Mutation Of Arginine Research Articles

Charge Reversal of the Uppermost Arginine in Sliding Helix S4-I Affects Gating of Cardiac Sodium Channel.

Several mutations of the uppermost arginine, R219, in the voltage-sensing sliding helix S4I of cardiac sodium channel Nav1.5 are reported in the ClinVar databases, but the clinical significance of the respective variants is unknown (VUSs). AlphaFold 3 models predicted a significant downshift of S4I in the R219C VUS. Analogous downshift S4I, upon its in silico deactivation, resulted in a salt bridge between R219 and the uppermost glutamate, E161, in helix S2I. To understand how salt bridge elimination affects biophysical characteristics, we generated mutant channel R219E, expressed it in the HEK293-T cells, and employed the patch-clamp method in a whole-cell configuration. Mutation R219E did not change the peak current density but shortened time to the peak current at several potentials, significantly enhanced activation, enhanced steady-state inactivation and steady-state fast inactivation, and slowed recovery from inactivation. Taken together, these data suggest that mutation R219E destabilized the resting state of Nav1.5. Cardiac syndromes associated with mutations R219P/H/C/P or E161Q/K are consistent with the observed changes of biophysical characteristics of mutant channel R219E suggesting pathogenicity of the respective VUSs, as well as ClinVar-reported VUSs involving arginine or glutamate in homologous positions of several Nav1.5 paralogs.

A Conserved Di-Lysine Motif in the E2 Transactivation Domain Regulates MmuPV1 Replication and Disease Progression.

The papillomavirus E2 protein regulates the transcription, replication, and segregation of viral episomes within the host cell. A multitude of post-translational modifications have been identified which control E2 functions. A highly conserved di-lysine motif within the transactivation domain (TAD) has been shown to regulate the normal functions of the E2 proteins of BPV-1, SfPV1, HPV-16, and HPV-31. This motif is similarly conserved in the E2 of the murine papillomavirus, MmuPV1. Using site-directed mutagenesis, we show that the first lysine (K) residue within the motif, K112, is absolutely required for E2-mediated transcription and transient replication in vitro. Furthermore, mutation of the second lysine residue, K113, to the potential acetyl-lysine mimic glutamine (Q) abrogated E2 transcription and decreased transient replication in vitro, while the acetylation defective arginine (R) mutant remained functional. Both K113 mutants were able to induce wart formation in vivo, though disease progression appeared to be delayed in the K113Q group. These findings suggest that acetylation of K113 may act as a mechanism for repressing MmuPV1 E2 activity.

Insights into the regulation of CHIP E3 ligase-mediated ubiquitination of neuronal protein BNIP-H.

BCL2/adenovirus E1B 19-kDa protein-interacting protein 2 homolog (BNIP-H or Caytaxin), a pivotal adaptor protein that facilitates cerebellar cortex growth and synaptic transmission, is posttranslationally modified to regulate neuronal function. This study reports the ubiquitination of BNIP-H by Carboxyl terminus of Hsc70-Interacting Protein (CHIP), a U-box containing E3 ligase that is also regulated via autoubiquitination. Specifically, it was observed that CHIP autoubiquitinated itself primarily at Lys23 and Lys31 in vitro. Mutation of these residues shows the autoubiquitination of successive lysines of CHIP. In total, nine lysines on CHIP were identified as the autoubiquitination sites, the collective mutation of which almost completely terminated its autoubiquitination. Additionally, CHIP-mediated ubiquitination of BNIP-H is completely inhibited when BNIP-H bears arginine mutations at four key lysine residues. Next, using hydrogen deuterium exchange mass spectrometry, a model of a plausible mechanism was proposed. The model suggests transient N-terminal interactions between the CHIP and BNIP-H which allows for the swinging of U-box domain of CHIP to ubiquitinate BNIP-H. Following complex dissociation, BNIP-H population is regulated via the ubiquitin-proteasome pathway. Collectively, these results aid in our understanding of CHIP-mediated BNIP-H ubiquitination and provide further insight into the roles of these proteins in neuritogenesis and neurotransmission.

