Project description:Infection with Mycobacterium tuberculosis (M. tb) is initiated when an aerosol droplet carrying a few bacilli is inhaled into an alveolus. Alveolar epithelial cells (AEC) (type II and type I) are among the first cells encountered by the infecting bacteria and greatly outnumber macrophages in the alveolus. M. tb replicates dramatically (>20,000 fold) in a “non-migrating” compartment in the lung prior to the development of the cell-mediated immune response in aerosol-infected mice (Wolf AJ, 2008). M. tb DNA has been found in type II AEC in autopsied lung tissue of latently infected individuals (Hernandez-Pando R et. al, 2000; Barrios-Payan J et. al 2012), and M. tb-infected AEC in broncho-alveolar lavage (BAL) and in sputum samples from TB patients indicates the infection of these cells in active as well as latent human TB (Eum SY et. al, 2010). M. tb has been shown to infect and replicate in the human type II AEC line, A549, and passaging of M. tb through A549 increases M. tb invasiveness (Bermudez LE et.al, 2002). In this work, we have used DNA microarray analysis to investigate the transcriptome of M. tb replicating in type II AEC (A549) compared to M. tb grown logarithmically in Middlebrook 7H9 broth media in order to identify M. tb adaptations to this intracellular environment as well as M. tb mechanisms/factors contributing to M. tb replication and increased invasiveness in primary infection.

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:Infection with Mycobacterium tuberculosis (M. tb) is initiated when an aerosol droplet carrying a few bacilli is inhaled into an alveolus. Alveolar epithelial cells (AEC) (type II and type I) are among the first cells encountered by the infecting bacteria and greatly outnumber macrophages in the alveolus. M. tb replicates dramatically (>20,000 fold) in a “non-migrating” compartment in the lung prior to the development of the cell-mediated immune response in aerosol-infected mice (Wolf AJ, 2008). M. tb DNA has been found in type II AEC in autopsied lung tissue of latently infected individuals (Hernandez-Pando R et. al, 2000; Barrios-Payan J et. al 2012), and M. tb-infected AEC in broncho-alveolar lavage (BAL) and in sputum samples from TB patients indicates the infection of these cells in active as well as latent human TB (Eum SY et. al, 2010). M. tb has been shown to infect and replicate in the human type II AEC line, A549, and passaging of M. tb through A549 increases M. tb invasiveness (Bermudez LE et.al, 2002). In this work, we have used DNA microarray analysis to investigate the transcriptome of M. tb replicating in type II AEC (A549) compared to M. tb grown logarithmically in Middlebrook 7H9 broth media in order to identify M. tb adaptations to this intracellular environment as well as M. tb mechanisms/factors contributing to M. tb replication and increased invasiveness in primary infection. The global gene expression of M. tb H37Rv replicating in A549 cells at 72 hr was compared to that of M. tb grown to log phase in Middlebrook 7H9 media.

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: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: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.

Project description:Canonical auxin signalling starts with auxin binding to the receptor complex, followed by modulation of gene transcription and protein abundance (Tan et al., 2007; Chapman and Estelle, 2009; Slade et al., 2017). However, recent studies also showed an alternative mechanism in roots involving intra-cellular auxin perception, but not transcriptional reprogramming (Fendrych et al., 2018). Despite knowledge on effects of auxin on Arabidopsis root growth at the protein and phosphorylation level is increasing (Zhang et al., 2013; Mattei et al., 2013; Slade et al., 2017), it still remains incomplete. To address this gap in our knowledge, we explored the impact of auxin on the root tip proteome and phosphoproteome.

Project description:Reanalysis of some Hi-C from Bonev et al. 2017 with HiCUP v0.9.2

Project description:The goal of this study is to molecularly characterize regulatory variation in pancreatic progenitor cells (PPC). Here, we derived PPC from iPSCs of nine iPSCORE individuals (DeBoever et al., 2017; Panopoulos et al., 2017), and generated RNA-seq, ATAC-seq, scRNA-seq, and snATAC-seq. We strive to understand the role of functional genetic variation during fetal pancreatic development that later give rise to adult pancreatic diseases.

Project description:Reanalysis of some Hi-C from Bonev et al. 2017 with HiCUP version 0.6.1