research roundup

These 3 Houston research projects are coming up with life-saving innovations

A Rice research team is tapping into materials science to better understand Alzheimer’s disease, a UH professor is developing a treatment for hereditary vision loss, and a BCM researcher is looking at stress and brain cancer. Photo by Gustavo Raskosky/Rice University

Research, perhaps now more than ever, is crucial to expanding and growing innovation in Houston — and it's happening across the city right under our noses.

In InnovationMap's latest roundup of research news, three Houston institutions are working on life-saving health care research thanks to new technologies.

Rice University scientists' groundbreaking alzheimer's study

Angel Martí (right) and his co-authors (from left) Utana Umezaki and Zhi Mei Sonia He have published their latest findings on Alzheimer’s disease. Photo by Gustavo Raskosky/Rice University

According to the Centers for Disease Control and Prevention, Alzheimer’s disease will affect nearly 14 million people in the U.S. by 2060. A group of scientists from Rice University are looking into a peptide associated with the disease, and their study was published in Chemical Science.

Angel Martí — a professor of chemistry, bioengineering, and materials science and nanoengineering and faculty director of the Rice Emerging Scholars Program — and his team have developed a new approach using time-resolved spectroscopy and computational chemistry, according to a news release from Rice. The scientists "found experimental evidence of an alternative binding site on amyloid-beta aggregates, opening the door to the development of new therapies for Alzheimer’s and other diseases associated with amyloid deposits."

Amyloid plaque deposits in the brain are a main feature of Alzheimer’s, per Rice.

“Amyloid-beta is a peptide that aggregates in the brains of people that suffer from Alzheimer’s disease, forming these supramolecular nanoscale fibers, or fibrils” says Martí in the release. “Once they grow sufficiently, these fibrils precipitate and form what we call amyloid plaques.

“Understanding how molecules in general bind to amyloid-beta is particularly important not only for developing drugs that will bind with better affinity to its aggregates, but also for figuring out who the other players are that contribute to cerebral tissue toxicity,” he adds.

The National Science Foundation and the family of the late Professor Donald DuPré, a Houston-born Rice alumnus and former professor of chemistry at the University of Louisville, supported the research, which is explained more thoroughly on Rice's website.

University of Houston professor granted $1.6M for gene therapy treatment for rare eye disease

Muna Naash, a professor at UH, is hoping her research can result in treatment for a rare genetic disease that causes vision loss. Photo via UH.edu

A University of Houston researcher is working on a way to restore sight to those suffering from a rare genetic eye disease.

Muna Naash, the John S. Dunn Endowed Professor of biomedical engineering at UH, is expanding a method of gene therapy to potentially treat vision loss in patients with Usher Syndrome Type 2A, or USH2A, a rare genetic disease.

Naash has received a $1.6 million grant from the National Eye Institute to support her work. Mutations of the USH2A gene can include hearing loss from birth and progressive loss of vision, according to a news release from UH. Naash's work is looking at applying gene therapy — the introduction of a normal gene into cells to correct genetic disorders — to treat this genetic disease. There is not currently another treatment for USH2A.

“Our goal is to advance our current intravitreal gene therapy platform consisting of DNA nanoparticles/hyaluronic acid nanospheres to deliver large genes in order to develop safe and effective therapies for visual loss in Usher Syndrome Type 2A,” says Naash. “Developing an effective treatment for USH2A has been challenging due to its large coding sequence (15.8 kb) that has precluded its delivery using standard approaches and the presence of multiple isoforms with functions that are not fully understood."

BCM researcher on the impact of stress

This Baylor researcher is looking at the relationship between stress and brain cancer thanks to a new grant. Photo via Andriy Onufriyenko/Getty Images

Stress can impact the human body in a number of ways — from high blood pressure to hair loss — but one Houston scientist is looking into what happens to bodies in the long term, from age-related neurodegeneration to cancer.

Dr. Steven Boeynaems is assistant professor of molecular and human genetics at Baylor College of Medicine. His lab is located at the Jan and Dan Duncan Neurological Research Institute at Texas Children’s Hospital, and he also is a part of the Therapeutic Innovation Center, the Center for Alzheimer’s and Neurodegenerative Diseases, and the Dan L Duncan Comprehensive Cancer Center at Baylor.

