Phase I/II clinical trial evaluating AAV-mediated gene therapy for a severe paediatric metabolic liver disease: Ornithine Transcarbamylase deficiency
Lead Research Organisation:
University College London
Department Name: Institute of Child Health
Abstract
Ornithine transcarbamylase deficiency (OTCD) is a rare X-linked genetic disorder characterized by complete or partial lack of the enzyme ornithine transcarbamylase (OTC). OTC is a key element of the urea cycle, whereby the liver breaks down and removes surplus nitrogen from the body. OTCD patients accumulate nitrogen in the form of excess ammonia (hyperammonemia) in the blood. Ammonia is toxic and patients suffer 'hyperammonaemic decompensations' with symptoms including vomiting, impaired voluntary movement, and progressive lethargy. If left untreated these may progress to coma and life-threatening complications.
Symptoms present within a few days of birth of males with severe OTCD. As well as significant risk of mortality, the neurotoxic effects of excess ammonia result in longer-term neurological abnormalities such as intellectual disability, developmental delays, and cerebral palsy. As with milder forms of this disease (which may present later in both male and female children and adults), infants are managed with ammonia-scavenging drugs and dietary intervention, however hyperammonaemic decompensations still occur.
Neonatal-onset OTCD patients require liver transplantation (LT) for long-term survival. Whilst LT can be life-saving, opportunity for this intervention remains limited and not without risk of mortality and morbidity. Advances have been made in surgical practices to facilitate access to donor liver tissue, including 'living-donor partial liver grafts' and 'reduced-liver transplantation' whereby infants and children receive a portion of an adult liver. However, both the patient and their family still remain with the challenge of life-long immunosuppression and medical follow-up. European guidelines recommend LT for those patients with severe phenotype, aged between 3 and 12 months as neonatal transplant in such metabolically unstable patients is considered too great a risk. Of 15 paediatric OTCD patients transplanted in the UK this past decade, there were only 4 of this age. All others were over 3 years old and all had long-term neurological impairment.
We have developed an Adeno associated virus (AAV)-based gene therapy (AAV-LK03-OTC) to specifically target the liver and restore functional expression of OTC. Our approach encompasses the single administration of gene therapy to OTCD infants to provide immediate normalisation of liver metabolism, thereby reducing acute risk of mortality from hyperammonaemic decompensations. Such treatment would serve as a 'bridge-to-transplant' enabling paediatric patients to continue to grow in a metabolically stable condition until such time that transplantation is possible, also minimising longer-term neurological morbidity associated with hyperammonaemia.
Our laboratory experiments have demonstrated the enhanced ability of AAV-LK03-OTC to target liver cells over other AAV, and to elicit elevated expression of functional OTC. We have demonstrated that AAV-LK03-OTC restores liver function in experimental mouse models of this genetic disease and are currently testing the safety of AAV-LK03-OTC in animal studies. Recent success with other viral gene therapies advanced to early clinical trials (e.g. AAV8 for Haemophilia B) and the increased targeting to liver cells (AAV-LK03 >10-fold more transformation of liver cells than AAV8) reinforce confidence in this approach as being safe.
We will now translate our pre-clinical findings to conduct a Phase I/II dose-finding clinical trial assessing the safety and efficacy of AAV-LK03-OTC. As children are the OTCD population with greatest unmet need, we aim to recruit 12 paediatric patients in the UK to provide early clinical data for later stage development and commercialisation of this transformative advanced therapy. This project aims to deliver a step-change in the clinical management of paediatric OTCD patients and provide critical gene therapy evidence applicable to many other liver-inherited metabolic diseases.
Symptoms present within a few days of birth of males with severe OTCD. As well as significant risk of mortality, the neurotoxic effects of excess ammonia result in longer-term neurological abnormalities such as intellectual disability, developmental delays, and cerebral palsy. As with milder forms of this disease (which may present later in both male and female children and adults), infants are managed with ammonia-scavenging drugs and dietary intervention, however hyperammonaemic decompensations still occur.
