10913996 (B.P.A.I. Apr. 1, 2010)

Ex Parte Iversen et al

Board of Patent Appeals and InterferencesApr 1, 2010

10913996 (B.P.A.I. Apr. 1, 2010)

UNITED STATES PATENT AND TRADEMARK OFFICE __________ BEFORE THE BOARD OF PATENT APPEALS AND INTERFERENCES __________ Ex parte PATRICK L. IVERSEN and DAVID A. STEIN __________ Appeal 2009-013446 Application 10/913,996 Technology Center 1600 __________ Decided: April 1, 2010 __________ Before TONI R. SCHEINER, ERIC GRIMES, and JEFFREY N. FREDMAN, Administrative Patent Judges. FREDMAN, Administrative Patent Judge. DECISION ON APPEAL This is an appeal under 35 U.S.C. § 134 involving claims to anti- flaviviral antisense compounds. We have jurisdiction under 35 U.S.C. § 6(b). We reverse. Appeal 2009-013446 Application 10/913,996 2 Statement of the Case Background “This invention relates to an oligonucleotide analog for use in treating a flavivirus infection in animals, to an antiviral method employing the analog, and to a method for monitoring binding of the analog to a viral genome target site” (Spec. 1, ll. 10-12). The Claims Claims 17, 27, and 30 are on appeal. Claim 17 is representative and reads as follows: 17. An anti-flaviviral compound composed of morpholino subunits and phosphorus-containing intersubunit linkages joining a morpholino nitrogen of one subunit to a 5' exocyclic carbon of the adjacent subunit, and characterized by: (i) a nuclease-resistant backbone, (ii) capable of uptake by virus-infected animal cells, (iii) containing between 8-40 nucleotide bases, (iv) having a sequence of 8 contiguous bases complementary to the sequence identified by SEQ ID NO: 3, and (v) capable of forming with a flavivirus ssRNA genome containing SEQ ID NO: 3, a heteroduplex structure characterized by a temperature of dissociation of at least 45°C. The prior art The Examiner relies on the following prior art references to show unpatentability: Summerton et al., Morpholino antisense oligomers: design, preparation and properties, 7(3) ANTISENSE NUCLEIC ACID DRUG DEV 187- 195 (1997). Appeal 2009-013446 Application 10/913,996 3 Raviprakash et al., Inhibition of Dengue Virus by Novel, Modified Antisense Oligonucleotides, 69(1) J. VIROLOGY 69-74 (1995). Khromykh et al., Essential Role of Cyclization Sequences in Flavivirus RNA Replication, 75(14) J. VIROLOGY 6719-6728 (2001). The issue The Examiner rejected claims 17, 27, and 30 under 35 U.S.C. § 103(a) as obvious over Summerton, Raviprakash, and Khromykh (Ans. 3-6). The Examiner finds that “Raviprakash et al. teaches inhibition of flavivirus using antisense oligomers targeted to 3’ regions essential for replication, Summerton et al. teaches improved antisense oligomers using morpholino subunits, and Khromykh et al. teaches sequences essential for RNA replication and conserved among flavivirus” (Ans. 5). The Examiner then concludes that the ordinary artisan “would have been motivated to combine the morpholino antisense oligomers of Summerton et al., the flaviviral sequence targets ‘containing’ or comprising SEQ ID NO:3 and ‘having’ or comprising SEQ ID NO:22 in light of the teachings of Raviprakash et al. and Khromykh et al.” (Ans. 5). Appellants argue that “Raviprakash et al. suggests that the antisense oligonucleotides found to inhibit flavivirus replication ‘probably function via an RNase H cleavage of the oligonucleotide:RNA heteroduplex.’” (App. Br. 7). Appellants argue that the “Summerton et al. reference, disclosing a morpholino oligonucleotide that is stated to act through an RNase H independent mechanism, would therefore not be a logical starting point in the solution of this problem” (App. Br. 7). Appeal 2009-013446 Application 10/913,996 4 Appellants argue that “the prior art teaches away from the morpholino oligonucleotide compound selected as the starting point for the presently claimed invention, by suggesting that the oligonucleotide must be able to promote RNase H-dependent RNA cleavage in order to be effective in viral inhibition” (App. Br. 7). Appellants argue that “based on the Raviprakash et al. reference, one skilled in the art would have been led not to a cyclization sequence as a logical target, but to a target region spanning the translation initiation region” (App. Br. 8). In view of these conflicting positions, we frame the obviousness issue before us as follows: Have Appellants demonstrated that the Examiner erred in concluding that it would have been obvious to synthesize an antisense oligonucleotide composed of morpholino and phosphorus linkages which comprises a sequence complementary to SEQ ID NO: 3? Findings of Fact (FF) 1. Summerton teaches “the design, preparation, and properties of Morpholino oligos, a novel antisense structural type that solves the sequence specificity problem and provides high and predictable activity in cells” (Summerton 187, abstract). 