World Wildlife Conservation Day: Reflecting on the Role of Science in Protecting Threatened or Endangered Species and Ecosystems  

Posted on by Kelly Grooms
A sign reading “Wildlife Conservation Area — Please keep to marked footpaths” stands in the foreground of a grassy field, with rows of young crops and a line of trees under a partly cloudy sky.

December 4 marks World Wildlife Conservation Day, a day set aside to highlight global efforts to protect endangered species and preserve the biodiversity and ecosystems that sustain our planet. It is an opportunity to call attention to the serious threats posed by wildlife crimes, such as poaching and illegal trafficking, and a time to stand together against ongoing dangers to wildlife and their habitat.  

Every organism, from myxozoans to blue whales, has a place in the delicate balance of ecosystems. When these systems become unstable, the impact can be far reaching—affecting anything from crop loss and soil fertility to water and air quality. This World Wildlife Conservation Day we want to reflect on the role science can play in understanding and protecting the wildlife and ecosystems that support us all.  

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From Mt. Fuji to the Lab Bench: A UW-Madison Student’s Summer in Japan

Posted on by Promega

This blog is guest-written by Lucy Kneeley, a 2025 recipient of the Promega International Internship Scholarship. The scholarship is granted annually to University of Wisconsin-Madison students traveling abroad for internship opportunities.

Lucy Kneeley poses at the summit of Mt Fuji.

Last summer, I completed an internship at the Institute of Science Tokyo in the lab of Professor Satoshi Kaneko. As someone who has never been out of the United States for more than a 10-day vacation, I gained a lot of valuable communication experience by navigating a language barrier, but more importantly, across different social norms. Immersing myself in a new country with a new language and culture has led me to think differently and realize how quickly a group of strangers can become a new community. By the end of the three months, I had formed a network of colleagues and friends at the university and within the local community.

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Trends and Tools Transforming Drug Discovery: Five Takeaways from Discover Glo 2025

Posted on by Meghan Rollins

In biologics, cell therapy, and targeted protein degradation, the science is moving fast—and so are the tools. From GPCR-targeted therapies to real-time CAR-T manufacturing tools, new techniques are reshaping how scientists approach drug development, live-cell imaging, and protein degradation.

The “Bringing Light to Science” Discover Glo 2025 speaker series brought together researchers from across academia and industry to share real-world examples of how bioluminescent technologies are helping them advance their research. Now available on demand, these sessions offer fresh perspectives and actionable takeaways on the future of therapeutic development, cellular analysis and assay design.

We’ve distilled five key takeaways from the sessions—practical insights you can apply to your own work or use to stay current with where the field is heading.

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Promega Fc Effector Assays: Measure Every Mechanism

Posted on by Promega

This post is written by Kai Hillman, PhD, Promega Corporation.

Every day, scientists push the boundaries of what’s possible with monoclonal antibodies (mAbs)—from targeting cancer cells to calming autoimmune-driven inflammation. These therapies rely not only on binding but on engineering the desired immune response. The suite of Promega Fc Effector Assays helps you understand these interactions from receptor binding and function, through bridging studies. With consistency, sensitivity, and scalability, these assays support teams from early discovery through lot release.

This article draws on real-world publications and product insights to show how Promega assays are powering next-generation immunotherapies—and redefining how we measure immune engagement.

Schematic diagramming the suite of Promega Fc effector assays in one seamless workflow to support antibody development across the pipeline.
Figure 1. Promega delivers the most comprehensive suite of Fc effector assays in one seamless workflow to support antibody development across the pipeline.
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Residence Time: The Impact of Binding Kinetics on Compound-Target Interactions

Posted on by Promega

This blog was written by guest contributor Tian Yang, Associate Product Manager, Promega, in collaboration with Kristin Huwiler, Manager, Small Molecule Drug Discovery, Promega.

During the development of chemical probes or small-molecule drugs, compound affinity (Kd) or potency (IC50) is used to characterize compound-target interactions, to guide structure-activity relationship analysis and lead optimization and to assess compound selectivity.

However, neither parameter provides information on how quickly a compound engages with and dissociates from the target. The dissociation constant Kd reflects the relative concentrations of unbound and bound state of the compound at thermodynamic equilibrium, and while IC50 is an empirical metric that measures the concentration at which a biochemical or cellular process is reduced to half of the maximum value, IC50 values are typically determined when the process is assumed to be at equilibrium or steady-state. For a closed system, like cells in a culture dish, these thermodynamic parameters are quite informative. In an open system like the human body, where compound-target interactions often do not reach equilibrium, the kinetic parameters, in addition to the thermodynamic parameters, are needed to better understand and characterize compound target engagement over time (1,2).

