From the early steps of whisker formation to its evolutionary disappearance: the (curious) case of Prdm1 and its regulation

Pierluigi Giuseppe Manti
EPFL, 2016
Thèse EPFL

Résumé

Whiskers (also known as vibrissae) are sensory organs that are thought to have first appeared in Therapsida, a group of synapsids that includes mammals and evolutionary ancestors like the Thrinaxodon(1). They are highly conserved among mammals to the notable exception of the higher primates and are important for behavior, especially for nocturnal animals and the ones living in burrows(2). Furthermore, the mechanoreceptors of the vibrissae signal to the primary somatosensory cortex, where a discrete and well-defined structure in layer 4 represents each whisker(3). This structure, known as barrel cortex, occupies a large portion of the rodent brain. Strikingly, Prdm1 conditional KO (cKO) mice are one of the rare transgenic strains that do not develop whiskers while forming a pelage; on the other hand, the other head structures expressing Prdm1 (including pelage hair follicles and teeth) grow normally(4). In the developing whisker pad, Prdm1 expression is confined to the mesenchyme underlying the embryonic epidermis that will later form the whisker epidermal placode; it lasts until dermal papilla formation, when a âswitchâ occurs to the precursors of the inner root sheath. The Prdm1 ablation study we conducted revealed the absence of the patterned up-regulation of Bmp2 (marker of placode formation), Shh (a protein secreted by the epidermal placode responsible for the first epidermal signal) and Bmp4 (expressed in the pre-follicle mesenchyme). On the other hand, Lef1 is expressed uniformly in the mesenchyme of the whisker pad, thus pointing out the integrity of the Î²Catenin-mediated first mesenchymal signal. Those results suggest the role of Prdm1 as a master gene in whisker development. Prdm1 expressing cells are mainly non-proliferative; however, a small subpopulation at the periphery is cycling. Being Sox2 coexpressed with Prdm1 in the whisker mesenchyme, we performed lineage tracing with Sox2CreERT2 and ROSAYFP transgenic strains. Those experiments revealed that Sox2/Prdm1 expressing cells contribute to the formation of the dermal papilla, dermal sheath and putative pericytes of the whisker follicle and thus constitute a population of embryonic progenitors crucial for whisker formation. We subsequently investigated the development of the barrel cortex in our cKO mice. Intriguingly, a disorganized pattern was observed in cKO mice, suggesting that the loss of expression of a single gene, and consequently the disappearance of vibrissae, drastically impacts the development of the whole somatosensory system. Finally, we hypothesized that the loss of Prdm1 expression might explain the disappearance of whisker follicles in the human during evolution. Prdm1 being no longer expressed in the human lineage during hair follicle development(5), we reasoned that the loss of regulatory elements of its upstream genes might contribute to this phenomenon; we demonstrated that Lef1 acts upstream of Prdm1 during whisker development and are currently testing the role of its potential enhancers (Leaf) during this process. Bibliography: 1: (http://en.wikipedia.org/wiki/therapsid) 2: Petersen, C. C. H. The Functional Organization of the Barrel Cortex. Neuron 56, 339â355 (2007) 3: Woolsey, T. A. & Van der Loos, H. The structural organization of layer IV in the somatosensory region (SI) of mouse cerebral cortex. The description of a cortical field composed of discrete cytoarchitectonic units. Brain Res. 17, 205â242 (1970) 4: Robertson, E. J. et al. Blimp1 regulates development of the posterior forelimb, caudal pharyngeal arches, heart and sensory vibrissae in mice. Development 134, 4335â4345 (2007). 5: Sellheyer, K. & Krahl, D. Blimp-1: a marker of terminal differentiation but not of sebocytic progenitor cells. J. Cutan. Pathol. 37, 362â370 (2010).

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Pierluigi Giuseppe Manti
EPFL, 2016
Thèse EPFL

Résumé

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https://infoscience.epfl.ch/record/218432?ln=fr

À propos de ce résultat

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Publications associées (121)

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A conserved transcriptional enhancer that specifies Tyrp1 expression to melanocytes

Friedrich Beermann

Pigment cells of mammals originate from two different lineages: melanocytes arise from the neural crest, whereas cells of the retinal pigment epithelium (RPE) originate from the optic cup of the developing forebrain. Previous studies have suggested that pigmentation genes are controlled by different regulatory networks in melanocytes and RPE. The promoter of the tyrosinase-related family gene Tyrp1 has been shown to drive detectable transgene expression only to the RPE, even though the gene is also expressed in melanocytes as evident from Tyrp1-mutant mice. This indicates that the regulatory elements responsible for Tyrp1 gene expression in the RPE are not sufficient for expression in melanocytes. We thus searched for a putative melanocyte-specific regulatory sequence and demonstrate that a bacterial artificial chromosome (BAC) containing the Tyrp1 gene and surrounding sequences is able to target transgenic expression to melanocytes and to rescue the Tyrp1b (brown) phenotype. This BAC contains several highly conserved non-coding sequences that might represent novel regulatory elements. We further focused on a sequence located at -15 kb, which we identified as a melanocyte-specific enhancer as shown by cell culture and transgenic mice experiments. In addition, we show that the transcription factor Sox10 can activate this conserved enhancer. The presence of a distal Tyrp1 regulatory element, which specifies melanocyte-specific expression, supports the idea that separate regulatory sequences can mediate differential gene expression in melanocytes and RPE.

