There’s a certain group of people (including this blog post author) who derive no small amount of amusement from seeing stock photos of DNA and pointing out flaws in the structure. It’s even more amusing when these photos are used in marketing by life science companies. The most common flaw: the DNA molecule is a left-handed double helix.
What does that even mean? DNA, like many organic chemicals in biology, is a chiral molecule. That is, it can exist in two structural forms that are mirror images of each other but are not superimposable (enantiomers). Just like your left and right hands are mirror images of each other, the two DNA structures are left-handed and right-handed double helices. The DNA double helix is chiral, because its building blocks (nucleotides) are chiral.
It can be challenging, at first glance, to tell whether an image of DNA is left-handed or right-handed. Various helpful hints are available; however, the one that I’ve found easiest to remember is described in a blog post by Professor Emeritus Larry Moran at the University of Toronto:
Imagine that the double helix is a spiral staircase, and you’re walking down the staircase. If you’re turning to the right as you descend, the DNA structure is right-handed; if turning to the left, it’s left-handed. In the image shown earlier, the DNA molecule on the right is a right-handed double helix, while its mirror image is left-handed.
Roses, the universal symbol of love and affection, are one of the most popular ornamental flowering shrubs used by landscapers and home gardeners and account for almost half of the billion-dollar ornamental plant market. The growing prevalence of rose rosette disease poses a significant threat to these industries. This lethal disease is caused by the Rose rosette emaravirus (RRV) and transmitted by the tiny eriophyid mite, Phyllocoptes fructiphilus. Infection by RRV results in prolific growth of clustered and bunched plant shoots (witches’ broom), malformed flowers and leaves, malformed shoots and enlarged stems and abundant leaf growth and thorniness. This excessive growth depletes the plant’s energy, eventually causing death.
Emerging and Devastating Plant Viruses of the Genus Emaravirus
RRV is a single-stranded, segmented, negative-sense RNA virus belonging to the genus Emaravirus, a relatively new genus that was established in 2012. These emerging viruses can be devastating to trees, herbaceous woody plants and vines. At Texas A&M University, Dr. Jeanmarie Verchot’s lab is working to better characterize and understand these new viruses. In addition to threatening roses, these viruses cause damage to important agriculture crops such as wheat and pigeon peas. They also endanger sensitive ecosystems when they infect plants specialized to a particular habitat, as is the case with Palo verde broom virus infection of palo verde trees of the Sonoran Desert (1).
It has become increasingly evident to scientists that the intellectual prowess of your average crow has been roundly underestimated. With remarkable skills including superior social acumen, analogical thinking and the ability to craft and use tools, crows seem to prove themselves more and more clever with every investigation into the inner workings of their small, but mighty, brains.
Most recently, new research has revealed that crows may be capable of recursion, a hallmark feature of advanced linguistic ability originally posited by Noam Chomsky in his hierarchy of grammars. Recursion in language is used to grow the complexity of sentence structure to contain, in theory, an infinite number of embedded elements or ideas. Put simply, linguistic recursion refers to the nesting of one grammatical structure, this sentence for example, within another of the same kind. Formerly thought to be a skill exclusive to primates, research like that recently published in Science Advances has challenged this assumption.
At the time of writing this post, no scientist had yet discovered the secret to immortality. In our world, we’ve come to accept that living things are born, grow old and die—the circle of life.
And yet, for many years, life scientists believed that the circle of life did not apply to our constituent cells when cultured in a laboratory. That is, cultured normal human cells were immortal, and they would continue to grow and proliferate forever, as long as they were provided with the necessary nutrients.
Pioneering work published in 1961 by Leonard Hayflick and Paul Moorhead challenged that theory (reviewed in 1). Their research showed that normal cells in culture have a finite capacity to replicate. After they reach a certain number of replicative cycles, cells stop dividing. Hayflick and Moorhead made the important distinction between normal human cells and cultured cancer cells, which are truly immortal. In later years, the limit to the number of replicative cycles normal human cells can undergo became known as the Hayflick limit. Although some scientists still express skepticism about these findings, the Hayflick limit is widely recognized as a fundamental principle of cell biology.
