Plasma Membrane Expression Research Articles

Abstract 4136861: Title: Protein interaction profiling of the Kv11.1 potassium channel reveals new therapeutic targets for Long QT Syndrome

Background: The voltage-gated potassium ion channel K V 11.1 plays a crucial role in cardiac repolarization. Genetic variants in K V 11.1 lead to Long QT Syndrome (LQTS), a condition associated with fatal arrhythmias. Approximately 90% of missense variants linked to LQTS cause intracellular protein transport (trafficking) dysfunction. Some K V 11.1 channel blockers act as chemical chaperones (e.g., E-4031) and increase K V 11.1 channel trafficking. However, these drugs cannot be used in LQTS patients. The underlying mechanisms, such as the protein networks involved in folding and quality control for K V 11.1 channel trafficking remain largely unexplored. Methods: We used affinity-purification (e.g., coimmunoprecipitation) coupled with mass spectrometry to quantify protein interaction changes in human embryonic kidney cells expressing wild-type K V 11.1 or two trafficking-deficient channel variants in the presence or absence of chemical chaperone E-4031. After co-immunoprecipitations and protein digestions, peptides were identified using multiplexed mass spectrometry. Results: We identified 572 protein interactions enriched in K V 11.1-expressing cells. We used bioinformatic analysis to make a cellular model showcasing likely K V 11.1 protein interactions localization from early biogenesis and transcription to plasma membrane expression (Figure 1). We revealed proteins responsible for protein folding, translation, proteasomal degradation, and others with most protein interactions significantly elevated in the genetic variants compared to wild-type (Figure 2). Upon 24-hour treatment with E-4031, some of these interactions were reduced towards wild-type and indicated potential molecular targets for therapeutic intervention (Figure 3). Conclusions: We report the discovery of novel K V 11.1 protein-protein interactions that could be therapeutically targeted to improve K V 11.1 trafficking and treat Long QT Syndrome.

SEMA7A-mediated juxtacrine stimulation of IGFBP-3 upregulates IL-17RB at pancreatic cancer invasive front.

Tumor invasion is the hallmark of tumor malignancy. The invasive infiltration pattern of tumor cells located at the leading edge is highly correlated with metastasis and unfavorable patient outcomes. However, the regulatory mechanisms governing tumor malignancy at the invasive margin remain unclear. The IL-17B/IL-17RB pathway is known to promote pancreatic cancer invasion and metastasis, yet the specific mechanisms underlying IL-17RB upregulation during invasion are poorly understood. In this study, we unveiled a multistep process for IL-17RB upregulation at the invasive margin, which occurs through direct communication between tumor cells and fibroblasts. Tumor ATP1A1 facilitates plasma membrane expression of SEMA7A, which binds to and induces IGFBP-3 secretion from fibroblasts. The resulting gradient of IGFBP-3 influences the direction and enhances IL-17RB expression to regulate SNAI2 in invasion. These findings highlight the importance of local tumor-fibroblast interactions in promoting cancer cell invasiveness, potentially leading to the development of new therapeutic strategies targeting this communication.

