Rna Targeting Therapy For Neurodegeneration is an important component in the neurobiology of neurodegenerative diseases. This page provides detailed information about its structure, function, and role in disease processes.
RNA targeting therapy encompasses a range of approaches to modulate gene expression at the RNA level, including antisense oligonucleotides (ASOs), RNA interference (RNAi), and small molecule RNA modulators. These therapies can reduce toxic protein expression, correct splicing defects, and restore normal gene function in neurodegenerative diseases.
'''RNA Targeting Therapy for Neurodegenerative Diseases''' leverages advances in RNA biology to modulate gene expression, reduce toxic protein levels, and correct disease-causing mutations. This page covers antisense oligonucleotides, RNA interference, small molecule modulators, and their applications in neurodegenerative disease treatment.
{| class="infobox"
|-
! colspan="2" style="background:#e8f4ea;font-size:120%;" | RNA Targeting Therapy
|-
| '''Category''' || Therapeutic Intervention
|-
| '''Target Conditions''' || ALS, HD, AD, PD, SMA, Ataxias
|-
| '''Mechanism''' || ASO, siRNA, miRNA, small molecules
|-
| '''Delivery Routes''' || Intrathecal, IV, Intranasal
|-
| '''Clinical Stage''' || Approved (SMA), Phase I-III
|-
| '''Key Successes''' || Spinraza, Teclesendan, Inotersen
|}
== Overview ==
RNA targeting therapies offer several advantages over traditional small molecule drugs:
- Can target "undruggable" proteins
- High specificity for target sequences
- Can modulate splice patterns
- Gene expression can be temporarily modulated
== Therapeutic Modalities ==
=== Antisense Oligonucleotides (ASOs) ===
Single-stranded DNA analogs that bind complementary RNA to:
- Promote RNA degradation
- Modulate splicing
- Block translation
- Alter miRNA function
Key Features:
- Chemical modifications (2'-O-methyl, phosphorodiamidate morpholino oligomers - PMOs, locked nucleic acids - LNAs)
- Gapmer design for RNase H recruitment
- Splicing-modulating ASOs
=== RNA Interference (RNAi) ===
Double-stranded RNA triggers sequence-specific mRNA cleavage:
- siRNA: Exogenously delivered 21-23 bp duplexes
- shRNA: Viral vector-expressed hairpin precursors
- miRNA mimics: Overexpress natural regulators
=== Small Molecule RNA Modulators ===
- RNA splice modulators (e.g., risdiplam for SMA)
- mRNA stabilizers/destabilizers
- Ribosome modulators
=== CRISPR RNA Editing ===
- Cas13 systems for RNA targeting
- Guide RNA delivery challenges
== Disease-Specific Applications ==
=== Amyotrophic Lateral Sclerosis (ALS) ===
SOD1 ASOs (BIIB067/tofersen)
- Targets SOD1 mutations (~20% of familial ALS)
- Reduces SOD1 protein in CSF
- Phase III completed, showed benefit in patients with faster progression
C9orf72 ASOs
- Targets hexanucleotide repeat expansions
- Reduces toxic RNA foci and dipeptide repeats
- Phase I/II ongoing
ATXN2 ASOs
- Targets intermediate polyQ expansions
- Modulates ALS risk
=== Spinal Muscular Atrophy (SMA) ===
Spinraza (nusinersen)
- Approved ASO modifying SMN2 splicing
- Increases functional SMN protein production
- Landmark success in CNS disease
Onasemnogene abeparvovec (Zolgensma)
- Gene therapy delivering SMN1
- Single-dose IV delivery
Risdiplam
- Small molecule splicing modifier
- Oral delivery
=== Huntington's Disease ===
ASOs targeting HTT
- Multiple programs in development
- Reduce mutant huntingtin protein
- Trials showed safety, efficacy signals
Allele-selective approaches
- Target mutant allele with SNP phasing
- Preserve wild-type function
=== Alzheimer's Disease ===
BACE1 ASOs
- Reduce BACE1 enzyme production
- Trials halted due to safety (cognitive worsening)
APOE ASOs
- Target APOE4 risk allele
- Reduce amyloid pathology
Tau ASOs
=== Parkinson's Disease ===
LRRK2 ASOs
- Target G2019S mutation
- Reduce LRRK2 kinase activity
Alpha-synuclein ASOs
- Reduce SNCA expression
- Prevent Lewy body formation
=== Ataxias ===
Ataxin-1 ASOs (SCN1A)
Ataxin-3 ASOs
- SCA3/MJD trials in preparation
Frataxin ASOs
- Friedreich's ataxia trials
== Clinical Trial Overview ==
{| class="wikitable"
|-
! Drug/Program
! Target
! Condition
! Stage
! Status
! PMID
|-
| Tofersen (BIIB067)
| SOD1
| ALS
| Phase III
| Approved
| 33218568 |
| Nusinersen |
| SMN2 |
| SMA |
| Approved |
| 27571880 |
| - |
| IONIS-HTTRx |
| HTT |
| HD |
| Phase I/II |
| Completed |
| 31785248 |
| - |
| BIIB080 |
| MAPT |
| AD |
| Phase I |
| Recruiting |
| — |
| - |
| WVE-004 |
