Mammalian Tissue Culture Cells Research Articles

Insight into the emerging insect to human pathogen Photorhabdus revealing geographic differences in immune cell tropism.

Photorhabdus asymbiotica is a species of the insect pathogenic Photorhabdus genus that has been isolated as an etiological agent in human infections. Since then, multiple isolates have been identified worldwide; however, actual clinical infections have so far only been identified in North America, Australia, and Nepal. Previous research on the clinical isolates had shown that the strains differed in their behaviour when infecting cultured human cells. In this study, we investigate the differences between the pathogenic activities of P. asymbiotica isolates from different geographic locations. Pathogenicity was analysed using infection assays with both cultured cell lines (THP-1, CHO, and HEK cells) and primary immune cells, and peripheral blood mononuclear cells (PBMCs) isolated from human blood. Here, we present the findings from the Australian (Kingscliff) and North American (ATCC43949) clinical isolates, and non-clinical soilborne nematode isolates from Thailand (PB68) and Northern Europe (HIT and JUN) of P. asymbiotica. We also show the first findings from a new clinical isolate of P. luminescens (Texas), the first non-asymbiotica species to cause a human infection, confirming its ability to infect and survive inside human immune cells. Here for the first time, we show how P. asymbiotica selectively infects certain immune cells while avoiding others and that infectivity varies depending on growth temperature. We also show that the tropism varies depending on the geographic location a strain is isolated from, with only the European HIT and JUN strains lack the ability to survive within mammalian cells in tissue culture.

Anti‐Covid Gene Therapy: Integration of Authentic Research into a Continuously Evolving Undergraduate Laboratory Course

Undergraduate biology students often graduate without exposure to authentic research experiences. Laboratory courses follow a one or two week fail‐proof experiment resembling a cookbook recipe, lacking the uncertainty of genuine research. Techniques in molecular biology cover an array of skills essential to succeed in a biotechnological laboratory today. I have been developing an evolving molecular biology lab course based on the teaching of concepts while imparting the skills and applications of modern techniques, providing students with theoretical concepts and laboratory skills. We prepare students to carry‐out scientific protocols that can be applied to a future workforce setting. Students are immersed in a 10‐week series of labs with the objective to use molecular cloning to make a novel gene therapy vector; therapies are designed to inhibit the expression of genes of the virus that causes Covid‐19, severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2). Students are introduced to PubMed and GenBank to research the background of SARS‐CoV‐2 and its target genes; the Spike gene (S), the membrane gene (M) the nucleocapsid gene (N) and the envelope gene (E). Students use the DNA software, Serial Cloner, as a tool to evaluate DNA sequences and mFOLD to analyze RNA structure. Students generate and visualize the design of an antisense gene therapy directed against one of the target viral genes. Using our gene therapy platform, students generate a vector with a unique target. Subsequently student‐generated vectors were transfected into mammalian tissue culture cells that express one of the target genes (S, M, N or E) and RNA and protein was collected to measure the efficacy of the gene therapy vector to reduce the expression of the target viral gene. In our initial experiments, we observed greater than 2.5‐fold reduction in the Spike Covid mRNA. Currently, students are testing additional therapies to maximize efficacy.

Spatial and temporal control of mitochondrial H2O2 release in intact human cells

Hydrogen peroxide (H2O2) has key signaling roles at physiological levels, while causing molecular damage at elevated concentrations. H2O2 production by mitochondria is implicated in regulating processes inside and outside these organelles. However, it remains unclear whether and how mitochondria in intact cells release H2O2. Here, we employed a genetically encoded high‐affinity H2O2 sensor, HyPer7, in mammalian tissue culture cells to investigate different modes of mitochondrial H2O2 release. We found substantial heterogeneity of HyPer7 dynamics between individual cells. We further observed mitochondria‐released H2O2 directly at the surface of the organelle and in the bulk cytosol, but not in the nucleus or at the plasma membrane, pointing to steep gradients emanating from mitochondria. Gradient formation is controlled by cytosolic peroxiredoxins, which act redundantly and with a substantial reserve capacity. Dynamic adaptation of cytosolic thioredoxin reductase levels during metabolic changes results in improved H2O2 handling and explains previously observed differences between cell types. Our data suggest that H2O2‐mediated signaling is initiated only in close proximity to mitochondria and under specific metabolic conditions.

