Chick Lrrn2, a novel downstream effector of Hoxb1 and Shh, functions in the selective targeting of rhombomere 4 motor neurons

Background; Capricious is a Drosophila adhesion molecule that regulates specific targeting of a subset of motor neurons to their muscle target. We set out to identify whether one of its vertebrate homologues, Lrrn2, might play an analogous role in the chick.Results; We have shown that Lrrn2 is expressed from early development in the prospective rhombomere 4 (r4) of the chick hindbrain. Subsequently, its expression in the hindbrain becomes restricted to a specific group of motor neurons, the branchiomotor neurons of r4, and their pre-muscle target, the second branchial arch (BA2), along with other sites outside the hindbrain. Misexpression of the signalling molecule Sonic hedgehog (Shh) via in ovo electroporation results in upregulation of Lrrn2 exclusively in r4, while the combined expression of Hoxb1 and Shh is sufficient to induce ectopic Lrrn2 in r1/2. Misexpression of Lrrn2 in r2/3 results in axonal rerouting from the r2 exit point to the r4 exit point and BA2, suggesting a direct role in motor axon guidance.Conclusion; Lrrn2 acts downstream of Hoxb1 and plays a role in the selective targeting of r4 motor neurons to BA2.</p

The release of histone proteins from cells via extracellular vesicles [Elektronisk resurs]

Histones are chromatin-associated proteins localized to the nucleus. However, extracellular histones are present in biofluids from healthy individuals and become elevated under disease conditions, such as neurodegeneration and cancer. Hence, extracellular histones may have important biological functions in healthy and diseased states, which are not understood. Histones have been reported in the proteomes of extracellular vesicles (EVs), including microvesicles and exosomes. The main aim of this thesis was to determine whether or not extracellular histones are secreted via EVs/exosomes.In an initial study (Paper I), I optimized methods for human embryonic kidney (HEK293) cell culture, transfection and protein detection using western blotting.In the main study (Paper II), I used oligodendrocyte cell lines (rat OLN-93 and mouse Oli-neu) to investigate the localization of histones to EVs. Western blotting of EVs purified from OLN-93 cell-conditioned media confirmed the presence of linker and core histones in them. Immunolocalization and transmission electron microscopy confirmed that histones are localized to EVs, as well as intraluminal vesicles (ILVs) within multivesicular bodies (MVBs). This suggests that histones are secreted via the MVB/exosome pathway.Localization of histones in EVs was investigated by biochemical/proteolytic degradation and purification followed by western blotting. Surprisingly, histones were associated with the membrane but not the luminal fraction. Overexpression of tagged histones in HEK293 cells confirmed their conserved, membrane localization. OLN-93 cell EVs contained both double stranded and single stranded DNA but nuclease and protease digestion showed that the association of histones and DNA with EVs was not interdependent.The abundance of histones in EVs was not affected by differentiation in Oli-neu cells. However, histone release was upregulated as an early response to cellular stress in OLN-93 cells and occurred before the release of markers of stress including heat shock proteins. Interestingly, a notable upregulation in secretion of small diameter (50-100 nm) EVs was observed following heat stress, suggesting that a sub-population of vesicles may be involved specifically in histone secretion in response to stress. Proteomic analyses identified the downregulation of endosomal sorting complex required for transport (ESCRT) as a possible mechanism underlying increased histone secretion.In Paper III, I developed methods to quantify extracellular histone proteins in human ascites samples from ovarian cancer patients. In summary, we show for the first time that membrane-associated histones are secreted via the MVB/exosome pathway. We demonstrate a novel pathway for extracellular histone release that may have a role in both health and disease. </p

Role of pro-inflammatory S100A9 protein in amyloid-neuroinflammatory cascade in Alzheimer’s disease and traumatic brain injury [Elektronisk resurs]