2. Summerton teaches that “consideration of cost and ease of synthesis, chemical stability, aqueous solubility, and affinity and homogeneity of binding to RNA led us to focus on the phosphorodiamidite shown in Figure 2 as our principle [sic] linkage type for oligos targeted against single-stranded RNA sequences” (Summerton 189, col. 1). Appeal 2009-013446 Application 10/913,996 5 3. Summerton teaches that “Morpholino phosphorodiamidate oligos of the type shown in Figure 2 are immune to a wide range of nucleases” (Summerton 190, col. 1 to 2). 4. Summerton teaches that “antisense oligos can be easily delivered into cultured cells simply by passaging anchorage-dependent cells by the common procedure of scraping with a rubber policemen. This has been shown to achieve significant oligo entry into the cytosolic compartment” (Summerton 193, col. 2). 5. Summerton teaches that “a Morpholino oligo 25 subunits in length, in both the presence and absence of RNase H, inhibits its targeted mRNA somewhat better than the corresponding S-DNA oligo in the presence of added RNase H” (Summerton 190, col. 2). 6. Summerton teaches that the RNA/Morpholino melting temperature is 81.3°C (see Summerton 190, Table 1). 7. Raviprakash teaches that “[d]engue virus, a member of the flavivirus family, causes one of the major infectious diseases in the tropical regions of the world” (Raviprakash 69, col. 1). 8. Raviprakash teaches “significant inhibition of dengue virus type 2 in cells microinjected with antisense PS oligonucleotides containing C-5 propyne-substituted uridines and cytidines” (Raviprakash 69, col. 2). 9. Raviprakash teaches that in “determining the regions for selection as targets for antisense oligonucleotides, we considered (i) the predicted local secondary structure for dengue virus RNA as analyzed by the Fold program . . . and (ii) the pyrimidine content of the sequence” (Raviprakash 73, col. 2). Appeal 2009-013446 Application 10/913,996 6 10. Raviprakash teaches that: [w]e chose five different target regions: the 5’ antisense oligonucleotide spanned the translation initiation region, including the last residue of the initiating methionine codon; the NS5a and NS5b antisense oligonucleotides targeted two different regions of the NS-5 gene, which presumably codes for the RNA-dependent RNA polymerase; and the 3’a and 3’b antisense oligonucleotides targeted sequences in the 3’ untranslated region. (Raviprakash 73, col. 2). 11. Raviprakash teaches that the “data presented here show that although both the 5’-AS and 3’b-AS oligonucleotides . . . resulted in significantly less viral replication than the controls, at the lower 0.1 µM concentration the 5’-AS oligonucleotide appeared to be more effective” (Raviprakash 74, col. 1). 12. Raviprakash teaches that the “3’a oligonucleotide, whose target is only 100 bases upstream of the 3’b target, shows limited efficacy. These differences are probably a reflection of the complex secondary structures presented by the large (>10-kb) dengue virus RNA” (Raviprakash 74, col. 1). 13. Khromykh teaches that “[o]ur results with the KUN replicon establish the essential role of both the 5’ and 3’ CS in replication” (Khromykh 6726, col. 1). 14. Khromykh teaches that “the results obtained by mutation analysis with the KUN replicon unequivocally establish the essential requirement of complementary CS in the 5’ region and 3’ UTR for replication in vivo. Because of the conservation of these motifs, the results Appeal 2009-013446 Application 10/913,996 7 can be extrapolated to other mosquito-borne flaviviruses” (Khromykh 6727, col. 1). 15. Figure 1, panel C of Khromykh is reproduced below: “FIG. 1. Computer-generated secondary-structure analysis of the interaction between the genomic plus-strand RNA at the 5’ and 3’ ends for four Appeal 2009-013446 Application 10/913,996 8 mosquito-borne flaviviruses. . . . The conserved putative CS are boxed.” (Khromykh 6721). 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) (“[T]he examiner bears the initial burden, on review of the prior art or on any other ground, of presenting a prima facie case of unpatentability.”). “[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 v. Teleflex Inc., 550 U.S. 398, 418 (2007). “To differentiate between proper and improper applications of ‘obvious to try,’ this court outlined two classes of situations where ‘obvious to try’ is erroneously equated with obviousness under § 103. In the first class of cases, what would have been ‘obvious to try’ would have been to vary all parameters or try each of numerous possible choices until one possibly arrived at a successful result, where the prior art gave either no indication of which parameters were critical