In vivo labeling of endogenous genomic loci in C. elegans using CRISPR/dCas9.

Visualization of genomic loci with open chromatin state has been reported in mammalian tissue culture cells using a CRISPR/Cas9-based system that utilizes an EGFP-tagged endonuclease-deficient Cas9 protein (dCas9::EGFP) (Chen et al. 2013). Here, we adapted this approach for use in Caenorhabditis elegans . We generated a C. elegans strain that expresses the dCas9 protein fused to two nuclear-localized EGFP molecules (dCas9::NLS::2xEGFP::NLS) in an inducible manner. Using this strain, we report the visualization in live C. elegans embryos of two endogenous repetitive loci, rrn-4 and rrn-1 , from which 5S and 18S ribosomal RNAs are constitutively generated.

Practical Methods for Expression of Recombinant Protein in the Pichia pastoris System

One of the most critical challenges of genetic engineering is the expression of recombinant proteins using biological expression systems. Nowadays, different expression systems from bacteria to mammalian tissue culture cells are available for the production of recombinant proteins for medical and industrial purposes. Among various choices, yeast expression systems such as Pichia pastoris are promising candidates. The P. pastoris expression system is a standard tool for the production of biopharmaceuticals and industrial enzymes. It is also considered a unique host for the expression of subunit vaccines which could significantly affect the growing market of medical biotechnology. Using P. pastoris as an expression system for heterologous proteins, this article provides detailed basic protocols for cloning of a recombinant cassette into a suitable expression vector, the transformation of foreign vector DNAs into the yeast by electroporation, and expression and purification of desired recombinant protein. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Cloning of a recombinant cassette into a suitable expression vector Basic Protocol 2: Transformation of P. pastoris and selection of transformants Basic Protocol 3: Optimization and large-scale expression of recombinant proteins Basic Protocol 4: Purification of recombinant proteins.

Design, Synthesis and Testing of an Anti‐Covid Gene Therapy: Integration of Authentic Research into an Undergraduate Laboratory Course

Undergraduate biology students often graduate without exposure to authentic research experiences. Laboratory courses follow a one or two week fail-proof experiment resembling a cookbook recipe, lacking the uncertainty of genuine research. Techniques in molecular biology cover an array of skills essential to succeed in a biotechnological laboratory today. This lab course is based on the teaching of concepts while imparting the skills and applications of modern techniques, providing students with theoretical concepts and laboratory skills. We prepare students to carry-out scientific protocols that can be applied to a future workforce setting. Students are immersed in a 10-week series of labs with the objective to use molecular cloning to make a novel gene therapy vector; therapies are designed to inhibit the expression of genes of the virus that causes Covid-19, severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Students are introduced to PubMed and Genbank to research the background of SARS-CoV-2 and its target genes; the Spike gene (S), the membrane gene (M) the nucleocapsid gene (N) and the envelope gene (E). Students use the DNA software, Serial Cloner, as a tool to evaluate DNA sequences and mFOLD to analyze RNA structure. Students generate and visualize the design of an antisense gene therapy directed against one of the target viral genes. Using our gene therapy platform, students generate a vector with a unique target. Subsequently student-generated vectors were transfected into mammalian tissue culture cells that express the target genes (S, M, N or E) and RNA and protein was collected to measure the efficacy of the gene therapy vector to reduce the expression of the target viral gene.

