In attempts to develop a method of introducing DNA into Pyrococcus furiosus, we discovered a variant within the wild-type population that is naturally and efficiently competent for DNA uptake. A pyrF gene deletion mutant was constructed in the genome, and the combined transformation and recombination frequencies of this strain allowed marker replacement by direct selection using linear DNA. We have demonstrated the use of this strain, designated COM1, for genetic manipulation. Using genetic selections and counterselections based on uracil biosynthesis, we generated single-and double-deletion mutants of the two gene clusters that encode the two cytoplasmic hydrogenases. The COM1 strain will provide the basis for the development of more sophisticated genetic tools allowing the study and metabolic engineering of this important hyperthermophile.It would be difficult to overestimate the contribution of genetic manipulation to the study of any biological system, and it is an essential tool for the metabolic engineering of biosynthetic and substrate utilization pathways. This is particularly true for the archaea since, in spite of their environmental and industrial importance, coupled with their unique molecular features, much remains to be learned about their biology (2). The marine hyperthermophilic anaerobe Pyrococcus furiosus is of special interest not only for its ability to grow optimally at 100°C and the implications of this trait for its biology but also for industrial applications of its enzymes, as well as its capacity to produce hydrogen efficiently (4, 13, 44). The ability to apply genetic analyses of P. furiosus to underpin existing biochemical and molecular studies will contribute greatly to the establishment of P. furiosus as a model organism, particularly for biological hydrogen production.The development of genetic systems in the archaea, in general, presents many unique challenges given the extreme growth requirements of many of these organisms. To date, genetic systems of various levels of sophistication have been developed for representatives of all major groups of archaea, including halophiles, methanogens, thermoacidophiles, and hyperthermophiles (2,6,30,40,43,46). A variety of transformation methods are being used, including electroporation, heat shock with or without CaCl 2 treatment, phage-mediated transduction, spheroplast transformation, liposomes, and, very recently, even conjugation with Escherichia coli (2, 12). Transformation via natural competence has been reported in three archaeal species, in comparison to over 60 bacterial species that are known to exhibit this trait (16,36). Two of them are the methanogens Methanococcus voltae PS (7, 27) and Methanobacterium thermoautotrophicum Marburg (47); however, transformation frequencies were low, and there have been no follow-up studies regarding natural competence. The other is the hyperthermophile Thermococcus kodakarensis, which has an optimal growth temperature of 85°C. Its natural competence has enabled the development of genetic tools fo...
We describe the development of a convenient and sensitive reporter gene system for Streptomyces spp. based on the use of a promoterless copy of the xylE gene of Pseudomonas putida. The xylE gene product is a catechol dioxygenase, which converts the colorless substrate catechol to an intensely yellow hydroxymuconic semialdehyde. A promoterless copy of xyIE was placed under the transcriptional control of galPI, a glucose-repressed and galactose-induced promoter from Streptomyces lividans, and its expression was examined in bacterial colonies on agar plates or in liquid cultures grown in the presence of glucose or galactose as the sole carbon source. On plates, colonies of bacteria grown on galactose turned bright yellow within a few minutes of being sprayed with a solution of catechol, whereas colonies on glucose-containing plates remained white or only slightly colored, even after extensive incubation. Activity of gaUlPI-xylE fusions was conveniently measured in crude cell extracts with a simple colorimetric assay and was shown to faithfully reflect intracellular RNA levels, as determined by quantitative dot blots. Moreover, differences in expression levels of xylE fusions driven by mutant galPI promoters were readily apparent in color reactions on plates. The properties ofxylE as a reporter gene thus make it suitable not only for quantitatively monitoring expression of regulated promoters in Streptomyces spp. but also for recovering mutations that alter the expression levels of promoters of interest.
Very few cultivated microorganisms can degrade lignocellulosic biomass without chemical pretreatment. We show here that "Anaerocellum thermophilum" DSM 6725, an anaerobic bacterium that grows optimally at 75°C, efficiently utilizes various types of untreated plant biomass, as well as crystalline cellulose and xylan. These include hardwoods such as poplar, low-lignin grasses such as napier and Bermuda grasses, and high-lignin grasses such as switchgrass. The organism did not utilize only the soluble fraction of the untreated biomass, since insoluble plant biomass (as well as cellulose and xylan) obtained after washing at 75°C for 18 h also served as a growth substrate. The predominant end products from all growth substrates were hydrogen, acetate, and lactate. Glucose and cellobiose (on crystalline cellulose) and xylose and xylobiose (on xylan) also accumulated in the growth media during growth on the defined substrates but not during growth on the plant biomass. A. thermophilum DSM 6725 grew well on first-and second-spent biomass derived from poplar and switchgrass, where spent biomass is defined as the insoluble growth substrate recovered after the organism has reached late stationary phase. No evidence was found for the direct attachment of A. thermophilum DSM 6725 to the plant biomass. This organism differs from the closely related strain A. thermophilum Z-1320 in its ability to grow on xylose and pectin. Caldicellulosiruptor saccharolyticus DSM 8903 (optimum growth temperature, 70°C), a close relative of A. thermophilum DSM 6725, grew well on switchgrass but not on poplar, indicating a significant difference in the biomass-degrading abilities of these two otherwise very similar organisms.
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