ABSTRACT
Transient gene expression (TGE) in mammalian cells is a well-known approach to the fast expression of recombinant proteins. The human cell line HEK (human embryonic kidney) 293F is widely used in this field, due to its adaptability to grow in suspension to high cell densities in serum-free media, amenability to transfection, and production of recombinant proteins in satisfactory quantities for functional and structural analysis. Amounts of plasmid DNA (pDNA) required in transfections for TGE remain high (usually 1 µg pDNA/mL, or even higher), representing a noticeable proportion of the overall cost. Thus, there is an economic need to reduce amounts of coding pDNA in TGE processes. In this work, amounts of both pDNA and transfecting agent used for TGE in HEK 293F cells have been explored in order to reduce them without compromising (or even improving) the productivity of the process in terms of protein yield. In our hands, minimal polyethyleneimine (PEI) cytotoxicity and optimum protein yields were obtained when transfecting at 0.5 µg pDNA/mL (equal to 0.5 µg pDNA/million cells) and a DNA-to-PEI ratio of 1:3, a trend confirmed for several unrelated recombinant proteins. Thus, carefully tuning pDNA and transfecting agent amounts not only reduces the economic costs but also results in higher recombinant protein yields. These results surely have a direct application and interest for the biopharmaceutical industry, always concerned in increasing productivity while decreasing economic costs. KEY POINTS: ⢠Mammalian cells are widely used to produce recombinant proteins in short times. ⢠Tuning DNA and transfecting agent are of great interest to optimize economic costs. ⢠Reducing DNA and transfecting agent amounts result in higher protein yields.
Subject(s)
DNA , Polyethyleneimine , Animals , Humans , Cost-Benefit Analysis , Plasmids , DNA/metabolism , Transfection , Polyethyleneimine/chemistry , Recombinant Proteins/genetics , Recombinant Proteins/metabolism , Mammals/genetics , Mammals/metabolismABSTRACT
OBJECTIVE: Catecholaminergic signaling has been a target for therapy in different type of cancers. In this work, we characterized the ADRß2, DRD1 and DRD2 expression in healthy tissue and endometrial tumors to evaluate their prognostic significance in endometrial cancer (EC), unraveling their possible application as an antitumor therapy. METHODS: 109 EC patients were included. The expression of the ADRß2, DRD1 and DRD2 proteins was evaluated by immunohistochemistry and univariate and multivariate analysis to assess their association with clinic-pathological and outcome variables. Finally, HEC1A and AN3CA EC cell lines were exposed to different concentrations of selective dopaminergic agents alone or in combination to study their effects on cellular viability. RESULTS: ADRß2 protein expression was not associated with clinico-pathological parameters or prognosis. DRD1 protein expression was reduced in tumors samples but showed a significant inverse association with tumor size and stage. DRD2 protein expression was significantly associated with non-endometrioid EC, high grade tumors, tumor size, worse disease-free survival (HR = 3.47 (95%CI:1.35-8.88)) and overall survival (HR = 2.98 (95%CI:1.40-6.34)). The DRD1 agonist fenoldopam showed a reduction of cellular viability in HEC1A and AN3CA cells. The exposure to domperidone, a DRD2 antagonist, significantly reduced cell viability compared to the control. Finally, DRD1 agonism and DRD2 antagonism combination induced a significant reduction in cell viability of the AN3CA cells compared to monotherapy, close to being an additive response than a synergistic effect (CI of 1.1 at 0.5% Fa). CONCLUSION: DRD1 and DRD2 expression levels showed a significant association with clinico-pathological parameters. Both the combined activation of DRD1 and blockage of DRD2 may form an innovative strategy to inhibit tumor growth in EC.
