Cardiac sodium channel palmitoylation regulates channel function and cardiac excitability with implications for arrhythmia generation

Pei, Zifan

09 December 2016

Indiana University-Purdue University Indianapolis (IUPUI) / The  cardiac  voltage-­gated  sodium  channels  (Nav1.5)  play  a  specific  and   critical  role  in  regulating  cardiac  electrical  activity  by  initiating  and  propagating   action  potentials  in  the  heart.  The  association  between  Nav1.5  dysfunctions  and   generation  of  various  types  of  cardiac  arrhythmia  disease,  including  long-­QT3   and  Brugada  syndrome,  is  well  established.  Many  types  of  post-­translational   modifications  have  been  shown  to  regulate  Nav1.5  biophysical  properties,   including  phosphorylation,  glycosylation  and  ubiquitination.  However,  our   understanding  about  how  post-­translational  lipid  modification  affects  sodium   channel  function  and  cellular  excitability,  is  still  lacking.  The  goal  of  this   dissertation  is  to  characterize  Nav1.5  palmitoylation,  one  of  the  most  common   post-­translational  lipid  modification  and  its  role  in  regulating  Nav1.5  function  and   cardiac  excitability.     In  our  studies,  three  lines  of  biochemistry  evidence  were  shown  to  confirm   Nav1.5  palmitoylation  in  both  native  expression  background  and  heterologous   expression  system.  Moreover,  palmitoylation  of  Nav1.5  can  be  bidirectionally   regulated  using  2-­Br-­palmitate  and  palmitic  acid.  Our  results  also  demonstrated   that  enhanced  palmitoylation  in  both  cardiomyocytes  and  HEK293  cells   increases  sodium  channel  availability  and  late  sodium  current  activity,  leading  to   enhanced  cardiac  excitability  and  prolonged  action  potential  duration.  In  contrast,   blocking  palmitoylation  by  2-­Br-­palmitiate  increases  closed-­state  channel inactivation  and  reduces  myocyte  excitability.  Our  computer  simulation  results   confirmed  that  the  observed  modification  in  Nav1.5  gating  properties  by  protein   palmitoylation  are  adequate  for  the  alterations  in  cardiac  excitability.  Mutations  of   potential  palmitoylation  sites  predicted  by  CSS-­Palm  bioinformatics  tool  were   introduced  into  wild-­type  Nav1.5  constructs  using  site-­directed  mutagenesis.   Further  studies  revealed  four  cysteines  (C981,  C1176,  C1178,  C1179)  as   possible  Nav1.5  palmitoylation  sites.  In  particular,  a  mutation  of  one  of  these   sites(C981)  is  associated  with  cardiac  arrhythmia  disease.  Cysteine  to   phenylalanine  mutation  at  this  site  largely  enhances  of  channel  closed-­state   inactivation  and  ablates  sensitivity  to  depalmitoylation.  Therefore,  C981  might  be   the  most  important  site  that  regulates  Nav1.5  palmitoylation.  In  summary,  this   dissertation  research  identified  novel  post-­translational  modification  on  Nav1.5   and  revealed  important  details  behind  this  process.  Our  data  provides  new   insights  on  how  post-­translational  lipid  modification  alters  cardiomyocyte   excitability  and  its  potential  role  in  arrhythmogenesis.

Cardiac arrhythmia

Ion channelopathy

Palmitoylation

Voltage-gated sodium channel

Post-translational modification

Regulation of Protein Arginine Methyl Transferase 5 by Novel Serine 15 Phosphorylation in Colorectal Cancer