9293 Do Obesity-Associated MRAP2 Variants Modulate MC4R and GHSR Signaling?

Abstract Disclosure: A.V. Rodriguez Rondon: None. F. Volker: None. M.S. Welling: None. C. de Groot: None. M.M. van Haelst: None. E.L. van den Akker: None. E.F. van Rossum: None. P.J. Delhanty: None. J.A. Visser: None. Melanocortin 2 receptor accessory protein 2 (MRAP2) is a membrane-bound protein expressed on hypothalamic neurons that modulate the function of appetite-regulating receptors, including melanocortin-4 receptor (MC4R) and growth hormone secretagogue receptor (GHSR). While pathogenic variants in the MRAP2 gene are associated with obesity, the mechanism for this remains unclear. The aim of this study is to investigate the functional impact of wildtype (WT) MRAP2 and MRAP2 variants on MC4R and GHSR signaling. Four MRAP2 variants (S80F, R125C, P167A and Q174X) were identified in patients with obesity by obesity gene panel analysis. The functional effects of these variants were analyzed by co-transfecting HEK293 cells with expression plasmids encoding WT or variant MRAP2 and WT MC4R or WT GHSR. Endpoint analyses included cell surface expression, and ligand-induced second messenger responses (α-MSH-induced cAMP response for MC4R and ghrelin-induced Ca2+ mobilization for GHSR), β-arrestin-2 recruitment, and internalization. WT MRAP2 significantly decreased basal MC4R cell surface expression by 68.1±4.3% (p<0.001). In the absence of MRAP2, α-MSH induced MC4R internalization. However, in the presence of WT MRAP2, MC4R cell surface expression was increased by 89.4±6.9% upon α-MSH stimulation (p<0.001). GHSR cell surface expression and ghrelin-induced internalization were not affected by WT MRAP2. Furthermore, in the cells expressing MC4R with WT MRAP2, the maximal α-MSH-induced cAMP and β-arrestin-2 recruitment responses were increased by 29.8±5.2% and 81.3±4.2% respectively (p<0.001), compared with those lacking MRAP2. We also investigated GHSR ghrelin-induced Ca2+ mobilization and found that, in the presence of WT MRAP2, this increased significantly by 95.37±21.9%, (p<0.0003). However, ghrelin-induced β-arrestin-2 recruitment was suppressed by 69.8±7.6%, (p<0.001). Using these endpoints we found no effect of the variants on the ability of MRAP2 to modulate ligand-induced signaling by MC4R and GHSR. Our results indicate that WT MRAP2 enhances the cAMP response by increasing MC4R cell membrane expression upon α-MSH stimulation, and enhances GHSR Ca2+ mobilization by decreasing β-arrestin-2 recruitment upon ghrelin stimulation. The MRAP2 variants assessed in this study behaved as WT MRAP2 in α-MSH-induced MC4R and ghrelin-induced GHSR signaling, suggesting that these may be benign variants. However, since MRAP2 can modulate multiple receptors, we cannot rule out that these MRAP2 variants affect other appetite-regulating receptors and thereby influence body weight regulation via other pathways. Presentation: 6/3/2024

6789 Do Obesity-Associated MRAP2 Variants Modulate MC4R and GHSR Signaling?

Abstract Disclosure: A.V. Rodriguez Rondon: None. F. Volker: None. M.S. Welling: None. C. de Groot: None. M.M. van Haelst: None. E.L. van den Akker: None. E.F. van Rossum: None. P.J. Delhanty: None. J.A. Visser: None. Melanocortin 2 receptor accessory protein 2 (MRAP2) is a membrane-bound protein expressed on hypothalamic neurons that modulate the function of appetite-regulating receptors, including melanocortin-4 receptor (MC4R) and growth hormone secretagogue receptor (GHSR). While pathogenic variants in the MRAP2 gene are associated with obesity, the mechanism for this remains unclear. The aim of this study is to investigate the functional impact of wildtype (WT) MRAP2 and MRAP2 variants on MC4R and GHSR signaling. Four MRAP2 variants (S80F, R125C, P167A and Q174X) were identified in patients with obesity by obesity gene panel analysis. The functional effects of these variants were analyzed by co-transfecting HEK293 cells with expression plasmids encoding WT or variant MRAP2 and WT MC4R or WT GHSR. Endpoint analyses included cell surface expression, and ligand-induced second messenger responses (α-MSH-induced cAMP response for MC4R and ghrelin-induced Ca2+ mobilization for GHSR), β-arrestin-2 recruitment, and internalization. WT MRAP2 significantly decreased basal MC4R cell surface expression by 68.1±4.3% (p<0.001). In the absence of MRAP2, α-MSH induced MC4R internalization. However, in the presence of WT MRAP2, MC4R cell surface expression was increased by 89.4±6.9% upon α-MSH stimulation (p<0.001). GHSR cell surface expression and ghrelin-induced internalization were not affected by WT MRAP2. Furthermore, in the cells expressing MC4R with WT MRAP2, the maximal α-MSH-induced cAMP and β-arrestin-2 recruitment responses were increased by 29.8±5.2% and 81.3±4.2% respectively (p<0.001), compared with those lacking MRAP2. We also investigated GHSR ghrelin-induced Ca2+ mobilization and found that, in the presence of WT MRAP2, this increased significantly by 95.37±21.9%, (p<0.0003). However, ghrelin-induced β-arrestin-2 recruitment was suppressed by 69.8±7.6%, (p<0.001). Using these endpoints we found no effect of the variants on the ability of MRAP2 to modulate ligand-induced signaling by MC4R and GHSR. Our results indicate that WT MRAP2 enhances the cAMP response by increasing MC4R cell membrane expression upon α-MSH stimulation, and enhances GHSR Ca2+ mobilization by decreasing β-arrestin-2 recruitment upon ghrelin stimulation. The MRAP2 variants assessed in this study behaved as WT MRAP2 in α-MSH-induced MC4R and ghrelin-induced GHSR signaling, suggesting that these may be benign variants. However, since MRAP2 can modulate multiple receptors, we cannot rule out that these MRAP2 variants affect other appetite-regulating receptors and thereby influence body weight regulation via other pathways. Presentation: 6/3/2024

