Chemistry: molecular biology and microbiology – Micro-organism – tissue cell culture or enzyme using process... – Recombinant dna technique included in method of making a...
Reexamination Certificate
1999-09-07
2001-09-25
Guzo, David (Department: 1636)
Chemistry: molecular biology and microbiology
Micro-organism, tissue cell culture or enzyme using process...
Recombinant dna technique included in method of making a...
C435S440000, C435S477000, C435S006120, C435S320100, C435S252300, C536S023100, C536S024100
Reexamination Certificate
active
06294358
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to the identification and utilization of promoters for expression of nucleic acid sequences in thermophiles.
BACKGROUND OF THE INVENTION
The high-temperature operating conditions of certain industrial processes in the areas of pharmaceutical synthesis, biodegradation of complex agricultural and industrial waste compounds, and food processing dictate the use of thermostable enzymes that can function at high temperatures. A significant advantage thermostable enzymes provide are cost savings resulting from longer storage stability and the higher activity at high temperature.
Thermostable enzymes have traditionally been used for saccharification in food processing and proteolysis in detergent industry (Williams, R. A. D. Biotechnological applications of the genus Thermus. Thermophiles: Science and Technology, Reykjavik, Iceland, 1992). Glucosidases are utilized extensively throughout the starch processing industry. Thermostable carbohydrases are directly involved in the manufacture of all starch-derived products. Isomersases are involved in production of high-fructose corn syrup. Two other important industrial carbohydrases are the pectolytic enzymes and lactase (Burgess, K. and M. Shaw. In
Industrial enzymology.
Ed. by T. Godfrey and Reichelt, J., N.Y. p. p. 260. 1983; Bombouts, F. M. and W. Pilnik. In
Microbial enzymes and bioconversions.
Ed. by A. H. Rose, N.Y. p. 269. 1980). A recent development in the industrial enzyme area is the use of cellulase for the production of glucose from cellulose (Mandels, M. In
Annual reports on fermentation processes.
Ed. by G. T. Tsao, N.Y. p. 35. 1982). Proteolytic enzymes, constituting a significant segment of the total industrial enzyme market are utilized in the detergent industry (Godfrey, T. and J. Reichelt. (1983) Industrial enzymology.).
One of the most promising new applications of thermostable enzymes is in the manufacture of specialty chemicals and pharmaceutical intermediates. Enzymes (or biocatalysts) are now being viewed as clearly superior in cases where stereospecific synthetic reactions are involved, such as synthesis of chiral compounds as pharmaceutical intermediates. Enzymes can carry out the reaction more specifically and under conditions which are safer for the environment. Thermostable enzymes have advantages since they are generally more stable in organic solvents, can carry out reactions at high temperatures where substrate and product solubility is higher, and can be recycled and used for longer periods of time because of their inherent stability.
A relatively new application of thermostable enzymes is PCR-based diagnostics. Thermostable polymerases have been extremely useful in the detection and molecular characterization of agents causing cancer, AIDS, and numerous other infectious diseases. Thermostable DNA-polymerase can already compete in market value with enzymes having traditional applications. Thermostable DNA replication proteins have important applications in molecular biology research.
A significant limitation to the widespread use of thermostable enzymes in such applications is the difficulty in expressing the proteins in a host bacteria. Thermophilic bacteria belong to a wide range of very different taxonomic groups (Kristiansson, J. K. and K. O. Stetter. Thermophilic bacteria. In
Thermophilic bacteria.
Ed. by J. K. Kristiansson, CRC Press, Inc., Boca Raton. p. 1-18. 1992). One of the best studied is the gram negative genus Thermus. Species belonging to this genus are easy to handle, growing aerobically in a broad temperature range of 45 to 85° C. and not requiring pressurized incubation devices (Williams, R. A. D. Biotechnological applications of the genus Thermus. Thermophiles: Science and Technology, Reykjavik, Iceland, 1992). These strains grow to high densities in simple and inexpensive liquid media and form colonies on solid agar. With a doubling time less than 2 hours, the microorganisms of the genus Thermus are suitable organisms for various industrial applications.