Subject(s)
Endometrial Neoplasms , Receptors, Dopamine D2 , Female , Humans , Prognosis , Receptors, Dopamine D2/metabolism , Endometrial Neoplasms/drug therapyABSTRACT
The last big outbreaks of Ebola fever in Africa, the thousands of avian influenza outbreaks across Europe, Asia, North America and Africa, the emergence of monkeypox virus in Europe and specially the COVID-19 pandemics have globally stressed the need for efficient, cost-effective vaccines against infectious diseases. Ideally, they should be based on transversal technologies of wide applicability. In this context, and pushed by the above-mentioned epidemiological needs, new and highly sophisticated DNA-or RNA-based vaccination strategies have been recently developed and applied at large-scale. Being very promising and effective, they still need to be assessed regarding the level of conferred long-term protection. Despite these fast-developing approaches, subunit vaccines, based on recombinant proteins obtained by conventional genetic engineering, still show a wide spectrum of interesting potentialities and an important margin for further development. In the 80's, the first vaccination attempts with recombinant vaccines consisted in single structural proteins from viral pathogens, administered as soluble plain versions. In contrast, more complex formulations of recombinant antigens with particular geometries are progressively generated and explored in an attempt to mimic the multifaceted set of stimuli offered to the immune system by replicating pathogens. The diversity of recombinant antimicrobial vaccines and vaccine prototypes is revised here considering the cell factory types, through relevant examples of prototypes under development as well as already approved products.
Subject(s)
COVID-19 , Influenza Vaccines , Viral Vaccines , Animals , COVID-19/prevention & control , Humans , RNA , Vaccination , Vaccines, Subunit , Vaccines, SyntheticABSTRACT
Vaults are protein nanoparticles that are found in almost all eukaryotic cells but are absent in prokaryotic ones. Due to their properties (nanometric size, biodegradability, biocompatibility, and lack of immunogenicity), vaults show enormous potential as a bio-inspired, self-assembled drug-delivery system (DDS). Vault architecture is directed by self-assembly of the "major vault protein" (MVP), the main component of this nanoparticle. Recombinant expression (in different eukaryotic systems) of the MVP resulted in the formation of nanoparticles that were indistinguishable from native vaults. Nowadays, recombinant vaults for different applications are routinely produced in insect cells and purified by successive ultracentrifugations, which are both tedious and time-consuming strategies. To offer cost-efficient and faster protocols for nanoparticle production, we propose the production of vault-like nanoparticles in Escherichia coli cells, which are still one of the most widely used prokaryotic cell factories for recombinant protein production. The strategy proposed allowed for the spontaneous encapsulation of the engineered cargo protein within the self-assembled vault-like nanoparticles by simply mixing the clarified lysates of the producing cells. Combined with well-established affinity chromatography purification methods, our approach contains faster, cost-efficient procedures for biofabrication in a well-known microbial cell factory and the purification of "ready-to-use" loaded protein nanoparticles, thereby opening the way to faster and easier engineering and production of vault-based DDSs.
Subject(s)
Escherichia coli , Nanoparticles , Escherichia coli/genetics , Escherichia coli/metabolism , Recombinant Proteins/metabolism , Drug Delivery Systems , Nanoparticles/chemistryABSTRACT
Bacterial inclusion bodies (IBs) are functional, non-toxic amyloids occurring in recombinant bacteria showing analogies with secretory granules of the mammalian endocrine system. The scientific interest in these mesoscale protein aggregates has been historically masked by their status as a hurdle in recombinant protein production. However, progressive understanding of how the cell handles the quality of recombinant polypeptides and the main features of their intriguing molecular organization has stimulated the interest in inclusion bodies and spurred their use in diverse technological fields. The engineering and tailoring of IBs as functional protein particles for materials science and biomedicine is a good example of how formerly undesired bacterial byproducts can be rediscovered as promising functional materials for a broad spectrum of applications.
Subject(s)
Bacteria/metabolism , Inclusion Bodies/metabolism , Bacteria/chemistry , Inclusion Bodies/chemistryABSTRACT
Fabry disease is a lysosomal storage disease arising from a deficiency of the enzyme α-galactosidase A (GLA). The enzyme deficiency results in an accumulation of glycolipids, which over time, leads to cardiovascular, cerebrovascular, and renal disease, ultimately leading to death in the fourth or fifth decade of life. Currently, lysosomal storage disorders are treated by enzyme replacement therapy (ERT) through the direct administration of the missing enzyme to the patients. In view of their advantages as drug delivery systems, liposomes are increasingly being researched and utilized in the pharmaceutical, food and cosmetic industries, but one of the main barriers to market is their scalability. Depressurization of an Expanded Liquid Organic Solution into aqueous solution (DELOS-susp) is a compressed fluid-based method that allows the reproducible and scalable production of nanovesicular systems with remarkable physicochemical characteristics, in terms of homogeneity, morphology, and particle size. The objective of this work was to optimize and reach a suitable formulation for in vivo preclinical studies by implementing a Quality by Design (QbD) approach, a methodology recommended by the FDA and the EMA to develop robust drug manufacturing and control methods, to the preparation of α-galactosidase-loaded nanoliposomes (nanoGLA) for the treatment of Fabry disease. Through a risk analysis and a Design of Experiments (DoE), we obtained the Design Space in which GLA concentration and lipid concentration were found as critical parameters for achieving a stable nanoformulation. This Design Space allowed the optimization of the process to produce a nanoformulation suitable for in vivo preclinical testing.
