New therapeutic avenues in bone repair
The latest research shows that PEPITEM could be used as a novel and early clinical intervention to reverse the impact of age-related musculoskeletal diseases
The latest research shows that PEPITEM could be used as a novel and early clinical intervention to reverse the impact of age-related musculoskeletal diseases
Birmingham researchers have shown PEPITEM, a naturally occurring peptide (small protein) holds promise as a new therapeutic for osteoporosis and other disorders that feature bone loss, with distinct advantages over existing drugs.
PEPITEM (Peptide Inhibitor of Trans-Endothelial Migration) was first identified in 2015 by University of Birmingham researchers.
The latest research, published today in Cell Reports Medicine, show for the first time that PEPITEM could be used as a novel and early clinical intervention to reverse the impact of age-related musculoskeletal diseases, with data demonstrating that PEPITEM enhances bone mineralisation, formation and strength, and reverses bone loss in animal models of disease.
While the most commonly used drugs, bisphosphonates, work by blocking the action of osteoclasts, PEPITEM acts by swinging the balance in favour of bone formation, without impacting the ability of osteoclasts to resorb regions of damaged or weak bone tissue via normal bone remodelling.
The research was funded by major grants from the Medical Research Council and the Lorna and Yuti Chernajovsky Biomedical Research Foundation, which funds pioneering research into the creation of new targeted medicines to improve health. Other funders included the British Society for Research on Ageing, and Versus Arthritis.
Bone is constantly formed, reformed, and remodelled throughout life, and up to 10% of human bone is replaced annually through a complex interplay between two cell types – osteoblasts, which form bone, and osteoclasts, which breakdown bone. Disturbances to this tightly orchestrated process are responsible for features of diseases such as osteoporosis and rheumatoid arthritis, which show excessive bone breakdown, or ankylosing spondylitis, where abnormal bone growth occurs.
The most commonly used osteoporosis therapies (bisphosphonates) target osteoclasts to prevent further bone loss. Although there are new ‘anabolic’ agents that can promote new bone formation, these have limitations in their clinical use, with teriparatide (parathyroid hormone, or PTH) only being effective for 24 months and romosozumab (anti-sclerostin antibody) being associated with cardiovascular events.
Therefore, there is a clear case for developing new therapies to stimulate bone repair in age-related musculoskeletal diseases, of which osteoporosis is the most common. Researchers led by Dr Helen McGettrick and Dr Amy Naylor, including Dr Jonathan Lewis and Ms Kathryn Frost, from the Institute of Inflammation and Ageing at the University of Birmingham and Dr James Edwards from Nuffield Department of Orthopaedics, Rheumatology and Musculoskeletal Sciences at the University of Oxford set out to investigate the potential therapeutic impact of PEPITEM in these disease states.
PEPITEM is a naturally occurring short protein (peptide) produced in the body and found circulating in everyone at low levels.
The research findings demonstrated that PEPITEM regulates bone remodelling and that increasing the amount present in the body stimulates bone mineralisation in ‘young bones’ that are not in a diseased or pre-osteoporotic state, and that this translates to an increase in bone strength and density similar to current standard of care drugs (bisphosphonates and PTH).
However, the key test for a potential new therapeutic is its ability to target the natural repair process that is compromised by age, or inflammatory disease. Here the researchers showed that giving additional PEPITEM limits bone loss and improves bone density in animal models of the menopause, which is a common trigger for osteoporotic bone loss in humans. Their studies also showed similar findings in models of inflammatory bone disease (arthritis), where PEPITEM significantly reduced bone damage and erosion.
These findings were underscored by studies using human bone tissue, harvested from older patients during joint surgery. These studies showed cells from older individuals respond to PEPITEM, significantly increasing the maturation of osteoblasts, and their ability to produce and mineralise bone tissues.
Their cell and tissue culture work showed PEPITEM has a direct effect on osteoblasts to promote bone formation, by increasing the activity of osteoblasts rather than their number. Further studies identified the NCAM-1 receptor as the specific receptor for PEPITEM on osteoblasts, and strongly suggested the NCAM-1- b-catenin signalling pathway is responsible for the upregulation of osteoblast activity. This receptor, and the pathway, are distinct from PEPITEM receptors that have been previously described in other tissues.
The researchers also investigated PEPITEM’s effect on osteoclasts and bone resorption. Here, mouse studies showed PEPITEM significantly reduces the number of osteoclasts, leading to reduced bone mineral resorption. The researchers subsequently demonstrated that the reduction in osteoclast activity is the result of a soluble substance released locally in bone tissues by osteoblasts ‘activated’ by PEPITEM.
Dr Helen McGettrick said: “While the most commonly used drugs, bisphosphonates, work by blocking the action of osteoclasts, PEPITEM acts by swinging the balance in favour of bone formation, without impacting the ability of osteoclasts to resorb regions of damaged or weak bone tissue via normal bone remodelling.”
