Project description:CD47 is a transmembrane glycoprotein that is ubiquitously expressed in different organs and tissues (Barclay and Van den Berg 2014; Liu, et al. 2017). In the human immune system, CD47 interacts with some integrins, two counter-receptor signal regulator protein (SIRP) family members, and the secreted thrombospondin-1 (TSP1) (Barclay and Van den Berg 2014; Gao, et al. 2016; Kaur, et al. 2013; Oldenborg, et al. 2000). CD47 has two established roles in the immune system. The CD47-SIRPα interaction was identified as a critical innate immune checkpoint, which delivers an antiphagocytic signal to macrophages and inhibits neutrophil cytotoxicity (Martínez- Sanz, et al. 2021). Its interaction with inhibitory SIRPα is a physiological anti-phagocytic “don’t eat me” signal on circulating red blood cells that is co-opted by cancer cells (Matlung, et al. 2017). Many malignant cells overexpress CD47 (Betancur, et al. 2017; Chao, et al. 2011; Jaiswal, et al. 2009; Majeti, et al. 2009; Oronsky, et al. 2020; Petrova, et al. 2017). CD47/SIRPα-targeted therapeutics have been developed to overcome this immune checkpoint for cancer treatment (Kaur, et al. 2020; Matlung, et al. 2017). Secondly, engagement of CD47 on T cells by TSP1 regulates their differentiation and survival (Grimbert, et al. 2006; Lamy, et al. 2007) and inhibits T cell receptor signaling and antigen presentation by dendritic cells (DCs) (Kaur, et al. 2014; Li, et al. 2002; Liu, et al. 2015; Miller, et al. 2013; Soto-Pantoja, et al. 2014; Weng, et al. 2014). TSP1/CD47 signaling has similar inhibitory functions to limit NK cell activation (Kim, et al. 2008; Nath, et al. 2018; Nath, et al. 2019; Schwartz, et al. 2019) and IL1β production by macrophages (Stein, et al. 2016). CD47 is therefore a checkpoint that regulates both innate and adaptive immunity. The recent understanding of CD47 antagonism associated with increased antigen presentation by DCs (Liu, et al. 2016) and natural killer cell cytotoxicity (Nath, et al. 2019) contributes to the heightened interest in CD47 as a therapeutic target (Kaur, et al. 2020).

Project description:Disruption of the circadian rhythm is associated with inflammatory diseases, metabolic syndrome and cancer. In mice, the time of day strongly influences lethality in response to LPS, with survival greatest at the beginning compared to the end of the light cycle (Halberg et al. 1960; Marpegan et al. 2009; Nguyen et al. 2013). Myeloid-cell intrinsic circadian clock components control inflammatory cytokine production (Gibbs et al. 2012; Curtis et al. 2015; Bellet et al. 2013), and metabolic inputs influence lethality in response to LPS (Wang et al. 2016; Weis et al. 2017; Traba et al. 2017), but the relative contributions of these inputs to daily changes in sepsis susceptibility are not known. Here we show that feeding, rather than light, controls time of day dependent LPS sensitivity. Mortality following LPS administration after 12 hours of food deprivation was associated with hypoglycemia, rather than inflammatory cytokine production, independent of the clock regulator BMAL1 expressed in myeloid cells. Deletion of BMAL1 in hepatocytes globally disrupted the transcriptional response to the feeding cycle in the liver and resulted in constitutively high LPS sensitivity. These results show that food, rather than light, is the ‘zeitgeber’ for acute mortality in response to LPS, with a critical role for the hepatocyte-intrinsic circadian clock in integrating nutritional cues to regulate survival in response to innate immune stimuli. Understanding the hepatic molecular programs operational in response to fasting versus fed cues could identify novel pathways that may be targeted to enhance resistance to endotoxemia.