Stress Granule Protein Features Allow for Accurate Prediction of Biological Condensate Localization with GraPES

Biological condensates have been thrust to the forefront of molecular biology over the past decade for their implications in enzymatic activity, neurodegenerative diseases, and cellular organization. It is thought that many of these membraneless organelles are formed through a process known as liquid-liquid phase separation, in which key protein or nucleic acid drivers seed the formation of protein-rich foci within the cellular milieu. Stress granules are stress-induced assemblies that are belong to this group of biological condensates and are of keen interest to the biomolecular research community due to being linked to both long-term cell viability and a variety of protein aggregation-based diseases. Recently, a large amount of proteomic data has been generated that provides unprecedented insight into stress granule composition and stands as fruitful ground for further analysis. Interrogation of this data revealed that stress granule proteins are enriched in features that favor protein liquid-liquid phase separation. Proteins within stress granules were found to be more disordered, soluble, and abundant than their proteome and cytosolic controls while also having an increased potential for post-translational modifications. Furthermore, these “stress granuleomes” were found to be enriched for multivalent character by possessing multiple ordered domains and being likely to interact with RNA maintaining a high level of protein-protein interactions under basal conditions. Our findings are consistent with the notion that stress granule formation is driven by protein liquid-liquid phase separation. Furthermore, stress granule proteins appear poised near solubility limits while possessing the ability to dynamically alter their phase behavior in response to external threat. We culminate results from our analysis into novel predictors for granule incorporation in yeast and mammalian cells that out performs similar computational tools. Using this predictor, we were able to correctly identify new stress granule components, two of which we validated with colocalization microscopy in mammalian tissue culture cells [1]. We then developed a second series of sequence-base predictors and integrate all of these computational tools into a user-friendly web-based interface, called GraPES (Granule Protein Enrichment Server), where users can either look up a variety of pre-calculated likelihood z-scores for human and yeast proteins or obtain novel predictions from their own input FASTA formatted protein sequences.

In Vitro Cultivation of the Syphilis Spirochete Treponema pallidum.

For over a century, investigation of Treponema pallidum subsp. pallidum, the spiral‐shaped bacterium that causes syphilis, was hindered by an inability to culture the organism in vitro. A recent breakthrough has enabled continuous in vitro growth of this organism in co‐culture with mammalian tissue culture cells. This article contains the protocols needed to culture T. pallidum in the standard laboratory environment. In addition, protocols for growing and maintaining the required tissue culture cells, for generating isogenic strains by limiting dilution, and for quantitating T. pallidum by darkfield microscopy are included. © 2021 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: In vitro cultivation of Treponema pallidum Basic Protocol 2: Generation of isogenic strains Support Protocol 1: Alternate harvest procedure Support Protocol 2: Culture of Sf1Ep cells Support Protocol 3: Assessment of T. pallidum number and viability

Using unnatural amino acids to selectively label proteins for cellular imaging: a cell biologist viewpoint.

Twenty-five years ago, GFP revolutionized the field of cell biology by enabling scientists to visualize, for the first time, proteins in living cells. However, when it comes to current, state-of-the-art imaging technologies, fluorescent proteins (such as GFP) have several limitations that result from their size and photophysics. Over the past decade, an elegant, alternative approach, which is based on the direct labeling of proteins with fluorescent dyes and is compatible with live-cell and super-resolution imaging applications, has been introduced. In this approach, an unnatural amino acid that can covalently bind a fluorescent dye is incorporated into the coding sequence of a protein. The protein of interest is thereby site-specifically fluorescently labeled inside the cell, eliminating the need for protein- or peptide-labeling tags. Whether this labeling approach will change cell biology research is currently unclear, but it clearly has the potential to do so. In this short review, a general overview of this approach is provided, focusing on the imaging of site-specifically labeled proteins in mammalian tissue culture cells, and highlighting its advantages and limitations for cellular imaging.

CRISPR-Cas12a-assisted PCR tagging of mammalian genes.

