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타겟 유전자 편집: How the Patent Dispute has Transformed Science Innovation

Cyagen Technical Content Team | September 11, 2019
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https://www.cyagen.kr/community/technical-bulletin/crispr-cas9-patent.html
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01 유전자 편집 특허 동향 및 분쟁의 역사 02 유전자 편집 지적재산권 및 라이선싱 구조 개요 03 상용 연구개발에서 유전자 편집 기술의 리스크 04 기존 유전자 표적 기술 개선으로 유전자 편집의 한계 극복 05 참고 문헌

As 타겟 유전자 편집-based innovations begin to move into clinical testing and the dispute over core patents continues worldwide, 타겟 유전자 편집 gene editing has been under increased scrutiny in both commercial and academic sectors. The complexity of the patent licensing landscape has considerable implications for companies seeking to commercialize 타겟 유전자 편집 technologies. Researchers in academia are also experiencing an increased requirement for assays validating the precision of 타겟 유전자 편집-based animal models – with grant reviewers expressing similar concerns for off-target effects. Herein, we provide an overview of the 타겟 유전자 편집 patent landscape and uncover how the development of 타겟 유전자 편집 technology has transformed the scientific environment for researchers across academia and commercial research and development (R&D) worldwide.

유전자 편집 특허 동향 및 분쟁의 역사

In May 2012, the University of California, Berkeley (UCB) filed a patent application on behalf of Jennifer Doudna and Emmanuelle Charpentier groundbreaking observations that the bacterial 타겟 유전자 편집 gene-editing system could be reprogrammed at the guide RNAs to target different DNA sequences. In December of the same year, the Broad Institute (with collaborators from MIT and Harvard University) also filed a patent application covering the 타겟 유전자 편집 gene editing technology’s applications in eukaryotic cells for Zhang Feng and his colleagues. Broad requested an “accelerated examination” of its application that sped up the United States Patent and Trademark Office (USPTO) review process. Despite filing after UCB, the Broad US patent (8,697,359) was issued in April 2014 – initiating the dispute over patent rights that continues today.

UCB quickly took action to request a patent interference hearing, which was approved by the US Patent and Trademark Office's Patent Trial and Appeal Board (PTAB) in December 2015. In February 2017, the PTAB three-judge panel made the first ruling that the Broad’s innovations were distinctly patentable subject matter from the UCB patent filings. This decision was upheld in September 2018 by the US Court of Appeals for the Federal Circuit: securing the US position that Broad’s claims are all limited to 타겟 유전자 편집 systems in a eukaryotic environment. Interestingly, on June 24, 2019, the PTAB initiated a new interference process that challenges the validity of UCB’s eukaryotic claims – designating UCB as the Junior Party, who will carry the burden of proof.6

유전자 편집 지적재산권 및 라이선싱 구조 개요

The rights to use 타겟 유전자 편집-based gene editing is divided into three primary fields of use:

  1. Noncommercial research
  2. Development of tool kits, reagents, and equipment
  3. Development, sale, and use of therapeutics using 타겟 유전자 편집

The main patent owners of 타겟 유전자 편집 have granted exclusive rights to private spin-off companies that can seek investments to develop 타겟 유전자 편집 applications.3 This enables these companies to negotiate individual licenses to third parties depending on the application. The Broad Institute, Harvard, and MIT have licensed their patents to Editas Medicine as part of this ‘inclusive innovation’ model. While Editas Medicine retains the right to exclusively use 타겟 유전자 편집 technology to develop genomic medicines for targets of interest, other companies may apply to license some of its intellectual property (IP) to target genes of interest that Editas is not pursuing. A general overview of the 타겟 유전자 편집 licensing landscape as of February 2019 is provided below:

유전자 편집 라이선싱 동향 개요

In February 2019, the Life Science business of Merck KGaA, Darmstadt, Germany, which operates in the U.S. and Canada under the name MilliporeSigma, was granted the first U.S. Patent for an improved 타겟 유전자 편집 genome-editing method. Its 타겟 유전자 편집 patent portfolio covers foundational and alternative genome-editing methods and includes granted patents in Australia, Canada, Europe, Singapore, China, Israel, and South Korea.5 By July 2019, Merck and the Broad Institute announced an agreement for granting non-exclusive licenses to 타겟 유전자 편집-based IP for use in commercial research and product development. The licensing framework is consistent with the Broad Institute’s long-standing practices – MilliporeSigma’s 타겟 유전자 편집 IP “will become available royalty-free to non-profit academic institutions, non-profit business communities, and governmental agencies for their internal research”.1 Licensing will follow the ethical considerations of both the Broad and MilliporeSigma, thereby excluding certain applications of 타겟 유전자 편집 technology. To work around these restrictions, each entity may continue offering licenses independently of this agreement.

