Resources - GEN - Genetic Engineering and Biotechnology News

Explore at the Single-Cell Level: Reveal Insights Hidden in Complex Cell Populations

Kathy Vuksanaj — Thu, 19 Oct 2023 20:13:43 +0000

Next-generation sequencing (NGS) is continuously evolving. Traditional short-read DNA sequencing has encouraged break-throughs at ever-lower costs across the field of genomics. However, tumors, brains, the immune system, and other complex systems require the greater resolution and flexibility only recently introduced with single-cell sequencing. Compared to the more established bulk RNA sequencing (RNA-Seq), single-cell sequencing magnifies cellular differences to glean intel about how an individual cell functions in its environment. By sequencing individual cells to determine the base sequences, researchers can obtain genomic, transcriptomic, or multiomic data on a cell-by-cell basis, revealing details that are otherwise overlooked.

Single-cell sequencing applies to any study that requires detailed understanding of a cell population, marking tremendous potential for multiple research areas spanning a diversity of applications. This eBook highlights single-cell innovations and approaches, demonstrating how NGS identifies a neuroblastoma target and provides insights for brain rejuvenation and the development of combination therapies. We also invite researchers to explore how the Element AVITI System synthesizes quality, flexibility, and compatibility to deliver affordable single-cell sequencing at any scale so that you can own the next breakthrough.

Sponsored by:

The post Explore at the Single-Cell Level: Reveal Insights Hidden in Complex Cell Populations appeared first on GEN - Genetic Engineering and Biotechnology News.

Human T Cell Activation and Expansion Kit

Christina Jackson — Mon, 02 Oct 2023 19:30:58 +0000

Akadeum Life Sciences announced the release of their human T cell activation & expansion kit with buoyancy activated cell sorting (BACS) microbubbles. The kit was designed to isolate, activate, and expand T cells from a sample in one workflow. Current cell isolation methods include magnetic activated cell separation (MACS^®) and fluorescence-activated cell sorting (FACS). Akadeum says their activation and expansion microbubbles provide scientists and researchers with a quick, more efficacious, and cost-effective solution to provide better treatments for patients.

Akadeum Life Sciences

The post Human T Cell Activation and Expansion Kit appeared first on GEN - Genetic Engineering and Biotechnology News.

Dual Entry Fume Hoods

Christina Jackson — Mon, 02 Oct 2023 19:30:56 +0000

The UniFlow SE Dual Entry Hood has launched with safety glass sashes front and rear to allow observers a clear view as well as access to procedures. A split transparent baffle system provides airflow on both sides of the fume hood. The hood was designed for schools and industrial use where additional access is required. The company says the material used for construction is chemical/corrosion resistant, flame retardant, non-metallic, lightweight composite fiber reinforced polyester resin. The fume hood has a picture frame opening that angles the air into the sash opening and is equipped with vertical, sliding, clear, safety tempered glass panels on front and rear. All electrical components and services are UL and CSA listed.

HEMCO

The post Dual Entry Fume Hoods appeared first on GEN - Genetic Engineering and Biotechnology News.

Liquid-Chromatography System

Christina Jackson — Mon, 02 Oct 2023 19:30:03 +0000

HaLCon is a purpose-built liquid chromatography system for bioprocessing designed to enable rapid HPLC-quality protein titer measurement and to integrate directly into your bioprocessing suite. According to the company, HaLCon was chosen by attendee vote as the Best of Show for excellence in innovation for life science technology. When used with an automated sampling system, measurements can be obtained to deliver actionable data-points.

RedShiftBio

The post Liquid-Chromatography System appeared first on GEN - Genetic Engineering and Biotechnology News.

Multiomic Profiling Kit

Christina Jackson — Mon, 02 Oct 2023 19:30:01 +0000

10x Genomics announced the commercial availability of a new Chromium Single Cell Gene Expression Flex High-Throughput Multiomic Profiling Kit. The company claims the kit enables streamlined, multiomic characterization of cell populations so that researchers can expand their options at a larger scale and detect simultaneous gene and protein expression. The kit was designed to give researchers access to data that will help them understand indications like cancer, neurodegenerative diseases, and cellular and molecular immunology.

10x Genomics

The post Multiomic Profiling Kit appeared first on GEN - Genetic Engineering and Biotechnology News.

Single-Cell Spatial Proteomics by Molecular Pixelation

Christina Jackson — Fri, 01 Sep 2023 11:03:21 +0000

By Filip Karlsson

The spatial distribution of cell surface proteins, which governs vital processes of the immune system such as inter-cell communication and mobility, has proven difficult to assess. New tools are needed that not only capture spatial organization of immune cells, but also multiplex at a high level while delivering high resolution and throughput.

