Progesterone | EPFL Graph Search

Progesterone (P4) is an endogenous steroid and progestogen sex hormone involved in the menstrual cycle, pregnancy, and embryogenesis of humans and other species. It belongs to a group of steroid hormones called the progestogens and is the major progestogen in the body. Progesterone has a variety of important functions in the body. It is also a crucial metabolic intermediate in the production of other endogenous steroids, including the sex hormones and the corticosteroids, and plays an important role in brain function as a neurosteroid. In addition to its role as a natural hormone, progesterone is also used as a medication, such as in combination with estrogen for contraception, to reduce the risk of uterine or cervical cancer, in hormone replacement therapy, and in feminizing hormone therapy. It was first prescribed in 1934. Biological activity Pharmacodynamics of progesterone#Mechanism of action Progesterone is the most important progestogen

How adeno-associated virus Rep78 relocalises Cdc25B to arrest the cell cycle

Florence Magnin

Adeno-associated virus (AAV) is a small DNA virus belonging to the family of the parvoviridae. AAV infects the human population, however no disease has been associated with this virus. On the contrary, AAV was reported to have oncosuppressive activities. The AAV genome contains two genes: the Rep gene encoding four non-structural proteins (Rep78, 68, 52 and 40) and the Cap gene encoding the three capsid proteins. Rep78 is implicated in transcription, replication and site-specific integration of the viral DNA. It has been shown to block the cell cycle in G1, G2 and S phase with a complete inhibition of DNA synthesis. To be able to induce such a strong cell cycle arrest, Rep78 affects several proteins implicated in the regulation of the cell cycle, such as the family of the cell division cycle 25 (Cdc25) phosphatases. Rep78 has been shown to inactivate Cdc25A by binding to it and preventing it from accessing its substrates. Cdc25B shares conserved domains with Cdc25A and moreover has an important role in cell cycle regulation, especially in giving the signal for entry into mitosis. Thus, in this work, the interaction between Cdc25B and Rep78 was examined in more detail. Rep78 was found to bind to Cdc25B and to alter its intracellular localisation. Cdc25B is nuclear, but has to migrate into the cytoplasm at the end of the G2 phase to activate proteins needed for the entry into mitosis. The expression of Rep78, which is nuclear, leads to the sequestration of Cdc25B in the nucleus. Moreover, Rep78 by interacting with Cdc25B not only changes its localisation, but also inhibits its phosphatase activity. Our model is that Rep78 interacts with Cdc25B and thus retains it in the nucleus. This sequestration of Cdc25B in the nucleus prevents it from activating the proteins in the cytoplasm needed to give the entry signal into mitosis, thus contributing to the G2/M arrest induced by Rep78. Moreover, the inhibition of Cdc25B phosphatase activity by Rep78 may also contribute to the cell cycle block. Rep78 also interacts with a number of cellular proteins implicated in DNA replication, DNA repair or recombination. Interactions between Rep78 and mini-chromosome maintenance 3 (MCM3), DNA polymerases α and δ, proliferating cell nuclear antigen (PCNA), Rad50 and Rad51 were identified in this work as well as possible interactions between Rep78 and Ataxia telangiectasia mutated (ATM) or Ataxia telangiectasia and Rad3 related (ATR) proteins. These interactions may contribute to AAV genome replication as well as its integration into the host DNA.

EPFL2009

Progestins used for hormonal contraception in Switzerland: study of their effects on the breast epithelium

