Neuroscience

Unlocking the Neuroscience of How Experiencing Traumatic Stress Leads to Aggression – SciTechDaily

By Society for NeuroscienceMay 18, 2020

Strengthened amygdala pathways increase aggression, may be targets for PTSD treatment.

Traumatic stress can cause aggression by strengthening two brain pathways involved in emotion, according to research recently published inJNeurosci. Targeting those pathways via deep brain stimulation may stymie aggression associated with post-traumatic stress disorder.

The consequences of traumatic stress linger long after the stress ends. People suffering from post-traumatic stress disorder often display heightened aggression, caused by unknown changes in the amygdala. An almond-shaped structure nestled deep inside the brain, the amygdala plays an essential role in emotion, social behaviors, and aggression.

Attacking another animal or experiencing traumatic stress strengthens amygdala pathways and leads to aggressive behavior. Credit: Nordman et al., JNeurosci 2020

Nordman et al. examined how different amygdala circuits changed in male mice after traumatic stress. Two connections strengthened, resulting in more attacks on other mice: the circuitry connecting the amygdala to the ventromedial hypothalamus and the bed nucleus of the stria terminalis. The former modulates the frequency of attacks, while the latter controls the length of attacks. The research team then used low frequencies of light to stop the pathways from strengthening, preventing an increase in aggressive behavior. Deep brain stimulation may elicit the same effect in humans.

Reference: Potentiation of Divergent Medial Amygdala Pathways Drives Experience-Dependent Aggression Escalation by Jacob Nordman, Xiaoyu Ma, Qinhua Gu, Michael Potegal, He Li, Alexxai V. Kravitz and Zheng Li, 18 May 2020, JNeurosci.DOI: 10.1523/JNEUROSCI.0370-20.2020

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Unlocking the Neuroscience of How Experiencing Traumatic Stress Leads to Aggression - SciTechDaily

Neuroscience

The Brain Can "Update" Memories With Incorrect Information – Technology Networks

A new study shows that the brain can update or edit poorly-formed memories with the wrong information, potentially causing confusion, anxiety disorders like PTSD and, in extreme cases, false memories.

The research, published in Current Biology, is one of the first comprehensive characterisations of poorly-formed memories and may offer a framework for science to explore different therapeutic approaches to fear, memory and anxiety disorders. It may also have implications for accuracy of some witness testimony.

Senior author Professor Bryce Vissel, from the UTS Centre for Neuroscience & Regenerative Medicine, said his team used novel behavioural, molecular and computational techniques to investigate memories that have not been well-formed, and how the brain deals with them.

He explained, "For memories to be useful, they have to have been well-formed during an event - that is, they have to accurately reflect what actually happened.

"However, in the real world many memories are likely to be inaccurate - especially in situations where the experience was brief, sudden or highly emotional, as can often occur during trauma. Inaccurate memories can also occur when the memory is poorly encoded, potentially as a result of subtle differences in how each person processes memory or because of disease like Alzheimer's or dementia."

Lead author Dr Raphael Zinn said, "Our findings are exciting because they show that memory updating mechanisms that become activated after recall can refine and improve memories.

"Surprisingly, we found that the same process can, in some circumstances, lead to incorrect updating of the memory. We also identify one molecular mechanism, called reconsolidation, which could be mediating this process.

"This suggests we might be able to target such updating mechanisms therapeutically to treat memory and anxiety disorders where memory formation is poor."

The 6-year study shows that the same mechanism that updates poor memories can also severely distort them if it occurs in the wrong situation.

Professor Vissel said these findings could be useful for understanding memory fallibility in everyday life; fear and memory disorders, post-traumatic stress disorder (PTSD); and situations where accurate recall is critical, like witness testimony in courtrooms.

"While these findings come from studies in mice, this research is likely to apply across many animals with developed brains, including other mammals and humans. They might also tie in with dementias, where the main memory-related problem is an apparent inability to form accurate new memories.

"Why is memory fallible? Our study suggests that when an individual forms a poor memory, the brain reactivates the memory in a similar situation and then updates it. Sometimes a poorly formed memory can be wrongly reactivated in a similar, but irrelevant, situation. The brain may then update the memory from that irrelevant situation, causing the memory to become incorrect - rather than creating a new and entirely different memory of the new situation."

