Pardes Biosciences to suspend COVID-19 drug development after mid-stage trial fails

 Pardes Biosciences Inc said on Monday it will suspend further clinical development of its experimental antiviral treatment pomotrelvir, after the drug failed a mid-stage trial for treating COVID-19, and will explore strategic alternatives which may include a sale of the company.

The drug was being studied as a potential treatment of patients with mild-to-moderate COVID, but it could not achieve below-the-limit detection for infectious SARS-CoV-2 on day three when compared to a placebo a proportion of participants, according to the company.

Based on the study results, the company said it initiated a review of a range of strategic alternatives that may include an acquisition or merger, among others.

https://news.yahoo.com/pardes-biosciences-suspend-covid-19-121808628.html

Mars to Acquire Heska, Global Provider of Advanced Veterinary Diagnostic and Specialty Solutions

 Mars, Incorporated ("Mars"), and Heska Corporation (NASDAQ: HSKA) ("Heska") today announced that they have entered into a definitive agreement under which Mars will acquire Heska, a global provider of advanced veterinary diagnostic and specialty products for $120.00 per share. The transaction price represents a premium of approximately 38% over Heska's 60-calendar day volume weighted average price and a premium of approximately 23% over Heska's closing stock price as of March 31, 2023. The agreement has been unanimously approved by the boards of directors of both companies. Upon transaction close, Heska will join Mars Petcare, a purpose-driven global business serving pets and pet owners through products and services within veterinary health and diagnostics, nutrition, innovation, and technology. This acquisition will enable the Science & Diagnostics division of Mars Petcare to expand its diagnostic offerings and broadly promote point-of-care veterinary diagnostics to the global pet healthcare community.

https://stockhouse.com/news/press-releases/2023/04/03/mars-to-acquire-heska-global-provider-of-advanced-veterinary-diagnostic-and

Is it COVID-19 or the flu? New sensor could tell you in 10 seconds

 Have a cough, sore throat and congestion? Any number of respiratory viruses could be responsible. Conventional tests can identify certain likely culprits by relying on chemical reactions, but some researchers want to swap chemistry for electrical changes sensed by nanomaterials. Today, scientists report using a single-atom-thick nanomaterial to build a device that can simultaneously detect the presence of the viruses that cause COVID-19 and the flu -- at much lower levels and much more quickly than conventional tests for either.

The researchers will present their results at the spring meeting of the American Chemical Society (ACS). ACS Spring 2023 is a hybrid meeting being held virtually and in-person March 26-30, and features more than 10,000 presentations on a wide range of science topics.

The symptoms of both flu and COVID-19 overlap considerably, making it difficult to distinguish between them, notes Deji Akinwande, Ph.D., who is presenting the work at the meeting.

"When both of these viruses are circulating together as they did earlier this winter, it would be immensely useful to have a sensor that can simultaneously detect whether you have COVID, flu, none of the above or both," he says.

Akinwande, who is at The University of Texas at Austin, says that the device he and colleagues are developing could be modified to test for other infections as well.

The group, including Dmitry Kireev, Ph.D., a postdoc in Akinwande's lab, constructed the COVID-19 and flu sensor using graphene, a single layer of carbon atoms arranged in a hexagonal lattice pattern. Its extreme thinness renders graphene highly sensitive to any electrical changes in its environment. Akinwande and other researchers see enormous potential in using it and other, similar nanomaterials to create sensors for many different applications.

"These ultra-thin nanomaterials generally hold the record for best sensitivity, even down to the detection of single atoms, and they can improve the ability to detect very small quantities of basically anything that needs to be sensed, whether it's bacteria or viruses, in gas or in blood," Akinwande says.

Previously, his group reported designing a graphene-based temporary tattoo that could monitor blood pressure. The tattoo consists of pairs of sensors placed along the arteries of the arm. One half of each pair sends out an electrical current that its partner detects. This signal is used to determine blood flow.

