On April 5, 2025, Dr. David R. Liu stood in the spotlight at the Barker Hangar in Santa Monica, California, to receive the Breakthrough Prize in Life Sciences—one of the most prestigious honors in science. Dubbed the “Oscars of Science,” the Breakthrough Prizes were launched in 2012 by tech philanthropists including Sergey Brin, Mark Zuckerberg and Priscilla Chan, Yuri and Julia Milner and Anne Wojcicki. These prizes recognize groundbreaking achievements in life sciences, physics, and mathematics, with each laureate receiving a $3 million award—more than twice the amount of a Nobel Prize.
The winners are selected by panels of previous Breakthrough Prize recipients, ensuring peer-driven recognition. The annual ceremony brings together not only the best minds in science but also celebrities, filmmakers, and tech industry leaders, creating an uncommon crossover between pop culture and research, in an effort to bring more public attention as well as funding to scientific achievement.
Dr. Liu was honored for inventing base editing and prime editing, technologies that allow precise, programmable rewriting of DNA to correct mutations linked to genetic disease—without introducing double-stranded breaks. These tools have rapidly transitioned from the bench to the clinic, with at least 15 clinical trials currently underway worldwide targeting diseases like sickle cell anemia, T-cell leukemia, and others.
Cell signaling is a finely tuned process where both timing and spatial context play essential roles. Whether it’s a hormone triggering a cellular response or a drug modulating a pathway, these processes unfold in dynamic, spatially organized ways. To study them, researchers rely on chemigenetic biosensors—genetically encoded tools that light up in response to molecular activity. However, traditional biosensors are constrained by several limitations: poor photostability under prolonged imaging, limited spectral flexibility for multiplexing, and insufficient spatial resolution for studying signaling events at subcellular scales.
Luciferase reporter assays are essential tools in molecular and cellular biology, offering sensitive and quantitative means to study gene expression, transcriptional regulation, signal transduction pathways, and cellular responses to various stimuli. With multiple luciferase reporters and detection reagents available, how do you know which one fits your specific workflow or readout needs?
Choosing a reporter and detection system that aligns with your experimental goals helps you tailor your luciferase reporter assay for the most meaningful results. This blog post will help you navigate the options and key considerations.
Attention-Deficit/Hyperactivity Disorder (ADHD) is a complex neurodevelopmental disorder that affects millions worldwide. Current therapeutic treatment relies on pharmaceutical approaches, but emerging research suggests that dietary supplements, such as omega-3 fatty acids, may offer complementary therapeutic options. A recent study published in the Journal of Psychiatric Research explores the relationship between inflammation and dietary supplements to determine how they might influence ADHD pathology. This work was conducted in Dr. Edna Grünblatt’s lab at the University of Zurich and was supported through Promega’s Academic Access Program. I had the chance to interview Dr. Natalie Walter, the lead author, to learn more about how her work offers potential opportunities for non-pharmacological interventions.
In our final blog post on double-stranded RNA (dsRNA), we turn our attention to the chemical building blocks of mRNA therapeutics—modified nucleotides. These seemingly minor changes to the RNA sequence play a crucial role in the success of mRNA-based vaccines and treatments. However, they also introduce complexities in accurately detecting and quantifying unwanted dsRNA byproducts— key steps in ensuring the therapeutic efficacy of your mRNA product.
What Are Modified Nucleotides?
Modified nucleotides are ribonucleotides containing chemically altered nucleosides — like specialty ingredients swapped into a classic recipe to improve taste and nutrition. Just as a chef might use a lactose-free milk or gluten-free flour to make a dish easier to digest without changing its core structure, scientists use chemically altered nucleosides during in vitro transcription (IVT) to improve how mRNA therapies perform. These modifications replace their natural counterparts (e.g., uridine or cytidine) in the final RNA product. Their incorporation improves the performance and safety of mRNA therapeutics in several ways:
As mRNA therapeutics continue to expand across clinical pipelines, one persistent challenge remains for developers: reducing double-stranded RNA (dsRNA) contaminants that can compromise safety and efficacy. These unintended byproducts of in vitro transcription (IVT) can trigger unwanted immune responses and reduce the potency of the final product. Developers must prioritize dsRNA detection and control as essential steps in the process. In our previous blog post we offered a high-level discussion of what is double-stranded RNA (dsRNA), its biological function, and importance of detection in a therapeutic context. Here, we’ll take a closer look at origins of dsRNA contamination, quality control measures, and improvement strategies.