Reference: Zinn, R., Leake, J., Krasne, F. B., Corbit, L. H., Fanselow, M. S., & Vissel, B. (2020). Maladaptive Properties of Context-Impoverished Memories. Current Biology, S0960982220305546.https://doi.org/10.1016/j.cub.2020.04.040

This article has been republished from the followingmaterials. Note: material may have been edited for length and content. For further information, please contact the cited source.

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The Brain Can "Update" Memories With Incorrect Information - Technology Networks

Neuroscience

Neurobiologist Finds Potent Pain-Suppression Center in the Brain – Duke Today

A Duke University research team has found a small area of the brain in mice that can profoundly control the animals sense of pain.

Somewhat unexpectedly, this brain center turns pain off, not on. Its also located in an area where few people would have thought to look for an anti-pain center, the amygdala, which is often considered the home of negative emotions and responses, like the fight or flight response and general anxiety.

People do believe there is a central place to relieve pain, thats why placebos work, said senior author Fan Wang, the Morris N. Broad Distinguished Professor of neurobiology in the School of Medicine. The question is where in the brain is the center that can turn off pain.

Most of the previous studies have focused on which regions are turned ON by pain, Wang said. But there are so many regions processing pain, youd have to turn them all off to stop pain. Whereas this one center can turn off the pain by itself.

The work is a follow-up to earlier research in Wangs lab looking at neurons that are activated, rather than suppressed, by general anesthetics. In a 2019 study, they found that general anesthesia promotes slow-wave sleep by activating the supraoptic nucleus of the brain. But sleep and pain are separate, an important clue that led to the new finding, which appears online May 18 in Nature Neuroscience.

The researchers found that general anesthesia also activates a specific subset of inhibitory neurons in the central amygdala, which they have called the CeAga neurons (CeA stands for central amygdala; ga indicates activation by general anesthesia). Mice have a relatively larger central amygdala than humans, but Wang said she had no reason to think we have a different system for controlling pain.

Using technologies that Wangs lab has pioneered to track the paths of activated neurons in mice, the team found the CeAga was connected to many different areas of the brain, which was a surprise, Wang said.

By giving mice a mild pain stimulus, the researchers could map all of the pain-activated brain regions. They discovered that at least 16 brain centers known to process the sensory or emotional aspects of pain were receiving inhibitory input from the CeAga.

Pain is a complicated brain response, Wang said. It involves sensory discrimination, emotion, and autonomic (involuntary nervous system) responses. Treating pain by dampening all of these brain processes in many areas is very difficult to achieve. But activating a key node that naturally sends inhibitory signals to these pain-processing regions would be more robust.

Using a technology called optogenetics, which uses light to activate a small population of cells in the brain, the researchers found they could turn off the self-caring behaviors a mouse exhibits when it feels uncomfortable by activating the CeAga neurons. Paw-licking or face-wiping behaviors were completely abolished the moment the light was switched on to activate the anti-pain center.

Its so drastic, Wang said. They just instantaneously stop licking and rubbing.

When the scientists dampened the activity of these CeAga neurons, the mice responded as if a temporary insult had become intense or painful again. They also found that low-dose ketamine, an anesthetic drug that allows sensation but blocks pain, activated the CeAga center and wouldnt work without it.

Now the researchers are going to look for drugs that can activate only these cells to suppress pain as potential future pain killers, Wang said.

The other thing were trying to do is to (transcriptome) sequence the hell out of these cells, she said. The researchers are hoping to find the gene for a rare or unique cell surface receptor among these specialized cells that would enable a very specific drug to activate these neurons and relieve pain.

This research was supported by the National Institutes of Health (DP1MH103908, R01 DE029342, R01 NS109947, R01 DE027454), the Holland-Trice Scholar Award, the W.M. Keck Foundation, and a predoctoral fellowship from the National Science Foundation.

