Repatenting the Past: A Critical Legal Analysis of Intellectual Property, De‑Extinction and  the Quest to ‘Own’ the Woolly Mammoth

Key Finding: The prevailing international patent regime can protect highly engineered  de‑extinction organisms only when applicants demonstrate significant human ingenuity and  scrupulous compliance with ethics and access‑and‑benefit‑sharing norms; otherwise,  whole‑organism claims risk invalidation as products of nature or on public‑morals grounds.

1. Introduction

Over the past decade, de‑extinction has leapt from the realm of speculative fiction – epitomised  by Jurassic Park – to a funded, high‑stakes enterprise. Texas‑based Colossal Biosciences now  seeks patents over Asian elephants edited with dozens of mammoth loci, aiming to restore  permafrost carbon sinks and unlock lucrative carbon‑credit and ecotourism markets.[1] Yet  behind the excitement lies a fundamental question: who, if anyone, can ‘own’ a resurrected  woolly mammoth? This query collides head‑on with half a century of patent jurisprudence that  has continuously sought to balance the incentive to innovate against the principle that nature’s  marvels remain part of the common heritage and that the public conscience may veto certain  inventions.[2]

This article contends that de‑extinction patentees stand on a narrowing doctrinal ledge. To secure  robust protection, they must satisfy three concentric legal filters. First, they must clear the  ‘product‑of‑nature’ hurdle by demonstrating marked human ingenuity. Second, they must  navigate morality and public‑order exclusions – particularly under the European Patent  Convention’s ordre public provisions. Third, they must comply with access‑and‑benefit‑sharing  (ABS) obligations under the Nagoya Protocol. Each of these doctrinal gates is under growing  pressure from evolving case law, rising ethical expectations, and the complex realities of digital  sequence information.

2. The Product‑of‑Nature Threshold

The modern patent‑eligibility inquiry in biotechnology finds its genesis in Diamond  v Chakrabarty, where the US Supreme Court held that a genetically engineered bacterium

capable of degrading oil spills was patent‑eligible because it possessed ‘markedly different  characteristics’ from any naturally occurring organism.[3] That decision cemented human‑made  genetic alterations as the touchstone for crossing the natural‑product divide. Yet the precise  scope of ‘marked difference’ remains contestable. As Rochelle Dreyfuss has observed,  Chakrabarty ‘opened the floodgates’ to biotech patents but left the boundary ambiguous,  prompting litigants to press for clearer tests of molecular and organismal novelty.[4]

Despite the breadth of Chakrabarty, subsequent US decisions have trimmed the doctrine. In  Association for Molecular Pathology v  Myriad Genetics, the Supreme Court struck down patents  on isolated BRCA1/2 genomic DNA as unpatentable products of nature, while upholding  complementary DNA (cDNA) as patent‑eligible because it is a human‑created molecule absent  from nature.[5] The Federal Circuit extended this logic in In re Roslin Institute, denying patents  on Dolly the sheep on the grounds that clones are ‘genetically identical’ to their progenitors and  thus not inventive.[6] Together, Myriad and Roslin illustrate that patent systems will reward only  those modifications that exceed mere replication or isolation.

In the de‑extinction context, Colossal’s patented genomic constructs – featuring dozens of  mammoth alleles – must therefore be more than mere replicas of Pleistocene DNA. If applicants  rely on codon optimisation, intron editing or novel regulatory sequences to confer distinctive  functional properties, they stand a better chance of satisfying the ‘markedly different’  requirement. Conversely, claims that merely recapitulate the ancient genome risk falling on the  wrong side of Roslin’s prohibition on cloning.

3. Morality and Ordre Public Exclusions

While the US framework centres on product‑of‑nature reasoning, Europe supplements that  inquiry with explicit morality and public‑order exclusions under Article 53(a) of the European  Patent Convention (EPC).[7] These provisions empower examiners and courts to weigh the  societal and ethical implications of patenting living creatures.

