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A Sourcebook for the Worldwide Discovery of a Creative Organic Universe
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VIII. Earth Earns: An Open Participatory Earthropocene to Astropocene CoCreative Future

2. Second Genesis: Sentient LifeKinder Transitions to a New Intentional, BioGenetic Questiny

Loman, Nick. The Sequencing Singularity. nanoporetech.com/resource-centre/videos/sequencing-singularity. A half hour 2016 YouTube presentation by the University of Birmingham genetic bioinformatics researcher, which is also available on the Oxford Nanopore site. The phrase was first cited in a 2015 Nature Reviews Microbiology article above to express how novel human abilities are beginning to curate, edit, and author anew life’s informative code.

Sequencing is poised to disrupt clinical practice. Whole swathes of diagnostic tests may eventually be replaced with a single assay - sequencing - as we reach the "sequencing singularity". I will review recent advances in the use of nanopore sequencing for clinical microbiology and human genetics, including our collaborations on viral and bacterial diagnostic sequencing, real-time surveillance, direct RNA and human whole-genome sequencing, and discuss the opportunities and barriers around moving to sequencing as a routine test in the clinic.

Nick works as Professor of Microbial Genomics and Bioinformatics in the Institute for Microbiology and Infection at the University of Birmingham. His research explores the use of cutting-edge genomics and metagenomics approaches to the diagnosis, treatment and surveillance of infectious disease. Nick has so far used high-throughput sequencing to investigate outbreaks of important Gram-negative multi-drug resistant pathogens, and recently helped establish real-time genomic surveillance of Ebola in Guinea. His current work focuses on the development of novel sequencing and bioinformatics methods to aid the interpretation of genome and metagenome scale data generated in clinical and public health microbiology. (NL website)

Maharbiz, Michel. Synthetic Multicellularity. Trends in Cell Biology. 22/12, 2012. A University of California, Berkeley, computer engineer considers early explorations of how complex systems biology might be availed to commence the respectful creation of utile multicellular organisms. The motivation and standard of behavior for such endeavors would be their service toward a better, sustainable world for life and people. See also in this dedicated issue “Directed Cytoskeleton Self-Organization” by Timothee Vignaud, et al, which alludes to independent principles of organic form and vitality.

Concluding Remarks That this has profound ethical and societal consequences cannot be overstated. There is – perhaps controversially – an ultimately ecological rationale for this vision. For the most part, the technological base created by the industrial revolution communicates poorly with the underlying organic technology of the planet. The rapid expansion of man-made, acellular, resource-consuming, and waste-producing constructs is in large part responsible for the ecological and climactic mess we are in. Mindful of the vast ethical and societal questions raised, it is worth considering a future wherein our homes, our factories, and our consumer gadgets can ‘understand’ the language of organic systems around them and form part of a related or hybrid framework of information and material exchange. This notion – that our societal artifacts should be mindful of their natural surroundings – has long and deep roots in many cultures and has modern reflections in, for example, the natural building movements. It is my contention that the development of synthetic multicellular – and likely hybrid- systems is a step down this transformative road. (621-622)

The cytoskeleton architecture supports many cellular functions. Cytoskeleton networks form complex intracellular structures that vary during the cell cycle and between different cell types according to their physiological role. These structures result…, from the interplay between intrinsic self-organization properties and the conditions imposed by spatial boundaries. Along these boundaries, cytoskeleton filaments are anchored, repulsed, aligned, or reoriented. Such local effects can propagate alterations throughout the network and guide cytoskeleton assembly over relatively large distances. The experimental manipulation of spatial boundaries using microfabrication methods has revealed the underlying physical processes directing cytoskeleton self-organization. Here we review, step-by-step, from molecules to tissues, how the rules that govern assembly have been identified. We describe how complementary approaches, all based on controlling geometric conditions, from in vitro reconstruction to in vivo observation, shed new light on these fundamental organizing principles. (Vignaud Abstract)

Majumder, Sagardip and Allen Liu. Bottom-Up Synthetic Biology: Modular Design for Making Artificial Platelets. Physical Biology. 15/1, 2018. An article by University of Michigan bioengineers for a dedicated issue with the first title, edited. We quote the issue summary, which also applies to this paper. One could then reflect that in a cosmic genesis its natural evolutionary methods seem meant to pass to and be enhanced by our humankinder evolitionary phase.

