Reconditioning the Neurogenic Niche of Adult Non-human Primates by Antisense Oligonucleotide-Mediated Attenuation of TGFß Signaling.

Adult neurogenesis is a target for brain rejuvenation as well as regeneration in aging and disease. Numerous approaches showed efficacy to elevate neurogenesis in rodents, yet translation into therapies has not been achieved. Here, we introduce a novel human TGFß-RII (Transforming Growth Factor-Receptor Type II) specific LNA-antisense oligonucleotide ("locked nucleotide acid"-"NVP-13"), which reduces TGFß-RII expression and downstream receptor signaling in human neuronal precursor cells (ReNcell CX® cells) in vitro. After we injected cynomolgus non-human primates repeatedly i.th. with NVP-13 in a preclinical regulatory 13-week GLP-toxicity program, we could specifically downregulate TGFß-RII mRNA and protein in vivo. Subsequently, we observed a dose-dependent upregulation of the neurogenic niche activity within the hippocampus and subventricular zone: human neural progenitor cells showed significantly (up to threefold over control) enhanced differentiation and cell numbers. NVP-13 treatment modulated canonical and non-canonical TGFß pathways, such as MAPK and PI3K, as well as key transcription factors and epigenetic factors involved in stem cell maintenance, such as MEF2A and pFoxO3. The latter are also dysregulated in clinical neurodegeneration, such as amyotrophic lateral sclerosis. Here, we provide for the first time in vitro and in vivo evidence for a novel translatable approach to treat neurodegenerative disorders by modulating neurogenesis.

Save Your Maximum Tolerated Dose: How to Diagnose Procedure-Related Spinal Cord Lesions After Lumbar Intrathecal Bolus Administration of Oligonucleotides in Cynomolgus Monkeys.

Many potential drugs for treatment of neurodegenerative diseases, particularly antisense oligonucleotides (ASOs), are administered via lumbar intrathecal injection, because these drugs do not cross the blood-brain barrier. Intrathecal injection is a well-established method in cynomolgus monkeys, a species that is used in preclinical safety assessment when other nonrodent species cannot be used. The authors completed intrathecal ASO administration in over 30 preclinical safety studies (>1000 animals and >4500 dose administrations) during which we observed 3 cases of procedure-related spinal cord necrosis (incidence <0.1%). We describe clinical symptoms, diagnostic approaches, morphological features, and prognosis of this rare injury, and compare these findings with typical drug-related findings of ASOs dosed by intrathecal injection. The low incidence of procedure-related and dose-limiting lesions confines this analysis to a small sample set. The pattern of effects is similar across all monkeys despite differences in age, body weight, and intrathecal injection site. All 3 cases presented a combination of the following findings: blood in cerebrospinal fluid at time of injection, clinical signs that increase in severity within a day of dosing, lameness of both hind limbs, reduced muscle tone, and loss of patellar, foot grip, and/or anal reflexes. In all cases, magnetic resonance imaging (MRI) showed a linear hyperintense lesion in the lumbar spinal cord. In 2 cases, this hyperintensity was associated with evidence of spinal cord edema. We conclude that a pattern of in-life and pathology findings, including noninvasive MRI assessment, is indicative of procedure-related effects.

Extracellular protonation modulates cell-cell interaction mechanics and tissue invasion in human melanoma cells.

Detachment of cells from the primary tumour precedes metastatic progression by facilitating cell release into the tissue. Solid tumours exhibit altered pH homeostasis with extracellular acidification. In human melanoma, the Na+/H+ exchanger NHE1 is an important modifier of the tumour nanoenvironment. Here we tested the modulation of cell-cell-adhesion by extracellular pH and NHE1. MV3 tumour spheroids embedded in a collagen matrix unravelled the efficacy of cell-cell contact loosening and 3D emigration into an environment mimicking physiological confinement. Adhesive interaction strength between individual MV3 cells was quantified using atomic force microscopy and validated by multicellular aggregation assays. Extracellular acidification from pHe7.4 to 6.4 decreases cell migration and invasion but increases single cell detachment from the spheroids. Acidification and NHE1 overexpression both reduce cell-cell adhesion strength, indicated by reduced maximum pulling forces and adhesion energies. Multicellular aggregation and spheroid formation are strongly impaired under acidification or NHE1 overexpression. We show a clear dependence of melanoma cell-cell adhesion on pHe and NHE1 as a modulator. These effects are opposite to cell-matrix interactions that are strengthened by protons extruded via NHE1. We conclude that these opposite effects of NHE1 act synergistically during the metastatic cascade.

The Na+ /H+ -exchanger (NHE1) generates pH nanodomains at focal adhesions.

Many tumor cells are characterized by an increased net acid production. They extrude the excess protons mainly through the Na(+) /H(+) -exchanger NHE1. An increased NHE1 activity elevates the metastatic potential of tumor cells. Cell migration, a key step in the metastatic cascade, requires the formation and release of integrin-mediated cell-matrix contacts (focal adhesions). As NHE1 has been localized to focal adhesion sites, the present study tests the hypothesis that NHE1 generates measurable pH nanodomains right at focal adhesions. In order to ratiometrically measure pH close to the plasma membrane, we established a novel application of the total internal reflection fluorescence microscopy (TIRFM). Human melanoma cells were transfected with DsRed2-paxillin to identify focal adhesion sites. The pH-sensitive dyes BCECF and WGA-fluorescein were used to measure the submembranous cytosolic and the pericellular pH, respectively. Distinct pH nanodomains were found at focal adhesions, particularly at those located at the cell front, where NHE1 was concentrated. These sites featured a remarkably alkaline cytosolic and an acidic pericellular pH and thus a much steeper proton gradient across the plasma membrane compared to the rest of the cell. The generation of pH nanodomains could be assigned to NHE1-mediated H(+) export because such pH domains could not be detected in NHE1-deficient cells. Given that both integrin avidity and mechanisms contributing to adhesion turnover are pH-sensitive, we propose that pH nanodomains at focal adhesions, locally created and maintained by NHE1 activity especially at the cell front, modulate adhesion dynamics in migrating cells.