상용 연구개발에서 유전자 편집 기술의 리스크

In 2019, the nature of the 타겟 유전자 편집 patent landscape continues to become more complicated as global patent offices rule differently on various claims – providing more uncertainty for commercial applications of the technology. 타겟 유전자 편집 patent analytics data from IPStudies reveal a total of 3800+ patent families and 110+ licensing agreements as of February 2019, with an average publication of roughly 200 patent families each month. Developments are also occurring more rapidly in the licensing of 타겟 유전자 편집 technology, “with more than 40 public announcements in 2018 (an increase of more than 50% over the former past three years), following the granting and/or consolidation of several pioneering patents in Europe and the USA”.2 With the ongoing dispute over the 타겟 유전자 편집 core patents - and thousands of pending patent applications based on the same – it remains extremely challenging for companies to obtain effective authorization to commercialize 타겟 유전자 편집-based innovations on the global stage.

As a direct consequence of the surrogate licensing model (across specific application areas) and the unresolved claims to the core IP, there are significant risks to both commercial entities and academics seeking to utilize the technology. These risks may only increase as more patents are granted: individual claims will become narrower and harder to enforce as the global 타겟 유전자 편집 IP landscape becomes increasingly complex. The protections afforded by the licenses granted thus far remain unclear as the ongoing legal dispute is underway. Even Broad has declared that “this is a complex patent and licensing landscape that threatens innovation” - calling UCB to join discussions for a coordinated licensing approach.6 In this context, the exploration of new genome editing methods with well-defined IP landscapes will become paramount for those seeking to develop new genomic medicines.

기존 유전자 표적 기술 개선으로 유전자 편집의 한계 극복

In terms of drug development, ​​타겟 유전자 편집 technology is most frequently used in the preparation of animal models which are used to accelerate research into diseases such as cancer and neurodegeneration – but additional gene modification techniques are available to address its limitations. Gene editing technologies used to generate animal models is largely divided into two types: 타겟 유전자 편집 and ES cell (ESC) mediated (a.k.a. traditional gene targeting). Given that ESC mediated gene targeting is not covered by any issued patents, the commercial improvement of traditional gene targeting has been unfettered, leading to the innovative TurboKnockout® gene targeting system.

Although 타겟 유전자 편집 technology is a rapid and flexible method for inducing mutations in vitro and in vivo, it has notable off-target risks that make it unsuitable for complex genetic modification projects. 타겟 유전자 편집-based models face challenges with generating precise point mutations: the particularly short guide RNA sequences that guide the associated nuclease can cause breaks to occur at unintended sites in the genome. Given their potential for off-target effects, 타겟 유전자 편집-based models often require whole-genome sequencing (WGS) to be performed prior to publication in leading journals. Those applying for grants often face the same concerns from reviewers – who may reject proposals using animal models generated using a 타겟 유전자 편집-based approach. Given that WGS is a high-cost test that often requires outsourcing, the advantages of 타겟 유전자 편집 may quickly be outweighed by the increasing demand for WGS to verify accuracy in every model used. Furthermore, the US National Institutes of Health (NIH) announced the Somatic Cell Genome Editing (SCGE) program in January 2018 to support improved assays for evaluating the potential adverse biological effects of genome-editing tools. An editorial featured in Nature Medicine in August 2018 reinforces the need for researchers to prioritize “monitor[ing] possible unintended DNA alteration due to 타겟 유전자 편집 in vivo … even as newer 타겟 유전자 편집 methods offer a way to edit the genome without making the double-stranded breaks that seem to pose the greatest risk of accidental effects”.4

Traditional gene targeting is accurate and free of off-target effects, enabling its use for generating complicated animal models; however, the main drawback of traditional gene targeting has been an extended turnaround time, with projects averaging 10-14 months. With the freedoms permitted by the simplified IP landscape related to ESC mediated gene targeting, recent innovations provide all the advantages of ESC mediated techniques while shortening turnaround time to be nearly on-par with 타겟 유전자 편집 projects. In 2015, Cyagen released a proprietary ESC mediated TurboKnockout® service that utilizes a super competent ES cell line, which generates 100% ESC-derived founder mice, alongside a self-deleting selection cassette, which eliminates the need to breed to Flp deleter mice. These innovations eliminate two generations of breeding, shortening production time by 4-6 months as compared to industry standard.  A comparison of 타겟 유전자 편집, traditional, and TurboKnockout® gene targeting methods for generating animal models are provided in the following table:

