Treatment response and resistance in major depressive disorder (MDD) show a significant genetic component, but previous studies had limited power also due to MDD heterogeneity. This literature review Show more
Treatment response and resistance in major depressive disorder (MDD) show a significant genetic component, but previous studies had limited power also due to MDD heterogeneity. This literature review focuses on the genetic factors associated with treatment outcomes in MDD, exploring their overlap with those associated with clinically relevant symptom dimensions. We searched PubMed for: (1) genome-wide association studies (GWASs) or whole exome sequencing studies (WESs) that investigated efficacy outcomes in MDD; (2) studies examining the association between MDD treatment outcomes and specific depressive symptom dimensions; and (3) GWASs of the identified symptom dimensions. We identified 13 GWASs and one WES of treatment outcomes in MDD, reporting several significant loci, genes, and gene sets involved in gene expression, immune system regulation, synaptic transmission and plasticity, neurogenesis and differentiation. Nine symptom dimensions were associated with poor treatment outcomes and studied by previous GWASs (anxiety, neuroticism, anhedonia, cognitive functioning, melancholia, suicide attempt, psychosis, sleep, sociability). Four genes were associated with both treatment outcomes and these symptom dimensions: CGREF1 (anxiety); MCHR1 (neuroticism); FTO and NRXN3 (sleep). Other overlapping signals were found when considering genes suggestively associated with treatment outcomes. Genetic studies of treatment outcomes showed convergence at the level of biological processes, despite no replication at gene or variant level. The genetic signals overlapping with symptom dimensions of interest may point to shared biological mechanisms and potential targets for new treatments tailored to the individual patient's clinical profile. Show less
The destiny of a messenger RNA is determined from a combination of in cis elements, like peculiar secondary structures, and in trans modulators, such as RNA binding proteins and non-coding, regulatory Show more
The destiny of a messenger RNA is determined from a combination of in cis elements, like peculiar secondary structures, and in trans modulators, such as RNA binding proteins and non-coding, regulatory RNAs. RNA guanine quadruplexes belong to the first group: these strong secondary structures have been characterized in many mRNAs, and their stabilization or unwinding provides an additional step for the fine tuning of mRNA stability and translation. On the other hand, many cytoplasmic long non-coding RNAs intervene in post-transcriptional regulation, frequently by direct base-pairing with their mRNA targets. We have previously identified the lncRNA SMaRT as a key modulator of the correct timing of murine skeletal muscle differentiation; when expressed, lnc-SMaRT interacts with a G-quadruplex-containing region of Mlx-γ mRNA, therefore inhibiting its translation by counteracting the DHX36 helicase activity. The "smart" mode of action of lnc-SMaRT led us to speculate whether this molecular mechanism could be extended to other targets and conserved in other species. Here, we show that the molecular complex composed by lnc-SMaRT and DHX36 also includes other mRNAs. We prove that lnc-SMaRT is able to repress Spire1 translation through base-pairing with its G-quadruplex-forming sequence, and that Spire1 modulation participates to the regulation of proper skeletal muscle differentiation. Moreover, we demonstrate that the interaction between DHX36 and lnc-SMaRT is indirect and mediated by the mRNAs present in the complex. Finally, we suggest an extendibility of the molecular mechanism of lnc-SMaRT from the mouse model to humans, identifying potential functional analogues. Show less
Guanine-quadruplexes (G4) included in RNA molecules exert several functions in controlling gene expression at post-transcriptional level; however, the molecular mechanisms of G4-mediated regulation ar Show more
Guanine-quadruplexes (G4) included in RNA molecules exert several functions in controlling gene expression at post-transcriptional level; however, the molecular mechanisms of G4-mediated regulation are still poorly understood. Here, we describe a regulatory circuitry operating in the early phases of murine muscle differentiation in which a long non-coding RNA (SMaRT) base pairs with a G4-containing mRNA (Mlx-γ) and represses its translation by counteracting the activity of the DHX36 RNA helicase. The time-restricted, specific effect of lnc-SMaRT on the translation of Mlx-γ isoform modulates the general subcellular localization of total MLX proteins, impacting on their transcriptional output and promoting proper myogenesis and mature myotube formation. Therefore, the circuitry made of lnc-SMaRT, Mlx-γ, and DHX36 not only plays an important role in the control of myogenesis but also unravels a molecular mechanism where G4 structures and G4 unwinding activities are regulated in living cells. Show less