Commissioned by Science Gallery, Dublin for Grow Your Own… Life After Nature, October 24 2013–January 19 2014.
Can we ‘preserve’ by looking forward? The sixth great extinction event in the history of biology is underway, and we humans may be its cause.
While conservationists struggle to protect existing ‘natural’ species and reverse the effects of the Anthropocene (the human epoch), synthetic biologists are busy designing new organisms for the ‘benefit of humanity’. What might the ‘wilds’ look like in a synthetic biological future?
Designing for the Sixth Extinction investigates synthetic biology’s potential impact on biodiversity and conservation. Could we tolerate ‘rewilding’ — the conservation movement that lets nature take control — using synthetic biology to make nature ‘better’? Letting synthetic biodiversity loose to save the ‘nature’ that we idealise would disrupt existing conventions of preservation.
In this version of the future, novel companion species designed by synthetic biologists support endangered natural species and ecosystems. Financed by corporate biodiversity offset schemes, patented species are released into the wild. They compensate for biodiversity lost due to widespread monoculture farming of biomass for biofuel and chemical production. For a thriving bioeconomy, the preservation of natural biodiversity is worthwhile not just for sentimental reasons, it is also a valuable DNA library for future biological designs.
Modeled on fungus, bacteria, invertebrates and mammals, the designed species are ecological machines that fill the void left by vanished organisms, or offer novel protection against more harmful invasive species, diseases and pollution.
Constructed using an expanded DNA code that produces non-biodegradable proteins, the synthetic biodiversity is hardy in the face of wild predators that have not yet evolved to eat and digest them. They operate in enclosed ecosystems, the outcome of decades of political negotiation and compromise around biosafety and release.
Designed organisms used to maintain or revive disappearing ecosystems would demand a relaxed attitude to biological control, risk and ownership. The taxonomic status of organisms that are technologically isolated with no purpose except to save others is also uncertain. Are they even ‘alive’? If nature is totally industrialized for the benefit of society—which for some is the logical endpoint of synthetic biology — will nature still exist for us to save?
CONCEPT AND DESIGN
Alexandra Daisy Ginsberg
ADDITIONAL RESEARCH AND DESIGN
Victor Papanek: The Politics of Design, Vitra Design Museum
7th Moscow International Biennale of Contemporary Art, New Tretyakov Gallery
Beauty, Cooper Hewitt Design Triennial
Designs of the Year 2015, Design Museum
Globale: Exo-Evolution, ZKM | Center for Art and Media Karlsruhe
What Design Can Do, Stedelijk Museum
Istanbul Design Biennale 2014
Grow Your Own..., Science Gallery, Dublin
Rewilding with Synthetic Biology. Lightbox with colour transparency, 150cm × 225cm.
Convergent and divergent interests in biodiversity.
Installation view, Stedelijk Museum, 2015. Lightbox with colour transparency, accompanied by models, timeline, prints and fictional patent applications for four organisms. Photograph: Gert Jan van Rooij.
Detail from "Rewilding with Synthetic Biology"
MOBILE BIOREMEDIATION UNIT
The present invention relates to a biologically-powered mobile soil bioremediation device with pH sensing and display capabilities.
Statement of Invention:
The device is a soil bioremediation unit that neutralises high soil acid levels caused by pollution. The chassis is designed to disturb the topsoil as it moves. Outlets on its lower surface disperse an alkali hygroscopic fluid. Disributed pH sensors are linked to colourchanging display nodes on the upper surface, which switch from yellow to red in acidic pH areas. The device is programmed to move towards acid soils. Designed with two extra bases in its DNA, it is indigestible to natural biodiversity to promote biosafety and prevent horizontal gene transfer. The unit can produce up to ten copies. A genetic killswitch limits the device to a twenty-eight day functional lifespan.
1. Display node (red – acid)
2. Display node (yellow – alkali)
3. Alkali hygroscopic fluid
4. Soil agitator ridges
5. pH sensors
6. Fluid outlets
Installation view, Stedelijk Museum, 2015. Mobile Bioremediation Unit models. Photograph: Gert Jan van Rooij.
AUTONOMOUS SEED DISPERSER
The present invention relates to a roving seed dispersal device that increases local plant biodiversity.
Statement of Invention:
The autonomous device has a specially designed surface that collects and disperses seeds from local plant species. The precision distribution of coarse hairs interspersed with flexible rubberised spines enables maximum aggregation and distribution. The movement of the chassis induces flexing of the spines to release collected seeds, which are then pressed into the soil. The device is programmed using a 6-base DNA code that builds the chassis out of inedible synthetic proteins to prevent consumption by natural species. Power is generated by waste processing of proprietary devices including Mobile Bioremediation Units. Reproduction is programmed to 5 copies per unit, and lifespan limited via killswitch to 600 days.
1. Flexible rubberised spines
2. Spines sweep up seeds
3. Seed-trapping hairs
4. Seed tramplers
5. Spines relax to release seeds
SELF-INFLATING ANTIPATHOGENIC MEMBRANE PUMP
The present invention relates to a synthetic biological device used to treat the infection that causes Sudden Oak Death.
Statement of Invention:
The single-use device is distributed via spores to establish filamentous networks within oak trees. A proprietary biochemical sensor activates the dormant network on detection of infection. A two-part diaphragm pump self-assembles with an inner and outer chamber. The self-inflating outer chamber surface is distributed with non-return valves to permit the ingress of air. The inner chamber produces an antipathogenic serum. At full inflation, the membrane pump pushes serum into the infection site. Post-injection, the pump deflates, decouples, and spores are released. The device operates using a 6-base DNA code that produces synthetic materials, to prevent ingestion by natural organisms. Biological waste is managed by the proprietary Autonomous Seed Disperser.
BIOAEROSOL MICROTRAPPING BIOFILM
The present invention relates to a self-replicating biofilm that traps airborne pollutants and harmful biological matter including virus particles, bacteria and fungal spores.
Statement of Invention:
The self-replicating biofilm coats leaf surfaces to provide maximum surface area to trap and secure harmful airborne particles that cause damage to biodiversity, e.g. Chalara fraxinea fungal spores responsible for ash dieback. The underlying leaf surface continues to function normally due to regular spacing between the biofilm nodes. Any trapped matter is safely discarded with the leaf when it is shedded by the tree in autumn. This biowaste is collected and processed by the Mobile Bioremediation Unit as part of our proprietary 6-base DNA Closed Synthetic Ecosystem technology.
1. Biofilm colonisation
2. Bioaerosol particle trapping
3. Shedded leaf with bioaerosols secured
4. Closed-loop waste management