Slower swimming promotes chemotactic encounters between bacteria and small phytoplankton

TL;DR

This study models how bacterial swimming speed and phytoplankton size influence chemotactic search efficiency, revealing that slower swimming bacteria benefit more from chemotaxis towards larger phytoplankton, especially in nutrient-poor waters.

Contribution

It provides a quantitative analysis of how phytoplankton size and bacterial swimming speed affect chemotactic encounter rates, highlighting the conditions under which chemotaxis is most advantageous.

Findings

Chemotaxis significantly reduces search times for small phytoplankton in productive waters.

Larger phytoplankton chemotaxis benefits are more robust to environmental variations.

In oligotrophic waters, chemotaxis can drastically decrease search times for picophytoplankton, especially for bacteria with low swimming speeds.

Abstract

Chemotaxis enables marine bacteria to increase encounters with phytoplankton cells by reducing their search times, provided that bacteria detect noisy chemical gradients around phytoplankton. Gradient detection depends on bacterial phenotypes and phytoplankton size: large phytoplankton produce spatially extended but shallow gradients, whereas small phytoplankton produce steeper but spatially more confined gradients. To date, it has remained unclear how phytoplankton size and bacterial swimming speed affect bacteria's gradient detection ability and search times for phytoplankton. Here, we compute an upper bound on the increase in bacterial encounter rate with phytoplankton due to chemotaxis over random motility alone. We find that chemotaxis can substantially decrease search times for small phytoplankton, but this advantage is highly sensitive to variations in bacterial phenotypes or phytoplankton leakage rates. By contrast, chemotaxis towards large phytoplankton cells reduces the search time more modestly, but this benefit is more robust to variations in search or environmental parameters. Applying our findings to marine phytoplankton communities, we find that, in productive waters, chemotaxis towards phytoplankton smaller than 2 micrometers provides little to no benefit, but can decrease average search times for large phytoplankton (about 20 micrometers) from two weeks to two days, an advantage that is robust to variations and favors bacteria with higher swimming speeds. By contrast, in oligotrophic waters, chemotaxis can reduce search times for picophytoplankton (about 1 micrometer) up to ten-fold, from a week to half a day, but only for bacteria with low swimming speeds and long sensory timescales. This asymmetry may promote the coexistence of diverse search phenotypes in marine bacterial populations.