ABSTRACT
Fabry disease (FD) is a lysosomal storage disease caused by mutations in the gene for the α-galactosidase A (GLA) enzyme. The absence of the enzyme or its activity results in the accumulation of glycosphingolipids, mainly globotriaosylceramide (Gb3), in different tissues, leading to a wide range of clinical manifestations. More than 1000 natural variants have been described in the GLA gene, most of them affecting proper protein folding and enzymatic activity. Currently, FD is treated by enzyme replacement therapy (ERT) or pharmacological chaperone therapy (PCT). However, as both approaches show specific drawbacks, new strategies (such as new forms of ERT, organ/cell transplant, substrate reduction therapy, or gene therapy) are under extensive study. In this review, we summarize GLA mutants described so far and discuss their putative application for the development of novel drugs for the treatment of FD. Unfavorable mutants with lower activities and stabilities than wild-type enzymes could serve as tools for the development of new pharmacological chaperones. On the other hand, GLA mutants showing improved enzymatic activity have been identified and produced in vitro. Such mutants could overcome several complications associated with current ERT, as lower-dose infusions of these mutants could achieve a therapeutic effect equivalent to that of the wild-type enzyme.
Subject(s)
Fabry Disease/genetics , Genetic Predisposition to Disease , Mutation , alpha-Galactosidase/genetics , Alleles , Animals , Combined Modality Therapy/adverse effects , Combined Modality Therapy/methods , Disease Management , Enzyme Activation , Fabry Disease/diagnosis , Fabry Disease/metabolism , Fabry Disease/therapy , Humans , Structure-Activity Relationship , Treatment Outcome , alpha-Galactosidase/chemistry , alpha-Galactosidase/metabolismABSTRACT
Unraveling the characteristics and putative applications of naturally occurring protein aggregates has received an increasing interest during the last years. For example, the finding that the proteins embedded within bacterial inclusion bodies are, at least partially, biologically functional opened new opportunities for their rational design and application as naturally self-immobilized biocatalysts or as new drug delivery systems ("nanopills"). In another scenario, it is well established that "conformational diseases" are caused by misfolding and protein aggregation in different cells and tissues. The presence of such protein aggregates is a hallmark of these conditions, therefore becoming an excellent target for new therapeutic approaches for such devastating pathologies. Aggresomes are protein aggregates found in eukaryotic cells when the intracellular protein degradation machinery is overtitered. These protein-based nanoparticles are increasingly becoming excellent models in studies aimed to obtain a better understanding and control over protein aggregation processes in eukaryotic cells. In this work, we focus on some of the latest findings in the field of putative aggresome applications in biotechnology, as a new type of self-assembled immobilized biocatalysts, and in nanomedicine, mainly on their relationship with conformational diseases and the rational design of better therapeutics through a deeper understanding of protein aggregation processes.