Recently, the Cancer Prevention and Research Institute of Texas, or CPRIT, awarded Boeynaems a grant to continue his work studying how cells and organisms respond to stress.

“Any cell, in nature or in our bodies, during its existence, will have to deal with some conditions that deviate from its ideal environment,” Boeynaems says in a BCM press release. “The key issue that all cells face in such conditions is that they can no longer properly fold their proteins, and that leads to the abnormal clumping of proteins into aggregates. We have seen such aggregates occur in many species and under a variety of stress-related conditions, whether it is in a plant dealing with drought or in a human patient with aging-related Alzheimer’s disease."

Now, thanks to the CPRIT funding, he says his lab will now also venture into studying the role of cellular stress in brain cancer.

“A tumor is a very stressful environment for cells, and cancer cells need to continuously adapt to this stress to survive and/or metastasize,” he says in the release.

“Moreover, the same principles of toxic protein aggregation and protection through protein droplets seem to be at play here as well,” he continues. “We have studied protein droplets not only in humans but also in stress-tolerant organisms such as plants and bacteria for years now. We propose to build and leverage on that knowledge to come up with innovative new treatments for cancer patients.”

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Building Houston

 
 

At a recent SXSW panel, four Houston energy experts discussed the importance of research, commercialization, and more in Houston to drive the energy transition. Photo via Getty Images

Every part of the energy industry is going to have a role in the energy transition — from the universities where the research and development is happening to the startups and the incumbent industry leaders, as a recent SXSW panel discussed.

“We are well known in Houston for being the energy capital of the world," Jane Stricker, executive director of the Houston Energy Transition Initiative, says as moderator of the panel. "The industry typically comes together with stakeholders to think about the solutions and how to solve this dual challenge of continuing to provide more energy to the world but doing it in a way that significantly reduces emissions at the same time.”

The panel, entitled "Ground Zero: Creating Pathways from Research to Scale Deployment," was put on by HETI, an organization under the Greater Houston Partnership, and took place Sunday, March 12, in Austin at SXSW.

“I often say that I believe Houston is ground zero for the transition because we have this unique combination of assets, infrastructure, innovation, research at universities, and a collective understanding of the importance of energy to people’s lives that allows us to tackle this problem in new ways," she continues.

Sticker was joined by Paul Cherukuri, vice president for innovation at Rice University; Juliana Garaizar, chief development and investment officer at Greentown Labs; and Tara Karimi, co-founder and CTO of Cemvita Factory. The panel highlighted the challenges facing Houston as it promises to lead the energy transition.

For Cherukuri, whose innovation-focused position was newly created when he was appointed to it last August, it's a pivotal moment for research institutions.

"It's really an exciting time in Houston because universities are changing," says Cherukuri. "Rice University itself is changing in dramatic ways, and it's a great opportunity to really plug into the energy transition inside of Houston."

The role he plays, as he explains, is to connect Rice innovators to the rest of the city and the world.

"We have to partner through the accelerators as well as with with companies who can catch what we've made and take it to scale," he continues. "That's uniquely something that we can do in Houston. It's not something that a lot of cities can do."

Representing the scaling efforts is Greentown Labs, and Garaizar explains how the Massachusetts-based organization, which has its second outpost in Houston, connects its member companies to corporate partners that can become funders, pilot partners, customers, and more. But scaling can only be accomplished with the right technologies and the proper funding behind them.

"Sixty percent of the technologies that are going to be used to decarbonize the world haven't yet been invented," she says on the panel. "So, there's a huge pull for technology right now. And we see people who are only on the private equity space now finally invested in a lot of earlier series like series A, but there's still some road to to be made there."

Houston-based Cemvita Factory is in the scale phase, and Karimi explains how she's actively working with companies to apply the company's unique biotechnology to convert CO2 to natural resources to accommodate each customer's needs. Cemvita is on the front lines of interacting with incumbent energy businesses that play a major role in the future of energy.

"The way we communicate with energy companies, we tell them that us to be the innovation arm for you and we work together," Karimi says. "I think it's everybody needs to understand it's a transition. There is no way to just change the way that chemicals are produced just immediately and replace it with something new. It's a transition that needs both aspects."

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