To build the infection sensor, the researchers had to make graphene respond to the presence of viral protein. To do so, they looked to the immune system, which produces antibodies that are fine-tuned to recognize and latch onto particular pathogens. The researchers linked antibodies against SARS-CoV-2, the virus that causes COVID-19, and against the flu virus to graphene. When a sample from an infected person is placed on the sensor, these antibodies bind to their target proteins, prompting a change in the electrical current.

The researchers did not have the safety facilities needed to use whole, active flu or SARS-CoV-2 viruses to test the roughly square-inch sensor. To substitute, they used proteins from these viruses delivered in fluid intended to resemble saliva. Their results indicated that not only could the sensor detect the presence of the proteins, it could do so when they were present at extremely low quantities. This sensitivity suggested the sensor could be used for detecting the much more sparse viral particles found in breath, Akinwande says.

The sensor also worked quickly, returning results within about 10 seconds of dropping in a sample, he says. By comparison, conventional COVID-19 tests can take minutes or hours, depending on the type, and a dual COVID and flu test recently authorized by the U.S. Food and Drug Administration takes about half an hour to produce results.

Akinwande and his group are working to improve its performance further, including by expanding the slate of viruses it can detect. With funding from the National Science Foundation, they are developing a sensor designed to test for SARS-CoV-2 variants, such as omicron and delta. While they are currently focusing on a two-variant design, the test could be adapted to simultaneously identify even more, they say.

The researchers acknowledge support and funding from the National Science Foundation.

https://www.sciencedaily.com/releases/2023/03/230328145528.htm

Tighter core stabilizes SARS-CoV-2 spike protein in new emergent variants

 Just as a tight core is a component of good physical fitness for humans, helping to stabilize our bodies, mutations that tightened the core of the SARS-CoV-2 spike protein in new variants may have increased the virus's fitness.

New research led by Penn State reveals that the stem region of the spike protein became progressively tighter over time, and the team thinks this likely improved the virus's ability to transmit through nasal droplets and infect host cells once in the body. The team said the stem region of the protein that emerged in the most recent Omicron variants is as rigid as it can get, which could mean that newer vaccines may be effective for longer than the ones that targeted the original variant.

"We wanted to see how the spike protein morphed structurally as it evolved from the original wild-type strain of the virus, through the alpha, delta and most recently Omicron variants," said Ganesh Anand, associate professor of chemistry and of biochemistry and molecular biology, Penn State. "We found that the spike protein was initially more flexible at the stem region, which is where the spike protein is bundled together, but over time, mutations caused the protein to become progressively tighter and more rigid, and we think it's now as rigid as it can get. This is important because it means that vaccines that are developed to target the current variant with these rigid spike proteins are likely to be effective for much longer than previous vaccines against the more flexible wild-type strain."

To study how the spike protein changed with each of the new variants, the team studied the virus in vitro (in a test tube) using a technique called amide hydrogen/deuterium exchange mass spectrometry.

Anand explained that the SARS-CoV-2 spike protein is composed of three chain molecules called monomers that are bound together to form a trimer. The spike protein is made up of two subunits, an S1 and S2 subunit. The S1 subunit contains a receptor binding domain while the S2 subunit contains the stem region responsible for bundling the trimer.

"It is analogous to a tree, with the stem forming the trunk and the receptor binding domain forming the branches," said Anand.

The team's results, which published in the journal eLife, revealed that the spike protein stem first became more rigid with the D614G mutation, which is common to all SARS-CoV-2 variants. The stem became progressively more twisted with the emergence of new mutations in subsequent variants, and the Omicron BA.1 variant showed the largest magnitude increase in stabilization relative to preceding variants.

Why would the virus benefit from a tighter core?

"We did not study the virus in patients, so we cannot determine if the changes we observed in the spike protein directly affected the newer variants such as Omicron's ability to transmit more readily; however, we can say that the changes likely made the virus more fit, which could translate to better transmission," said Anand. "A tighter core could likely make the virus more stable in nasal droplets and faster at binding to and entering host cells. So, for example, what initially took about 11 days to develop an infection after exposure now takes only about four days."