Large-scale production of single-stranded RNA (ssRNA) for mRNA-based therapeutics is primarily done through in vitro transcription (IVT), an enzymatic process designed to generate high-yield, functional mRNA transcripts from a DNA template. This process uses purified RNA polymerase enzymes, such as T7, that recognize specific promoter sequences in the DNA template, generating the RNA transcripts of interest. However, IVT reactions also generate unwanted dsRNA byproduct. Below, we delve into some of the major quality control (QC) considerations and strategies to reduce dsRNA byproducts.
Labeled antibodies are indispensable tools in research and clinical diagnostics, used in everything from cell imaging and ELISAs to immunotherapies and ADC development. But if you’ve ever tried labeling antibodies the traditional way—purify, buffer exchange, conjugate, purify again—you know it can be tedious and time-consuming. That’s where on-bead conjugation steps in with a solution.
Tuberculosis (TB) remains one of the deadliest infectious diseases globally, with millions of new cases and over a million deaths each year. The rise of drug-resistant strains has only complicated treatment and control efforts, turning TB into a moving target for clinicians and public health officials alike. Understanding how TB spreads, evolves and becomes resistant requires more than just microscopes and cultures—it demands a detailed look at the bacterium’s genetic code.
The new lyophilization equipment will more than double the lyophilization capacity of Promega Madison.
On March 12, 2025, a 46,000-pound stainless-steel chamber made a five-hour journey through Feynman Center to its final resting place in the brand-new Fill-Lyophilize-Finish suite. This massive piece of equipment will more than double the lyophilization capacity at Promega Madison, safeguarding the continuity of production and opening new frontiers in product formulation.
Lyophilization provides scientists with increased stability, enhanced flexibility and protection against error. Promega has been lyophilizing reagents in-house since the mid-1990s, and demand has steadily grown over time. The recent expansion reflects the company’s commitment to anticipating scientists’ future needs and planning for the long term.
Why is Lyophilization Important?
Lyophilization, also known as freeze-drying, provides a variety of benefits in the lab. For example, lyophilized reagents can typically be stored at higher temperatures, and they offer longer stability.
Stuart Forsyth inspects the lyophilization chamber during its installation.
“Lyophilized product also gives you added flexibility in how you tailor your reagents to your specific need,” says Stuart Forsyth, Sr Process Validation Engineer at Promega. “Whether you’re reconstituting with a buffer, water or even a sample, you’re able to alter the assay’s concentration and formulation in ways that are impossible with liquid formulations.”
Promega also offers lyophilization for customers working with Promega to manufacture custom products. The flexibility helps many labs, especially diagnostics, ensure that the final reagent maximizes efficiency and ease of use for point-of-care applications.
“Especially if you’re lyophilizing the whole assay in one, you’re removing a lot of potential for mistakes by the user that would result in product failure,” says Terri McDonnell, Director of Global Custom & OEM Commercial Development. “Lyophilization capabilities are powerful tools to have in your toolbox as you try to formulate a reagent for minimal risk of misuse or mistakes.”
Expanding Lyophilization at Promega Madison
The new lyophilizer will primarily be used with 10ml vials and 100ml bottles, but it can process numerous other formats.
Promega Operations closely monitors the throughput capacity of all critical processes. For years, the team has projected that manufacturing would outgrow the existing lyophilization capacity sometime in the mid-2020s. The project to build out the empty suite in Feynman Manufacturing Center began in 2021, and it will start producing products for sale in early 2026.