Flow cytometry using fluorophore-labeled antibodies has been extensively used to study proteins on immune cells for several decades. More recently, efforts have been made to overcome the multiplexing limitations of conventional flow cytometry by instead labeling antibodies with isotopes for mass spectrometry readout, or with oligonucleotides for next-generation sequencing readout.

Although these approaches can be used to characterize and phenotype cells at high multiplex and throughput, the information they provide pertains only to the abundance of each target protein on each cell. They do not describe the spatial organization of the targeted molecules.

Fluorescence microscopy has traditionally been used to study the spatial organization of proteins on single cells, but multiplexing is limited to a few targets due to the spectral properties of fluorophores, and the signal-to-noise ratio suffers from autofluorescence and spectral bleed-through between channels. Furthermore, the view provided by each microscopy image is limited to a selected focal plane, so if the whole cell surface is to be represented, a Z-stack of images for each fluorophore is required, limiting throughput.

Recently, methods solely relying on oligonucleotide sequences to image biological samples have been demonstrated. Sometimes referred to as “DNA microscopy,” these methods rely on the incorporation of DNA tags that can be decoded to reveal both biomolecule identity and position within the biological sample. These methods offer possibilities to circumvent the limitations in multiplexing, throughput, and (potentially) resolution that beset optical imaging–based methods.

Pixelgen Technologies has developed Molecular Pixelation (MPX) technology to unlock a new spatial dimension to single-cell proteomics research by supplementing abundance information with spatial information about target proteins. This added spatial dimension provides researchers with opportunities to gain deeper insights into cell function at sub-cellular resolution.

The MPX protocol can be performed using standard molecular biology laboratory equipment, without the need for any dedicated hardware or consumables to compartmentalize cells, and a dedicated data processing pipeline is available for DNA processing and analysis of the sequencing output. The reagent kit contains an 80-plex panel against cell surface receptor targets on the major types of peripheral blood mononuclear cells (PBMCs)—T cells, B cells, natural killer cells, and monocytes—and allows for sequencing of up to 1,000 cells per sample and a total of eight samples per reagent kit. Dedicated data processing software tools are available for straightforward data processing and analysis of the rich data that the technology generates.

MPX workflow overview

The MPX workflow can be divided into six steps: a cell preparation step, two pixelation steps, an NGS preparation step, an NGS step, and an analysis step (Figure 1). During the cell preparation step, the immune cells in suspension are chemically fixed with paraformaldehyde to lock the surface proteins in place and prevent any reorganization during downstream sample processing. The fixed cells are blocked, and a target panel of 80 antibody-oligonucleotide conjugates (AOCs) is added, whereupon the AOCs bind their surface receptor targets. Next, the pixelation steps consist of serially hybridizing a set of so-called DNA pixels to the oligonucleotide portion of AOCs bound to cells. DNA pixels are single-stranded DNA molecules produced by rolling circle amplification, where each unique DNA pixel molecule contains repeats of a unique sequence identifier. Each DNA pixel molecule can hybridize to multiple AOCs in proximity on the cell surface.

The DNA pixel identifier sequence is then incorporated onto the hybridized AOC via a gap-fill ligation enzymatic reaction, forming about 1,000 neighborhoods on the cell surface where all AOC molecules within each neighborhood now share the same DNA pixel identifier sequence. The hybridization and gap-fill ligation reactions are then repeated for a total of two pixelation steps, thereby creating two sets of partially overlapping neighborhoods across the cell surface of each assayed cell.

Each generated amplicon contains a protein identifier barcode, a unique molecular identifier sequence, two DNA pixel identifier sequences, and PCR primer sites. The generated amplicons are finally amplified by PCR, purified, and quantified for Illumina sequencing.

Data processing and spatial inference

In short, the dedicated data processing pipeline, which is called Pixelator, receives the sequencing reads and subjects them to quality filtering, decoding (to establish protein identities), error correction, and consolidation (to collapse identical reads into unique sequences). Each sequenced unique molecule can be represented as an edge (link) of a graph (network) with the DNA pixel identifier sequences as nodes and the protein identity tags as edge or node attributes. Separated “cell graphs” representing individual cells are contained within the sample-level graph generated from a sequenced sample.

Spatial inference of the relative locations of individual AOC molecules is possible by interrogating the relative positions of the AOCs within each cell graph. This also allows for the calculation of spatial metrics such as the degree of clustering (polarity) of each of the 80 protein targets, or the level of colocalization between pairs of protein targets.

Results

Data analysis of protein abundance can be performed on MPX data similarly to other multiplexed single-cell methods. For example, PBMCs taken from a healthy donor were processed through the MPX protocol, and then a uniform manifold approximation and projection (UMAP) dimensionality reduction was performed on the protein count matrix output, which formed separated clusters that were consistent with the expected protein signatures for the major cell types expected in the PBMC samples (Figure 2). The fraction of each cell type was also consistent with expected fractions seen in healthy PBMC donors.

