Abstract Many hydrocarbon-contamina

Abstract Many hydrocarbon-contaminated environments
are characterized by low or elevated temperatures, acidic
or alkaline pH, high salt concentrations, or high pressure.
Hydrocarbon-degrading microorganisms, adapted to
grow and thrive in these environments, play an important
role in the biological treatment of polluted extreme habitats.
The biodegradation (transformation or mineralization)
of a wide range of hydrocarbons, including aliphatic,
aromatic, halogenated and nitrated compounds, has
been shown to occur in various extreme habitats. The
biodegradation of many components of petroleum hydrocarbons
has been reported in a variety of terrestrial and
marine cold ecosystems. Cold-adapted hydrocarbon degraders
are also useful for wastewater treatment. The use
of thermophiles for biodegradation of hydrocarbons with
low water solubility is of interest, as solubility and thus
bioavailability, are enhanced at elevated temperatures.
Thermophiles, predominantly bacilli, possess a substantial
potential for the degradation of environmental pollutants,
including all major classes. Indigenous thermophilic
hydrocarbon degraders are of special significance
for the bioremediation of oil-polluted desert soil. Some
studies have investigated composting as a bioremediation
process. Hydrocarbon biodegradation in the presence
of high salt concentrations is of interest for the bioremediation
of oil-polluted salt marshes and industrial
wastewaters, contaminated with aromatic hydrocarbons
or with chlorinated hydrocarbons. Our knowledge of the
biodegradation potential of acidophilic, alkaliphilic, or
barophilic microorganisms is limited.
Introduction
Biodegradation is the metabolic ability of microorganisms
to transform or mineralize organic contaminants into
less harmful, non-hazardous substances, which are
then integrated into natural biogeochemical cycles. The
intensity of biodegradation is influenced by several factors,
such as nutrients, oxygen, pH value, composition,
concentration and bioavailability of the contaminants,
chemical and physical characteristics and the pollution
history of the contaminated environment. Bioremediation,
a non-destructive, cost- and treatment-effective and
sometimes logistically favorable cleanup technology,
attempts to accelerate the naturally occurring biodegradation
of contaminants through the optimization of limiting
conditions (Norris 1994; Allard and Neilson 1997;
Alexander 1999).
Many environments are characterized by low or elevated
temperatures, acidic or alkaline pH, high salt concentrations,
or high pressure. Extremophilic microorganisms
are adapted to grow and thrive under these adverse
conditions. Hydrocarbon degrading extremophiles are
thus ideal candidates for the biological treatment of polluted
extreme habitats. In this review we summarize the
recent developments, obtained both in laboratory and
field studies, in biodegradation and bioremediation of
hydrocarbon contaminants that are of environmental
concern in extreme habitats.