[HTML][HTML] Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
Background Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
[PDF][PDF] Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson, FJ Lapointe, RT Papke… - 2018 - researchgate.net
Background: Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
[HTML][HTML] Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson… - Genome …, 2018 - genomebiology.biomedcentral.com
Haloarchaea, a major group of archaea, are able to metabolize sugars and to live in
oxygenated salty environments. Their physiology and lifestyle strongly contrast with that of …
oxygenated salty environments. Their physiology and lifestyle strongly contrast with that of …
Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson, FJ Lapointe, RT Papke… - Genome …, 2018 - par.nsf.gov
Background: Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson, FJ Lapointe, RT Papke… - Genome …, 2018 - inria.hal.science
Background Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson, FJ Lapointe, RT Papke… - Genome …, 2018 - hal-sfo.ccsd.cnrs.fr
Background Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson, FJ Lapointe, RT Papke… - Genome …, 2018 - ird.hal.science
Background Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson, FJ Lapointe… - Genome …, 2018 - pubmed.ncbi.nlm.nih.gov
Background Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson, FJ Lapointe, RT Papke… - Genome Biology, 2018 - hal.utc.fr
Background Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
Hundreds of novel composite genes and chimeric genes with bacterial origins contributed to haloarchaeal evolution
R Méheust, AK Watson, FJ Lapointe, RT Papke… - Genome …, 2018 - mnhn.hal.science
Background Haloarchaea, a major group of archaea, are able to metabolize sugars and to
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …
live in oxygenated salty environments. Their physiology and lifestyle strongly contrast with …