11002141 (B.P.A.I. Sep. 1, 2010)

Ex Parte Mashko et al

Board of Patent Appeals and InterferencesSep 1, 2010

11002141 (B.P.A.I. Sep. 1, 2010)

UNITED STATES PATENT AND TRADEMARK OFFICE __________ BEFORE THE BOARD OF PATENT APPEALS AND INTERFERENCES __________ Ex parte SERGEI VLADIMIROVICH MASHKO and DANILA VADIMOVICH ZIMENKOV __________ Appeal 2009-010864 Application 11/002,141 Technology Center 1600 __________ Before ERIC GRIMES, JEFFREY N. FREDMAN, and STEPHEN WALSH, Administrative Patent Judges. FREDMAN, Administrative Patent Judge. DECISION ON APPEAL1 This is an appeal under 35 U.S.C. § 134 involving claims to a method of controlling gene expression and an expression control sequence. The Examiner rejected the claims as obvious. We have jurisdiction under 35 U.S.C. § 6(b). We reverse. 1 The two-month time period for filing an appeal or commencing a civil action, as recited in 37 C.F.R. § 1.304, or for filing a request for rehearing, as recited in 37 C.F.R. § 41.52, begins to run from the “MAIL DATE” (paper delivery mode) or the “NOTIFICATION DATE” (electronic delivery mode) shown on the PTOL-90A cover letter attached to this decision. Appeal 2009-010864 Application 11/002,141 2 Statement of the Case The invention concerns a “prokaryotic artificial regulatory system providing increase of the controlled gene expression as the result of increase of an intracellular concentration of the sense amino acid” (Spec. 5, ll. 17- 20). Claims 11-16 and 24-26 are on appeal (see App. Br. 2). The claims have not been argued separately and therefore stand or fall together. 37 C.F.R. § 41.37(c)(1)(vii). Independent claim 11 is representative and reads as follows: 11. A method for controlling expression of a target gene, comprising transforming a bacterium with a genetic construct comprising an expression control sequence, cultivating said bacterium in a culture medium, and changing an intracellular concentration of an amino acid on which expression control by the expression control sequence depend, to control expression of the target gene, wherein the expression control sequence is an expression control sequence which controls expression of a target gene linked downstream of the expression control sequence depending on an intracellular concentration of an amino acid, wherein in a bacterium which harbors a DNA construct comprising the expression control sequence, a promoter linked upstream of the expression control sequence and the target gene linked downstream of the expression control sequence, frequency of termination in the expression control sequence when transcription initiates from the promoter is decreased due to an increase in the intracellular concentration of an Appeal 2009-010864 Application 11/002,141 3 amino acid, whereby expression of the target gene increases, wherein said expression control sequence comprises a region coding for a leader peptide comprising said amino acid and a ρ independent terminator, wherein when translation of the leader peptide stops at codon of said amino acid in the course of the translation in case of starvation of said amino acid, a base pairing structure of the ρ independent terminator is formed in a transcript of the expression control sequence, whereby the frequency of termination in the expression control sequence, of the transcription increases; wherein said expression control sequence comprises five segments which are from an attenuator of a tryptophan operon of Escherichia coli and an attenuator of a histidine operon of Escherichia coli when the five segments are numbered in order from an upstream side, the first and second segments, and a coding region for the leader peptide comprise the corresponding part of the attenuator of the tryptophan operon, the fourth and fifth segments comprise the corresponding part of the attenuator of the histidine operon, and the third segment comprises a combination of the corresponding parts of the attenuators of the tryptophan operon and the histidine operon; wherein the first segment overlaps with codon of the amino acid in the leader peptide; and wherein the sequence of each segment or a part thereof and the sequence of the adjacent segment or a part thereof constitute an inverted repeat sequence. Appeal 2009-010864 Application 11/002,141 4 The issue2 The Examiner rejected