Prognostic Value of CD14 Expression in Peripheral Blood Mononuclear Cell Membrane in Patients with Severe COPD Complicated with Pulmonary Infection.

Severe chronic obstructive pulmonary disease (COPD) patients with pulmonary infections face higher morbidity and mortality. To investigate mononuclear cell membrane CD14 as a prognostic marker for their outcome. A total of 311 participants were included: 122 in the coinfection group, 127 in the severe COPD group, and 62 in the control group. The patients in the coinfection group were categorized into survival (n=106) and death (n=16) groups based on hospitalization prognosis. The CD14%, CD14MFI, and CD14IND values were compared between the groups. Death risk factors were assessed by COPD grading, FEV1% pred, FEV1/FVC, CD14%, CD14MFI, and CD14IND. Correlations between CD14 parameters and mortality, COPD grade, FEV1%pred, and FEV1/FVC were analyzed. The critical value for CD14IND to predict patient death was determined and survival rates were compared between the high and the low-risk groups. CD14% values were significantly lower in the COPD and co-infection groups than in the control groups (p<0.05). The survival group showed a steady increase in mCD14 expression, while the death group showed fluctuating low levels. Low value of CD14% was identified as a risk factor for death and correlated with mortality and COPD severity (p<0.001). CD14IND≤74.36 predicted death with 91.22% sensitivity and 95.51% specificity. The high-risk group had a significantly lower 30-day survival rate (68.42%) compared with the low-risk group (95.24%) (log-rank χ2=10.067, p=0.002). The CD14 parameters of mononuclear cell membranes prove to be promising markers for predicting prognosis and death in severe COPD patients with lung infection.

A Lipid Nanoparticle-Formulated Self-Amplifying RNA Rift Valley Fever Vaccine Induces a Robust Humoral Immune Response in Mice.

Rift Valley fever (RVF) is a mosquito-borne viral zoonosis that causes high fetal and neonatal mortality rates in ruminants and sometimes severe to fatal complications like encephalitis and hemorrhagic fever in humans. There is no licensed RVF vaccine for human use while approved livestock vaccines have suboptimal safety or efficacy. We designed self-amplifying RNA (saRNA) RVF vaccines and assessed their humoral immunogenicity in mice. Plasmid DNA encoding the Rift Valley fever virus (RVFV) medium (M) segment consensus sequence (WT consensus) and its derivatives mutated to enhance cell membrane expression of the viral surface glycoproteins n (Gn) and c (Gc) were assessed for in vitro expression. The WT consensus and best-expressing derivative (furin-T2A) were cloned into a Venezuelan equine encephalitis virus (VEEV) plasmid DNA replicon and in vitro transcribed into saRNA. The saRNA was formulated in lipid nanoparticles and its humoral immunogenicity in BALB/c mice was assessed. High quantities of dose-dependent RVFV Gn IgG antibodies were detected in the serum of all mice immunized with either WT consensus or furin-T2A saRNA RVF vaccines. Significant RVFV pseudovirus-neutralizing activity was induced in mice immunized with 1 µg or 10 µg of the WT consensus saRNA vaccine. The WT consensus saRNA RVF vaccine warrants further development.

Divergent folding-mediated epistasis among unstable membrane protein variants.

