How Does Human Papillomavirus (HPV) Infection Drive the Progression of Cervical Cancer?

Posted on by Ken Doyle

Cervical cancer is a major health problem for women, and it is currently the fourth most common cancer in women globally (1). A worldwide analysis of cancer estimates from the Global Cancer Observatory 2018 database showed that cervical cancer disproportionally affects lower-resource countries, on the basis of their Human Development Index; it was the leading cause of cancer-related death in women in many African countries (1).

Global cervical cancer incidence 2018
Estimated cervical cancer global incidence rates from the GLOBOCAN 2018 database; image generated using IARC (http://go.iarc.fr/today).

Infection by human papillomavirus (HPV), a double-stranded DNA virus, is the leading cause of cervical cancer. Many types of HPV have been identified, and at least 14 high-risk HPV types are cancer-causing, according to a World Health Organization (WHO) fact sheet. Of these types, HPV-16 and HPV-18 are responsible for 70% of cervical cancers and pre-cancerous cervical lesions. HPV infection is sexually transmitted, most commonly by skin-to-skin genital contact. Although the majority of HPV infections are benign and resolve within a year or two, persistent infection in women, together with other risk factors, can lead to the development of cervical cancer [reviewed in (2)].

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New Bioluminescent Sensor Can Detect Multiple Antibodies in a Single Drop of Blood

Posted on by Johanna Lee
nanoluc invivo imaging

Antibody tests are often used to determine whether individuals have been exposed to certain bacteria or viruses. For most existing antibody tests, the process goes something like this: A vial of blood is drawn from the individual, the vial is sent to a lab, then a trained technicians performs the antibody test and sends back the results. The current process is less than ideal for a few reasons. For one, blood draws are invasive and can be painful. Also, getting results could take days, due to the time required to deliver and process the sample. Lastly, costs can be high, since the need for trained professionals and specialized instruments in laboratory settings adds to the cost of each test.

What if all you needed to do for an antibody test was apply a single drop of blood onto a thin piece of film, and you would get results on the spot within five minutes? Scientists have recently developed an antibody test based on bioluminescent technology that could make this a reality. They describe their findings in a recent study published in ACS Sensors.

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iGEM in a Pandemic: Reflecting on Human Practices

Posted on by Promega

Today’s blog is written by the University of Copenhagen iGEM Team.

The International Genetically Engineered Machine (iGEM) competition has 257 teams of students competing this year. Despite all of the unique difficulties we’re all facing in 2020, the University of Copenhagen is competing once again. This year’s project involves a unique approach to Chronic Inflammatory Diseases (CIDs).

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A Closer Look at C. difficile Biology with Luminescent Tagging

Posted on by Jordan Villanueva

Clostridium difficile is a bacterium that infects around half a million people per year in the United States. The infection causes symptoms ranging from diarrhea to severe colitis, and it’s one of the most common infections contracted while staying in the hospital. As the global incidence of C. diff infection has risen over the past decade, so has the pressure to develop novel therapeutic strategies. This requires a thorough exploration of all aspects of C. difficile biology.

Two recent papers published by researchers at the University of Leiden have shed light on C. difficile physiology using HiBiT protein tagging. The HiBiT system allows detection of proteins in live cells using an 11 amino acid tag. The HiBiT tag binds to the complementary LgBiT polypeptide to reconstitute the luminescent NanoBiT® enzyme. The resulting luminescence is proportional to the amount of HiBiT-tagged protein that is present.

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Rapid COVID-19 Testing, International Collaboration, and a Family Favor

Posted on by Jordan Villanueva

When the COVID-19 pandemic descended on New York in March 2020, Christopher Mason, PhD, knew he was in a unique position to contribute. The Mason Lab specializes in sequencing and computational methods in functional genomics – valuable expertise for addressing an emerging infectious disease. Within days, Chris and his team were helping to analyze patient data, as well as developing new tests and detection methods for the SARS-CoV-2 virus.

3d model of coronavirus covid-19

The Mason Lab developed protocols for a simple COVID-19 detection test that requires less time and equipment than common PCR methods. Their subsequent preprint detailing these methods quickly gained widespread attention, and Chris found himself fielding an endless stream of questions and requests.

During the frenzy, Chris received a call from his older brother. Cory Mason is the mayor of Racine, Wisconsin, the brothers’ hometown.

“He said he saw me tweeting about our new test,” Chris says. “Then he asked me, ‘What if we set it up here in Wisconsin?’’

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Screen Media in the Time of COVID-19: Should You Be Reading this Blog?