claims 11-16 and 24-26 under 35 U.S.C. § 103(a) as obvious over Lu,3 Gish,4 and Landick5 (Ans. 3-7). The Examiner concludes it would have been obvious to combine the construct as taught by Lu with elements of the expression control sequence that is regulated by tryptophan as taught by Gish with a rearrangement of the well described terminator and antiterminator sequences of the his operon taught by Landick, so that expression control sequence comprising a promoter and target gene is regulated and increased by intracellular amino acid concentration, particularly tryptophan. One would have been motivated to combine these teachings in order to obtain the expected benefit of an efficient inducible expression construct for the expression of heterologous DNA. (Ans. 6.) Appellants contend that “even if the skilled artisan were to combined the disclosures of Lu et al, Gish et al, and Landick et al, the concept of an anti-attenuator would not have been expected” (App. Br. 7-8). Appellants 2 The Examiner does not restate the claim objection, so we will treat this objection as withdrawn. 3 Chung-Dar Lu and Ahmed T. Abdelal, The gdhB Gene of Pseudomonas aeruginosa Encodes an Arginine-Inducible NAD+- Dependent Glutamate Dehydrogenase Which is Subject to Allosteric Regulation, 183 J. BACTERIOLOGY 490-499 (2001). 4 Kurt Gish and Charles Yanofsky, Evidence Suggesting cis Action by the TnaC Leader Peptide in Regulating Transcription Attenuation in the Tryptophanase Operon of Escherichia coli, 177 J. BACTERIOLOGY 7245-7254 (1995). 5 Robert Landick and Charles Yanofsky, Transcription Attenuation in ESCHERICHIA COLI AND SALMONELLA TYPHIMURIUM CELLULAR AND MOLECULAR BIOLOGY 1276-1301 (F. Niedhardt Ed., 1987). Appeal 2009-010864 Application 11/002,141 5 contend that “the transcript of an anti-attenuator takes the antitermination configuration when the amount of the final product is adequate (i.e., sufficient). Thus, the response to the final product in an anti-attenuator (i.e., the present invention) is the exact opposite of the response in an attenuator (i.e., that disclosed by Landick et al)” (id. at 9). Appellants contend that even assuming arguendo that the artisan would have been motivated to combine the disclosure of Lu et al, Gish et al, and Landick et al to obtain an efficient inducible expression construct for the expression of heterologous DNA, at best the resulting expression construct will be an attenuator based on a combination of the attenuators disclosed in the cited references. (Id. at 10.) The issue with respect to this rejection is: Does the evidence of record support the Examiner’s conclusion that the cited prior art renders obvious a method of controlling expression with an anti-attenuator expression control sequence as required by Claim 11? Findings of Fact (FF) 1. The Specification teaches an artificial regulatory system, which “unlike the natural attenuators of amino acid operons, provides not decrease, but increase of the controlled gene expression in case of excess of the sense amino acid intracellular concentration” (Spec. 5, l. 27 to 6, l. 4). 2. Specification Figure 1 is reproduced below: Appeal 2009-010864 Application 11/002,141 6 “Fig. 1 shows the explanatory scheme of the structures and properties of the native attenuators and the expression control sequence (artificial anti- attenuator)” (Spec. 11, ll. 2-5). 3. Table 1 of the Specification is reproduced below: “Table 1. Determination of CAT activity in the strains carrying the recombinant plasmids with the tested regulatory elements” (Spec. 25, ll. 8- 10). Appeal 2009-010864 Application 11/002,141 7 4. The Specification shows that the native trpL attenuator increases expression during starvation of the amino acid tryptophan relative to the expression in conditions of excess tryptophan, while the “anti- attenuators” show increased levels of expression during tryptophan excess relative to tryptophan starvation (see Spec. 25, Table 1). 5. Lu teaches a recombinant plasmid with the gdhB operon which when “grown in LB supplemented with 20 mM arginine, had a 28-fold- higher NAD-GDH activity than the control strain” (Lu 492, col. 2). 6. The Examiner finds that Lu teaches a regulatory operon which “comprises at least 3 segments capable of forming base pair structures . . . The sequence taught contains an inverted repeat sequences (Id. ‘GTTG’, in sequence line ‘70’)” (Ans. 5). 