Transient expression
Transient expression, also known as transient gene expression, is a molecular biology technique that enables the temporary introduction of foreign genetic material, such as DNA or RNA constructs, into host cells, resulting in short-term protein production or functional analysis without integration into the host genome.[1] This process typically lasts 1–7 days, allowing genes to be expressed episomally before the introduced material is diluted or degraded during cell division.[1] It contrasts with stable expression, where genetic material integrates into the genome for long-term, heritable expression.[2] The technique is widely applied in both plant and mammalian cell systems, offering a rapid and versatile platform for research and biotechnology.[3] In plants, common methods include agroinfiltration using Agrobacterium tumefaciens to deliver T-DNA into leaf cells, protoplast transfection via polyethylene glycol (PEG) or electroporation, and biolistic particle bombardment, enabling high-throughput studies without the need for tissue regeneration or stable transformants.[4][5] These approaches facilitate quick assessment of gene function, protein localization (e.g., in chloroplasts or nuclei), and regulatory elements, as well as manipulation of metabolic pathways like flavonoid biosynthesis.[3] In mammalian cells, such as HEK293 or CHO lines, transient expression often relies on lipid-based transfection, electroporation, or viral vectors like baculovirus, providing efficient tools for validating recombinant proteins, screening mutations, and producing complex biologics.[6][7][8] Key advantages of transient expression include its speed—yielding results in days rather than months required for stable lines—and flexibility for co-expressing multiple genes or testing synthetic biology constructs without altering the host germline.[4] It has become essential for functional genomics, enabling protein-protein interaction studies via techniques like bimolecular fluorescence complementation (BiFC), and for industrial applications such as rapid antibody production and vaccine development, including antigens for SARS-CoV-2.[1][3] Ongoing optimizations, such as enhanced vectors, delivery methods including vacuum and sonication-assisted techniques (VAST) and mRNA transfection, continue to boost expression levels and scalability as of 2025, making it a cornerstone of modern molecular research.[9][10][11]Fundamentals
Definition and Principles
Transient gene expression refers to the temporary production of proteins from foreign genes introduced into host cells, typically via plasmid DNA or synthetic mRNA, where the introduced nucleic acid remains extrachromosomal (episomal) and does not integrate into the host genome.[12] This non-integrative nature results in expression that is short-lived, as the genetic material is progressively diluted during cell division or degraded by cellular nucleases, generally persisting for hours to several days depending on the system.[13][14] Unlike stable expression, transient systems provide rapid assessment of gene function without permanent genetic alteration.[2] The core principles of transient gene expression revolve around the episomal maintenance of the introduced nucleic acid, enabling transcription and subsequent translation without genomic incorporation. In DNA-based approaches, the plasmid DNA enters the nucleus and serves as a template for transcription, driven by engineered promoters that recruit host RNA polymerase machinery. For instance, the cytomegalovirus (CMV) immediate-early promoter is widely used in mammalian cells due to its strong, constitutive activity, while the cauliflower mosaic virus (CaMV) 35S promoter is a standard choice for plant cells, providing robust expression across diverse tissues.[15][16] Translation efficiency then depends on the export of the transcribed mRNA to the cytoplasm, where ribosomes assemble the protein product. The duration of expression is modulated by cellular factors such as the rate of cell division, which dilutes non-replicating plasmids in proliferating cells, and the inherent stability of the DNA, influenced by its sequence and cellular degradation pathways.[17] In contrast, RNA-based transient expression utilizes synthetic mRNA directly introduced into the cytoplasm, bypassing the need for nuclear entry and transcription. This approach yields a faster onset of protein production, often detectable within minutes to hours, as the mRNA is immediately available for ribosomal translation without the intermediate step of DNA-to-RNA synthesis.