First report of cis-1,4-polyisoprene degradation by Gordonia paraffinivorans.

The use of rubber has increased over the years, leading to a series of environmental problems due to its indefinite decomposition time. Bioremediation employing microorganisms have drawn an increasing interest and originated several studies of microbial rubber degradation. Genome sequencing and in silico analysis demonstrated that G. paraffinivorans MTZ041 isolate encodes the lcp gene (Latex Clearing Protein), responsible for expressing an enzyme that performs the first step in the assimilation of synthetic and natural rubber. Growth curves and scanning electron microscopy (SEM) were conducted for MTZ041 in natural (NR) and synthetic rubber (IR) as sole carbon source during 11 weeks. After 80 days, robust growth was observed and SEM analysis revealed the presence of bacilli and the formation of biofilm-like structures on natural and synthetic rubber. This is the first report of a G. paraffinivorans rubber degrader. Given the complexity of this substrate and the relative small number of microorganisms with this ability, the description and characterization of MTZ041 is of great importance on bioremediation processes of rubber products.

Microbial community structure and dynamics in thermophilic composting viewed through metagenomics and metatranscriptomics.

Composting is a promising source of new organisms and thermostable enzymes that may be helpful in environmental management and industrial processes. Here we present results of metagenomic- and metatranscriptomic-based analyses of a large composting operation in the São Paulo Zoo Park. This composting exhibits a sustained thermophilic profile (50 °C to 75 °C), which seems to preclude fungal activity. The main novelty of our study is the combination of time-series sampling with shotgun DNA, 16S rRNA gene amplicon, and metatranscriptome high-throughput sequencing, enabling an unprecedented detailed view of microbial community structure, dynamics, and function in this ecosystem. The time-series data showed that the turning procedure has a strong impact on the compost microbiota, restoring to a certain extent the population profile seen at the beginning of the process; and that lignocellulosic biomass deconstruction occurs synergistically and sequentially, with hemicellulose being degraded preferentially to cellulose and lignin. Moreover, our sequencing data allowed near-complete genome reconstruction of five bacterial species previously found in biomass-degrading environments and of a novel biodegrading bacterial species, likely a new genus in the order Bacillales. The data and analyses provided are a rich source for additional investigations of thermophilic composting microbiology.