Comparison of Gene Targeting Technologies Used in Animal Model Generation

  TurboKnockout® 타겟 유전자 편집 Gene Targeting Traditional Gene Targeting
Turnaround time 6-8 months 5-7 months 10-14 months
Approach Homologous recombination in ESC by Cyagen’s TurboKnockout® technology 타겟 유전자 편집 nuclease mediated gene targeting by pronuclear injection Homologous recombination in ESC by traditional technology
Applications Conditional knockout
Large fragment knockin
Humanization
Global knockout
Point Mutation
Short fragment knockin
Conditional knockout
Large fragment knockin
Humanization
Potential off-target effects No Yes No
Self-deleting selection cassette Yes No No
Screening method PCR PCR + Sequencing PCR

 

TurboKnockout® is the gold standard for generating conditional knockout and knockin mouse models, featuring all of the benefits of both 타겟 유전자 편집- and ESC-based methods without any of the drawbacks. Whether you are developing a humanized mouse model or simply need to knockin large genomic fragments or cDNA, efficiency and specificity can be problematic. 타겟 유전자 편집 is severely limited by knockin fragment sizes and requires a minimum distance between loxP sites for conditional knockout – these constraints are eliminated with TurboKnockout® gene targeting. Cyagen’s TurboKnockout® service allows for large fragments to be easily knocked into specific endogenous loci with no off-target effects and guaranteed germ-line transmission, providing founders in only 6-8 months with a 100% money-back guarantee.

원스톱 마우스 모델 검색 플랫폼: MouseAtlas

MouseAtlas는 KO부터 인간화 마우스까지 유전자 및 제품 모델명 검색만으로 원하는 모델을 쉽게 찾을 수 있는 플랫폼입니다. 생체 마우스인지 정자 상태인지, 실시간 재고 상황, 검증 데이터, 상세 설명 등을 직관적으로 확인하고 바로 주문할 수 있습니다. 당사 내부 제품 관리 시스템과 연동되어 실시간으로 업데이트되며, 현재 39,000종 이상의 모델 마우스가 등록되어 있어 연구자들에게 매우 편리한 원스톱 솔루션을 제공합니다.

>> MouseAtlas에서 관심 유전자 검색하기

As the global 타겟 유전자 편집 patent landscape continues drastic growth, becoming increasingly unclear, the ability to effectively commercialize 타겟 유전자 편집-based innovations and perform research with 타겟 유전자 편집-based animal models has become increasingly precarious and costly. For pharmaceutical companies who care about patent issues, ES cell targeting technology remains the safest choice to completely avoid the risk of intellectual property disputes. Researchers have also experienced increased pressure - from both academia and federal agencies - to implement assays to evaluate adverse biological effects of 타겟 유전자 편집 tools: adding costly model validation procedures (such as WGS) that quickly mitigate the cost-effectiveness of 타겟 유전자 편집 models. As more assays are created to evaluate the potential effects of 타겟 유전자 편집 and corroborate the technology, the availability of alternative model generation methods will remain valuable assets for researchers seeking precise cell & animal models to accelerate their disease studies.

참고 문헌

  1. “Broad Institute, MilliporeSigma to Offer Non-Exclusive Licenses to 타겟 유전자 편집 IP.” Genetic Engineering & Biotechnology News. Mary Ann Liebert, Inc. publishers, July 23, 2019. https://www.genengnews.com/news/broad-institute-milliporesigma-to-offer-non-exclusive-licenses-to-crispr-ip/.
  2. “타겟 유전자 편집 Patent Analytics.” IPStudies, n.d. https://www.ipstudies.ch/crispr-patent-analytics/.
  3. Cynober, Timothé. “타겟 유전자 편집: One Patent to Rule Them All.” Labiotech.eu. Labiotech.eu, March 6, 2019. https://labiotech.eu/features/crispr-patent-dispute-licensing/.
  4. “Keep off-Target Effects in Focus.” Nature Medicine 24, no. 8 (August 6, 2018): 1081–81. https://doi.org/10.1038/s41591-018-0150-3.
  5. “Merck KGaA, Darmstadt, Germany Receives First U.S. Patent for Improved 타겟 유전자 편집 Genome-Editing Method.” U.S. Patent 타겟 유전자 편집 - News - Merck KGaA, Darmstadt, Germany. Merck KGaA, Darmstadt, Germany, February 19, 2019. https://www.emdgroup.com/en/news/first-us-patent-crispr-19-02-2019.html.
  6. “Statement and Background on 타겟 유전자 편집 Patent Process.” Broad Institute. Broad Communications, July 31, 2019. https://www.broadinstitute.org/crispr/journalists-statement-and-background-crispr-patent-process.
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