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DNA construct

A DNA construct is an artificially engineered segment of DNA, typically assembled as a plasmid or larger vector, that incorporates specific genetic elements to enable the introduction and controlled expression of foreign genes in target cells or organisms.^[1] These constructs are fundamental tools in molecular biology and genetic engineering, allowing researchers to manipulate gene function for purposes such as protein production, disease modeling, and functional genomics studies.^[2] The core components of a DNA construct generally include a promoter or enhancer sequence to regulate the timing and location of gene expression, a coding region containing the gene of interest (often derived from cDNA or genomic DNA), and a polyadenylation signal to ensure proper mRNA processing and stability.^[1] Optional elements, such as insulators or boundary elements like locus control regions (LCRs) or matrix attachment regions (MARs/SARs), may be added to minimize positional effects and enhance faithful expression in the host genome.^[1] Constructs are commonly built using bacterial artificial chromosomes (BACs) for larger inserts (100–300 kb) or standard plasmids for smaller ones (<25 kb), with prokaryotic vector sequences often removed to prevent transcriptional suppression.^[1] In applications, DNA constructs facilitate techniques like pronuclear microinjection for creating transgenic mice, where they have been used since the 1980s to overexpress or knock down genes in vivo.^[1] They also play a key role in synthetic biology, where de novo synthesis assembles oligonucleotides into functional genetic circuits or even entire genomes for testing biological designs.^[2] Additionally, in single-molecule experiments, customized constructs with labeled handles (e.g., biotins) enable the study of DNA-protein interactions using tools like optical tweezers.^[3] Overall, these versatile tools underpin advances in biotechnology, from recombinant protein production to gene therapy development.^[2]

Overview

Definition and Purpose

A DNA construct is an artificially assembled DNA molecule created by combining specific DNA fragments, typically including a gene of interest and associated regulatory sequences, to enable controlled expression or manipulation within a host organism.^[4] This recombinant structure is produced through molecular biology techniques that join DNA segments from diverse sources, distinguishing it from naturally occurring DNA, which evolves without human intervention and lacks such modular engineering for targeted functions. The assembly relies on foundational tools like restriction enzymes, which cut DNA at precise recognition sites, and DNA ligase, which seals the fragments together, allowing for the creation of stable, functional units.^[4] The primary purpose of a DNA construct is to facilitate targeted genetic modifications, such as inserting, expressing, silencing, or editing genes in host cells or organisms to study biological processes or achieve practical applications.^[5] By integrating regulatory elements like promoters with the coding sequence of the gene of interest, constructs ensure that the desired genetic output occurs under specific conditions, such as in response to environmental cues or tissue types.^[1] This enables precise control over gene activity, which is essential for experiments in functional genomics and biotechnology, where natural DNA sequences alone cannot provide the required specificity or efficiency. Unlike natural DNA, which forms continuous genomic sequences shaped by evolutionary pressures, a DNA construct's engineered modularity allows customization for experimental outcomes, often carried by vectors like plasmids that propagate the construct in host cells without integrating into the genome unless intended.^[4] This design prioritizes functionality, such as high-level expression or conditional activation, over the organism's native architecture.^[1]

Importance in Biotechnology

DNA constructs have revolutionized biotechnology by enabling recombinant DNA technology, which allows the precise insertion of genes into host organisms for targeted protein production. The first successful application was the production of human insulin in 1978 using Escherichia coli bacteria engineered with a synthetic insulin gene construct, marking the advent of scalable, animal-free biomanufacturing and leading to FDA approval in 1982.^[6]^[7] This breakthrough extended to gene therapy, where DNA constructs serve as vectors to deliver therapeutic genes, correcting genetic defects in conditions like hemophilia through stable integration into host genomes, including FDA approvals for hemophilia A and B therapies in 2022-2024, and ongoing research for conditions like cystic fibrosis.^[8]^[9]^[10] In synthetic biology, these constructs facilitate the design and assembly of novel genetic circuits, enabling the engineering of microbes for biofuel production and metabolic pathway optimization.^[11]^[12] In agriculture, DNA constructs underpin genetically modified organisms (GMOs), such as herbicide-tolerant soybeans and insect-resistant corn, which incorporate transgenes like the CP4 EPSPS gene for glyphosate resistance or Bt toxin genes for pest control, enhancing crop yields and reducing pesticide use.^[13]^[14] In medicine, they drive vaccine development; DNA vaccines, consisting of plasmid constructs encoding antigens, have shown efficacy against viruses like Zika and influenza in clinical trials by inducing robust cellular and humoral immunity.^[15]^[16] For research, DNA constructs are essential in model organisms like Drosophila melanogaster and Danio rerio, where they enable gene knockdown, overexpression, or editing to study developmental biology and disease mechanisms, accelerating discoveries in human genetics.^[17]^[18] The economic impact of DNA construct innovations is profound, with the biotechnology sector growing from niche research in the 1970s to a global market valued at over $1.5 trillion by 2023, largely fueled by recombinant protein therapeutics like insulin, which reduced production costs and met rising demand for diabetes treatment affecting 589 million adults (aged 20-79) worldwide as of 2024.^[19]^[20] This includes blockbuster drugs such as monoclonal antibodies, generating annual revenues exceeding $200 billion, and GMO crops contributing $186 billion to U.S. farm income from 1996 to 2020 through increased productivity.^[21]^[22] Ethical and regulatory considerations surround DNA constructs due to their potential environmental and health risks, prompting biosafety frameworks like the U.S. Coordinated Framework for Regulation of Biotechnology (1986), which classifies GMOs under existing laws for food safety and environmental impact assessments.^[23] Debates persist over GMO labeling and long-term ecological effects, as seen in the European Union's past moratorium (1998-2004) and ongoing strict regulatory requirements until rigorous risk evaluations confirm no undue hazards, balancing innovation with public trust.^[24]^[25]

Historical Development

Origins in Recombinant DNA

The foundational concepts underlying DNA constructs emerged in the mid-20th century, building on the elucidation of DNA's molecular structure. In 1953, James D. Watson and Francis H.C. Crick proposed the double-helix model of DNA, revealing its capacity for self-replication and information storage through base pairing, which laid the theoretical groundwork for manipulating genetic material as modular components.^[26] This discovery shifted biological research toward understanding DNA as a manipulable entity, setting the stage for later engineering efforts in the 1960s and 1970s. A critical advance came with the identification of restriction enzymes, which enabled precise cleavage of DNA at specific sequences. In 1970, Hamilton O. Smith, Thomas A. Kelly, and Kent W. Wilcox isolated the first Type II restriction endonuclease, HindII, from Haemophilus influenzae, capable of cutting DNA at defined sites without requiring additional host factors, unlike earlier Type I enzymes.^[27] This tool, later refined in collaboration with Daniel Nathans for mapping viral genomes like SV40, provided the means to generate DNA fragments suitable for reassembly, addressing a key barrier to creating hybrid molecules. The first experimental realization of a recombinant DNA molecule occurred in 1972, when Paul Berg and colleagues constructed a chimeric DNA by joining segments from simian virus 40 (SV40) and bacteriophage lambda using EcoRI restriction enzyme and DNA ligase. This in vitro assembly demonstrated that disparate DNA sequences could be covalently linked to form stable, functional hybrids, marking the birth of recombinant DNA technology and establishing DNA constructs as engineered entities for genetic study. Building on this, in 1973, Herbert W. Boyer and Stanley N. Cohen developed plasmid-based cloning systems in Escherichia coli, inserting antibiotic resistance genes from one plasmid into another to create self-replicating constructs that could propagate foreign DNA in bacterial hosts. Their approach transformed DNA constructs into modular, replicable tools, leveraging plasmids' natural extrachromosomal stability for efficient propagation. Early efforts faced significant challenges, including DNA instability during ligation and compatibility issues between viral or phage elements and bacterial hosts, which often led to degradation or failed replication in E. coli systems. These hurdles were mitigated through iterative refinements in enzyme specificity and host selection, solidifying recombinant DNA as a viable framework for constructing custom genetic modules.