[11][18][19] However, mRNA stability is generally lower than that of DNA, leading to shorter expression windows unless modified with protective elements like 5' caps or poly-A tails to resist exonuclease degradation. The overall level of transient gene expression can be conceptually modeled as proportional to the product of transfection efficiency, promoter strength (for DNA-based systems), and nucleic acid stability: \text{Expression level} \propto [\text{Transfection efficiency}] \times [\text{Promoter strength}] \times [\text{mRNA/DNA stability}] This relationship is derived from fundamental molecular kinetics: transfection efficiency determines the initial amount of nucleic acid delivered per cell, promoter strength governs the rate of mRNA transcription (or directly influences translation initiation for mRNA), and stability dictates the persistence of the template or transcript, integrating over time to yield cumulative protein output.[11] For DNA, the transcription rate k_{\text{trans}} is promoter-dependent (k_{\text{trans}} \propto \text{promoter strength}), leading to mRNA accumulation [\text{mRNA}] = \frac{k_{\text{trans}} [\text{DNA}]}{\gamma_{\text{mRNA}}}, where \gamma_{\text{mRNA}} is the mRNA degradation rate (inversely related to stability); translation then scales with [\text{mRNA}], modulated by initial DNA delivery (efficiency) and DNA half-life. For mRNA, the model simplifies by replacing promoter strength with direct translation efficiency, emphasizing rapid but transient kinetics.[18]Historical Development
The origins of transient expression techniques trace back to the early 1970s, when researchers developed methods to introduce foreign DNA into mammalian cells for short-term gene activity without genomic integration. A pivotal advancement was the calcium phosphate precipitation method, introduced by Frank L. Graham and Adriaan J. van der Eb in 1973, which enabled the efficient transfection of human adenovirus 5 DNA into KB cells, allowing the first reliable transient assays for viral infectivity and gene function studies.90341-3) This technique marked a shift from earlier, less efficient viral infection methods, providing a non-viral alternative for rapid protein production and functional analysis in cultured cells. In the 1980s, transient expression expanded to plant systems and diversified delivery approaches. The leaf disk assay using Agrobacterium tumefaciens, developed by Robert B. Horsch and colleagues in 1985, facilitated the transfer of T-DNA into tobacco leaf explants, enabling transient gene expression studies that preceded stable transformation and accelerated plant genetic engineering. Concurrently, electroporation emerged as a versatile physical method; Tony K. K. Wong and Eberhard Neumann demonstrated its use for DNA transfer into mouse L cells in 1982, broadening applicability across cell types including bacteria, yeast, and plants by creating temporary membrane pores via electric pulses.91233-0) The 1990s and 2000s saw the proliferation of viral vectors and optimized non-viral systems, enhancing expression efficiency for biopharmaceutical applications. Recombinant adenoviral vectors, refined in the early 1990s, allowed high-level transient transgene delivery to non-dividing cells; for instance, Michael A. Rosenfeld et al. reported in 1991 the in vivo expression of human alpha-1-antitrypsin in rat lungs, paving the way for gene therapy trials. Plasmid-based optimizations followed, with Geraldine Backliwal and team achieving over 1 g/L yields of recombinant antibodies in HEK293E cells via transient transfection in 2008, through vector redesign and media modulation, significantly boosting scalability for antibody production. The 2010s and 2020s witnessed accelerated innovation, driven by the COVID-19 pandemic and synthetic biology. mRNA-based transient expression gained prominence with lipid nanoparticle delivery; the Pfizer-BioNTech BNT162b2 vaccine, authorized in late 2020, utilized nucleoside-modified mRNA to transiently produce SARS-CoV-2 spike protein in human cells, eliciting immune responses in over 95% of recipients in phase 3 trials. Post-2020, CRISPR/Cas9 integration with transient systems enabled precise gene editing validation without permanent modification; for example, ribonucleoprotein delivery methods in the early 2020s facilitated transient Cas9 activity in plant and mammalian cells for functional genomics. By 2025, synthetic biology applications incorporated transient expression for modular circuit prototyping, such as computational tools identifying small molecules to enhance gene delivery in high-throughput screens.| Year | Key Development | Researchers/Key Contributors | Impact |
|---|---|---|---|
| 1973 | Calcium phosphate transfection for mammalian cells | Graham and van der Eb | Enabled first non-integrative DNA delivery for transient assays in cultured cells, foundational for molecular biology studies.90341-3) |