Many membrane proteins are prone to misfolding, which compromises their functional expression at the plasma membrane. This is particularly true for the mammalian gonadotropin-releasing hormone receptor GPCRs (GnRHR). We recently demonstrated that evolutionary GnRHR modifications appear to have coincided with adaptive changes in cotranslational folding efficiency. Though protein stability is known to shape evolution, it is unclear how cotranslational folding constraints modulate the synergistic, epistatic interactions between mutations. We therefore compared the pairwise interactions formed by mutations that disrupt the membrane topology (V276T) or tertiary structure (W107A) of GnRHR. Using deep mutational scanning, we evaluated how the plasma membrane expression of these variants is modified by hundreds of secondary mutations. An analysis of 251 mutants in three genetic backgrounds reveals that V276T and W107A form distinct epistatic interactions that depend on both the severity and the mechanism of destabilization. V276T forms predominantly negative epistatic interactions with destabilizing mutations in soluble loops. In contrast, W107A forms positive interactions with mutations in both loops and transmembrane domains that reflect the diminishing impacts of the destabilizing mutations in variants that are already unstable. These findings reveal how epistasis is remodeled by conformational defects in membrane proteins and in unstable proteins more generally.

Divergent folding-mediated epistasis among unstable membrane protein variants

Many membrane proteins are prone to misfolding, which compromises their functional expression at the plasma membrane. This is particularly true for the mammalian gonadotropin-releasing hormone receptor GPCRs (GnRHR). We recently demonstrated that evolutionary GnRHR modifications appear to have coincided with adaptive changes in cotranslational folding efficiency. Though protein stability is known to shape evolution, it is unclear how cotranslational folding constraints modulate the synergistic, epistatic interactions between mutations. We therefore compared the pairwise interactions formed by mutations that disrupt the membrane topology (V276T) or tertiary structure (W107A) of GnRHR. Using deep mutational scanning, we evaluated how the plasma membrane expression of these variants is modified by hundreds of secondary mutations. An analysis of 251 mutants in three genetic backgrounds reveals that V276T and W107A form distinct epistatic interactions that depend on both the severity and the mechanism of destabilization. V276T forms predominantly negative epistatic interactions with destabilizing mutations in soluble loops. In contrast, W107A forms positive interactions with mutations in both loops and transmembrane domains that reflect the diminishing impacts of the destabilizing mutations in variants that are already unstable. These findings reveal how epistasis is remodeled by conformational defects in membrane proteins and in unstable proteins more generally.

3,3',5-Triiodothyroacetic Acid Transporters.

Introduction: Thyroid hormone transporters are essential for thyroid hormones to enter target cells. Monocarboxylate transporter (MCT) 8 is a key transporter and is expressed at the blood-brain barrier (BBB), in neural cells and many other tissues. Patients with MCT8 deficiency have severe neurodevelopmental delays because of cerebral hypothyroidism and chronic sequelae of peripheral thyrotoxicosis. The T3 analog 3,3',5-triiodothyroacetic acid (TRIAC) rescued neurodevelopmental features in animal models mimicking MCT8 deficiency and improved key metabolic features in patients with MCT8 deficiency. However, the identity of the transporter(s) that facilitate TRIAC transport are unknown. Here, we screened candidate transporters that are expressed at the human BBB and/or brain-cerebrospinal fluid barrier and known thyroid hormone transporters for TRIAC transport. Materials and Methods: Plasma membrane expression was determined by cell surface biotinylation assays. Intracellular accumulation of 1 nM TRIAC was assessed in COS-1 cells expressing candidate transporters in Dulbecco's phosphate-buffered saline (DPBS)/0.1% glucose or Dulbecco's modified Eagle's medium (DMEM) with or without 0.1% bovine serum albumin (BSA). Expression of Slc22a8 was determined by fluorescent in situ hybridization in brain sections from wild-type and Mct8/Oatp1c1 knockout mice at postnatal days 12, 21, and 120. Results: In total, 59 plasma membrane transporters were selected for screening of TRIAC accumulation (n = 40 based on expression at the human BBB and/or brain-cerebrospinal fluid barrier and having small organic molecules as substrates; n = 19 known thyroid hormone transporters). Screening of the selected transporter panel showed that 18 transporters facilitated significant intracellular accumulation of TRIAC in DPBS/0.1% glucose or DMEM in the absence of BSA. In the presence of BSA, substantial transport was noted for SLCO1B1 and SLC22A8 (in DPBS/0.1% glucose and DMEM) and SLC10A1, SLC22A6, and SLC22A24 (in DMEM). The zebrafish and mouse orthologs of these transporters similarly facilitated intracellular accumulation of TRIAC. Highest Slc22a8 mRNA expression was detected in mouse brain capillary endothelial cells and choroid plexus epithelial cells at early postnatal time points, but was reduced at P120. Conclusions: Human SLC10A1, SLCO1B1, SLC22A6, SLC22A8, and SLC22A24 as well as their mouse and zebrafish orthologs are efficient TRIAC transporters. These findings contribute to the understanding of TRIAC treatment in patients with MCT8 deficiency and animal models thereof.