Marie Shamseddin

Breast cancer is the most commonly diagnosed cancer and the most common cause of cancer death among women. Hormones have been shown to have a key role in breast development and carcinogenesis. Repeated activation of progesterone receptor (PR) signaling as it occurs during menstrual cycles is important in cancer risk. Through hormonal contraception many women are exposed to synthetic PR agonists, progestins, either on their own or in combination with the synthetic estrogen receptor (ER) agonist, ethinyl estradiol (EE). Progestins vary in their chemical structures and biological activities. Epidemiological studies show that hormonal contraceptions increase the risk of breast cancer but to date there have been few studies that analyze specific progestins regarding the breast cancer risk they confer. We hypothesized that different progestins have distinct abilities to induce cell proliferation and to modulate gene expression in the breast epithelium and this may ultimately have different effects on breast cancer risk. To test the hypothesis that different progestins currently used in hormonal contraceptions in Switzerland have distinct abilities to induce the expression of important mediators of PR action, receptor activator of NF-ÎºB ligand (RANKL) and Wnt4, we employed mouse mammary gland organoids and human breast tissue microstructures. We find that androgenic progestins strongly induce RANKL and Wnt4 whereas anti-androgenic progestins fail to do so. To test the ability of different progestins currently used in hormonal contraceptions in Switzerland to induce cell proliferation in human breast epithelium, we humanized mouse mammary gland using intraductal injection of human breast epithelial cells obtained from reduction mammoplasty surgery. We show that breast epithelial cells maintain hormone receptor expression and remain hormone responsive in this approach. We find that the androgenic progestins, Gestodene and Levonorgestrel, promote cell proliferation over two months more than progesterone. Furthermore, we show that Androgen receptor (AR) inhibition abrogates promegestone-induced RANKL induction and reduces cell proliferation induced by androgenic progestin, LNG. We also show that activation of AR signaling through DHT exposure is sufficient to induce proliferation of human breast epithelial cells. Thus, different progestins have different biological effects on the breast epithelium that appear to be related to their androgenic activities.

EPFL2018

A viral vector based in vivo model of tauopathy to explore therapeutic strategies against tau pathology

Sameer Mohammad Khaleel Nazeeruddin

Tauopathies are neurodegenerative diseases whose common pathological feature is the intraneuronal accumulation of tau aggregates. Tau protein has various roles in the neuron, among which stabilization of microtubules (MT), regulation of synaptic activity or axonal transport. Subsequently, tau pathology exerts toxicity through mechanisms that likely involve the loss of normal function or the gain of toxic functions. In tauopathies, tau undergoes post-translational modifications (PTM), which are thought to promote the detachment from the MT, change its subcellular localization, and induce conformational changes that favor its assembly with other tau monomers, forming oligomers and fibrils. Furthermore, both normal and pathological forms of tau can be transferred from neuron to neuron. This process may have an important role in disease progression, by propagating the pathology along synaptically connected brain regions, which reflects the evolution of the symptoms. Therefore, the aggregation of tau protein and its propagation are promising targets for potential treatments. In the present thesis, our objective was to assess the efficacy of two treatments using a mouse model of tauopathy based on local overexpression of the 4R0N human tau (hTau) wild-type (WT) induced by intracerebral injection of an adeno-associated viral (AAV) vector. In the first part of the thesis, we overexpressed tau in the entorhinal cortex (EC) of WT mice to induce pathology and assess the effects of aggregation inhibitor compounds orally administered. Although we did not observe any effect on markers of tau aggregation, likely because the induced pathology was still at an early stage, the treatment was found to enhance phosphorylation of the Ser202/Thr205 residues in the EC and ipsilateral hippocampus (HPC). Additionally, we measured an increase in the density of microglial cells in the HPC, and significantly decreased levels of total hTau in the cerebrospinal fluid of the treated mice. These findings suggest a potential positive effect of this treatment on the clearance of hTau. In the second part of the thesis, we unilaterally overexpressed hTau in the mouse CA3 HPC and used the connectivity between both hemispheres to quantify the propagation of tau from neuron-to-neuron to the contralateral HPC. We found neurons labelled for hTau in the contralateral HPC, the number of which was increased in 5xFAD mice carrying the amyloid pathology. Next, to induce an antibody response against pathological tau, we subcutaneously injected a vaccine against the phospho-Ser396/404 tau epitope. The vaccine induced a potent antibody response in WT mice, but antibody titers remained low in the 5xFAD mice. In the treated WT mice, immunohistochemistry showed a decreased PHF-1 immunoreactivity in the HPC, indicating that the generated antibodies indeed recognized the phospho-Ser396/404 epitope. Remarkably, the vaccine decreased the number of neurons positive for hTau in the contralateral HPC, suggesting an effect of immunotherapy on tau propagation. Furthermore, the vaccine also showed potential neuroprotective effects, by decreasing the level of neurodegeneration in the dentate gyrus of treated mice as a function of the anti-phospho-tau antibody titer. In this work, using adapted AAV8-based models of local tau overexpression in the mouse brain, we reveal the effects of two treatments on different aspects of tau pathology related to the progression of the symptoms in tauopathies.

EPFL2019