Author: Johanna Lee

Producing Snake Venom— in the Lab

Posted on by Johanna Lee

Snakebite is a serious public health issue in many tropical countries. Every year, roughly 2 million cases of poisoning from snakebites occur, and more than 100,000 people die. Snake venom is extremely complex, containing a cocktail of chemicals, many of which are undefined. This complicates the development of new therapeutics for treating snakebite.

Antivenom is the most effective treatment for snakebites, but its production is complex and dangerous. It involves manually milking the venom from different species of live snakes, then injecting small doses of the venom into animals (mostly horses) to stimulate an immune response. After a period of time, antibodies form in the animal’s blood, which is purified for use as antivenom.

But what if we could produce snake venom in the lab, instead of using live snakes? Recently, a group from the Netherlands did just that by growing organoids derived from snake venom glands.

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Learnings From the Eppendorf Exchange Program

Posted on by Johanna Lee

Last year, on Promega’s 40th anniversary, we received a generous gift from a friend in the industry: Eppendorf. That gift was an exchange program. The teenage child of any Promega employee was given the opportunity to visit an Eppendorf family in another country, and in return host the Eppendorf family’s child in their home. The goal was for both children to experience another culture and build a relationship with each other.

In 2019, 11 Promega children bid good-bye to their parents, hopped on a plane, and flew to Germany. There they would stay for three weeks with a family they’ve never met. For all involved, it proved to be a valuable and positive learning opportunity. Here are a few takeaways from their experience:

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Diabetes Research: Measuring the Activity of Insulin

Posted on by Johanna Lee

We rely on insulin supplied by our pancreas at the right dose and at the right time to control our blood glucose levels and energy storage. Insulin works by regulating the energy usage of various cell types in the body. When this process goes awry, it can cause diabetes.

There are two types of diabetes, defined by how insulin is dysregulated. In Type 1 Diabetes (T1D), the pancreas produces too little insulin. Patients need to give themselves insulin in order to respond to glucose in the diet. In Type 2 Diabetes (T2D), patients do not respond well to the insulin produced in their body. Therefore, they need to give themselves more to avoid hyperglycemia (high blood glucose).

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NLRP3: The New Hope for Treating Chronic Inflammatory Diseases

Posted on by Johanna Lee

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.

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How Antioxidants Stimulate Lung Cancer Metastasis

Posted on by Johanna Lee

You may have heard that antioxidants are good for you, but in some cases, they can be harmful. In 2014, a study led by Dr. Martin Bergo at the Karolinska Institutet in Sweden showed that antioxidant supplements, such as vitamin E, accelerated tumor growth. This sparked much controversy as it was previously believed that antioxidants prevented tumor progression.

Since then, more evidence suggest that antioxidants indeed promote tumor progression by reducing reactive oxygen species (ROS) that block tumor growth. In 2019, the same group published a follow-up study to further explain how antioxidants promote lung cancer metastasis.

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Evaluating CAR NK Immunotherapy in Patient-Derived Colorectal Organoids

Posted on by Johanna Lee

In recent years, great advances have been made in the field of immunotherapy to treat cancer. One of the most promising treatments involves engineering immune cells to express chimeric antigen receptors (CAR). These receptors are carefully designed to recognize antigens expressed on the surface of tumor cells. Once the target is recognized, the CAR-engineered immune cells can attack and kill the tumor cells. CAR T cells have been successfully used to treat certain blood cancers—three CAR T therapies for lymphoma and leukemia have gained US FDA approval. In these cases, T cells were taken from individual patients, grown and genetically-altered in the lab, then reintroduced into the same patient. Continue reading “Evaluating CAR NK Immunotherapy in Patient-Derived Colorectal Organoids”

How Gut Microbes Affect Our Brain

Posted on by Johanna Lee

coliform bacteriaThink about the last time you gave a presentation. The feeling of having “butterflies in your stomach”. Or when you meet someone for the first time, that “gut feeling” of whether you two will get along. In our day-to-day lives, we often associate what happens in the gut with what goes on in our brain. In fact, scientific evidence suggests that our gut and our brain frequently communicate—through gut microbes. Apparently, the existence of trillions of bacteria and eukaryotes in our gut is not only crucial for our physical health, they may also be important for our mental health.

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How Cheese Helped Us Understand Microbial Interactions

Posted on by Johanna Lee

In almost every environment on earth, such as soil, human skin and gut, there lives a whole community of microbes—sometimes up to hundreds of species. It may seem like they all flourish in peace. But just like you may have friendly or hostile interactions with your neighbors, the different bacterial species interact in various ways. They may cooperate, compete or, sometimes, even kill each other. The interaction is complicated, and scientists have struggled to understand the nature of these microbiome interactions. How do microbiomes assemble and maintain stability? How do the interactions among different species affect gene expression?

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4 Things We Recently Learned About Cats

Posted on by Johanna Lee

We know a lot about cats. We know that they’re adorable, they make us happy and they can survive a fall from a 32-story building. But apparently, there’s still a lot we don’t know about them. Here are four things we only recently discovered about cats.