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CRISPR/Cas9 Knock-In Tagging: Simplifying the Study of Endogenous Biology

Posted on by Ken Doyle

Understanding the expression, function and dynamics of proteins in their native environment is a fundamental goal that’s common to diverse aspects of molecular and cell biology. To study a protein, it must first be labeled—either directly or indirectly—with a “tag” that allows specific and sensitive detection.

Using a labeled antibody to the protein of interest is a common method to study native proteins. However, antibody-based assays, such as ELISAs and Western blots, are not suitable for use in live cells. These techniques are also limited by throughput and sensitivity. Further, suitable antibodies may not be available for the target protein of interest.

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From Content Creators to Communication Partners: The Role of Motion in Scientific Storytelling

Posted on by Taylor McAda
Image generated by DALL-E.

Moving Science Forward — Literally

I’ve always believed that the best science stories don’t just inform — they move us. And in many cases, that’s quite literal.

Whether I’m designing a figure for a new assay or animating a step-by-step protocol, I see motion as a bridge that turns complexity into clarity. When used well, that bridge transforms scientific communication from dense and static into something dynamic, visual and memorable.

And it’s not just me — a graphic designer — saying this. Scholars like Daniel Liddle describe motion as a form of visual rhetoric: a way to persuade, clarify and build trust through movement. Motion isn’t just decoration — it’s meaning made visible.

In this post, I’ll explore why motion matters in scientific communication and how animation makes complex ideas easier to grasp. From turning a protocol into a story that sticks to making technical jargon something you can remember, motion design helps science feel more approachable and a lot more memorable.

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How Calcium Shapes Cell Communication and Invasion

Posted on by Shannon Sindermann

Platelets are best known for their role in blood clotting, but they also participate in other biological processes that influence how cells communicate and behave. In research models, scientists have observed that tumor cells can interact with platelets in ways that affect how they move and attach to new environments. A recent study by Morris et al., published in Scientific Reports, explored the molecular details behind these platelet–cell interactions and the role of calcium in regulating them.

The Role of Integrins and Calcium

The study focused on integrins, which are surface proteins that help cells anchor to their surroundings and communicate with the extracellular matrix. Two integrins, αIIbβ3 and αvβ3, are particularly important because they mediate platelet–platelet and platelet–cancer cell binding. Their structure and function depend on divalent cations such as calcium, which stabilize receptor conformation and support ligand binding.

When extracellular calcium levels were manipulated, platelet behavior changed in distinct ways.

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Therapeutics Come Alive: An Interview with PharmaBiome

Posted on by Nour Mozaffari

The next generation of medicine may not come in a pill or vial — but in a living community of microbes. Scientists at Pharmabiome, a Zurich-based biotechnology company, are leveraging their expertise in microbiome research to create truly “living” therapies.

More Than a Gut Feeling

All around us – and inside –exists an entire universe of microscopic organisms commonly referred to as the microbiome. In fact, our body contains more microbes than human cells, working hand in hand to maintain normal physiology. The most heavily colonized part of our body is our gastrointestinal (GI) tract – our gut – housing thousands of different bacteria, viruses and fungi. Collectively termed ‘gut microbiota’, this complex network of microorganisms helps us digest nutrients, produces essential metabolites, protects us against pathogens, and more.

The diverse species in our GI tract co-exist in a dynamic equilibrium, each fulfilling a defined set of functions and interacting with other species through cross-feeding mechanisms that, together, promote gut health. When this delicate balance is perturbed, be it through dietary changes, antibiotic treatments, or other factors, the effect ripples across the body. Increasing evidence suggests that gut dysbiosis actively contributes to pathological conditions ranging from inflammatory bowel disease (IBD) and obesity to neurological and autoimmune disorders. The good news is, as our understanding of gut ecology evolves, so does the potential to harness and reshape the microbiome to improve health.

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Targeted Protein Degradation: How Chemoproteomics and Induced Proximity Are Shaping Drug Discovery

Posted on by Amy Landreman

Earlier this fall, more than 90 researchers from academia and industry gathered at the Promega Madison campus for the 4th TPD & Induced Proximity Symposium. The event focused on the rapidly advancing field of targeted protein degradation (TPD) and the broader concept of induced proximity—therapeutic strategies that bring two or more proteins into proximity to trigger a specific biological effect. 

This 4th year reflected of the symposium a maturing and diversifying field with chemoproteomics and proteomescale mapping redefining what it means to be “druggable,” while AI and high throughput biology are connecting molecular design to cellular function. Yet the mission remains unchanged—using molecular approaches that leverage the cellular machinery to make progress against targets once deemed “undruggable.” 

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