Here we describe a time-efficient strategy for endogenous C-terminal gene tagging in mammalian tissue culture cells. An online platform is used to design two long gene-specific oligonucleotides for PCR with generic template cassettes to create linear dsDNA donors, termed PCR cassettes. PCR cassettes encode the tag (e.g., GFP), a Cas12a CRISPR RNA for cleavage of the target locus, and short homology arms for directed integration via homologous recombination. The integrated tag is coupled to a generic terminator shielding the tagged gene from the co-inserted auxiliary sequences. Co-transfection of PCR cassettes with a Cas12a-encoding plasmid leads to robust endogenous expression of tagged genes, with tagging efficiency of up to 20% without selection, and up to 60% when selection markers are used. We used target-enrichment sequencing to investigate all potential sources of artifacts. Our work outlines a quick strategy particularly suitable for exploratory studies using endogenous expression of fluorescent protein-tagged genes.

The nucleolus functions as a phase-separated protein quality control compartment.

The nuclear proteome is rich in stress-sensitive proteins, which suggests that effective protein quality control mechanisms are in place to ensure conformational maintenance. We investigated the role of the nucleolus in this process. In mammalian tissue culture cells under stress conditions, misfolded proteins entered the granular component (GC) phase of the nucleolus. Transient associations with nucleolar proteins such as NPM1 conferred low mobility to misfolded proteins within the liquid-like GC phase, avoiding irreversible aggregation. Refolding and extraction of proteins from the nucleolus during recovery from stress was Hsp70-dependent. The capacity of the nucleolus to store misfolded proteins was limited, and prolonged stress led to a transition of the nucleolar matrix from liquid-like to solid, with loss of reversibility and dysfunction in quality control. Thus, we suggest that the nucleolus has chaperone-like properties and can promote nuclear protein maintenance under stress.

Abstract 2655: Oxygen tension regulates lysosomal activation and receptor tyrosine kinase degradation

Abstract Oxygen sensing is crucial for adaptation to variable habitats and physiological conditions. Low oxygen tension, or hypoxia, is a common feature of solid tumors and hypoxic tumors are often more aggressive and resistant to therapy. Here we show that, in mammalian tissue culture cells, hypoxia suppressed lysosomal acidification/activation and receptor tyrosine kinase (RTK) degradation. Hypoxia down-regulated mTORc1, reducing its ability to activate transcription factor EB (TFEB), a master regulator of v-ATPase, the lysosomal proton pump. Hypoxia prevented epidermal growth factor receptor (EGFR) degradation in tumor tissues, whereas activation of lysosomes enhanced tumor cell response to anti-EGFR treatment. Our results linkoxygen tension and lysosomal activity, provide a molecular explanation of the malignant phenotype associated with hypoxic tumors, and suggest activation of lysosomes may provide therapeutic benefit in RTK-targeted cancer therapy. Citation Format: Jaewoo Hong, P. Charles Lin, Todd Wuest, Yongfen Min. Oxygen tension regulates lysosomal activation and receptor tyrosine kinase degradation [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 2655.

Localization of SUMO-modified Proteins Using Fluorescent Sumo-trapping Proteins.

Here we are presenting a novel method to study the sumoylation of proteins and their sub-cellular localization in mammalian cells and nematode oocytes. This method utilizes a recombinant modified SUMO-trapping protein fragment, kmUTAG, derived from the Ulp1 SUMO protease of the stress-tolerant budding yeast Kluyveromyces marxianus. We have adapted the properties of the kmUTAG for the purpose of studying sumoylation in a variety of model systems without the use of antibodies. For the study of SUMO, KmUTAG has several advantages when compared to antibody-based approaches. This stress-tolerant SUMO-trapping reagent is produced recombinantly, it recognizes native SUMO isoforms from many species, and unlike commercially available antibodies it shows reduced affinity for free, unconjugated SUMO. Representative results shown here include the localization of SUMO conjugates in mammalian tissue culture cells and nematode oocytes.

