Synthetic biology initiatives frequently aim to redesign organisms so that they can create a material, such as a drug or fuel, or acquire a new function, such as the ability to sense something in the environment. Examples of what researchers are creating using synthetic biology include: • Utilizing microorganisms for bioremediation to remove contaminants from our water, soil, and air. • Production of complex natural products that are usually extracted from plants but cannot be obtained in sufficient amounts, e.g. drugs of natural origin, such as
artemisinin and
paclitaxel. • Beta-carotene, a substance typically associated with carrots that prevents vitamin A deficiency, is produced by rice that has been modified. Every year, between 250,000 and 500,000 children lose their vision due to vitamin A deficiency, which also significantly raises their chance of dying from infectious infections. • As a sustainable and environmentally benign alternative to the fresh roses that perfumers use to create expensive smells, yeast has been created to produce rose oil. which codes for the enzyme that is the source of bacterial
bioluminescence, and can be placed after a respondent
promoter to express the luminescence genes in response to a specific environmental stimulus. One such sensor created, consisted of a
bioluminescent bacterial coating on a photosensitive
computer chip to detect certain
petroleum pollutants. When the bacteria sense the pollutant, they luminesce. Another example of a similar mechanism is the detection of landmines by an engineered
E.coli reporter strain capable of detecting
TNT and its main degradation product
DNT, and consequently producing a green fluorescent protein (
GFP). Modified organisms can sense environmental signals and send output signals that can be detected and serve diagnostic purposes. Microbe cohorts have been used. Biosensors could also be used to detect pathogenic signatures—such as of
SARS-CoV-2—and can be
wearable. For the purpose of detecting and reacting to various and temporary environmental factors, cells have developed a wide range of regulatory circuits, ranging from transcriptional to post-translational. These circuits are made up of transducer modules that filter the signals and activate a biological response, as well as carefully designed sensitive sections that attach analytes and regulate signal-detection thresholds. Modularity and selectivity are programmed to biosensor circuits at the transcriptional, translational, and post-translational levels, to achieve the delicate balancing of the two basic sensing modules. However, not all synthetic nutrition products are animal food products – for instance, as of 2021, there are also products of
synthetic coffee that are reported to be close to commercialization. Similar fields of research and production based on synthetic biology that can be used for the production of food and drink are: • Genetically engineered
microbial food cultures (e.g. for solar-energy-based protein powder) • Cell-free artificial synthesis (e.g. synthetic
starch; )
Materials Photosynthetic microbial cells have been used as a step to synthetic production of
spider silk.
Biological computers A
biological computer refers to an engineered biological system that can perform computer-like operations, which is a dominant paradigm in synthetic biology. Researchers built and characterized a variety of
logic gates in a number of organisms, and demonstrated both analog and digital computation in living cells. They demonstrated that bacteria can be engineered to perform both analog and/or digital computation. In 2007, in human cells, research demonstrated a universal logic evaluator that operates in mammalian cells. Subsequently, researchers utilized this paradigm to demonstrate a proof-of-concept therapy that uses biological digital computation to detect and kill human cancer cells in 2011. In 2016, another group of researchers demonstrated that principles of
computer engineering can be used to automate digital circuit design in bacterial cells. In 2017, researchers demonstrated the 'Boolean logic and arithmetic through DNA excision' (BLADE) system to engineer digital computation in human cells. In 2019, researchers implemented a
perceptron in biological systems opening the way for
machine learning in these systems.
Cell transformation Cells use interacting genes and proteins, which are called gene circuits, to implement diverse function, such as responding to environmental signals, decision making and communication. Three key components are involved: DNA, RNA and Synthetic biologist designed gene circuits that can control gene expression from several levels including transcriptional, post-transcriptional and translational levels. Traditional metabolic engineering has been bolstered by the introduction of combinations of foreign genes and optimization by directed evolution. This includes engineering
E. coli and
yeast for commercial production of a precursor of the
antimalarial drug,
Artemisinin. Entire organisms have yet to be created from scratch, although living cells can be
transformed with new DNA. Several ways allow constructing synthetic DNA components and even entire
synthetic genomes, but once the desired genetic code is obtained, it is integrated into a living cell that is expected to manifest the desired new capabilities or
phenotypes while growing and thriving. Cell transformation is used to create
biological circuits, which can be manipulated to yield desired outputs.
