key: cord-0899864-znib6pj3 authors: White, Richard Allen title: The Future of Virology is Synthetic date: 2021-08-31 journal: mSystems DOI: 10.1128/msystems.00770-21 sha: 94442e2534f7bf6b65a9d566c5e0572122a1a9bc doc_id: 899864 cord_uid: znib6pj3 The virosphere (i.e., global virome) represents a vast library of unknown genes on the planet. Synthetic biology through engineering principles could be the key to unlocking this massive global gene repository. Synthetic viruses may also be used as tools to understand “the rules of life” in diverse microbial ecosystems. Such insights may be crucial for understanding the assembly, diversity, structure, and scale of virus-mediated function. Viruses directly affect resilience, stability, and microbial community selection via death resistance cycles. Interpreting and clarifying these effects is essential for predicting the system’s ecology, evolution, and ecosystem stability in an increasingly unstable global climate. A “silent looming pandemic” due to multidrug-resistant microbes will directly impact the global economy, and synthetic virology could provide a future strategy of treatment using targeted viral therapy. This commentary will discuss current techniques for manipulating viruses synthetically, contributing to improved human health and sustainable agriculture. WHAT IS SYNTHETIC VIROLOGY? S ynthetic virology is a subdiscipline of virology that applies molecular, computational, and synthetic biology principles from the fundamentals obtained from naturally occurring viruses to engineer viruses. The first virus assembled from synthetic oligonucleotides was poliovirus (1), followed by the phiX174 bacteriophage (i.e., phage) (2) . Synthetic viruses are built upon a previously sequenced genome, and then oligonucleotides are ordered and assembled synthetically (e.g., Gibson) (2) . Synthetic virions should be evaluated morphologically using transmission electron microscopy (TEM) or atomic force microscopy (AFM) to ensure viral genome packaging within particles (i.e., complete virion assembly) before host validation as a quality control step. Computational tools can predict hosts of various viruses via a variety of methods (3) . If the host is available, an infection could be confirmed from a synthetic virus. If successful, it would enable a user to construct model systems directly from sequencing data (Fig. 1) . In the early 1950s, it was unknown what molecule drove heredity, whether it was nucleic acids or protein. Finally, Hershey and Chase (4), using T2 phage, confirmed it was DNA, using synthetic radiolabeled phage proteins ( 35 S) and DNA ( 32 P). Thus, viruses established the first rule of life that nucleic acids, not protein, was the molecule of inheritance. Therefore, synthetic viruses were used to establish the first rule of life; now, viruses can be used to understand the assembly, diversity, structure, and scale of virus-mediated influence. Synthetic biology represents a significant opportunity for economic advancement, including an estimated $11.4 billion market by 2021 (5) . Synthetic viruses could even be engineered to perform specific tasks and may have broad applications in agriculture, medicine, climate change, and, potentially, carbon capture (Fig. 1) . The virosphere, which is a collection of all of Earth's viruses, represents the most abundant biological entities (6, 7) . The virosphere is estimated at an abundance 10 31 virus-like particles (VLPs) called the "Hendrix product." (6) . This Hendrix product is larger than a mole of atoms (6.022 Â 10 23 , Avogadro's number), more numerous than stars in the observable universe (10 21 ) and greater than the number of all the cells in the human body (10 13 ) (6-8). The human body also contains a vast abundance of viruses. The oral virome is ;10 11 VLPs (assuming 10 8 ml 21 in 1.5 liter of saliva), the stool virome is ;4.5 Â 10 11 VLPs (assuming 10 9 g 21 in 454 g of stool), and the urine virome is 7 Â 10 9 VLPs (assuming 10 7 g 21 in 700 ml of urine) (9, 10) . The numbers of VLPs in stool and oral viromes, at ;10 11 , are equivalent to the number of stars in the Milky Way galaxy. A diverse virome is interacting through life and death struggles daily within the human body. Viral abundances can be measured directly via staining nucleic acids or indirectly via measuring nucleic acids. For indirect measurement, a priori information is required about the viral genome, and then a PCR-based diagnostic (e.g., digital PCR) (11) can be used to estimate viral genome equivalents. A random nucleic acid stain is used (e.g., SYBR), and then VLPs are counted with