TMIC-62. INVESTIGATING THE ROLE OF OSTEOPONTIN IN RADIORESISTANCE OF H3.3-G34R PEDIATRIC HIGH-GRADE GLIOMA

Abstract Pediatric high-grade gliomas (pHGGs) are currently the leading cause of cancer-related deaths in children. Around 15% of pHGGs harbor a glycine to arginine (G34R) mutation in histone H3.3. Gliomas in general, including H3.3-G34R gliomas, contain cell populations that are resistant to chemotherapy and radiation therapy. These resistant cell populations are responsible for tumor recurrence seen in over 90% of patients within two years after treatment. Uncovering molecular mechanisms responsible for radiation resistance is essential for the development of new targeted therapies against glioma. In our lab’s H3.3-G34R mouse model, we have observed mice that are both radioresistant and radiosensitive. In order to investigate potential mechanisms of resistance leading to this phenotype, we performed single-cell RNA sequencing (scRNA-seq) on 3 non-treated (NT) glioma-bearing mice, 3 mice resistant to treatment (R), and 3 mice susceptible to treatment (S). The scRNA-seq data was processed and filtered using FastQC, Cellranger, CellBender, and DoubletFinder before downstream analysis. Ligand-receptor interaction analysis using CellChat in conjunction with differential expression analysis demonstrated differential expression and secretion of a cytokine known as Secreted Phosphoprotein 1 (SPP1)/Osteopontin (OPN) from tumor-associated microglia and macrophages. Current literature on SPP1 has suggested that its expression may play a role in tumor aggressiveness. However, there is conflicting evidence regarding its mechanism of action when secreted from tumor-associated microglia and macrophages. Additionally, its role in radioresistance has yet to be fully explored. We will present data utilizing in vitro and in vivo experimentation to elucidate the role that differential expression of SPP1 may play in the radioresistance of our H3.3-G34R mouse model. Supported by grants from NIH-NINDS, the Pediatric Brain Tumor Foundation, and Ian’s Friends Foundation

Crotonylation of NAE1 Modulates Cardiac Hypertrophy via Gelsolin Neddylation.

Cardiac hypertrophy and its associated remodeling are among the leading causes of heart failure. Lysine crotonylation is a recently discovered posttranslational modification whose role in cardiac hypertrophy remains largely unknown. NAE1 (NEDD8 [neural precursor cell expressed developmentally downregulated protein 8]-activating enzyme E1 regulatory subunit) is mainly involved in the neddylation modification of protein targets. However, the function of crotonylated NAE1 has not been defined. This study aims to elucidate the effects and mechanisms of NAE1 crotonylation on cardiac hypertrophy. Crotonylation levels were detected in both human and mouse subjects with cardiac hypertrophy through immunoprecipitation and Western blot assays. Tandem mass tag (TMT)-labeled quantitative lysine crotonylome analysis was performed to identify the crotonylated proteins in a mouse cardiac hypertrophic model induced by transverse aortic constriction. We generated NAE1 knock-in mice carrying a crotonylation-defective K238R (lysine to arginine mutation at site 238) mutation (NAE1 K238R) and NAE1 knock-in mice expressing a crotonylation-mimicking K238Q (lysine to glutamine mutation at site 238) mutation (NAE1 K238Q) to assess the functional role of crotonylation of NAE1 at K238 in pathological cardiac hypertrophy. Furthermore, we combined coimmunoprecipitation, mass spectrometry, and dot blot analysis that was followed by multiple molecular biological methodologies to identify the target GSN (gelsolin) and corresponding molecular events contributing to the function of NAE1 K238 (lysine residue at site 238) crotonylation. The crotonylation level of NAE1 was increased in mice and patients with cardiac hypertrophy. Quantitative crotonylomics analysis revealed that K238 was the main crotonylation site of NAE1. Loss of K238 crotonylation in NAE1 K238R knock-in mice attenuated cardiac hypertrophy and restored the heart function, while hypercrotonylation mimic in NAE1 K238Q knock-in mice significantly enhanced transverse aortic constriction-induced pathological hypertrophic response, leading to impaired cardiac structure and function. The recombinant adenoviral vector carrying NAE1 K238R mutant attenuated, while the K238Q mutant aggravated Ang II (angiotensin II)-induced hypertrophy. Mechanistically, we identified GSN as a direct target of NAE1. K238 crotonylation of NAE1 promoted GSN neddylation and, thus, enhanced its protein stability and expression. NAE1 crotonylation-dependent increase of GSN promoted actin-severing activity, which resulted in adverse cytoskeletal remodeling and progression of pathological hypertrophy. Our findings provide new insights into the previously unrecognized role of crotonylation on nonhistone proteins during cardiac hypertrophy. We found that K238 crotonylation of NAE1 plays an essential role in mediating cardiac hypertrophy through GSN neddylation, which provides potential novel therapeutic targets for pathological hypertrophy and cardiac remodeling.

