Caveolae are small plasma membrane invaginations present in many different cell types, which have been linked to diverse cellular functions, including cell signalling, membrane rearrangements and lipid regulation. The caveolae markers, members of the caveolin family of proteins, are essential for caveola formation and function. Recently, however, a protein named PTRF (Polymerase I and Transcript Release Factor) or cavin, originally identified as a nuclear factor that regulates transcription in vitro, was shown to be associated with caveolae in adipocytes. In the first chapter of this thesis, I have used the zebrafish Danio rerio to investigate the relation of PTRF/cavin to caveolae as well as caveola function in vivo. During zebrafish development, PTRF/cavin was highly expressed in the notochord in 18 h, 24 h and 35 h post-fertilization embryos, as detected by in situ hybrydization. Analysis of later development stages showed that PTRF/cavin is also present in the otic vesicle, brachial arches, and periderm. Disruption of PTRF/cavin expression, via morpholino-mediated inhibition, caused severely defective development of the notochord as well as heart edema, in a dose-dependent manner. PTRF/cavin knockdown embryos had curved notochords and were shorter than the controls. Examination of the notochord by electron microscopy showed that the number of caveolae was greatly reduced in PTRF/cavin-morpholino-injected embryos. Similar effects were observed when caveolin-1, the major protein of caveolae in non-muscle cells, was down-regulated. Altogether, these results indicated a role for PTRF/cavin during formation and/or stabilization of caveolae as well as an essential role for caveolae during zebrafish embryo development. Combined with results obtained in mammalian cells, these findings identify PTRF/cavin as the first component of a caveolar coat, required for caveola formation and function (Hill et al., 2008). We subsequently identified a family of PTRF/cavin-related proteins, the cavins, that all associate with caveolae. Using biochemistry, light microscopy, and FRET-based approaches we characterised PTRF/cavin and the new members of this family of proteins SDR/cavin-2, SRBC/cavin-3 and MURC/cavin-4. We have shown that the four members of the cavin family form a multi-protein complex that associates with caveolae. This complex can constitutively assemble in the cytosol and then associate with caveolin at the plasma membrane caveolae; interestingly, caveolin is essential for the plasma membrane translocation of the cavin complex, and in caveolin-1 knockout cells the four cavin proteins are restricted to the cytosol. PTRF/cavin-1, but not other cavins, can induce caveola formation in a heterologous system and is required for the recruitment of the cavin complex to caveolae. The four cavin proteins present distinct patterns of tissue expression, which suggests that caveolae may perform tissue-specific functions regulated by the composition of the cavin complex. MURC/cavin-4 is expressed predominantly in muscle and its distribution is perturbed in human muscle disease associated with caveolin-3 dysfunction, identifying MURC/cavin-4 as a novel muscle disease candidate caveolar protein. To functionally investigate the relation of cavins and caveolae, we explored a caveolar function in mechanosensation. Through the use of hypo-osmotic media, we induced membrane-stretch and showed that the increased membrane tension leads to dissociation of the caveolin-cavin module and caveola disassembly as observed by immunofluorescence and FLIM/FRET techniques. Once released from caveolae, caveolin was seen internalized in late endosomes and lysosomes. Cavin-1, on the other hand, was found to be diffused in the cytosol and from there it was translocated to the nuclear compartment. The nuclear translocation was observed in several different cell types, which suggests a universal role for nuclear cavin-1, and was independent of caveolin expression. Analysis of live cells using real-time FLIM/FRET showed that cells quickly respond to variations in membrane tension by dissociation/re-association of caveolin and cavin-1. Altogether, in the course of this project, I was able to show that cavin-1 is an essential regulator of caveola biogenesis in cultured cells and in vivo. Cavin-1 and the other members of the PTRF/Cavin family form a multiprotein complex that is recruited to caveolae by caveolin and coats plasma membrane caveolae. The association between cavin-1 and caveolin is crucial for caveolae assembly and this interaction has a role in the cellular sensation of plasma membrane tension. Under high membrane tensions, caveolin and cavin-1 dissociate with the consequent flattening of caveolae. Under these circumstances, caveolin is internalized into enlarged endosomes and lysosomes while cavin-1 is translocated to the nucleus, identifying for the first time a caveola- to nucleus signalling pathway. The exact role of nuclear cavin-1 under plasma membrane stretch is now amenable to analysis.
Identifer | oai:union.ndltd.org:ADTP/286520 |
Creators | Michele Bastiani |
Source Sets | Australiasian Digital Theses Program |
Detected Language | English |
Page generated in 0.0018 seconds