Synchronized lineage tracing of cell membranes and nuclei by dual recombinases and dual fluorescent

Genetic lineage tracing has been widely employed to investigate cell lineages and fate. However, conventional reporting systems often label the entire cytoplasm, making it challenging to discern cell boundaries. Additionally, single Cre-loxP recombination systems have limitations in tracing specific cell populations. This study proposes three reporting systems that utilizing Cre, Dre, and Dre + Cre mediated recombination. These systems incorporate tdTomato expression on the cell membrane and PhiYFP expression within the nucleus, allowing for clear observation of the nucleus and membrane. The efficacy of these systems is successfully demonstrated by labeling cardiomyocytes and hepatocytes. The potential for dynamic visualization of the cell membrane is showcased using intravital imaging microscopy or three-dimensional imaging. Furthermore, by combining this dual recombinase system with the ProTracer system, hepatocyte proliferation is traced with enhanced precision. This reporting system holds significant importance for advancing the understanding of cell fate studies in development, homeostasis, and diseases.

Multi-omic Analysis of Human B-cell Activation Reveals a Key Lysosomal BCAT1 Role in mTOR Hyperactivation by B-cell receptor and TLR9.

B-lymphocytes play major adaptive immune roles, producing antibody and driving T-cell responses. However, how immunometabolism networks support B-cell activation and differentiation in response to distinct receptor stimuli remains incompletely understood. To gain insights, we systematically investigated acute primary human B-cell transcriptional, translational and metabolomic responses to B-cell receptor (BCR), Toll-like receptor 9 (TLR9), CD40-ligand (CD40L), interleukin-4 (IL4) or combinations thereof. T-independent BCR/TLR9 co-stimulation, which drives malignant and autoimmune B-cell states, jointly induced PD-L1 plasma membrane expression, supported by NAD metabolism and oxidative phosphorylation. BCR/TLR9 also highly induced the transaminase BCAT1, which localized to lysosomal membranes to support branched chain amino acid synthesis and mTORC1 hyperactivation. BCAT1 inhibition blunted BCR/TLR9, but not CD40L/IL4-triggered B-cell proliferation, IL10 expression and BCR/TLR pathway-driven lymphoma xenograft outgrowth. These results provide a valuable resource, reveal receptor-mediated immunometabolism remodeling to support key B-cell phenotypes including PD-L1 checkpoint signaling, and identify BCAT1 as a novel B-cell therapeutic target.

Evaluation of stored red blood cell quality after washing using immune indices

Washed red blood cells (RBCs) can be used to treat immune-related diseases. However, whether the washing process changes the quality of RBCs and affects the curative effect of transfusion therapy remains unclear. We retrospectively analysed the clinical data of patients who received blood transfusion. The physiological and biochemical parameters of RBCs were tested on an automated haematology-biochemical analyser. CD47 and phosphatidylserine (PS) plasma membrane expression were analysed using flow cytometry. Morphological changes in RBCs were observed using scanning electron microscopy. The results showed that the curative effect on patients who received washed RBCs was weaker than that on those who received non-washed RBCs. Physiological and biochemical parameters of RBCs were not significantly different. RBC immune indices changed significantly after washing. The expression of “don't eat me” signals was weakened, whereas the intensity of “eat me” signals was enhanced. This study suggests that the current use of physiological and biochemical parameters as indicators to evaluate the quality of RBCs may not be comprehensive and that evaluation of the real status of RBCs requires other effective parameters. Immune molecules in RBCs are expected to become supplementary markers for evaluating RBC quality.

Therapeutic potentials of nonpeptidic V2R agonists for partial cNDI-causing V2R mutants.

