Donnelly Centre for Cellular &amp; Biomolecular Research

Institute of Biomedical Engineering

Princess Margaret Cancer Centre

Donnelly Centre for Cellular & Biomolecular Research

Faculty of Applied Science & Engineering

University Health Network

Subheadline

"This could be a game-changer for treating complex conditions where targeting multiple pathways is beneficial, such as cancer and viral infections"

Researchers at the �ܼ��ѿ��ȫ and its hospital partners have developed a method for co-delivering therapeutic RNA and potent drugs directly into cells, potentially leading to a more effective treatment of diseases.

The research, published recently in the journal Advanced Materials, explores how ionizable drugs can be used to co-formulate small interfering RNA (siRNA) for more effective intracellular delivery.

The team – including Molly Shoichet, the study’s corresponding author and a University Professor in �ܼ��ѿ��ȫ’s department of chemical engineering and applied chemistry in the Faculty of Applied Science & Engineering – specifically targeted drug-resistant cells with the delivery of a relevant siRNA. The siRNA was discovered study co-author and collaborator David Cescon, a clinician scientist at the Princess Margaret Cancer Centre, University Health Network, and an associate professor in �ܼ��ѿ��ȫ’s Temerity Faculty of Medicine.

“We found that our co-formulation method not only potently delivered siRNA to cells but also simultaneously delivered active ionizable drugs,” said research lead author Kai Slaughter, a PhD candidate in Shoichet’s lab.

“This could be a game-changer for treating complex conditions where targeting multiple pathways is beneficial, such as cancer and viral infections.”

siRNA is a powerful tool in medicine, capable of silencing specific genes responsible for disease, but delivering these molecules into cells without degradation remains a significant challenge. While recent innovations in ionizable lipid design have led to efficiency improvements, traditional nanoparticle formulations are limited in the amount of small molecule drugs they can carry.

When therapeutic formulations are absorbed by cells, small molecule drugs and siRNA are often trapped in small compartments called endosomes, preventing them from reaching their target destination and reducing their effectiveness.

The research team discovered that combining siRNA with ionizable drugs – compounds that change their charge based on pH levels – enhances the stability and delivery efficiency of siRNA inside cells, helping both the siRNA and drug escape the endosome and more effectively reach their destination. This novel method utilizes the protective properties of lipids to safeguard siRNA during its journey through the body and ensure the release of RNA and the drug together within the target cells.

“One of the biggest hurdles in siRNA therapy has been getting these molecules to where they need to go without losing their potency,” Shoichet says.

“Our approach using ionizable drugs as carriers marks a significant step forward in overcoming this barrier, while also showing how drugs and RNA can be delivered together in the same nanoparticle formulation.”

�ܼ��ѿ��ȫ researchers integrate crucial immune cells onto heart-on-a-chip platform

Christopher.Sorensen — Fri, 23 Aug 2024 12:56:51 +0000

�ܼ��ѿ��ȫ researchers integrate crucial immune cells onto heart-on-a-chip platform

Christopher.Sorensen Fri, 08/23/2024 - 08:56

Cutline

L-R: �ܼ��ѿ��ȫ post-doctoral fellow Shira Landau, PhD alum Yimu Zhao and Professor Milica Radisic are three of the primary authors of a study that could lead to advancements in the creation of more stable and functional heart tissues (supplied images)

Qin Dai

Topic

Institute of Biomedical Engineering

Toronto General Hospital

Donnelly Centre for Cellular & Biomolecular Research

Faculty of Applied Science & Engineering

University Health Network

Subheadline

The immune cells, known as primitive macrophages, were found to enhance heart tissue function and vessel stability

Researchers at the �ܼ��ѿ��ȫ have discovered a novel method for incorporating primitive macrophages – crucial immune cells – into heart-on-a-chip technology, in a potentially transformative step forward in drug testing and heart disease modeling.

In a study published in Cell Stem Cell, an interdisciplinary team of scientists describe how they integrated the macrophages – which were derived from human stem cells and resemble those found in the early stages of heart development – onto the platforms. These macrophages are known to have remarkable abilities in promoting vascularization and enhancing tissue stability.