Neonatal-onset OTCD patients require liver transplantation (LT) for long-term survival. Whilst LT can be life-saving, opportunity for this intervention remains limited and not without risk of mortality and morbidity. Advances have been made in surgical practices to facilitate access to donor liver tissue, including 'living-donor partial liver grafts' and 'reduced-liver transplantation' whereby infants and children receive a portion of an adult liver. However, both the patient and their family still remain with the challenge of life-long immunosuppression and medical follow-up. European guidelines recommend LT for those patients with severe phenotype, aged between 3 and 12 months as neonatal transplant in such metabolically unstable patients is considered too great a risk. Of 15 paediatric OTCD patients transplanted in the UK this past decade, there were only 4 of this age. All others were over 3 years old and all had long-term neurological impairment.
We have developed an Adeno associated virus (AAV)-based gene therapy (AAV-LK03-OTC) to specifically target the liver and restore functional expression of OTC. Our approach encompasses the single administration of gene therapy to OTCD infants to provide immediate normalisation of liver metabolism, thereby reducing acute risk of mortality from hyperammonaemic decompensations. Such treatment would serve as a 'bridge-to-transplant' enabling paediatric patients to continue to grow in a metabolically stable condition until such time that transplantation is possible, also minimising longer-term neurological morbidity associated with hyperammonaemia.
Our laboratory experiments have demonstrated the enhanced ability of AAV-LK03-OTC to target liver cells over other AAV, and to elicit elevated expression of functional OTC. We have demonstrated that AAV-LK03-OTC restores liver function in experimental mouse models of this genetic disease and are currently testing the safety of AAV-LK03-OTC in animal studies. Recent success with other viral gene therapies advanced to early clinical trials (e.g. AAV8 for Haemophilia B) and the increased targeting to liver cells (AAV-LK03 >10-fold more transformation of liver cells than AAV8) reinforce confidence in this approach as being safe.
We will now translate our pre-clinical findings to conduct a Phase I/II dose-finding clinical trial assessing the safety and efficacy of AAV-LK03-OTC. As children are the OTCD population with greatest unmet need, we aim to recruit 12 paediatric patients in the UK to provide early clinical data for later stage development and commercialisation of this transformative advanced therapy. This project aims to deliver a step-change in the clinical management of paediatric OTCD patients and provide critical gene therapy evidence applicable to many other liver-inherited metabolic diseases.
Technical Summary
The urea cycle is an essential pathway in the liver for the detoxification of ammonia, produced by the breakdown of proteins. Urea cycle defects (UCD) have high rates of mortality and morbidity. Ornithine Transcarbamylase deficiency (OTCD) is the most common inherited UCD (60% total) and in severe cases, symptoms present early in newborns progressing to coma and death if untreated. Patients are managed with ammonia-scavenging drugs and dietary intervention, however acute hyperammonaemic decompensations still occur with significant mortality and compromised neurological development.
Paediatric OTCD patients require liver transplant for long-term survival, curing UCD but itself carrying significant risk and need for lifelong immunosuppression. We have developed an Adeno-associated viral-based gene therapy (AAV-LK03-OTC) to specifically target the liver and restore functional expression of Ornithine Transcarbamylase. Our approach of single administration of viral gene therapy provides immediate normalisation of liver metabolism thereby reducing risk of both acute mortality and longer-term neurological morbidity thus protecting neonatal patients waiting to undergo liver transplant.
We are testing the safety of AAV-LK03-OTC in studies in animal studies. Recent success of other viral gene therapies advanced to early clinical trials (e.g. AAV8 for Haemophilia B) and the increased targeting to liver cells (AAV-LK03 >10-fold more transformation of hepatocytes than AAV8) reinforce the potential of this approach as a safe and effective therapy. We will now translate our pre-clinical findings to conduct a Phase I/II dose-finding clinical trial assessing the safety and efficacy of AAV-LK03-OTC. As children are the OTCD population with greatest unmet need, we will recruit 12 paediatric patients in the UK to provide early clinical data for later stage development and commercialisation of this transformative advanced therapy.