Key Milestones and Advances

In 1977, researchers at Genentech achieved the first successful expression of a eukaryotic gene in a bacterial host by chemically synthesizing and inserting a gene for the human hormone somatostatin into Escherichia coli, marking a pivotal step in producing eukaryotic proteins via recombinant DNA constructs.^[28] This breakthrough demonstrated the feasibility of heterologous expression systems, enabling the scalable production of therapeutic peptides and laying the groundwork for the biotechnology industry.^[29] The 1980s saw the development of shuttle vectors, which replicate in both prokaryotic and eukaryotic hosts, facilitating the transfer and manipulation of DNA constructs across species boundaries; a key example is the pIJ101 plasmid for E. coli and Streptomyces lividans described in 1982.^[30] Concurrently, the invention of the polymerase chain reaction (PCR) by Kary Mullis in 1983 revolutionized DNA amplification, allowing rapid generation of large quantities of specific DNA sequences for construct assembly without reliance on laborious cloning.^[31] The first formal description of PCR appeared in 1985, highlighting its application in enzymatic amplification of beta-globin genomic sequences. During the late 1980s and 1990s, site-specific recombination systems like Cre-loxP emerged as powerful tools for precise DNA construct manipulation; originally identified in bacteriophage P1 in 1981, Cre recombinase was adapted for eukaryotic use by 1988, enabling conditional gene activation and excision in mammalian cells.^[32] This system's expansion in the 1990s supported targeted insertions and knockouts, transforming genetic engineering.^[33] Parallel advances in viral vectors for mammalian cells, particularly adeno-associated virus (AAV) platforms refined in the late 1990s and early 2000s, improved delivery efficiency and transgene expression stability, with key breakthroughs in helper-virus-free production systems by 2001.^[34] In the 2010s, the integration of CRISPR-Cas9 into DNA constructs, first demonstrated in 2012 through in vitro reconstitution of the RNA-guided endonuclease for site-specific DNA cleavage, enabled programmable genome editing with unprecedented precision and ease.^[35] This was complemented by the creation of the first synthetic bacterial genome in 2010, where a 1.08-megabase Mycoplasma mycoides chromosome was chemically synthesized, assembled, and transplanted into a recipient cell, proving the viability of fully synthetic DNA constructs for minimal genomes.^[36] Recent advances in the 2020s have focused on derivative technologies like base editing, initially developed in 2016 but refined for higher fidelity in clinical applications, which allows single-base conversions without double-strand breaks using a deactivated Cas9 fused to a cytidine deaminase. Similarly, prime editing, introduced in 2019, employs a Cas9 nickase-reverse transcriptase fusion guided by a pegRNA to install precise insertions, deletions, or substitutions, offering expanded versatility for therapeutic constructs with minimal off-target effects.^[37] In 2020, the Nobel Prize in Chemistry was awarded to Emmanuelle Charpentier and Jennifer Doudna for the development of CRISPR-Cas9. By 2023, the first CRISPR-based gene editing therapy, exagamglogene autotemcel (Casgevy), was approved by the FDA for treating sickle cell disease and beta-thalassemia, marking a milestone in clinical application of DNA constructs.^[38]^[39]

Core Components

Regulatory Elements

Regulatory elements are non-coding DNA sequences within a DNA construct that modulate the expression of associated genes by controlling the initiation, efficiency, and termination of transcription. These elements ensure precise spatiotemporal regulation, allowing gene expression to be activated in specific cell types, developmental stages, or in response to environmental cues. In biotechnology, incorporating appropriate regulatory elements into constructs is essential for achieving desired expression levels and patterns, such as constitutive, inducible, or tissue-specific activity.^[40] Promoters serve as the primary sites for transcription initiation, recruiting RNA polymerase and transcription factors to the DNA template. Constitutive promoters, like the cytomegalovirus (CMV) promoter derived from human cytomegalovirus, drive continuous high-level expression in a wide range of mammalian cells without external stimuli, making them ideal for robust gene delivery in expression vectors. In contrast, inducible promoters, such as the lac operon promoter from Escherichia coli, enable controlled expression in response to specific inducers like isopropyl β-D-1-thiogalactopyranoside (IPTG); the lac promoter's activity is repressed by the LacI repressor protein until the inducer binds and alleviates repression, facilitating tunable gene expression in bacterial systems. Core promoter motifs, including the TATA box—a conserved AT-rich sequence located approximately 25-35 base pairs upstream of the transcription start site—position the transcription initiation complex accurately, influencing the basal transcription rate across various promoters.^[41]^[42]^[43] Enhancers, silencers, and insulators provide additional layers of spatial and temporal control by interacting with promoters over long distances. Enhancers are cis-regulatory sequences, typically 50-1500 base pairs long, that bind activator proteins to boost transcription rates, often functioning independently of their orientation or position relative to the gene; they loop DNA to contact promoters via mediator complexes, enhancing gene expression in specific contexts. Silencers, conversely, recruit repressor proteins to inhibit transcription, reducing gene activity in inappropriate cells or conditions. Insulators act as boundaries, preventing enhancers or silencers from promiscuously influencing neighboring genes by blocking their interactions or maintaining chromatin domains; for example, the chicken β-globin HS4 insulator shields transgenes from positional variegation in genomic integration sites. These elements collectively fine-tune expression to avoid off-target effects in complex eukaryotic genomes.^[44]^[45] Polyadenylation signals and terminators are crucial for post-transcriptional processing and mRNA stability. Polyadenylation signals, often featuring the consensus sequence AAUAAA in eukaryotes, direct the cleavage of pre-mRNA and addition of a poly(A) tail, which protects the mRNA from degradation and facilitates nuclear export and translation; in DNA constructs, synthetic poly(A) signals like those from the bovine growth hormone (bGH) gene ensure efficient 3' end formation. Terminators, located downstream of the poly(A) signal, promote RNA polymerase release and prevent read-through transcription into adjacent sequences, maintaining construct integrity; bacterial terminators, such as rho-independent hairpins, form stem-loop structures to halt transcription, while eukaryotic terminators couple with polyadenylation for coupled termination. These elements are vital for producing stable, mature mRNA transcripts in both prokaryotic and eukaryotic expression systems.^[46]^[47] Tissue-specific regulatory elements further restrict expression to particular cell types by integrating promoter motifs with lineage-determining transcription factors. For instance, liver-specific promoters, such as the rat phosphoenolpyruvate carboxykinase (PEPCK) promoter, incorporate binding sites for hepatocyte nuclear factor 1α (HNF-1α) to drive expression predominantly in hepatocytes, minimizing ectopic activity in other tissues. These promoters often combine core elements like the TATA box with upstream enhancer-like motifs responsive to organ-specific signals, enabling targeted gene therapy applications.^[48]

