New Muscle Disease Indication for ATL1102 – Limb Girdle Muscular Dystrophy R2
22 June 2022 - 11:15PM
Antisense Therapeutics Limited [ASX:ANP | US OTC:ATHJY | FSE:AWY]
today announced the results from a first study of antisense to
CD49d in a limb girdle muscular dystrophy R2 (LGMDR2) mouse model.
LGMDR2 is a rare genetic muscle disease that is caused by mutations
in the dysferlin gene that leads to significant reduction or
absence of dysferlin protein levels in muscle fibers. Dysferlin
loss occurs in both males and females with the condition called
dysferlinopathy or LGMDR2. LGMDR2 is characterized by muscle
inflammation, fibrosis, adiposity (fat) and progressive weakness in
the hip and shoulder area (i.e. the limb girdle) proximal muscles
(those closest to the center of the body) with loss of ambulation
and upper limb function in adulthood. LGMDR2 affects ~ 1 in 125,000
people.1,2,3 There are no disease modifying agents in advanced
development and no treatments have proven to be beneficial to slow
the progression of the disease.
This first study of antisense to CD49d in the
LGMDR2 mouse model (Bla/J mice with dysferlin loss) was undertaken
in collaboration with experts in genetic muscle disease at the
Murdoch Children’s Research Institute (MCRI) in Melbourne and the
Jain Foundation in the USA. The Jain Foundation
(https://www.jain-foundation.org/), a non-profit disease foundation
established in the hopes of curing dysferlinopathy, is coordinating
the worldwide efforts to find a treatment for dysferlinopathy and
have substantial experience with LGMDR2.
In the study, Bla/J mice were treated with an
antisense oligonucleotide (ASO) to CD49d at three dose levels (5,
10 and 20mg/kg) once weekly for six weeks, with a corresponding
negative control oligonucleotide at the same dose levels. The study
also included untreated Bla/J mice and healthy mice as controls.
The results showed that at the low 5mg/kg/week ASO dose, the RNA
levels of CD49d, and CD8 T cells and F4/80 macrophage cells in the
quadricep muscle were significantly decreased by 42%, 86% and 70%
respectively, compared to the levels observed in the mice dosed at
the 5mg/kg/week dose level of the control oligonucleotide
(P<0.05 Fisher’s Least Significant difference test). A
significant reduction in CD8 RNA vs the untreated control Bla/J was
also observed (see Figure 1 below).
Notably, in the quadricep muscle of the female
untreated control mice, there was 2.5 times more F4/80 RNA than
male mice (data on file). F4/80 is a marker of macrophages which
are key immune cells involved in the disease and the increase in
these cells is suggestive of a more active disease in the female
mice. ASO treatment in female mice achieved significant reduction
in F4/80 and CD8 cell mRNA in the quadricep muscle. In these same
female mice, a trend towards reduction of 38% (P=0.0656) in CD49d
RNA was observed compared to untreated Bla/J in another proximal
muscle called the Psoas (see Figure 2 below). Given these
observations the next study will be conducted in the female mice as
agreed with the experts at the Jain Foundation.
The results from this first investigation of the
potential of an antisense to CD49d drug in the Bla/J dysferlin
deficient mouse model have shown the use of a low dose of the drug
reduces the target (CD49d) and key immune cell (F4/80 macrophage
and CD8+ T cells) RNA in the muscle. The results support the
Company’s plans to move forward with the second phase (chronic
setting) of the program with a follow on study in the same mouse
model to test the potential of the low dose to reduce adipose (fat)
levels, muscle loss and damage. The second study is planned for
3Q/4QCY22 (pending the availability of suitably aged mice) and
designed to run for four months, with results to follow shortly
thereafter.
The use of ATL1102 as a treatment for
dysferlinopathy is covered in ANP’s patent application
PCTAU2020/050445 directed at modifying muscle performance by
reducing muscle adiposity. The recently filed provisional
application 2021903024 also claims the use of ATL1102 to reduce
thrombospondin-1 reported to be beneficial in treating the disease.
The data from Bla/J mice studies can be used to support the
prosecution of these claims and the filing of a new patent
application.
Dr George Tachas Ph.D., Director,
Drug Discovery and Patents at Antisense Therapeutics
said “We are pleased to be continuing our key scientific
collaboration with the MCRI while also benefiting from the expert
advice provided by the Jain Foundation. The positive results from
this first study in dysferlin deficient mice encourage us to move
into the chronic phase of the program and we look forward with
great anticipation to the results of this follow on study. There
are several genetic muscle diseases with similar immune cell
involvement like in LGMDR2 and DMD and so this data points to the
potential use of low dose of ATL1102 as a treatment for such
conditions.”