Hartley, Antja-Voy Anthoneil

01 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The overexpression of protein arginine methyltransferase 5 (PRMT5) is strongly correlated to poor clinical outcomes for colorectal cancer (CRC) patients. Previously, we demonstrated that PRMT5 overexpression could substantially augment activation of NF-κB via methylation of arginine 30 (R30) on its p65 subunit, while knockdown of PRMT5 showed the opposite effect on the transcriptional competence of p65. However, the precise mechanisms governing this PRMT5/NF-κB axis are still largely unknown. We report a novel finding that PRMT5 is phosphorylated on serine 15 (S15) in response to interleukin-1β (IL-1β) stimulation. Overexpression of the serine-to-alanine mutant of PRMT5 (S15A-PRMT5), in either HEK293 cells or HT29, DLD1 and HCT116 CRC cells attenuated NF-κB activation compared to wild type (WT)-PRMT5, confirming that S15 phosphorylation is critical for the activation of NF-κB by PRMT5. Furthermore, we found that overexpression of S15A-PRMT5 mutant attenuated the expression of a subset of NF-κB target genes through decreased p65 occupancy at their respective promoters. Importantly, the S15A-PRMT5 mutant also reduced IL-1β-induced methyltransferase activity of PRMT5 as well as its ability to form a complex with p65. Finally, we observed that the S15A-PRMT5 mutant diminished the growth, migratory and colony-forming abilities of CRC cells compared to the WT-PRMT5. Collectively, our findings provide strong evidence that novel phosphorylation of PRMT5 at S15 is critical to its regulation of NF-κB and plays an essential role in promoting the cancer-associated functions exerted by the PRMT5/NF-κB axis. Therefore, development of inhibitors to block phosphorylation of PRMT5 at S15 could become a potential novel therapeutic approach to treat CRC. / 2020-10-15

Colorectal cancer

NF-KB

post-translational modification

PRMT5 phosphorylation

Serine 15

Epigenetic regulations in cell wall degradation and regeneration in Oryza sativa

Tan, Feng

06 August 2011

It is well known that chromatin components are key players in establishing and maintaining spatial and temporal gene expression in plants, however, little is known about the epigenetic regulation on cell wall degradation and regeneration. This study aimed to 1) investigate the global proteome and phosphoproteome of rice chromatin, and 2) characterize changes in chromatin components and chromatin structure associated with cell wall degradation and regeneration, and 3) characterize the differentially regulated proteins and eventually explore the mechanism. In this dissertation, we examine proteins copurified with chromatin using both 2-DE gel and shotgun approaches from rice (Oryza sativa) suspension cells. Nine hundred seventy-two distinct protein spots were resolved on 2-DE gels and 509 proteins were identified by MALDI-MS/MS following gel excision, these correspond to 269 unique proteins. When the chromatin copurified proteins are examined using shotgun proteomics, a large number of histone variants in addition to the four common core histones were identified. Furthermore, putative phosphoproteins copurified with chromatin were examined using Pro-Q Diamond phosphoprotein stain and followed by MALDI-MS/MS. Our studies provided new insights into the chromatin composition in plants. To study the epigenetic regulation of the cell wall degradation and regeneration, we examined cellular responses to the enzymatic removal of the cell wall in rice suspension cells using proteomic approaches. We found that removal of cell wall stimulates cell wall synthesis from multiple sites in protoplasts instead of from a single site as in cytokinesis. Microscopy examination and chromatin decondensation assay further showed that removal of the cell wall is concomitant with substantial chromatin reorganization. Histone post-translational modification studies using both Western blots and isotope labeling assisted quantitative mass spectrometry analyses revealed substantial histone modification changes, particularly H3K18AC and H3K23AC, are associated with the degradation and regeneration of the cell wall. Labelree comparative proteome analyses further revealed that chromatin associated proteins undergo dramatic changes upon removal of the cell wall, particularly cytoskeleton, cell wall metabolism, and stress-response proteins. This study demonstrates that cell wall removal is associated with substantial chromatin change and may lead to stimulation of cell wall synthesis using a novel mechanism.

LC-MS

2-DE

histone post-translational modification

proteomics

cell wall

regeneration

epigenetics

Characterization of the Role of Testis-Specific Serine Kinase1 (tssk1) in Human Sperm Capacitation

Chicoine, Kay-ellen

01 January 2013

The ability of a sperm to fertilize an egg involves a complex series of events, referred to as capacitation. Capacitation involves sperm acquiring a hyperactive state of motility and the ability to undergo an exocytotic process called the acrosome reaction (AR). Molecular intervention of cell signaling pathways involved in sperm capacitation has been proposed as a way for developing novel male contraceptives. Testis-specific serine kinase1 (TSSK1) is a novel protein in the calcium/calmodulin superfamily of human kinases, and has the potential for targeted inhibition to provide a highly safe and effective form of male contraception. It is expressed post-meiotically during spermatogenesis, and is localized to the head and tail of the mature sperm. Tssk1/Tssk2 knockout (KO) mouse models have demonstrated that these proteins are necessary for sperm function as deletion of these genes have rendered male mice infertile. Studies presented here involve the investigation of the biochemical regulation of TSSK1 and its role in human sperm capacitation. Posttranslational modification of TSSK1 was analyzed in capacitated human sperm in the presence or absence of AR inducers in vitro. Furthermore, experimental conditions were tested for measuring TSSK1 enzymatic activity in capacitated human sperm, and TSSK1 kinase activity was further correlated to the observed phosphorylation/dephosphorylation. Lastly, a computer-aided sperm analysis (CASA) protocol for assessing human sperm motility was standardized. Human sperm cell subpopulations were evaluated under different sperm capacitating conditions, and a Boolean argument was created to quantify progressive and non-progressive hyperactive cells. Determining TSSK1’s regulation by posttranslational modifications will help further characterize this protein as a potential target for inhibition and, ultimately, for use as a novel technique of male contraception. Improved conditions for human sperm analysis by CASA may provide a tool for assessing a potential role of TSSK1 in human sperm motility and hyperactivation.