Figure 2. UMAP visualization of MPX count data from a PBMC sample. The observed clusters contain count signatures consistent with expected cell subpopulations within a PBMC sample. The pie chart indicates the fraction of all cells for each cluster.

To demonstrate the added spatial dimension of the data, Raji B cells were treated with an AOC of the CD20 therapeutic antibody drug rituximab before fixation and processing of the treated cells and untreated control cells through the protocol. Rituximab is known to cluster CD20 on B cells, which should then be reflected in the rituximab polarity score output of data.

The clustering of CD20 occurring upon rituximab AOC treatment was confirmed with fluorescence microscopy (Figure 3). Polarity scores for rituximab depicting the degree of clustered protein expression were compared between stimulated and control samples, and they showed a significant elevation of polarity scores for rituximab-treated cells. Additionally, graph representations of individual rituximab-treated cells, colored by the count density of rituximab of each node, showed a clustered expression pattern consistent with microscopy validation.

Figure 3. Polarity scores of rituximab-treated and -untreated Raji cells (left). Polarity scores were significantly elevated for rituximab treated cells, suggesting a clustered protein expression. Fluorescence microscopy validation confirmed the presence of clustered protein expression for rituximab-treated cells (middle). A heatmap of rituximab count density from a representative cell graph of a stimulated sample shows a clustered expression pattern (right).

Conclusion

Unlocking a new spatial dimension to single-cell proteomics research at high multiplex and throughput can enable researchers to gain additional and deeper insights into immune cell function at scale. Example data from Pixelgen Technologies’ MPX technology showcases the ability to detect differential spatial clustering of a target protein confirmed to be clustered upon stimulation with rituximab.

Filip Karlsson is co-founder and chief technology officer of Pixelgen Technologies. Website: www.pixelgen.com.

The post Single-Cell Spatial Proteomics by Molecular Pixelation appeared first on GEN - Genetic Engineering and Biotechnology News.

2PP 3D-Printing: Tailored Software Reduces Stitching

Christina Jackson — Fri, 01 Sep 2023 10:57:59 +0000

UpNano has released a software upgrade for its NanoOne platform of high-resolution 3D-printers. According to the company, the upgrade is compatible with all NanoOne printers. The 2-photon polymerization-based (2PP) 3D-printers by UpNano were designed to be used in industry and academia for biocompatible applications in cell and medical research. The compact desktop print system offers high-resolution 3D-printing across twelve orders of magnitude. At the basis of the upgrade is the ability to define several printing parameters individually and set changes of those parameters during the printing process in advance.

UpNano

The post 2PP 3D-Printing: Tailored Software Reduces Stitching appeared first on GEN - Genetic Engineering and Biotechnology News.

Cell Culture Media System

Christina Jackson — Fri, 01 Sep 2023 10:57:58 +0000

The TheraPRO^® CHO Media System, a GS CHO cell culture media system, has been launched by Lonza to simply processes and optimize productivity and protein quality when used with GS-CHO cell lines. The system was designed to support pharmaceutical and biotechnology companies manufacturing therapeutic proteins to further improve product quality while streamlining time-to-market. The company claims the chemically defined, animal component–free, two-part production system achieves high viable cell concentrations and more than 5g/L protein titer during a 15-day culture cycle.

Lonza

The post Cell Culture Media System appeared first on GEN - Genetic Engineering and Biotechnology News.

Normalizer Kits for Next-Generation Sequencing

Christina Jackson — Fri, 01 Sep 2023 10:57:56 +0000

QIAGEN has launched QIAseq Normalizer Kits to provide researchers with a convenient and cost-effective method to pool different DNA libraries for best-quality results from next-generation sequencing (NGS) runs. Researchers can use QIAseq Normalizer with QIAGEN’s existing QIAseq library prep solutions to streamline NGS workflows or with a range of DNA- and RNA-library prep workflows from other providers for Illumina sequencing platforms. QIAseq Normalizer results in double-stranded DNA libraries, which are compatible with long-term storage.

QIAGEN

The post Normalizer Kits for Next-Generation Sequencing appeared first on GEN - Genetic Engineering and Biotechnology News.

Fluorescent Protein Control Platform

Christina Jackson — Fri, 01 Sep 2023 10:57:16 +0000

Slingshot Biosciences has launched the SpectraComp^® series. As explained by the company, the fluorescent protein control series was designed to transform the way scientists analyze cells to lead to changes in drug development and the diagnostic testing industry. By genetically modifying T cells and other immune cells in humanized mice to express fluorescent reporter proteins, including eGFP and mCherry, scientists can observe live cells and tissue locations, and track protein trafficking. The SpectraComp eGFP and mCherry will provide researchers with an on-demand cell mimic control platform that will allow them to explore further in flow cytometry analysis.

Slingshot Biosciences

The post Fluorescent Protein Control Platform appeared first on GEN - Genetic Engineering and Biotechnology News.