I used to love taking magazine quizzes to learn more about myself. I thought it would be fun to create a quiz to help you find out what scientific career path may be the best fit for you. Be open-minded while taking the quiz and remember that this is just for fun!
1. My greatest strength is:
a) My artistry b) My perseverance c) My attention to detail d) My problem solving skills e) My personality- I get along with everyone
Last week, a diverse group of stakeholders attended CRISPRcon Midwest, hosted by the Keystone Policy Center and the University of Wisconsin–Madison. The goal of the day-long conference was to emphasize the importance and value of gene editing technology, and how it must be communicated deliberately between scientists, the public, policymakers, and other stakeholders.
Julie Shapiro, Senior Policy Director of Keystone Policy Center, acted as Emcee for the event. Given the diverse group of attendees, she mentioned in her opening remarks that the event organizers were “seeking conversation, not consensus” and emphasized the “power of respectful dialogue.” A slide overhead showcased the ground rules for the day, which included statements such as “dare to listen, dare to share, and dare to disagree.”
CRISPRcon aimed to included voices beyond those represented by keynote speakers and panelists, so they incorporated live polling through an online app to keep the audience engaged and an active participant in the conversations throughout the day. From the opening remarks, it was clear that this conference would not just deliver on its promise of thoughtful conversation about the science, but build further understanding about the societal impacts of a rapidly advancing technology.
There is nothing like a bit of recognition to energize your efforts, right? Promega was recently awarded the 2019 Distinguished Performer: Sustainabilityaward, as one of the Deloitte Wisconsin 75 awardees.
This award is not so much a feather in our cap, as fuel for our sustainability fire both in Madison, and globally. Here are a few details on the award and why Promega was chosen.
Kaelin and Ratcliffe’s labs focused their efforts on the transcription factor HIF (hypoxia-inducible factor). This transcription factor is critical in the cellular adaptation of to changes in oxygen availability.
When oxygen levels are elevated cells contain very little HIF. Ubiquitin is added to the HIF protein via the VHL complex and it is degraded in the proteasome. When oxygen levels are low (hypoxia) the amount of HIF increases.
In 2001 both groups published articles characterizing the interaction between VHL and HIF, and these articles were referenced by the Nobel Prize Organization in their press release about this year’s award. (1,2). Both studies demonstrated that under the normal oxygen conditions hydroxylation of proline residue P564 enabled VHL to recognize and bind to HIF.
The use of cell free expression (i.e., TNT Coupled Transcription/Translation System) by both labs was key in the characterization of the VHL:HIF interaction The labs utilized HIF and VHL 35-S labeled proteins generated via the TNT system under both normal or in a hypoxic work station to:
Determine the affect of ferrous chloride and cobaltous chloride on the interaction
Map the specific region of HIF required for the interaction to occur (556-574)
Determine the effect of HIF point mutations on the interaction
Use synthetic peptides to block the interaction
Conclude that a factor in mammalian cells was necessary for the interaction to occur.
Do you ever wonder whether you’re on the “right” career path? If you’re in academia, the trajectory you should follow can seem pretty rigid—undergrad degree, PhD, postdoc, PI, and then the elusive tenure. Have you considered that there isn’t a single “correct” path?
That’s the message one of Promega’s Science Writers, Julia Nepper PhD, emphasized when she was interviewed recently on the HelloPhD podcast. The HelloPhD podcast offers advice to help students, postdocs, faculty and scientists navigate the hard questions they face every day related to graduate school and careers in science.
121: A Teenager Goes to Grad School, Julia offered her insight on dealing
with failure and finding a scientific career path that’s right for you. She
also shared her unusual story of starting grad school at age 17 and some of the
unique experiences she had along the way that led her to choose a career in
To listen to this podcast and learn more about HelloPhD, click here.