Spatially organized cellular processes arise from the interactions of nanometer building blocks. These emergent behaviors cannot be understood by knowing the parts alone, but rather how they interact. A central challenge in cell biology is thus to understand how cellular processes are organized spatiotemporally from the component parts. One powerful approach in such quest is bottom-up cellular reconstitution as an attempt to recreate the complexity of cellular life. Many examples of bottom-up reconstitution have come from various cytoskeletal, molecular motors, and membrane trafficking systems and provide vivid demonstrations of large-scale biomimetic behaviors. In addition, the use of cell-free extracts provides an experimental platform for connecting genetic information to modifying component parts. This special issue highlights both current cellular reconstitution efforts from purified proteins as well as cell-free systems of DNA-programmed behaviors in artificial cells.

Maniscalco, Sabrina, et al. Quantum Network Medicine. arXiv:2206.12405. With a Rethinking Medicine with Network Science and Quantum Algorithms subtitle, seventeen University of Helsinki, Finnish Quantum Institute physicists, provide a thorough study of how these universe to human, original and manifest realms, could inform and integrate so as to form a palliative synthesis. See also Translational Quantum Machine Intelligence for Tumor Dynamics in Oncology at (2202.10919). A planatural philoSophia might trace an overall evolution whence an accumulated medical/health corpus is meant to be fed back to the fraught beings from whom it arose. Thus a self-cocreative genesis which heals, medicates, cures itself comes into view.

The emerging field of network medicine views ways to investigate disease pathogenesis, integrating information from relevant Omics databases, including protein-protein interaction, correlation-based, gene regulatory, and Bayesian networks. However, this requires analysing large amounts of data with an urgent need for powerful computation methods. At the microscopic level, drug-target chemistry simulation becomes a quantum problem, which needs a quantum solution. As we will discuss, quantum computing may be a key ingredient in enabling the full potential of network medicine. We propose to combine network medicine and quantum algorithms in a novel research field for a new era of disease prevention and drug design. (Excerpt)

Mu, Wenjing, et al. Superstructural ordering in self-sorting coacervate-based protocell networks. Nature Chemistry. February, 2024. Chinese Academy of Sciences, Beijing, Beijing University of Chemical Technology, and Centre for Protolife Research School of Chemistry, University of Bristol (Stephen Mann) researchers post initial array of approaches and techniques by which various synthetic organisms may be brought into being. But at this early stage of intentional procreation, any foray as this must have serious ethical, philosophic and commom guidance before going further.


Bottom-up assembly of higher-order cyto-mimetic systems capable of coordinated physical behaviours, collective chemical signalling and spatially integrated processing is a pathway toward an artificial multicellularity. Here we develop coacervate microdroplets that self-sort into protocell networks. The protocell superstructures exhibit macromolecular spatial enzyme/ribozyme biocatalysis and molecular translocation. These methodologies are a step towards the spontaneous orchestration of protocell models into artificial tissues and colonies with ordered architectures and collective functions. (Abstract)

Mukai, Takahito, et al. Rewriting the Genetic Code. Annual Review of Microbiology. 71/557, 2017. Biochemists Mukai, Markus Englert, and Dieter Soll, Yale University and Marc Lajoie, University of Washington broach how the latest techniques can facilitate and commence an epochal moment whence human acumen can begin anew to modify life’s evolutionary genomic script. Some article sections are Natural Expansion of the Genetic Code, Orthogonal Translation Systems, Codon Reassessment, and Preparing for Radically Altered Genetic Codes.

The genetic code—the language used by cells to translate their genomes into proteins that perform many cellular functions—is highly conserved throughout natural life. Rewriting the genetic code could lead to new biological functions such as expanding protein chemistries with noncanonical amino acids (ncAAs) and genetically isolating synthetic organisms from natural organisms and viruses. It has long been possible to transiently produce proteins bearing ncAAs, but stabilizing an expanded genetic code for sustained function in vivo requires an integrated approach: creating recoded genomes and introducing new translation machinery that function together without compromising viability or clashing with endogenous pathways. In this review, we discuss design considerations and technologies for expanding the genetic code. The knowledge obtained by rewriting the genetic code will deepen our understanding of how genomes are designed and how the canonical genetic code evolved. (Abstract)

Nicolaou, K. C. Organic Synthesis: The Art and Science of Replicating the Molecules of Living Nature and Creating Others like Them in the Laboratory. Proceedings of the Royal Society A. Online January, 2014. The renowned Rice University biochemist surveys the unlimited horizons for “synthetic and medicinal chemistry” to both heal the past creature phase, and begin a new material nature of immense benefit. Of course all respectful ethics have to be considered beforehand. And may one add that such activities which seem so open and inviting to us imply a real role as cosmic chemists and catalysts.