Corresponding author Milica Radisic, a senior scientist in the University Health Network's Toronto General Hospital Research Institute and professor in the Institute of Biomedical Engineering at �ܼ��ѿ��ȫ’s Faculty of Applied Science & Engineering, says the approach promises to enhance the functionality and stability of engineered heart tissues.

“We demonstrated here that stable vascularization of a heart tissue in vitro requires contributions from immune cells, specifically macrophages. We followed a biomimetic approach, re-establishing the key constituents of a cardiac niche,” says Radisic, who holds a Canada Research Chair in Functional Cardiovascular Tissue Engineering

“By combining cardiomyocytes, stromal cells, endothelial cells and macrophages, we enabled appropriate cell-to-cell crosstalk such as in the native heart muscle.”

Professor Milica Radisic's research team have worked on developing a miniaturized version of cardiac tissue on heart-on-a-chip platforms for a decade (photo by Nick Iwanyshyn)

A major challenge in creating bioengineered heart tissue is achieving a stable and functional network of blood vessels. Traditional methods have struggled to maintain these vascular networks over extended periods, limiting their effectiveness for long-term studies and applications.

In their study, researchers demonstrated that the primitive macrophages could create stable, perfusable microvascular networks within the cardiac tissue, a feat that had previously been difficult to achieve.

Furthermore, the macrophages helped reduce tissue damage by mitigating cytotoxic effects, thereby improving the overall health and functionality of the engineered tissues.

“The inclusion of primitive macrophages significantly improved the function of cardiac tissues, making them more stable and effective for longer periods,” says Shira Landau, a post-doctoral fellow in Radisic’s lab and one of the study’s lead authors.

The breakthrough has far-reaching implications for the field of cardiac research. By enabling the creation of more stable and functional heart tissues, researchers can better study heart diseases and test new drugs in a controlled environment.

Researchers say this technology could lead to more accurate disease models and more effective treatments for heart conditions.

�ܼ��ѿ��ȫ researchers develop AI model to predict 'very dynamic' peptide structures

Christopher.Sorensen — Thu, 15 Aug 2024 12:54:41 +0000

�ܼ��ѿ��ȫ researchers develop AI model to predict 'very dynamic' peptide structures

Christopher.Sorensen Thu, 08/15/2024 - 08:54

Cutline

PhD Graduate Osama Abdin and Professor Philip M. Kim developed a deep-learning model that can predict all possible shapes of peptides, which are are of keen interest to researchers who are developing therapeutics (supplied image)

Topic

Donnelly Centre for Cellular & Biomolecular Research

Alumni

Artificial Intelligence

Computer Science

Subheadline

The new model expands on the capabilities of Google DeepMind's AlphaFold, the leading AI system for predicting protein structures

Researchers at the �ܼ��ѿ��ȫ have developed a deep-learning model that can predict all possible shapes of peptides – chains of amino acids that are shorter than proteins, but perform similar biological functions.

Called PepFlow, the model combines machine learning and physics to model the range of folding patterns that a peptide can assume based on its energy landscape.

Peptides, unlike proteins, are dynamic molecules that can take on a range of conformations. They are involved in many biological processes that are of keen interest to researchers who are developing therapeutics.

“We haven’t been able to model the full range of conformations for peptides until now,” said Osama Abdin, first author on the study and recent PhD graduate of molecular genetics at �ܼ��ѿ��ȫ’s Donnelly Centre for Cellular and Biomolecular Research. “PepFlow leverages deep-learning to capture the precise and accurate conformations of a peptide within minutes.

“There’s potential with this model to inform drug development through the design of peptides that act as binders.”

The study was recently published in the journal Nature Machine Intelligence.

A peptide’s role in the human body is directly linked to how it folds since its 3D structure determines the way it binds and interacts with other molecules.

“Peptides were the focus of the PepFlow model because they are very important biological molecules and they are naturally very dynamic, so we need to model their different conformations to understand their function,” said Philip M. Kim, the study’s principal investigator and a professor at the Donnelly Centre. “They’re also important as therapeutics, as can be seen by the GLP1 analogues, like Ozempic, used to treat diabetes and obesity.”

Peptides are also cheaper to produce than their larger protein counterparts, said Kim, who is also a professor of computer science in �ܼ��ѿ��ȫ’s Faculty of Arts & Science and a professor of molecular genetics in the Temerty Faculty of Medicine.