2006

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Obesity is currently a leading global health concern. Treatments include undergoing a weight-loss regimen. However, successful weight-loss is variable, where the heritability of obesity is considered part of the cause. This patient variability to weight-loss was addressed by Carayol et al. (2017), where protein plasma level changes was associated to genetic variability and changes in BMI under a low-calorie diet intervention. A highly significant association region was found to regulate downstream gene FAM46A; coding for a nucleotidyl-transferase protein. Loss of function mutations in FAM46A have previously been discovered in multiple human diseases, such as osteogenesis imperfecta. However, there is a lack of understanding of FAM46Aâs function, especially in the context of adipose tissue and metabolism. This thesis aimed to follow up on the Carayol et al. study by investigating the transcriptional regulation of FAM46A and how the associated region is influencing this regulation, as well as how FAM46A is involved in adipose tissue function. When mapping the physical DNA interaction network around the associated region using chromosome conformation capture (3C) in human subcutaneous adipocytes (SGBS cells), no interactions between the FAM46A promoter and selected loci of the associated region were found. Interestingly, significant interaction peaks downstream of the promoter overlapped with regions of open chromatin and were enriched for transcription factor (TF) motifs that are involved in stem cell differentiation and TGFÎ² signalling. SMAD4, part of the TGFÎ² signalling pathway, binds to this region, indicating a potential regulator of FAM46A. To address FAM46Aâs potential role in adipocyte function, FAM46A expression was disrupted in vitro in differentiating adipocytes. Reduction of FAM46A expression in SGBS cells resulted in decreased expression of PPARG and CEBPA, the master regulators of adipogenesis, complemented by a reduction in lipid accumulation. Follow up studies in murine mesenchymal stem cells where Fam46a was over-expressed were controversial as this led to a decrease in adipogenic markers (Adipoq and PPARðŸ). Overall, disruption of FAM46A expression led to opposing changes in adipogenic potential, suggesting the requirement for a more stable cell system to study FAM46A in vitro. To further characterise the role of Fam46a, metabolic phenotyping of a Fam46a knockout (KO) mouse model under hyper-caloric stress was performed in collaboration with the IMG in Prague. This model revealed a significantly smaller mouse, and increased plasma alkaline phosphatase, as previously observed. When fed a high-fat diet, KO mice had reduced overall fat mass, improved glucose clearance and reduced adipocyte size in both subcutaneous and visceral white adipose tissue (subWAT/visWAT) depots. Transcriptomic analysis of these two depots revealed an up-regulation of genes expressed in ribosome related pathways in the subWAT, whereas the visWAT showed the up-regulation of fatty acid metabolism pathways, suggesting that the KO adipose tissue is more metabolically active. Other down-regulated pathways involved stem cell differentiation and BMP/TGFÎ²-signalling. In conclusion, this study found the possible regulation of the FAM46A promoter by TFs involved in adipogenesis regulation, such as SMAD proteins, as well as strengthening its possible functional involvement in TGFÎ² signalling by enrichment of this pathway in KO studies.

EPFL2021

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Rhythmic and clock-dependent chromatin loops regulate circadian gene expression

Jérôme Mermet

In mammals the circadian clock drives daily behavioural and physiological changes that resonate with environmental cues, which can be observed, for example, in the intricate timing of rest during the night and activity during the day in humans. The circadian clock consists of a network of hierarchical clocks in which the central pacemaker is located in the suprachiasmatic nucleus, which is sensitive to external light and propagates time to the peripheral organ-based clocks. Within organs, clocks tick in each individual cell and are molecularly encoded in the genome as a network of dynamic feedback loops. By mediating the expression of the appropriate gene products at the correct moment of the day, the molecular clocks op-timize physiological functions of virtually every cell in our body, allowing us to synchronize with daily fluc-tuations in the environment. In mammalian cells the chromatin organization in the nucleus consists of a topological network, in which chromatin interactions between distal regulatory elements such as enhancers and target genes are essen-tial to regulate gene expression. Important questions remain: is the complex chromatin folding dynamic and if so on which genomic and temporal scales? In fact, dynamic rearrangements of the chromatin have been reported on multiple genomic and time scales, from the entire genome to enhancer-promoter con-tacts, across developmental transitions, cellular differentiation, and transcription cycles. With this per-spective in mind, the circadian oscillator provides a unique model to study the dynamics of genomic inter-actions in the context of fluctuating transcription. Here, we explored chromatin contacts of core-clock and clock-controlled gene promoters in the mouse. We aimed at evaluating the putative dynamics of chromatin contacts, at estimating their conservation across tissues, and at exploring the contribution of the circadian clock to this interaction network. To achieve this goal, we performed 4C-sequencing assays at two circadian time points in the liver and kidney of WT and clock-deficient animals. Overall, we observe that chromatin contacts are largely conserved across circadian time points and genetic backgrounds, and are tissue-specific. Our experiments reveal that the promoters of core-clock and clock-controlled genes contact distal genomic regions containing en-hancer chromatin signatures, suggesting a functional role of these distal sites in target gene regulation. Our data also suggest a clock-driven module of rhythmic genes that are colocalized in the nucleus. However, we also observe dynamic contacts between oscillating gene promoter and enhancer-like ge-nomic regions. In this thesis, we discuss in detail two examples of dynamic chromatin looping that are ob-served at the Cry1 and Gys2 loci. Our data reveal not only a dynamic coupling between the chromatin loop and the transcriptional state but also that the dynamic of chromatin looping depends on a functional clock. Furthermore, genome editing experiments using CRISPR-Cas9 tools reveal that the Cry1 distal site is essential for the transcriptional regulation of Cry1 and contributes to the circadian clock robustness both in-vivo and in cultured cells. These results demonstrate how local chromatin rearrangements take place in a 24-hour time-scale and set chromatin looping between gene promoters and distal regions as a new reg-ulatory layer for circadian gene expression.

EPFL2017

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Rhythmic and clock-dependent chromatin loops regulate circadian gene expression

Jérôme Mermet

EPFL2017

EPFL2021