Tag: pulmonary hypertension

New Insights and Potential Treatments for Pulmonary Hypertension

Human heart. Credit: Scientific Animations CC4.0

A new study from researchers with UCLA Health and collaborating organisations has found that asporin, a protein encoded by the ASPN gene, plays a protective role in pulmonary arterial hypertension (PAH).

Their findings, out now in the peer-reviewed journal Circulation, offer new insights into this incurable, often-fatal disease and suggest potential new ways to treat it. The ASPN gene is part of a group of genes associated with the cartilage matrix.

“We were surprised to find that asporin, which previously had not been linked to PAH, gets upregulated to increased levels as a response to counteract this disease process,” said Dr Jason Hong, a pulmonary and critical care physician at UCLA Health and the study’s corresponding author. “This novel finding opens up new avenues for understanding PAH pathobiology and developing potential therapies.” 

Pulmonary hypertension is a serious medical condition characterised by high blood pressure in the arteries that supply the lungs. It causes these arteries to narrow or become blocked, which, in turn, slows blood flow to the heart, requiring it to work harder to pump blood through the lungs. Eventually, the heart muscle becomes weak and begins to fail. 

Need for New Therapies

According to recent estimates, PAH affects about 1% of the global population, but that number climbs to 10% in people who are 65 or older. 

There’s no cure for the disease, but medications and lifestyle changes can help slow progression, manage symptoms and prolong life.

The urgent need for new therapies, combined with the potential of multiomics – an integrated approach to drive discovery across multiple levels of biology – inspired Hong and research colleagues, including co-first author Lejla Medzikovic and senior author Mansoureh Eghbali to take a deep dive into the disease. Both work at UCLA’s Eghbali Laboratory.

Methodology

For the study, the researchers applied novel computational methods, including transcriptomic profiling and deep phenotyping, to lung samples of 96 PAH patients and 52 control subjects without the condition from the largest multicenter PAH lung biobank available to-date. They integrated this data with clinical information, genome-wide association studies, graphic models of probabilities and multiomics analysis.

“Our detailed analysis found higher levels of asporin in the lungs and plasma of PAH patients, which were linked to less severe disease,” Hong said.

Additionally, Medzikovic noted that their cell and living-organism experiments found that asporin inhibited pulmonary artery smooth muscle cell proliferation and a key signaling pathway that occurs with PAH.

“We also demonstrated that recombinant asporin treatment reduced PAH severity in preclinical models,” said Medzikovic.

Next Steps

Hong and colleagues plan to further investigate the mechanisms by which asporin exerts its protective effects in PAH and explore potential therapeutic applications, focusing on how to translate their findings into clinical trials.

“Asporin represents a promising new target for therapeutic intervention in pulmonary arterial hypertension,” he explained. “Enhancing asporin levels in PAH patients could potentially lead to improved clinical outcomes and reduced disease progression.”

Source: University of California – Los Angeles Health Sciences

A Genetic Clue to Pulmonary Hypertension Risk

Photo by Sangharsh Lohakare on Unsplash

University of Pittsburgh Schools of Medicine researchers uncovered a fundamental mechanism that controls the body’s response to limited oxygen and regulates blood vessel disease of the lung.

By combing through genomes of more than 20 000 individuals in the US, France, England and Japan and combining the results with molecular studies in the lab, the team discovered a shared genetic trait that could predict a higher risk of pulmonary hypertension and its more severe form, pulmonary arterial hypertension, and influence the development of drug therapies that target the body’s response to limited oxygen. The findings were published in Science Translational Medicine.

“This new level of knowledge will help identify people who may be at a higher genetic risk of pulmonary hypertension and jump-start precision medicine practices to offer customised treatments,” said senior author Stephen Chan, MD, PhD.

Pulmonary hypertension encompasses a range of conditions of various causes that manifest in high blood pressure in the arteries of the lung and the right side of the heart.

The disease is accompanied by a decreased supply of oxygen to the lung tissue and the blood, is chronic and deadly, and its molecular origins and genetic background remain unsolved.

Using a combined approach of genomics and biochemistry, the Chan lab found a gene pair that had an important function in regulating blood vessel metabolism and disease.

This gene pair included a long non-coding RNA molecule – a messenger that facilitates the transformation of the body’s genetic code into protein products – and a protein binding partner, and their interaction was frequently active in cells exposed to low oxygen compared to normal cells.

Taking the findings a step further, the team discovered that a single DNA letter change directing expression of this RNA-protein pair under low oxygen conditions was associated with a higher genetic risk of pulmonary hypertension across diverse patient populations.

According to Chan, pulmonary hypertension is a borderline orphan disease, and the limited number of patients with pulmonary hypertension makes it challenging to find genetic variations that are rare but still impactful enough to eclipse individual differences.

With that in mind, Pitt scientists turned to collaborators around the globe and to public research datasets to ensure that the findings are relevant across a diverse global population.

Chan hopes that his findings will spur the development of targeted therapies relevant to oxygen sensitivity in blood vessel lining and that their pending patent application will contribute to the growth on an entirely new field of epigenetic and RNA drug therapeutics that work not by manipulating the genome but by changing how it is being read.

Source: University of Pittsburgh