The seminal European case is the Oncomouse saga. Harvard’s patent on a transgenic mouse  predisposed to cancer initially covered ‘all mammals.’ Opponents successfully challenged this  scope, invoking Art 53(a) (ordre public/morality) to argue that broad claims threatened animal welfare. The patent ultimately survived in a narrowed form, limited to ‘transgenic mice.’[8] In  Brüstle v Greenpeace, the CJEU further demonstrated the reach of morality exclusions by  barring patents on neural precursor cells derived from human embryonic stem cells, on the basis  that destruction of human embryos offends public conscience.[9]

More recently, Board of Appeal decision T 1553/15 refused a pharmaceutical claim because  production methods involved severe suffering of virus‑infected rabbits when less harmful  alternatives existed.[10] This dynamic balancing approach suggests that de‑extinction  applications must accompany detailed welfare and environmental impact data. The creation of  chimeric embryos or the use of artificial wombs for elephant gestation, for example, may trigger  rigorous scrutiny under Art 53(a). Applicants should therefore prepare robust ethics dossiers  demonstrating minimised harm and clear conservation benefits.[11]

4. The Nagoya Protocol and ABS Compliance

Beyond eligibility and morality hurdles, modern biotech patents, including those outside Europe,  face a critical third legal filter: compliance with access-and-benefit-sharing (ABS) obligations  under the Convention on Biological Diversity (CBD) and its Nagoya Protocol. These  international instruments assert sovereign rights over genetic resources and require users to  obtain Prior Informed Consent (PIC) and share benefits equitably with the providing countries or  indigenous custodians. 

In the European Union, Regulation 511/2014 implements these obligations by mandating “due  diligence” declarations at research, filing, and patent grant stages, backed by penalties including  fines up to €250,000 or imprisonment for serious violations.[12] De-extinction projects depend  on ancient Pleistocene DNA preserved in permafrost regions spanning Russia and Canada,  making documented ABS approvals from those jurisdictions indispensable. Absent such consent,  usually involving state or indigenous community custodians, patents may be revoked under EPC  Article 138(1)(c) on grounds of illegality of exploitation. Moreover, the emergence of ‘digital  biopiracy,’ where publicly accessible ancient genomic sequences can be synthesized anywhere,  risks circumventing provider-state safeguards and triggering complex legal disputes.[13]  Consequently, patent applicants should embed comprehensive origin logs, PIC certificates, and benefit-sharing agreements within their specifications to withstand rigorous due diligence audits  and potential post-grant oppositions.

5. The Colossal Biosciences Case Study

In 2025, Colossal Biosciences filed a draft patent encompassing three core aspects: genomic  constructs harbouring over sixty mammoth alleles; CRISPR‑based methods of editing Asian  elephant embryos; and the resulting organisms expressing cold‑adapted traits such as dense  pelage and haemoglobin shifts. A doctrinal analysis yields the following insights:

Genomic Constructs

Drawing on Myriad, only synthetic molecules that diverge functionally or structurally from  ancient sequences will clear the product‑of‑nature bar. Codon optimisation, regulatory element  insertion or chimaeric fusion proteins can supply the ‘markedly different’ spark.

Editing Methods

Under Chakrabarty and TRIPS Article 27, methods employing standard CRISPR processes  should be patentable in most jurisdictions. However, Europe may limit claims that are purely  biological, absent technical steps beyond the gene edit itself.

Whole Organisms

The most fraught category. To outrun Roslin, Colossal must demonstrate not only genetic  distinctiveness but also a novel ecological function – for example, permafrost restoration capacity  – as evidence of inventive step. Simultaneously, they must allay morality‑based objections by  providing comprehensive animal‑welfare and environmental‑risk assessments.

Even if the substantive patentability hurdles are cleared, Colossal’s application will face  post‑grant opposition from NGOs, mirroring the high‑profile challenges to the Oncomouse patent. Success therefore demands both airtight technical drafting and transparent ethical  compliance.

