Tissue- and sex-specific small RNAomes reveal sex differences in response to the environment

RNA interference (RNAi) related pathways are essential for germline development and fertility in metazoa and can contribute to inter- and trans-generational inheritance. In the nematode Caenorhabditis elegans, environmental double-stranded RNA provided by feeding can lead to heritable changes in phenotype and gene expression. Notably, transmission efficiency differs between the male and female germline, yet the underlying mechanisms remain elusive. Here we use high-throughput sequencing of dissected gonads to quantify sex-specific endogenous piRNAs, miRNAs and siRNAs in the C. elegans germline and the somatic gonad. We identify genes with exceptionally high levels of secondary 22G RNAs that are associated with low mRNA expression, a signature compatible with silencing. We further demonstrate that contrary to the hermaphrodite germline, the male germline, but not male soma, is resistant to environmental RNAi triggers provided by feeding, in line with previous work. This sex-difference in silencing efficacy is associated with lower levels of gonadal RNAi amplification products. Moreover, this tissue- and sex-specific RNAi resistance is regulated by the germline, since mutant males with a feminized germline are RNAi sensitive. This study provides important sex- and tissue-specific expression data of miRNA, piRNA and siRNA as well as mechanistic insights into sex-differences of gene regulation in response to environmental cues. Author summary Environmental factors such as heat or pathogens influence living organisms, and in some cases these experiences can be passed on to the next generation. One such environmental factor is double stranded RNA that can be taken up by some animals and induce changes in gene expression via small RNA mediated silencing. Here, we use the roundworm Caenorhabditis elegans to show that the female and male germline react differently to the presence of such an environmental factor that may affect transmission to following generations. Sequencing of gonadal small RNA suggests that the underlying sex-differences affect downstream processing but not uptake. Furthermore, we describe the naturally occurring small RNA populations of female and male gonads and use genetic mutants to assign small RNAs to the two tissues of the gonad, namely the somatic gonad or the germline. These sex-and tissue-specific small RNA expression data provide an important resource for future research. In addition, this work reveals mechanistic insights into sex-differences in response to environmental cues.

Circadian dynamics of RNA localisation in the mammalian liver

Clémence Yumie Syloun Hurni

Gene expression in eukaryotes is a complex multi-step process. It starts in the nucleus with transcription, the synthesis of a mRNA copy from a DNA template. While in the nucleus, the RNA transcript is subject to multiple co- and post-transcriptional modifications, including splicing, capping, polyadenylation, and assembly into ribonucleoprotein complexes. Correctly processed mRNA is exported to the cytoplasm and translated by ribosomes to form a chain of amino acids: the protein. The mRNA lifetime in the cytoplasm is determined by the activity of a distinct set of RNA Binding Proteins, enzymes, and functional RNAs, which promote stability or degradation. Each step of the RNA life cycle is tightly regulated to ensure proper cellular function. The kinetic rates governing these steps are dynamic and notably adapt to the daily fluctuations of the environment related to the alternance of day and night. Indeed, most organisms possess an internal timing system called the circadian clock. The clock is a genetically encoded self-sustained transcriptional-translational feedback loop, which operates in almost every cell and tissue of the body. It controls the temporal gene expression program to synchronise cellular and physiological functions to the external world. In this thesis, I explore the transcriptome of the mouse liver by combining RNA-sequencing, mathematical modelling, and single-molecule RNA-FISH (smFISH), with an emphasis on the spatio-temporal organisation of RNA expression at the subcellular and tissue scales. I first investigate how RNA are differentially localised at the scale of the liver tissue. Hepatocytes are arranged in structural and functional units called lobules, and carry out different physiological functions depending on their spatial position within the lobule. In this collaborative work, we characterised spatio-temporal gene expression profiles, and showed that that while the expression of hundreds of genes is dually orchestrated by time and space, the circadian core clock is expressed uniformly within the liver lobule, and is therefore robust to the heterogeneous microenvironment. Second, I explore the RNA localisation at the scale of a hepatocyte. The subcellular distributions of RNA in different compartments (here, the nucleus and the cytoplasm), are dictated by the balance of a synthesis term and a decay term. To quantify the kinetic parameters driving nuclear and cytoplasmic mRNA accumulation, I sequenced RNA from both cellular fractions from mouse livers sampled at different times of the day. Using a mathematical model describing rhythmic pre-mRNA and mRNA profiles, I could estimate the nuclear export rates and cytoplasmic degradation rates of

\sim

1400 genes. Nuclear export occurs on a much shorter time-scale than cytoplasmic degradation, and nuclear lifetime has only a minor contribution to the total RNA lifetime. However, a subset of metabolic genes remain in the nucleus for more than one hour (up to four hours), which accounts for the long phase delay between the peak times of transcription and of cytoplasmic accumulation. Furthermore, nuclear export contributes to the modulation and generation of rhythmic profiles of ~10% of the cycling nuclear mRNA. This study provides a comprehensive estimation of the nuclear and cytoplasmic life times in the liver and contributes to a better understanding of the dynamic regulation of the transcriptome during the feeding-fasting cycle.