Effect of an essential arginine mutation (R473C) on the catalytic reaction of cytochrome c oxidase from Paracoccus denitrificans. Characterization through UV/Vis and electrochemical-FTIR spectroscopy

Effect of an essential arginine mutation (R473C) on the catalytic reaction of cytochrome c oxidase from Paracoccus denitrificans. Characterization through UV/Vis and electrochemical-FTIR spectroscopy

Novel mutations in acetolactate synthase confer high levels of resistance to tribenuron-methyl in Fagopyrum tataricum

Tartary buckwheat (Fagopyrum tataricum) field weeds are rich in species, with many weeds causing reduced quality, yield, and crop failure. The selection of herbicide-resistant Tartary buckwheat varieties, while applying low-toxicity and efficient herbicides as a complementary weed control system, is one way to improve Tartary buckwheat yield and quality. Therefore, the development of herbicide-resistant varieties is important for the breeding of Tartary buckwheat. In this experiment, 50 mM ethyl methyl sulfonate solution was used to treat Tartary buckwheat seeds (M1) and then planted in the field. Harvested seeds (M2) were planted in the experiment field of Guizhou University, and when seedlings had 5–7 leaves, the seedlings were sprayed with 166 mg/L tribenuron-methyl (TBM). A total of 15 resistant plants were obtained, of which three were highly resistant. Using the homologous cloning method, an acetolactate synthase (ALS) gene encoding 547 amino acids was identified in Tartary buckwheat. A GTG (valine) to GGA (glycine) mutation (V409G) occurred at position 409 of the ALS gene in the high tribenuron-methyl resistant mutant sm113. The dm36 mutant harbored a double mutation, a deletion mutation at position 405, and a GTG (valine) to GGA (glycine) mutation (V411G) at position 411. The dm110 mutant underwent a double mutation: an ATG (methionine) to AGG (arginine) mutation (M333R) at position 333 and an insertion mutation at position 372. The synthesis of Chl a, Chl b, total Chl, and Car was significantly inhibited by TBM treatment. TBM was more efficient at suppressing the growth of wild-type plants than that of mutant plants. Antioxidant enzyme activities such as ascorbate peroxidase, peroxidase, and superoxide dismutase were significantly higher in resistant plants than in wild-type after spraying with TBM; malondialdehyde content was significantly lower than in wild-type plants after spraying with TBM. Plants with a single-site mutation in the ALS gene could survive, but their growth was affected by herbicide application. In contrast, plants with dual-site mutations in the ALS gene were not affected, indicating that plants with dual-site mutations in the ALS gene showed higher levels of resistance than plants with a single-site mutation in the ALS gene.