CITATION: General Anesthetics Activate a Potent Central Pain-Suppression Circuit in The Amygdala, Thuy Hua, Bin Chen, Dongye Lu, Katsuyasu Sakurai, Shengli Zhao, Bao-Xia Han, Jiwoo Kim, Luping Yin, Yong Chen, Jinghao Lu, Fan Wang. Nature Neuroscience, May 18, 2020. DOI: 10.1038/s41593-020-0632-8

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Neurobiologist Finds Potent Pain-Suppression Center in the Brain - Duke Today

Neuroscience

Study Reveals Link between Diversity in Daily Experiences and Sense of Well-Being | Neuroscience, Psychology – Sci-News.com

New and diverse daily experiences are linked to enhanced happiness, according to a study published in the journal Nature Neuroscience.

Heller et al reveal a previously unknown connection between our daily physical environments and sense of well-being. Image credit: Frank MoreLight.

Our results suggest that people feel happier when they have more variety in their daily routines: when they go to novel places and have a wider array of experiences, said New York Universitys Dr. Catherine Hartley, lead co-author of the study.

The opposite is also likely true: positive feelings may drive people to seek out these rewarding experiences more frequently.

In the study, Dr. Hartley and colleagues investigated the following question: is diversity in humans daily experiences associated with more positive emotional states?

To do so, the researchers conducted GPS tracking of participants in New York and Miami for three to four months, asking subjects by text message to report about their positive and negative emotional state during this period.

The results showed that on days when people had more variability in their physical location visiting more locations in a day and spending proportionately equitable time across these locations they reported feeling more positive: happy, excited, strong, relaxed, and/or attentive.

The scientists then sought to determine if this link between exploration and positive emotion had a connection to brain activity.

To do this, about half of the subjects returned to a laboratory and underwent MRI scans.

The MRI results showed that people for whom this effect was the strongest those whose exposure to diverse experiences was more strongly associated with positive feeling (affect) exhibited greater correlation between brain activity in the hippocampus and the striatum.

These are brain regions that are associated, respectively, with the processing of novelty and reward beneficial or subjectively positive experiences.

These results suggest a reciprocal link between the novel and diverse experiences we have during our daily exploration of our physical environments and our subjective sense of well-being, Dr. Hartley said.

Collectively, these findings show the beneficial consequences of environmental enrichment across species, demonstrating a connection between real-world exposure to fresh and varied experiences and increases in positive emotions, said lead co-author Dr. Aaron Heller, a researcher at the University of Miami.

_____

A.S. Heller et al. Association between real-world experiential diversity and positive affect relates to hippocampal-striatal functional connectivity. Nat Neurosci, published online May 18, 2020; doi: 10.1038/s41593-020-0636-4

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Study Reveals Link between Diversity in Daily Experiences and Sense of Well-Being | Neuroscience, Psychology - Sci-News.com

Neuroscience

ProMIS Neurosciences and BC Neuroimmunology expand collaboration to develop and commercialize proprietary diagnostic assays – GlobeNewswire

TORONTO and CAMBRIDGE, Mass., May 19, 2020 (GLOBE NEWSWIRE) -- ProMIS Neurosciences, Inc. (TSX: PMN) (OTCQB: ARFXF), a company with unique, core technology to predict novel targets on the molecular surface of complex proteins, announced today that, in addition to its ongoing program to develop a high-throughput and accurate test for detection of antibodies to the causative agent of COVID-19, it has expanded its collaboration with BC Neuroimmunology (BCNI) to include development of highly sensitive and specific assays to support accurate screening and diagnosis of Alzheimers disease (AD).

Both BCNI and ProMIS Neurosciences have years of experience utilizing surface plasmon resonance (SPR) technology, and believe that recent, significant advances in throughput and stability are likely to make SPR a broadly used and cost-effective diagnostic platform. SPR is expected to offer greater accuracy, flexibility and adaptability compared to ELISA (enzyme-linked immunosorbent assay), the prevailing standard.

The current COVID-19 pandemic has created a need for the rapid expansion of accurate serology testing for the presence of antibodies to the virus causing COVID-19. It is widely acknowledged that such a test for COVID-19 immunity is essential to understanding patterns of immunity in the community and supporting an effective surveillance program. As recently announced, the collaboration between ProMIS and BCNI is making significant progress towards the development of an SPR-based antibody assay, aiming to achieve 100% sensitivity and 99.9% specificity for the virus causing COVID-19.

