by interest from our readers and authors, we highlight some of the marine microbiome papers published recently across the Microbiome Family🦠

#OceanPlastics #AntimicrobialResistance #PlanktonicLife

Find out more➡️
biomedcentral.com/collections/wm…
Microbiome (@microbiomej) 's Twitter Profile Photo

In #Microbiome 🔍Investigating the impact of glufosinate (GLU) on chili plant growth & rhizosphere microbial communities 🚨Jasmonic acid acts as a chemoattractant, promoting bacterial growth & metabolic activity to degrade GLU residues in soil 👉doi.org/pvb9

In #Microbiome

🔍Investigating the impact of glufosinate (GLU) on chili plant growth & rhizosphere microbial communities

🚨Jasmonic acid acts as a chemoattractant, promoting bacterial growth & metabolic activity to degrade GLU residues in soil

👉doi.org/pvb9
Microbiome (@microbiomej) 's Twitter Profile Photo

In #AnimalMicrobiome 🔍A randomized controlled dietary feeding trial assessing the effect of high levels of dietary zinc on the microbiomes of a gestating sow & her neonatal piglets 📢Sows had significantly higher alpha diversity at farrowing 👉doi.org/pvb4

In #AnimalMicrobiome

🔍A randomized controlled dietary feeding trial assessing the effect of high levels of dietary zinc on the microbiomes of a gestating sow & her neonatal piglets

📢Sows had significantly higher alpha diversity at farrowing

👉doi.org/pvb4
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In #Microbiome 🔍Exploring pairwise bacterial interactions within the human gut microbiome and their contributions to host health🦠 📢Key factors influencing interaction patterns include metabolic capacity and motility 👉doi.org/pvwm

In #Microbiome

🔍Exploring pairwise bacterial interactions within the human gut microbiome and their contributions to host health🦠

📢Key factors influencing interaction patterns include metabolic capacity and motility

👉doi.org/pvwm
Microbiome (@microbiomej) 's Twitter Profile Photo

In #EnvironmentalMicrobiome 🔍Identifying the mechanism of Bacillus pacificus SG15’s inhibitory effect on the asexual reproduction of Jellyfish Aurelia coerulea polyps🪼 🚨SG15 influenced both endodermal and ectodermal polyp cells 👉doi.org/pvwk

In #EnvironmentalMicrobiome

🔍Identifying the mechanism of Bacillus pacificus SG15’s inhibitory effect on the asexual reproduction of Jellyfish Aurelia coerulea polyps🪼

🚨SG15 influenced both endodermal and ectodermal polyp cells

👉doi.org/pvwk
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In #Microbiome 🔍Investigating how heat stress alters the rhizomicrobiomes of Panax notoginseng 🚨Beneficial microbes Burkholderia sp. and Saitozyma podzolica were confirmed to be responsible for resisting multiple stresses 👉doi.org/g9sm9v

In #Microbiome

🔍Investigating how heat stress alters the rhizomicrobiomes of Panax notoginseng

🚨Beneficial microbes Burkholderia sp. and Saitozyma podzolica were confirmed to be responsible for resisting multiple stresses

👉doi.org/g9sm9v
Microbiome (@microbiomej) 's Twitter Profile Photo

In #AnimalMicrobiome 🔍Examining how exposure to environmental levels of antibiotics affects the skin microbiomes of Eurasian carp (Cyprinus carpio) 📢Low-level exposure to chemical mixtures can alter fish skin microbiome compositions 👉doi.org/pvwh

In #AnimalMicrobiome

🔍Examining how exposure to environmental levels of antibiotics affects the skin microbiomes of Eurasian carp (Cyprinus carpio)

📢Low-level exposure to chemical mixtures can alter fish skin microbiome compositions

👉doi.org/pvwh
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🦠What is microbiome research and what makes a good microbiome study? In their Editorial, the Senior Editors of Microbiome highlight the challenges of microbiome research and what they are looking for in submissions. 🚨Find out more: doi.org/g9fjn3

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In #Microbiome 🌋Submarine volcano Fani Maoré hosts full sulfur-cycling microbial community 🚨Detecting representations of 8 bacterial phyla, but mostly Pseudomonadota, Bacteroidota and Campylobacterota 👉doi.org/pwj2

In #Microbiome

🌋Submarine volcano Fani Maoré hosts full sulfur-cycling microbial community

🚨Detecting representations of 8 bacterial phyla, but mostly Pseudomonadota, Bacteroidota and Campylobacterota