Loss-of-function mutations in the type 2 vasopressin receptor (V2R) are a major cause of congenital nephrogenic diabetes insipidus (cNDI). In the context of partial cNDI, the response to desmopressin (dDAVP) is partially, but not entirely, diminished. For those with the partial cNDI, restoration of V2R function would offer a prospective therapeutic approach. In this study, we revealed that OPC-51803 (OPC5) and its structurally related V2R agonists could functionally restore V2R mutants causing partial cNDI by inducing prolonged signal activation. The OPC5-related agonists exhibited functional selectivity by inducing signaling through the Gs-cAMP pathway while not recruiting β-arrestin1/2. We found that six cNDI-related V2R partial mutants (V882.53M, Y1283.41S, L1614.47P, T2736.37M, S3298.47R and S3338.51del) displayed varying degrees of plasma membrane expression levels and exhibited moderately impaired signaling function. Several OPC5-related agonists induced higher cAMP responses than AVP at V2R mutants after prolonged agonist stimulation, suggesting their potential effectiveness in compensating impaired V2R-mediated function. Furthermore, docking analysis revealed that the differential interaction of agonists with L3127.40 caused altered coordination of TM7, potentially contributing to the functional selectivity of signaling. These findings suggest that nonpeptide V2R agonists could hold promise as potential drug candidates for addressing partial cNDI.

Pathological and Biological Significance of the Specific Glycan, TRA-1-60, on Aggressive Gastric Adenocarcinoma

The glycans form a unique complex on the surface of cancer cells and play a pivotal role in tumor progression, impacting proliferation, invasion, and metastasis. TRA-1-60 is a glycan that was identified as a critical marker for the establishment of fully reprogrammed inducible pluripotent stem cells. Its expression has been detected in multiple cancer tissues, including embryonal carcinoma, prostate cancer, and pancreatic cancer, but the biological and pathological characterization of TRA-1-60-expressing tumor cells remains unclear within various types of malignancies. Here, we report the biological characteristics of TRA-1-60-expressing gastric cancer cells, especially those with its cell surface expression, and the therapeutic significance of targeting TRA-1-60. The cells with cell membrane expression of TRA-1-60 were mainly observed in the invasive area of patient gastric cancer tissues and correlated with advanced stages of the disease based on histopathological and clinicopathological analyses. In vitro analysis using a scirrhous gastric adenocarcinoma line, HSC-58, which highly expresses TRA-1-60 on its plasma membrane, revealed increased stress-resistant mechanisms, supported by the upregulation of glutathione synthetase and NCF-1 (p47phox) via lipid–ROS regulatory pathways, as detected by RNA-seq analysis followed by oxidative stress gene profiling. Our in vivo therapeutic study using the TRA-1-60-targeting antibody–drug conjugate, namely, Bstrongomab-conjugated monomethyl auristatin E, showed robust efficacy in a mouse model of peritoneal carcinomatosis induced by intraperitoneal xenograft of HSC-58, by markedly reducing massive tumor ascites. Thus, targeting the specific cell surface glycan, TRA-1-60, shows a significant therapeutic impact in advanced-stage gastric cancers.

Novel in vivo optogenetic tools reveal autonomous pacemaker control of renal hemodynamics by macula densa cells