kinase

TSSK1

human

sperm

post-translational modification

CASA

Cell Biology

Molecular Biology

Regulation of Rice Flowering Time and Seed Development

Meng, Xiaoxi

10 August 2018

Rice is one of the most important cereal crops for the world population. Flowering time and seed development of rice are directly related to plant regional and ecological adaptions, and productive yield. In this dissertation, to gain knowledge of seed development in rice, the status of post-translational modifications (PTMs) in developing rice seeds was investigated. Numerous modified lysine sites in developing rice seeds were identified utilizing antibody-based affinity enrichment approaches and nano-HPLC/MS/MS analyses of acetylated, succinylated, crotonylated and 2-hydroxyisobutyrylated peptides. Functional annotation analyses indicated that a wide variety of vital biological processes were targeted by lysine PTMs. A number of modified histone and non-histone proteins were found to harbor multiple PTMs, and our findings showed that many modified histone sites were conserved across plant, human, and animal systems. Comprehensive analyses of lysine modification sites illustrated that the sites were highly sequence-specific for distinct motifs. Overall, this study provides a systematic analysis of lysine PTM proteome in plants, which will serve as the basis for future investigations of the regulatory mechanisms and functions of lysine PTMs. The mechanisms of flowering time variances in response to different photoperiods were further studied in the rice mutant, HSS. QTL-seq analysis identified a major effect on chromosome 6 responsible for the phenotypic divergence between Nipponbare (wild-type) and HSS rice. Sequence and mRNA expression analyses confirmed that allelic variants of Hd1 make HSS plants less sensitive to photoperiod by altering expression level of Hd3a. Diurnal expression pattern analyses revealed that DTH8 transcripts were largely affected by Hd1 expression level in both LD and SD. This result suggested that Hd1 may able to regulate DTH8 and DTH8-Hd1 complex abundance in response to day length in rice flowering time regulation. In addition, we discussed the functions of PTMs in flowering time regulation in rice.

rice

QTL mapping

QTL-seq

post-translational modification

proteome

whole genome resequencing

Proteomic Based Approaches for Differentiating Tumor Subtypes

Wang, Linan

23 May 2017

No description available.

Biomedical Research

Proteomics

Mass Spectrometry

Thymus

Thymoma

Histones

Biomarker

Cancer

Pathology

Post- Translational Modification

Acetylation

Synthetic Tools for the Preparation of Modified Histones

Shimko, John C.

19 December 2011

No description available.