On October 3, 2022, the Nobel Assembly at Karolinska Institutet announced the 2022 Nobel Prize in Physiology or Medicine had been awarded to Svante Pääbo, director of the Department of Genetics at the Max Planck Institute for Evolutionary Anthropology in Leipzig, Germany. The Assembly cited his “discoveries concerning the genomes of extinct hominins and human evolution”. They mentioned the highlight of his research: the seemingly impossible task, at the time, of sequencing the Neanderthal genome. The discoveries that followed from this sequencing project continue to redefine our understanding of modern human origins.
The award showcases the technological advancements made in the analysis of ancient DNA. However, Pääbo’s research had an inauspicious beginning. In 1985, he published the results of his early work, cloning and sequencing DNA fragments from a 2,400-year-old Egyptian mummy (1). Unfortunately, later analysis revealed that the samples could have been contaminated by the researchers’ own DNA (2).
We’ve learned a few important lessons from the COVID-19 pandemic.
Perhaps the most significant one is the importance of an early and rapid global response to the initial outbreak. A coordinated response—including widespread use of masks and other personal protective equipment (PPE), travel restrictions, lockdowns and social distancing—could save lives and reduce long-term health effects (1). Widespread availability of effective vaccines goes hand in hand with these measures.
New Boosters to Fight Omicron
Last month, Pfizer/BioNTech announced the US Food and Drug Administration (FDA) had granted emergency use authorization (EUA) for a new adapted-bivalent COVID-19 booster vaccine for individuals 12 years and older. This vaccine combines mRNA encoding the wild-type Spike protein from the original vaccine with another mRNA encoding the Spike protein of the Omicron BA.4/BA.5 subvariants. Moderna also announced FDA EUA for its new Omicron-targeting COVID-19 booster vaccine. The Omicron variant of SARS-CoV-2 shows multiple mutations across its subvariants, and it is currently the dominant SARS-CoV-2 variant of concern across the world.
Booster doses of vaccines have become a way of life, both due to declining effectiveness of the original vaccines especially in older adults (2), and the rapid mutation rate of SARS-CoV-2 (3). Clinical data for the new Pfizer/BioNTech booster vaccine showed superior effectiveness in eliciting an immune response against Omicron BA.1 compared to the original vaccine. Previously, Moderna published interim results from an ongoing phase 2-3 clinical trial, showing that the new bivalent booster vaccine elicited a superior neutralizing antibody response against Omicron, compared to its original COVID-19 vaccine (4).
The first monoclonal antibody (mAb) was produced in a lab 1975, and the first therapeutic mAb was introduced in the United States to prevent kidney transplant rejection in 1986. The first mAb used in cancer treatment the anti-CD20 mAb, rituximab, was used to treat non-Hodgkin’s lymphoma and chronic lymphocytic leukemia. Today therapeutic mAbs have become a mainstay of cancer, autoimmune disease, and metabolic disease therapies and include HERCEPTIN® used to treat certain forms of breast cancer, Prolia used to treat bone loss in post-menopausal women, and Stelara used to treat autoimmune diseases like psoriatic arthritis and severe Crohn disease, among many others. Therapeutic mAbs bind targets with high specificity and affinity and they can recruit effector cells to drive target elimination through mechanisms such as antibody-dependent cellular cytotoxicity (ADCC) or antibody-dependent cellular phagocytosis (ADCP), making them highly specific, effective therapies.
Post-translational modifications (PTM) of proteins are essential for the function of many proteins, but aberrant modification of protein residues also can interfere with protein function. PTMs occur in two ways. Proteins may be modified through the activity of enzymes such as kinases, phosphorylases, glycosylases and others that add or remove specific chemical moieties to amino acid residues. PTMs can also result from non-enzymatic reaction between electrophilic compounds and nucleophilic arginine and lysine residues within a protein. Metabolites and metabolic by products produced during glycolysis, especially glyoxal and methylglyoxal (MGO), are examples of such electrophilic compounds. These compounds can react with arginine and lysine to produce advanced glycation end products (AGEs), which are biomarkers associated with aging and degenerative diseases such as Alzheimer disease, diabetes and others. MGO is also elevated in tumors that have switched from oxidative phosphorylation to glycolysis as their main energy production pathway.