Cancer-associated Histone H3 N-terminal arginine mutations disrupt PRC2 activity and impair differentiation

Dysregulated epigenetic states are a hallmark of cancer and often arise from genetic alterations in epigenetic regulators. This includes missense mutations in histones, which, together with associated DNA, form nucleosome core particles. However, the oncogenic mechanisms of most histone mutations are unknown. Here, we demonstrate that cancer-associated histone mutations at arginines in the histone H3 N-terminal tail disrupt repressive chromatin domains, alter gene regulation, and dysregulate differentiation. We find that histone H3R2C and R26C mutants reduce transcriptionally repressive H3K27me3. While H3K27me3 depletion in cells expressing these mutants is exclusively observed on the minor fraction of histone tails harboring the mutations, the same mutants recurrently disrupt broad H3K27me3 domains in the chromatin context, including near developmentally regulated promoters. H3K27me3 loss leads to de-repression of differentiation pathways, with concordant effects between H3R2 and H3R26 mutants despite different proximity to the PRC2 substrate, H3K27. Functionally, H3R26C-expressing mesenchymal progenitor cells and murine embryonic stem cell-derived teratomas demonstrate impaired differentiation. Collectively, these data show that cancer-associated H3 N-terminal arginine mutations reduce PRC2 activity and disrupt chromatin-dependent developmental functions, a cancer-relevant phenotype.

Arginines of the CGN codon family are Achilles' heels of cancer genes.

Recent studies have revealed that arginine is the most favorable target of amino acid alteration in most cancer types and it has been suggested that the high preference for arginine mutations reflects the critical roles of this amino acid in the function of proteins. High rates of mutations of arginine residues in cancer, however, might also be due to increased mutability of arginine codons of the CGN family as the CpG dinucleotides of these codons may be methylated. In the present work we have analyzed spectra of single base substitutions of cancer genes (oncogenes, tumor suppressor genes) and passenger genes in cancer tissues to assess the contributions of CpG hypermutability and selection to arginine mutations. Our studies have shown that arginines encoded by the CGN codon family display higher rates of mutation in both cancer genes and passenger genes than arginine codons AGA and AGG that are devoid of CpG dinucleotide, suggesting that the predominance of arginine mutations in cancer is primarily due to CpG hypermutability, rather than selection for arginine replacement. Nevertheless, our results also suggest that CGN codons for arginines may serve as Achilles' heels of cancer genes. CpG hypermutability of key arginines of proto-oncogenes, leading to high rates of recurrence of driver mutations, contributes significantly to carcinogenesis. Similarly, our results indicate that hypermutability of the CpG dinucleotide of CGA codons (converting them to TGA stop codons) contributes significantly to recurrent truncation and inactivation of tumor suppressor genes.

Lysine-36 of Drosophila histone H3.3 supports adult longevity.

Aging is a multifactorial process that disturbs homeostasis, increases disease susceptibility, and ultimately results in death. Although the definitive set of molecular mechanisms responsible for aging remain to be discovered, epigenetic change over time is proving to be a promising piece of the puzzle. Several post-translational histone modifications have been linked to the maintenance of longevity. Here, we focus on lysine-36 of the replication-independent histone protein, H3.3 (H3.3K36). To interrogate the role of this residue in Drosophila developmental gene regulation, we generated a lysine-to-arginine mutant that blocks the activity of its cognate-modifying enzymes. We found that an H3.3BK36R mutation causes a significant reduction in adult lifespan, accompanied by dysregulation of the genomic and transcriptomic architecture. Transgenic co-expression of wild-type H3.3B completely rescues the longevity defect. Because H3.3 is known to accumulate in nondividing tissues, we carried out transcriptome profiling of young vs aged adult fly heads. The data show that loss of H3.3K36 results in age-dependent misexpression of NF-κB and other innate immune target genes, as well as defects in silencing of heterochromatin. We propose H3.3K36 maintains the postmitotic epigenomic landscape, supporting longevity by regulating both pericentric and telomeric retrotransposons and by suppressing aberrant immune signaling.

