NSD Overexpression in the Fat Body Increases Antimicrobial Peptide Production by the Immune Deficiency Pathway in Drosophila.

Nuclear receptor-binding SET domain-containing protein 1 (NSD1) inactivation in tumor cells contributes to an immune-cold phenotype, indicating its potential association with immune disturbances. Drosophila NSD is a homolog of the human NSD1. Thus, in this study, we investigated the effect of NSD overexpression in the fat body, the central organ involved in Drosophila immune responses. Upon ectopic expression of NSD in the fat body, the mRNA levels of antimicrobial peptides increased. Using reporter constructs containing deletions of various NF-κB sites in the Attacin-A (AttA) promoter, we found that transcriptional activation by NSD is mainly mediated via the IMD pathway by activating Relish. Since the IMD pathway is required to resist Gram-negative bacterial infections, we further examined the effect of fat body-specific NSD overexpression on Drosophila immune defenses. Upon oral ingestion of Gram-negative Pseudomonas entomophila, the survival rate of the NSD-overexpressing larvae was higher than that of the wild type, suggesting a positive role of NSD in immune responses. Taken together, these results suggest the association of NSD with the IMD pathway and is thus expected to contribute to the elucidation of the molecular mechanisms of immune malfunction in various NSD1-associated human diseases.

Drosophila NSD deletion induces developmental anomalies similar to those seen in Sotos syndrome 1 patients.

BACKGROUND: Haploinsufficiency of the human nuclear receptor binding suppressor of variegation 3-9, enhancer of zeste, and trithorax (SET) domain 1 (NSD1) gene causes a developmental disorder called Sotos syndrome 1 (SOTOS1), which is associated with overgrowth and macrocephaly. NSD family proteins encoding histone H3 lysine 36 (H3K36) methyltransferases are conserved in many species, and Drosophila has a single NSD homolog gene, NSD. OBJECTIVE: To gain insight into the biological functions of NSD1 deficiency in the developmental anomalies seen in SOTOS1 patients using an NSD-deleted Drosophila mutant. METHODS: We deleted Drosophila NSD using CRISPR/Cas9-mediated targeted gene knock-out, and analyzed pleiotropic phenotypes of the homozygous mutant of NSD (NSD-/-) at various developmental stages to understand the roles of NSD in Drosophila. RESULTS: The site-specific NSD deletion was confirmed in the mutant. The H3K36 di-methylation levels were dramatically decreased in the NSD-/- fly. Compared with the control, the NSD-/- fly displayed an increase in the body size of larvae, similar to the childhood overgrowth phenotype of SOTOS1 patients. Although the NSD mutant flies survived to adulthood, their fecundity was dramatically decreased. Furthermore, the NSD-/- fly showed neurological dysfunctions, such as lower memory performance and motor defects, and a diminished extracellular signal-regulated kinase (ERK) activity. CONCLUSIONS: The NSD-deleted Drosophila phenotype resembles many of the phenotypes of SOTOS1 patients, such as learning disability, deregulated ERK signaling, and overgrowth; thus, this mutant fly is a relevant model organism to study various SOTOS1 phenotypes.

Overexpression of H3K36 methyltransferase NSD in glial cells affects brain development in Drosophila.

NSD1 is a histone methyltransferase that methylates the lysine 36 at histone H3. NSD duplication is associated with short stature, microcephaly, intellectual disability, and behavioral defects in humans. Ectopic overexpression of NSD, an NSD1 homolog in Drosophila, was shown to induce developmental abnormalities via apoptosis. In this study, to investigate the effects of NSD overexpression on Drosophila brain development, we first examined the typical NSD expression pattern in larval brains and found that endogenous NSD promoter activity was detected only in subsets of glial cells. Pan-glial, but not pan-neuronal, NSD overexpression induced apoptosis in larval brain cells. However, pan-glial NSD overexpression also induced caspase-3 cleavage in neuronal cells. Among the various glial cell types, NSD overexpression in only astrocytic glia induced apoptosis and abnormal learning defects in the larval stage. Furthermore, NSD overexpression downregulated the expression of various astrocyte-specific genes, including draper (drpr), possibly owing to an indirect effect of NSD overexpression-induced astrocytic apoptosis. Since drpr plays a role in axon pruning during mushroom body (MB) formation in Drosophila astrocytes, we examined the effect of astrocytic NSD overexpression on this process and found that it disrupted the clearance of γ-neurons in the MB, subsequently inducing arrhythmic locomotor activity of the fly. Thus, these results suggest that aberrant NSD overexpression may cause neurodevelopmental disorders by interfering with crucial functions of astrocytes in the brain, underlining the importance of the tightly controlled astrocytic NSD expression for proper neurodevelopment.