Taysha Gene Therapies Announces Publication of Positive Preclinical Data for TSHA-104 Demonstrating Therapeutic Potential in SURF1-associated Leigh Syndrome in Journal Molecular Therapy: Methods & Clinical Development
Taysha Gene Therapies has published promising preclinical data for TSHA-104, a gene therapy targeting SURF1-associated Leigh syndrome. The study, featured in Molecular Therapy: Methods & Clinical Development, shows that TSHA-104 can restore normal blood lactate levels and enhance COX1 activity in a dose-dependent manner in SURF1 knockout mice. No toxicity or severe tissue damage was observed. Notably, there are currently no approved therapies for this condition, highlighting the significance of TSHA-104's potential.
- TSHA-104 restored normal blood lactate levels in SURF1 knockout mice.
- The therapy increased COX1 activity in brain and muscle in a dose-dependent manner.
- No toxicity or severe tissue damage was observed in preclinical studies.
- TSHA-104 is positioned as a potential treatment for a disease with no approved therapies.
- Combination of intrathecal and intravenous delivery showed no additional benefits.
TSHA-104 restored to normal levels elevation of blood lactate on exhaustive exercise in dose-dependent manner in SURF1 knockout mice
TSHA-104 increased COX1 activity in brain and muscle in dose-dependent manner in SURF1 knockout mice
Combination of intrathecal and intravenous delivery did not prove benefit over intrathecal alone
No associated toxicity risks or severe tissue damage were seen
There are no approved treatments for the underlying cause of the disease and the burden of disease and risk of mortality are high
SURF1 deficiency is a monogenic mitochondrial disorder that is the most common cause of cytochrome c oxidase deficient Leigh syndrome, a rapidly progressive neurological disorder that leads to degeneration of the CNS. Leigh syndrome typically presents in the first year of life and is characterized by progressive loss of mental and movement abilities that can result in death in early childhood. Approximately 10
“SURF1 is part of cytochrome c oxidase, a mitochondrial enzyme known as COX involved in the metabolic production of ATP. Children with SURF1 deficiency have severely impaired COX activity and cannot generate ATP by aerobic respiration appropriately. This disruption in overall energy metabolism increases anaerobic respiration, leading to elevated levels of lactate and the clinical phenotype of Leigh syndrome,” said
RA Session II, President, Founder and CEO of Taysha, added, “In the mouse model, we are seeing expression of SURF1 in the brain and spinal cord at levels sufficient to effectively restore COX activity in the brain, liver and muscle with one intrathecal administration of TSHA-104. We are encouraged by the ability of TSHA-104 to diminish exhaustive exercise-induced lactic acidosis, supporting intact mitochondrial function under states of stress in these preclinical models. This proof-of-concept study indicates TSHA-104 is safe and effective in rescuing metabolic dysfunction in preclinical models of SURF1 deficiency.”
A one-time intrathecal injection of TSHA-104 resulted in codon-optimized human SURF1 expression in multiple relevant brain and spinal cord regions in SURF1 knockout mice. A combination of intrathecal and intravenous delivery did not provide any benefit over intrathecal delivery alone, supporting continued use of intrathecal administration. TSHA-104 increased mitochondrially encoded cytochrome c oxidase 1 (MT-CO1) abundance four weeks post-injection in the CNS and peripheral tissues and increased COX1 activity in brain and muscle in a dose-dependent manner. Biochemical COX activity correlated with histological COX content level, supporting regional COX activity. Following exhaustive exercise-induced lactic acidosis TSHA-104 was able to rescue elevated lactate levels in SURF1 knockout mice dose-dependently. The safety profile assessed by non-GLP (Good Laboratory Practice) evaluation in wild-type mice using a similar dosing regimen determined no associated toxicity risks or severe tissue damage detected up to one year post-injection. Collectively this proof-of-concept study demonstrates TSHA-104 can safely and sufficiently rescue mitochondrial dysfunction in SURF1 knockout mice, supporting further translational development for the treatment of SURF1-associated Leigh syndrome.
TSHA-104 is an AAV9-based gene replacement therapy encoding the human SURF1 protein that is administered intrathecally for the treatment of SURF1-associated Leigh syndrome. TSHA-104 has been granted Orphan Drug and Rare Pediatric Disease designations by the FDA.
About
Forward-Looking Statements
This press release contains forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995. Words such as “anticipates,” “believes,” “expects,” “intends,” “projects,” and “future” or similar expressions are intended to identify forward-looking statements. Forward-looking statements include statements concerning the potential of our product candidates, including TSHA-104, to positively impact quality of life and alter the course of disease in the patients we seek to treat, our research, development and regulatory plans for our product candidates, TSHA-104’s eligibility for accelerated approval in
View source version on businesswire.com: https://www.businesswire.com/news/home/20210915005357/en/
Company Contact:
SVP, Corporate Communications and Investor Relations
klee@tayshagtx.com
Media Contact:
carolyn.hawley@canalecomm.com
Source:
FAQ
What are the results of the TSHA-104 study in SURF1 knockout mice?
What disease does TSHA-104 target?
What was the safety profile of TSHA-104 in the study?
How is TSHA-104 administered?