Designed proteins protein was one of the first proteins designed for a fold that had never been seen before in nature. Natural proteins can be engineered, for example, by
directed evolution, novel protein structures that match or improve on the functionality of existing proteins can be produced. One group generated a
helix bundle that was capable of binding
oxygen with similar properties as
hemoglobin, yet did not bind
carbon monoxide. A similar protein structure was generated to support a variety of
oxidoreductase activities while another formed a structurally and sequentially novel
ATPase. Another group generated a family of G-protein coupled receptors that could be activated by the inert small molecule
clozapine N-oxide but insensitive to the native
ligand,
acetylcholine; these receptors are known as
DREADDs. Novel functionalities or protein specificity can also be engineered using computational approaches. One study was able to use two different computational methods: a bioinformatics and molecular modeling method to mine sequence databases, and a computational enzyme design method to reprogram enzyme specificity. Both methods resulted in designed enzymes with greater than 100 fold specificity for production of longer chain alcohols from sugar. Another common investigation is
expansion of the natural set of 20
amino acids. Excluding
stop codons, 61
codons have been identified, but only 20 amino acids are coded generally in all organisms. Certain codons are engineered to code for alternative amino acids including: nonstandard amino acids such as O-methyl
tyrosine; or exogenous amino acids such as 4-fluorophenylalanine. Typically, these projects make use of re-coded
nonsense suppressor tRNA-
Aminoacyl tRNA synthetase pairs from other organisms, though in most cases substantial engineering is required. Other researchers investigated protein structure and function by reducing the normal set of 20 amino acids. Limited protein sequence libraries are made by generating proteins where groups of amino acids may be replaced by a single amino acid. For instance, several
non-polar amino acids within a protein can all be replaced with a single non-polar amino acid. One project demonstrated that an engineered version of
Chorismate mutase still had catalytic activity when only nine amino acids were used. Researchers and companies practice synthetic biology to synthesize
industrial enzymes with high activity, optimal yields and effectiveness. These synthesized enzymes aim to improve products such as detergents and lactose-free dairy products, as well as make them more cost effective. The improvements of metabolic engineering by synthetic biology is an example of a biotechnological technique utilized in industry to discover pharmaceuticals and fermentive chemicals. Synthetic biology may investigate modular pathway systems in biochemical production and increase yields of metabolic production. Artificial enzymatic activity and subsequent effects on metabolic reaction rates and yields may develop "efficient new strategies for improving cellular properties ... for industrially important biochemical production".
Designed nucleic acid systems Scientists can encode digital information onto a single strand of
synthetic DNA. In 2012,
George M. Church encoded one of his books about synthetic biology in DNA. The 5.3
Mb of data was more than 1000 times greater than the previous largest amount of information to be stored in synthesized DNA. A similar project encoded the complete
sonnets of
William Shakespeare in DNA. More generally, algorithms such as NUPACK, ViennaRNA, Ribosome Binding Site Calculator, Cello, enables the design of new genetic systems. Many technologies have been developed for incorporating
unnatural nucleotides and amino acids into nucleic acids and proteins, both in vitro and in vivo. For example, in May 2014, researchers announced that they had successfully introduced two new artificial
nucleotides into bacterial DNA. By including individual artificial nucleotides in the culture media, they were able to exchange the bacteria 24 times; they did not generate
mRNA or proteins able to use the artificial nucleotides.
Space exploration Synthetic biology raised
NASA's interest as it could help to produce resources for astronauts from a restricted portfolio of compounds sent from Earth. On Mars, in particular, synthetic biology could lead to production processes based on local resources, making it a powerful tool in the development of occupied outposts with less dependence on Earth.
Synthetic life functions in the minimal
genome of the synthetic organism,
Syn 3 One important topic in synthetic biology is
synthetic life, that is concerned with hypothetical organisms created
in vitro from
biomolecules and/or
chemical analogues thereof. Synthetic life experiments attempt to either probe the
origins of life, study some of the properties of life, or more ambitiously to recreate life from non-living (
abiotic) components. Synthetic life biology attempts to create living organisms capable of carrying out important functions, from manufacturing pharmaceuticals to detoxifying polluted land and water. In medicine, it offers prospects of using designer biological parts as a starting point for new classes of therapies and diagnostic tools. It has been claimed that this would be difficult, A completely synthetic bacterial chromosome was produced in 2010 by
Craig Venter, and his team introduced it to genomically emptied bacterial host cells. The host cells were able to grow and replicate. The
Mycoplasma laboratorium is the only living organism with completely engineered genome. The first living organism with 'artificial' expanded DNA code was presented in 2014; the team used
E. coli that had its genome extracted and replaced with a chromosome with an expanded genetic code. The
nucleosides added are
d5SICS and
dNaM. followed by national synthetic cell organizations in several countries, including FabriCell, MaxSynBio and BaSyC. The European synthetic cell efforts were unified in 2019 as SynCellEU initiative. In 2023, researchers were able to create the first synthetically made human embryos derived from stem cells.
Drug delivery platforms In therapeutics, synthetic biology has achieved significant advancements in altering and simplifying the therapeutics scope in a relatively short period of time. In fact, new therapeutic platforms, from the discovery of disease mechanisms and drug targets to the manufacture and transport of small molecules, are made possible by the logical and model-guided design construction of biological components. Recently synthetic biologists reprogrammed bacteria to sense and respond to a particular cancer state. Most often bacteria are used to deliver a therapeutic molecule directly to the tumor to minimize off-target effects. To target the tumor cells,
peptides that can specifically recognize a tumor were expressed on the surfaces of bacteria. Peptides used include an
affibody molecule that specifically targets human
epidermal growth factor receptor 2 and a synthetic
adhesin. The other way is to allow bacteria to sense the
tumor microenvironment, for example hypoxia, by building an AND logic gate into bacteria. Then the bacteria only release target therapeutic molecules to the tumor through either
lysis or the
bacterial secretion system. Lysis has the advantage that it can stimulate the immune system and control growth. Multiple types of secretion systems can be used and other strategies as well. The system is inducible by external signals. Inducers include chemicals, electromagnetic or light waves. Multiple species and strains are applied in these therapeutics. Most commonly used bacteria are
Salmonella typhimurium,
Escherichia coli,
Bifidobacteria,
Streptococcus,
Lactobacillus,
Listeria and
Bacillus subtilis. Each of these species have their own property and are unique to cancer therapy in terms of tissue colonization, interaction with immune system and ease of application.