Anand noted that one of the reasons the vaccines have not been able to fully neutralize the virus is because they were generated against the spike protein of the original wild-type variant.

"The latest bivalent booster -- which targets newer variants -- helps, but people who never got this booster aren't receiving this more targeted protection," he said. "Future vaccines that focus specifically on Omicron are likely to be effective for longer."

Finally, Anand said that the spike protein has now become so tightly twisted that it is unlikely to structurally change further at the stem region.

"There are limits to how much it can tighten," he said. "I think that we can have some cautious optimism, in that we're not going to continuously have variants emerging, at least tightening is not going to be a mechanism."

Other Penn State authors on the paper include chemistry graduate students Sean Braet, Theresa Buckley and Varun Venkatakrishnan. Kim-Marie Dam, postdoctoral research fellow, and Pamela Bjorkman, assistant professor of biology and biological engineering, Caltech, also are authors.

Journal Reference:

1. Varun Venkatakrishnan, Theresa SC Buckley, Sean M Braet, Kim-Marie A Dam, Pamela J Bjorkman, Ganesh S Anand. Timeline of changes in spike conformational dynamics in emergent SARS-CoV-2 variants reveal progressive stabilization of trimer stalk with altered NTD dynamics. eLife, 2023; 12 DOI: 10.7554/eLife.82584

https://www.sciencedaily.com/releases/2023/03/230331131453.htm

Candidate found to inhibit malignant melanoma growth

 Malignant melanoma is a relatively aggressive type of skin cancer. When detected early, it is usually treatable by surgical resection only, but metastases develop often spreading to distant areas. Currently, tumor thickness and the presence of ulceration are some of the known prognostic factors used as indicators of malignant melanoma. Therefore, the discovery of valuable markers to assess the malignant potential of melanoma more accurately may be necessary to develop appropriate treatments.

Cross talk between cancer cells and surrounding stromal cells is believed to orchestrate cancer progression through a variety of mechanisms. Cancer-associated fibroblasts (CAFs) -- key factors in the tumor microenvironment -- in particular have been implicated in cancer cell progression. It has also been reported that the exosomes, a type of small vesicles, produced by CAFs play an important role in cancer progression.

A research group led by Naho Fujii, M.D., and Professor Hisashi Motomura from Osaka Metropolitan University Graduate School of Medicine investigated the effect of CAF-derived exosomes on the growth of malignant melanoma cells. The group found that the transmembrane proteins CD9 and CD63 were mainly present on CAF-derived exosomes, and that among the exosomes, the CD9-positive ones inhibited the growth of malignant melanoma cells.

"As a plastic surgeon, usually I provide surgical treatment for skin cancer, but I have wanted to study other treatment methods for a long time," explained Fujii, M.D. "This study suggests that CD9-positive exosomes inhibit the growth of malignant melanoma, so CD9-positive exosomes may be a useful marker to evaluate the malignant grade of melanoma. We expect further research will lead to the development of new treatments in that line."

Journal Reference:

1. Naho Fujii, Masakazu Yashiro, Takaharu Hatano, Heishiro Fujikawa, Hisashi Motomura. CD9-positive Exosomes Derived from Cancer-associated Fibroblasts Might Inhibit the Proliferation of Malignant Melanoma Cells. Anticancer Research, 2022; 43 (1): 25 DOI: 10.21873/anticanres.16130

https://www.sciencedaily.com/releases/2023/03/230328145453.htm

Components of cytoskeleton strengthen effect of sex hormones

 Steroid hormones, to which belong sex hormones like estrogen or testosterone, are important signaling molecules and are responsible among other things for controlling female and male phenotypic sex differentiation. They act by binding to receptor molecules that switch on and off the activity of hormone-dependent genes. Researchers at the University of Freiburg and Kiel University Hospital have discovered that components of the cytoskeleton are critically involved in this process. The findings are relevant for the diagnosis of medical conditions and the study of diseases and cancers in which steroid hormones play important roles. The study was published in the journal Nature.