The new model expands on the capabilities of AlphaFold, the leading Google DeepMind AI system for predicting protein structure. It does this by generating a range of conformations for a given peptide. Taking inspiration from highly advanced physics-based machine learning models, PepFlow can also model peptide structures that take on unusual formations, including the ring-like structure that results from a process called macrocyclization. Peptide macrocycles are currently a highly promising venue for drug development.

“It took two-and-a-half years to develop PepFlow and one month to train it, but it was worthwhile to move to the next frontier beyond models that only predict one structure of a peptide,” Abdin said.

There are, however, limitations given that PepFlow represents the first version of a new model. The study authors noted a number of ways in which PepFlow could be improved, including training the model with explicit data for solvent atoms, which would dissolve the peptides to form a solution, and for constraints on the distance between atoms in ring-like structures.

Yet, even as a first version, the researchers say PepFlow is a comprehensive and efficient model with potential for furthering the development of treatments that depend on peptide binding to activate or inhibit biological processes.

“Modelling with PepFlow offers insight into the real energy landscape of peptides,” said Abdin.

The research was supported by the Canadian Institutes of Health Research and the Natural Sciences and Engineering Research Council of Canada.

�ܼ��ѿ��ȫ researchers develop RNA-targeting technology to precisely manipulate parts of human genes

Christopher.Sorensen — Thu, 08 Aug 2024 18:26:00 +0000

�ܼ��ѿ��ȫ researchers develop RNA-targeting technology to precisely manipulate parts of human genes

Christopher.Sorensen Thu, 08/08/2024 - 14:26

Cutline

From left to right: PhD student Jack Daiyang Li, Professor Benjamin Blencowe and Associate Professor Mikko Taipale (supplied images)

Topic

Donnelly Centre for Cellular & Biomolecular Research

Genes

Subheadline

“Our new tool makes possible a broad range of applications, from studying gene function and regulation to potentially correcting splicing defects in human disorders and diseases”

Researchers at the �ܼ��ѿ��ȫ have harnessed a bacterial immune defence system, known as CRISPR, to efficiently and precisely control the process of RNA splicing.

The technology opens the door to new applications, including systematically interrogating the functions of parts of genes and correcting splicing deficiencies that underlie numerous diseases and disorders.

“Almost all human genes produce RNA transcripts that undergo the process of splicing, whereby coding segments, called exons, are joined together and non-coding segments, called introns, are removed and typically degraded,” said Jack Daiyang Li, first author on the study and PhD student of molecular genetics, working in the labs of �ܼ��ѿ��ȫ researchers Benjamin Blencowe and Mikko Taipale at the Donnelly Centre for Cellular and Biomolecular Research in the Temerty Faculty of Medicine.

Exons from the same gene can be mixed and matched in various combinations to produce different versions of RNA, and consequently, different proteins. This process, called alternative splicing, contributes to the diverse expression of the 20,000 human genes that encode proteins, allowing the development and functional specialization of different types of cells.

However, it is unclear what most exons or introns do and the misregulation of normal alternative splicing patterns is a frequent cause or contributing factor to various diseases, including cancers and brain disorders. In addition, there is a lack of existing methods that allow for the precise and efficient manipulation of splicing.

The new study, published in the journal Molecular Cell, describes how a catalytically deactivated version of an RNA-targeting CRISPR protein, referred to as dCasRx, was joined to more than 300 splicing factors to discover a fusion protein called dCasRx-RBM25. This protein is capable of activating or repressing alternative exons in an efficient and targeted manner.

“Our new effector protein activated alternative splicing of around 90 per cent of tested target exons,” said Li. “Importantly, it is capable of simultaneously activating and repressing different exons to examine their combined functions.”

This multi-level manipulation will facilitate the experimental testing of functional interactions between alternatively spliced variants from genes to determine their combined roles in critical developmental and disease processes.

“Our new tool makes possible a broad range of applications, from studying gene function and regulation, to potentially correcting splicing defects in human disorders and diseases,” said Blencowe, principal investigator on the study, Canada Research Chair in RNA Biology and Genomics, Banbury Chair in Medical Research and a professor of molecular genetics at the Donnelly Centre and Temerty Medicine.

