Article published by Medical Xpress

Researchers have identified a potential treatment target for CDKL5 deficiency disorder (CDD), one of the most common types of genetic epilepsy. CDD causes seizures and impaired development. To date, there are no disease-targeting antiseizure medications. Recently, researchers have identified calcium channel Cav2.3 as a potential therapeutic target for CDD. Cav2.3 allows calcium to enter nerve cells, exciting the cells and allowing them to pass on electrical signals. This process is needed for the nervous system to function properly, but too much calcium coming into nerve cells can result in over-excitability and seizures. The researchers recorded calcium channel function and observed that a process called phosphorylation which changes the function of the channel was not occurring. Specifically, the channels were able to open, but were taking longer to close, leading to larger and more prolonged calcium currents flowing into cells. This implies that CDKL5 is needed to limit calcium entry into cells. Genetic mutations that enhance channel activity are already known to cause severe early-onset epilepsy in a related condition called DEE69 which shares similar symptoms as CDD. These results suggest that over-activity of nerve cells is a common feature of both disorders and that inhibiting the channel could help with symptoms like seizures. Marisol Sampedro-Castañeda, postdoctoral researcher, said, “Our research highlights for the first time a CDKL5 target with a link to neuronal excitability. There is evidence that this calcium channel could be involved in other types of epilepsy too, so we believe that Cav2.3 inhibitors could eventually be tested more widely. Our findings have implications for a large group of people, from the families affected by these conditions to researchers working in the rare epilepsy field.” 

Article published by Drug Target Review

Most people have the same genetic information in every cell of their body. However, during fetal development, two or more genetically diverse sets of cells can develop. These genetically diverse or ‘mosaic’ cells may cause disorders or diseases including epilepsy. Scientists have recently discovered an alternate origin of brain mosaicism in some children with focal epilepsy. The scientists performed a genetic analysis of brain tissue, blood and buccal cells (cells derived from the inside of the cheek). Tissue samples were taken from six patients, aged two months to seven months, who underwent epilepsy surgery. Analyses of the tissues showed that some of the cells in the brain tissue had extra copies of chromosome 1q compared to the normal tissue. The blood and buccal cells did not have any cells with extra copies of chromosome 1q. “This work is incredibly exciting for two reasons,” noted a study author. “First, it links a recently identified cause of epilepsy to a pathological finding, furthering our understanding of how chromosome 1q causes unrelenting seizures. Second, it opens the door to new mechanisms of how brain tissue may be impacted by genetic problems differently than the rest of the body. Now, we have to reconsider how we look at genetic causes of epilepsy.”

Article published by Baylor College of Medicine

Developmental and epileptic encephalopathy (DEE) refers to a group of neurodevelopmental conditions characterized by developmental delay, cognitive impairment and seizures in children. In 2016, the first case linking variants in both copies of the UBA5 gene to DEE44 was reported. Since then, twelve distinct missense variants in the UBA5 gene have been identified. Recently, Dr. Hugo J. Bellen and his team at Baylor College of Medicine and the Jan and Dan Duncan Neurological Research Institute at Texas Children’s Hospital generated a new fruit fly model to assess the severity of symptoms caused by each of these variants. The severity and the type of symptoms varied widely among different variants. For instance, five variants caused progressive motor defects, three of which also caused developmental delays or seizure-like symptoms. Their systematic analysis lays the foundation for better evaluation of the variants, which is important for DEE44 patients in the future and for the development of drugs and gene therapy to treat this rare disorder. The study was published in the journal eLife.

Article published by Medical Xpress

The largest genetic study of its kind, coordinated by the International League Against Epilepsy, including scientists from FutureNeuro at RCSI University of Medicine and Health Sciences, has discovered specific changes in our DNA that increase the risk of developing epilepsy.

The research, published in Nature Genetics, greatly advances our knowledge of why epilepsy develops and may inform the development of new treatments for the condition.

Epilepsy, a common brain disorder of which there are many different types, is known to have genetic component and to sometimes run in families. Here, researchers compared the DNA from diverse groups of almost 30,000 people with epilepsy to the DNA of 52,500 people without epilepsy. The differences highlighted areas of our DNA that might be involved in the development of epilepsy.

The researchers identified 26 distinct areas in our DNA that appear to be involved in epilepsy. This included 19 which are specific to a particular form of epilepsy called ‘genetic generalized epilepsy’ (GGE). They were also able to point to 29 genes that are probably contributing to epilepsy within these DNA regions.

The scientists found that the genetic picture was quite different when comparing distinct types of epilepsy, in particular, when “focal” and “generalized” epilepsies were compared. The results also suggested that proteins that carry electrical impulse across the gaps between neurons in our brain make up some of the risk for generalized forms of epilepsy.

“Gaining a better understanding of the genetic underpinnings of epilepsy is key to developing new therapeutic options and consequently a better quality of life for the over 50 million people globally living with epilepsy,” said Professor Gianpiero Cavalleri, Professor of Human Genetics at RCSI School of Pharmacy and Biomolecular Science and Deputy Director of the SFI FutureNeuro Research Center.

Article published by News Medical Science

Epilepsy in infants ranges in severity and can leave caregivers with questions about their child’s health. While genetic testing to help determine the cause of epilepsy is possible, comprehensive testing does not always happen routinely and it can take a long time, leaving families waiting for answers.

Published in The Lancet Neurology, this international study sequenced the genomes of 100 infants with unexplained seizures, along with their parents, from four countries (England, USA, Canada and Australia) to better understand the potential strengths of early, broad genome sequencing (a process which looks for changes across the entire genome) for infantile epilepsy.

The researchers used rapid genome sequencing (rGS) to investigate the impact of an expedited genetic diagnosis on care for the first time. Across all children enrolled in the study, 43 per cent received a diagnosis within weeks, and that diagnosis impacted prognosis in nearly 90 per cent of those cases, guiding treatment options for over half.