Abstract
Sphingopyxis (formerly Sphingomonas) alaskensis, a numerically abundant species isolated from Alaskan waters
and the North Sea represents one of the only pure cultures of a typical oligotrophic ultramicrobacterium isolated
from the marine environment. In this study, physiological and molecular characterization of an extinction dilution
isolate from the North Pacific indicate that it is a strain of Sphingopyxis alaskenis, extending the known
geographical distribution of this strain and affirming its importance as a model marine oligotroph. Given the
importance of open ocean systems in climatic processes, it is clearly important to understand the physiology and
underlying molecular biology of abundant species, such as S. alaskensis, and to define their role in biogeochemical
processes.
S. alaskensis is thought to proliferate by growing slowly on limited concentrations of substrates thereby avoiding
outright starvation. In order to mimic environmental conditions chemostat culture was used to study the physiology
of this model oligotroph in response to slow growth and nutrient limitation. It was found that the extent of nutrient
limitation and starvation has fundamentally different consequences for the physiology of oligotrophic
ultramicrobacteria compared with well-studied copiotrophic bacteria (Vibrio angustum S14 and Escherichia coli).
For example, growth rate played a critical role in hydrogen peroxide resistance of S. alaskensis with slowly
growing cells being 10, 000 times more resistant than fast growing cells. In contrast, the responses of V. angustum
and E. coli to nutrient availability differed in that starved cells were more resistant than growing cells, regardless of
growth rate.
In order to examine molecular basis of the response to general nutrient limitation, starvation and oxidative stress in
S. alaskensis we used proteomics to define differences in protein profiles of chemostat-grown cultures at various
levels of nutrient limitation. High-resolution two-dimensional electrophoresis (2DE) methods were developed and
2DE protein maps were used to define proteins regulated by the level of nutrient limitation. A number of these
proteins were identified with the aid of mass spectrometry and cross-species database matching. The identified
proteins are involved in fundamental cellular processes including protein synthesis, protein folding, energy
generation and electron transport, providing an important step in discovering the molecular basis of oligotrophy in
this model organism.