Background Traumatic brain injury (TBI) is a complex disease with a spectrum of symptoms and disabilities. Over the past decade TBI has become the focus of research due to growing epidemiological and clinical evidences that TBI incidences are strong risk factors for Alzheimer’s disease (AD). Major pathological hallmarks of AD are massive accumulations of amyloid-β peptide (Aβ) toxic oligomers and plaques. Neuroinflammation is also considered as a common denominator in AD and aging. The epidemiological and experimental studies have supported that non-steroidal anti-inflammatory drugs markedly reduce the age-related prevalence of AD and can slow amyloid deposition by mechanisms that still remain elusive. S100A9 is a multifunctional cytokine with diverse roles in the cell signaling pathways associated with inflammation and cancers. A widespread expression of S100A9 was also reported in many other ailments involving inflammatory processes, such as AD, malaria, cerebral ischemia and TBI, implying that S100A9 may be a universal biomarker of inflammation. The distinctive feature of S100A9 compared to other pro-inflammatory cytokines is its ability to self-assemble into amyloids, which may lead to the loss of its signaling functions and acquired amyloid cytotoxicity, exceeding that of Aβ.Methods S100A9 properties was studied under various ex vivo and in vitro conditions. First, human and mouse tissues with TBI and AD were subjected to microscopic, immunohistochemical and immunofluorescent techniques. Then, aged mouse treated with native, oligomeric and fibrillary S100A9 was also studied by using behavioral and neurochemical analysis. Moreover, S100A9 was established as a biomarker of dementia progression and compared with others such as Aβ42 and tau proteins, by studying cerebrospinal fluid (CSF) samples from different stages of dementia. Finally, in vitro experiments on S100A9 amyloidogenesis, co-aggregation with Aβ40 and Aβ42, digestion and cytotoxicity were also performed by using spectroscopic, atomic force microscopy and cell biology methods.Results S100A9-driven amyloid-neuroinflammatory cascade serves as a link between TBI and AD. We have found that S100A9 contributes to the plaque formation and intraneuronal responses in AD, being a part of the amyloid-neuroinflammatory cascade. In TBI we have found that extensive S100A9 neuronal production and amyloid self-assembly is triggered immediately after injury, leading to apoptotic pathways and neuronal loss. S100A9 is an integral component of both TBI precursor-plaques, formed prior to Aβ deposition, and AD plaques, characterized by different degree of amyloid maturation, indicating that all plaques are associated with inflammation. Both intra- and extracellular amyloid-neuroinflammatory cascades are intertwined and showed similar tendencies in human and mouse tissues in TBI and AD. Ex vivo findings are further supported by in vitro experiments on S100A9 amyloidogenesis, digestion and cytotoxicity. Importantly, being highly amyloidogenic itself, S100A9 can trigger and aggravate Aβ amyloid self-assembly and significantly contribute to amyloid cytotoxicity. Moreover, the CSF dynamics of S100A9 levels matches very closely the content of Aβ42 in AD, vascular dementia and mild cognitive impairment due to AD, emphasizing the involvement of S100A9 together with Aβ in the amyloid-neuroinflammatory cascade in these ailments.Conclusions The conclusions of this thesis is that the inflammatory pathways and S100A9 specifically represent a potential target for the therapeutic interventions during various post-TBI stages and far prior AD development to halt and reverse these damaging processes.</p

Studies on lipid transport and extracellular vesicle production in Caenorhabditis elegans ciliated neurons [Elektronisk resurs]

The cilium is a protrusion of cell membrane. Both the protein and lipid contents of cilia are different from those of other parts of the cell membrane. While the transport of proteins into and out of cilia has been intensively studied, much less is known about how the lipid content of ciliary membranes is regulated. TAT-6 is a P4-family ATPase that is expressed in C. elegans ciliated neurons whose endings are exposed to the environment. To study the function of TAT-6 and that other translocases in lipid transport in C. elegans ciliated neurons, I developed a technique to allow labelling of cilia with lipids. For the first time I used fusogenic liposomes to study the roles of all the TAT proteins in this organism in maintaining the lipid asymmetry in this organelle. Assessment the cilia with these liposomes showed that TAT-5 and TAT-1 translocase activities promote the transport of phosphatidylethanolamine (PE) and phosphatidylserine (PS) respectively and TAT-6 has an overlapping function in transporting both phospholipds. In C. elegans males, certain ciliated neurons release extracellular vesicles (EVs). The cilium is a site of EV biogenesis and shedding. I found that ciliated neurons in tat-6 mutant males produced significantly fewer EVs than those in wild type. tat-1, tat-5 and pad-1 mutants, however, produced far more EVs than those in wild type. PPK-3, CUP-5 and LMP-1 are proteins necessary for endolysosomal trafficking and lysosomes biogenesis, a process in which TAT-1 has previously been shown to function in C. elegans intestinal cells. I found that, like tat-1 mutants, ppk-3, lmp-1 and cup-5 mutant males release significantly greater numbers of EVs from cilia compared with wild-type. I found that increasing and decreasing the cGMP signaling cause defects in the response and turning behavior in male C. elegans respectively. Exposing wild-type males to high levels of 8-Bromoguanosine 3′,5′-cyclic monophosphate strongly reduced response behavior. Males mutant for odr-3, which encodes a G protein were defective in response. Overall my investigations indicate that the regulation of lipid asymmetry and phospholipid transport is required for proper cilia function in C. elegans, that intercellular trafficking and lipid composition have important roles in EVs biogenesis, and that different TAT proteins can affect the size and number of EVs produced. I also showed that in male animals, cGMP is one of the mediators in mating transduction signal and that a high level of cGMP inhibits mating response behavior in male C. elegans. </p

Role of pannexin-1 in the cellular uptake, release and hydrolysis of anandamide by T84 colon cancer cells

AbstractThe large pore ion channel pannexin-1 (Panx1) has been reported to play a role in the cellular uptake and release of anandamide (AEA) in the hippocampus. It is not known whether this is a general mechanism or limited to the hippocampus. We have investigated this pharmacologically using T84 colon cancer cells. The cells expressed Panx1 at the mRNA level, and released ATP in a manner that could be reduced by treatment with the Panx1 inhibitors carbenoxolone and mefloquine and the Panx1 substrate SR101. However, no significant effects of these compounds upon the uptake or hydrolysis of exogenously applied AEA was seen. Uptake by T84 cells of the other main endocannabinoid 2-arachidonoylglycerol and the AEA homologue palmitoylethanolamide was similarly not affected by carbenoxolone or mefloquine. Total release of tritium from [3H]AEA-prelabelled T84 cells over 10 min was increased, rather than inhibited by carbenoxolone and mefloquine. Finally, AEA uptake by PC3 prostate cancer and SH-SY5Y neuroblastoma cells, which express functional Panx1 channels, was not inhibited by carbenoxolone. Thus, in contrast to the hippocampus, Panx1 does not appear to play a role in AEA uptake and release from the cells studied under the conditions used.</jats:p