Synthetic organic chemists have the power to replicate some of the most intriguing molecules of living nature in the laboratory and apply their developed synthetic strategies and technologies to construct variations of them. Such molecules facilitate biology and medicine, as they often find uses as biological tools and drug candidates for clinical development. In addition, by employing sophisticated catalytic reactions and appropriately designed synthetic processes, they can synthesize not only the molecules of nature and their analogues, but also myriad other organic molecules for potential applications in many areas of science, technology and everyday life. After a short historical introduction, this article focuses on recent advances in the field of organic synthesis with demonstrative examples of total synthesis of complex bioactive molecules, natural or designed, from the author’s laboratories, and their impact on chemistry, biology and medicine. (Abstract)

Nielsen, Peter. A New Molecule of Life? Scientific American. December, 2008. The director of the Center for Biomolecular Recognition at the University of Copenhagen describes a synthetic hybrid of protein and DNA called peptide nucleic acid or PNA that combines genetic information storage with a protein-like stability.

Noshay, JaclEleven computational biologists at Oak Ridge Nayn, et al. Quantum biological insights into CRISPR-Cas9 sgRNA efficiency from explainable-AI driven feature engineering. Nucleic Acids Research. 51/19, 2023. Eleven computational biologists at Oak Ridge National Laboratory and the University of Tennessee explain a novel synthesis of these genetic editing abilities with quantum physical (organic) principles.

CRISPR-Cas9 tools have transformed genetic manipulation capabilities. While empirical rules have been developed for a range of model organisms, the basis for sgRNA efficiency remains poorly understood. Here we enter a novel feature set and a new public resource by way of quantum chemical tensors. We use the iterative AI model known as Random Forest (iRF) to encode attributes of position-specific sequences for Escherichia coli sgRNAs and identify traits for sgRNA design in bacterial species. We believe that these encodings can enhance our understanding of the quantum biological processes involved in the CRISPR-Cas9 machinery. (Abstract)

Ostrov, Nili, et al. Synthetic Genomes with Altered Genetic Codes. Current Opinion in Systems Biology. October, 2020. With sections such as Genetic codes that use unnatural codons, Altering the canonical triplet code, and more, Harvard Medical School geneticists including George Church post a latest survey about this epochal shift whence collective human intellect, with respectful observance, can begin a second ecosmic procreation. See also Technological Challenges and Milestones for Writing Genomes by Nili Ostrov, et al in Science (366/310, 2019).


The genetic code is the set of rules that define how information encoded in DNA is interpreted into amino acids to make proteins. Recently, technological advances in DNA synthesis, sequencing and genome engineering are enabling the development of synthetic genomes with altered genetic codes. Such comprehensive genome modifications endow these organisms with capabilities such as genetic isolation, virus resistance, and production of new functional proteins. (Abstract)

Whole genome recoding is an emerging field with great potential for elucidation of fundamental biological phenomena as well as generating novel enabling biotechnologies. Deeper understanding of genome structure and function is critical to succeed in these efforts, as well as development of robust computational and synthetic biology methods. While challenging, synthetic genomes with altered genetic codes offer an exciting opportunity to explore the rules of life. (8)

Parrington, John. Redesigning Life: How Genome Editing Will Transform the World. Oxford: Oxford University Press, 2016. An Oxford University pharmacologist and author describes many auspicious potentials by which to begin a epochal recreation by way of informed human intention to make everything anew. If to gloss, people can have roles as editors, curators, indeed writers of nature’s genomic script, CRISPR plus, as it may now pass our ethical continuance.

Pascalie, Jonathan, et al. Developmental Design of Synthetic Bacterial Architectures by Morphogenetic Engineering. ACS Synthetic Biology. Online May, 2016. A French theorist team including Rene Doursat continues their project to commence not only a genomics revolution, but a second genesis of an organismic anatomy and physiology so as to facilitate and develop improved, healthy, enhanced, intentional creaturely beings liberated from contingent evolutionary tinkering.

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