Coding and Functional Sequences

The gene of interest (GOI) in a DNA construct refers to the specific DNA sequence that encodes the target protein or functional RNA molecule intended for expression or study in the host organism.^[4] This segment typically consists of an open reading frame (ORF), which is the continuous stretch of codons from the start codon (AUG) to a stop codon, free of intervening stop codons, ensuring proper translation into the desired polypeptide. In prokaryotic designs, the GOI is often a cDNA or synthetic ORF lacking introns for direct expression, while eukaryotic constructs may include native genomic sequences with exons and introns to facilitate accurate splicing and processing in mammalian or plant cells. Selectable markers are coding sequences integrated into DNA constructs to enable the identification and selection of host cells that have successfully taken up the plasmid or vector. These markers commonly encode enzymes conferring resistance to antibiotics, such as the ampicillin resistance gene (bla or ampR), which produces β-lactamase to hydrolyze ampicillin and allow growth of transformed Escherichia coli on selective media.^[49] Introduced in the seminal pBR322 plasmid, ampR has become a standard marker due to its high efficiency in bacterial propagation, with transformed cells achieving resistance levels sufficient for colony selection at concentrations up to 100 μg/mL ampicillin.^[50] Other markers, like kanamycin resistance (kanR), function similarly by inactivating antibiotics via phosphorylation, ensuring only recombinant hosts survive.^[51] Reporter genes serve as functional coding sequences that produce easily detectable products to monitor the success of transfection, expression levels, or localization of the GOI without disrupting its function. The green fluorescent protein (GFP) gene, derived from Aequorea victoria jellyfish, is a widely used reporter that folds into a chromophore-emitting fluorescent protein detectable by fluorescence microscopy or flow cytometry, enabling real-time visualization of gene expression in living cells.^[52] First demonstrated as an in vivo marker in 1994, GFP and its variants (e.g., enhanced GFP) are fused to the GOI via linkers or expressed separately, providing non-invasive tracking with excitation at 488 nm and emission at 509 nm. Other reporters, such as luciferase from fireflies, produce bioluminescent signals quantifiable by luminometry to assess promoter activity or construct stability.^[53] Linker sequences and multiple cloning sites (MCS) enhance the modularity of DNA constructs by providing short, flexible DNA segments that connect functional elements and facilitate precise insertion of the GOI. An MCS is a polylinker region containing 10–20 unique restriction enzyme recognition sites in tandem, allowing directional cloning of inserts using compatible overhangs without disrupting other construct components.^[54] For instance, common MCS designs include sites for enzymes like EcoRI, HindIII, and BamHI, often positioned within a non-essential portion of a marker gene (e.g., lacZα in pUC vectors) for blue-white screening of recombinants.^[55] Linkers, typically 5–20 base pairs, may encode glycine-serine repeats to minimize steric hindrance in fusion proteins or serve as spacers between the GOI and reporters.^[54] Origins of replication (ori) are essential non-coding functional sequences, though sometimes classified under functional elements, that direct autonomous replication of the DNA construct within bacterial hosts like E. coli. The ColE1 ori, a medium-copy-number origin (~15–20 copies per cell), relies on RNA II priming and RNA I inhibition for regulated replication initiation at a specific 555 bp upstream site, enabling efficient plasmid amplification during cloning.^[56] Derived from the ColE1 plasmid and refined in pBR322, this ori supports copy numbers up to 500 in derivatives like pUC, balancing stability and yield for construct propagation. Yeast-specific oris, such as ARS1, function analogously in eukaryotic shuttles for Saccharomyces cerevisiae maintenance.^[57]

Construction Techniques

Traditional Cloning Methods

Traditional cloning methods, pioneered in the early 1970s, rely on restriction endonucleases to cut DNA at specific recognition sites and DNA ligase to join compatible fragments, enabling the assembly of recombinant DNA molecules for propagation in host cells. This approach, first demonstrated by Stanley Cohen and Herbert Boyer in 1973, involved the in vitro construction of functional bacterial plasmids by ligating restriction enzyme-generated fragments from separate plasmids, marking the birth of recombinant DNA technology.^[58] Their work established plasmids as versatile vector backbones, circular DNA molecules capable of autonomous replication in bacterial hosts like Escherichia coli, which serve as the foundation for inserting foreign DNA sequences.^[58] The core of traditional cloning centers on restriction enzyme digestion followed by ligation, typically using T4 DNA ligase derived from bacteriophage T4. T4 DNA ligase, discovered in 1967 by Bernard Weiss and Charles C. Richardson, catalyzes the formation of phosphodiester bonds between adjacent 3'-hydroxyl and 5'-phosphate termini on double-stranded DNA, sealing nicks or joining cohesive ends produced by restriction enzymes. Restriction enzymes, such as EcoRI or HindIII, generate sticky ends with 5' or 3' overhangs that facilitate directional ligation when compatible, ensuring the insert DNA fragment aligns precisely with the vector.^[59] A typical step-by-step process begins with PCR amplification of the insert DNA using primers designed to incorporate flanking restriction sites, allowing specific cleavage without altering the coding sequence. The amplified insert and a linearized plasmid vector, often containing a multiple cloning site (MCS), are then digested with the same restriction enzymes to produce compatible ends; the MCS provides a cluster of unique restriction sites for precise insertion. Following digestion, enzymatic reactions are purified via agarose gel electrophoresis to isolate the desired fragments, minimizing uncut or nonspecific products. The purified insert and vector are then mixed in a ligation reaction with T4 DNA ligase under optimized conditions, such as a 3:1 molar ratio of insert to vector, to promote recombinant formation while dephosphorylating the vector to prevent self-ligation.^[60] The ligated products are transformed into competent E. coli cells via heat shock or electroporation, allowing uptake and replication of the recombinant plasmids as extrachromosomal elements.^[61] To identify successful recombinants among transformed colonies, blue-white screening is commonly employed, leveraging the lacZ gene's alpha-complementation in vectors like pUC19. In this system, the MCS is embedded within a fragment of the lacZ alpha-peptide coding region; intact vectors produce functional beta-galactosidase upon induction with IPTG, hydrolyzing X-gal substrate to yield blue colonies, whereas inserts disrupting lacZ result in white colonies indicating recombination. This method, refined in the 1980s, enables rapid visual selection without individual plasmid isolation.^[59] Despite their foundational role, traditional cloning methods have notable limitations, including the introduction of scar sequences—short extraneous nucleotides from restriction sites that can alter protein expression or create unintended fusion points. Additionally, efficiency drops significantly for large inserts exceeding 10 kb, as multiple ligation events increase the risk of incomplete or incorrect assemblies, often requiring subcloning strategies or lower yields.^[62] These constraints, rooted in the enzyme-dependent nature of the technique, drove the evolution toward more advanced assembly methods in later decades.^[63]

Synthetic Biology Approaches

Synthetic biology approaches to DNA construct assembly emphasize seamless, high-efficiency methods that enable the joining of multiple DNA fragments without introducing unwanted scars or restriction sites, facilitating the construction of complex genetic circuits and large-scale synthetic genomes. These techniques, developed primarily since the early 2000s, leverage enzymatic reactions, homologous recombination, or in vivo cellular machinery to achieve precise, directional assembly in a single reaction or minimal steps, contrasting with earlier restriction enzyme-based methods by reducing labor and error rates.^[12] One seminal method is Gibson assembly, introduced in 2009, which utilizes overlap extension PCR to generate DNA fragments with 20-40 base pair homologous overlaps at their ends. In a single isothermal reaction at 50°C, a 5' exonuclease chews back the 5' ends to create single-stranded overhangs, followed by annealing of complementary overlaps and ligation by T5 DNA polymerase and Taq DNA ligase, allowing the scarless joining of up to 10 or more fragments in correct orientation. This approach has been widely adopted for assembling large constructs, such as bacterial chromosomes exceeding 100 kilobases, due to its versatility across species and compatibility with synthetic DNA synthesis.^[64] Golden Gate assembly, developed in 2008, employs type IIS restriction enzymes like BsaI, which cut outside their recognition sequences to produce unique 4-base overhangs, enabling directional and scarless cloning without leaving restriction sites in the final product. The method involves designing primers to incorporate type IIS sites flanking the desired sequences, followed by a one-pot digestion-ligation reaction where fragments are iteratively assembled into a vector, achieving near-100% efficiency for up to nine fragments in modular systems like MoClo or Golden Braid. Its modularity supports standardized parts libraries, making it ideal for plant synthetic biology and metabolic engineering pathways.^[65]^[66] Additional methods include recombineering using the lambda Red system from bacteriophage λ, which promotes homologous recombination in Escherichia coli via the Exo, Beta, and Gam proteins to integrate linear DNA fragments with short 40-50 base pair homologies directly into the genome or plasmids, enabling rapid modifications of large constructs up to megabases without in vitro cloning. For even larger assemblies, yeast transformation-associated recombination (TAR) exploits Saccharomyces cerevisiae's high-fidelity homologous recombination to circularize and join overlapping DNA fragments in vivo; a TAR vector with yeast centromere and autonomously replicating sequence elements captures genomic regions or synthetic fragments up to 100-300 kilobases by co-transformation, as demonstrated in cloning human DNA as yeast artificial chromosomes.^[67]^[68] These approaches offer significant advantages in scalability for synthetic genomes, such as the 1.08-megabase Mycoplasma mycoides genome assembled via hierarchical Gibson methods, by supporting hierarchical or iterative assembly of dozens to hundreds of fragments with efficiencies over 90%, reducing costs from thousands to hundreds of dollars per kilobase. Automation is enhanced through software platforms like Benchling, which integrates sequence design, overlap prediction, and protocol generation for Gibson and Golden Gate workflows, streamlining collaboration and high-throughput experimentation in industrial settings.^[69]^[70] Recent advancements as of 2025 have further expanded these capabilities, incorporating CRISPR-Cas systems for in vivo assembly. For instance, methods like CasHRA enable one-step assembly of over 1 Mb genomes in yeast with efficiencies around 65%, while HAnDy uses CRISPR-mediated haploidization to assemble ~1 Mb constructs in approximately 6 days. In E. coli, techniques such as REXER and CONEXER facilitate rapid replacement or assembly of large genomic segments up to 1.1 Mb using universal spacers. Additionally, AI-enabled automation in biofoundries, including robotic pipelines for mutagenesis, assembly, and transformation, has achieved 100% accuracy in constructing multi-part plasmids, accelerating the design-build-test-learn cycle in synthetic biology.^[71]^[72]