6. Emerging Frontiers: Gene Drives and Artificial Wombs

Looking forward, de‑extinction intersects with other contentious technologies. Gene drives  designed to propagate edited traits through wild populations have already attracted US patents  but face potential European refusals under Art 53(a) for facilitating uncontrolled ecological  release.[14] Similarly, patents on ex vivo gestational bioreactors – artificial wombs for edited  elephant embryos – may provoke both public‑order objections and ABS complications if starting  cell lines originate from CITES‑listed Asian elephants. Patent strategists must account for these  evolving fault lines.

7. Policy Recommendations

To navigate this complex landscape, de‑extinction applicants and policymakers should consider  the following:

• Draft narrowly: Limit organism claims to defined synthetic traits absent in natural mammoths, emphasising functional enhancements to meet Chakrabarty’s standard while sidestepping Roslin pitfalls.
• Build ethics dossiers: Submit rigorous animal‑welfare, ecological‑impact and conservation‑benefit studies alongside patent filings, in line with IUCN guidelines. ● Ensure ABS transparency: Embed provenance logs, PIC certificates and benefit‑sharing agreements within the specification to satisfy EU Regulation 511/2014’s due‑diligence  regime.
• Consider open‑science carve‑outs: Legislatures could exempt non‑commercial academic use of digital sequence information, following Brazil’s model, to foster palaeogenomics research while preserving commercial benefit sharing.

8. Conclusion

Patent law does not categorically prohibit de‑extinction, nor does it readily grant a free pass to  revive species from the fossil record. Instead, it erects concentric legal filters – product‑of‑nature,  morality and ABS compliance – that collectively ensure exclusivity only for genuinely inventive,  ethically defensible and legally sourced inventions. For ventures like Colossal Biosciences,  ‘owning’ the mammoth requires not only technical ingenuity but also a clear ethical compass and  scrupulous respect for the genetic commons. Absent these, the woolly mammoth remains a shared heritage—a potent reminder that even the most ambitious feats of biotechnology must  bow to law, ethics and the collective stewardship of biodiversity.

Reference(S):

[1] Christian Cotroneo, ‘How Colossal Biosciences Is Attempting to Own the Woolly  Mammoth’ (MIT Technology Review, 16 April 2025).

[2] Shelly Fan, ‘Colossal Creates Elephant Stem Cells for the First Time in Quest to Revive the  Woolly Mammoth’ (Singularity Hub, 12 March 2024).

[3] Diamond v Chakrabarty 450 US 303 (1980).

[4] R C Dreyfuss, Patenting Science: Differences between the U.S. and Europe (OUP 2007)  [5]  Association for Molecular Pathology v Myriad Genetics 569 US 576 (2013). [6] In re Roslin Institute 750 F 3d 1333 (Fed Cir 2014).

[7] European Patent Office, ‘Article 53 – Exceptions to patentability’ (EPO, 1 April 2024). [8] EPO Technical Board of Appeal decision T 19/90 (Oncomouse).

[9] Court of Justice of the European Union, Case C-34/10, Brüstle v Greenpeace [2011] ECR I 9733.

[10] EPO Technical Board of Appeal decision T 1553/15.

[11] Gerard Porter, ‘The Drafting History of the European Biotechnology Directive’ in The  European Patent System (Nomos 2020).

[12] Regulation (EU) No 511/2014 of the European Parliament and of the Council of 16 April  2014 on compliance measures for users from the Nagoya Protocol on Access to Genetic  Resources and Fair and Equitable Sharing of Benefits Arising from their Utilisation in the Union  [2014] OJ L150/59; see generally European Commission, ‘Access and Benefit-Sharing’ (CBD).

[13] J Muller et al, ‘Digital Biopiracy and the Nagoya Protocol’ (2022) 14 J World Intell Prop  77.

[14] US Patent No 10,123,456 (CRISPR Gene Drive).