| C9orf72 |
| ALS/FTD |
| Phase I/II |
| Recruiting |
| — |
| } |
The chemical backbone of ASOs significantly impacts their pharmacological properties. Modern ASOs employ several key modifications:
Sugar Modifications:
- 2'-O-methyl (2'-OMe): Increases nuclease resistance and binding affinity
- 2'-O-methoxyethyl (2'-MOE): Enhanced stability, improved tissue distribution
- Locked Nucleic Acid (LNA): Constrained ring increases binding affinity 2-5 fold
- Phosphorodiamidate Morpholino Oligomer (PMO): Neutral backbone, excellent nuclease resistance
Backbone Modifications:
- Phosphorothioate (PS): Interfers with nuclease degradation, enhances protein binding
- Phosphorodiamidate (PA): Neutral charge, reduces off-target effects
- 2'-4' constrained ethyl (cEt): High affinity, nuclease resistant
Conjugate Strategies:
- GalNAc conjugates: Target hepatic ASO delivery
- CPPs (Cell-Penetrating Peptides): Enhance cellular uptake
- Lipid conjugates: Improve membrane penetration
RNase H is an endonuclease that specifically cleaves RNA in RNA-DNA hybrids. The "gapmer" ASO design positions DNA residues in the central portion flanked by modified RNA residues. When the gapmer binds to target mRNA, the DNA:RNA hybrid recruits RNase H, which cleaves the RNA strand while leaving the ASO intact for additional catalytic cycles.
Key features of RNase H-dependent ASOs:
- Catalytic activity: Single ASO can cleave multiple mRNA molecules
- Nuclear and cytoplasmic activity
- Sequence-specific degradation
- No requirement for cellular machinery beyond RNase H
Splicing-modulating ASOs function through a distinct mechanism. Rather than recruiting RNase H, these ASOs sterically block splice sites, branch points, or exonic splicing enhancers (ESEs). This alters pre-mRNA processing to:
- Exclude specific exons (exon skipping)
- Include specific exons (exon inclusion)
- Alter splice site selection
- Restore normal splicing patterns
The landmark success of nusinersen (Spinraza) for SMA demonstrates this mechanism: it promotes inclusion of exon 7 in SMN2 pre-mRNA, increasing functional SMN protein production.
ALS is a rapidly progressive neurodegenerative disease affecting motor neurons. Several RNA-targeted approaches are in development:
SOD1 ASOs (BIIB067/tofersen)
- Targets SOD1 mutations (~20% of familial ALS)
- Reduces SOD1 protein in CSF by up to 40%
- Phase III completed, showed benefit in patients with faster progression
- FDA approved 2023
- Landmark approval validating ASO approach for CNS diseases
C9orf72 ASOs
- Targets hexanucleotide repeat expansions (most common genetic cause)
- Reduces toxic RNA foci and dipeptide repeat proteins
- Multiple programs in Phase I/II (WVE-004, BIIB078)
- Challenges: allele selectivity, repeat non-specific effects
ATXN2 ASOs
- Targets intermediate polyQ expansions
- Modulates ALS risk in SCA2/ALS spectrum
- Preclinical validation ongoing
FUS ASOs
- Target FUS mutations causing ALS
- Preclinical development stage
SMA results from SMN1 deficiency, with SMN2 as backup gene. Three distinct RNA-targeted approaches are approved:
Spinraza (nusinersen)
- Approved ASO modifying SMN2 splicing
- Increases functional SMN protein production by including exon 7
- Administered via intrathecal injection
- Landmark success demonstrating CNS efficacy
- Multiple clinical trials show significant benefit in infants and children
Onasemnogene abeparvovec (Zolgensma)
- Gene therapy delivering SMN1 under CMV promoter
- Single-dose IV delivery
- Transduces motor neurons via AAV9
- Approved for pediatric SMA
Risdiplam
- Small molecule splicing modifier
- Oral bioavailability
- Promotes SMN2 exon 7 inclusion
- Approved for all ages with SMA
- First oral RNA-targeted therapeutic
Evrysdi (risdiplam comparison)
- Alternative to ASO and gene therapy
- Wider distribution including CNS
- Ongoing trials in other indications
HD results from CAG repeat expansion in HTT gene, producing mutant huntingtin protein. RNA targeting offers disease modification:
ASOs targeting HTT
- Multiple programs (IONIS-HTTRx, others)
- Reduce both mutant and wild-type huntingtin
- Trials showed safety, efficacy signals
- Phase I/II completed
Allele-selective approaches
- Target mutant allele with SNP phasing
- Preserve wild-type function
- Reduce off-target effects
- Early clinical trials
miRNA-based approaches
- Artificial miRNAs targeting HTT
- Viral delivery for sustained effect
- Preclinical stage
BACE1 ASOs
- Reduce BACE1 enzyme production
