Cold acclimation of chill coma mechanisms in the locust CNS

Temperature has profound effects on the neural function and behaviour of insects. When exposed to low temperature, migratory locusts (Locusta migratoria) enter chill coma (neuromuscular paralysis) and can resume normal body functions after returning to normal temperature. Our laboratory has studied phenomena underlying environmental stress-induced comas in locusts and found that they are associated with a sudden loss of K+ homeostasis and also a temporary electrical silence in the central nervous system (CNS). However, the mechanisms underlying chill coma entry and recovery are not well understood, particularly the role of the CNS has not been determined. Here, I investigated neural function during chill coma in the locust by measuring electrical activity in the CNS. As pre-exposure to moderately low temperatures, either chronically (cold acclimation) or acutely (rapid cold hardening; RCH), has been found to improve the insect’s cold tolerance, I also determined cold acclimation and RCH protocols that will improve the locust's cold tolerance and whether these protocols affect neural shutdown during chill coma in the locust. With an implanted thermocouple in the thorax, I determined the temperature associated with a loss of responsiveness (CTmin) in intact male adult locusts. In parallel experiments, I recorded field potential (FP) in the metathoracic ganglion (MTG) in semi-intact preparations to determine the temperature that would induce neural shutdown. I found that acclimation at 10 ˚C and RCH at 4 ˚C reduced chill coma recovery time (CCRT) in intact animal preparations and RCH at 4 ˚C for 4 hours reduced the temperature at neural shutdown in semi-intact preparations. These results suggest that pre-exposure to cold can improve the locust's resistance to chill coma and support the notion that the CNS has a role in determining entry into and exit from chill coma in locusts.

Les récepteurs GPR91 et GPR99 et leur implication dans le développement du système nerveux visuel

Les récepteurs couplés aux protéines G (RCPG) démontrent de plus en plus de capacités à activer des mécanismes jusqu’alors associés à des facteurs de transcription ou des molécules d’adhésion. En effet, de nouvelles preuves rapportent qu’ils pourraient également participer au guidage axonal qui est le mécanisme permettant aux axones de cellules nerveuses de rejoindre leur cible anatomique. Le guidage axonal se fait par l’interaction entre les molécules de guidage et une structure particulière présente à l’extrémité de l’axone, le cône de croissance. Par exemple, les RCPGs participent au guidage des cellules ganglionnaires de la rétine (CGR), dont les axones s’étendent de la rétine jusqu’au noyaux cérébraux associés à la vision. Cet effet est observé avec des RCPGs tels que les récepteurs aux cannabinoïdes (CB1 et CB2) et celui du lysophosphatidylinositol, le GPR55. Les RCPGs GPR91 et GPRG99, respectivement récepteurs au succinate et à l’α-cétoglutarate, se trouvent à la surface de ces CGRs, ce qui en font des candidats potentiels pouvant participer au guidage axonal. Dans ce mémoire, l’effet des ligands de ces récepteurs sur la croissance et la navigation des axones des CGRs fut analysé. L’impact produit par ces récepteurs ainsi que leurs ligands sur la morphologie des cônes de croissance fut déterminé en mesurant leur taille et le nombre de filopodes présents sur ces cônes. Pour évaluer le rôle du succinate et de l’a-cétoglutarate sur la croissance globale des axones de CGRs, la longueur totale des projections axonales d’explants rétiniens a été mesurée. L’effet de ces ligands des récepteurs GPR91 et GPR99 sur le guidage axonal a également été évalué en temps réel à l’aide d’un gradient créé par un micro injecteur placé à 45° et à 100µm du cône de croissance. La distribution in vivo des récepteurs GPR91 et GPR99 sur la rétine a été étudié à l’aide d’expériences d’immunohistochimie. Les résultats obtenus indiquent que l’ajout de 100µM de succinate produit une augmentation de la taille des cônes de croissance et du nombre de filopodes présents à leur surface. Il augmente également la croissance des axones. Ce type de réponse fut également observé lorsque les cellules furent soumises à 200µM d’α-cétoglutarate. Fait à noter, les deux récepteurs n’ont pas d’impact sur le guidage axonal. Ces résultats indiquent donc que les agonistes des récepteurs GPR91 et GPR99 augmentent la croissance des cellules ganglionnaires lorsqu’ils sont présents lors du développement. Par contre, ils n’ont pas d’influence sur la direction prise par les cônes de croissance. Ces nouvelles données sont un pas de plus dans la compréhension des mécanismes qui gèrent et participent au développement et la croissance des CGRs, ce qui pourrait donner de nouvelles cibles thérapeutique pouvant mener à la régénération de nerfs optiques endommagés.