| 1982 | Electroporation for DNA transfer | Wong and Neumann | Expanded transient expression to diverse cell types, improving efficiency over chemical methods.91233-0) |
| 1985 | Agrobacterium-mediated leaf disk assay for plants | Horsch et al. | Accelerated transient gene studies in plants, precursor to widespread genetic transformation. |
| 1991 | Recombinant adenoviral vectors for in vivo expression | Rosenfeld et al. | Facilitated high-efficiency transient delivery to tissues, advancing gene therapy and vaccine development. |
| 2008 | Optimized plasmid transfection yielding >1 g/L in HEK293 | Backliwal et al. | Scaled up recombinant protein production, supporting biomanufacturing for therapeutics. |
| 2020 | mRNA-LNP for transient spike protein expression | Pfizer-BioNTech team (Polack et al.) | Revolutionized vaccine platforms, enabling rapid response to pandemics with 95% efficacy. |
| 2023-2025 | CRISPR-RNP and synthetic biology integrations | Various (e.g., transient Cas9 in plants; computational enhancers) | Enhanced editing validation and circuit design, promoting transgene-free applications in biotech. |
Comparison to Other Expression Systems
Versus Stable Expression
Transient expression differs fundamentally from stable expression in that the introduced genetic material remains episomal and is not integrated into the host genome, allowing for temporary maintenance without the need for selection markers like antibiotic resistance genes, whereas stable expression relies on genomic integration to achieve heritable, long-term propagation of the transgene.[20] This lack of integration in transient systems results in expression durations typically lasting from a few days to about two weeks, in contrast to the indefinite expression provided by stable cell lines once established.[21] In terms of process, transient expression bypasses the requirement for clonal selection and expansion, enabling rapid setup and protein detection within 24-96 hours post-transfection, often culminating in peak expression at 48-72 hours before declining due to plasmid dilution during cell division and DNA degradation.[2] Stable expression, however, involves transfection followed by selection, subcloning, and validation, which can take 9-12 weeks to generate reliable cell lines.[22] While transient methods may yield high initial protein levels—up to 3 g/L as of 2024 in optimized mammalian systems like CHO cells—these often decrease significantly after 72 hours, whereas stable lines maintain consistent output over extended periods, reaching up to 10 g/L for monoclonal antibodies in biopharmaceutical production.[23][24] Transient expression is particularly suited for rapid prototyping of gene function, preliminary toxicity assessments, and small-scale validation of constructs where short-term data suffices, avoiding the prolonged timelines of stable systems. Recent advancements, such as enhanced transient platforms in CHO cells, have improved yields and scalability, narrowing the performance gap with stable systems as of 2025.[25] In contrast, stable expression is preferred for large-scale, sustained production of therapeutics, such as recombinant proteins and biologics, due to its reliability and scalability for industrial applications.[23]| Aspect | Transient Expression | Stable Expression |
|---|---|---|
| Timeline | 1-7 days to peak expression and harvest | 9-12 weeks for line establishment and validation |
| Cost | Lower (fewer resources, no long-term selection) | Higher (extended culturing, screening, and optimization) |
| Risks | Variable expression levels, batch inconsistency | Insertional mutagenesis, genomic instability |
Versus Constitutive Expression
Transient expression and constitutive expression are distinct but complementary concepts in molecular biology. Constitutive expression refers to the continuous production of a gene product driven by strong, unregulated promoters, such as those associated with housekeeping genes like actin or GAPDH (in eukaryotes) or viral promoters like CMV in mammalian cells and CaMV 35S in plants, which maintain steady-state levels without external induction. In contrast, transient expression describes the temporary delivery of non-integrating DNA or RNA constructs, resulting in limited-duration gene activity that peaks within hours to days before declining due to template dilution or degradation during cell division. This temporal limitation is independent of the promoter type used.[21] Transient systems often incorporate constitutive promoters to achieve high, immediate expression levels for short-term analyses, while also supporting inducible promoters (e.g., Tet-on system) for controlled activation. This flexibility allows evaluation of regulatory elements without long-term genomic changes, avoiding potential toxicity from sustained overexpression in constitutive setups. For example, constitutive promoters can cause cellular stress from constant high protein levels, whereas transient delivery enables reversible testing.