<?xml version="1.0" encoding="utf-8" standalone="yes"?><rss version="2.0" xmlns:atom="http://www.w3.org/2005/Atom"><channel><title>Mónica v. Orellana | Amano Lab | Hokkaido University</title><link>https://amanoresearch.com/authors/monica-v.-orellana/</link><atom:link href="https://amanoresearch.com/authors/monica-v.-orellana/index.xml" rel="self" type="application/rss+xml"/><description>Mónica v. Orellana</description><generator>HugoBlox Kit (https://hugoblox.com)</generator><language>en-us</language><lastBuildDate>Tue, 30 Jul 2024 00:00:00 +0000</lastBuildDate><item><title>Metaproteomic analysis decodes trophic interactions of microorganisms in the dark ocean</title><link>https://amanoresearch.com/publication/zhao-202407-metaproteomic/</link><pubDate>Tue, 30 Jul 2024 00:00:00 +0000</pubDate><guid>https://amanoresearch.com/publication/zhao-202407-metaproteomic/</guid><description>&lt;p&gt;Proteins in the open ocean represent a significant source of organic matter, and their profiles
reflect the metabolic activities of marine microorganisms. Here, by analyzing metaproteomic samples
collected from the Pacific, Atlantic and Southern Ocean, we reveal size-fractionated patterns of the
structure and function of the marine microbiota protein pool in the water column, particularly in
the dark ocean (&amp;gt;200 m). Zooplankton proteins contributed three times more than algal proteins to
the deep-sea community metaproteome. Gammaproteobacteria exhibited high metabolic activity in the
deep-sea, contributing up to 30% of bacterial proteins. Close virus-host interactions of this taxon
might explain the dominance of gammaproteobacterial proteins in the dissolved fraction. A high
urease expression in nitrifiers suggested links between their dark carbon fixation and zooplankton
urea production. In summary, our results uncover the taxonomic contribution of the microbiota to the
oceanic protein pool, revealing protein fluxes from particles to the dissolved organic matter pool.&lt;/p&gt;</description></item><item><title>Substrate uptake patterns shape niche separation in marine prokaryotic microbiome</title><link>https://amanoresearch.com/publication/zhao-202405-niche/</link><pubDate>Fri, 17 May 2024 00:00:00 +0000</pubDate><guid>https://amanoresearch.com/publication/zhao-202405-niche/</guid><description>&lt;p&gt;Marine heterotrophic prokaryotes primarily take up ambient substrates using transporters. The
patterns of transporters targeting particular substrates shape the ecological role of heterotrophic
prokaryotes in marine organic matter cycles. Here, we report a size-fractionated pattern in the
expression of prokaryotic transporters throughout the oceanic water column due to taxonomic
variations, revealed by a multi-“omics” approach targeting ATP-binding cassette (ABC) transporters
and TonB-dependent transporters (TBDTs). Substrate specificity analyses showed that marine SAR11,
Rhodobacterales, and Oceanospirillales use ABC transporters to take up organic nitrogenous compounds
in the free-living fraction, while Alteromonadales, Bacteroidetes, and Sphingomonadales use TBDTs
for carbon-rich organic matter and metal chelates on particles. The expression of transporter
proteins also supports distinct lifestyles of deep-sea prokaryotes. Our results suggest that
transporter divergency in organic matter assimilation reflects a pronounced niche separation in the
prokaryote-mediated organic matter cycles.&lt;/p&gt;</description></item></channel></rss>