EPFL2021

The use of RNA interference to increase PEI-mediated transient gene expression in mammalian cells

Martin Bertschinger

DNA uptake by polyethylenimine (PEI)-mediated transfection was investigated in Chinese hamster ovary (CHO DG44) cells. Rapid DNA uptake was observed with the maximum occurring during the first 45-60 min after addition of PEI-DNA complexes to cells. With longer incubation times, the aggregation of PEI-DNA particles reduced the rate of DNA uptake. At early times after transfection, the kinetics of DNA uptake were constant, suggesting that the limiting factor to PEI transfection was the rate of endocytosis. The most efficient transfection with PEI was observed at a density of 2 x 106 cells/ml and at a PEI:DNA ratio of 2:1 (w/w). DNA uptake at higher PEI:DNA ratios was also efficient, but the toxicity of PEI decreased the recombinant protein yield. The optimal PEI:DNA ratio was found to be related to the number of cells in the culture. Once in the cell, PEI:DNA particles must be disassembled to allow transcription of the recombinant gene. Here their disassembly was investigated using a simple in vitro assay. The particles were formed with either a linear (25 kDa or JetPEITM) or a branched PEI (2, 25, or 750 kDa) and then mixed with varying amounts of a competitor (RNA, DNA, or heparin). The amount of plasmid DNA released from particles was determined by agarose gel electrophoresis or spectroscopy. The stability of the particles to changes in pH, osmolarity, and the PEI:DNA ratio was also determined. Either the presence of heparin or high salt concentrations (1-2 M) yielded complete particle disassembly for all PEIs tested. The addition of RNA to particles formed with linear PEIs or branched 2 kDa PEI resulted in the rapid release of all the plasmid DNA, even at an RNA concentration of 50 µg/ml. However, the presence of RNA at concentrations up to 400 µg/ml induced only partial disassembly of particles formed with branched PEIs of 25 or 750 kDa. In the presence of competitor DNA, slow particle disassembly was observed with particles made with linear 25 kDa PEI, JetPEI, and branched 2 kDa PEI, but DNA release was not seen for particles made with branched PEIs of higher molecular weight. The presence of BSA only resulted in partial disassembly of PEI-DNA particles, and DNA release was not observed after the exposure of particles to acidic pH as low as 3. For all the PEIs tested, their stability increased as the PEI:DNA ratio increased. It was concluded from these studies that branched PEIs have a higher affinity for DNA than linear PEIs and that the intracellular disassembly of PEI-DNA particles may involve interactions between PEI and cellular RNA. In the second part of the work, RNA interference (RNAi) was used to enhance transient gene expression by knockdown of two different mRNAs, the E1A mRNA in human embryonic kidney 293 EBNA (HEK293E) cells and the ube2i mRNA in CHO DG44 cells and HEK293 cells. HEK293 cells are transformed with the adenovirus E1A and E1B genes. Because the E1A proteins function as transcriptional activators or repressors, they may have a positive or negative effect on transient transgene expression in this cell line. Suspension cultures of HEK293 cells were co-transfected with a reporter plasmid expressing the GFP gene and a plasmid expressing a short hairpin RNA (shRNA) targeting the E1A mRNAs for degradation by RNAi. The presence of the shRNA in HEK293E cells reduced the steady state level of E1A mRNA up to 75% and increased transient GFP expression from either the elongation factor-1α (EF-1α) promoter or the human cytomegalovirus (HCMV) immediate early promoter up to 3-fold. E1A mRNA depletion also resulted in a 2-fold increase in transient expression of a recombinant IgG in suspension cultures when the IgG light and heavy chain genes were driven by the EF-1α promoter. These results demonstrated that E1A has a negative effect on transient gene expression in HEK293E cells. Efficient RNAi-mediated depletion of ube2i mRNA in CHO DG44 cells was accomplished by co-expression of 2 shRNAs targeting two distinct sides in the ube2i mRNA, whereas knockdown with only one of the shRNAs at a time was insufficient for reducing ube2i mRNA levels. The reduction of the ube2i mRNA level in CHO DG44 cells was shown to enhance transient GFP expression 2-fold and IgG expression 2.5-fold. For these experiments, the GFP gene was under the control of the CMV IE promoter and the IgG light and heavy chain genes were under the control of the human EF-1α promoter. Thus, the enhancement of transient gene expression resulting from ube2i mRNA depletion was not promoter-dependent. These results demonstrated that sumoylation has a negative effect on transient gene expression in CHO DG44 and HEK293E cells.

EPFL2006

Development and characterization of a triple combination gene therapy vector inhibiting HIV-1 multiplication

Isabelle Barde, Didier Trono

BACKGROUND: RNA-based approaches are promising for long-term gene therapy against HIV-1. They can target virtually any step of the viral replication cycle. It is also possible to combine anti-HIV-1 transgenes targeting different facets of HIV replication to compensate for limitations of any individual construct, maximizing efficacy and decreasing chances of escape mutations. We have previously developed two strategies to inhibit HIV-1 multiplication. One was a short hairpin RNA targeting the host factor cyclophilin A implicated in HIV-1 replication. Additionally, an antisense derivative of U7 small nuclear RNA was designed to induce the skipping of the HIV-1 Tat and Rev internal exons. RESULTS: In the present study, we have established an additional tRNAval promoter-driven shRNA against the coding sequence of viral infectivity factor. When human T-cell lines or primary CD4+ T cells are transduced with a triple lentiviral vector encoding these three therapeutic RNAs, HIV-1 multiplication is very efficiently suppressed. Moreover, all three therapeutic RNAs exhibit antiviral effects at early stages of the viral replication cycle (i.e. prior to viral cDNA integration or gene expression). CONCLUSIONS: These findings make this triple lentiviral vector an attractive candidate for a gene therapy against HIV/AIDS.

2008