Abstract
Transcriptional changes normally occur during development but also underlie differences between healthy and pathological conditions. Transcription factors or chromatin modifiers are involved in orchestrating gene activity, such as the cohesin genes and their regulator NIPBL. In our previous studies, using a zebrafish model for nipblb knockdown, we described the effect of nipblb loss-of-function in specific contexts, such as central nervous system development and hematopoiesis. However, the genome-wide transcriptional impact of nipblb loss-of-function in zebrafish embryos at diverse developmental stages remains under investigation. By RNA-seq analyses in zebrafish embryos at 24 h post-fertilization, we examined genome-wide effects of nipblb knockdown on transcriptional programs. Differential gene expression analysis revealed that nipblb loss-of-function has an impact on gene expression at 24 h post fertilization, mainly resulting in gene inactivation. A similar transcriptional effect has also been reported in other organisms, supporting the use of zebrafish as a model to understand the role of Nipbl in gene regulation during early vertebrate development. Moreover, we unraveled a connection between nipblb-dependent differential expression and gene expression patterns of hematological cell populations and AML subtypes, enforcing our previous evidence on the involvement of NIPBL-related transcriptional dysregulation in hematological malignancies.
Highlights
The capability of regulating gene expression is a key feature of cells and is implicated in all cellular processes
In our previous studies, using a zebrafish model for nipblb knockdown, we described the effect of nipblb loss-of-function in specific contexts, such as central nervous system development and hematopoiesis
A similar transcriptional effect has been reported in other organisms, supporting the use of zebrafish as a model to understand the role of Nipbl in gene regulation during early vertebrate development
Summary
The capability of regulating gene expression is a key feature of cells and is implicated in all cellular processes. Dysregulation of NIPBL has been associated with tumor insurgence, in particular, in hematological malignancies [21,22,23] To further verify this association, we used a collection of gene sets related to myeloid differentiation and AML in the functional enrichment analysis of the gene expression pattern induced by nipblb loss-of-function. The down-regulation induced by nipblb loss-of-function resembles the transcriptional pattern induced by NMP1 mutations in AMLs, as verified by the functional annotation and by the expression level of genes down-regulated by nipblb loss-of-function in the transcriptomes of AML patients with mutant and wild-type NPM1 Taken together, these data provide new insights into the role of nipbl in regulating zebrafish gene expression. By unraveling a connection between nipblb-dependent differential expression and gene sets related to different hematological cell populations and AML subtypes, we shed light on the possible involvement of NIPBL-related transcriptional dysregulation in hematological malignancies
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