Whole Exome Sequencing widens the genetic landscape of Hereditary Optic Neuropathies

Hereditary optic neuropathies (HON) are a genetic cause of visual impairment characterized by degeneration of retinal ganglion cells. The majority of HON are caused by pathogenic variants in mtDNA genes and in gene OPA1. However, several other genes can cause optic atrophy and can only be identified by high throughput genetic analysis. Whole Exome Sequencing (WES) is becoming the primary choice in rare disease molecular diagnosis, being both cost effective and informative. We performed WES on a cohort of 106 cases, of which 74 isolated ON patients (ON) and 32 syndromic ON patients (sON). The total diagnostic yield amounts to 27%, slightly higher for syndromic ON (31%) than for isolated ON (26%). The majority of genes found are related to mitochondrial function and already reported for harbouring HON pathogenic variants: ACO2, AFG3L2, C19orf12, DNAJC30, FDXR, MECR, MTFMT, NDUFAF2, NDUFB11, NDUFV2, OPA1, PDSS1, SDHA, SSBP1, and WFS1. Among these OPA1, ACO2, and WFS1 were confirmed as the most relevant genetic causes of ON. Moreover, several genes were identified, especially in sON patients, with direct impairment of non-mitochondrial molecular pathways: from autophagy and ubiquitin system (LYST, SNF8, WDR45, UCHL1), to neural cells development and function (KIF1A, GFAP, EPHB2, CACNA1A, CACNA1F), but also vitamin metabolism (SLC52A2, BTD), cilia structure (USH2A), and nuclear pore shuttling (NUTF2). Functional validation on yeast model was performed for pathogenic variants detected in MECR, MTFMT, SDHA, and UCHL1 genes. For SDHA and UCHL1 also muscle biopsy and fibroblast cell lines from patients were analysed, pointing to possible pathogenic mechanisms that will be investigated in further studies. In conclusion, WES proved to be an efficient tool when applied to our ON cohort, for both common disease-genes identification and novel genes discovery. It is therefore recommended to consider WES in ON molecular diagnostic pipeline, as for other rare genetic diseases.

Neuro-ophthalmological and electrophysiological characterization of mitochondrial diseases.

Aims and methods: 1) characterization of patients with Dominant Optic Atrophy (DOA) associated with mutations in AFG3L2 and ACO2 genes in comparison with classical OPA1-DOA; 2) characterization of patients with mtDNA mutations causing MELAS and MERRF syndromes and correlation with heteroplasmy; 3) longitudinal evaluation of subacute m.11778G>A/MTND4 Leber’s Hereditary Optic Neuropathy (LHON) patients co-treated with rAAV2/2-ND4 gene therapy and idebenone. We performed a comprehensive neuro-ophthalmological assessment coupled with electrophysiological examination. Results: 1) We described and compared 23 ACO2 and 13 AFG3L2 patients with 72 OPA1 patients. All patients presented temporally predominant optic atrophy, with ACO2 showing higher RNFL and GCL thicknesses at OCT, while AFG3L2 was virtually-indistinguishable from OPA1. 2) Retinopathy was the most common manifestation in 17/33 MELAS patients, conversely, optic atrophy was the most common finding in 7/8 MERRF patients. Correlation of heteroplasmy with neuro-ophthalmological parameters failed to disclose any significance in MELAS, while it negatively correlated with OCT parameters in MERRF. 3) We compared modifications in visual acuity, OCT and electrophysiological parameters at 3 timepoints in 9 LHON patients. We observed significant decrease of RNFL thickness and reduction of PhNR amplitude. Visual acuity improved of about -0.37 LogMAR, correlating significantly with time from onset and from injection, but not with idebenone therapy duration. Discussion: 1) ACO2 seems associated to better preservation of retinal ganglion cells, depending on a different pathogenic mechanism involving mtDNA maintenance, as opposed to AFG3L2 which is involved in OPA1 processing. 2) MELAS and MERRF patients presented with a clearly distinct ocular phenotype, possibly reflecting a selective susceptibility of different retinal cell types to global energy defect or oxidative stress. 3) Follow up of LHON patients treated with gene therapy confirmed the deterioration in OCT and electrophysiological parameters, while the amount of visual improvement was similar to the one observed in recent clinical trials.