Could bacteria survive on Mars? While images of the red planet might spark thoughts of barren landscapes and lifeless deserts, Mars holds a fascinating possibility: under suitable conditions, pockets of salty, perchlorate-rich brines could temporarily form on or near its surface. These brines are formed by salts that naturally absorb water from their surroundings. By lowering the temperature at which water freezes, these salts can stabilize liquid water, raising intriguing questions about the potential for microbial life. But what exactly would it take for bacteria to survive there? New research from Kloss et al. published in Scientific Reports sheds light on this cosmic question.
For the success of adeno-associated virus (AAV)-based gene therapies, accurate viral titration is non-negotiable. But as interest in AAVs as delivery vectors soars, so does the challenge of getting consistent, reproducible genome titers—a critical hurdle in biologics workflows where speed and standardization are paramount.
Impact of DNase Digestion on Accuracy
A recent peer-reviewed study pinpoints a surprising source of this variability: the DNase digestion, a common step used to remove contaminating DNA. “[DNase digestion]… led to a significant decrease in genome titers for several AAV serotypes,” the authors write,highlighting concerns around workflow reproducibility and data reliability.The research, published in Molecular Therapy: Methods & Clinical Development, demonstrates how different engineered AAV serotypes respond inconsistently to standard DNase treatment, significantly impacting final titer results. These findings are particularly relevant for scientists developing and optimizing cell and gene therapy platforms, where regulatory expectations for analytical precision continue to rise.
This study addresses the challenge of accurately measuring viral titers in engineered AAVs, which have enhanced transduction efficiency but exhibit lower yields when measured using traditional genome titering methods. Specifically, the authors explored the impact of DNase digestion on the stability of engineered AAV capsids that contain peptide insertions. Through a series of rigorous experiments including electron microscopy, quantitative PCR (qPCR) and digital droplet PCR (ddPCR), they found that the heat-inactivation step commonly used following DNase treatment to eliminate free-floating DNA can compromise the integrity of engineered AAV capsids.
At Grove Biopharma, the R&D team is advancing a rational design approach to drug discovery. Their Bionic Biologics™ Platform assembles custom-engineered peptides to target intracellular protein-protein interactions into stable, potent, cell permeable therapeutics. By combining the precision of biologics with the efficiency of synthesizing small molecules, Grove accelerates lead generation and optimization.
Grove’s technology enables targeting key proteins involved in cancer and neurodegenerative diseases for which effective therapeutics have historically been difficult to develop. Their candidate molecules focus on important targets such as the Androgen Receptor splice variant, SHOC2 within the RAS/RAF pathway, the MYC-regulator WDR5, a Tau isoform relevant to Alzheimer’s Disease, and the Keap1-Nrf2 interaction associated with neurodegeneration. These programs have made significant progress and now represent some of the most advanced agents in their pipeline.
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.
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.
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.
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.
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).
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.
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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