Attenuation of neurovirulence of chikungunya virus by a single amino acid mutation in viral E2 envelope protein

BackgroundChikungunya virus (CHIKV) has reemerged as a major public health concern, causing chikungunya fever with increasing cases and neurological complications.MethodsIn the present study, we investigated a low-passage human isolate of the East/ Central/South African (ECSA) lineage of CHIKV strain LK(EH)CH6708, which exhibited a mix of small and large viral plaques. The small and large plaque variants were isolated and designated as CHIKV-SP and CHIKV-BP, respectively. CHIKV-SP and CHIKV-BP were characterized in vitro and in vivo to compare their virus production and virulence. Additionally, whole viral genome analysis and reverse genetics were employed to identify genomic virulence factors.ResultsCHIKV-SP demonstrated lower virus production in mammalian cells and attenuated virulence in a murine model. On the other hand, CHIKV-BP induced higher pro-inflammatory cytokine levels, compromised the integrity of the blood–brain barrier, and led to astrocyte infection in mouse brains. Furthermore, the CHIKV-SP variant had limited transmission potential in Aedesalbopictus mosquitoes, likely due to restricted dissemination. Whole viral genome analysis revealed multiple genetic mutations in the CHIKV-SP variant, including a Glycine (G) to Arginine (R) mutation at position 55 in the viral E2 glycoprotein. Reverse genetics experiments confirmed that the E2-G55R mutation alone was sufficient to reduce virus production in vitro and virulence in mice.ConclusionsThese findings highlight the attenuating effects of the E2-G55R mutation on CHIKV pathogenicity and neurovirulence and emphasize the importance of monitoring this mutation in natural infections.

Computational Studies Show How the H463R Mutation Turns hKv1.5 into an Inactivation State.

The KCNA5 gene provides the code for the α-subunit of the potassium channel Kv1.5. The genetic variant H463R in the Kv1.5 channel has been reported to cause a functional loss in atrial fibrillation (AF) patients. Understanding the mutations at a molecular level is key to developing improved therapeutics concerning cardiac hKv1.5 and hKv1.4 channels. Molecular dynamics and umbrella sampling free energy simulations are an effective tool to understand the mutation's effect on ion conduction, which we have employed and found that the hKv1.5[H463R] mutation imposes an energy barrier on the ion conduction pathway compared to the wild-type channel's ion free energy and pore structure. These results imply that the arginine mutation associated with the AF disease in particular modulates the inactivation process of hKv1.5. Kv1.4, encoded by the KCNA4 gene, is also present in the heart. Therefore, we considered simulation studies of the equivalent H507R mutation in the hKv1.4 channel and found that the mutation slightly reduces the ion conduction barrier in the ion conduction pathway, making it insignificant.

The role of lysine acetylation in the function of mitochondrial ribosomal protein L12.

Mitochondria play a central role in energy production and cellular metabolism. Mitochondria contain their own small genome (mitochondrial DNA, mtDNA) that carries the genetic instructions for proteins required for ATP synthesis. The mitochondrial proteome, including the mitochondrial transcriptional machinery, is subject to post-translational modifications (PTMs), including acetylation and phosphorylation. We set out to determine whether PTMs of proteins associated with mtDNA may provide a potential mechanism for the regulation of mitochondrial gene expression. Here, we focus on mitochondrial ribosomal protein L12 (MRPL12), which is thought to stabilize mitochondrial RNA polymerase (POLRMT) and promote transcription. Numerous acetylation sites of MRPL12 were identified by mass spectrometry. We employed amino acid mimics of the acetylated (lysine to glutamine mutants) and deacetylated (lysine to arginine mutants) versions of MRPL12 to interrogate the role of lysine acetylation in transcription initiation in vitro and mitochondrial gene expression in HeLa cells. MRPL12 acetyl and deacetyl protein mimics were purified and assessed for their ability to impact mtDNA promoter binding of POLRMT. We analyzed mtDNA content and mitochondrial transcript levels in HeLa cells upon overexpression of acetyl and deacetyl mimics of MRPL12. Our results suggest that MRPL12 single-site acetyl mimics do not change the mtDNA promoter binding ability of POLRMT or mtDNA content in HeLa cells. Individual acetyl mimics may have modest effects on mitochondrial transcript levels. We found that the mitochondrial deacetylase, Sirtuin 3, is capable of deacetylating MRPL12 in vitro, suggesting a potential role for dynamic acetylation controlling MRPL12 function in a role outside of the regulation of gene expression.