Macula densa (MD) cells, the tubular component of the juxtaglomerular apparatus (JGA) are generally considered as sensor cells detecting tubular salt (NaCl) concentration and based on this information provide feedback control of glomerular hemodynamics (tubuloglomerular feedback, TGF). However, the neuron-like differentiation and activity as non-traditional MD functions are emerging. This study addressed the paradigm-shifting hypothesis that rather than being simply the sensory arm of TGF, MD cells function as the nephron’s autonomous pacemaker and the primary driver and oscillator of glomerular hemodynamics. Single cell MD Ca2+ signaling was analyzed in vivo using intravital multiphoton microscopy (MPM) of MD-GT mice that selectively express the ratiometric Ca2+ reporter GCaMP6f/tdTomato in MD cells. Optogenetic MD stimulation was induced in vivo by blue light (470nm) exposure of MD-Ai27 mouse kidneys that express the depolarizing channelrhodopsin ChR2 specifically in MD cells. Conversely, MD inhibition was induced by yellow light (560nm) exposure of MD-Ai39 mouse kidneys that selectively express the hyperpolarizing halorhodopsin NpHR in MD cells. Cell membrane expression of ChR2 (in MD-Ai27 mice) and NpHR (in MD-Ai39 mice) only in the MD among all renal cell types was confirmed using immunohistochemistry. Pacemaker-like regular Ca2+ oscillations (4-fold elevations in baseline Ca2+ and average frequency of 0.03 Hz) and their cell-to-cell propagation within the MD plaque via long cell processes were observed in MD-GT mice. These Ca2+ oscillations were MD cell autonomous, as they were preserved in freshly dissected single MD cells and in the in vitro dissected and microperfused JGA, and were exclusively confined to the MD area. Bulk and scRNA seq and MD transcriptome analysis identified the high MD expression of genes related to pacemaker function, cell membrane depolarization, voltage-dependent ion channels, Ca2+ signaling and synaptic transmission that was validated by immunohistochemistry. Blue light exposure of single glomeruli/JGAs using ROI scan in MD-Ai27 mouse kidneys that previously underwent superficial corticotomy (open loop nephrons) acutely and reversibly increased capillary and afferent (AA)/efferent arteriole (EA) blood flow by approx. 50% in the light-exposed glomerulus but not in adjacent glomeruli. In contrast, yellow light exposure of single glomeruli/JGAs in MD-Ai39 mouse kidneys acutely and reversibly decreased blood flow but increased glomerular capillary diameter (suggesting preferential EA vs AA vasoconstriction) in the exposed but not in adjacent single nephrons. In addition, yellow light stimulation of single glomeruli in MD-Ai39 mouse kidneys augmented the spontaneous glomerular blood flow oscillations in these open-loop nephrons (frequency of 0.03 Hz), but not in adjacent control nephrons. Altogether, these studies identified MD cells as the nephron’s central pacemaker and oscillator of single nephron blood flow, and emphasized the importance of MD cell membrane potential and Ca2+-dependent vasodilator release as a major driver of nephron function. DK064234 DK123564 DK135290. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Apoptotic-Related MiRNAs Correlated with Functional and Flow Cytometric Parameters in Asthenozoospermic Holstein Bulls After Freeze-Thaw Process.

Many cellular processes in spermatozoa, including apoptosis and motility, are regulated by miRNA. Different miRNAs and molecular pathways are involved in asthenozoospermia (AS) conditions, which are thought to be one of the causes of infertility with reduced sperm motility. Thirty-two semen samples from four Holstein bulls with normozoospermia (NS), total motility ≥ 70%, and progressive motility ≥ 60%, and 32 semen samples from four bulls with AS, total motility ≤ 40%, and progressive motility ≤ 32% were used to investigate the function of apoptosis-related miRNAs in the AS group. Samples were then aspirated into a 0.5 mL straw after dilution with a Tris-egg yolk extender and frozen at -196°C. After freezing, semen samples were thawed for 2 weeks at 37°C and sperm kinematic parameters, plasma membrane integrity, acrosome integrity, DNA fragmentation, apoptosis status, and expression of apoptosis-related miRNAs (miR-2114, miR-296-3p, miR-455-3p, and miR345-3p) were evaluated. Our results showed that the functional and flow cytometric parameters of the NS group were significantly better than those of the AS group. In the NS group, miR-455-3pp and miR-2412 were upregulated, while miR-345-3p was downregulated compared with the AS group. In the AS group, miR-296-39, miR-2412, and miR-345-3p levels were strongly correlated with membrane integrity, DNA fragmentation, and apoptosis status. The findings demonstrated that the selected miRNAs based on bioinformatic analysis in AS and NS samples had a substantial association with functional and flow cytometry indicators and may be involved in regulating apoptosis and motility in AS samples.

Identification of Antibodies to DQβ:DRα Interisotypic Heterodimers in Human Sera.

HLA class II antigens, DR, DQ, and DP, comprised an α and β chains, which typically combine, within the same isotype, to form the major histocompatibility complex:peptide complex. Interisotypic pairing is not commonly observed. Although reports of DQβ:DRα heterodimers exist, the pairing was reported to be unstable and, therefore, not studied to any extent. DQβ:DRα single antigens were produced through transfectant cell lines and used to identify and characterize positive reactive human sera by a multiplex bead-based assay. Stable DQβ:DRα transfectants were constructed. Cell surface staining with class II-specific monoclonal antibodies revealed that some DQB1 alleles appear to be more efficient in expressing DQβ:DRα heterodimers. Interestingly, alleles within the same serological group varied in their efficiency of forming dimers on the cell surface. For example, DQβ0601:DRα had the highest transfection and cell membrane expression efficiency among 16 common DQB1 alleles tested. In contrast, DQβ0603:DRα-positive transfectants demonstrated minimal surface expression. Assembly of DQβ0601:DRα was not affected by the presence of a DQα chain. DQβ0601:DRα and DQβ0603:DRα single-antigen beads were used to screen human sera. Positive sera were identified that reacted to the unique epitopes of DQβ0601:DRα protein on the cell surface of the transfectants. Our studies have demonstrated that unique DQβ:DRα heterodimers can be formed and are stably expressed on the cell surface. Such antigenic combinations, presented on single-antigen beads, demonstrated that patient sera can react with such heterodimers. Investigations on the potential clinical roles of antibodies against such interisotypic heterodimers are now possible.

