<?xml version="1.0" encoding="utf-8" standalone="yes"?><rss version="2.0" xmlns:atom="http://www.w3.org/2005/Atom"><channel><title>Cindy Lee | Amano Lab | Hokkaido University</title><link>https://amanoresearch.com/authors/cindy-lee/</link><atom:link href="https://amanoresearch.com/authors/cindy-lee/index.xml" rel="self" type="application/rss+xml"/><description>Cindy Lee</description><generator>HugoBlox Kit (https://hugoblox.com)</generator><language>en-us</language><lastBuildDate>Tue, 16 Dec 2025 00:00:00 +0000</lastBuildDate><item><title>Microbial diagenesis of dissolved organic matter from the ocean’s surface to abyssal depths: a case study in the Humboldt upwelling system</title><link>https://amanoresearch.com/publication/engel-202512-diagenesis/</link><pubDate>Tue, 16 Dec 2025 00:00:00 +0000</pubDate><guid>https://amanoresearch.com/publication/engel-202512-diagenesis/</guid><description>&lt;p&gt;Marine dissolved organic matter (DOM) represents one of Earth’s largest dynamic carbon
pools—comparable in scale to atmospheric CO₂. Primarily derived from phytoplankton production in the
sunlit surface ocean, DOM serves as a key substrate for heterotrophic microbes that actively
transform and recycle it. The portion remaining after microbial diagenesis contributes to the
long-lived deep-sea reservoir of refractory dissolved organic carbon (RDOC) with turnover times up
to millennia. DOC lability is an important trait determining microbial utilization as well as carbon
storage time in the ocean and can be inferred from its chemical composition, particularly changes in
individual amino acids (AAs). In this study, we examined dissolved (DOC) and particulate organic
carbon (POC) distribution, composition and concentration of dissolved hydrolyzable AAs (DHAA),
microbial community structure, and activity along depth profiles from the surface to the
abyssopelagic zone (down to 5,000 m) in the Humboldt upwelling system off Chile—one of the ocean’s
most productive regions. Our results show a pronounced decrease in DOC concentration and lability,
and in viral and prokaryotic abundance with depth. Below the mesopelagic zone, DOC displayed
characteristics of RDOC: &amp;lt;42 μmol C L −1 , [DHAA-C]:[DOC] ~ 0.6%, and a glycine fraction of ~75 mol%
DHAA. Bacterial biomass production and extracellular enzyme activities (EEA), however, were
detectable below the mesopelagic zone and even at abyssal depths, albeit at very low rates.
Cell-specific EEA and the proportion of high nucleic acid (HNA) cells increased with depth
suggesting adaptation to an extremely low-substrate environment. We discuss microbial carbon
turnover under varying assumptions of bacterial growth efficiency and conclude that microbial life
in the bathy- and abyssopelagic zones of the Humboldt Current is likely sustained by the flux of
sinking particulate organic matter.&lt;/p&gt;</description></item></channel></rss>