The expanded collaboration between BCNI and ProMIS is designed to address the anticipated launches of disease-modifying treatments in the Alzheimers/dementia area, which will necessitate the broad availability of appropriate and accurate diagnostic assays. SPR will be used in this context to develop sensitive blood-based AD diagnostic tests quickly and cost-effectively.

Dr. Hans Frykman, Chief Executive Officer of BCNI and a globally recognized neuro-immunologist stated: We firmly believe that SPR will displace tests based on ELISA, a decades-old technology, due to its superior accuracy and flexibility. At BCNI, we are developing high-throughput SPR tests in conjunction with ProMIS whose unique peptide antigens are anticipated to be a critical component for development and commercialization of top-quality assays targeting infectious disease, such as COVID-19, and neurodegenerative disease, such as Alzheimers.

Commenting on the expanded collaboration with BCNI, Eugene Williams, ProMIS executive chairman, stated: It has been very clear to us since the launch of ProMIS that diagnostics represent an important application of our unique technology platform. We have announced significant progress on development of an SPR-based antibody test for COVID-19 and believe high quality assays in this space are necessary to help safely get the economy back on track. In the field of neuroscience, the anticipated launch of aducanumab and BAN2401 for treatment of Alzheimers disease will create a dramatic increase in demand for dementia screening and diagnostics. We intend to help address this very important unmet need by capitalizing on our existing portfolio of antibodies and antigens and applying these existing assets to BCNIs outstanding expertise in the development of high performance diagnostic tests.

About ProMIS Neurosciences

ProMIS Neurosciences, Inc. is a development stage biotechnology company whose unique core technology is the ability to rationally predict the site and shape (conformation) of novel targets known as Disease Specific Epitopes on the molecular surface of proteins. In the infectious disease setting, these disease-specific epitopes represent peptide antigens that can be used as an essential component to create accurate and sensitive serological assays to detect the presence of antibodies that arise in response to a specific infection, such as COVID-19. These peptide antigens can also be used to create potential therapeutic antibodies to treat active infection, as well as serve as the basis for development of vaccines. ProMIS is headquartered in Toronto, Ontario, with offices in Cambridge, Massachusetts. ProMIS is listed on the Toronto Stock Exchange under the symbol PMN, and on the OTCQB Venture Market under the symbol ARFXF.

Visit us at http://www.promisneurosciences.com or follow us onTwitter and LinkedIn. To learn more about COVID-19 antibody testing, listen at ProMIS Neurosciences website.

For media inquiries, please contact:Shanti Skiffingtonshanti.skiffington@gmail.comTel. 617 921-0808

For Investor Relations please contact:Alpine Equity AdvisorsNicholas Rigopulos, Presidentnick@alpineequityadv.comTel. 617 901-0785

The TSX has not reviewed and does not accept responsibility for the adequacy or accuracy of this release. This information release contains certain forward-looking information. Such information involves known and unknown risks, uncertainties and other factors that may cause actual results, performance or achievements to be materially different from those implied by statements herein, and therefore these statements should not be read as guarantees of future performance or results. All forward-looking statements are based on the Company's current beliefs as well as assumptions made by and information currently available to it as well as other factors. Readers are cautioned not to place undue reliance on these forward-looking statements, which speak only as of the date of this press release. Due to risks and uncertainties, including the risks and uncertainties identified by the Company in its public securities filings, actual events may differ materially from current expectations. The Company disclaims any intention or obligation to update or revise any forward-looking statements, whether as a result of new information, future events or otherwise.

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ProMIS Neurosciences and BC Neuroimmunology expand collaboration to develop and commercialize proprietary diagnostic assays - GlobeNewswire

Neuroscience

Neuroscience Market Necessity And Demand 2020 to 2026 – Galus Australis

The global Neuroscience Market research report thoroughly explains each and every aspect related to the Neuroscience Market, which facilitates the reports reader to study and evaluate the upcoming market trend and execute the analytical data to promote the business. The growth trend forecasted on account of thorough examination offers in-depth information regarding the global Neuroscience Market. A pathway of development is offered by the market to the several connected networks of businesses under it, which include different firms, industries, organizations, vendors, distributors, and local manufacturers too. All the key Neuroscience Market players compete with each other by offering better products and services at a reasonable price in order to grab significant share at the regional and global level market.