Engineered yeast-based platform Synthetic biologists are developing genetically modified live yeast that can deliver therapeutic biologic medicines. When orally delivered, these live yeast act like micro-factories and will make therapeutic molecules directly in the gastrointestinal tract. Because yeast are eukaryotic, a key benefit is that they can be administered together with antibiotics. Probiotic yeast expressing human P2Y2 purinergic receptor suppressed intestinal inflammation in mouse models of inflammatory bowel disease. A live
S. boulardii yeast delivering a tetra-specific anti-toxin that potently neutralizes Toxin A and Toxin B of
Clostridioides difficile has been developed. This therapeutic anti-toxin is a fusion of four single-domain antibodies (
nanobodies) that potently and broadly neutralize the two major virulence factors of C. difficile at the site of infection in preclinical models. The first in human clinical trial of engineered live yeast for the treatment of
Clostridioides difficile infection is anticipated in 2024 and will be sponsored by the developer Fzata, Inc.
Cell-based platform The immune system plays an important role in cancer and can be harnessed to attack cancer cells. Cell-based therapies focus on
immunotherapies, mostly by engineering
T cells. T cell receptors were engineered and 'trained' to detect cancer
epitopes.
Chimeric antigen receptors (CARs) are composed of a fragment of an
antibody fused to intracellular T cell signaling domains that can activate and trigger proliferation of the cell. Multiple second generation CAR-based therapies have been approved by FDA. Gene switches were designed to enhance safety of the treatment. Kill switches were developed to terminate the therapy should the patient show severe side effects. Mechanisms can more finely control the system and stop and reactivate it. Since the number of T-cells are important for therapy persistence and severity, growth of T-cells is also controlled to dial the effectiveness and safety of therapeutics. Although several mechanisms can improve safety and control, limitations include the difficulty of inducing large DNA circuits into the cells and risks associated with introducing foreign components, especially proteins, into cells.
Biofuels, pharmaceuticals and biomaterials The most popular biofuel is ethanol produced from corn or sugar cane, but this method of producing biofuels is troublesome and constrained due to the high agricultural cost and inadequate fuel characteristics of ethanol. A substitute and potential source of renewable energy is microbes that have had their metabolic pathways altered to be more efficient at converting biomass into biofuels. Only if their production costs could be made to match or even beat those of present fuel production can these techniques be expected to be successful. Related to this, there are several medicines whose pricey manufacturing procedures prevent them from having a larger therapeutic range. The creation of new materials and the microbiological manufacturing of biomaterials would both benefit substantially from novel artificial biology tools.
Regulatory elements To build and develop biological systems, regulating components including regulators, ribosome-binding sites (RBSs), and terminators are crucial. Despite years of study, there are many various varieties and numbers of promoters and terminators for Escherichia coli, but also for the well-researched model organism Saccharomyces cerevisiae, as well as for other organisms of interest, these tools are quite scarce. Numerous techniques have been invented for the finding and identification of promoters and terminators in order to overcome this constraint, including genome mining, random mutagenesis, hybrid engineering, biophysical modelling, combinatorial design, and rational design.
Bioprinted organs Other transplants and induced regeneration There is ongoing research and development into synthetic biology based methods for inducing
regeneration in humans as well the creation of transplantable
artificial organs.
Nanoparticles, artificial cells and micro-droplets Synthetic biology can be
used for creating nanoparticles which can be used
for drug-delivery as well as for other purposes. Complementing research and development seeks to and has created
synthetic cells that mimics functions of biological cells. Applications include medicine such as
designer-
nanoparticles that make blood cells eat away—from the inside out—portions of
atherosclerotic plaque that cause heart attacks. Synthetic micro-droplets for
algal cells or synergistic algal-bacterial multicellular
spheroid microbial reactors, for example, could be used to produce
hydrogen as
hydrogen economy biotechnology.
Electrogenetics Mammalian designer cells are engineered by humans to behave a specific way, such as an immune cell that expresses a synthetic receptor designed to combat a specific disease. Electrogenetics is an application of synthetic biology that involves utilizing electrical fields to stimulate a response in engineered cells. Controlling the designer cells can be done with relative ease through the use of common electronic devices, such as smartphones. Additionally, electrogenetics allows for the possibility of creating devices that are much smaller and compact than devices that use other stimulus through the use of microscopic electrodes. This was implemented in ElectroHEK cells, cells that contain voltage-gated calcium channels that are electrosensitive, meaning that the ion channel can be controlled by electrical conduction between electrodes and the ElectroHEK cells. == Ethics ==