Biochemistry

histone

post-translational modification

peptide synthesis

native chemical ligation

total synthesis

Mass Spectrometric Analysis of Tyrosine Metabolic Enzymes

Vavricka, Christopher John

25 August 2009

The metabolism of tyrosine is essential for many critical biochemical events including catecholamine synthesis, melanogenesis and insect cuticle sclerotization. These pathways are highly regulated in both insects and mammals by many well-characterized enzymes including dopa decarboxylase and tyrosine hydroxylase. On the other hand, there are still many enzymes involved in these processes that we know very little about. Dopachrome tautomerase (DCT), dopachrome conversion enzyme (DCE) and α-methyldopa resistant protein (AMD) fall into the category of the less characterized enzymes. Dopachrome is a pivotal intermediate in melanogenesis. Mammalian DCT and insect DCE both use dopachrome as a substrate. DCE catalyzes a decarboxylative structural rearrangement of dopachrome to 5,6-dihydroxyindole (DHI), whereas DCT mediates the isomerization/tautomerization of dopachrome to 5,6-dihydroxyindole-2-carboxylic acid (DHICA). DHI is oxidized easily, leading to the production of melanin, as well as reactive oxygen species (ROS). DHICA is less reactive, relative to DHI, and consequently produces less toxic byproducts during melanogenesis; therefore DCT plays an important role in detoxification of DHI and ROS. Purification and MS analysis of DCE and DCT determined that N-glycosylation is a primary post-translational modification. Q-TOF mass spectrometry was used to determine N-glycosylation patterns from Aedes aegypti DCE and MALDI-TOF/TOF was used to determine multiple glycosylation sites in DCT. N-glycosylation is critical for the folding and trafficking of secreted proteins in the endomembrane system. The analysis of glycosylation sites in DCE and DCT therefore is essential toward achieving a comprehensive understanding of their structure and function. Like DCT, AMD also plays a protective role. The AMD protein was originally identified in Drosophila mutants hypersensitive to α-methyldopa, an inhibitor of dopa decarboxylase (DDC). Production of dopamine by DDC is critical for developing insects because dopamine conjugates are used as crosslinking agents for cuticle sclerotization. Although there has been much discussion into the function of AMD, what exactly this protein does has been unknown. AMD shares 48% sequence identity with DDC, however we have found that AMD is an enzyme, which possesses a different catalytic activity. GC-MS analysis of AMD enzymatic reaction components revealed that AMD catalyzes the oxidative decarboxylation of L-DOPA to DOPAL, and also the oxidative decarboxlation of α-methyldopa to 3,4-dihydroxyphenylacetone. In summary, multiple N-glycosylation sites were characterized in DCT and DCE, furthermore a new protein function has been demonstrated for AMD. These experiments were performed using classical biochemistry techniques in combination with mass spectrometry. / Ph. D.

tyrosine metabolism

mass spectrometry

proteomics

dopamine

alpha-methyldopa

melanogenesis

dopachrome

glycosylation

post-translational modification

Loss of Tiparp results in aberrant layering of the cerebral cortex

Grimaldi, Giulia, Vagaska, B., Ievglevskyi, O., Kondratskaya, E., Glover, J.C., Matthews, J.

11 August 2019

Yes / 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD)-inducible poly-ADP-ribose polymerase (TIPARP) is an enzyme that adds a single ADP-ribose moiety to itself or other proteins. Tiparp is highly expressed in the brain; however, its function in this organ is unknown. Here, we used Tiparp–/– mice to determine Tiparp’s role in the development of the prefrontal cortex. Loss of Tiparp resulted in an aberrant organization of the mouse cortex, where the upper layers presented increased cell density in the knock-out mice compared with wild type. Tiparp loss predominantly affected the correct distribution and number of GABAergic neurons. Furthermore, neural progenitor cell proliferation was significantly reduced. Neural stem cells (NSCs) derived from Tiparp–/– mice showed a slower rate of migration. Cytoskeletal components, such as α-tubulin are key regulators of neuronal differentiation and cortical development. α-tubulin mono-ADP ribosylation (MAR) levels were reduced in Tiparp–/– cells, suggesting that Tiparp plays a role in the MAR of α-tubulin. Despite the mild phenotype presented by Tiparp–/– mice, our findings reveal an important function for Tiparp and MAR in the correct development of the cortex. Unravelling Tiparp’s role in the cortex, could pave the way to a better understanding of a wide spectrum of neurological diseases which are known to have increased expression of TIPARP. / European Union Seventh Framework Program (FP7-PEOPLE-2013-COFUND) Grant n609020-Scientia Fellows (to G.G.) and by the Johan Throne Holst Foundation and the University of Oslo (J.M.).

Cortex

Cortex layering

Mono-ADP ribosylation

PARP

Post-translational modification

Tiparp

Regulation of E2F-1 by methylation and NEDDylation

Loftus, Sarah Jane

January 2012

E2F-1 has a central role in cell cycle orchestration, and its activity is tightly regulated. One of the ways E2F-1 activity is controlled is by direct modification by post translational modifications such as acetylation, ubiquitination and phosphorylation. Here it was demonstrated that E2F-1 is targeted by two novel modifications, namely methylation by Set7/9 and NEDDylation, both within the DNA binding and heterodimerisation domain of the protein. NEDDylation and methylation of E2F-1 both decrease the stability and diminish the transcriptional activity of E2F-1. Lysine residues in E2F-1 involved in NEDDylation are also targeted by methylation, allowing the potential for interplay between these modifications. Methylation of E2F-1 was demonstrated to be a prerequisite for its NEDDylation and the multi-domain protein UHRF1 implicated in mediating this effect. The results define a new level of control on E2F-1 and suggest a protein code with pleiotropic effects involved in E2F-1 regulation.

571.6