Get Summary Of this Report : https://www.coherentmarketinsights.com/market-insight/neuroscience-market-2487

The report includes the latest coverage of the impact of COVID-19 on the Neuroscience Market. The incidence has affected nearly every aspect of the business domain. This study evaluates the current scenario and predicts future outcomes of the pandemic on the global economy.

The report incorporates an estimated impact of strict standards and regulations set by the government over the market in the upcoming years. The market report also comprises exhaustive research done using several analytical tools such as SWOT analysis to identify the market growth pattern.

Major Players Are:Alpha Omega, Inc., GE Healthcare, Axion Biosystems, Inc., Siemens Healthineers, Blackrock Microsystems LLC, Femtonics Ltd., Intan Technologies, LaVision Biotec GmbH, Mediso Medical Imaging Systems, Neuralynx Inc., NeuroNexus Technologies, Inc., Newport Corporation, Plexon Inc., Noldus Information Technology, Scientifica Ltd., Sutter Instrument Corporation, Thomas Recording GmbH, and Trifoil Imaging Inc.

Regions & Countries Mentioned In The Neuroscience Market Report:

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Various analytical tools such as SWOT, Feasibility analysis, Porters Five Forces analysis, Value Chain analysis, and Capacity utilization analysis are implemented while evaluating the Neuroscience Market which certainly helps a reader to get a deeper perception of the market and its participants. Additionally, it covers a cardinal evaluation of market history, patterns, changing dynamics, market and manufacturing trends, demand and supply activities, and technological development.

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Neuroscience Market Necessity And Demand 2020 to 2026 - Galus Australis

Neuroscience

Student Research Awards Named by Center for Research on Families – UMass News and Media Relations

The Center for Research on Families (CRF) has announced the recipients of this year's Student Research Awards.

CRF is committed to supporting students engaged in family research, with student researchers addressing family challenges such as malnutrition in older adults, womens health in remote regions of the world, health effects of breastfeeding, socioemotional development of the multiracial children, how brain structures affect memory and how young childrens ability to understand language influences brain development.

The awards program recognizes outstanding student research on issues related to families.

Dissertation Award Recipients:

Bi-sek Hsaiao, School of Public Health and Health Sciences, nutrition

Sarah McCormick, College of Natural Sciences, psychological and brain science

Merika Sanders, College of Natural Sciences, psychological and brain science

Methodology Scholarship Recipient:

Christina Rowley, College of Natural Sciences, clinical psychology

Travel Award Recipients:

Youngjoon Bae, College of Social and Behavioral Sciences, sociology

Melise Edwards, College of Natural Sciences, neuroscience and behavior

Olivia Laramie, School of Behavioral Sciences, public policy

Learn more about the awardees and their researchhere.

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Student Research Awards Named by Center for Research on Families - UMass News and Media Relations

Neuroscience

What near-death experiences can tell scientists about how the brain works – Boing Boing

Floating out of your body and looking down on it. The story of your life flashing by before your eyes. Seeing a bright light at the end of a dark tunnel. These are just two of the most common experiences that people report after a near-death experience (NDE). For some people, NDEs are a transformative spiritual or mystical experience. But what's the source of the phenomena? That's a question that fascinates Dr. Christof Koch is president and chief scientist of the Allen Institute for Brain Science who studies the neuroscience of consciousness. In Scientific American, Koch surveys the science of near-death experiences and what they can tell us about how our brains work under extreme duress. From Scientific American:

Modern death requires irreversible loss of brain function. When the brain is starved of blood flow (ischemia) and oxygen (anoxia), the patient faints in a fraction of a minute and his or her electroencephalogram, or EEG, becomes isoelectricin other words, flat. This implies that large-scale, spatially distributed electrical activity within the cortex, the outermost layer of the brain, has broken down. Like a town that loses power one neighborhood at a time, local regions of the brain go offline one after another. The mind, whose substrate is whichever neurons remain capable of generating electrical activity, does what it always does: it tells a story shaped by the persons experience, memory and cultural expectations.