Types of Constructs

Expression Vectors

Expression vectors are specialized DNA constructs engineered to drive the high-level production of proteins or RNA molecules within host cells, typically incorporating strong promoters and other regulatory elements to achieve efficient transcription and translation. These vectors are widely used in biotechnology for recombinant protein production, enabling the expression of heterologous genes in prokaryotic or eukaryotic systems. Unlike other DNA constructs focused on genome modification, expression vectors prioritize output yield and control, often featuring inducible promoters to regulate timing and levels of expression. In bacterial expression systems, vectors such as the pET series utilize the T7 promoter, which is recognized by the bacteriophage T7 RNA polymerase, to facilitate high-yield protein production in Escherichia coli hosts like BL21(DE3). This system, originally developed by Studier and Moffatt, allows for tightly controlled, inducible expression upon addition of IPTG, achieving protein levels up to 50% of total cellular protein due to the polymerase's high specificity and processivity. The pET vectors include multiple cloning sites downstream of the promoter and ribosome binding site, making them suitable for rapid cloning and overexpression of target genes in bacterial cells optimized for industrial-scale production.^[73] For mammalian cell expression, vectors like pcDNA3.1 employ the cytomegalovirus (CMV) immediate-early promoter, a strong enhancer-promoter element that drives constitutive, high-level transcription in a broad range of mammalian cell lines, supporting transient transfection for short-term protein production. This promoter, first characterized by Boshart et al., exhibits robust activity in non-dividing and dividing cells, often yielding expression levels 10-100 fold higher than weaker viral promoters like SV40. pcDNA vectors are particularly valued for their compatibility with eukaryotic post-translational modifications, such as glycosylation, essential for functional studies of mammalian proteins. Viral expression vectors, including lentiviral systems, enable stable integration into the host genome for long-term gene expression, particularly in hard-to-transfect cells like primary neurons or stem cells. Derived from HIV-1, these self-inactivating lentiviral vectors, pioneered by Naldini et al., integrate via the viral integrase, providing sustained transgene expression over months without the immunogenicity issues of integrating retroviral vectors. They are pseudotyped with VSV-G envelope for broad tropism and can achieve transduction efficiencies exceeding 90% in vivo, making them ideal for applications requiring persistent protein output. To enhance expression efficiency, expression vectors often incorporate optimization features such as codon usage adaptation, where the gene sequence is modified to match the host's preferred codons, reducing translational pauses and increasing yields by up to 10-fold in heterologous systems. This approach, as detailed by Gustafsson et al., accounts for tRNA availability and GC content biases specific to the host organism. Additionally, fusion tags like the polyhistidine (His-tag), introduced by Hochuli et al., are commonly appended to the protein for facile purification via immobilized metal affinity chromatography (IMAC), allowing single-step isolation with purities often >95% while minimally affecting protein folding. These features collectively streamline the production pipeline from cloning to purified product.

Gene Editing Constructs

Gene editing constructs are specialized DNA molecules designed to introduce precise alterations into the genome, such as insertions, deletions, or substitutions, primarily through the induction of double-strand breaks (DSBs) that are repaired via cellular mechanisms like non-homologous end joining (NHEJ) or homology-directed repair (HDR). These constructs typically encode programmable nucleases fused to DNA-binding domains, enabling site-specific targeting, and often include donor templates for desired sequence integration. Unlike expression vectors focused on protein production, gene editing constructs prioritize genomic modification for knockouts, knock-ins, or corrections.^[74] CRISPR-Cas9 plasmids represent a cornerstone of modern gene editing constructs, featuring an expression cassette for the Cas9 endonuclease open reading frame (ORF), typically under a constitutive promoter like CMV or CAG, alongside a separate cassette for the single guide RNA (sgRNA). The sgRNA is expressed from the U6 promoter, a RNA polymerase III promoter that drives precise transcription of the 20-nucleotide guide sequence complementary to the target DNA, followed by the scaffold RNA that recruits Cas9 to form the ribonucleoprotein complex. This design allows for efficient DSB induction at user-defined loci in mammalian cells, as demonstrated in early applications where CRISPR-Cas9 achieved targeted mutagenesis rates exceeding 25% in human cell lines.^[35]^[74] Transcription activator-like effector nucleases (TALENs) and zinc finger nucleases (ZFNs) utilize modular DNA-binding domains fused to the FokI nuclease domain to create DSBs, requiring dimerization for cleavage activity. TALENs consist of customizable TALE repeats from Xanthomonas bacteria, each recognizing a single nucleotide via repeat-variable di-residues (RVDs), assembled into left and right arms spaced 12-20 base pairs apart to flank the target site. ZFNs, predating TALENs, employ zinc finger modules (typically 3-6 fingers) that bind 9-18 base pairs, also in pairs for FokI activation. These constructs have enabled targeted editing in various organisms, with TALENs showing up to 50% efficiency in human cells for specific loci. Homology-directed repair (HDR) templates are integrated into gene editing constructs or co-delivered as separate donors to facilitate precise knock-ins by providing a homologous sequence for repair following DSB induction. These templates typically include 500-800 base pair homology arms flanking the desired insertion, such as a corrected exon or reporter gene, with optional selection markers like puromycin resistance for enrichment. Linear double-stranded DNA, single-stranded oligodeoxynucleotides (ssODNs), or circular plasmids serve as donor formats, with ssODNs achieving HDR efficiencies of 10-20% in CRISPR-edited cells when targeting non-dividing loci. Design considerations emphasize avoiding Cas9 re-cleavage by incorporating silent mutations at the protospacer adjacent motif (PAM) within the homology arms.^[74] To mitigate off-target effects inherent in programmable nucleases, gene editing constructs incorporate high-fidelity variants, such as SpCas9-HF1 for CRISPR-Cas9, which features four amino acid substitutions (N497A, R661A, Q926A, D1135V) that reduce non-specific interactions while preserving on-target activity. This variant exhibits no detectable genome-wide off-target mutations in human cells, even at high expression levels, compared to wild-type Cas9's off-target rates of up to 10%. Similar strategies for TALENs and ZFNs involve optimizing spacer lengths and RVD/finger affinities to enhance specificity.