Paediatric OTCD patients require liver transplant for long-term survival, curing UCD but itself carrying significant risk and need for lifelong immunosuppression. We have developed an Adeno-associated viral-based gene therapy (AAV-LK03-OTC) to specifically target the liver and restore functional expression of Ornithine Transcarbamylase. Our approach of single administration of viral gene therapy provides immediate normalisation of liver metabolism thereby reducing risk of both acute mortality and longer-term neurological morbidity thus protecting neonatal patients waiting to undergo liver transplant.
We are testing the safety of AAV-LK03-OTC in studies in animal studies. Recent success of other viral gene therapies advanced to early clinical trials (e.g. AAV8 for Haemophilia B) and the increased targeting to liver cells (AAV-LK03 >10-fold more transformation of hepatocytes than AAV8) reinforce the potential of this approach as a safe and effective therapy. We will now translate our pre-clinical findings to conduct a Phase I/II dose-finding clinical trial assessing the safety and efficacy of AAV-LK03-OTC. As children are the OTCD population with greatest unmet need, we will recruit 12 paediatric patients in the UK to provide early clinical data for later stage development and commercialisation of this transformative advanced therapy.
Planned Impact
This work aims to progress a new gene therapy treatment for children with an inherited metabolic disease of the liver (termed OTCD). New born patients with the disease are at high risk of mortality and suffer long-term neurological complications. Liver transplantation is the only current cure for this disease, however this option requires the children to grow and stabilise sufficiently (typically to over 3 years old in the UK), worsening the risk of life-threatening symptoms and long-term neurological impairment.
We have developed a liver-targeting viral gene therapy for OTCD which we aim to test for safety and efficacy initially in older children (i.e. 6-16 year old), before treating neonatal patients. This project represents the next step to address the unmet clinical need for a 'bridge-to-transplant' for paediatric OTCD patients, providing a transformative change to the clinical care and outcomes for these children, as well as providing critical gene therapy evidence applicable to many other liver-inherited metabolic diseases.
We have developed a liver-targeting viral gene therapy for OTCD which we aim to test for safety and efficacy initially in older children (i.e. 6-16 year old), before treating neonatal patients. This project represents the next step to address the unmet clinical need for a 'bridge-to-transplant' for paediatric OTCD patients, providing a transformative change to the clinical care and outcomes for these children, as well as providing critical gene therapy evidence applicable to many other liver-inherited metabolic diseases.
Organisations
- University College London (Lead Research Organisation)
- Children's Hospital of Philadelphia (Collaboration)
- UNIVERSITY OF SYDNEY (Collaboration)
- JG Zebra Consulting Ltd (Project Partner)
- University of Manchester (Project Partner)
- Children Living with Inherited Metabolic Diseases (Project Partner)
- Enabling Research (Project Partner)
- Birmingham Children's Hospital (Project Partner)
- Guy's and St Thomas' NHS Foundation Trust (Project Partner)
Publications
Perocheau DP
(2019)
Age-Related Seroprevalence of Antibodies Against AAV-LK03 in a UK Population Cohort.
in Human gene therapy
Thompson DA
(2021)
An ERG and OCT study of neuronal ceroid lipofuscinosis CLN2 Battens retinopathy.
in Eye (London, England)
Lorvellec M
(2020)
An In Vitro Whole-Organ Liver Engineering for Testing of Genetic Therapies.
in iScience
Baruteau J
(2019)
Argininosuccinic aciduria: Recent pathophysiological insights and therapeutic prospects.
in Journal of inherited metabolic disease
Cozmescu AC
(2021)
Gene therapies targeting the liver.
