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Literature DB >> 4506763

The upper temperature limit for eukaryotic organisms.

Abstract

An upper temperature limit near 60 degrees for eukaryotic organisms is documented by results of a systematic search for fungi able to grow at higher temperatures. Samples from hot springs, thermal soils, self-heating coal waste piles, and other natural and man-made heated habitats did not yield fungi when enrichments were done at 62 degrees , whereas fungi able to grow at 55-60 degrees can be readily isolated from such habitats. Earlier work had shown that eukaryotic algae are also absent from environments with temperatures above 55-60 degrees . It is suggested that the failure of eukaryotes to evolve members able to grow at higher temperatures is due to their inability to form organellar membranes that are both thermostable and functional.

Entities: Species

Mesh：

Substances：
Culture Media

Year: 1972 PMID： 4506763 PMCID： PMC426956 DOI： 10.1073/pnas.69.9.2426

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

14 in total

Review 1. Temperature effects on microorganisms.

Authors: J Farrell; A Rose
Journal: Annu Rev Microbiol Date: 1967 Impact factor: 15.500

2. Life at high temperatures. Evolutionary, ecological, and biochemical significance of organisms living in hot springs is discussed.

Authors: T D Brock
Journal: Science Date: 1967-11 Impact factor: 47.728

10. Thermal adaptation in yeast: growth temperatures, membrane lipid, and cytochrome composition of psychrophilic, mesophilic, and thermophilic yeasts.

Authors: H Arthur; K Watson
Journal: J Bacteriol Date: 1976-10 Impact factor: 3.490

The upper temperature limit for eukaryotic organisms.

Review 1. Temperature effects on microorganisms.

2. Life at high temperatures. Evolutionary, ecological, and biochemical significance of organisms living in hot springs is discussed.

3. Comparative thermostability of enzymes from Bacillus stearothermophilus and Bacillus cereus.

4. Bacterial growth rates above 90 degrees C in Yellowstone hot springs.

5. Limits of microbial existence: temperature and pH.

6. Cellulolytic activity in municipal solid waste composting.

7. The upper temperature limit of Cyanidium caldarium.

8. Transduction in Proteus morganii.

9. Thermus aquaticus gen. n. and sp. n., a nonsporulating extreme thermophile.

10. Thermostable aldolase from Thermus aquaticus.

Review 1. Thermophilic fungi: their physiology and enzymes.

2. Novel archaea and bacteria dominate stable microbial communities in North America's Largest Hot Spring.

3. Temperature dependence of the DNA double helix at the nanoscale: structure, elasticity, and fluctuations.

4. Isolation of thermophilic fungi from snuff.

5. Submicroscopic morphology of Trichophyton mentagrophytes grown at different temperatures.

Review 6. Eukaryotic organisms of continental hydrothermal systems.

7. Biological limits of temperature and pressure.

8. Diversity of thermophilic and thermotolerant fungi in corn grain.

9. Eucaryote thermophily: role of lipids in the growth of Talaromyces thermophilus.

10. Thermal adaptation in yeast: growth temperatures, membrane lipid, and cytochrome composition of psychrophilic, mesophilic, and thermophilic yeasts.