Delivery and Transfection

In Vitro Delivery Methods

In vitro delivery methods enable the introduction of DNA constructs, such as plasmids, into isolated cells or tissues under controlled laboratory conditions, facilitating transient or stable genetic modification for research purposes. These techniques are essential for studying gene function in cell culture systems, where efficiency is measured by transfection rates—the percentage of cells successfully incorporating the DNA—and balanced against cytotoxicity, which can reduce cell viability and experimental reliability. Common methods prioritize non-viral approaches to avoid immune responses associated with viral vectors, though they often yield lower efficiencies in primary or hard-to-transfect cells. Chemical transfection relies on reagents that form complexes with DNA constructs to facilitate uptake through endocytosis in cultured eukaryotic cells. Lipofectamine, a cationic lipid formulation, is widely used for transient transfection due to its high efficiency in mammalian cell lines like HEK293 and HeLa, achieving up to 90% transfection rates under optimized conditions with minimal toxicity when dosed appropriately. Similarly, calcium phosphate precipitation, a classical method introduced in the 1970s, involves mixing DNA with calcium chloride and phosphate buffer to create a DNA-calcium-phosphate coprecipitate that adheres to cell surfaces for internalization; it is cost-effective and suitable for large-scale transfections but can exhibit batch-to-batch variability and higher cytotoxicity in sensitive cell types. Both methods typically result in transient expression lasting days to weeks, as the DNA does not integrate into the genome without additional selection markers. Electroporation delivers DNA constructs by applying short electric pulses to create transient pores in the cell membrane, allowing direct entry of nucleic acids without chemical intermediaries. This physical method is versatile, optimized for both prokaryotic cells like E. coli, where pulse durations of 4-5 ms yield transformation efficiencies exceeding 10^9 transformants per microgram of DNA, and mammalian cell lines such as CHO or Jurkat, achieving 70-80% transfection rates with reduced cytotoxicity through nucleofection variants that target the nucleus. Seminal work in the 1980s established electroporation parameters, including field strengths of 0.5-2.5 kV/cm, to minimize irreversible membrane damage while maximizing DNA uptake; however, it requires specialized equipment and can cause cell stress, necessitating post-pulse recovery protocols. Efficiency often correlates with DNA concentration and cell density, with cytotoxicity dropping below 20% in optimized protocols for high-throughput applications. Microinjection provides precise, direct delivery of DNA constructs into individual cells or cellular compartments using a fine glass needle under microscopic guidance, ideal for low-throughput experiments requiring high specificity. Commonly applied to oocytes, embryos, or isolated nuclei, this technique ensures nearly 100% delivery success per injected cell by bypassing membrane barriers, as demonstrated in early studies on Xenopus laevis eggs where microinjected plasmids expressed reporter genes with minimal off-target effects. It is particularly valuable for hard-to-transfect primary cells or when cytotoxicity must be avoided, though labor-intensive and limited to small sample sizes; transfection efficiency is effectively 100% for targeted cells, but overall yield depends on injection volume (typically 1-10 picoliters) and operator skill. Cytotoxicity is low compared to bulk methods, primarily arising from mechanical stress rather than reagents.

In Vivo Delivery Systems

In vivo delivery systems for DNA constructs aim to introduce genetic material directly into living organisms, enabling therapeutic gene expression or experimental manipulation in target tissues while navigating physiological barriers such as circulation, immune surveillance, and cellular uptake.^[75] These methods are essential for applications like gene therapy, where sustained transgene expression is required without genomic integration to minimize risks of insertional mutagenesis.^[76] Viral and non-viral approaches dominate, each balancing efficiency, safety, and specificity. Viral vectors, particularly adeno-associated virus (AAV) serotypes, are widely used for in vivo delivery due to their low immunogenicity, non-integrating nature, and ability to transduce non-dividing cells.^[77] AAV vectors facilitate long-term gene expression in post-mitotic tissues like retina and muscle, with serotype-specific tropisms guiding tissue targeting.^[76] A seminal example is Luxturna (voretigene neparvovec), an AAV2-based therapy approved in 2017 for treating inherited retinal dystrophy caused by RPE65 mutations, where subretinal injection restores vision through non-integrating delivery of the functional RPE65 gene.^[78] This approach has demonstrated durable efficacy in clinical trials, with patients showing improved multi-luminance mobility testing scores for up to 9 years post-administration as of 2024.^[79]^[80] More recently, delandistrogene moxeparvovec (Elevidys), an AAVrh74-based therapy fully approved by the FDA in 2024 for Duchenne muscular dystrophy, delivers a micro-dystrophin gene via intramuscular injection to ambulatory and non-ambulatory patients.^[81] Non-viral systems offer safer alternatives by avoiding viral immunogenicity, though they often achieve lower transfection efficiency.^[82] Nanoparticles and liposomes encapsulate DNA constructs to protect against nuclease degradation and enhance cellular uptake via endocytosis, enabling targeted delivery to organs like the liver or tumors through surface modifications such as PEGylation or ligand conjugation.^[83] For instance, lipid nanoparticles have been optimized for systemic administration, achieving significant hepatocyte transfection in preclinical models.^[84] Hydrodynamic injection, involving rapid intravenous infusion of a large DNA solution volume, exploits fluid pressure to permeabilize liver endothelium, resulting in near-complete hepatocyte transfection in rodents—efficiencies exceeding 90%—and has been adapted for localized delivery in larger animals.^[85] Physical methods like biolistics, or gene gun delivery, propel DNA-coated microprojectiles into target tissues using high-velocity gas, bypassing endosomal barriers for direct cytosolic access.^[86] This technique is particularly effective for plants, where it has enabled stable transformation of crops like maize by delivering constructs into callus tissues, yielding transgenic lines with herbicide resistance.^[87] In animals, handheld gene guns facilitate epidermal delivery in skin for vaccine studies, achieving transient expression in keratinocytes detectable for up to four days post-bombardment.^[86] Despite advances, in vivo delivery faces significant challenges, including immune responses that can neutralize vectors or transgene products, reducing efficacy and causing inflammation.^[88] AAV vectors, for example, elicit capsid-specific T-cell responses in up to 50% of patients, leading to hepatocyte destruction and loss of transgene expression.^[89] Tissue specificity remains a hurdle, as many AAV serotypes exhibit strong liver tropism—AAV8 and AAV9 transduce over 80% of hepatocytes after intravenous administration—limiting extrahepatic applications unless capsid engineering redirects tropism.^[90] Strategies like transient immunosuppression or serotype selection mitigate these issues, but off-target effects and biodistribution variability persist in clinical translation.^[77]

Applications

Research and Diagnostics

DNA constructs play a pivotal role in functional genomics by enabling the study of gene regulation and signaling pathways through reporter systems. Reporter constructs, such as those incorporating the firefly luciferase gene, are fused to promoter regions of interest to monitor transcriptional activity in real-time. For instance, luciferase assays quantify pathway activation by measuring bioluminescent output following substrate addition, providing high sensitivity for detecting subtle changes in gene expression. These constructs have been widely adopted for dissecting cellular responses to stimuli, including cytokine signaling and viral infections, due to their non-invasive detection and quantitative precision.^[91] In model organism engineering, DNA constructs are essential for creating transgenic animals that recapitulate human diseases. Pronuclear injection involves microinjecting linearized DNA constructs into the pronuclei of one-cell-stage zygotes, leading to random genomic integration and germline transmission of the transgene. This technique, pioneered in the early 1980s, has generated seminal models like those overexpressing oncogenes to study tumorigenesis or knocking down genes to mimic metabolic disorders such as Tangier disease. Transgenic mice produced via this method allow longitudinal observation of disease progression, facilitating insights into genetic mechanisms underlying conditions like cancer and neurodegeneration.^[92] Diagnostic tools leveraging DNA constructs include biosensors that employ promoter-driven reporters for pathogen detection. These systems integrate transcription factors responsive to pathogen-specific signals, such as quorum-sensing molecules, with promoters controlling reporter genes like GFP or luciferase. Upon analyte binding, the transcription factor activates the promoter, inducing reporter expression that signals pathogen presence through fluorescence or luminescence. Examples include E. coli-based sensors detecting Pseudomonas aeruginosa via N-acyl homoserine lactones, enabling rapid, portable identification in environmental samples like water. Such constructs offer specificity and sensitivity for early disease detection without complex instrumentation.^[93] High-throughput screening in drug discovery utilizes CRISPR library constructs to systematically perturb genes and identify therapeutic targets. These libraries consist of pooled guide RNA (gRNA) arrays delivered via lentiviral vectors, targeting thousands of genes to create loss-of-function phenotypes in cell populations. Screens readout via next-generation sequencing or phenotypic assays reveal genes modulating drug sensitivity, such as those involved in cancer synthetic lethality. For example, genome-wide CRISPR knockout libraries have pinpointed vulnerabilities in RAS-driven tumors, accelerating candidate validation and reducing development timelines. This approach enhances discovery efficiency by integrating functional genomics with pharmacological testing.^[94]