“We have developed a versatile engineered splicing factor that outperforms other available tools in the targeted control of alternative exons,” said Taipale, also principal investigator on the study, Canada Research Chair in Functional Proteomics and Proteostasis, Anne and Max Tanenbaum Chair in Molecular Medicine and associate professor of molecular genetics at the Donnelly Centre and Temerty Medicine. “It is also important to note that target exons are perturbed with remarkably high specificity by this splicing factor, which alleviates concerns about possible off-target effects.”

The researchers now have a tool in hand to systematically screen alternative exons to determine their roles in cell survival, cell-type specification and gene expression.

When it comes to the clinic, the splicing tool has potential to be used to treat numerous human disorders and diseases, such as cancers, in which splicing is often disrupted.

The research was supported by the Canadian Institutes of Health Research and the Simons Foundation.

�ܼ��ѿ��ȫ researchers lead discovery of natural compounds that selectively kill parasites

rahul.kalvapalle — Tue, 21 May 2024 17:46:46 +0000

�ܼ��ѿ��ȫ researchers lead discovery of natural compounds that selectively kill parasites

rahul.kalvapalle Tue, 05/21/2024 - 13:46

Cutline

An international study led by PhD student Taylor Davie (L) and Professor Andrew Fraser (R) of the Donnelly Centre for Cellular and Biomolecular Research could have important implications for treatment of lethal parasitic worms (supplied images)

Topic

Donnelly Centre for Cellular & Biomolecular Research

Molecular Genetics

Subheadline

The compounds stall a unique metabolic process that parasitic worms use to survive in the human gut

An international team led by researchers at the �ܼ��ѿ��ȫ has found a family of natural compounds that could potentially be harnessed as treatments for parasitic worms, which wreak havoc in developing countries in the tropics.

Infection by these parasites, which are transmitted through soil, leads to malaise, weakness, malnutrition and other debilitating symptoms, and can cause developmental defects and growth impairments in children.

The newly discovered compounds stall the unique metabolic process that the worms use to survive in the human gut, according to the study, which was published in Nature Communications.

“Soil-transmitted parasitic worms infect over one billion people around the world, typically in low-income communities of developing countries without comprehensive health care and infrastructure for sanitation,” said Taylor Davie, first author on the study and a PhD student at �ܼ��ѿ��ȫ’s Donnelly Centre for Cellular and Biomolecular Research. “Parasites are becoming less susceptible to the few anthelmintic drugs available, so there’s an urgent need to find new compounds.”

Many parasitic worm species spend a large portion of their life cycle inside a human host. To adapt to the environmental conditions of the gut, particularly a lack of oxygen, the parasite switches to a type of metabolism that depends on a molecule called rhodoquinone (RQ).

The parasite can survive inside its human host for many months using RQ-dependent metabolism.

The research team chose to target the adaptive metabolic process of the parasitic worm because RQ is only present in the parasite’s system – humans do not produce or use RQ. Therefore, compounds that can regulate the molecule’s production or activity would selectively kill the parasite, with no harm done to the human host.

The researchers conducted a screen of natural compounds isolated from plants, fungi and bacteria on the model organism C. elegans. Although C. elegans is not a parasite, this worm also depends on RQ for metabolism when oxygen is not available.

“This is the first time that we have been able to screen for drugs that specifically target the unusual metabolism of these parasites,” said Andrew Fraser, principal investigator on the study and professor of molecular genetics at the Donnelly Centre and the Temerty Faculty of Medicine.

“The screen was only possible because of recent progress made by our group and others in using C. elegans to study RQ-dependent metabolism, and our collaboration with RIKEN, one of Japan’s biggest research agencies.

“We screened their world-class collection of 25,000 natural compounds, resulting in our discovery of a family of benzimidazole compounds that kills worms relying on this type of metabolism.”

The researchers suggest a multi-dose regimen using the newly discovered family of compounds to treat parasitic worms. While a single-dose treatment is easier to facilitate in mass drug administration programs, a longer treatment program would eliminate the parasite more effectively.

“We are very pleased with the results of the study, which made use of our library,” said Hiroyuki Osada, professor of pharmacy at the University of Shizuoka and group director of the Chemical Biology Research Group at the RIKEN Center for Sustainable Resource Science.

“The study shows the power of the screening approach, allowing researchers in this case to search through a very large number of molecules within a focused collection of natural products. Screens are very efficient, which is key for addressing urgent research questions of global relevance like this one.”