or no direction as to which of many possible choices is likely to be successful.” In re Kubin, 561 F.3d 1351, 1359 (Fed. Cir. 2009) (citing In re O’Farrell, 853 F.2d 894, 903 (Fed. Cir. 1988)). Analysis Summerton teaches morpholino antisense oligonucleotides which comprise phosphorus-containing intersubunit linkages, are nuclease Appeal 2009-013446 Application 10/913,996 9 resistant, capable of uptake by virus-infected animal cells, contain between 8 and 40 nucleotides and have Tm values greater than 45°C (FF 1-6). Raviprakash teaches antisense oligonucleotides directed to flaviviruses (FF 7-11). Raviprakash found that the “3’a oligonucleotide, whose target is only 100 bases upstream of the 3’b target, shows limited efficacy. These differences are probably a reflection of the complex secondary structures presented by the large (>10-kb) dengue virus RNA” (Raviprakash 74, col. 1; FF 12). Khromykh, while not an antisense reference, teaches that the cyclization sequence is essential for flavivirus replication (FF 13-14). The Examiner finds that the ordinary artisan would have had a reasonable expectation of success since “Raviprakash et al. teaches use of antisense oligomers for inhibiting flavivirus, Summerton et al. teaches improvement of antisense technology through use of morpholino subunits for antisense oligomers, and Khromykh et al. teaches essential sequences conserved among flavivirus nucleotide sequences” (Ans. 5-6). Appellants argue that “since Khromykh did not demonstrate the ability of antisense compounds directed against a cyclization sequence to inhibit viral replication, it is not predictable that an antisense compound would have the same effect as a mutation created in this region” (App. Br. 8). We find that Appellants have the better position in this very close case. While Khromykh’s results suggest the criticality of the cyclization sequence (FF 13-14), on this particularized set of facts, we do not agree with Appeal 2009-013446 Application 10/913,996 10 the Examiner that there was a reasonable expectation of success in selecting the cyclization sequence as an antisense target. The cyclization sequence is shown by Khromykh as being present in a region of secondary structure (FF 15). Raviprakash teaches that the oligonucleotide 3’a had limited efficacy because it was located in a region with secondary structure (FF 12). We conclude that selection of cyclization sequences for anti-flaviviral antisense compounds was not predictable or simply the result of routine experimentation. In Kubin, the court made clear that “where a defendant merely throws metaphorical darts at a board filled with combinatorial prior art possibilities, courts should not succumb to hindsight claims of obviousness.” Kubin, 561 F.3d at 1359. While the Examiner’s case is better than the situation outlined in Kubin, with Khromykh’s direction towards the cyclization sequence region, the rejection is significantly weakened by Raviprakash’s direct teaching that secondary structural regions, such as those in which Khromykh’s cyclization sequences are found, limit antisense efficacy (FF 12, 15). Unlike Kubin, where performing the detailed methodology of cloning would necessarily result in obtaining a molecule within the genus of nucleic acids being claimed, there was no predictable expectation that selecting an antisense oligonucleotide in a region of secondary structure in the flaviviral genome would predictably, or even likely, result in a compound capable of inhibiting flavivirus. The instant situation fits O'Farrell’s second kind of error, since the prior art of Summerton and Raviprakash provide general guidance regarding morpholino antisense to flavivirus, but do not identify Appeal 2009-013446 Application 10/913,996 11 the specific sequence of SEQ ID NO: 3 as an antisense target, as required by claim 17. Khromykh also does not identify SEQ ID NO: 3 as an antisense target. While Khromykh’s teaching of the criticality of the cyclization sequence might represent a promising field of experimentation for antisense, Raviprakash’s teaching that regions of secondary structure, where cyclization sequences are found, have limited efficacy in antisense inhibition, renders selection of the cyclization sequences as unpredictable (FF 12). Conclusion of Law Appellants have demonstrated that the Examiner erred in concluding that it would have been obvious to synthesize an antisense oligonucleotide composed of morpholino and phosphorus linkages which comprises a sequence complementary to SEQ ID NO: 3. SUMMARY In summary, we reverse the rejection of claims 17, 27, and 30 under 35 U.S.C. § 103(a) over Summerton, Raviprakash, and Khromykh. REVERSED alw SEED INTELLECTUAL PROPERTY LAW GROUP, PLLC 701 FIFTH AVE SUITE 5400 SEATTLE, WA 98104