The new lyophilizer nearly doubles the throughput capacity of Promega Madison. It will primarily be used with 10ml vials and 100ml bottles, but the line can also handle 2ml and 3ml vials and large LyoGuard trays for bulk powder production. At this point, the team plans to primarily use the Feynman suite for high-demand catalog products like CellTiter-Glo, creating flexibility to use the older lines for custom products and other smaller demands.
Continuity, Collaboration and Creativity
The new lyophilization suite will have several significant impacts for scientists using Promega reagents.
First, the new lyophilization line creates additional redundancy to ensure that key products are continuously available. The huge increase in capacity means that if one lyophilizer is down for maintenance, the others can handle picking up the slack. The new suite also features the current state-of-the-art automation technology, minimizing any risks for contamination or human error that would disrupt high-quality production.
The lyophilizer is unloaded by crane outside Feynman Manufacturing Center.
For customers working with Promega on custom orders, the new lyophilizer gives Promega more flexibility to collaborate with customers on finding the right formulation for their needs, all within the established quality system.
“We partner with a wide range of customers seeking to adapt or customize our technologies for specific applications,” says Terri McDonnell. “As the primary manufacturer of most of our products, and with the addition of new lyophilization capabilities, we can offer expanded scale and format options. Because these activities are performed in-house, we maintain greater control over quality and supply chain logistics, helping to ensure the consistent and reliable delivery of products.”
Finally, the additional capacity means that high-volume products can be manufactured less frequently by scaling up batch sizes. This frees up human resources to explore process improvements and dedicate more time to work outside of the production workflow. Kris Pearson, Director of Manufacturing Sciences and Custom operations, says the smaller equipment can serve as a sandbox where teams can test creative ideas.
“We’ll have more opportunity to work with R&D on new product development, and to dive deep into new cycles and what that can mean for our custom capabilities,” she says. “We can play around with new formats and processes to find new ways of offering a great product for every custom customer.”
Long-Term Planning and Strategy
As a private company, Promega isn’t beholden to short-term gains. Leadership prioritizes decisions that support future needs, while building in room to adapt to changes in the scientific landscape.
The architectural drawings of Feynman Manufacturing Center show the suite earmarked for lyophilization as early as 2012, before the building was constructed.
“When we started designing Feynman Manufacturing Center, we said we wanted 30% of the square footage to be frontier space,” says Jen Romanin VP of Global Support and IVD Operations, and key member of the Global Planning Team. “This space would give us future flexibility in where new features would be installed.”
Sometimes needs are forecasted far in advance – for example, the architectural drawings of Feynman Manufacturing Center dated February 2012 show the new suite was already earmarked for Lyophilization almost a decade before the construction project began. Other spaces are left intentionally unlabeled as a nod to the unknown needs that will emerge over time. Whatever arises, the flexibility and foresight built into Promega facilities will position the team to respond quickly – and build a high-quality solution – without having to break new ground.
“I think this says two things about us,” says Chuck York, Vice President of Operations at Promega. “First, it says we’re pretty confident we’re going to be here for a long time. Secondly, it says that no matter what happens between now and then, we want to make sure we’re prepared.”
In recent years, non-coding RNAs—especially microRNAs (miRNAs) and long non-coding RNAs (lncRNAs)—have emerged as powerful regulators of cellular behavior. These molecules modulate gene expression, often by targeting mRNAs for translational suppression or degradation. Two recent studies—one focused on osteoarthritis and the other on 5-Fu-resistant colorectal cancer—illustrate how these non-coding, regulatory RNAs operate within disease-relevant signaling networks, providing new points for therapeutic intervention.
Both studies use the pmirGLO Dual-Luciferase miRNA Target Expression Vector to evaluation predicted miRNA activity. This dual-luciferase system offers a clean and quantifiable way to validate miRNA–mRNA interactions using a simple bioluminescent readout. By cloning the 3´ untranslated regions (UTRs) of suspected targets downstream of a firefly luciferase reporter and normalizing against Renilla luciferase, researchers can rapidly confirm whether a miRNA directly regulates its target.
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