epifluorescence microscopy (12) or flow cytometry (13) . Dyes such as SYBR are double-stranded DNA (dsDNA) specific and fail to stain single-stranded DNA (ssDNA) and ssRNA effectively (7) . Giant viruses are filtered out and thus rarely counted (7) . A single RNA virus pandemic (e.g. severe acute respiratory syndrome coronavirus 2 [SARS-CoV-2]) can reach numbers .10 17 (14); hence, the Hendrix product must be larger to account for giant viruses and RNA and ssDNA viruses. Advances in viral counting are needed, including (i) measurement of intact particles, (ii) new dyes to differentiate nucleic acid types and strand types (RNA versus DNA, single versus double), (iii) particle size measurement, and (iv) an increase in overall throughput. AFM and TEM must be further explored for viral abundance measurements. Massive parallel sequencing (MPS; formally NextGen) has elucidated vast numbers of new viral genomes; however, we cannot unlock the functions of the enormous library of unknown genes. We currently struggle to provide functional gene validation to even highly studied organisms such as Escherichia coli, in which 35% of the genome has no functional validation (15) . The virosphere harbors an immense gene repertoire of ;10 32 genes (if we assume ;10 genes per virus with the Hendrix product). Viruses fair worse than E. coli in functional validation, with ;50% to 70% of the genes lacking functional validation. Such numbers, if validated, would provide a massive library of genes for synthetic biology. The impact of viruses on global biogeochemical cycles is noted and described broadly elsewhere (16) . The roles of viruses manipulating biogeochemical cycling have been documented via viral auxiliary metabolic genes (vAMGs) (16) . vAMGs are involved in many biogeochemical processes, from photosynthesis to carbon and phosphorus metabolism (16) . Photosynthetic engineering could increase carbon capture and storage within the lithosphere, relieving the climate crisis via photosynthesis-induced alkalinity to precipitate carbonate minerals (17) . Viruses carrying vAMGs can remodel carbon metabolism in cyanobacteria (16) , which could be further engineered with synthetic viruses to increase carbonate precipitation. Viral lysis of cyanobacteria induces calcium carbonate mineral precipitation (7) . Engineering viruses via direct lysis or via vAMG could enhance this process, leading to long-term carbon capture within minerals. Synthetic viruses themselves could be mineralized and then trap carbon on geological time scales. How vAMGs partition microbial metabolisms within the terrestrial ecosystems, including the rhizosphere relating to carbon, nitrogen, phosphorus, and plant productivity, is unknown. Phages carry a vAMG homolog to phoH (phosphate starvation-inducible protein) and pstS (phosphate-binding protein), both activated under phosphorus starvation (16) . While the function of phoH and pstS in phages is unknown, should these vAMGs be shown to enhance microbial metabolism related to phosphorus, this could provide plant growth-promoting effects. Therefore, viruses should be screened for plant growth-promoting processes beyond pathogen control within the rhizosphere microbiome. Engineered viruses could be trained to eliminate pesticides, antibiotics, and fungicides. In addition, viral cocktails could provide a targeted treatment directly toward a pathogen within the field or feedlot. These viral cocktails could be designed to kill, reprogrammed to remove pathogen virulence genes, or made to push cells into dormancy. WHO predicts that 10 million people will die from a drug-resistant microbial infection (DRMI) by 2050 (18) . Currently, at least 700,000 people die each year from DRMIs (18) . We are running out of drugs for microbial resistance, for which many now have no treatment, causing a "silent pandemic." Antibiotics are classically used as growth promoters in feedstocks (e.g., chickens, pigs, etc.) but increase DRMIs in a variety of bacterial pathogens (e.g., E. coli and Staphylococcus aureus) (19) . Because antibiotics are bacteriostatic (nonlethal), microbes can escape via resistant mutations. The significant use of antibiotics in agriculture and medical overuse for nonbacterial infection increase the likelihood of DRMI spread. Phage therapy is not a new idea; Felix d'Herelle proposed it at the beginning of the 20th century. Phage therapy offers targeted bactericidal (lethal) treatment for bacteria. Phage counterparts, mycoviruses, have been used as biocontrol agents to treat fungal infections (20) . As with phage, mycoviruses could be engineered for