Despite the widespread interest in Thermus cultures for a variety of applications, there is a need for systems to control gene expression in Thermus. Currently the expression of heterologous genes in thermophilic hosts is difficult and inconvenient. Expression vectors for thermophiles do not provide a choice of promoters or ribosome binding sites, nor do they provide a convenient ways to regulate expression. The reagents and methodologies provided herein allow for the production of commercially important enzymes including those from hyper- and extreme-thermophiles that can be difficult to produce using other systems. Also provided are reagents and methodologies for the construction of high-temperature fermentation strains which have been metabolically engineered with exogenous DNA for use in bioprocess applications such as production of complex molecules and pharmaceutical intermediates. Additionally, the systems provided herein are useful for thermostabilization of mesophilic proteins by genetic selection in a thermophile, which can also lead to altered enzymatic activity and a better understanding of the biochemical determinants for thermostability.
REFERENCES:
patent: 5459055 (1995-10-01), Jendrisak et al.
patent: 5786174 (1998-07-01), Weber et al.
patent: 5872238 (1999-02-01), Weber et al.
patent: 5969121 (1999-10-01), Allen et al.
patent: 5981177 (1999-11-01), Demirjian et al.
patent: 0138075 (1985-04-01), None
Gryaznova, et al. Biochimie 78: 915-919, 1996.*
Lasa et al., “Insertional mutagenesis in the extreme thermophilic eubacteriaThemus thermophilusHB8,” Molecular Microbiology, vol. 6, pp. 1555-1564, 1992.
Liao et al., “Isolation of a Thermostable enzyme variant by cloning and selection in a thermopile,” Proc. Natl. Acad. Sci. USA, vol. 83, pp. 576-580, 1986.
Lerner et al., “Structure of theBacillus subtiluspyrimidine biosynthetic (pyr) gene cluster,” J. Bacterilogy, vol. 169, pp. 2202-2206, 1987.
Nagahari et al., “Cloning and expression of the leucine gene from theThermus thermophilusinEscherichia coli,” Gene, vol. 10, pp. 137-145, 1980.
Sen & Oriel, “Transfer to transposon Tn916 fromBacillus subtilistoThermus aquaticus,” FEMS Microbiology Letters 67:131-134 (1990).
Koyama et al., “A plasmid vector for an extreme thermophile,Thermus thermophilus,” FEMS Microbiology Letters 72:97-102 (1990).
Koyama & Furukawa, “Cloning and Sequence Analysis f Tryptophan Synthease Genes of an Extreme Thermophile,Thermus thermophilusHB27: Plasmid transfer from Replica-PlatedEscherichia coliRecombinant Colonies to CompetentT. ThermophilusCells,” J. of Bacteriology, 172:3490-3495 (1990).
Koyama et al., “Genetic Transformation of the Extreme ThermophileThermus thermophilusand of Other Thermus spp.,” J. Bacteriology, 166:338-340 (1986).
Borges and Bergquist, “Genomic Restriction map of the Extrememly Thermophilic BacteriumThermus ThermophilusHB8,” J. Bacteriology, 175:103-110 (1993).
Matsumura et al., “Enzymatic and ucleotide Sequence Studies of a Kanamycin-Inactivating Enzyme Encoded by a Plasmid fromThermophilic Bacilliin Comparison with That encoded by Plasmid pUB110,” J. of Bacteriology, 160:413-420 (1984).
Matsumura & Aiba, “Screening of Thermostable Mutant of Kanamycin Nucleotidyltransferase by the Use of a Transformation System for a Thermophile,Bacillus stearothermophilus,” J. of Biological Chemistry, 260:15289-15303 (1985).
Matsumura et al., “Cumulative effect of intragenic amino-acid replacements on the thermostability of protein,” Nature, 323:356-358 (1986).
Lasa et al., “Development of Thermus-Escherichia Shutle Vectores and Their Use of Expression of theClostridium thermocellumCelA Gene inThermus thermophilus,” J. of Bacteriology, 174:6424-6431.
Faraldo et al., “Sequence of the S-Layer Gene ofThermus thermophilusHB7 and Functionality of its Promoter inEscheria coli,” J. of Bacteriology, 174:7458-7462 (1992).
Mather & Fee, “Development of Plasmid Cloning Vectors forThermus thermophilusHB8: Expression of a Heterologous, Plasmid-Bone Kanamycin Nucleotidyltransferase Gene,” Appli
Demirjian David C.
Peredultchuk Mikhail
Vonstein Veronica
Guzo David
Leffers, Jr. Gerald G.
Thermogen Inc.
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