Laura
Rufibach, Co-President of the
Jain Foundation, said
“With a singularly focused mission to find a cure for
dysferlinopathy, we at the Jain Foundation are pleased to be
working with Antisense Therapeutics and the MCRI on their research
program evaluating the antisense to CD49d drug as a possible
treatment of dysferlinopathy. We are encouraged by the results of
the first study and look forward to the data of the longer dosing
study to assess the efficacy of the treatment in mice in order to
determine the potential of ATL1102 to be an effective therapy in
this devastating and debilitating disease.”
Associate Professor Alastair Corbett,
Neurologist at the Concord Repatriation General Hospital Neurology
Clinic, said “LGMDR2 is a rare recessive muscular
dystrophy with no effective treatment. The disease starts in late
adolescence and patients show signs of muscle weakness at 15-30
years of age and it progresses slowly as people live into adult
life. Patients exhibit weakness of the shoulder and hip muscles
which adversely effects their upper and lower limb function.
Sufferers of the disease struggle with mobility with a significant
loss of quality of life and ultimately lose ambulation as they
become wheelchair bound. Many muscle dystrophies with significant
inflammation are in need of more effective therapies. I am very
pleased to be involved with the hope that such endeavors may help a
population in great need of an effective treatment.”
This announcement has been authorised for
release by the Board.
For more information please contact:
Antisense Therapeutics |
Investment Enquiries |
US/European IR & Media |
Mark
Diamond |
Gennadi
Koutchin |
Laine
Yonker/Joe Green |
Managing
Director and CEO |
XEC
Partners |
Edison
Investor Relations |
+61 (0)3
9827 8999 |
gkoutchin@xecpartners.com.au |
lyonker@edisongroup.com |
www.antisense.com.au |
1300 932
037 |
+1
646-653-7035 |
About Limb Girdle Muscular Dystrophy
R2 caused by the genetic loss of
dysferlin.
Limb-girdle muscular dystrophy (LGMD) is a group
of rare muscular dystrophies primarily characterized by hip and
shoulder (i.e. limb-girdle) proximal muscle weakness estimated to
occur as a class in up to 6.9 in every 100,000 people5. Over 30
subtypes have been identified with different underlying genetic
causes. Dysferlin loss occurs in the recessive genetic muscle
disorder LGMDR2, formerly known as LGMD2B, and the related muscle
disease Miyoshi myopathy dystrophy 1 (MMD1)6 . Collectively these
disorders caused by the loss of dysferlin are called
Dysferlinopathy 1. Dysferlinopathy (LGMDR2) prevalence is
approximately ~ 1 per 125,000 people3 or 2500 people in the US, or
18% of all LGMDs4 with an estimated upper range for LGMDR2 of ~
4000 people in the US.
In LGMDR2, the initial weakness is seen in the
proximal muscles and in the case of MMD1 there is initially distal
muscle weakness. However, natural history data on dysferlinopathy
have shown that LGMDR2 and MMD1 are the same disease6. Dysferlin is
a transmembrane protein that has been shown to be involved in
multiple cellular processes such as calcium regulation, membrane
repair, and membrane trafficking. The absence of dysferlin in
LGMDR2 is characterized by activated F4/80 macrophage and T cell
inflammation and increase in fat replacing the muscle, where
adipocytes replace dysferlin deficient muscle, as detected by MRI.
This progressively reduces muscle strength, ability to walk,
reduces upper limb function and quality of life.5 There are
currently no treatments for dysferlinopathy. The steroid drug
deflazacort treatment failed in a 6 month patient study and made
the disease worse. Deflazacort (1mg) taken for a month, every
second day for 5 months reduced muscle strength, which reversed
after cessation of steroid treatment7. There is an unmet need for
effective therapies so that people with LGMDR2 can maintain
ambulation, muscle strength and quality of life.
References
- https://www.jain-foundation.org/
-
https://www.jain-foundation.org/research/dysferlin-background/therapeutic-opportunities/
- Liu W et al Genetics in Medicine 21 2512-2520 (2019) Estimates
0.75 per 100000
https://www.nature.com/articles/s41436-019-0544-8
- Moore et al J Neuropathol Exp. Neurol 2006 65(10):
995-1003 https://academic.oup.com/jnen/article/65/10/995/2646712
-
https://rarediseases.org/rare-diseases/limb-girdle-muscular-dystrophies/
- https://pubmed.ncbi.nlm.nih.gov/33610434/
- https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3617000/
The study results in the psoas muscles above
suggest target CD49d RNA knockdown when CD8+ and F4/80+ cells
remain in the female psoas muscle. In the quadricep muscles the
target CD49d knockdown is less visible as the CD8+ and F4/80+ cells
that express CD49d are substantially reduced (by 86% and 70%
respectively) so there are less cells remaining to observe a
statistically significant reduction versus untreated control
mice.
Australian Whisky (ASX:AWY)
Historical Stock Chart
From Nov 2024 to Dec 2024
Australian Whisky (ASX:AWY)
Historical Stock Chart
From Dec 2023 to Dec 2024