Genetic and other epidemiological risk factors of infants and children with hypospadias: a case control study

BackgroundTo study hypospadias as regard epidemiological risk factors and genetic association with mutations in Steroid 5 alpha reductase type 2 genes.MaterialsThis study was conducted on two groups; the first group included 50 male children with hypospadias and the other group included 50 male healthy children as a matched control. All patients and controls were subjected to detailed history, physical examination and molecular study of 5-alpha-reductase gene polymorphisms (V89L and G34R).ResultsMean age in hypospadias group was 3.28 ± 2.87 years. The most common type of hypospadias was the glanular type in 19 children (38%). Higher maternal and paternal age, consanguinity, rural residence and preterm labor carry significant epidemiological risk factors for hypospadias. According to genetic study, all healthy children carried the wild valine residue (VV) genotype, while only 44% of hypospadias cases carried the wild VV genotype and 56% carried the mutant L allele (homozygote for leucine residue and heterozygote for both valine and leucine (VL)) with high significant p value (p < 0.001). For Allele Specific—polymerase chain reaction for glycine to arginine (G34R) mutation detection in the 5 alpha reductase type 2 gene, hypospadias children had significantly higher frequency of heterozygous GR genotype than healthy controls. Binary logistic regression analysis showed that mother age and rural residence were the most independent predictors for hypospadias.ConclusionsV89L and G34R Steroid 5 alpha reductase type 2 gene polymorphisms, higher maternal and paternal age, consanguinity, rural residence and preterm labor carry significant risk factors for hypospadias. On multivariate logistic regression, mother age and rural residence are the most independent predictors for hypospadias.

Mechanistic Insight into Poly-Reactivity of Immune Antibodies upon Acid Denaturation or Arginine Mutation in Antigen-Binding Regions.

The poly-reactivity of antibodies is defined as their binding to specific antigens as well as to related proteins and also to unrelated targets. Poly-reactivity can occur in individual molecules of natural serum antibodies, likely due to their conformation flexibility, and, for therapeutic antibodies, it plays a critical role in their clinical development. On the one hand, it can enhance their binding to target antigens and cognate receptors, but, on the other hand, it may lead to a loss of antibody function by binding to off-target proteins. Notably, poly-reactivity has been observed in antibodies subjected to treatments with dissociating, destabilizing or denaturing agents, in particular acidic pH, a common step in the therapeutic antibody production process involving the elution of Protein-A bound antibodies and viral clearance using low pH buffers. Additionally, poly-reactivity can emerge during the affinity maturation in the immune system, such as the germinal center. This review delves into the underlying potential causes of poly-reactivity, highlighting the importance of conformational flexibility, which can be further augmented by the acid denaturation of antibodies and the introduction of arginine mutations into the complementary regions of antibody-variable domains. The focus is placed on a particular antibody's acid conformation, meticulously characterized through circular dichroism, differential scanning calorimetry, and sedimentation velocity analyses. By gaining a deeper understanding of these mechanisms, we aim to shed light on the complexities of antibody poly-reactivity and its implications for therapeutic applications.

Mapping the Acetylamino and Carboxyl Groups on Glycans by Engineered α-Hemolysin Nanopores.

