Archaea and the new age of microorganisms.

Archaea were, until recently, considered to be confined to specialized environments including those at high temperature, high salinity, extremes of pH and ambients that permit methanogenesis. Recently developed molecular methods for studying microbial ecology, which do not necessitate cell culturing, have demonstrated their presence in a wide variety of temperate and cold environments including agricultural and forest soils, fresh water lake sediments, marine picoplankton and deep-sea locations. These discoveries mark the beginning of a new era for investigating the Archaea and in particular their physiological and metabolic properties and their biological roles in complex microbial populations.

Shuttle vectors for hyperthermophilic archaea.

Progress in understanding the basic molecular, biochemical, and physiological characteristics of archaeal hyperthermophiles has been limited by the lack of suitable expression vectors. Here, we report the construction of versatile shuttle vectors that can be maintained, and selected for, in both archaea and bacteria. The primary construct, pAG1, was produced by ligating portions of the archaeal cryptic plasmid pGT5 and the bacterial plasmid pUC19, both of which exhibit high copy numbers. A second vector construct, pAG2, was generated, with a reduced copy number in Escherichia coli, by introducing the Rom/Rop gene from pBR322 into pAG1. After transformation, both pAG1 and pAG2 were stably maintained and propagated in the euryarchaeote Pyrococcus furiosus, the crenarchaeote Sulfolobus acidocaldarius, and in Escherichia coli. An archaeal selective marker, the alcohol dehydrogenase gene from Sulfolobus solfataricus, was isolated by polymerase chain reaction (PCR) amplification and cloned into the two constructs. They were stably maintained and expressed in the two archaea and conferred resistance to butanol and benzyl alcohol. However, the vector pAG21, deriving from pAG2, proved the more stable in E. coli probably due to its lower copy number in the bacterium. Conditions are presented for the use of the vectors which, potentially, can be used for other hyperthermophilic archaea.

General vectors for archaeal hyperthermophiles: strategies based on a mobile intron and a plasmid.

Although there are currently no cloning and expression vectors available for archaeal hyperthermophiles, small cryptic plasmids have been characterized for these organisms as well as viruses and introns capable of spreading between cells. Below, we review the recent progress in adapting these genetic elements as vectors for Pyrococcus furiosus and Sulfolobus acidocaldarius. An efficient and reliable transformation procedure is described for both organisms. The potential of the mobile intron from Desulfurococcus mobilis, inserted into the bacterial vector pUC18 to generate a new type of vector, was investigated in S. acidocaldarius. A polylinker was inserted upstream from the open reading frame encoding the homing enzyme I-DmoI. Both the polylinker and a 276 bp fragment of the tetracycline gene from pBR322 could be inserted into the intron-plasmid construct and spreading still occurred in the culture of S. acidocaldarius. Experiments are in progress to test the co-mobility of the alcohol dehydrogenase and beta-galactosidase genes from Sulfolobus species with the intron. A shuttle vector pCSV1 was also produced by fusing the pGT5 plasmid from Pyrococcus abyssi and the bacterial vector pUC19 which, on transformation, is stable in both organisms without selection. Growth inhibition studies indicate that both P. furiosus and S. acidocaldarius are sensitive to the antibiotics carbomycin, celesticetin, chloramphenicol and thiostrepton as well as butanol and butylic alcohol. Spontaneous mutants resistant to these drugs have been isolated carrying single site mutations in their 23S rRNA gene; they include mutants of S. acidocaldarius resistant to chloramphenicol, carbomycin and celesticetin with the mutation C2452U and thiostrepton-resistant mutants of P. furiosus carrying the mutation A1067G (both numbers corresponding to Escherichia coli 23S rRNA). These mutated genes are being developed as selective markers. Moreover, two beta-galactosidase genes from P. furiosus have been cloned as possible phenotypic markers; one of these exhibits maximum activity at 95 degrees C with O-nitrophenyl beta-D-galactopyranoside as substrate.