Next steps for the research team are to refine the new class of inhibitors through additional in-vivo testing with parasitic worms, which will be performed by the Keiser lab at the University of Basel in Switzerland, and to continue screening for compounds that inhibit RQ.

“This study is just the beginning,” said Fraser. “We have found several other very powerful compounds that affect this metabolism including, for the first time, a compound that blocks the ability of the worms to make RQ.

“We hope our screens will deliver drugs to treat major pathogens around the world.”

This research was supported by the Canadian Institutes of Health Research and the European Molecular Biology Organization.

�ܼ��ѿ��ȫ researchers' approach to producing neural cells could yield new treatments for Parkinson’s

rahul.kalvapalle — Mon, 13 May 2024 13:03:19 +0000

�ܼ��ѿ��ȫ researchers' approach to producing neural cells could yield new treatments for Parkinson’s

rahul.kalvapalle Mon, 05/13/2024 - 09:03

Cutline

PhD Student Andy Yang, left, and Professor Stephane Angers, right, at the Donnelly Centre for Cellular and Molecular Biology are advancing a novel approach to developing dopaminergic neurons (supplied images)

Topic

Institutional Strategic Initiatives

Donnelly Centre for Cellular & Biomolecular Research

Graduate Students

Leslie Dan Faculty of Pharmacy

Medicine by Design

Parkinson's

Subheadline

An antibody was used to selectively activate a receptor in a molecular signalling pathway to develop dopaminergic neurons

Researchers at the �ܼ��ѿ��ȫ believe they’ve found a way to better control the generation of key neurons depleted in Parkinson’s disease – suggesting a potentially new approach to addressing a disease with no cure and few effective treatments.

In preclinical studies, the researchers used an antibody to selectively activate a receptor in a molecular signalling pathway to develop dopaminergic neurons. These neurons produce dopamine, a neurotransmitter critical to brain health.

While researchers around the world have been working to coax stem cells to differentiate into dopaminergic neurons to replace those lost in patients living with Parkinson’s disease, the efforts have so far been hindered in part by an inability to target specific receptors and areas of the brain.

“We used synthetic antibodies that we had previously developed to target the Wnt signaling pathway,” said principal investigator Stephane Angers, who is director of �ܼ��ѿ��ȫ’s Donnelly Centre for Cellular and Molecular Biology and a professor in the Leslie Dan Faculty of Pharmacy and the Temerty Faculty of Medicine.

“We can selectively activate this pathway to direct stem cells in the midbrain to develop into neurons by targeting specific receptors in the pathway. This activation method has not been explored before.”

Parkinson’s disease is the second-most common neurological disorder after Alzheimer’s, affecting over 100,000 Canadians. It particularly impacts older men, progressively impairing movement and causing pain as well as sleep and mental health issues.

Most previous research efforts to activate the Wnt signaling pathway relied on a GSK3 enzyme inhibitor. This method involves multiple signaling pathways for stem cell proliferation and differentiation, which can have an unintended effect on the newly produced neurons and activate off-target cells.

“We developed an efficient method for stimulating stem cell differentiation to produce neural cells in the midbrain,” said Andy Yang, first author on the study and a PhD student at the Donnelly Centre. “Moreover, cells activated via the FZD5 receptor closely resemble dopaminergic neurons of natural origin.”

Another promising finding of the study, published recently in the journal Development, is that implanting the artificially-produced neurons in a rodent model with Parkinson’s disease led to improvement of the rodent’s locomotive impairment.

“Our next step would be to continue using rodent or other suitable models to compare the outcomes of activating the FZD5 receptor and inhibiting GSK3,” said Yang. “These experiments will confirm which method is more effective in improving symptoms of Parkinson’s disease ahead of clinical trials.”

The research was supported by �ܼ��ѿ��ȫ’s Medicine by Design program, an institutional strategic initiative that receives funding from the Canada First Research Excellence Fund and the Canadian Institutes of Health Research.