7. Gish teaches that “[e]levated levels of tryptophan induce transcription antitermination at one or more Rho factor-dependent termination sites in the leader region of the operon” (Gish 7245, abstract). 8. Gish teaches “plasmids containing the intact tna operon (pKG1), a translational fusion of tnaA to lacZ driven by the tna promoter . . . or the tet promoter” (Gish 7248, col. 1). 9. Gish teaches that in tests “with a plasmid containing the intact tna operon, there was appreciable induction by DL-1-methyltryptophan and L-tryptophan” (Gish 7248, col. 1). 10. Gish teaches that “these data support the conclusion that the predicted RNA secondary structures are not responsible for tryptophan induction” (Gish 7251, col. 1). Appeal 2009-010864 Application 11/002,141 8 11. Landick teaches regarding the his operon that “segments of the leader transcript theoretically can fold into two alternative secondary structures: one has a potential Rho-independent terminator at its 3’ end, and the other structure could function as an antiterminator” (Landick 1283, col. 2). Principles of Law The Examiner has the initial burden of establishing a prima facie case obviousness under 35 U.S.C. § 103. In re Oetiker, 977 F.2d 1443, 1445 (Fed. Cir. 1992). “[R]ejections on obviousness grounds cannot be sustained by mere conclusory statements; instead, there must be some articulated reasoning with some rational underpinning to support the legal conclusion of obviousness.” KSR Int’l Co. v. Teleflex Inc., 550 U.S. 398, 418 (2007). Analysis The Examiner acknowledges that Landick “does not teach how to modify an attenuator to impart anti-attenuator activity” (Ans. 8). The Examiner nevertheless contends that “one would have been motivated to combine these references, and the attenuators, in order to obtain the expected benefit of an efficient inducible expression construct for the expression of heterologous DNA” (id.). The Examiner’s statement is not an articulated reason to make an anti- attenuator, nor is there any underpinning to support this conclusion. The Examiner, while identifying a teaching of the his operon (FF 11), does not even provide evidence that the trp operon is taught in the prior art. Appeal 2009-010864 Application 11/002,141 9 The Examiner also argues that “the name of the composition does not matter . . . the references teach that the frequency of termination in the expression control sequence is decreased, leading to gene expression that is increased due to an increase in amino acid concentration” (Ans. 9-10). We are not persuaded since this is not what claim 11 requires for the expression control sequence. Claim 11 is directed towards a method for controlling target gene expression using an expression control sequence which increases the frequency of termination of translation “in case of starvation of amino acid” (see Claim 11). Thus, as Appellants contend, the “attenuator attenuates translation as an amino acid increases, whereas the anti-attenuator attenuates translation as an amino acid decreases” (App. Br. 10). We agree with Appellants that the Examiner has not adequately explained how the references would have suggested modifying an attenuator into an anti-attenuator as required by Claim 11. The Examiner has not pointed to any disclosure in Lu, Gish, or Landick that provides any disclosure of an anti-attenuator like activity. Although the Examiner concludes that this limitation would have been obvious based on Landick, the Examiner has not pointed out any part of Landick that would have suggested to one of skill in the art the formation of an anti-attenuator. The Examiner has not explained how Landick’s “could function” (FF 11) statement provided sufficient information. Appeal 2009-010864 Application 11/002,141 10 Conclusion of Law The evidence of record does not support the Examiner’s conclusion that the cited prior art renders obvious a method of controlling expression with an anti-attenuator expression control sequence as required by Claim 11. SUMMARY In summary, we reverse the rejection of claims 11-16 and 24-26 under 35 U.S.C. § 103(a) as obvious over Lu, Gish, and Landick. REVERSED cdc OBLON, SPIVAK, MCCLELLAND MAIER & NEUSTADT, L.L.P. 1940 DUKE STREET ALEXANDRIA, VA 22314