Helen Dunster, the Business Development Manager who has curated the intellectual property associated with PEPITEM for the last 8 years says: “PEPITEM is the subject of a number of patent families relating to its activity in inflammation and inflammatory immune-mediated, bone and obesity related diseases, and also comprising of smaller PEPITEM pharmacophores. A US patent application (US18488234) covering the use of PEPITEM in the treatment or prevention of bone disease, has a priority filing date of 8/10/2019.”
Therapeutic avenues in bone repair: Harnessing an anabolic osteopeptide (PEPITEM) to boost bone growth and prevent bone loss is published in Cell Reports Medicine and available at DOI: 10.1016/j.xcrm.2024.101574.
For media information contact Ruth Ashton, University of Birmingham Enterprise, email: r.c.ashton@bham.ac.uk
For commercial enquiries contact Helen Dunster, University of Birmingham Enterprise, email: h.dunster@bham.ac.uk
About the University of Birmingham
The University of Birmingham is ranked amongst the world’s top 100 institutions, and its work brings people from across the world to Birmingham, including researchers and teachers and more than 6,500 international students from nearly 150 countries.
University of Birmingham Enterprise helps researchers turn their ideas into new services, products and enterprises that meet real-world needs. We also provide incubation, and support innovators and entrepreneurs with mentoring, advice, and training, manage the University’s Academic Consultancy Service, and University of Birmingham Enterprise Operating Divisions.
About the Nuffield Department of Orthopaedics, Rheumatology and Musculoskeletal Sciences (NDORMS)
The Nuffield Department of Orthopaedics, Rheumatology and Musculoskeletal Sciences (NDORMS) is a multi-disciplinary department focusing on discovering the causes of musculoskeletal and inflammatory conditions to deliver excellent and innovative care that improves people’s quality of life. The largest European academic department in its field, NDORMS is part of the Medical Sciences Division of the University of Oxford, and is a rapidly growing community of more than 500 orthopaedic surgeons, rheumatologists and scientists all working in the field of musculoskeletal disorders.
The research work of the department takes place in several locations across the Nuffield Orthopaedic Centre, namely the Botnar Institute for Musculoskeletal Sciences, the Kennedy Institute of Rheumatology, and the Kadoorie Centre. The co-location with NHS services puts the department in an excellent position with basic researchers working alongside clinicians. This substantially improves research capacity, improving access for researchers to patients, and facilitating the interaction between clinicians and scientists that is essential for successful medical research.
About the Lorna and Yuti Chernajovsky Biomedical Research Foundation
The Lorna and Yuti Chernajovsky Biomedical Research Foundation was set up in 2019 to improve public health by providing grants to support high-quality biomedical research into the development of new targeted biomedical therapies. The Foundation’s income and assets result from royalties from beta-interferon. The Foundation aims to improve public health by providing grants to support high-quality biomedical research into the development of new targeted biomedical therapies in the fields of autoimmunity, inflammation, infectious diseases, and ageing.
About the Medical Research Council
The Medical Research Council is at the forefront of scientific discovery to improve human health. Founded in 1913 to tackle tuberculosis, the MRC now invests taxpayers’ money in some of the best medical research in the world across every area of health. Thirty-three MRC-funded researchers have won Nobel prizes in a wide range of disciplines, and MRC scientists have been behind such diverse discoveries as vitamins, the structure of DNA and the link between smoking and cancer, as well as achievements such as pioneering the use of randomised controlled trials, the invention of MRI scanning, and the development of a group of antibodies used in the making of some of the most successful drugs ever developed. Today, MRC-funded scientists tackle some of the greatest health problems facing humanity in the 21st century, from the rising tide of chronic diseases associated with ageing to the threats posed by rapidly mutating micro-organisms. The Medical Research Council is part of UK Research and Innovation.
About the British Society for Research on Ageing
The British Society for Research on Ageing (BSRA) is a scientific society, formed in 1939, to promote and support research into the biology of ageing. The society brings together researchers and students studying ageing with events, network building, and annual meetings. The BSRA provides its eminent and decorated membership with a platform, and advocates for the importance and impact of research and understanding of ageing biology, and fund research with the ultimate goal of slowing the progress of ageing.
About Versus Arthritis
Versus Arthritis is the UK’s largest arthritis charity. Over 10 million people in the UK have arthritis - that’s one in six living with the pain, fatigue, and disability it can cause. The impact of arthritis can be huge, affecting the ability to work, care for family, move free from pain and live independently. Together with researchers, healthcare professionals, policymakers, supporters and volunteers, Versus Arthritis works tirelessly to make sure everyone with arthritis has access to the treatments and support they need to live the life they choose, with real hope of a cure in the future.
The State of Musculoskeletal Health - a collection of the most up-to-date, UK-wide statistics on arthritis and other musculoskeletal (MSK) conditions by Versus Arthritis. The State of Musculoskeletal Health (versusarthritis.org)
Staff profile for Professor Helen McGettrick, Professor of Inflammation and Vascular Biology, Department of Inflammation and Ageing, College of Medicine and Health, the University of Birmingham
Staff profile for Dr Amy Naylor, Research Fellow in the Department of Inflammation and Ageing, College of Medicine and Health.