Real-Time Quantitative PCR and Fluorescence In Situ Hybridization for Subcellular Localization of miRNAs in Neurons.

Neuronal miRNAs play major roles in regulation of synaptic development and plasticity. The small size of miRNAs and, in some cases, their low level of expression make their quantification and detection challenging. Here, we outline methods to quantify steady state levels of miRNAs in neurons and the brain by using real-time quantitative PCR (RT-qPCR) and to determine miRNA subcellular localization in primary neurons by a sensitive fluorescence in situ hybridization (FISH) method.

Native Chromatin Proteomics Reveals a Role for Specific Nucleoporins in Heterochromatin Organization and Maintenance.

Spatially and functionally distinct domains of heterochromatin and euchromatin play important roles in the maintenance of chromosome stability and regulation of gene expression, but a comprehensive knowledge of their composition is lacking. Here, we develop a strategy for the isolation of native Schizosaccharomyces pombe heterochromatin and euchromatin fragments and analyze their composition by using quantitative mass spectrometry. The shared and euchromatin-specific proteomes contain proteins involved in DNA and chromatin metabolism and in transcription, respectively. The heterochromatin-specific proteome includes all proteins with known roles in heterochromatin formation and, in addition, is enriched for subsets of nucleoporins and inner nuclear membrane (INM) proteins, which associate with different chromatin domains. While the INM proteins are required for the integrity of the nucleolus, containing ribosomal DNA repeats, the nucleoporins are required for aggregation of heterochromatic foci and epigenetic inheritance. The results provide a comprehensive picture of heterochromatin-associated proteins and suggest a role for specific nucleoporins in heterochromatin function.

Evolving Models of Heterochromatin: From Foci to Liquid Droplets.

Two recent papers (Larson et al., 2017; Strom et al., 2017) in Nature propose that heterochromatic domains are organized into phase-separated liquid compartments. Here we highlight the main findings that support the liquid-like nature of HP1 domains and discuss their functional implications in gene silencing and genome organization.

A microRNA negative feedback loop downregulates vesicle transport and inhibits fear memory.

The SNARE-mediated vesicular transport pathway plays major roles in synaptic remodeling associated with formation of long-term memories, but the mechanisms that regulate this pathway during memory acquisition are not fully understood. Here we identify miRNAs that are up-regulated in the rodent hippocampus upon contextual fear-conditioning and identify the vesicular transport and synaptogenesis pathways as the major targets of the fear-induced miRNAs. We demonstrate that miR-153, a member of this group, inhibits the expression of key components of the vesicular transport machinery, and down-regulates Glutamate receptor A1 trafficking and neurotransmitter release. MiR-153 expression is specifically induced during LTP induction in hippocampal slices and its knockdown in the hippocampus of adult mice results in enhanced fear memory. Our results suggest that miR-153, and possibly other fear-induced miRNAs, act as components of a negative feedback loop that blocks neuronal hyperactivity at least partly through the inhibition of the vesicular transport pathway.

Microcephaly gene links trithorax and REST/NRSF to control neural stem cell proliferation and differentiation.

Microcephaly is a neurodevelopmental disorder causing significantly reduced cerebral cortex size. Many known microcephaly gene products localize to centrosomes, regulating cell fate and proliferation. Here, we identify and characterize a nuclear zinc finger protein, ZNF335/NIF-1, as a causative gene for severe microcephaly, small somatic size, and neonatal death. Znf335 null mice are embryonically lethal, and conditional knockout leads to severely reduced cortical size. RNA-interference and postmortem human studies show that ZNF335 is essential for neural progenitor self-renewal, neurogenesis, and neuronal differentiation. ZNF335 is a component of a vertebrate-specific, trithorax H3K4-methylation complex, directly regulating REST/NRSF, a master regulator of neural gene expression and cell fate, as well as other essential neural-specific genes. Our results reveal ZNF335 as an essential link between H3K4 complexes and REST/NRSF and provide the first direct genetic evidence that this pathway regulates human neurogenesis and neuronal differentiation.

Defective transcription initiation causes postnatal growth failure in a mouse model of nucleotide excision repair (NER) progeria.

Nucleotide excision repair (NER) defects are associated with cancer, developmental disorders and neurodegeneration. However, with the exception of cancer, the links between defects in NER and developmental abnormalities are not well understood. Here, we show that the ERCC1-XPF NER endonuclease assembles on active promoters in vivo and facilitates chromatin modifications for transcription during mammalian development. We find that Ercc1(-/-) mice demonstrate striking physiological, metabolic and gene expression parallels with Taf10(-/-) animals carrying a liver-specific transcription factor II D (TFIID) defect in transcription initiation. Promoter occupancy studies combined with expression profiling in the liver and in vitro differentiation cell assays reveal that ERCC1-XPF interacts with TFIID and assembles with POL II and the basal transcription machinery on promoters in vivo. Whereas ERCC1-XPF is required for the initial activation of genes associated with growth, it is dispensable for ongoing transcription. Recruitment of ERCC1-XPF on promoters is accompanied by promoter-proximal DNA demethylation and histone marks associated with active hepatic transcription. Collectively, the data unveil a role of ERCC1/XPF endonuclease in transcription initiation establishing its causal contribution to NER developmental disorders.

Dominant and redundant functions of TFIID involved in the regulation of hepatic genes.

To study the in vivo role of TFIID in the transcriptional regulation of hepatic genes, we generated mice with liver-specific disruption of the TAF10 gene. Inactivation of TAF10 in hepatocytes resulted in the dissociation of TFIID into individual components. This correlated with the downregulation of most hepatocyte-specific genes during embryonic life and a defect in liver organogenesis. Unexpectedly, however, the transcription of less than 5% of active genes was affected by TAF10 inactivation and TFIID disassembly in adult liver. The extent of changes in transcription of the affected genes was dependent on the timing of their activation during liver development, relative to that of TAF10 inactivation. Furthermore, TFIID dissociation from promoters leads to the re-expression of several postnatally silenced hepatic genes. Promoter occupancy analyses, combined with expression profiling, demonstrate that TFIID is required for the initial activation or postnatal repression of genes, while it is dispensable for maintaining ongoing transcription.