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
2002-01-16
2004-07-20
Leffers, Gerry (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...
C435S069100, C435S325000, C435S252300, C435S320100, C435S471000, C536S023100, C536S023400, C536S024100
Reexamination Certificate
active
06764837
ABSTRACT:
The present invention relates to nucleic acid molecules and constructs containing these nucleic acid molecules and methods of using these constructs to express heterologous genes in hosts. In particular, the nucleic acid molecules of the present invention comprise a DNA sequence encoding at least a portion of the &agr; subunit of the RNA polymerase (referred to herein as RNAP) obtained from the same genus source from which the heterologous genes were originally isolated. The nucleic acid constructs also can optionally comprise, if required for expression of the heterologous genes, at least one gene encoding a transcriptional regulator, also obtained from the same genus as the source of the heterologous genes.
BACKGROUND OF THE INVENTION
Although many host cell systems are well characterized and utilized to express a number of heterologous genes, there are still many genes that cannot be expressed in such host cell systems, as for example,
Escherichia coli
(
E. coli
). It is believed that the lack of expression in these host cell systems is a result of the promoter sequences of the heterologous genes not being recognized by the host RNAP. The present invention has solved this problem by showing that this block in expression can be overcome by co-expression of at least a portion of the rpoA gene product, the gene that encodes the &agr; subunit of the RNAP, obtained from the same genus as the source of the heterologous gene that is desired to be expressed in the new host cell. The co-expressed &agr; subunit of the RNAP from the same genus as the source of the heterologous gene combines with the other subunits of the RNAP, &bgr;, &bgr;′, and &sgr;, to form a functional RNAP. Additionally, if transciptional regulators, such as transcriptional activators or transcriptional repressors, or additional other subunits of the RNAP, such as &bgr;, &bgr;′ or &sgr;, are required to obtain expression of the heterologous gene, then these additional components also are obtained from the same genus as the source of the heterologous gene. Since two different rpoA genes are present in a single host cell, there will be various combinations of RNAPs present in the host cell (1) RNAP containing two &agr; subunits of the same genus as the host (2) RNAP containing two &agr; subunits from the same genus source as the heterologous gene, and (3) RNAP containing one &agr; subunit from the same genus as the host and one &agr; subunit from the same genus source as the heterologous gene. A heterologous gene is intended to mean a gene that is not from the same source as the host cell.
Agrobacterium tumefaciens
is a Gram-negative soil bacterium which is the causative agent of Crown Gall disease, affecting primarily dicotyledonous plant species (reviewed in 18, 62). The pathogen incites production of the characteristic tumor through the transfer of a piece of DNA (T-DNA) from the Ti (Tumor inducing) plasmid into susceptible plant cells, with subsequent integration into the host genome. The T-DNA contains genes that direct the biosynthesis of auxin and cytokinin in infected cells (1, 57), resulting in uncontrolled cell division leading to production of the characteristic tumor. The T-DNA also contains genes for the biosynthesis of unique compounds called opines which the bacterium can utilize as a carbon and nitrogen source (39).
Successful transfer of the T-DNA is dependent on the coordinated expression of virulence (vir) genes located on the Ti plasmid but separate from the T-DNA. Expression of vir genes occurs in response to certain phenolic compounds released from wounded plants (54). This expression is augmented by monosaccharides (5, 52), and an acidic pH (38) which are characteristics of plant wound sites. Expression of vir genes requires virA and virG, which are members of the family of two component regulatory systems (60). VirA is an inner membrane associated histidine protein kinase which autophosphorylates in response to the environmental signals (19, 28). The phosphate moiety is subsequently transferred to the aspartate residue of VirG, which in turn activates transcription from promoters containing a specific 12 base pair sequence called the vir box, present in the promoters of all vir genes (29, 44). In addition to virA and virG, other chromosomally encoded genes have been identified in
A. tumefaciens
that have been shown to modulate virulence gene expression either directly or indirectly (12, 15, 20, 61).
The use of
E. coil
as a heterologous host in which to study the regulation of
A. tumefaciens
virulence genes and the mechanism of T-DNA transfer constitutes an ideal model system given the degree of characterization at both the biochemical and genetic level. However, all previous attempts to reconstitute vir gene expression in
E. coil
have not been successful. Possible explanations for the lack of vir gene expression include the presence of unidentified regulatory genes in
A. tumefaciens
required for vir induction, and/or that
E. coli
may contain specific repressor(s) of vir gene induction.
A characteristic of vir gene promoters is the absence of a strong −35 sequence (10). Dnase I footprinting studies have shown that VirG protects a region extending into where the −35 consensus sequence should be (29, 44). It has been suggested that binding of VirG may functionally replace the −35 consensus sequence allowing transcription to occur. This situation is similar to Class II CAP-dependent promoters, in which the CAP binding site overlaps with the −35 sequence. Studies have demonstrated that transcription at Class II CAP-dependent promoters requires interaction between CAP and the &agr; subunit (rpoA) of RNAP (42, 49, 64). Many transcriptional factors from
E. coli
are known to require interaction with the &agr; subunit of RNAP, including FNR (59), GaiR (9), MarA (24), Mer R (7), MetR (23) OxyR (56), OmpR (21), Rob (26), SoxS (25), and TyrR (34). Analysis of the &agr; subunit from
E. coli
indicates the presence of two independent domains, the N-terminal domain and the C-terminal domain (21, 27, 63). The N-terminal domain (NTD) is involved in the assembly of the core polymerase, while the C-terminal domain (CTD) is involved in interaction with certain transcriptional regulators (7, 9, 21, 23, 24, 25, 26, 32, 34, 47, 56, 59). Recently, interaction between the NTD and CAP at Class II CAP-dependent promoters has been demonstrated (42,49).
The present methods of expressing heterologous genes are particularly useful to express multiple genes or operons in a metabolic pathway by co-expressing the rpoA gene product obtained from the same natural hosts from which the genes or operons were originally isolated with the multiple genes. The present method provides an advantage over existing multiple gene expression systems by eliminating the need to separately isolate each gene in the metabolic pathyway and link each gene to a promoter that is functional in the host. Expression of heterologous genes for an entire metabolic pathway in hosts is particularly useful to produce particular metabolites, such as pharmaceuticals, food supplements, chemical products or fine chemical products.
The present invention further provides nucleic acid molecules and methods whereby heterologous genes encoding metabolites in an entire metabolic pathway can be introduced into hosts so that these hosts possess specific catabolic and/or metabolic characteristics that allow the hosts to grow or express gene products under specific environmental conditions. These hosts are useful in bioremediation, bioassays and biocontrol studies where manipulation of natural or symbiotic bacterial flora is desired, such as in the control of parasites or insects where bacterial symbiants are involved.
The present invention broadly relates to the expression of heterologous genes in a host using nucleic acid molecules comprising a gene encoding the complete &agr; subunit of the RNAP obtained from the same genus as the source of the heterologous genes or at least a portion of the &agr; subunit of the RNA
Chow Marie
Jin Shouguang
Lohrke Scott M.
Severinov Konstantin
Board of Trustees of the University of Arkansas
Leffers Gerry
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