The bacterial isolates were identif

The bacterial isolates were identified on the
basis of 16S ribosomal RNA conserved sequences. The
bacterial isolated strains were identified as
Microbacterium sp. NA23, Paenibacillus urinalis NA26,
Bacillus sp. NB6, Pseudomonas aeruginosa NB26. The
sequences were submitted to NCBI Gene bank and
accession numbers were obtained (Table 1). Bacterial
growth and adherence with the expanded polystyrene
film for longer period of time without any other carbon
source indicate that isolated soil bacteria are able tocolonize and use expanded polystyrene as a sole carbon
source. The microbial colonization of a polymer surface is
the first requirement for its biodegradation (Yabannavar
and Bartha, 1993). Soil burial is employed to study the
biodegradability of polymers (Yabannavar and Bartha,
1993; Orhan and Büyükgüngör, 2000; Rizzarelli et al.,
2004; Alvarez et al., 2006; Schlemmer et al., 2009). Soil
burial is much close to the natural conditions encountered
by the waste polymer materials (Alvarez et al., 2006) and
act as a field test for further application of biodegradation
studies.
The microbial population is influenced by the materials
in the surrounding environment. Those soil microbes that
will be able to best utilise the carbon contained in the
polymer will be abundant while others will not survive.
There is a wide variety of degradation pathways
employed by a large biodiversity of microorganisms to
metabolize aromatic hydrocarbons. Such organisms are
the main focus of research for clean-up of environmental
pollution (Atlas and Cerniglia, 1995; Van Hamme et al.,
2003). Natural physical and chemical spoilage processes
in various materials are characterized as biodegradation.
The organisms involved are called biodeteriogens that
possess the saprotrophic ability of using substrata to
sustain their growth and reproduction (Pinzari et al.,
2006).