[27] The temporal control in transient expression supports dynamic studies, such as pulse-like profiles for time-sensitive processes (e.g., signal transduction), complementing the uniform output of constitutive systems, which provide baselines for steady-state effects. In practice, transient expression is commonly used to validate constitutive promoters before stable integration; for instance, luciferase reporter assays under transient conditions confirm the activity of CaMV 35S in plant protoplasts, assessing consistent expression across transfections.[28] The kinetics of protein accumulation can be modeled to illustrate these dynamics: \frac{d[\text{Protein}]}{dt} = k_{\text{[synthesis](/page/Synthesis)}} - k_{\text{[degradation](/page/Degradation)}} In systems using constitutive promoters with stable integration, k_{\text{synthesis}} remains constant, leading to equilibrium. In transient expression, even with constitutive promoters, template loss causes k_{\text{synthesis}} to decay exponentially, yielding transient protein levels.[29]| Aspect | Transient Expression (with Constitutive or Inducible Promoters) | Constitutive Expression (Promoter-Driven Continuous Output) |
|---|---|---|
| Control Mechanism | Temporal limitation via non-integrating DNA/RNA; supports constitutive (e.g., CMV, 35S) or inducible promoters for short-term control | Strong, unregulated promoters (e.g., CMV, 35S); can be used in transient or stable systems for persistence |
| Pros in Functional Genomics | Rapid testing of promoters/elements; avoids toxicity from prolonged expression; enables dynamic/pulse studies | Provides stable baselines for long-term assays; simplifies screening of gene effects under constant conditions |
| Cons in Functional Genomics | Variable duration across cells; requires repeated transfections for extended work | Risk of artifacts from sustained overexpression; may need stable integration for long-term use |
Delivery Methods
Physical and Chemical Transfection
Physical transfection methods introduce nucleic acids into cells through mechanical or electrical disruption of the cell membrane, enabling transient expression without integration into the genome. Electroporation, a widely adopted technique, applies short electric pulses to create transient pores in the plasma membrane, facilitating DNA uptake. Developed as a gene delivery method in the early 1980s, electroporation achieves transfection efficiencies of 50-90% in mammalian cells, depending on parameters such as voltage (typically 200-1000 V), pulse duration, and buffer composition.[30][31] Optimizations often involve low-conductivity buffers to minimize toxicity and heat generation, with cell viability maintained above 70% in protocols using exponential decay pulses.[32] Microinjection provides high-precision delivery by directly injecting DNA into the cell nucleus or cytoplasm using a fine glass micropipette under microscopic control. This method, pioneered for mammalian gene transfer in the early 1980s, ensures nearly 100% transfection efficiency per injected cell but is limited by low throughput, typically processing only hundreds of cells per session. It is particularly useful for hard-to-transfect primary cells, where optimizations focus on needle diameter (0.5-1 μm) and injection pressure to avoid membrane rupture.[33] Particle bombardment, or gene gun technology, accelerates DNA-coated microprojectiles (e.g., gold or tungsten particles, 1-3 μm in diameter) into cells using high-pressure helium gas. Introduced in 1987, this approach bypasses the cell wall in plants but also transfects mammalian tissues effectively, with efficiencies reaching 20-50% in adherent monolayers.[34] Optimizations include particle coating density (0.1-2 μg DNA per mg particles) and acceleration pressure (900-1500 psi) to balance penetration and cell survival.[35] Chemical transfection relies on reagents that form complexes with nucleic acids to promote endocytosis and endosomal escape for transient expression. Calcium phosphate precipitation, a foundational method since 1973, involves mixing DNA with calcium chloride and phosphate buffer to create nanoscale precipitates that cells internalize via phagocytosis. Efficiencies vary from 10-50% in adherent cell lines, influenced by pH (6.8-7.2) and incubation time (4-16 hours), though it is sensitive to serum and requires fresh precipitates to mitigate variability.