Glycan is a crucial class of biological macromolecules with important biological functions. Functional groups determine the chemical properties of glycans, which further affect their biological activities. However, the structural complexity of glycans has set a technical hurdle for their direct identification. Nanopores have emerged as highly sensitive biosensors that are capable of detecting and characterizing various analytes. Here, we identified the functional groups on glycans with a designed α-hemolysin nanopore containing arginine mutations (M113R), which is specifically sensitive to glycans with acetamido and carboxyl groups. Molecular dynamics simulations indicated that the acetamido and carboxyl groups of the glycans produce unique electrical signatures by forming polar and electrostatic interactions with the M113R nanopores. Using these electrical features as the fingerprints, we mapped the length of the glycans containing acetamido and carboxyl groups at the monosaccharide, disaccharide, and trisaccharide levels. This proof-of-concept study provides a promising foundation for developing single-molecule glycan fingerprinting libraries and demonstrates the capability of biological nanopores in glycan sequencing.

Abstract 3730: A new type of transcriptional reprogramming by an IRF4 mutation in lymphoma

Abstract Disease-causing mutations in genes encoding transcription factors (TFs) are a recurrent finding in hematopoietic malignancies and might involve key regulators of lineage adherence and cellular differentiation1-3. Such mutations can affect TF-interactions with their cognate DNA-binding motifs4,5. Whether and how TF-mutations impact upon the nature of binding to TF composite elements (CE) and influence their interaction with other TFs is unclear. Here, we report a new mechanism of TF alteration in human lymphomas with perturbed B cell identity. It is caused by a recurrent somatic missense mutation c.295T&amp;gt;C (p.Cys99Arg; p.C99R) targeting the center of the DNA-binding domain of Interferon Regulatory Factor 4 (IRF4), a key TF in immune cell-differentiation and -activation6,7. IRF4-C99R fundamentally alters IRF4 DNA-binding, with loss-of-binding to canonical IRF motifs and neomorphic gain-of-binding to canonical and non-canonical IRF composite elements (CEs). Furthermore, IRF4-C99R thoroughly modifies IRF4 function, by blocking IRF4-dependent plasma cell induction, and up-regulating disease-specific genes in a non-canonical Activator Protein-1 (AP-1)-IRF-CE (AICE)-dependent manner. Our data explain how a single arginine mutation creates a complex switch of TF specificity and gene regulation. These data open the possibility of designing specific inhibitors to block the neomorphic, disease-causing DNA-binding activities of a mutant transcription factor. Citation Format: Pierre Cauchy. A new type of transcriptional reprogramming by an IRF4 mutation in lymphoma. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 3730.

Inhibition mechanism of AMPA receptors by the pore blocker memantine.

Fast excitatory synaptic transmission in the mammalian central nervous system is mediated by AMPA-type ionotropic glutamate receptors. AMPA receptors co-assemble with auxiliary proteins, such as transmembrane AMPA receptor regulatory proteins (TARPs), cornichons, cysteine knot proteins and GSG1; which regulate AMPAR assembly, trafficking, gating, and pharmacology. TARPs are the most studied AMPAR auxiliary proteins for their role in the synaptic plasticity. The coupling between AMPA and TARPs change their kinetic and pharmacology properties. Here we show that in the presence of TARPs GluA2 receptors are inhibited by memantine. Memantine inhibition is dependent on charge at site 607, glutamine to arginine mutation showing a larger inhibition by memantine relative to the that GluA2(R) and the GluA2(Q). The inhibition by memantine is activity- and voltage-dependent, suggesting a pore block mechanism.