Researchers devise new method to find proteins for targeted treatment of disease

Christopher.Sorensen — Tue, 26 Mar 2024 18:12:33 +0000

Researchers devise new method to find proteins for targeted treatment of disease

Christopher.Sorensen Tue, 03/26/2024 - 14:12

Cutline

Visiting Scientist Juline Poirson and Associate Professor Mikko Taipale worked with researchers at Sinai Health to develop a method to interrogate the entire human proteome for “effector” proteins, which can influence the stability of other proteins (supplied images)

Topic

Sinai Health

Donnelly Centre for Cellular & Biomolecular Research

Subheadline

“Targeting proteins through induced proximity is a new and promising area of biomedical research”

Researchers at Sinai Health and the �ܼ��ѿ��ȫ have created a new platform to identify proteins that can be used to control the stability of other proteins – a new and largely unrealized approach to treating diseases.

The researchers developed a method to interrogate the entire human proteome for “effector” proteins, which can influence the stability of other proteins via induced proximity. The approach effectively attempts to hijack cellular processes for therapeutic purposes.

The study marks the first time researchers have searched for effector proteins on this scale, and has identified many new effectors that could potentially be used to develop new drugs.

“We found more than 600 new effector proteins in 14,000 genes,” said Juline Poirson, first author on the study and visiting scientist at �ܼ��ѿ��ȫ’s Donnelly Centre for Cellular and Biomolecular Research. “Over 200 of the new effectors can efficiently degrade their target proteins, while about 400 effectors were capable of stabilizing, and thereby increasing the abundance of, an artificial target protein.”

The study, which involved researchers at Sinai Health’s Lunenfeld-Tanenbaum Research Institute, was published in the journal Nature.

“Targeting proteins through induced proximity is a new and promising area of biomedical research,” said Mikko Taipale, principal investigator on the study and an associate professor of molecular genetics at the Donnelly Centre and in the Temerty Faculty of Medicine. “Not only did we find new effectors worth further investigation for drug discovery, we developed a synthetic platform that can be used to conduct unbiased, proteome-wide, induced-proximity screens to continue expanding the library of effector proteins.”

The effectors currently in use for targeted protein degradation and stabilization are E3 ubiquitin ligases (E3s) and deubiquitinases (DUBs), respectively. E3 is an enzyme that transfers the ubiquitin molecule to the target protein, which essentially flags the protein for a proteosome to digest it. On the other hand, a DUB enzyme removes the ubiquitin tag from a protein, thereby preventing the protein from being recognized and degraded by a proteosome.

The results of the study demonstrate that E3s are quite varied in the degree to which they can degrade target proteins. The research team also discovered four of what they call “angry E3s,” which consistently degrade targets regardless of other factors, such as the location of the target within the cell.

One surprising finding was that some of the strongest effectors for targeted protein degradation were E2 conjugating enzymes, instead of E3s. These differ from E3s in that they are involved at an earlier step of protein degradation and do not directly engage the target protein. Because E2s were not considered to be easily targeted with drugs, they had not been harnessed for protein degradation until recently. They represent, however, the untapped potential of stronger effectors than ones currently in use.

The study demonstrates that exploring the whole proteome for induced proximity offers enormous opportunities for therapeutic interventions.

KLHL40, one of the identified effectors, could potentially be hijacked for targeted protein stabilization to treat skeletal muscle disorders. The research team also found that targeted protein degradation with FBXL12 and FBXL15 effectors could be particularly useful in treating chronic myeloid leukemia.

Targeted protein degradation and stabilization are innovative methods of drug discovery that have thus far been plagued with the “protein pair problem,” where the best effector for a target protein cannot be predicted accurately. Matching a target protein with the right effector is essential to successfully and safely facilitate degradation and stabilization processes in tissues.

“The synthetic screening platform developed by our team solves the protein matching issue through rapid, large-scale testing of effector and target protein interactions,” said Poirson. “We’re confident that an unbiased induced-proximity approach can be used to find effectors for almost any target.”

The research was supported by the David Dime and Elisa Nuyten Catalyst Fund, the Mark Foundation for Cancer Research, the Charles H. Best Postdoctoral Fellowship and the Canadian Institutes of Health Research (CIHR) Fellowship.