1. Sharp, tiny “papillae” on cat tongues help deep-clean their fur.

Cats spend much of their time licking themselves. On the surface of their tongue are hundreds of tiny claw-shaped spines called papillae, each the size of half a grain of rice. Recently, a study published in PNAS revealed the purpose of these structures. The authors found that the tips of the papillae create a U-shaped cavity (imagine a coffee straw cut in half). The cavity holds saliva and helps move it down through the fur to the cat’s skin, allowing deeper cleaning. “Why should I care,” you ask? With these results, the authors created a brush that mimics a cat’s tongue. It tugged less and was easier to clean than a normal brush. The new design could be used to distribute cleaning solutions into carpets. Or, remove allergens from cat fur.

2. Feral cats aren’t great at controlling city rat population.

Many people assume that feral cats hunt and kill rats, helping control city rat population. However, a recent study showed that they’re not doing a great job. The researchers set up cameras around a rat colony in New York City and recorded the behaviors of feral cats that came near. A lucky graduate student watched all 306 videos and tallied cat behaviors such as walking, stalking and chasing. Over 79 days, only three times did a cat actively hunt a rat; and of the two cases in which the hunt was a success, the rats were relatively small in size. The presence of the cats did, however, cause the rats to hide more. Bottom line, let’s not release cats to control rat population.

3. Male cats tend to be left-pawed, and females right-pawed.

Just like humans can be left- or right-handed, cats also prefer using one of their paws over the other. The scientific term for this is called laterality, and it has been examined in many animals including rats, frogs, primates and whales. In this recent study, the paw preference of 44 pet cats were examined in their own homes. They found that most cats showed laterality when reaching for food (73%), stepping down stairs (70%) or stepping over their litter box (66%). While 90% of humans are right-handed, laterality in cats is much more equal—roughly half are left-biased and half right-biased. Surprisingly, the researchers also discovered that male cats are much more likely to prefer their left paw, while females prefer their right paw. The reason is unclear, but it may hint at the underlying differences of the male and female brains.

4. Cats domesticated themselves over thousands of years without much genetic change.

Humans can’t tell cats what to do—they do what they want, when they want. If you’ve ever had a cat, you know it’s true. In fact, this statement also applies to how they were domesticated. In a comprehensive study, researchers examined ancient DNA from more than 200 cats spanning the last 9,000 years and found that the modern domestic cat comes from two main lineages: one from southeast Asian and the other from Egypt. Cats likely began hanging out with humans when our ancestors began farming. With an abundance of rodents that fed on crops, cats voluntarily stayed close and slowly domesticated on their own. The genetic makeup of domesticated cats hasn’t changed much over thousands of years, except the appearance of striped or blotched tabby coat markings. And why would they change? They’re perfect just the way they are.

Dear Tech Serv, Thank You!

Posted on by Johanna Lee

It’s that time of year again. Time to be thankful and show gratitude for those special people in your life. The undergrad who does the dishes, the labmate who shares their buffers when yours runs out, the collaborator that sends you data on a Saturday… Take a moment this week to say thank you, or send them an email to show your appreciation.

Today, we want to thank our Technical Services team. They work hard to help researchers choose the right assay for their needs, understand results and troubleshoot technical problems. They strive to provide the best service for those in need. Many on the receiving end have sent thankful messages:

“I deeply appreciate the help you have been and the email you just sent. I think with the information here, I may have sorted out an issue that has plagued our lab for the past few months.”

“Cannot tell you how grateful I am–you’ve been a tremendous help.”

“You are super sharp and caught critical errors in my protocol (the calculation and dilution errors you referenced below). While few of my colleagues run kinase assays, I did consult 6 of them, and none caught the errors you did. You’re clearly an expert and I truly appreciate how you’ve tailored everything for my ‘beginner’ level.”

“Wow, I cannot thank you enough! You have NO idea how helpful this is! You guys are absolutely great.”

Here’s one heart-warming story we had to share in which Tech Serv helped a group of students turn frowns into smiles.

In April, Tech Serv received a message from a professor from a university in Michigan regarding an issue with the pGEM Vector System. He was teaching a cell and molecular biology course and his students were unable to generate any colonies. “I have a very disappointed group of seniors on my hands. Please see the photo attached. All those sad faces trying to exude how hard they’ve worked with nothing to show for it. Any insight would be greatly appreciated,” he wrote.

“I understand the frustation of a kit that is not working, the students look so sad!” replied the Tech Serv team. Turns out, the cells may have been past expiration or subjected to repeated freeze thaws that caused the cells to lose competence. Tech Serv sent them a replacement kit with a photo of the team for encouragement.

“We greatly appreciate you replacing what we have and aim to turn those frowns into happy faces before graduation,” the professor replied.

Two weeks later, they got their colonies and wrote back: “It worked very well! We were able to make the most of this and they experienced a very good exercise in troubleshooting. I would say the group would view all that happened as a success. Thank you, we will continue to order from Promega as you’ve always proven to be a very client-friendly company!”

Nothing brings more happiness to the Tech Serv team than your success, so don’t hesitate to contact them with any questions you may have. They’re here to help.

Thanks, Tech Serv!