Subject(s)
Biocatalysis , Biotechnology/methods , Eukaryota/chemistry , Inclusion Bodies/chemistry , Protein Aggregates , Protein Conformation , Cytoplasm/chemistry , Drug Delivery Systems , Eukaryota/cytology , Eukaryota/physiology , Humans , Nanomedicine , Protein Folding , Proteins/metabolism , Proteins/therapeutic use , ProteolysisABSTRACT
The identification of DNA coding sequences contained in the genome of many organisms coupled to the use of high throughput approaches has fueled the field of recombinant protein production. Apart from basic research interests, the growing relevance of this field is highlighted by the global sales of the top ten biopharmaceuticals on the market, which exceeds the trillion USD in a steady increasing tendency. Therefore, the demand of biological compounds seems to have a long run on the market. One of the most popular expression systems is based on Escherichia coli cells which apart from being cost-effective counts with a large selection of resources. However, a significant percentage of the genes of interest are not efficiently expressed in this system, or the expressed proteins are accumulated within aggregates, degraded or lacking the desired biological activity, being finally discarded. In some instances, expressing the gene in a homologous expression system might alleviate those drawbacks but then the process usually increases in complexity and is not as cost-effective as the prokaryotic systems. An increasing toolbox is available to approach the production and purification of those difficult-to-express proteins, including different expression systems, promoters with different strengths, cultivation media and conditions, solubilization tags and chaperone coexpression, among others. However, in most cases, the process follows a non-integrative trial and error strategy with discrete success. This review is focused on the design of the whole process by using an integrative approach, taken into account the accumulated knowledge of the pivotal factors that affect any of the key processes, in an attempt to rationalize the efforts made in this appealing field.
Subject(s)
Escherichia coli/genetics , Gene Expression Regulation, Bacterial , Industrial Microbiology/methods , Protein Biosynthesis , Recombinant Proteins/genetics , Bacillus/genetics , Bacillus/metabolism , Bacterial Proteins/genetics , Bacterial Proteins/metabolism , Computational Biology , Corynebacterium/genetics , Corynebacterium/metabolism , Cost-Benefit Analysis , Escherichia coli/metabolism , Lactococcus/genetics , Lactococcus/metabolism , Molecular Chaperones/genetics , Molecular Chaperones/metabolism , Pseudoalteromonas/genetics , Pseudoalteromonas/metabolism , Recombinant Proteins/biosynthesisABSTRACT
Lack of targeting and improper biodistribution are major flaws in current drug-based therapies that prevent reaching high local concentrations of the therapeutic agent. Such weaknesses impose the administration of high drug doses, resulting in undesired side effects, limited efficacy and enhanced production costs. Currently, missing nanosized containers, functionalized for specific cell targeting will be then highly convenient for the controlled delivery of both conventional and innovative drugs. In an attempt to fill this gap, health-focused nanotechnologies have put under screening a growing spectrum of materials as potential components of nanocages, whose properties can be tuned during fabrication. However, most of these materials pose severe biocompatibility concerns. We review in this study how proteins, the most versatile functional macromolecules, can be conveniently exploited and adapted by conventional genetic engineering as efficient building blocks of fully compatible nanoparticles for drug delivery and how selected biological activities can be recruited to mimic viral behavior during infection. Although engineering of protein self-assembling is still excluded from fully rational approaches, the exploitation of protein nano-assemblies occurring in nature and the direct manipulation of protein-protein contacts in bioinspired constructs open intriguing possibilities for further development. These methodologies empower the construction of new and potent vehicles that offer promise as true artificial viruses for efficient and safe nanomedical applications.
Subject(s)
Drug Delivery Systems , Genetic Therapy , Nanomedicine , Protein Engineering , NanoparticlesABSTRACT
BACKGROUND: Lipopolysaccharide (LPS), also referred to as endotoxin, is the major constituent of the outer leaflet of the outer membrane of virtually all Gram-negative bacteria. The lipid A moiety, which anchors the LPS molecule to the outer membrane, acts as a potent agonist for Toll-like receptor 4/myeloid differentiation factor 2-mediated pro-inflammatory activity in mammals and, thus, represents the endotoxic principle of LPS. Recombinant proteins, commonly manufactured in Escherichia coli, are generally contaminated with endotoxin. Removal of bacterial endotoxin from recombinant therapeutic proteins is a challenging and expensive process that has been necessary to ensure the safety of the final product. RESULTS: As an alternative strategy for common endotoxin removal methods, we have developed a series of E. coli strains that are able to grow and express recombinant proteins with the endotoxin precursor lipid IVA as the only LPS-related molecule in their outer membranes. Lipid IVA does not trigger an endotoxic response in humans typical of bacterial LPS chemotypes. Hence the engineered cells themselves, and the purified proteins expressed within these cells display extremely low endotoxin levels. CONCLUSIONS: This paper describes the preparation and characterization of endotoxin-free E. coli strains, and demonstrates the direct production of recombinant proteins with negligible endotoxin contamination.