Researchers pinpoint issue that could be hampering common chemotherapy drug

Christopher.Sorensen — Mon, 18 Mar 2024 15:00:03 +0000

Researchers pinpoint issue that could be hampering common chemotherapy drug

Christopher.Sorensen Mon, 03/18/2024 - 11:00

Cutline

(photo by Glasshouse Images/Getty Images)

Topic

Donnelly Centre for Cellular & Biomolecular Research

Biochemistry

Cancer

Subheadline

Study finds two enzymes that work against the chemotherapy drug gemcitabine, preventing it from effectively treating pancreatic cancer

Researchers at the �ܼ��ѿ��ȫ’s Donnelly Centre for Cellular and Biomolecular Research have found two enzymes that work against the chemotherapy drug gemcitabine, preventing it from effectively treating pancreatic cancer.

The enzymes – APOBEC3C and APOBEC3D – increase during gemcitabine treatment and promote resistance to DNA replication stress in pancreatic cancer cells.

This, in turn, counteracts the effects of gemcitabine and allows for the growth of cancer cells.

Tajinder Ubhi and Grant Brown (supplied images)

“Pancreatic cancer has proven to be very challenging to treat, as it is usually diagnosed at stage 3 or 4,” said Tajinder Ubhi, first author on the study and a former PhD student in biochemistry in �ܼ��ѿ��ȫ’s Temerty Faculty of Medicine.

“It is the most lethal type of cancer in Canada, with an average survival time of less than two years. While chemotherapy with gemcitabine has increased survival by a few months in clinical trials, options for treatment of pancreatic cancer remain limited.”

The findings were published in the journal Nature Cancer.

Replication stress is the key process by which gemcitabine stops cancer cells from continuing to multiply. It involves the dysregulation of DNA replication, which occurs when cells divide. Replication stress can transform a healthy cell into a cancerous one, but can also be activated within cancer cells to eliminate them.

Gemcitabine has been used for nearly three decades to treat a wide variety of cancers, including pancreatic, breast and bladder cancer. However, a downside of using gemcitabine to target dividing cells is that it can produce toxic side effects in tissues that aren’t being targeted for treatment.

Ubhi and other members of Professor Grant Brown’s lab at the Donnelly Centre have been trying to understand the possible causes of replication stress and its impacts. One way to do this is by studying the stress response mechanisms in cancer cells treated with gemcitabine.

“We conducted a genome-wide CRISPR screen to find genes that could increase the sensitivity of pancreatic cancer cells to gemcitabine,” said Brown, professor of biochemistry at the Donnelly Centre and in the Temerty Faculty of Medicine who is the principal investigator on the study.

“We were excited to identify APOBEC3C and APOBEC3D because other enzymes in the APOBEC3 family can cause cancers to eventually become resistant to treatment. We discovered a more direct role for the enzymes, where they actually protect pancreatic cancer cells from gemcitabine therapy.”

Neither enzyme is naturally found in high concentrations within healthy or cancerous cells. The catch is that the replication stress the drug causes in pancreatic cancer cells in turn triggers an increase in both enzymes. The research team found that removing either APOBEC3C or APOBEC3D kills pancreatic cells by stymieing DNA repair and destabilizing the cell genome.

“What is most exciting is that the removal of just APOBEC3C or APOBEC3D is enough to stop the replication of gemcitabine-treated pancreatic cancer cells,” said Ubhi. “This indicates that the enzymes could be effective new targets for treating this form of cancer.”

The research received support from the Canada Foundation for Innovation, the Canadian Cancer Society, Canadian Friends of the Hebrew University, the Canadian Institutes of Health Research, Cold Spring Harbor Laboratory, the Government of Ontario, the Lustgarten Foundation, the Ministry for Culture and Innovation of Hungary, the U.S. National Institutes of Health, the Northwell Health Affiliation, the Ontario Institute for Cancer Research, Pancreatic Cancer Canada, the Princess Margaret Cancer Foundation, the Simons Foundation, the Terry Fox Research Institute and the Thompson Foundation.

Researchers discover one million new components of the human genome

Christopher.Sorensen — Thu, 08 Feb 2024 19:16:32 +0000

Researchers discover one million new components of the human genome

Christopher.Sorensen Thu, 02/08/2024 - 14:16

Cutline

Timothy Hughes, professor and chair of �ܼ��ѿ��ȫ’s department of molecular genetics in the Temerty Faculty of Medicine, is the principal researcher on a study that found nearly one million new exons, or stretches of DNA that are expressed in mature RNA (photo courtesy of the Donnelly Centre)

Topic

Donnelly Centre for Cellular & Biomolecular Research

Genome

Molecular Genetics