in Journal of hepatology
Massaro G
(2021)
Gene Therapy for Lysosomal Storage Disorders: Ongoing Studies and Clinical Development.
in Biomolecules
Seker Yilmaz B
(2023)
Genetic Therapy Approaches for Ornithine Transcarbamylase Deficiency.
in Biomedicines
Seker Yilmaz B
(2023)
Liver transplantation in ornithine transcarbamylase deficiency: A retrospective multicentre cohort study
in Molecular Genetics and Metabolism Reports
Jeyaraj R
(2021)
The Genetics of Inherited Cholestatic Disorders in Neonates and Infants: Evolving Challenges.
in Genes
Seker Yilmaz B
(2022)
Three-Country Snapshot of Ornithine Transcarbamylase Deficiency.
in Life (Basel, Switzerland)
Title | Innovations in gene therapy for the treatment of OTC deficiency |
Description | In collaboration with SciAni we created an animation that describes this project. It is posted on YouTube and targets general population. |
Type Of Art | Film/Video/Animation |
Year Produced | 2019 |
Impact | The movie has been seen by >1000 viewers. |
URL | https://www.youtube.com/watch?v=kdHEKXaLnps |
Description | Children's Hospital of Philadelphia |
Organisation | Children's Hospital of Philadelphia |
Country | United States |
Sector | Hospitals |
PI Contribution | This is a collaboration on gene therapy in OTC Deficiency. We provide the clinical trial expertise to this collaboration. |
Collaborator Contribution | The partners provide expertise in gene therapy vector generation. |
Impact | Partner contributes to the project on gene therapy in urea cycle disorders |
Start Year | 2017 |
Description | Sydney University, Australia |
Organisation | University of Sydney |
Department | Central Clinical School |
Country | Australia |
Sector | Hospitals |
PI Contribution | We are collaborating with Professor Alexander on the liver directed gene therapy project. We have a joint grant from the MRC DPFS where I am the PI and Prof Alexander is the co-PI. My group's contribution is the expertise in running clinical trial in rare paediatric diseases. |
Collaborator Contribution | Prof Alexander's group have the expertise in adeno associated vectors and specifically vector design for gene therapy in urea cycle disorders. |
Impact | 2 grants: NHMRC grant to Prof Alexander where I am a co-PI and the MRC DPFS grant currently. |
Start Year | 2014 |
Title | New award for a phase I/II clinical trial of AAV gene therapy in OTC |
Description | AAV based gene therapy for OTC deficiency |
Type | Therapeutic Intervention - Cellular and gene therapies |
Current Stage Of Development | Early clinical assessment |
Year Development Stage Completed | 2023 |
Development Status | Under active development/distribution |
Clinical Trial? | Yes |
Impact | Novel therapy for patients with high unmet need |
Description | Presentation at the Advanced Therapies Congress |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Professional Practitioners |
Results and Impact | Presentation at an international conference |
Year(s) Of Engagement Activity | 2023 |
URL | https://www.terrapinn.com/congress/advanced-therapies/index.stm |
Description | Presentation at the BioJapan conference |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Third sector organisations |
Results and Impact | A presentation to an international audience at BioJapan congress. |
Year(s) Of Engagement Activity | 2022 |
URL | https://jcd-expo.jp/en/global-lp.html |
Description | Workshop on Gene therapies in Inherited Metabolic Disorders for Metabolic Support UK patient organisation |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | National |
Primary Audience | Patients, carers and/or patient groups |
Results and Impact | With colleagues: Dr John Counsell, Dr Julien Baruteau, Prof Nick Greene and Prof Simon Waddington we engaged with Metabolic Support UK in order to organise a 2 hour webinar-style workshop on gene therapies for metabolic disorders. The webinar was well attended by the families and a small number of health professionals. |
Year(s) Of Engagement Activity | 2020 |
URL | https://www.metabolicsupportuk.org/gene-therapy-webinar/ |