Posted on by Michele Arduengo

Screen Media. Cell phones. Social media accounts. If you are a parent, you have probably discussed rules of engagement with your children about these things. All of our modern social media platforms are designed to keep us engaged with them by showing us the latest post, the next video or the people now online. Work emails give us notifications when something arrives in our Inbox. Business software platforms like Microsoft Teams send us notifications whenever someone comments in a conversation we have ever been part of. There are many siren signals pulling us toward our screens.

Enter COVID-19, the flu-like illness caused by the SARS-CoV-2 virus that has already claimed the lives of 210,000 people in the United States, and leaving countless others permanently affected by other long-term health consequences. Spread by aerosol, COVID-19 is most dangerous in places where lots of people congregate in a small area, particularly if they are talking to each other. Consequently, office buildings are empty as many of us work or go to school remotely.

Before COVID-19, if I had a day full of meetings at work, I was running from conference room to conference room, two miles, uphill, in the snow between buildings. Now, a day full of meetings means sitting in front of a computer monitor, trying to figure out how I will get any kind of break between calls. The average number of steps recorded by my pedometer has decreased markedly since March when our remote work started.

Technology has been an incredible blessing during this pandemic—allowing us to continue to work and stay connected with friends and family. Technology is the only way that some people can connect with loved ones in long-term care facilities. It allows students to continue learning through remote classrooms and chats.

But what has been the effect of the increased time spent on screens during this pandemic?

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Maximize Your Time in the Lab: Improve Experimental Reproducibility with Thaw-and-Use Cells

Posted on by Michele Arduengo

Many cell biology researchers can name their department’s  or institutions’s “cell culture wizard”—the technician with 20+ years of experience whose cell cultures are always free from contamination, exhibit reliable doubling rates and show no phenotype or genotype weirdness. Cell culture takes skill and experience. Primary cell culture can be even more difficult still, and many research and pharmaceutical applications require primary cells.

Yet, among the many causes of failure to replicate study results, variability in cell culture stands out (1). Add to the normal challenges of cell culture a pandemic that shut down cell culture facilities and still limits when and how often researchers can monitor their cell culture lines, and the problem of cell culture variability is magnified further.

Treating Cells as Reagents

A good way to reduce variability in cell-based studies is to use the thaw-and-use frozen stock approach. This involves freezing a large batch of “stock” cells, then performing quality control tests to ensure they respond appropriately to treatment. Then whenever you need to perform an assay, just thaw another vial of cells from that batch and begin your assay—just like an assay reagent! This approach eliminates the need to grow your cells to a specific stage, which could take days and introduce more variability.

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The Impact of Positive Self-Talk: A Next-Level Story

Posted on by Promega

Today’s blog is written by Malynn Utzinger, Director of Integrative Practices, and Tim Weitzel, ESI Architect.

Last month in this series, we posed to you that the most important decision you’ll ever make is the one about how to respond to the circumstances of your life – the story you tell yourself when the rough patches of life show up. Because of our brains’ wiring, we tend to spin self-defensive and blaming stories as a first line of defense until we learn to pause, check in with ourselves, and cultivate a narrative of more generative possibilities.
This month, we promised you a next-level story that shows the outer impact that happened when one person changed his self-talk.

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How A Change in Immune Cell Metabolism Contributes to Severe COVID-19

Posted on by Johanna Lee
Illustration of energy metablism in cell.

There is still a lot we don’t know about COVID-19 and the virus, SARS-CoV-2, that caused the pandemic and changed the way we live. But there are two things we do know about the disease: 1) Patients with diabetes and high blood glucose levels are more likely to develop severe COVID-19 symptoms with higher mortality.  2) Patients that experience an uncontrolled inflammatory response, called the cytokine storm, also develop more severe COVID-19 symptoms. The fact that both high glucose levels and an exaggerated immune response drive severe disease suggests that the two may be linked. But how? The answer may lie in the metabolism of immune cells in the lungs of COVID-19 patients, according to a recent study published in Cell Metabolism.

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Identifying the Ancestor of a Domesticated Animal Using Whole-Genome Sequencing

Posted on by Sara Klink

What animal can be found around the globe that outnumbers humans three to one? Gallus gallus domesticus, the humble chicken. The human appetite for eggs and lean meat drive demand for this feathered bird, resulting in a poultry population of over 20 billion.

Controversy over the origin of the domestic chicken (when, where and which species) have lead some researchers to look for that information in the genomes of contemporary chicken breeds and wild jungle fowl, the candidates from which chickens were derived. By sequencing over 600 genomes from Asian domestic poultry as well as 160 genomes from all four wild jungle fowl species and the five red jungle fowl subspecies, Wang et al. wanted to understand and identify the relationships and relatedness among these species and derive where domesticated chickens first arose.

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