Chaetomium thermophilum explained

Chaetomium thermophilum is a thermophilic filamentous fungus. It grows on dung or compost (rotten organics). It is notable for being a eukaryote with a high temperature tolerance (60 °C). Its optimal growth temperature is 50–55 °C.

Research

Since fungi are eukaryotic and not distant from animals they are good models for comparative and easy-to-manipulate research, and in the case of C. thermophilum, it is of special significance. First, given the fact it is thermophilic, proteins derived from this fungus are heat stable and thus easier to work with. Proteins from C. thermophilum are thermophilic and thus better for studies (structural and biochemical) than comparable mesophilic fungi. Studying nuclear pore complex proteins, it was found that protein isolation was more abundant and more soluble than in yeast (yeast proteins precipitate at a lower temperature).[1]

Genome and proteome

The genome of C. thermophilum has been completely sequenced. It spans 28.3 Mb and encodes 7227 predicted protein coding genes.[2] [3] Saccharomyces cerevisiae, a model yeast, has 73% protein homology to this fungus.

The proteome of C. thermophilum has been studied and 27 distinct protein communities, including 108 interconnected complexes have been identified.[4]

Model system for identifying higher-order protein interactions

The first observation of a metabolon in fatty acid metabolism at high resolution came from cryo-electron microscopic analysis of cellular homogenates from C. thermophilum. Other protein complexes and higher-order interactions were predicted and validated using a novel integration of experimental and computational methods which include proteomics, cross-linking mass spectrometry, computational structural biology and electron microscopy. The cellular homogenates of C. thermophilum were used to derive protein complex structures at high resolution, with purity of the native protein complex < 40%.

External links

Notes and References

  1. Insight into Structure and Assembly of the Nuclear Pore Complex by Utilizing the Genome of a Eukaryotic Thermophile
  2. Bock. Thomas. Chen. Wei-Hua. Ori. Alessandro. Malik. Nayab. Silva-Martin. Noella. Huerta-Cepas. Jaime. Powell. Sean T.. Kastritis. Panagiotis L.. Smyshlyaev. Georgy. 2014-12-16. An integrated approach for genome annotation of the eukaryotic thermophile Chaetomium thermophilum. Nucleic Acids Research. 42. 22. 13525–13533. 10.1093/nar/gku1147. 25398899. 0305-1048. 4267624.
  3. Web site: Genozymes Public Genomes . Genome.fungalgenomics.ca . 2014-05-17.
  4. Kastritis. Panagiotis L.. O'Reilly. Francis J.. Bock. Thomas. Li. Yuanyue. Rogon. Matt Z.. Buczak. Katarzyna. Romanov. Natalie. Betts. Matthew J.. Bui. Khanh Huy. 2017-07-01. Capturing protein communities by structural proteomics in a thermophilic eukaryote. Molecular Systems Biology. en. 13. 7. 936. 10.15252/msb.20167412. 28743795. 1744-4292. 5527848.