Therapeutic and Industrial Uses

DNA constructs play a pivotal role in gene therapy for monogenic diseases, delivering functional genes to correct genetic deficiencies. A prominent example is Zolgensma (onasemnogene abeparvovec-xioi), an adeno-associated virus (AAV9) vector-based construct that carries a functional copy of the human SMN1 gene to treat spinal muscular atrophy (SMA), a neuromuscular disorder caused by mutations in the SMN1 gene leading to motor neuron loss.^[95] Administered as a one-time intravenous infusion, the construct enables motor neuron cells to produce the survival motor neuron (SMN) protein, improving muscle function and survival rates in pediatric patients under two years old.^[95] The U.S. Food and Drug Administration (FDA) approved Zolgensma on May 24, 2019, marking a milestone in AAV-mediated gene therapy for SMA, with clinical trials demonstrating sustained motor milestone achievement in treated infants.^[95] Another advancement is Casgevy (exagamglogene autotemcel), a CRISPR/Cas9-based gene-editing therapy using lentiviral vectors to deliver DNA constructs that edit the BCL11A gene in hematopoietic stem cells, reactivating fetal hemoglobin production to treat sickle cell disease (SCD) and transfusion-dependent beta-thalassemia (TDT). Approved by the FDA on December 8, 2023, for SCD in patients 12 years and older, and on January 16, 2024, for TDT, Casgevy involves ex vivo editing followed by autologous stem cell transplantation, offering potential for long-term disease modification with clinical trials showing elimination of vaso-occlusive crises in SCD patients.^[39] In vaccine development, DNA constructs serve as plasmids encoding pathogen antigens to elicit immune responses without live virus risks. ZyCoV-D, developed by Zydus Cadila, is a plasmid-based DNA vaccine using the pVAX1 vector to encode the full-length SARS-CoV-2 spike protein with an IgE leader sequence, promoting antigen expression in host cells for humoral and cellular immunity.^[96] Delivered intradermally via a needle-free device, it induces neutralizing antibodies and T-cell responses against COVID-19.^[96] Phase 3 trials in India involving over 27,000 participants showed 66.6% efficacy against symptomatic COVID-19, with 100% protection against moderate and severe disease, and a favorable safety profile with mostly mild adverse events like injection-site pain.^[96] The Drug Controller General of India granted emergency use authorization in August 2021, establishing ZyCoV-D as the first approved DNA vaccine for human use.^[96] Industrial biotechnology leverages DNA constructs for metabolic engineering to enhance microbial production of biofuels. In yeast, constructs integrating genes for xylose utilization enable efficient fermentation of lignocellulosic biomass into ethanol, addressing limitations in native Saccharomyces cerevisiae pathways that favor glucose.^[97] A key advancement involves engineering strains with bacterial xylose isomerase and transporters, alongside cellobiose hydrolysis genes, allowing simultaneous co-fermentation of glucose, xylose, and cellobiose from pretreated biomass.^[97] This engineered S. cerevisiae strain achieved ethanol yields up to 89% of theoretical maximum from mixed sugars, reducing fermentation time and by-products like xylitol, thus improving second-generation biofuel scalability.^[97] Such constructs, demonstrated in a 2010 study, have informed industrial strains for sustainable ethanol production from agricultural waste.^[97] Agricultural applications utilize DNA constructs to confer traits like herbicide resistance, boosting crop yields and simplifying weed management. Roundup Ready soybeans incorporate the CP4 EPSPS gene from Agrobacterium sp. strain CP4, encoding a glyphosate-insensitive 5-enolpyruvylshikimate-3-phosphate synthase enzyme that sustains the shikimate pathway essential for aromatic amino acid synthesis despite herbicide exposure.^[98] The construct, integrated via Agrobacterium-mediated transformation, results in stable expression in event GTS 40-3-2, allowing selective weed control without crop damage.^[98] The U.S. FDA and USDA approved this construct for commercialization in 1994, leading to widespread adoption; by 2005, over 87% of U.S. soybeans were glyphosate-tolerant, enhancing productivity through reduced tillage and herbicide use.^[99] The CP4 EPSPS protein's structural modification at residue 100 prevents glyphosate binding, ensuring robust resistance validated across crop generations.^[98]