[36][37] In plant systems, polyethylene glycol (PEG)-mediated transfection is commonly used for protoplasts, where isolated cells are treated with PEG to facilitate DNA uptake through membrane fusion. This method, effective since the 1980s, achieves variable efficiencies (10-80%) depending on protoplast viability and PEG concentration (typically 20-40%), and is valuable for high-throughput functional studies without cell walls.[4] Lipofection employs cationic lipid vesicles, such as those in Lipofectamine, to encapsulate DNA and fuse with the plasma membrane. First described in 1987, this technique yields 70-90% efficiency in HEK293 cells through charge-based complexing and lipid bilayer disruption.[38][39] Optimizations include DNA-to-lipid ratios (1:2-1:3 w/w) and serum-free media to enhance stability, with toxicity reduced by using low concentrations (0.5-2 μL reagent per well).[40] Polyethylenimine (PEI), a branched cationic polymer introduced in 1995, condenses DNA into compact polyplexes via electrostatic interactions, promoting lysosomal escape through a proton sponge effect.[41] It achieves 40-80% transfection efficiency across diverse cell types, with optimizations centering on PEI nitrogen-to-DNA phosphate ratios (6:1 to 10:1) and linear vs. branched forms (25 kDa branched PEI often preferred for higher yields).[42] In optimized setups, these methods support transient protein yields up to 100 mg/L in suspension cultures.[40] Transfection efficiency is commonly quantified as: \text{Efficiency} = \left( \frac{\text{Number of transfected cells}}{\text{Total number of cells}} \right) \times 100 using reporter genes like GFP analyzed by flow cytometry.[43]Biological Delivery Systems
Biological delivery systems for transient expression utilize living vectors, such as viruses and bacteria, to introduce genetic material into host cells without stable genomic integration, enabling short-term gene activity for research and therapeutic applications. These methods leverage the natural infection mechanisms of biological agents to achieve targeted delivery, often with higher specificity and efficiency compared to abiotic techniques like chemical transfection.[44] Viral vectors are prominent in these systems due to their ability to efficiently transduce a wide range of cell types. Adenoviral vectors, being non-integrating, deliver DNA that remains episomal in the nucleus, supporting rapid transient expression lasting hours to days in both dividing and non-dividing cells, with production titers reaching up to 10^12 particles per mL.[44] Adeno-associated virus (AAV) vectors also operate transiently in dividing cells, providing expression for up to 2 weeks via episomal persistence, and are favored for their low immunogenicity and ability to target diverse tissues such as neurons and hepatocytes.[45] Lentiviral vectors can be engineered for pseudo-transient expression through non-integrating modifications, such as integrase mutations (e.g., D64V), which prevent genomic insertion while maintaining efficient reverse transcription and episomal formation for short-term transgene activity in non-dividing cells like stem cells.[46] The core mechanisms of viral delivery involve virion attachment and entry via receptor-mediated endocytosis, followed by endosomal escape, capsid uncoating in the cytoplasm to release the genome, and nuclear import through nuclear pore complexes, often facilitated by viral proteins interacting with host factors like dynein for transport.[47] These processes yield high transduction efficiencies in optimized mammalian cell cultures for vectors like adenovirus and AAV, while efficiencies for bacterial systems vary depending on the host and protocol.[47][48] Bacterial systems complement viral approaches, particularly in plant and insect applications. Agrobacterium tumefaciens facilitates transient expression in plant cells, primarily dicots, by transferring T-DNA from its Ti plasmid into the host nucleus via Vir proteins: VirD2 initiates T-strand formation and nuclear targeting, while VirE2 coats and protects the DNA during export through a type IV secretion system.[48] Baculovirus vectors excel in insect cells for high-yield transient protein production and have been adapted via BacMam hybrids—incorporating mammalian promoters—for efficient transduction in mammalian cells, achieving up to 90% expression in lines like HEK293 without replication.[49] Recent developments in the 2020s have focused on engineering viral vectors for enhanced mRNA delivery in vaccine applications, such as capsid-modified AAV variants (e.g., via directed evolution) that improve tissue tropism and transduction for transient antigen expression, as seen in trials for respiratory viruses and cancer immunotherapies.[50] Vector dosing is optimized using the multiplicity of infection (MOI), defined as \text{MOI} = \frac{\text{Number of viral particles}}{\text{Number of target cells}}, which guides the selection of doses to achieve peak transient expression while minimizing toxicity; for instance, an MOI of 10-100 often balances efficiency and cell viability in adenoviral systems.[51]Applications in Plant Cells
