Microbes, which yield several ecolo

Microbes, which yield several ecological services such as
degradation of pollutants, are investigated for bioremediation of
accidental and chronic pollutions. In the present issue, several
original data dealing the diversity and role of microbes, which
are involved in biodegradation of toxic dichloromethane, are
presented (Muller et al., 2011). Dichloromethane (DCM) is
a volatile toxic halogenated solvent mainly used industrially.
DCM-degrading bacteria have been models of choice to study
microbial dehalogenation metabolism at the physiological,biochemical and genetic levels for a long time, and have also
been used in bioremediation processes. DCM-degrading strains
isolated in recent years are presented as well as enzymes known
to catalyse dehalogenation of DCM. Insights on the modes of
adaptation of bacteria to DCM gained by comparative genomics
analysis of two DCM-degrading bacteria highlight the importance
of horizontal gene transfer in the dissemination of DCM
utilisation genes in the environment. On the other hand, Halter
et al. (2011) present significant findings on another pollutant,
arsenic. They analyzed the arsenic-adapted prokaryotic
community which lives in a moderately contaminated site near
Sainte-Marie-aux-Mines (France). The microbial community
was characterized, using metaproteomic and 16S rRNAencoding
gene amplification. The metaproteomic analysis
revealed an unsuspected high diversity of the arsenic-adapted
prokaryotic community including Planctomycetes and Cyanobacteria
but also an archaeal community comprising Euryarchaeaota
and Thaumarchaeota. Additional papers analyzed
the microbial communities involved in the degradation of other
hydrocarbon pollutants. While Cravo-Laureau et al. (2011)
investigated the response of pollutant-degrading community
under environmental constraints such as oxygen fluctuation,
Ce´bron et al. (2011) reported the development of soil bioindicators
to assess biological diversity and activity in polycyclic
aromatic hydrocarbon (PAH)-polluted soil. Indeed,
microorganisms could be appropriate and user-friendly
biosensors for a fine and rapid detection of pollutants in
aquatic environments (Durrieu et al., 2011). However, a deep
analysis of microbial diversity and physiology revealed the
existence of unexpected degradation pathways of pollutants
such as alkenes (Grossi et al., 2011). Microbes also contribute to
the occurrence of diverse natural compounds (e.g. pristane and
phytane) often used as biomarkers in marine environment by
developing various and unexpected bioconversion pathways
(Rontani and Bonin, 2011).