References

[1]
Strategies for Designing Transgenic DNA Constructs - PMC
Generating a typical transgenic construct involves assembling three basic DNA elements: (1) a promoter and/or enhancer which confers the desired spatial and ...
[2]
Specific Synthetic Biology Concepts, Approaches, and Tools - NCBI
Jun 19, 2018 · In its most basic form, DNA construction produces oligonucleotides (oligos), single strands of user-defined ... DNA construct has been synthesized ...
[3]
DNA Construct - an overview | ScienceDirect Topics
A DNA construct refers to a customized large DNA plasmid that is designed and fabricated for single-molecule experiments aimed at understanding the mechanism ...
[4]
Isolating, Cloning, and Sequencing DNA - NCBI - NIH
In one sense it literally refers to the act of making many identical copies of a DNA molecule—the amplification of a particular DNA sequence.Large DNA Molecules Are Cut... · Gel Electrophoresis Separates...
[5]
Recombinant DNA Technology
Recombinant DNA technology involves using enzymes and various laboratory techniques to manipulate and isolate DNA segments of interest.
[6]
Recombinant Protein Production: The Future of Biotechnology
Apr 4, 2023 · Insulin was the first recombinant protein produced using recombinant DNA technology in 1978. Before this advanced technology, insulin was ...
[7]
Historical Background and Biotechnology Milestones of ... - Biointron
Sep 29, 2025 · The first therapeutic recombinant protein, human insulin, was produced in E. coli by Genentech in 1978 and approved by the FDA in 1982. This ...
[8]
Integrating DNA vectors for gene therapy - PMC - NIH
Nonviral, integrating DNAs have reached a tipping point in establishing themselves as potential vectors for gene therapy.
[9]
Applications of genome editing technology in the targeted therapy of ...
Jan 3, 2020 · We review recent advances of the three major genome editing technologies (ZFNs, TALENs, and CRISPR/Cas9) and discuss the applications of their derivative ...<|separator|>
[10]
Synthetic DNA Synthesis and Assembly - PubMed Central - NIH
Depending on the results the constructs can then be modified or refined and the test cycle is repeated until a DNA construct is obtained that produces the ...
[11]
Recent advances in DNA assembly technologies - PMC
It employs iterative cycles of restriction digestion and ligation reactions to assemble small DNA parts into a large DNA construct (Smolke, 2009; Sarrion- ...Missing: definition | Show results with:definition
[12]
GMO Crops, Animal Food, and Beyond - FDA
Mar 5, 2024 · For example, cornstarch can be made with GMO corn and sugar can be made with GMO sugar beets. GMO Crops. Corn: Corn is the most commonly grown ...
[13]
Genetically engineered crops for sustainably enhanced food ...
The DNA construct with the gene of interest is introduced into the plants via Agrobacterium tumefaciens or gene gun (particle bombardment) (Lacroix and Citovsky ...<|control11|><|separator|>
[14]
DNA Vaccines: History, Molecular Mechanisms and Future ...
DNA vaccination technologies using naked plasmids is the first type of genetic vaccines developed, followed by viral vectors and mRNA.
[15]
The next-generation DNA vaccine platforms and delivery systems
Secondly, DNA vaccines have flexible construction and can be easily manipulated using molecular technology. The designed DNA vaccine can specifically express ...Abstract · Current status and challenges... · DNA delivery systems · Expert opinion
[16]
Developmental genetics with model organisms | PNAS
Jul 18, 2022 · Genetic animal model organisms with large research communities are the nematode Caenorhabditis elegans, the fly Drosophila melanogaster, the zebrafish Danio ...
[17]
Making designer mutants in model organisms | Development
Nov 1, 2014 · Unlike classical homologous recombination (HR), HDR can use short DNA templates as donors, including single-stranded oligonucleotides. HDR is ...Introduction · Designer Endonucleases... · Applications: Designer...
[18]
[PDF] The Economic Impact of Biotechnology - Southwest Economy, Issue ...
Apr 19, 2002 · Stanley Cohen and Herbert Boyer's transfer of DNA from one organism to another in 1973 was a major milestone in biotech, leading to an explosion ...
[19]
The impact of biotechnology on the global insulin market
May 13, 2025 · Biotechnology has had a dramatic impact on how insulin is manufactured, and how much it costs to produce it. This paper examines the political, ...Missing: constructs | Show results with:constructs
[20]
[PDF] Guide to U.S. Regulation of Genetically Modified Food and ...
are regulated under the same U.S. laws that govern the health, safety, efficacy, and environmental impacts of similar products derived by more.
[21]
Genetically modified organisms: adapting regulatory frameworks for ...
Oct 20, 2022 · New genome editing techniques are opening new avenues to genetic modification development and uses, putting pressure on these frameworks.
[22]
Biosafety legislation and the regulatory status of the products of ...
Dec 6, 2021 · Precision breeding represents a new challenge for biosafety regulators when applying the legal definition of living modified organisms ...
[23]
A Structure for Deoxyribose Nucleic Acid - Nature
The determination in 1953 of the structure of deoxyribonucleic acid (DNA), with its two entwined helices and paired organic bases, was a tour de force in ...
[24]
Expression in Escherichia coli of a Chemically Synthesized Gene for ...
A gene for somatostatin, a mammalian peptide (14 amino acid residues) hormone, was synthesized by chemical methods. This gene was fused to the Escherichia coli ...
[25]
Making, Cloning, and the Expression of Human Insulin Genes ... - NIH
This was first accomplished in E coli, which expressed a synthetic gene for somatostatin and was reported in 1977. A similar approach was employed in E coli ...
[26]
Shuttle vectors for cloning recombinant DNA in Escherichia coli and ...
Shuttle vectors for cloning recombinant DNA in Escherichia coli and Streptomyces griseofuscus C581. ... 1980 Apr 10;284(5756):526–531. doi: 10.1038/284526a0. [DOI] ...
[27]
Kary B. Mullis – Facts - NobelPrize.org
In 1985, Kary Mullis invented the process known as polymerase chain reaction (PCR), in which a small amount of DNA can be copied in large quantities over a ...
[28]
The Cre-lox and FLP-FRT systems - The Jackson Laboratory
The Cre-lox system. Cre-lox technology was introduced in the 1980s (Sauer and Henderson 1988; Sternberg and Hamilton 1981) and patented by DuPont ...
[29]
Cre-Lox Neurogenetics: 20 Years of Versatile Applications in Brain ...
In the late 1980s and early 1990s, following the pioneering efforts by Mario Capecchi, Oliver Smithies, and Martin Evans on gene targeting and embryonic stem ...Young and Foolish · Cre-Driver Resources for... · Cre-Driving Toward Multiple...
[30]
Gene therapy then and now: A look back at changes in the field over ...
May 7, 2025 · ... virus (AAV) was developed as a mammalian gene transfer vector ... The late 1990s to early 2000s saw major breakthroughs for AAV vector development ...
[31]
A Programmable Dual-RNA–Guided DNA Endonuclease ... - Science
Jun 28, 2012 · Our study reveals a family of endonucleases that use dual-RNAs for site-specific DNA cleavage and highlights the potential to exploit the system for RNA- ...
[32]
Creation of a Bacterial Cell Controlled by a Chemically Synthesized ...
May 20, 2010 · We report the design, synthesis, and assembly of the 1.08–mega–base pair Mycoplasma mycoides JCVI-syn1.0 genome starting from digitized genome sequence ...Missing: laboratorium | Show results with:laboratorium
[33]
Search-and-replace genome editing without double-strand ... - Nature
Oct 21, 2019 · Here we describe prime editing, a versatile and precise genome editing method that directly writes new genetic information into a specified DNA site.
[34]
Promoters - Addgene
It is not unusual to have several regulatory elements, such as enhancers, several kilobases away from the transcription start site (TSS). Eukaryotic promoters ...<|separator|>
[35]
Impact of Different Promoters on Episomal Vectors Harbouring ...
May 26, 2016 · We conclude that the CMV promoter performs best in terms of yielding both high expression levels and high levels of stability using this episomal vector system.Results · Recombinant Protein... · Gene Copy Number Analysis
[36]
Exploitation of the Escherichia coli lac operon promoter for ...
The E. coli lac operon promoter is used to control recombinant protein production in bacteria, especially in E. coli, and is widely used in biotech.<|separator|>
[37]
Liver cell specific gene transcription in vitro: the promoter elements ...
Liver cell specific gene transcription in vitro: the promoter elements HP1 and TATA box are necessary and sufficient to generate a liver-specific promoter.
[38]
Enhancers: five essential questions - PMC - PubMed Central - NIH
Enhancers are DNA-regulatory elements that activate transcription of a gene or genes to higher levels than would be the case in their absence. These elements ...
[39]
Chromatin insulators: regulatory mechanisms and epigenetic ...
Enhancer-blocking insulators are DNA elements that disrupt the communication between a regulatory sequence, such as an enhancer or a silencer, and a promoter.
[40]
Ending the message: poly(A) signals then and now
Polyadenylation [poly(A)] signals (PAS) are a defining feature of eukaryotic protein-coding genes. The central sequence motif AAUAAA was identified in the mid- ...
[41]
Plasmids 101: Terminators and PolyA signals - Addgene Blog
Mar 31, 2016 · Terminators are found downstream of the gene to be transcribed, and typically occur directly after any 3' regulatory elements, such as the polyadenylation or ...
[42]
Targeting of therapeutic gene expression to the liver by using liver ...
The tissue-specific activation of the LPKPP by the viral enhancer was attributed to HNF-1α binding to the LPKPP. Taken together, these results support the idea ...
[43]
Construction and characterization of new cloning vehicles. II. A ...