Agrobacterium-Mediated Transformation
Agrobacterium-mediated transient expression in plants exploits the bacterium's natural mechanism of transferring a single-stranded DNA segment, known as T-DNA, from its Ti or Ri plasmid to the plant cell nucleus without requiring stable integration into the host genome. This process is facilitated by the type IV secretion system (T4SS), composed of the VirB/VirD4 complex, which exports the T-strand—generated by VirD1/VirD2 endonuclease nicking at T-DNA borders and coated with protective VirE2 proteins—directly into the plant cytoplasm and subsequently the nucleus via nuclear localization signals on VirD2.[48] Transient expression occurs as the episomal T-DNA is transcribed by plant machinery, typically lasting days to weeks, enabling rapid analysis of gene function without genomic alteration.[52] Key protocols for delivery include agroinfiltration, where an Agrobacterium suspension (optical density at 600 nm of 0.8–1.0) is infiltrated into leaf apoplasts using a needleless syringe for manual pressure or vacuum-assisted methods for uniform distribution, with Nicotiana benthamiana serving as the preferred host due to its high susceptibility and ease of infiltration. For Arabidopsis thaliana, transient expression is commonly achieved by syringe-mediated infiltration of rosette leaves or hypocotyls in a bacterial suspension supplemented with 5% sucrose and 0.05% Silwet L-77 surfactant, targeting leaf mesophyll cells. Post-infiltration, plants are co-cultivated under controlled conditions (22–25°C, 16-hour photoperiod) for 2–3 days to allow T-DNA transfer and initial expression, often with pre-induction of virulence genes using 100–200 μM acetosyringone for 2–3 hours.[53][54] Transformation efficiencies in optimized systems reach 50–90% of mesophyll cells in N. benthamiana leaves, as visualized by reporter gene expression like GFP, while recombinant protein accumulation typically yields 1–10% of total soluble protein, with peaks at 5–7 days post-infiltration.[55] Enhancements such as co-expression of viral suppressors of RNA silencing (e.g., p19 from Tomato bushy stunt virus) or strain selection (e.g., GV3101 or AGL1) can boost yields up to 15% of total soluble protein by mitigating plant defense responses.[56] This approach supports plant-specific applications in rapid functional genomics, including subcellular localization assays and promoter analysis, often completed within a week.[54] It is particularly valuable for virus-induced gene silencing (VIGS), where Agrobacterium delivers viral vectors like Tobacco rattle virus (TRV) to trigger targeted gene knockdown, enabling reverse genetics studies in non-model plants. Since 2020, advancements have extended its use in synthetic biology for metabolic engineering, such as assembling multi-gene pathways in N. benthamiana to produce pharmaceuticals or biofuels, leveraging high-throughput co-infiltration for pathway optimization. As of 2025, further improvements include pretreatments of Agrobacterium cells and explants to enhance transient expression efficiency in recalcitrant species like citrus, and integration with synthetic gene circuits for precise control of multi-gene expression.[57][58]Direct Gene Delivery Techniques
Direct gene delivery techniques for transient expression in plants encompass mechanical and chemical methods that enable the introduction of genetic material without relying on bacterial intermediaries, effectively addressing the barrier posed by rigid plant cell walls. Particle bombardment, also known as biolistics, involves coating microparticles—typically gold or tungsten particles ranging from 0.6 to 1.6 μm in diameter—with plasmid DNA and propelling them into target cells using a high-pressure helium burst.[59] This method bypasses the cell wall by delivering the particles at velocities sufficient for penetration into the cytoplasm and nucleus, making it particularly suitable for monocotyledonous species like maize, where other delivery systems may be less effective.[59] Transient expression efficiencies with biolistics in maize can reach 10-30% of bombarded cells, as measured by reporter gene activity such as β-glucuronidase (GUS).[60] Protoplast transfection represents another key direct approach, where plant cell walls are enzymatically removed using cellulase and macerozyme to generate protoplasts, followed by DNA uptake facilitated by polyethylene glycol (PEG) mediation or electroporation.