Project description:Intraocular tuberculosis (IOTB) is a significant cause of visual morbidity in TB-endemic countries. However, pathogenesis of Mycobacterium tuberculosis (M. tb) in the ocular compartment is poorly defined. IOTB is paucibacillary in a vast majority of patients although M. tb has been detected in both the retinal pigment epithelial (RPE) cells (Rao et al. 2006) and in the intraocular fluid (IOF) (Aggarwal et al., 2016; Bajgai et al., 2017) in some cases. In this study, we have examined the replication and whole genome transcriptome of M. tb in an IOF model (artificial IOF; AIOF) (Macri et al., 2015). Results show that, as reported for transcriptional profiles of M. tb in sputum (Sharma et al., 2017) and in a starvation model (PBS) (Betts et al., 2002), genes involved in active replication and aerobic respiration are either downregulated or not differentially expressed in the AIOF. In ARPE-19 cells (human RPE cell line), M. tb replicates poorly and exhibits a quiescent phenotype (Abhishek et al., 2018). As in sputum, PBS, and ARPE-19 cells, M. tb in AIOF downregulates genes of the DosR regulon indicating the suppression of dormancy. Importantly, genes encoding ESAT-6 and ESAT-6-like proteins are also downregulated or not differentially expressed in sputum, AIOF and ARPE-19 cells. This is stark contrast to the transcriptome of M. tb in alveolar epithelial cells (Ryndak et al., 2015) and in blood (Ryndak et al. 2014). These results paint a scenario wherein M. tb acquires a replicative and invasive phenotype when it infects a new host and disseminates systemically. However, M. tb acquires a quiescent phenotype upon reaching its final niche in an extrapulmonary site, the ocular environment.

Project description:Fusarium oxysporum is an worldwide economically important plant fungi pathogen that can cause vascular wilt disease on a wide variety of hosts (Williamson et al., 2007). In recent years, extensive research has been conducted to interpret transcriptional regulation of virulence genes in FO. (Weiberg et al., 2013;Brandhoff et al., 2017;Wang et al., 2017;Wang et al., 2018;Porquier et al., 2019). However, gaps in the protein level studies limited deeper understanding of molecular basis of FO. pathogenesis. In this study, we conducted the first proteome-wide analysis in FO.

Project description:RNA-sequencing data from human iPSC PGP1 cells (n=4) differentiated into mesoderm (day-2) (n=4) or cardiomyocytes (days 25-30) (n=4) through modulation of Wnt/β-catenin signaling as previously described (Cohn et al., 2019; Hinson et al., 2017; Hinson et al., 2015; Lian et al., 2012).

Project description:Regulation of gene expression is a sophisticated process leading to the activation or suppression of genes due to adaptation to environmental stimuli. The membrane-embedded FtsH proteases conserved in bacteria, chloroplasts and mitochondria, are involved in such regulation. The genome of the cyanobacterium Synechocystis sp. PCC 6803 encodes four FtsH homologues FtsH1-4, functioning in the form of oligomeric complexes. Homologue FtsH3 is bound in two hetero-oligomeric complexes, FtsH1/FstH3 and/or FtsH2/FtsH3, respectively. Previous data showed that the FtsH1/FtsH3 complex is involved in the acclimation of cells to iron deficiency by controlling the availability of the transcriptional regulator Fur (Sll0567). To gain more comprehensive insight into the physiological role of FtsH hetero-complexes, we carried out genome-wide expression profiling of a mutant conditionally depleted in FtsH3, grown under nutrient sufficiency and iron depletion. Our results show, that besides Fur, also the SufR and Pho regulons belong to the set of genes controlled by FtsH. Moreover, by combining the transcriptome data with in silico prediction we identified novel targets of Fur in Synechocystis PCC 6803. Fur tends to evoke mostly repression, but also appears to activate some target genes. We monitored the global gene expression in a conditional Synechocystis PCC6083 ftsH knockdown strain (FtsHdown) (Boehm et al., 2012) and a control strain (WT) at standard conditions and at iron depletion. The presence of ammonia to induced the conditional knockdown. Each sample was done in biological replicates.

Project description:S. aureus strain JKD6009 RNase III-HTF and USA300 RNase III-HTF were used in our study to capture the RNA-binding proteome in Staphylococcus aureus. Both strains were inoculated in TSB (Tryptone soya broth, Oxioid CM0129) and overnight cultured in 37°C, 200 rpm shaker. Strain JKD6009 RNase III-HTF was sub-cultured into 190 ml LPM (Coombes et al., 2004) (Low phosphate, low magnesium medium, 5 mM KCl, 7.5 mM (NH4)2SO4, 0.5 mM K2SO4, 8 µM MgCl2, 1 M KH2PO4, 16 mM Tris-HCl, 0.1% casamino acids, 0.3% Glycerol) and grew from OD600 0.01 to 1. Overnight cultures of USA300 RNase III-HTF was re-inoculated to 65 ml fresh TSB to OD600 0.05 and left to grow to an OD600 of ~3. Cells were then filtered through 0.45 µm filters using a vacuum filtration device (UVO3; (McKellar et al., JoVe 2020; Van Nues et al., Nature Communications 2017)) shifted to same volume of LPM medium for 15 min at 37ºC and UV irradiated in LPM in the Vari-X-linker (λ =254 nm) (https://www.vari-x-link.com; (McKellar et al., 2020; Van Nues et al., 2017)) with an energy dose of 2J/cm2. In total, 6 replicates were collected (three technical and two biological replicates) for each experiment.

