Brain pharmacology of intrathecal antisense oligonucleotides revealed through multimodal imaging
Curt Mazur, Berit Powers, Kenneth Zasadny, Jenna M. Sullivan, Hemi Dimant, Fredrik Kamme, Jacob Hesterman, John Matson, Michael Oestergaard, Marc Seaman, Robert W. Holt, Mohammed Qutaish, Ildiko Polyak, Richard Coelho, Vijay Gottumukkala, Carolynn M. Gaut, Marc Berridge, Nazira J. Albargothy, Louise Kelly, Roxana O. Carare, Jack Hoppin, Holly Kordasiewicz, Eric E. Swayze, Ajay Verma
Curt Mazur, Berit Powers, Kenneth Zasadny, Jenna M. Sullivan, Hemi Dimant, Fredrik Kamme, Jacob Hesterman, John Matson, Michael Oestergaard, Marc Seaman, Robert W. Holt, Mohammed Qutaish, Ildiko Polyak, Richard Coelho, Vijay Gottumukkala, Carolynn M. Gaut, Marc Berridge, Nazira J. Albargothy, Louise Kelly, Roxana O. Carare, Jack Hoppin, Holly Kordasiewicz, Eric E. Swayze, Ajay Verma
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Research Article Neuroscience

Brain pharmacology of intrathecal antisense oligonucleotides revealed through multimodal imaging

Abstract

Intrathecal (IT) delivery and pharmacology of antisense oligonucleotides (ASOs) for the CNS have been successfully developed to treat spinal muscular atrophy. However, ASO pharmacokinetic (PK) and pharmacodynamic (PD) properties remain poorly understood in the IT compartment. We applied multimodal imaging techniques to elucidate the IT PK and PD of unlabeled, radioactively labeled, or fluorescently labeled ASOs targeting ubiquitously expressed or neuron-specific RNAs. Following lumbar IT bolus injection in rats, all ASOs spread rostrally along the neuraxis, adhered to meninges, and were partially cleared to peripheral lymph nodes and kidneys. Rapid association with the pia and arterial walls preceded passage of ASOs across the glia limitans, along arterial intramural basement membranes, and along white-matter axonal bundles. Several neuronal and glial cell types accumulated ASOs over time, with evidence of probable glial accumulation preceding neuronal uptake. IT doses of anti-GluR1 and anti-Gabra1 ASOs markedly reduced the mRNA and protein levels of their respective neurotransmitter receptor protein targets by 2 weeks and anti-Gabra1 ASOs also reduced binding of the GABAA receptor PET ligand 18F-flumazenil in the brain over 4 weeks. Our multimodal imaging approaches elucidate multiple transport routes underlying the CNS distribution, clearance, and efficacy of IT-dosed ASOs.

Authors

Curt Mazur, Berit Powers, Kenneth Zasadny, Jenna M. Sullivan, Hemi Dimant, Fredrik Kamme, Jacob Hesterman, John Matson, Michael Oestergaard, Marc Seaman, Robert W. Holt, Mohammed Qutaish, Ildiko Polyak, Richard Coelho, Vijay Gottumukkala, Carolynn M. Gaut, Marc Berridge, Nazira J. Albargothy, Louise Kelly, Roxana O. Carare, Jack Hoppin, Holly Kordasiewicz, Eric E. Swayze, Ajay Verma

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Figure 2

Ex vivo PK and PD effects of IT-dosed ASOs on brain neurotransmitter receptor mRNA and protein expression.

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Ex vivo PK and PD effects of IT-dosed ASOs on brain neurotransmitter rec...
(A) IHC of GluR1 ASO uptake by brain and spinal cord at various times after dosing (0.7 mg IT bolus) from animals representative of the groups of 4 at each time point. (B) Regional GluR1 ASO PK and PD effect on GluR1 mRNA knockdown via PCR graphed versus time after dosing (in days). Dashed lines in A indicate regions used for analysis. (C) IHC for GluR1 protein at various time after dosing from animals representative of the groups of 4 at each time point. (D) Regional relationship between GluR1 ASO IHC and GluR1 mRNA and protein levels as determined by IHC. (E) AUC analysis of ASO concentrations in frontal cortex, lumbar, thoracic, and cervical spinal cord samples versus time. All data are graphed as mean ± SD with n values of 4 for all groups. Analysis of differences between AUCs of the tissues was by 1-way ANOVA with Bennett’s post hoc test; *P < 0.05.