[61] PEG transfection typically involves incubating protoplasts with DNA and 40% PEG for 15-20 minutes, achieving transfection efficiencies of 60-80% in optimized systems, while electroporation uses electrical pulses to enhance uptake, yielding 10-30% efficiency depending on conditions like field strength and pulse duration.[62][63] Transient gene expression in these protoplasts is observable within 24-48 hours post-transfection, allowing rapid assessment of promoter activity, protein localization, and gene function without stable integration.[61] Beyond these established methods, viral vectors and nanoparticle-based delivery have emerged as innovative direct techniques for transient expression. Viral vectors, such as those derived from Tobacco mosaic virus (TMV), an RNA virus, enable high-level transient expression by exploiting the virus's natural replication and movement within plant cells, often achieving amplified protein production without DNA integration.[64] For instance, TMV-based vectors have been used to express reporter genes in Nicotiana species, yielding detectable signals within days of inoculation.[65] Nanoparticle delivery, particularly with gold nanoparticles (AuNPs) in the 2020s, facilitates targeted uptake by functionalizing NPs with DNA or RNA cargoes; in protoplasts, PEG-modified magnetic AuNPs (~30 nm) have achieved over 95% delivery efficiency for labeled constructs, as detected by FITC signals in canola protoplasts, with GUS gene expression confirmed after 48 hours. For intact cells, efficiencies are generally lower due to the cell wall barrier, though advancements in functionalization enable penetration via endocytosis or passive diffusion in model plants.[66] These emerging systems show promise for recalcitrant species but face challenges in scalability and cargo stability. As of 2025, viral vector-based transient systems have seen substantial methodological advancements, improving accessibility and expression levels in diverse plant species for applications like transgene-free gene editing.[67][68] Yields from direct gene delivery vary by method and species, with protoplast systems achieving up to 5% of total soluble protein (TSP) as recombinant product in optimized cases, though efficiencies drop in recalcitrant species due to poor protoplast viability or wall reformation.[69] Optimizations often focus on particle size, helium pressure in biolistics, and enzyme concentrations in protoplast isolation to maximize penetration and expression. In biolistics, particle velocity v is derived from the kinetic energy imparted by helium pressure, given by v = \sqrt{\frac{2E}{m}} where E is the energy from the pressurized helium release and m is the microparticle mass; higher pressures (e.g., 1100-1300 psi) increase v to ~400-600 m/s, enhancing penetration but risking tissue damage.[70] These techniques collectively enable versatile transient studies, though challenges persist in achieving uniform delivery across diverse plant tissues.[59]Applications in Mammalian Cells
Non-Viral Transfection Methods
Transient expression in mammalian cells commonly utilizes non-viral methods to introduce plasmid DNA or mRNA into host cells without genomic integration. Popular cell lines include Human Embryonic Kidney 293 (HEK293) cells, which offer high transfection efficiency (up to 80%) due to their susceptibility to transfection, and Chinese Hamster Ovary (CHO) cells, favored for their ability to perform human-like post-translational modifications (PTMs) such as glycosylation and disulfide bonding. Other lines like COS, HeLa, and BHK are used for specific studies.[71][2] Key delivery techniques include chemical transfection with polyethyleneimine (PEI) or cationic lipids (e.g., Lipofectamine), which form complexes with nucleic acids to facilitate endocytosis. PEI is cost-effective for large-scale applications, achieving transient expression peaks at 24–72 hours post-transfection with protein yields of 10–500 mg/L in optimized shake-flask or bioreactor cultures. Electroporation applies electric pulses to create temporary pores in the cell membrane, suitable for hard-to-transfect lines like primary cells, with efficiencies reaching 50–90% in HEK293. For mRNA-based transient expression, methods like electroporation or lipid nanoparticles enable rapid translation within hours, avoiding nuclear delivery issues of DNA.[71][2] These approaches support diverse applications, including rapid recombinant protein production for structural biology (e.g., milligram-scale antibodies), functional genomics via CRISPR/Cas9 editing, and high-throughput screening of gene variants. For instance, transient transfection in HEK293 has been pivotal for producing viral vectors like AAV for gene therapy and antigens for vaccine development, including SARS-CoV-2 spike protein during the 2020 pandemic. Yields can be enhanced by vector optimizations, such as codon usage matching the host and inclusion of post-transcriptional regulatory elements (PTREs) like woodchuck hepatitis virus posttranscriptional regulatory element (WPRE), boosting expression by 5–10 fold. As of 2024, improvements in transfection reagents and automation have scaled transient systems to multi-liter bioreactors, yielding up to 1 g/L for complex biologics.[71][2][72]Viral Vector Systems