The new research findings show that filamentous actin, a component of the cytoskeleton, interacts with the androgen receptor directly in the cell nucleus and strengthens its effect. The androgen receptor mediates the signals of sex hormones for male sex development but also promotes the progression of prostate cancer.

A genetic modification as the key indicator

Scientists with different research foci from Freiburg, Kiel, and Lübeck collaborated on the study across disciplines. The project was led jointly by Prof. Dr. Robert Grosse and PD Dr. Nadine Hornig: Grosse conducts his research at the Cluster of Excellence CIBSS -- Centre for Integrative Biological Signalling Studies and the University of Freiburg's Faculty of Medicine, Hornig at University of Kiel´s Faculty of Medicine and the University Hospital Schleswig-Holstein, campus Kiel.

The researchers became aware of the previously unknown connection between actin and steroid hormones while studying the cells of patients with a so-called androgen insensitivity syndrome (AIS). People who live with AIS have a set of male XY chromosomes but have less pronounced male sexual characteristics, extending even to a completely female appearance. This is often due to a change in the androgen receptor, which means that male sex hormones can no longer take effect. However, the androgen receptor is frequently unchanged in patients with AIS.

"We want to find out what genetic modifications cause AIS in these patients," explains Hornig. "Thus, we wanted to identify further molecules that play a role in the development of sexual characteristics." For this purpose, the researchers used a screening method to examine the cells of patients with AIS. In the process, they discovered mutations in the DAAM2 gene in two patients: The molecule belongs to the group of formins and controls the dynamic polymerization and elongation of actin filaments. As a part of the cytoskeleton, actin is important for the stability and locomotion of cells but also serves regulatory functions.

High-resolution microscopy reveals the processes in the cell nucleus

The researchers used high-resolution 3D SIM microscopy to examine whether DAAM2 is indeed important for the effect of sex hormones. This is an elaborate technique that can be used to observe molecular movements within cells. The images show that DAAM2 and actin colocalize with the androgen receptor directly in the cell nucleus. Further experiments demonstrated that this colocalization is important for the control of gene activity.

"This is a completely unknown mode of action, which we succeeded in describing here for a very important receptor," says Grosse, highlighting the significance of the new findings. The research team assumes that the mechanism could be widespread and also influences the effect of other steroid hormones. "This could play a role in many physiological processes and diseases. It will be exciting to see whether it will enable new therapeutic approaches," explains Grosse.

Diagnosis possible for more patients with AIS

The discovery also provides a basis for further research on the development of sexual characteristics and enables a clear diagnosis for more patients with AIS: "Previously, patients with androgen insensitivity but without a modification in the androgen receptor did not receive a clear diagnosis despite having clear symptoms," says Hornig. "Now we can make a clear diagnosis for those in whom DAAM2 is altered."

Journal Reference:

1. Julian Knerr, Ralf Werner, Carsten Schwan, Hong Wang, Peter Gebhardt, Helga Grötsch, Almuth Caliebe, Malte Spielmann, Paul-Martin Holterhus, Robert Grosse, Nadine C. Hornig. Formin-mediated nuclear actin at androgen receptors promotes transcription. Nature, 2023; DOI: 10.1038/s41586-023-05981-1

https://www.sciencedaily.com/releases/2023/03/230328145522.htm

Obesity treatment could offer dramatic weight loss without surgery or nausea

 Imagine getting the benefits of gastric bypass surgery without going under the knife -- a new class of compounds could do just that. In lab animals, these potential treatments reduce weight dramatically and lower blood glucose. The injectable compounds also avoid the side effects of nausea and vomiting that are common with current weight-loss and diabetes drugs. Now, scientists report that the new treatment not only reduces eating but also boosts calorie burn.

The researchers will present their results today at the spring meeting of the American Chemical Society (ACS). 