Given these power outages, this experience may produce the rather strange and idiosyncratic stories that make up the corpus of NDE reports. To the person undergoing it, the NDE is as real as anything the mind produces during normal waking. When the entire brain has shut down because of complete power loss, the mind is extinguished, along with consciousness. If and when oxygen and blood flow are restored, the brain boots up, and the narrative flow of experience resumes.[...]

Why the mind should experience the struggle to sustain its operations in the face of loss of blood flow and oxygen as positive and blissful rather than as panic-inducing remains mysterious. It is intriguing, though, that the outer limit of the spectrum of human experience encompasses other occasions in which reduced oxygen causes pleasurable feelings of jauntiness, light-headedness and heightened arousaldeepwater diving, high-altitude climbing, flying, the choking or fainting game, and sexual asphyxiation.

"What Near-Death Experiences Reveal about the Brain" (SciAm)

image: detail of "Ascent of the Blessed" by Hieronymus Bosch

Repeating the word fuck actually can reduce your experience of pain, according to a new study by Keele University researchers. The psychologists ran an experiment in which subjects underwent a cold pressor test, a common method to pain threshold and tolerance by immersing your hand in freezing cold water for a minute. (See above video []

I enjoy the fun science stunts on ScienceBobs YouTube Channel.

The Lancet says Trumps letter contains factually incorrect details.

Weve all been cooped up in the house for way too long. Even though were all trying to be more health-conscious these days, the confinement is likely doing a number on both the physical and psychological health of millions. Young or old, male or female, its time for many to take some proactive steps toward []

At some point in the future, global communications networks will likely reach one standardized protocol that everyone uses. If you look back over the past few decades, theres a decent chance that when the story of digital networking is finally settled once and for all, its Cisco and Cisco-based systems that the globe will be []

Weve all grown accustomed to the new world order. And until we can go out and experience the world again like we used to, well settle for the next best thing: bringing the world to our door. And if ever there was a time for wine (and lots of it), its now. So even if []

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What near-death experiences can tell scientists about how the brain works - Boing Boing

Neuroscience

UTeach Dallas Students Show They are Class Acts, Secure K-12 Jobs – University of Texas at Dallas

When the COVID-19 pandemic closed K-12 schools in North Texas, three University of Texas at Dallas seniors in the UTeach Dallas program took the initiative to help their mentor teachers in area school districts transition to online learning. Now each has been hired at the same school where they performed their student teaching.

Tommy Fabyan

Tommy Fabyan, who earned a bachelors degree in interdisciplinary studies and a mathematics certificate, will teach math at Trent Middle School in the Frisco Independent School District. Neuroscience senior Aaly Hussain has landed a job teaching science at Skyline High School in Dallas ISD, while David Le, who graduated with a Bachelor of Science degree in biology, will be a science teacher at North Garland High School in Garland ISD.

Students in the UTeach Dallas program earn undergraduate degrees, primarily in STEM fields science, technology, engineering and math concurrently with teacher training and certification.The program is housed in the Department of Science/Mathematics Education in the School of Natural Sciences and Mathematics.

Fabyan, Hussain and Le are among the 26 UTeach Dallas students who have graduated or will graduate this year by August. Four more students have been hired as teachers at Dallas, Houston and Amarillo schools. Two more have completed the Master of Arts in Teaching program and will go on to share their expertise with area students.

UTeach Dallas is the gift that keeps giving to the University, because our graduates are teaching STEM subjects to younger students in the area, many of whom will go on to enroll at UTDallas. Its a long-term investment that pays off.

Katie Donaldson, assistant director of UTeach Dallas

Many UTeach Dallas graduates receive multiple job offers because of their subject expertise and experience in the classroom, said Katie Donaldson, assistant director of UTeach Dallas and master teacher.

Were getting calls daily from employers. Our students have a deep, rich content knowledge coming in to professional teaching. We put them in schools their first semester, helping teachers with fourth- or fifth-grade science or math. Before they ever start their student teaching, they have had 18 to 20 hours in the classroom, Donaldson said.