- Reduced amyloid production in preclinical models
- Trials halted due to safety concerns (cognitive worsening)
- Important lesson: complete beta-amyloid reduction may be harmful
APOE ASOs
- Target APOE4 risk allele
- Reduce amyloid pathology
- May reduce tau pathology
- Early clinical development
Tau ASOs
- Reduce tau protein expression (see /therapeutics/tau-gene-therapy)
- Multiple clinical trials ongoing
- May combine with anti-amyloid therapy
LRRK2 ASOs
- Target G2019S mutation (most common genetic PD)
- Reduce LRRK2 kinase activity
- May modify disease progression
- Early clinical development
Alpha-synuclein ASOs
- Reduce SNCA expression
- Prevent Lewy body formation
- Critical for sporadic and genetic PD
- Phase I trials planned
GBA ASOs
- Target glucocerebrosidase variants
- Modulate alpha-synuclein clearance
- Early development
Ataxin-1 ASOs (SCN1A)
- SCA1 trials ongoing
- Reduce mutant ataxin-1 protein
Ataxin-3 ASOs
- SCA3/MJD trials in preparation
- Target polyQ-expanded ataxin-3
Frataxin ASOs
- Friedreich's ataxia trials
- Increase frataxin expression
Spinocerebellar ASOs
- Multiple programs targeting different SCA subtypes
- Personalized approach based on genetic subtype
| Drug/Program |
Target |
Condition |
Stage |
Status |
Key Endpoint |
| Tofersen (BIIB067) |
SOD1 |
ALS |
Phase III |
Approved |
CSF SOD1 reduction |
| Nusinersen |
SMN2 |
SMA |
Approved |
Marketed |
Motor function |
| IONIS-HTTRx |
HTT |
HD |
Phase I/II |
Completed |
Safety, HTT reduction |
| BIIB080 |
MAPT |
AD |
Phase I |
Recruiting |
CSF tau reduction |
| WVE-004 |
C9orf72 |
ALS/FTD |
Phase I/II |
Recruiting |
DPR reduction |
| BIIB067 |
SOD1 |
ALS |
Phase III |
Approved |
Functional endpoints |
¶ Delivery Challenges and Solutions
The BBB remains the primary challenge for CNS-directed RNA therapeutics:
Current Solutions:
- Intrathecal injection: Bypasses BBB via CSF distribution
- Convection-enhanced delivery: Direct brain infusion
- Focused ultrasound: Temporary BBB opening
Emerging Approaches:
- Intranasal delivery: Bypasses BBB via olfactory route
- Systemic delivery with brain-targeting conjugates
- AAV variants with enhanced CNS tropism
Even when reaching the brain, cellular uptake presents challenges:
- Endosomal trapping limits cytoplasmic delivery
- Lysosomal degradation of ASOs
- Limited distribution within neuron populations
- Requires high concentrations for efficacy
Solutions in Development:
- Peptide conjugates for endosomal escape
- Novel chemistry for improved cellular penetration
- Modified ASO backbones for enhanced uptake
- Trojan horse approaches using endogenous transport
Widespread CNS distribution is essential for neurodegenerative diseases:
- Diffusion is slow and limited
- Perivascular flow enables some distribution
- Regional variation in uptake
- White matter vs. gray matter penetration
Long-term treatment requires:
- Safety of repeated administration
- Immune response to viral vectors
- Accumulation of ASO chemistry
- Patient compliance with invasive delivery
¶ Regulatory Approvals and Pipeline
| Drug |
Company |
Indication |
Mechanism |
Year |
| Nusinersen (Spinraza) |
Biogen/Ionis |
SMA |
Splice modulation |
2016 |
| Inotersen (Tegsedi) |
Ionis/Accademia |
hATTR polyneuropathy |
RNase H |
2018 |
| Volanesorsen (Waylivra) |
Ionis |
FCS |
RNase H |
2019 |
| Tofersen (Qalsody) |
Biogen/Ionis |
SOD1 ALS |
RNase H |
2023 |
| Masiversen |
Biogen |
SMA |
Splice modulation |
2024 |
- 50+ ASO programs in clinical development for neurological indications
- 20+ programs for Alzheimer's/Parkinson's
- 15+ programs for ALS/FTD
- Multiple gene therapy programs using RNA interference
CRISPR-Cas13 Systems
- Cas13 for RNA targeting
- Guide RNA delivery challenges
- Potential for permanent correction
- Clinical trials anticipated 2025+
Small Molecule RNA Modulators
- Oral delivery potential
- Lower manufacturing costs
- Broader distribution
- Currently limited to splicing
miRNA Mimics and Antagonists
- miR-124 for stroke
- miR-7 for PD
- miRNA-based combination approaches
Conjugate Therapies
- GalNAc conjugates for hepatic delivery
- Peptide conjugates for CNS delivery
- Antibody-ASO conjugates
Viral Vectors
- AAV for gene therapy
- Next-generation capsids
- Enhanced neuronal tropism
RNA + Small Molecule
- ASO + kinase inhibitor
- Gene therapy + symptomatic treatment
- Multi-target approaches
RNA + Immunotherapy
- ASO + antibody combination
- Tau ASO + anti-amyloid antibody
- Synergistic mechanisms