Asymmetric division events promote variability in cell cycle duration in animal cells and Escherichia coli

Asymmetric cell division is a major mechanism generating cell diversity. As cell cycle duration varies among cells in mammalian tissue culture cells, we asked whether their division asymmetry contributes to this variability. We identify among sibling cells an outlier using hierarchical clustering on cell cycle durations of granddaughter cells obtained by lineage tracking of single histone2B-labelled MDCKs. Remarkably, divisions involving outlier cells are not uniformly distributed in lineages, as shown by permutation tests, but appear to emerge from asymmetric divisions taking place at non-stochastic levels: a parent cell influences with 95% confidence and 0.5% error the unequal partitioning of the cell cycle duration in its two progenies. Upon ninein downregulation, this variability propagation is lost, and outlier frequency and variability in cell cycle durations in lineages is reduced. As external influences are not detectable, we propose that a cell-autonomous process, possibly involved in cell specialisation, determines cell cycle duration variability.

Potential blockade of the human voltage-dependent anion channel by MoS2 nanoflakes.

Despite significant interest in molybdenum disulfide (MoS2) nanomaterials, particularly in biomedicine, their biological effects have been understudied. Here, we explored the effect of MoS2 nanoflakes on the ubiquitous mitochondrial porin voltage-dependent anion channel (VDAC1), using a combined computational and functional approach. All-atomic molecular dynamics simulations suggest that MoS2 nanoflakes make specific contact interactions with human VDAC1. We show that the initial contacts between hVDAC1 and the nanoflake are hydrophobic but are subsequently enhanced by a complex interplay of van der Waals (vdW), hydrophobic and electrostatic interactions in the equilibrium state. Moreover, the MoS2 nanoflake can insert into the lumen of the hVDAC1 pore. Free-energy calculations computed by the potential of mean force (PMF) verify that the blocked configuration of the MoS2-hVDAC1 complex is more energetically favorable than the non-blocked binding mode. Consistent with these predictions, we showed that MoS2 depolarizes the mitochondrial membrane potential (Ψm) and causes a decrease in the viability of mammalian tissue culture cells. These findings might shed new light on the potential biological effect of MoS2 nanomaterials.

Ultraviolet (UV) Cross-Linking of Live Cells, Lysate Preparation, and RNase Titration for Cross-Linking Immunoprecipitation (CLIP).

One of the great advantages of RNA CLIP (cross-linking immunoprecipitation) is that RNA-protein complexes can be "frozen" in situ in live cells by ultraviolet (UV) irradiation. This protocol describes UV cross-linking of mammalian tissue culture cells or whole tissues. For the latter, the tissue is typically triturated to allow UV penetration. However, depending on the thickness of the chosen tissue, this may not be necessary. It is preferable to handle the tissue as little as possible, to keep it in ice-cold buffers, and to cross-link as soon after the time of collection as is feasible to preserve native interactions at the time of cross-linking. This protocol also describes cell lysis following cross-linking, as well as treatment with RNase to partially hydrolyze the bound RNA. The first time this protocol is performed, a pilot experiment should be performed to determine the optimal RNase concentration for the particular sample. Once the RNase conditions are optimized this section of CLIP protocol can be repeated on experimental samples before proceeding through the rest of the protocol.

Using Aldehyde Synergism To Direct the Design of Degradable Pro-Antimicrobial Networks.

We describe the design and synthesis of degradable, dual-release, pro-antimicrobial poly(thioether acetal) networks derived from synergistic pairs of aromatic terpene aldehydes. Initially, we identified pairs of aromatic terpene aldehyde derivatives exhibiting a synergistic antimicrobial activity against Pseudomonas aeruginosa by determining fractional inhibitory concentrations. Synergistic aldehydes were converted into dialkene acetal monomers and copolymerized at various ratios with a multifunctional thiol via thiol-ene photopolymerization. The step-growth nature of the thiol-ene polymerization ensures every cross-link junction contains a degradable acetal linkage enabling a fully cross-linked polymer network to revert into its small molecule constituents upon hydrolysis, releasing the synergistic aldehydes as active antimicrobial compounds. A three-pronged approach was used to characterize the poly(thioether acetal) materials: (i) determination of the degradation/aldehyde release behavior, (ii) evaluation of the antimicrobial activity, and (iii) identification of the cellular pathways impacted by the aldehydes on a library of mutated bacteria. From this approach, a polymer network derived from a 40:60 p-bromobenzaldehyde/p-anisaldehyde monomer ratio exhibited potent antimicrobial action against Pseudomonas aeruginosa, a common opportunistic human pathogen. From a transposon mutagenesis assay, we showed that these aldehydes target porins and multidrug efflux pumps. The aldehydes released from the poly(thioether acetal) networks exhibited negligible toxicity to mammalian tissue culture cells, supporting the potential development of these materials as dual-release antimicrobial biomaterial platforms.