All of them were student teaching when COVID-19 hit, she added. We told them to jump in and help their teachers wherever they could.

Fabyan had several challenges as he was completing his student teaching. His close-knit family had come to the U.S. from Ghana when he was 13. When his mother also a teacher had to undergo medical treatment last fall, Fabyan dropped out of student teaching to help care for her. After she stabilized, he returned to teaching this spring.

As the COVID-19 pandemic prompted teachers to transition completely to online learning for middle school math classes, Fabyan took charge of digital instruction for kids who did not respond particularly well to lectures. He set up Zoom tutorial sessions, videos and math games to target the areas where students needed help.

To get them even an inch closer to the aha! moment was amazing, Fabyan said.

He credited his mentor teacher for helping him overcome obstacles and even land a job at the school.

Being able to finally cross that finish line in my student teaching was really great. My mentor teacher has been my biggest cheerleader from the day I met her. She told me to invite the principal to watch me teach, so when it came to hiring someone, they already knew what I was capable of in the classroom, Fabyan said.

Aaly Hussain

At Skyline High School, Hussain was able to combine her love of the sciences and teaching, working with two different mentors to teach anatomy, physiology and pre-Advanced Placement chemistry. She decided to pursue teaching after working as a tutor in high school, where students told her she explained things nicely.

By the time COVID-19 hit, Hussain had already been using the online platform Google Classroom to upload assignments and videos that allowed students to do their projects online and receive feedback quickly.

It was perfect, Hussain said of the transition to online learning. I think its easier for my generation because we grew up with it. I had a good exchange with my mentors and set up Google pages for classes and internships.

Hussain, who is also a pre-med student, hopes to go to medical school and become a faculty member after gaining more teaching experience. The teaching aspect of it is what intrigues me, Hussain said.

David Le

Le, who will teach either chemistry or physics at North Garland High School this fall, also helped his mentors quickly formulate plans for online learning using interactive platforms to upload PowerPoint presentations, worksheets and videos with questions for students to answer.

When he learned he was going to be hired at the school, Le was thrilled and a little surprised. I slapped myself to see if I was awake, he said.

A first-generation college student, Le credited UTeach Dallas for stimulating his interest in STEM education. Being placed in a classroom early in his college career helped him realize that he enjoyed class preparation and interacting with students.

After being in the classroom, I was in love. UTeach pushed me when I needed it most. The energy and passion of the master teachers was out of this world. It was contagious, Le said.

Since 2008, UTeach Dallas has graduated almost 200 students with science or mathematics certification. All faculty instructors are award-winning master teachers with years of expertise.

UTeach Dallas is the gift that keeps giving to the University, because our graduates are teaching STEM subjects to younger students in the area, many of whom will go on to enroll at UTDallas. Its a long-term investment that pays off, Donaldson said.

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UTeach Dallas Students Show They are Class Acts, Secure K-12 Jobs - University of Texas at Dallas

Cell Biology

DNA May Not Be the Blueprint for Life Just a Scrambled List of Ingredients – SciTechDaily

DNA may not be lifes instruction book, but just a jumbled list of ingredients.

University of Maryland researcher develops potentially revolutionary framework for heredity and evolution in which inheritable information is stored outside the genome.

The common view of heredity is that all information passed down from one generation to the next is stored in an organisms DNA. But Antony Jose, associate professor of cell biology and molecular genetics at the University of Maryland, disagrees.

In two new papers, Jose argues that DNA is just the ingredient list, not the set of instructions used to build and maintain a living organism. The instructions, he says, are much more complicated, and theyre stored in the molecules that regulate a cells DNA and other functioning systems.

Jose outlined a new theoretical framework for heredity, which was developed through 20 years of research on genetics and epigenetics, in peer-reviewed papers in the Journal of the Royal Society Interface and the journal BioEssays. Both papers were published on April 22, 2020.

Joses argument suggests that scientists may be overlooking important avenues for studying and treating hereditary diseases, and current beliefs about evolution may be overly focused on the role of the genome, which contains all of an organisms DNA.

DNA cannot be seen as the blueprint for life, Jose said. It is at best an overlapping and potentially scrambled list of ingredients that is used differently by different cells at different times.