better biocontrol of fungal pathogens. As mentioned above, they could be designed, engineered, and tailored as cocktails for a specific pathogen. Also, viruses could be combined with antibiotics to make them effective again by adding back antibiotic-sensitive genes (21) or via an evolutionary approach (22) . Evolutionary approaches to phage therapy combined with antibiotics are modeled and described elsewhere (22) . Questions remain about the use of phage and mycoviral therapy in human patients, including safety, resistance, specificity, and biofilm penetration. Phages can degrade biofilms via depolymerase (23) , which can be engineered to be highly specific. The benefit of phage therapy, especially if tailored toward specific pathogens, is that it could be effective and safe, even for immunocompromised patients; however, further clinical studies are needed (24) . Less is known on mycoviral therapy for patients, as only viral-like particles, but no viruses, have been isolated for common human fungal pathogens, including Candida albicans (20) . In addition, bacteria and fungi can develop resistance to viral therapy; however, using multiviral cocktails of .5 viruses or more limits this resistance (25) . Viruses are commonly very specific to single hosts; however, they can be polyvirulent and infect many members of the same species. It has not been widely observed that viruses jump into different phyla, and they rarely jump beyond the class of their original host. The main issue is specificity, which can be combated by cocktail design or viral entry engineering. Viruses have been the catalysts for molecular biology, synthetic biology, and the genome sequencing revolution. Viruses have elucidated cellular mechanisms essential to regulating our microbiome and are fundamental to Earth's carbon cycle. Viral genes should be used creatively in research; to solve your questions, learn from them and use these technologies to solve global issues ranging from climate change to the silent pandemic. Viral-based mechanisms (e.g., CRISPR) can be disruptive technologies that are massive innovations. While the COVID-19 pandemic has highlighted the pivotal role of viruses in our daily life, remember that viruses are more friend than foe, and they are the future via synthetic biology. Chemical synthesis of poliovirus cDNA: generation of infectious virus in the absence of natural template Generating a synthetic genome by whole genome assembly: phiX174 bacteriophage from synthetic oligonucleotides Global overview and major challenges of host prediction methods for uncultivated phages Independent functions of viral protein and nucleic acid in growth of bacteriophage Synthetic biology in the driving seat of the bioeconomy Are there 10 31 virus particles on Earth, or more, or less? Between a rock and a soft place: the role of viruses in lithification of modern microbial mats Revised estimates for the number of human and bacteria cells in the body Characterization of virus-like particles associated with the human faecal and caecal microbiota The human urine virome in association with urinary tract infections Digital PCR provides absolute quantitation of viral load for an occult RNA virus Use of SYBR Green I for rapid epifluorescence counts of marine viruses and bacteria Optimization of procedures for counting viruses by flow cytometry The total number and mass of SARS-CoV-2 virions They-one defines the 35% of Escherichia coli genes that lack experimental evidence of function Marine viruses: truth or dare Calcifying cyanobacteria-the potential of biomineralization for carbon capture and storage Confronting antimicrobial resistance beyond the COVID-19 pandemic and the 2020 US election Antibiotic use in agriculture and its consequential resistance in environmental sources: potential public health implications Mycoviruses: future therapeutic agents of invasive fungal infections in humans? Reversing bacterial resistance to antibiotics by phage-mediated delivery of dominant sensitive genes Quantitative models of phage-antibiotic combination therapy Bacteriophage -a promising alternative measure for bacterial biofilm control Is phage therapy acceptable in the immunocompromised host? Phage cocktails can prevent the evolution of phage-resistant Enterococcus I thank Thulani P. Makhalanyane for the nomination for this special issue, Brendan P. Burns for helpful discussions, and Laura Newcomb for proofreading, edits, and suggestions. I also thank Floré for sponsoring this special collection in mSystems. R. A. White III is supported by a UNCC Bioinformatics and Genomics start-up package.