👉doi.org/pwj2
Microbiome (@microbiomej) 's Twitter Profile Photo

In #EnvironmentalMicrobiome 🔍Exploring the chemosynthetic biofilm microbiome of deep-sea hydrothermal vents across space and time 🦠Community composition is impacted by biofilm age, temperature, sulfide concentration ranges & locality 👉doi.org/pwj4

In #EnvironmentalMicrobiome

🔍Exploring the chemosynthetic biofilm microbiome of deep-sea hydrothermal vents across space and time

🦠Community composition is impacted by biofilm age, temperature, sulfide concentration ranges & locality

👉doi.org/pwj4
Microbiome (@microbiomej) 's Twitter Profile Photo

In #Microbiome 🔍Exploring how probiotic shows promise to mitigate acute ammonia toxicity (AI) in aquaculture 💡Supplementation of C. somerae mitigates AI by reversing depletion of intestinal argininosuccinic acid & promoting ureagenesis 👉doi.org/pwj3

In #Microbiome 

🔍Exploring how probiotic shows promise to mitigate acute ammonia toxicity (AI) in aquaculture

💡Supplementation of C. somerae mitigates AI by reversing depletion of intestinal argininosuccinic acid & promoting ureagenesis

👉doi.org/pwj3
Microbiome (@microbiomej) 's Twitter Profile Photo

In #AnimalMicrobiome 🔍Investigating the effects of three bacterial strains on pig health & microbial composition🐖 🚨Probiotics impacted growth performance, reduced fecal odor & enhanced pig carcass quality 👉doi.org/pwj4

In #AnimalMicrobiome

🔍Investigating the effects of three bacterial strains on pig health & microbial composition🐖

🚨Probiotics impacted growth performance, reduced fecal odor & enhanced pig carcass quality

👉doi.org/pwj4
Microbiome (@microbiomej) 's Twitter Profile Photo

In #Microbiome 🔍Investigating the links between the gut microbiome & typhoid fever 🚨Identifying 28 specific metabolic gene clusters negatively associated with typhoid fever, including 7 involved in SCFA metabolism 👉doi.org/pxb4

In #Microbiome

🔍Investigating the links between the gut microbiome & typhoid fever

🚨Identifying 28 specific metabolic gene clusters negatively associated with typhoid fever, including 7 involved in SCFA metabolism

👉doi.org/pxb4
Microbiome (@microbiomej) 's Twitter Profile Photo

In #EnvironmentalMicrobiome 🔍Exploring the daily dynamics of airborne bacterial communities in the sub-Antarctic 🦠Environmental factors, including wind direction, temperature & rainfall shaped community structure 👉doi.org/pxbz

In #EnvironmentalMicrobiome

🔍Exploring the daily dynamics of airborne bacterial communities in the sub-Antarctic

🦠Environmental factors, including wind direction, temperature & rainfall shaped community structure

👉doi.org/pxbz
Microbiome (@microbiomej) 's Twitter Profile Photo

In #Microbiome 🚀Investigating unique bacteria inhabiting NASA cleanrooms 🚨Resulting in 215 cultivable extremotolerant bacterial strains, including 53 new strains spanning to 26 completely novel species Read more👉doi.org/g9h7sx youtube.com/watch?v=QzKfjx…

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In #AnimalMicrobiome 🔍Investigating the impacts of antimicrobial treatment on the gut microbiome & resistance of rehabilitating seals🦭 🚨Untreated seals cohabiting with treated seals exhibited increased resistance gene loads 👉doi.org/pxb2

In #AnimalMicrobiome

🔍Investigating the impacts of antimicrobial treatment on the gut microbiome & resistance of rehabilitating seals🦭

🚨Untreated seals cohabiting with treated seals exhibited increased resistance gene loads

👉doi.org/pxb2
Microbiome (@microbiomej) 's Twitter Profile Photo

In #Microbiome 🚨Introducing an "inside-out" framework to explore the functional & ecological parallels between plant rhizosphere & gut microbiomes 🦠Emphasising the potential for cross-disciplinary innovation 👉doi.org/pzdz

In #Microbiome

🚨Introducing an "inside-out" framework to explore the functional & ecological parallels between plant rhizosphere & gut microbiomes

🦠Emphasising the potential for cross-disciplinary innovation

👉doi.org/pzdz