PgmNr C29: Transcriptome analysis in the Antarctic ciliate Euplotes focardii: molecular basis of cold adaptation and insights regarding the potential impact of climate change.

Authors:
Cristina Miceli; Sandra Pucciarelli; Patrizia Ballarini; Angela Piersanti; Kesava Pryan Ramasamy


Institutes
School of Biosciences and Veterinary Medicine, University of Camerino, IT.


Abstract:

Ciliates provide optimal model systems to study environmental adaptation. Comparative transcriptome analysis of Euplotes focardii, a strictly psychrophilic ciliate isolated from Antarctic seawater, and the mesophilic congeneric species E. crassus  revealed that in E. focardii the majority of the expressed genes code for proteins involved in oxidoreductase activity, as reported for Antarctic fishes and krill. These results confirm that a major problem of Antarctic marine organisms is to cope with increased O2 solubility at low temperatures. They also suggest that an increased defense against oxidative stress likely provides an important evolutionary feature that allowed the adaptation of Antarctic organisms in their oxygen-rich environment. Gene ontology annotation also revealed that many of the transcripts encoded proteins involved in maintenance of protein homeostasis (e.g., chaperones). Quantitative PCR showed that expression of Hsp70 genes was induced when E. focardii cells were subjected to oxidative stress, whereas thermal stress did not cause induction. These results argue that E. focardii in its current environment is well protected against reactive oxygen species and are consistent with prior reports of constitutive Hsp70 expression as a defense against cold-induced protein denaturation.  E. focardii appears to be poised to cope with the oxidative challenge that is likely to accompany oceanic warming over the next century, but the absence of a temperature-inducible chaperone response may place its proteome at risk. 

The comparative analysis of the Euplotes species also revealed a rapid evolution and unusual plasticity of the programmed +1 ribosomal frameshifting, a process that allows the change of the reading frame during translation. This process appears pervasive in Euplotes as it affects decoding of over 3,000 genes in these genomes and it is not conserved in the affected genes of the two species. In addition, evidence for +2 frameshifting appeared from the analysis.

We are currently setting up reverse genetics in E. focardii in order to have a better understanding of the function of some genes that are expressed only in the cold adapted species.