Viral vectors provide high-efficiency transient expression in mammalian cells by leveraging natural infection mechanisms, often used when non-viral methods yield low uptake. Adenoviral vectors, with their large capacity (up to 36 kb), enable strong, short-term expression (lasting 5–7 days) in a wide range of cell types, including non-dividing cells, under promoters like CMV. Efficiencies approach 100% in HEK293, with applications in vaccine production and gene function studies. Adeno-associated virus (AAV) vectors offer lower immunogenicity and episomal persistence for 1–2 weeks, ideal for delivering therapeutic genes in preclinical models.[71][2] The BacMam system, a hybrid approach, uses recombinant baculoviruses generated in insect cells to transduce mammalian cells, achieving 70–90% infection rates at multiplicities of infection (MOI) of 5–10. This method supports secreted protein expression up to 200–500 mg/L in 48–72 hours, with glycosylation profiles closer to human than bacterial systems. It is particularly useful for membrane proteins and signaling studies in HEK293 or primary neurons. The fraction of transduced cells follows Poisson distribution: \text{Percentage infected} = 100 \times (1 - e^{-\text{MOI}}) This equation guides MOI selection to balance expression and cytotoxicity, with peak production typically 40–60 hours post-transduction at 37°C. BacMam has advanced applications in drug discovery, such as G-protein coupled receptor (GPCR) screening, and biologics manufacturing. Recent 2020s developments include engineered BacMam variants for enhanced tropism and reduced innate immune activation, improving yields for COVID-19 therapeutics. Other vectors like lentiviral pseudotypes allow transient pseudotransduction for gene silencing via shRNA.[73][74][75] Overall, viral systems excel in scalability and fidelity for PTM-requiring proteins but require biosafety level 2 handling due to replication-incompetent designs. As of 2025, they remain essential for rapid prototyping of monoclonal antibodies and viral vaccines in mammalian platforms.[71]Advantages and Limitations
Key Benefits
Transient expression systems offer significant advantages in speed, enabling researchers to obtain results within 1-4 days following transfection, compared to the 2-6 months typically required to develop and validate stable cell lines. This rapid turnaround facilitates high-throughput screening applications, allowing for rapid evaluation of multiple genetic constructs in optimized workflows. Such efficiency is particularly valuable in early-stage research where iterative testing is essential. The flexibility of transient expression stems from its non-integrative nature, which avoids permanent genomic alterations and associated risks like insertional mutagenesis, making it suitable for studying toxic proteins that might impair stable cell line establishment or for implementing transient RNA interference (RNAi) without long-term silencing effects. Additionally, transient methods provide significant cost savings relative to stable line development by eliminating extensive selection and cloning steps, reducing reagent and labor demands. In research utility, transient expression excels in functional validation of gene products, promoter activity testing, and rapid prototyping for applications like vaccines; for instance, mRNA-based COVID-19 vaccine platforms leveraged transient expression principles to achieve preclinical prototypes and clinical deployment within months during the pandemic. These systems support diverse experimental needs across plant, mammalian, and other hosts, prioritizing quick insights over sustained production. Quantitatively, optimized transient platforms can deliver peak protein expression levels up to 1 g/L in mammalian cells. This higher initial output enhances scalability for proof-of-concept studies.| Use Case | Key Benefit | Quantitative Example |
|---|---|---|
| High-throughput screening | Enables rapid parallel testing of variants | Multiple constructs evaluated per week |
| Toxic protein expression | Bypasses genomic integration issues for viability | Yields up to 1 g/L without stable selection |
| Functional validation and promoter testing | Provides quick phenotypic readouts | Results obtainable in 1-4 days post-transfection |
| Vaccine prototyping | Accelerates antigen testing and iteration | Full platforms developed in months |