With the advent of genome editing using CRISPR-Cas9, researchers have been excited by the possibilities of precisely placed edits in cellular DNA. Any double-stranded break in DNA, like that induced by CRISPR-Cas9, is repaired by one of two pathways: Non-homologous end joining (NHEJ) or homology-directed repair (HDR). Using the NHEJ pathway results in short insertions or deletions (indels) at the break site, so the HDR pathway is preferred. However, the low efficiency of HDR recombination to insert exogenous sequences into the genome hampers its use. There have been many attempts at boosting HDR frequency, but the methods compromise cell growth and behave differently when used with various cell types and gene targets. The strategy employed by the authors of an article in Communications Biology tethered the DNA donor template to Cas9 complexed with the ribonucleoprotein and guide RNA, increasing the local concentration of the donor template at the break site and enhancing homology-directed repair. Continue reading “All You Need is a Tether: Improving Repair Efficiency for CRISPR-Cas9 Gene Editing”
Formalin Fixed Paraffin Embedded samples (FFPE) have been a mainstay of the pathology lab for over 100 years. Initially FFPE blocks were sectioned, stained with simple dyes and used for studying morphology, but now a variety of biomolecules can be analyzed in these samples. Over the past 10 years we have discovered that there is a treasure trove of genomics data waiting to be unearthed in FFPE tissue. While viral RNAs and miRNA were some of the first molecules found to be present and accessible for analysis starting in the 1990s, improvements to DNA and RNA extraction methods have demonstrated that PCR, qPCR, SNP genotyping, Exome and WGS are possible. This has resulted scientific publications of DNA and RNA data generated from FFPE samples starting in 2006, and today we see immense amounts of data generated from FFPE—with nearly 2000 citations in 2018 reporting sequencing of FFPE samples.
Depending on the type of project, prospective or
retrospective, the genomics scientist has an opportunity to affect the
probability of success by better understanding the fixation process. The
challenge with FFPE is the host of variables that have the potential to
negatively affect downstream assays.
Today’s blog is guest-written by Wihan Adi, a Master’s student majoring in physics at Justus-Liebig-University in Giessen and team member of iGEM Marburg. Although his background is in nuclear and particle physics, his research interests shifted toward affordable biosensors for point-of-care cancer detection, which is how he ended up doing microbiology for iGEM.
Back in March when the iGEM season had just started, Maurice, a fellow iGEM Marburg team member, told me that he was exchanging emails with Margaretha Schwartz from Promega. Given my background as a physics student, Promega was not a household name for me at the time. “So, are you interested in automating a plasmid purification protocol?” asked Maurice. He told me that Promega was willing to supply the Wizard® MagneSil® Plasmid Purification System for this purpose; that was another name that added to my confusion.
This year, iGEM Marburg is aiming to establish a fast phototrophic organism as a synthetic biology chassis. For this goal we chose Synechococcus elongatus UTEX 2973, with a reported doubling time of 90 minutes. More specifically, we are creating an easy to use toolbox to empower rapid design testing, including genome engineering tools, self-replicating plasmid systems, natural competence and a Golden Gate-based part library. Our team chose to work on phototrophic organisms because we envision accelerating research in this particular field. (Note: Last year, Marburg’s iGEM project won the Grand Prize!)
In the fall of 1989, a small group of forensic scientists, law enforcement officials and representatives from Promega Corporation gathered in Madison, Wisconsin, for the very first International Symposium on Human Identification (ISHI). At the time, DNA typing was in its infancy and had not yet been validated as a forensic method. The available technology consisted of two methods: detection of restriction fragment length polymorphisms (RFLPs) and variable number of tandem repeats (VNTRs). Promega had developed products based on both analytical methods, which essentially provide a DNA “fingerprint” or profile for each individual tested.
Among the attendees at that first symposium was Tom Callaghan, then a graduate student. That experience made a significant impact on his career path. Last week, at ISHI 30, he presented a session on rapid DNA testing. Dr. Callaghan currently serves as a Senior Biometric Scientist for the FBI. In 1999, he was instrumental in launching the FBI’s Combined DNA Index System (CODIS) and in 2003, he became the first CODIS Unit Chief.
Our innate immune system was meant to do good. Up until a
century ago, most humans died from infectious diseases like diarrhea,
tuberculosis and meningitis. Over millions of years, our immune system has
evolved to fight these life-threatening infections from pathogens. As a result,
we have developed a highly efficient response to these tiny invaders. But it
seems that our immune system may be turning against us.