For example, the gene for eye color exists in every cell of the body, but the process that produces the protein for eye color only occurs during a specific stage of development and only in the cells that constitute the colored portion of the eyes. That information is not stored in the DNA.

In addition, scientists are unable to determine the complex shape of an organ such as an eye, or that a creature will have eyes at all, by reading the creatures DNA. These fundamental aspects of anatomy are dictated by something outside of the DNA.

Jose argues that these aspects of development, which enable a fertilized egg to grow from a single cell into a complex organism, must be seen as an integral part of heredity. Joses new framework recasts heredity as a complex, networked information system in which all the regulatory molecules that help the cell to function can constitute a store of hereditary information.

Michael Levin, a professor of biology and director of the Tufts Center for Regenerative and Developmental Biology and the Allen Discovery Center at Tufts University, believes Joses approach could help answer many questions not addressed by the current genome-centric view of biology. Levin was not involved with either of the published papers.

Understanding the transmission, storage and encoding of biological information is a critical goal, not only for basic science but also for transformative advances in regenerative medicine, Levin said. In these two papers, Antony Jose masterfully applies a computer science approach to provide an overview and a quantitative analysis of possible molecular dynamics that could serve as a medium for heritable information.

Jose proposes that instructions not coded in the DNA are contained in the arrangement of the molecules within cells and their interactions with one another. This arrangement of molecules is preserved and passed down from one generation to the next.

In his papers, Joses framework recasts inheritance as the combined effects of three components: entities, sensors and properties.

Entities include the genome and all the other molecules within a cell that are needed to build an organism. Entities can change over time, but they are recreated with their original structure, arrangement and interactions at the start of each generation.

That aspect of heredity, that the arrangement of molecules is similar across generations, is deeply underappreciated, and it leads to all sorts of misunderstandings of how heredity works, Jose said.

Sensors are specific entities that interact with and respond to other entities or to their environment. Sensors respond to certain properties, such as the arrangement of a molecule, its concentration in the cell or its proximity to another molecule.

Together, entities, sensors and properties enable a living organism to sense or know things about itself and its environment. Some of this knowledge is used along with the genome in every generation to build an organism.

This framework is built on years of experimental research in many labs, including ours, on epigenetics and multi-generational gene silencing combined with our growing interest in theoretical biology, Jose said. Given how two people who contract the same disease do not necessarily show the same symptoms, we really need to understand all the places where two people can be differentnot just their genomes.

The folly of maintaining a genome-centric view of heredity, according to Jose, is that scientists may be missing opportunities to combat heritable diseases and to understand the secrets of evolution.

In medicine, for instance, research into why hereditary diseases affect individuals differently focuses on genetic differences and on chemical or physical differences in entities. But this new framework suggests researchers should be looking for non-genetic differences in the cells of individuals with hereditary diseases, such as the arrangement of molecules and their interactions. Scientists dont currently have methods to measure some of these things, so this work points to potentially important new avenues for research.

In evolution, Joses framework suggests that organisms could evolve through changes in the arrangement of molecules without changes in their DNA sequence. And in conservation science, this work suggests that attempts to preserve endangered species through DNA banks alone are missing critical information stored in non-DNA molecules.

Jose acknowledged that there will be much debate about these ideas, and experiments are needed to test his hypotheses. But, he said, preliminary feedback from scientists like Levin and other colleagues has been positive.

Antony Joses generalization of memory and encoding via the entity-sensor-property framework sheds novel insights into evolution and biological complexity and suggests important revisions to existing paradigms in genetics, epigenetics and development, Levin said.

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References:

A framework for parsing heritable information by Antony M. Jose, 22 April 2020, Journal of the Royal Society Interface.DOI: 10.1098/rsif.2020.0154

Heritable Epigenetic Changes Alter Transgenerational Waveforms Maintained by Cycling Stores of Information by Antony M. Jose, 22 April 2020, BioEssays.DOI: 10.1002/bies.201900254

Research in Antony Joses laboratory is supported by the National Institutes of Health (Award Nos. R01GM111457 and R01GM124356). The content of this article does not necessarily reflect the view of this organization.

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