Global profiling of arginine dimethylation in regulating protein phase separation by a steric effect–based chemical-enrichment method

Protein arginine methylation plays an important role in regulating protein functions in different cellular processes, and its dysregulation may lead to a variety of human diseases. Recently, arginine methylation was found to be involved in modulating protein liquid-liquid phase separation (LLPS), which drives the formation of different membraneless organelles (MLOs). Here, we developed a steric effect-based chemical-enrichment method (SECEM) coupled with liquid chromatography-tandem mass spectrometry to analyze arginine dimethylation (DMA) at the proteome level. We revealed by SECEM that, in mammalian cells, the DMA sites occurring in the RG/RGG motifs are preferentially enriched within the proteins identified in different MLOs, especially stress granules (SGs). Notably, global decrease of protein arginine methylation severely impairs the dynamic assembly and disassembly of SGs. By further profiling the dynamic change of DMA upon SG formation by SECEM, we identified that the most dramatic change of DMA occurs at multiple sites of RG/RGG-rich regions from several key SG-contained proteins, including G3BP1, FUS, hnRNPA1, and KHDRBS1. Moreover, both invitro arginine methylation and mutation of the identified DMA sites significantly impair LLPS capability of the four different RG/RGG-rich regions. Overall, we provide a global profiling of the dynamic changes of protein DMA in the mammalian cells under different stress conditions by SECEM and reveal the important role of DMA in regulating protein LLPS and SG dynamics.

Abstract 047: PPARg Deacetylation Mitigates Aortic Stiffness And Aortic Perivascular Adipose Tissue (aPVAT) Remodeling In Obese Male Mice

Clinical findings show that stiffening of large arteries can precede hypertension in obesity. The causality between arterial stiffness and blood pressure is complex and the underlying mechanism remains unclear. Thoracic aPVAT, a brown-like adipose tissue (AT), undergoes phenotypic changes in obesity resulting in the loss of its protective vascular effect. Our recent findings demonstrated that peroxisome proliferator-activated receptor gamma (PPARγ) deacetylation, a post-translational modification, enhances endothelium-dependent vasodilation. Based on this evidence and PPARγ’s role in regulating AT, we hypothesize that PPARγ deacetylation alleviates aortic stiffness and aPVAT remodeling in obesity . Male eight-week-old C57Bl/6 mice and genetically engineered deacetylation-mimetic mice with a double lysine to arginine mutation (K268R, K293R; 2KR mice) were randomized into two groups: Control groups of C57Bl/6 (n=8) and 2KR mice (n=5) received a regular chow diet (5% fat, 48.7% carbohydrates [3.2% sucrose]) and WD groups of C57Bl/6 (n=11) and 2KR mice (n=9) received a western diet (40% fat, 43% carbohydrates [34% sucrose]) for 20 weeks. Obesity was confirmed by markedly increased body weight in the C57Bl/6 (40.47 ± 1.71 g vs. 29.89 ± 0.76 g controls, p&lt;0.05) and 2KR mice (34.48 ± 1.68 g vs. 24.76 ± 0.59 g controls, p&lt;0.05) at 16 weeks on WD. Pulse wave velocity data, the gold standard measurement for arterial stiffness, revealed increased aortic stiffness in the 16 weeks (5.70 ± 0.61 m/s vs. 3.82 ± 0.24 m/s controls) and 20 weeks (4.89 ± 0.21 m/s vs. 4.02 ± 0.17 m/s controls) on WD in the C57Bl/6 group. Strikingly, WD 2KR mice did not show aortic stiffness after 16 weeks (4.36 ± 0.37 m/s vs. 4.34 ± 0.54 m/s controls, p=0.75) or 20 weeks (5.00 ± 0.65 m/s vs. 5.84 ± 0.96 m/s controls, p=0.49) of WD. aPVAT from WD C57Bl/6 group exhibited profound phenotypic changes, switching from brown- to white-like AT with larger Oil Red O stained lipid droplets, while aPVAT from WD 2KR showed reduced phenotypic modifications. Whether aPVAT contributes to aortic stiffness in obesity remains poorly understood and warrants further investigation. In conclusion, our results support a protective role of PPARγ deacetylation in obesity-related vascular complications.