Today’s blog is guest-written by Susanna Harris, a graduate student at the University of North Carolina in Chapel Hill.
thing to hear that everything is going to be okay. It’s another to know it and
make it that way.
At the end
of a lab meeting where I had outlined my last of six years getting my PhD, my
advisor announced she would be moving the lab from North Carolina to Massachusetts
in about six months. Just when everything had settled into place, this
announcement turned my bookshelf of plans on its side once again. Suddenly, I
didn’t know what would happen next.
I chose to
go to grad school partly to challenge myself to accept uncertainty. When I
started my PhD in Microbiology in 2014, I thought this would mean reading new
papers and adjusting experiments accordingly. As it has turned out, the real
challenge has been to constantly get back up as life and graduate school knock
me flat on my ass. Yes, I needed strength to power through, but even more than
that, I needed resilience.
Cardiovascular diseases, or CVDs, are collectively the most notorious gang of cold-blooded killers threatening human lives today. These unforgiving villains, including the likes of coronary heart disease, cerebrovascular disease and pulmonary embolisms, are jointly responsible for more deaths per year than any other source, securing their seat as the number one cause of human mortality on a global scale.
One of the
trademarks of most CVDs is the thickening and stiffening of the arteries, a
condition known as atherosclerosis. Atherosclerosis is characterized by the
accumulation of cholesterol, fats and other substances, which together form
plaques in and on the artery walls. These plaques clog or narrow your arteries
until they completely block the flow of blood, and can no longer supply
sufficient blood to your tissues and organs. Or the plaques can burst, setting
off a disastrous chain reaction that begins with a blood clot, and often ends
with a heart attack or stroke.
Given the global prevalence and magnitude of this problem, there is a significant and urgent demand for better ways to treat CVDs. In a recent study published in Nature Communications, researchers at the Carnegie Institution for Science, Johns Hopkins University and Mayo Clinic are taking the fight to CVDs through the study of low-density lipoproteins (LDLs), the particles responsible for shuttling bad cholesterol throughout the bloodstream.
Here in Technical Services we often talk with researchers at the beginning of their project about how to carefully design and get started with their experiments. It is exciting when you have selected the Luciferase Reporter Vector(s) that will best suit your needs; you are going to make luminescent cells! But, how do you pick the best way to get the vector into your cells to express the reporter? What transfection reagent/method will work best for your cell type and experiment? Do you want to do transient (short-term) transfections, or are you going to establish a stable cell line?
In recent years, it’s become a well-documented fact that koalas are about as picky as they are adorable. These beloved Australian marsupials have evolved to become ecological specialists: consumers that feed primarily on a single organism, or small number of organisms. Eucalyptus, their organism of choice, encompasses approximately 900 species, most of which are native to Australia. To the koala’s benefit, the leaves of eucalyptus trees are difficult to digest, low in protein content and their chemical composition contains compounds that are toxic. This makes their competition for eucalyptus with other species virtually nonexistent.
That’s not to say there isn’t competition amongst themselves. Of those 900 species of eucalyptus, koalas are only really known to feed on about 40–50 of them, and of those 40–50, they tend to limit their diet to around 10. Depending on their location, however, some koalas will only stick to one preferred type, which can lead to trouble.
In the late-80’s through the 90’s, food and health agencies focused
on a mysterious fatal brain disease that infected thousands of cattle. Bovine
spongiform encephalitis—or “mad cow disease”—is caused by an infectious protein
called a prion. Despite fears that tainted meat would cause the disease to
spread to humans, mad cow disease never really made an impact on human health.
However, forms of the prion disease such as Creutzfeldt-Jakob disease do affect
In addition to Creutzfeldt-Jakob disease, many neurodegenerative diseases such as Alzheimer’s, Parkinson’s, Huntington’s and amyotrophic lateral sclerosis (ALS or Lou Gehrig’s disease) are now thought to be a result of prion-like activity. There is no cure for these diseases, however, new experimental treatment strategies might help slow the progression of neural degeneration.
With average sea surface temperatures increasing around the world, coral bleaching events are growing in extent and severity. More than two thirds of the corals in the Great Barrier Reef, the world’s largest coral reef, have already bleached. While the physiological consequences of coral bleaching are well-studied, we still don’t fully understand how bleaching happens on a cellular level.
Steve Palumbi at Stanford University is delving deeper into the mechanisms by which coral bleaching occurs. In 2018, Promega pledged $3 million over three years to the nonprofit Revive & Restore Catalyst Science Fund, to identify and develop advanced techniques for conservation, enhancing biodiversity, and genetic rescue. Palumbi was awarded the first grant from this fund to study the genomic stress trigger that causes corals to bleach in warming oceans.
Human teeth play a key role in our understanding of how organisms evolve. Whenever a possible new member of the hominid family is uncovered, the shape and number of teeth are used to place that individual in the family tree. Teeth also harbor information about pathogens that have plagued humans for millennia. Because bacteria use our bloodstream as a transport system, protected places that can preserve DNA—like the pulp of teeth—are a rich medium for uncovering information about humans and the microbes that infected them.
Teeth have been the choice for identifying the infectious agent behind the Plague of Justinian in the sixth century and the Black Plague in the 14th century. In fact, Yersinia pestis, the bacterium responsible for these plagues, has infected humans as far back as the Neolithic. But what can we learn about the pandemic strain or strains of Y. pestis described in historical records? A team of researchers from Europe and the US, many of whom have been delving into the history of Y. pestis for the last decade, wanted to further investigate the Plague of Justinian. They studied bacterial DNA extracted from human remains found in Western European communal graves that were dated to around 541–750, the period of the historically documented Plague of Justinian. Their investigation examined the bacteria’s diversity and how far it spread during this “First Pandemic” of plague. Continue reading “Delving into the Diversity of The Plague of Justinian”
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.
Bacteria make you sick. The idea that bacteria cause illness has become ingrained in modern society, made evident by every sign requiring employees to wash their hands before leaving a restroom and the frequent food recalls resulting from pathogens like E. coli. But a parallel idea has also taken hold. As microbiome research continues to reveal the important role that bacteria play in human health, we’re starting to see the ways that the microbiota of the human body may be as important as our genes or environment.
The story of how our microbiome affects our health continues to get more complex. For example, researchers are now beginning to understand that the composition of bacteria residing in your body can significantly impact the effects of therapeutic drugs. This is a new factor for optimizing drug response, compared to other considerations such as diet, interaction with other drugs, administration time and comorbidity, which have been understood much longer.
The review “Kinase Inhibitors: the road ahead” was recently published in Nature Reviews Drug Discovery. In it, authors Fleur Ferguson and Nathanael Gray provide an up-to-date look at the “biological processes and disease areas that kinase-targeting small molecules are being developed against”. They note the related challenges and the strategies and technologies being used to efficiently generate highly-optimized kinase inhibitors.
This review describes the state of the art for kinase inhibitor therapeutics. To understand why kinase inhibitors are so important in the development of cancer (and other) therapeutics research, let’s start with the role of kinases in cellular physiology.