The antibiotic-resistant genes on pBR322 are not transposable. The vector pBR322 was constructed in order to have a plasmid with a single PstI site, located in ...
[44]
PBR322 - an overview | ScienceDirect Topics
The two antibiotic resistance genes possess unique cloning sites for the insertion of DNA fragments. Opening the plasmid with an RE and inserting a compatible ...
[45]
The art of vector engineering: towards the construction of next ...
The shuttle vector pALS‐1, originally described by Sthol and Lambowitz (1983), is a 13.1 kb recombinant plasmid that replicates in both N. crassa and E. coli; ...
[46]
Green fluorescent protein as a marker for gene expression - PubMed
A complementary DNA for the Aequorea victoria green fluorescent protein (GFP) produces a fluorescent product when expressed in ... 1994 Feb 11;263(5148):802-5. doi: 10.1126/science.8303295.
[47]
Reporter Gene - an overview | ScienceDirect Topics
The most common reporter genes are GFP and its variants. When placed ... 4), including bacteria (Chalfie et al., 1994; Christensen et al., 1996) and ...
[48]
Simplified plasmid cloning with a universal MCS design and ... - NIH
Mar 15, 2021 · We developed and standardized a plasmid cloning protocol based on a universal MCS (Multiple Cloning Site) design and bacterial in vivo assembly.
[49]
New cloning vectors and techniques for easy and rapid restriction ...
Each vector is constructed so that it contains the rarely found NotI restriction site joined to a short synthetic linker sequence that is followed by a multiple ...
[50]
Replication and Control of Circular Bacterial Plasmids - PMC
The origin of ColE1 replication, defined as the transition point between RNA II primer and DNA synthesized by DNA Pol I, has been positioned 555 bp downstream ...
[51]
A plasmid system with tunable copy number | Nature Communications
Jul 7, 2022 · In the ColE1 Origin, reversible binding of the inhibitory RNA-i to RNA-p exercises control over the copy number by inhibiting replication (left ...
[52]
Construction of Biologically Functional Bacterial Plasmids In Vitro
Abstract. The construction of new plasmid DNA species by in vitro joining of restriction endonuclease-generated fragments of separate plasmids is described.
[53]
Molecular Cloning Techniques - Addgene
Two pieces of DNA that have complementary overhangs, or which are both blunt-ended, can then be fused during a ligation reaction with T4 DNA ligase. Restriction ...
[54]
https://pmc.ncbi.nlm.nih.gov/articles/PMC7962268/
[55]
Traditional Cloning Basics | Thermo Fisher Scientific - ES
The first step in preparing the vector for traditional cloning is to create an insertion site by restriction digestion. The choice of restriction enzymes ...
[56]
Scarless Cloning with Golden Gate Assembly - US
Limited availability of unique restriction sites: Avoiding restriction sites within longer DNA sequences of interest is relatively difficult. This limitation ...
[57]
https://www.nature.com/articles/s41467-022-31422-0
[58]
Enzymatic assembly of DNA molecules up to several ... - PubMed
We describe an isothermal, single-reaction method for assembling multiple overlapping DNA molecules by the concerted action of a 5' exonuclease, ...
[59]
A one pot, one step, precision cloning method with high ... - PubMed
Nov 5, 2008 · A cloning strategy called 'Golden Gate' cloning was devised that allows to obtain in one tube and one step close to one hundred percent correct recombinant ...
[60]
A User's Guide to Golden Gate Cloning Methods and Standards
Nov 2, 2022 · We provide a beginner-friendly guide to Golden Gate assembly, compare the different available standards, and detail the specific features and quirks of ...Introduction · The Golden Gate Core Method · Hierarchical Assembly
[61]
Use of the λ Red-recombineering method for genetic engineering of ...
Apr 23, 2009 · The λ Red-recombineering method is a high-performance tool for rapid, precise genome modifications in Pantoea ananatis, using a selected mutant ...
[62]
Specific cloning of human DNA as yeast artificial chromosomes by ...
We reasoned that transformation-associated recombination (TAR) could be employed to clone large DNAs containing repeat sequences, thereby eliminating the need ...<|separator|>
[63]
DNA Synthesis, Assembly and Applications in Synthetic Biology - PMC
Such technologies hold the potential for significantly increasing the throughput and decreasing the cost of gene synthesis. Together with more efficient ...
[64]
Benchling and AstraZeneca
Learn how AstraZeneca used Benchling to create an automated DNA assembly framework to support rapid and cost-efficient construct generation.
[65]
Use of bacteriophage T7 RNA polymerase to direct selective high ...
A gene expression system based on bacteriophage T7 RNA polymerase has been developed. T7 RNA polymerase ... 1986 May 5;189(1):113-30. doi: 10.1016/0022-2836(86)90385-2. Authors. F W Studier, B A Moffatt.
[66]
Multiplex Genome Engineering Using CRISPR/Cas Systems - Science
We engineered two different type II CRISPR/Cas systems and demonstrate that Cas9 nucleases can be directed by short RNAs to induce precise cleavage at ...Missing: mammalian cells
[67]
The promise and challenge of in vivo delivery for genome therapeutics
Another major advantage to AAV over lentivirus is that multiple serotypes of AAV exist with different intrinsic or engineered tropism for various tissues such ...
[68]
Adeno-associated virus as a delivery vector for gene therapy of ...
Apr 3, 2024 · Adeno-associated virus (AAV) has emerged as a pivotal delivery tool in clinical gene therapy owing to its minimal pathogenicity and ability to establish long- ...
[69]
Emerging Issues in AAV-Mediated In Vivo Gene Therapy - PMC
In this review, we will give an overview on the biology of AAV vector, discuss the design of AAV-based gene therapy strategies for in vivo applications,
[70]
Overview of Retinal Gene Therapy: Current Status and Future ... - NIH
The first viral vector-delivered gene therapy, Luxturna, has been approved and is used to treat a previously untreatable disease.
[71]
Nanodelivery of nucleic acids | Nature Reviews Methods Primers
Apr 14, 2022 · Lipid-based nanoparticles, polymeric nanoparticles and inorganic nanoparticles are the most common non-viral nanocarriers for nucleic acid delivery.
[72]
Lipid-Based Nanoparticles for Drug/Gene Delivery: An Overview of ...
Aug 21, 2023 · In this review, we introduce the main types of LNPs used in drug formulations such as liposomes, nanoemulsions, solid lipid nanoparticles, nanostructured lipid ...
[73]
Enhancing non-viral DNA delivery systems: Recent advances in ...
Feb 10, 2025 · This review focuses on recent progress in the design of non-viral delivery systems for enhancing targeted DNA delivery and modulation of therapeutic efficiency.
[74]
Hydrodynamic Delivery: Characteristics, Applications, and ... - PMC
Hydrodynamic delivery was established in 1999 as a simple and efficient nonviral method for the delivery of plasmids to hepatocytes in mice.
[75]
Evaluation of biolistic gene transfer methods in vivo using non ...
Jun 2, 2011 · For biolistic transfer to skin, the barrel ring of the Gene Gun was lightly touching the skin. For biolistic transfer to liver, an abdominal ...
[76]
An improved biolistic delivery and analysis method for evaluation of ...
Biolistic delivery, also known as gene gun or particle bombardment, has been widely used to introduce DNA into plant tissues, both for transient expression and ...Missing: vivo | Show results with:vivo
[77]
Immune responses to AAV vectors: overcoming barriers to ...
Immune responses may be directed against the AAV vector component or the transgene product, or both. Animal models predicted many aspects of the human immune ...Aav Viruses And Recombinant... · Adaptive Immunity To Aav... · The Aav8-F. Ix Trial
[78]
Challenges Posed by Immune Responses to AAV Vectors - Frontiers
Host immune responses that limit durable therapeutic gene expression and cause clinically significant inflammation remain a major barrier to broadly ...
[79]
https://pmc.ncbi.nlm.nih.gov/articles/PMC10317065/
[80]
Advancements in the application of reporter gene cell lines in ...
Sep 24, 2025 · Due to its easy detection and high sensitivity, luciferase is one of the most commonly used enzymes in reporter gene assays for biological ...
[81]
Generating mouse models for biomedical research: technological ...
Jan 8, 2019 · To produce transgenic mice, a DNA construct is microinjected into the pronuclei (Box 1) of one-cell-stage zygotes (Bockamp et al., 2008). All or ...
[82]
Transcription Factor-Based Biosensors for Detecting Pathogens - PMC
We focused on the recent studies of transcription factor (TF)-based biosensors to detect microorganisms and discuss their perspectives and applications.Missing: driven | Show results with:driven
[83]
High-content CRISPR screening | Nature Reviews Methods Primers
Feb 10, 2022 · This Primer describes the basic and advanced concepts of CRISPR screening and its application as a flexible and reliable method for biological discovery.
[84]
FDA approves innovative gene therapy to treat pediatric patients ...
May 24, 2019 · Zolgensma is indicated for the treatment of children less than two years of age with SMA. The product is an adeno-associated virus vector-based ...
[85]
https://pmc.ncbi.nlm.nih.gov/articles/PMC10141091/
[86]
Engineered Saccharomyces cerevisiae capable of simultaneous ...
Dec 27, 2010 · The resulting yeast strains, cofermented cellobiose and xylose simultaneously and exhibited improved ethanol yield when compared to fermentation ...
[87]
Molecular basis for the herbicide resistance of Roundup Ready crops
Aug 29, 2006 · Roundup Ready crop lines contain a gene derived from Agrobacterium sp. strain CP4, encoding a glyphosate-tolerant enzyme, the so-called CP4 EPSP ...
[88]
[PDF] Roundup Ready Soybeans and Bt Field Corn
Approvals for commercialization of glyphosate tolerant soybeans were granted by FDA and USDA in. 1994 and by EPA in 1995. Glyphosate tolerant soybeans, commonly ...