Project description:S. aureus strain JKD6009 RNase III-HTF and USA300 RNase III-HTF were used in our study to capture the RNA-binding proteome in Staphylococcus aureus. Both strains were inoculated in TSB (Tryptone soya broth, Oxioid CM0129) and overnight cultured in 37°C, 200 rpm shaker. Strain JKD6009 RNase III-HTF was sub-cultured into 190 ml LPM (Coombes et al., 2004) (Low phosphate, low magnesium medium, 5 mM KCl, 7.5 mM (NH4)2SO4, 0.5 mM K2SO4, 8 µM MgCl2, 1 M KH2PO4, 16 mM Tris-HCl, 0.1% casamino acids, 0.3% Glycerol) and grew from OD600 0.01 to 1. Overnight cultures of USA300 RNase III-HTF was re-inoculated to 65 ml fresh TSB to OD600 0.05 and left to grow to an OD600 of ~3. Cells were then filtered through 0.45 µm filters using a vacuum filtration device (UVO3; (McKellar et al., JoVe 2020; Van Nues et al., Nature Communications 2017)) shifted to same volume of LPM medium for 15 min at 37ºC and UV irradiated in LPM in the Vari-X-linker (λ =254 nm) (https://www.vari-x-link.com; (McKellar et al., 2020; Van Nues et al., 2017)) with an energy dose of 2J/cm2. In total, 6 replicates were collected (three technical and two biological replicates) for each experiment.

Project description:S. aureus strain JKD6009 RNase III-HTF and USA300 RNase III-HTF were used in our study to capture the RNA-binding proteome in Staphylococcus aureus. Both strains were inoculated in TSB (Tryptone soya broth, Oxioid CM0129) and overnight cultured in 37°C, 200 rpm shaker. Strain JKD6009 RNase III-HTF was sub-cultured into 190 ml LPM (Coombes et al., 2004) (Low phosphate, low magnesium medium, 5 mM KCl, 7.5 mM (NH4)2SO4, 0.5 mM K2SO4, 8 µM MgCl2, 1 M KH2PO4, 16 mM Tris-HCl, 0.1% casamino acids, 0.3% Glycerol) and grew from OD600 0.01 to 1. Overnight cultures of USA300 RNase III-HTF was re-inoculated to 65 ml fresh TSB to OD600 0.05 and left to grow to an OD600 of ~3. Cells were then filtered through 0.45 µm filters using a vacuum filtration device (UVO3; (McKellar et al., JoVe 2020; Van Nues et al., Nature Communications 2017)) shifted to same volume of LPM medium for 15 min at 37ºC and UV irradiated in LPM in the Vari-X-linker (λ =254 nm) (https://www.vari-x-link.com; (McKellar et al., 2020; Van Nues et al., 2017)) with an energy dose of 2J/cm2. In total, 6 replicates were collected (three technical and two biological replicates) for each experiment.

Project description:Lewy body (LB) pathology and loss of dopaminergic neurons are imprints of Parkinson’s disease (PD). LBs are mainly comprised of alpha-Synuclein (Dijkstra et al., 2014). Strolling detection of LBs in brain regions contribute to progressive construct of PD pathology to which molecular mechanisms are not clear (H. Braak & Del Tredici, 2017). Two key facets of LB formation are protein aggregation via misfolding and transmission of misfoldled proteins to various brain regions, eventually causing neuronal death (Goedert, Spillantini, Del Tredici, & Braak, 2013; Pacelli et al., 2015). Misfolding requires alterations in intracellular physiology (Carbone, Costa, Provensi, Mannaioni, & Masi, 2017; Funes et al., 2014; Guzman et al., 2018; Pacelli et al., 2015) and detection of misfolded proteins in exosomes confirms exosomatic transmission (Ngolab et al., 2017). High levels of neurotropic-factors (Brockmann et al., 2017) and changes in bioenergetics are found in PD patients, these can bring physiological alterations (Smith et al., 2018). En masse, these evidences and hipocampal association with synucleopathies (Flores-Cuadrado, Ubeda-Bañon, Saiz-Sanchez, de la Rosa-Prieto, & Martinez-Marcos, 2016) allowed us to probe other volunerable PD proteins in cell-lysate and exosomal proteomes of bFGF treated hippocampal neurons. Using WPCNA we developed co-expression modules and spotted many PD related proteins; which can act as precursors during diseased or onset stage.