"Obesity and diabetes were the pandemic before the COVID-19 pandemic," says Robert Doyle, Ph.D., one of the two principal investigators on the project, along with Christian Roth, M.D. "They are a massive problem, and they are projected to only get worse."

Gastric bypass and related procedures, known collectively as bariatric surgery, offer one solution, often resulting in lasting weight loss and even remission of diabetes. But these operations carry risk, aren't suitable for everyone and aren't accessible for many of the hundreds of millions of people worldwide who are obese or diabetic. As an alternative, Doyle says, they could tackle their metabolic problems with a drug that replicates the long-term benefits of surgery.

Those benefits are linked to a post-bypass-surgery change in the gut's secretion levels of certain hormones -- including glucagon-like peptide-1 (GLP-1) and peptide YY (PYY) -- that signal fullness, curb appetite and normalize blood sugar. Current drugs that aim to replicate this effect primarily activate cellular receptors for GLP-1 in the pancreas and brain. That approach has shown great success in reducing weight and treating type 2 diabetes, drawing a lot of social media postings from celebrities in recent months. But many people can't tolerate the drugs' side effects, says Doyle. "Within a year, 80 to 90% of people who start on these drugs are no longer taking them." Doyle is at Syracuse University and SUNY Upstate Medical University, and Roth is at Seattle Children's Research Institute.

To address that drawback, various researchers have designed other treatments that interact with more than one type of gut hormone receptor. For example, Doyle's group created a peptide that activates two receptors for PYY, as well as the receptor for GLP-1. Dubbed GEP44, this compound caused obese rats to eat up to 80% less than they would typically eat. By the end of one 16-day study, they lost an average of 12% of their weight. That was more than three times the amount lost by rats treated with liraglutide, an injected drug that activates only the GLP-1 receptor and that is approved by the U.S. Food and Drug Administration for treating obesity. In contrast to liraglutide, tests with GEP44 in rats and shrews (a mammal that, unlike rats, is capable of vomiting) revealed no sign of nausea or vomiting, possibly because activating multiple receptors may cancel out the intracellular signaling pathway that drives those symptoms, Doyle says.

In its latest results, his team is now reporting that the weight loss caused by GEP44 can be traced not only to decreased eating, but also to higher energy expenditure, which can take the form of increased movement, heart rate or body temperature.

GEP44 has a half-life in the body of only about an hour, but Doyle's group has just designed a peptide with a much longer half-life. That means it could be injected only once or twice a week instead of multiple times a day. The researchers are now reporting that rats treated with this next-generation compound keep their new, slimmer physique even after treatment ends, which often isn't the case with currently approved drugs, Doyle says.

But weight loss isn't the only benefit of the peptide treatments. They also reduce blood sugar by pulling glucose into muscle tissue, where it can be used as fuel, and by converting certain cells in the pancreas into insulin-producing cells, helping replace those that are damaged by diabetes. And there's yet another benefit: Doyle and Heath Schmidt, Ph.D., of the University of Pennsylvania, recently reported that GEP44 reduces the craving for opioids such as fentanyl in rats. If that also works in humans, Doyle says, it could help addicts quit the illicit drugs or fend off a relapse.

The researchers have filed for patents on their compounds, and they plan to test their peptides in primates. They will also study how the treatments change gene expression and rewire the brain, and what that could mean for these compounds, as well as other types of medication.

"For a long time, we didn't think you could separate weight reduction from nausea and vomiting, because they're linked to the exact same part of the brain," Doyle says. But the researchers have now uncoupled those two pathways -- and that has implications for chemotherapy, which causes similar side effects. "What if we could maintain the benefit of chemotherapy drugs but tell the part of the brain that causes vomiting and nausea to knock it off? Then we could dose patients at a higher level, so they would have a better prognosis, and they would also have a better quality of life while undergoing chemotherapy," he says.

https://www.sciencedaily.com/releases/2023/03/230329091942.htm