<?xml version="1.0" encoding="utf-8" standalone="yes"?><rss version="2.0" xmlns:atom="http://www.w3.org/2005/Atom"><channel><title>Julia Steiger | Amano Lab | Hokkaido University</title><link>https://amanoresearch.com/authors/julia-steiger/</link><atom:link href="https://amanoresearch.com/authors/julia-steiger/index.xml" rel="self" type="application/rss+xml"/><description>Julia Steiger</description><generator>HugoBlox Kit (https://hugoblox.com)</generator><language>en-us</language><lastBuildDate>Thu, 01 Jan 2026 00:00:00 +0000</lastBuildDate><item><title>Single-cell heterotrophic activity in deep-ocean prokaryotic communities quantified by BONCAT and microautoradiography</title><link>https://amanoresearch.com/publication/amano-202601-boncat/</link><pubDate>Thu, 01 Jan 2026 00:00:00 +0000</pubDate><guid>https://amanoresearch.com/publication/amano-202601-boncat/</guid><description>&lt;p&gt;Prokaryotes play a central role in marine biogeochemical cycles, yet quantifying their activity
requires sensitive methods, particularly in the deep ocean where their biomass and metabolic rates
are low. One widely used method to determine single-cell activity of prokaryotes is bioorthogonal
non-canonical amino acid tagging (BONCAT), which offers a non-radioactive approach to measure
protein synthesis. However, direct comparisons between BONCAT and radioisotope-based techniques
across ocean depth gradients remain limited, particularly for low-activity prokaryotic communities.
To address this knowledge gap, we applied BONCAT to quantify single-cell heterotrophic activity in
prokaryotic communities from surface to bathypelagic depths (1000–4000 m) in the Southern Ocean near
the Kerguelen Islands. Employing picolyl azide-based copper-catalysed click chemistry, we compared
BONCAT (L-homopropargylglycine [HPG] incorporation) with microautoradiography (3H-methionine
uptake). BONCAT consistently detected active cells throughout the water column, with HPG-derived
total fluorescence intensity closely correlating with both microautoradiography (R2 = 0.91, P &amp;lt;
.001) and bulk methionine incorporation (R2 = 0.94, P &amp;lt; .001). This strong relationship between
BONCAT and microautoradiography was maintained into the upper bathypelagic depths, where detecting
single-cell activity becomes challenging. Our results demonstrate that BONCAT provides estimates of
single-cell heterotrophic activity consistent with microautoradiography in deep-ocean samples,
supporting its application as a non-radioactive alternative in low-activity environments.&lt;/p&gt;</description></item><item><title>Comparison of picolyl azide-based BONCAT and microautoradiography for assessing the heterotrophic prokaryotic activity in the deep ocean</title><link>https://amanoresearch.com/publication/amano-202510-boncat/</link><pubDate>Mon, 20 Oct 2025 00:00:00 +0000</pubDate><guid>https://amanoresearch.com/publication/amano-202510-boncat/</guid><description>&lt;p&gt;Prokaryotes play a central role in marine biogeochemical cycles, yet quantifying their activity
requires sensitive methods due to low biomass and metabolic rates, particularly in the deep ocean.
One recent method to determine single-cell activity of prokaryotes is bioorthogonal non-canonical
amino acid tagging (BONCAT), which offers a non-radioactive approach to measure protein synthesis.
However, direct comparisons between BONCAT and radioisotope-based techniques across ocean depth
gradients remain limited, particularly for low-activity prokaryotic communities. To address this
knowledge gap, we tested an optimised BONCAT protocol using picolyl azide fluorophores (BONCAT-pic)
to assess single-cell heterotrophic activity in prokaryotic communities from surface to bathypelagic
depths (1000–4000 m) in the Southern Ocean near the Kerguelen Islands. The method was first
optimised using aged coastal and open-ocean seawater, and then compared to microautoradiography with
3 H-methionine uptake. Statistical analysis shows that BONCAT-pic significantly improved detection
sensitivity compared to standard azide reagents. BONCAT-pic consistently detected active cells in
profiles over the open ocean water column, with cell proportions and fluorescence signals closely
correlating with both microautoradiography (R 2 = 0.9, p &amp;lt; 0.001) and bulk methionine incorporation
(R 2 = 0.6, p &amp;lt; 0.001). Our results demonstrate that BONCAT-pic is a reliable, fluorescence-based
method for quantifying heterotrophic activity at the single-cell level, extending its applicability
to prokaryotic communities in the deep ocean.&lt;/p&gt;</description></item></channel></rss>