Expression of Recombinant Genes in the Yeast Pichia pastoris

AbstractThe synthesis of specific recombinant proteins using single‐celled organisms from bacteria to mammalian tissue culture cells has become a major source of biopharmaceutical products for the industry and a source of a wide variety of proteins for academic research. A range of organisms are utilized for this purpose. One of the newest and most promising of these is the yeast Pichia pastoris. This article provides detailed basic protocols for the expression of heterologous genes and the synthesis of recombinant proteins utilizing this yeast. Specifically provided are protocols for the insertion of foreign vector DNAs into the yeast by electroporation, amplification of vector sequences by the post‐translational vector amplification (PTVA) method, and growth and expression of foreign genes in shake flask cultures. © 2018 by John Wiley & Sons, Inc.

Functional Analysis of the Dengue Virus Genome Using an Insertional Mutagenesis Screen.

In the last few decades, dengue virus, an arbovirus, has spread to over 120 countries. Although a vaccine has been approved in some countries, limitations on its effectiveness and a lack of effective antiviral treatments reinforce the need for additional research. The functions of several viral nonstructural proteins are essentially unknown. To better understand the functions of these proteins and thus dengue virus pathogenesis, we embarked on a genomewide transposon mutagenesis screen with next-generation sequencing to determine sites in the viral genome that tolerate 15-nucleotide insertions. Using this approach, we generated support for several published predicted transmembrane and enzymatic domains. Next, we created 7 mutants containing the 15-nucleotide insertion from the original selection and found 6 of them were capable of replication in both mammalian and mosquito tissue culture cells. Interestingly, one mutation had a significant impairment of viral assembly, and this mutation may lead to a better understanding of viral assembly and release. In addition, we created a fully infectious virus expressing a functionally tagged NS4B protein, which will provide a much-needed tool to elucidate the role of NS4B in viral pathogenesis.IMPORTANCE Dengue virus is a mosquito-borne virus distributed in tropical and subtropical regions globally that can result in hospitalization and even death in some cases. Although a vaccine exists, its limitations and a lack of approved antiviral treatments highlight our limited understanding of dengue virus pathogenesis and host immunity. The functions of many viral proteins are poorly understood. We used a previously published approach using transposon mutagenesis to develop tools to study these proteins' functions by adding insertions randomly throughout the viral genomes. These genomes were transferred into cells, and infectious progeny were recovered to determine sites that tolerated insertions, as only the genomes that tolerated insertions would be able to propagate. Using these results, we created viruses with epitope tags, one in the viral structural protein Capsid and one in the viral nonstructural protein NS4B. Further investigation of these mutants may elucidate the roles of Capsid and NS4B during dengue virus infections.

Assessing mRNA nuclear export in mammalian cells by microinjection.

The nuclear export of mRNAs is an important yet little understood part of eukaryotic gene expression. One of the easiest methods for monitoring mRNA export in mammalian tissue culture cells is through the microinjection of DNA plasmids into the nucleus and monitoring the distribution of the transcribed product over time. Here we describe how to setup a microscope equipped with a micromanipulator used in cell microinjections, and we explain how to perform a nuclear mRNA export assay and obtain the nuclear export rate for any given mRNA.