Subject(s)
Escherichia coli Proteins/genetics , Escherichia coli/genetics , Gene Deletion , Recombinant Proteins/isolation & purification , ATP-Binding Cassette Transporters/genetics , ATP-Binding Cassette Transporters/metabolism , Aldose-Ketose Isomerases/genetics , Aldose-Ketose Isomerases/metabolism , Bacterial Proteins/genetics , Bacterial Proteins/metabolism , Biosynthetic Pathways/genetics , Carbohydrate Sequence , Electrophoresis, Polyacrylamide Gel , Endotoxins/biosynthesis , Escherichia coli/metabolism , Escherichia coli Proteins/metabolism , Glycolipids/biosynthesis , Lipid A/analogs & derivatives , Lipid A/biosynthesis , Lipopolysaccharides/biosynthesis , Mass Spectrometry , Metabolic Engineering/methods , Molecular Sequence Data , Mutation , Recombinant Proteins/biosynthesis , Reproducibility of Results , Sugar Acids/metabolismABSTRACT
Aggresomes are protein aggregates found in mammalian cells when the intracellular protein degradation machinery is over-titered. Despite that they abound in cells producing recombinant proteins of biomedical and biotechnological interest, the physiological roles of these protein clusters and the functional status of the embedded proteins remain basically unexplored. In this work, we have determined for the first time that, like in bacterial inclusion bodies, deposition of recombinant proteins into aggresomes does not imply functional inactivation. As a model, human α-galactosidase A (GLA) has been expressed in mammalian cells as enzymatically active, mechanically stable aggresomes showing higher thermal stability than the soluble GLA version. Since aggresomes are easily produced and purified, we propose these particles as novel functional biomaterials with potential as carrier-free, self-immobilized catalyzers in biotechnology and biomedicine.
Subject(s)
Protein Aggregates , Protein Multimerization , Recombinant Proteins/metabolism , alpha-Galactosidase/metabolism , Biotechnology/methods , Cell Line , Humans , Recombinant Proteins/genetics , alpha-Galactosidase/geneticsABSTRACT
By recruiting functional domains supporting DNA condensation, cell binding, internalization, endosomal escape and nuclear transport, modular single-chain polypeptides can be tailored to associate with cargo DNA for cell-targeted gene therapy. Recently, an emerging architectonic principle at the nanoscale has permitted tagging protein monomers for self-organization as protein-only nanoparticles. We have studied here the accommodation of plasmid DNA into protein nanoparticles assembled with the synergistic assistance of end terminal poly-arginines (R9) and poly-histidines (H6). Data indicate a virus-like organization of the complexes, in which a DNA core is surrounded by a solvent-exposed protein layer. This finding validates end-terminal cationic peptides as pleiotropic tags in protein building blocks for the mimicry of viral architecture in artificial viruses, representing a promising alternative to the conventional use of viruses and virus-like particles for nanomedicine and gene therapy. FROM THE CLINICAL EDITOR: Finding efficient gene delivery methods still represents a challenge and is one of the bottlenecks to the more widespread application of gene therapy. The findings presented in this paper validate the application of end-terminal cationic peptides as pleiotropic tags in protein building blocks for "viral architecture mimicking" in artificial viruses, representing a promising alternative to the use of viruses and virus-like particles for gene delivery.
Subject(s)
DNA/administration & dosage , Gene Transfer Techniques , Nanoparticles/chemistry , Proteins/chemistry , Amino Acid Sequence , DNA/genetics , Genetic Therapy , HeLa Cells , Histidine/chemistry , Humans , Models, Molecular , Molecular Sequence Data , Peptides/chemistryABSTRACT
The integration of therapeutic biomolecules, such as proteins and peptides, in nanovesicles is a widely used strategy to improve their stability and efficacy. However, the translation of these promising nanotherapeutics to clinical tests is still challenged by the complexity involved in the preparation of functional nanovesicles and their reproducibility, scalability, and cost production. Here we introduce a simple one-step methodology based on the use of CO2-expanded solvents to prepare multifunctional nanovesicle-bioactive conjugates. We demonstrate high vesicle-to-vesicle homogeneity in terms of size and lamellarity, batch-to-batch consistency, and reproducibility upon scaling-up. Importantly, the procedure is readily amenable to the integration/encapsulation of multiple components into the nanovesicles in a single step and yields sufficient quantities for clinical research. The simplicity, reproducibility, and scalability render this one-step fabrication process ideal for the rapid and low-cost translation of nanomedicine candidates from the bench to the clinic.