Only limited information is available about site-specific MGO PTMs in mammal cells, and most studies have focused on measuring the amount of MGO modifications in a treatment scenario compared to a control. Donnellan and colleagues recently published work to identify specific MGO protein modifications. They used a “bottom-up” proteomic analysis of WIL2-NS B lymphoblastoid whole-cell lysates to identify specific MGO-modified proteins. In particular, the group was looking for modifications in proteins that might explain how MGO activity contributes to aneuploidy.
For the study, 100µg of cellular protein extract was reduced with dithiothreitol and then alkylated with chloroacetamide. The sample was diluted to reduce urea concentration. Trypsin Gold was added and samples were digested for 8 hours at 37°C. Digestion was terminated by adding formic acid. For ProAlanase digestion, 20µg of protein was reduced, alkylated and diluted to reduce urea concentration before adding digesting with ProAlanase for 4 hours at 37°C.
The authors identified 519 MGO-modified proteins. Most of the modifications were identified in the trypsin digestion reactions; however, ProAlanase digestion increased the number of MGO modifications identified by approximately 25% (with less than 4% of the modification sites being detected in both the ProAlanase and trypsin digestion reactions. The authors suggest that ProAlanase increased sequence coverage to reveal sites not detected in the trypsin digestions. Therefore, they conclude that ProAlanase can be used along with trypsin digestion to increase the identification of MGO modifications.
ProAlanase can be used along with trypsin digestion to increase the identification of MGO modifications.
MGO-modified proteins from the WIL2-NS whole cell lysates included proteins involved in glycolysis, translation initiation, protein folding, mRNA splicing, cell-to-cell adhesion, heat response, nucleosome assembly, protein SUMOylation and the G2/M cell cycle transition. More work to further characterize the sites of these modifications and their potential effects on the function of the modified proteins is ongoing.
Vaccine research and development is a major area of focus for life scientists across the globe. Clinical trials have shown that vaccines that target tumors show promise for cancer treatment. Additionally, the emergence of new zoonotic diseases has revealed a need to develop vaccines quickly as the world becomes more global and human populations interact more often with each other and wild habitats. Importantly, these vaccines need to be suitable for distribution in a variety of settings, including those that do not have easy access to refrigeration.
There are many ways to classify the different types of vaccines that are currently available. The National Institute of Allergy and Infectious Diseases in the United States, categorizes vaccines as: whole pathogen vaccines, subunit vaccines, and nucleic acid vaccines—based on how the antigen that stimulates the immune response is delivered to the host.
Whole-pathogen vaccines, which include many of vaccines used in clinical settings, use the entire pathogen (organism that causes the disease) that has been either weakened or killed to elicit a protective immune response. Killed vaccines are what their name implies: the pathogen has been killed so that it cannot cause disease, but enough of its structure remains to generate antibody response. Often, the immune response generated with killed vaccines is not as robust as that generated with other kinds of vaccines.
Weakened or attenuated vaccines use whole pathogens that have been weakened in the laboratory through long-term culture or other means. Our modern MMR (measles, mumps and rubella) vaccine is an example of an attenuated vaccine. These vaccines tend to generate strong, long-lasting immune responses, but have increased risk for immunocompromised individuals.
From macrophages that seek out and destroy infectious agents to fibroblasts that hold tissues and organs together, cells give form and function to our bodies. However, despite their foundational roles in our biology, there is still much we don’t know about cells—like where different cell types are localized, what states a given cell type may take on, how the molecular characteristics of cells change over a person’s lifetime and more. Addressing these questions will provide a deeper understanding about the cellular and genetic basis of human health and disease.
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