Subject(s)
Carbon Dioxide/chemistry , Green Fluorescent Proteins/chemistry , Nanostructures/chemistry , Polyethylene Glycols/chemistry , Serum Albumin, Bovine/chemistry , Animals , Cattle , Cell Line , Humans , Molecular Structure , Solvents/chemistryABSTRACT
By following simple protein engineering steps, recombinant proteins with promising applications in the field of drug delivery can be assembled in the form of functional materials of increasing complexity, either as nanoparticles or nanoparticle-leaking secretory microparticles. Among the suitable strategies for protein assembly, the use of histidine-rich tags in combination with coordinating divalent cations allows the construction of both categories of material out of pure polypeptide samples. Such molecular crosslinking results in chemically homogeneous protein particles with a defined composition, a fact that offers soft regulatory routes towards clinical applications for nanostructured protein-only drugs or for protein-based drug vehicles. Successes in the fabrication and final performance of these materials are expected, irrespective of the protein source. However, this fact has not yet been fully explored and confirmed. By taking the antigenic RBD domain of the SARS-CoV-2 spike glycoprotein as a model building block, we investigated the production of nanoparticles and secretory microparticles out of the versions of recombinant RBD produced by bacteria (Escherichia coli), insect cells (Sf9), and two different mammalian cell lines (namely HEK 293F and Expi293F). Although both functional nanoparticles and secretory microparticles were effectively generated in all cases, the technological and biological idiosyncrasy of each type of cell factory impacted the biophysical properties of the products. Therefore, the selection of a protein biofabrication platform is not irrelevant but instead is a significant factor in the upstream pipeline of protein assembly into supramolecular, complex, and functional materials.
ABSTRACT
A growing number of insights on the biology of bacterial inclusion bodies (IBs) have revealed intriguing utilities of these protein particles. Since they combine mechanical stability and protein functionality, IBs have been already exploited in biocatalysis and explored for bottom-up topographical modification in tissue engineering. Being fully biocompatible and with tuneable bio-physical properties, IBs are currently emerging as agents for protein delivery into mammalian cells in protein-replacement cell therapies. So far, IBs formed by chaperones (heat shock protein 70, Hsp70), enzymes (catalase and dihydrofolate reductase), grow factors (leukemia inhibitory factor, LIF) and structural proteins (the cytoskeleton keratin 14) have been shown to rescue exposed cells from a spectrum of stresses and restore cell functions in absence of cytotoxicity. The natural penetrability of IBs into mammalian cells (reaching both cytoplasm and nucleus) empowers them as an unexpected platform for the controlled delivery of essentially any therapeutic polypeptide. Production of protein drugs by biopharma has been traditionally challenged by IB formation. However, a time might have arrived in which recombinant bacteria are to be engineered for the controlled packaging of therapeutic proteins as nanoparticulate materials (nanopills), for their extra- or intra-cellular release in medicine and cosmetics.
Subject(s)
Inclusion Bodies/metabolism , Proteins/metabolism , Bacteria/metabolism , Catalase/metabolism , Drug Delivery Systems , HSP70 Heat-Shock Proteins/metabolism , HeLa Cells , Humans , Keratin-14/metabolism , Leukemia Inhibitory Factor/metabolism , Proteins/genetics , Recombinant Proteins/biosynthesis , Recombinant Proteins/genetics , Tetrahydrofolate Dehydrogenase/metabolismABSTRACT
Aggresomes are insoluble protein aggregates found in eukaryotic cells when the intracellular machinery is overtitered by, for example, the overexpression of a recombinant protein. These protein nanoparticles have become excellent models in studies devoted to elucidate protein aggregation processes in eukaryotic cells, like those involved in "conformational disorders" linked to neurodegenerative diseases. Since the presence of such protein aggregates is a hallmark of these conditions, they constitute an excellent target for new therapeutic approaches for such devastating pathologies. Moreover, and following the pathway opened a few years ago by bacterial inclusion bodies, eukaryotic aggresomes have been proposed as a new type of carrier-free, self-immobilized biocatalysts for use in biotechnology and biomedicine. Altogether, unraveling the characteristics and putative applications of naturally occurring protein aggregates has received an increasing interest during the last years. For that, availability of protocols allowing the production and purification of aggresomes constitute a valuable tool to boost research in the abovementioned fields. In this chapter, we describe both upstream and downstream protocols to obtain aggresomes produced in human cells, using as a model the recombinant human enzyme alpha-galactosidase A (GLA), together with technical tips and advices when working and analyzing eukaryotic aggresomes.
Subject(s)
Eukaryota , Neurodegenerative Diseases , Eukaryotic Cells/metabolism , Humans , Inclusion Bodies/metabolism , Neurodegenerative Diseases/metabolism , Protein AggregatesABSTRACT
Proteins are synthesized in heterologous systems because of the impossibility to obtain satisfactory yields from natural sources. The efficient production of soluble and functional recombinant proteins is among the main goals in the biotechnological field. In this context, it is important to point out that under stress conditions, protein folding machinery is saturated and this promotes protein misfolding and, consequently, protein aggregation. Thus, the selection of the optimal expression organism and its growth conditions to minimize the formation of insoluble protein aggregates should be done according to the protein characteristics and downstream requirements. Escherichia coli is the most popular recombinant protein expression system despite the great development achieved so far by eukaryotic expression systems. Besides, other prokaryotic expression systems, such as lactic acid bacteria and psychrophilic bacteria, are gaining interest in this field. However, it is worth mentioning that prokaryotic expression system poses, in many cases, severe restrictions for a successful heterologous protein production. Thus, eukaryotic systems such as mammalian cells, insect cells, yeast, filamentous fungus, and microalgae are an interesting alternative for the production of these difficult-to-express proteins.
Subject(s)
Escherichia coli , Protein Folding , Animals , Biotechnology , Escherichia coli/genetics , Escherichia coli/metabolism , Eukaryota , Mammals , Recombinant Fusion Proteins/metabolism , Recombinant Proteins , SolubilityABSTRACT
One of the most promising approaches in the drug delivery field is the use of naturally occurring self-assembling protein nanoparticles, such as virus-like particles, bacterial microcompartments or vault ribonucleoprotein particles as drug delivery systems (DDSs). Among them, eukaryotic vaults show a promising future due to their structural features,in vitrostability and non-immunogenicity. Recombinant vaults are routinely produced in insect cells and purified through several ultracentrifugations, both tedious and time-consuming processes. As an alternative, this work proposes a new approach and protocols for the production of recombinant vaults in human cells by transient gene expression of a His-tagged version of the major vault protein (MVP-H6), the development of new affinity-based purification processes for such recombinant vaults, and the all-in-one biofabrication and encapsulation of a cargo recombinant protein within such vaults by their co-expression in human cells. Protocols proposed here allow the easy and straightforward biofabrication and purification of engineered vaults loaded with virtually any INT-tagged cargo protein, in very short times, paving the way to faster and easier engineering and production of better and more efficient DDS.
Subject(s)
Nanoparticles , Drug Delivery Systems , Humans , Nanoparticles/chemistry , Recombinant Proteins/chemistryABSTRACT
Cancer is one of the main causes of death worldwide. To date, and despite the advances in conventional treatment options, therapy in cancer is still far from optimal due to the non-specific systemic biodistribution of antitumor agents. The inadequate drug concentrations at the tumor site led to an increased incidence of multiple drug resistance and the appearance of many severe undesirable side effects. Nanotechnology, through the development of nanoscale-based pharmaceuticals, has emerged to provide new and innovative drugs to overcome these limitations. In this review, we provide an overview of the approved nanomedicine for cancer treatment and the rationale behind their designs and applications. We also highlight the new approaches that are currently under investigation and the perspectives and challenges for nanopharmaceuticals, focusing on the tumor microenvironment and tumor disseminate cells as the most attractive and effective strategies for cancer treatments.