Satellite glial GPR37L1 and its ligand maresin 1 regulate potassium channel signaling and pain homeostasis.

G protein-coupled receptor 37-like 1 (GPR37L1) is an orphan GPCR with largely unknown functions. Here, we report that Gpr37l1/GRP37L1 ranks among the most highly expressed GPCR transcripts in mouse and human dorsal root ganglia (DRGs) and is selectively expressed in satellite glial cells (SGCs). Peripheral neuropathy induced by streptozotoxin (STZ) and paclitaxel (PTX) led to reduced GPR37L1 expression on the plasma membrane in mouse and human DRGs. Transgenic mice with Gpr37l1 deficiency exhibited impaired resolution of neuropathic pain symptoms following PTX- and STZ-induced pain, whereas overexpression of Gpr37l1 in mouse DRGs reversed pain. GPR37L1 is coexpressed with potassium channels, including KCNJ10 (Kir4.1) in mouse SGCs and both KCNJ3 (Kir3.1) and KCNJ10 in human SGCs. GPR37L1 regulates the surface expression and function of the potassium channels. Notably, the proresolving lipid mediator maresin 1 (MaR1) serves as a ligand of GPR37L1 and enhances KCNJ10- or KCNJ3-mediated potassium influx in SGCs through GPR37L1. Chemotherapy suppressed KCNJ10 expression and function in SGCs, which MaR1 rescued through GPR37L1. Finally, genetic analysis revealed that the GPR37L1-E296K variant increased chronic pain risk by destabilizing the protein and impairing the protein's function. Thus, GPR37L1 in SGCs offers a therapeutic target for the protection of neuropathy and chronic pain.

Abstract 3122: Preclinical development of a novel camptothecin-based antibody-drug conjugate targeting solid tumors expressing Claudin-6

Abstract Claudin-6 is a member of the claudin family and consists of four transmembrane helices, two extracellular loops, and an amino- and carboxyl-terminal tail with a PDZ-binding motif in the cytoplasm. It is involved in the formation of tight junctions and is expressed in developing human epithelial structures during early-to-mid gestation while expression in iadult tissues is mostly absent. Claudin-6 expression is upregulated in ovarian cancer, testicular cancer, endometrial cancer, non-small cell lung cancer (NSCLC) and gastric cancer. Here, the generation and preclinical characterization of a novel Claudin-6 specific antibody-drug conjugate (ADC) is described, composed of a humanized IgG1 directed against human Claudin-6 site-specifically conjugated a novel payload containing a valine-alanine cleavable linker and a camptothecin warhead with a drug to antibody ratio of 6. FcγR-mediated effector function of the ADC was abrogated via mutations in the Fc portion of the antibody. The purpose of this study was to evaluate the expression of Claudin-6 in different tumour indications and characterise the in vitro and in vivo anti-tumour activity in human cancer cell lines and patient-derived xenograft (PDX) models. In addition, the tolerability of the ADC was evaluated in a repeat-dose toxicity study cynomolgus monkeys. Cell binding studies using Fabs showed high affinity binding to Claudin-6, while affinity for Claudin-9 was 16-fold lower with no binding to Claudin-3 and Claudin-4. Cross-reactivity with cynomolgus monkey and mouse Claudin-6 was also demonstrated. Fcgamma receptor binding studies confirmed the strongly reduced binding of the antibody to FcγI, FcγI,IIa, FcγIIb and FcγIIa, consistent with the introduction of mutations in the Fc domain of the antibody. In vitro, the Claudin-6 ADC showed potent and specific cytotoxicity against various Claudin-6-expressing solid cancer cell lines, including OVCAR3, PA-1, OV-90, FU-97, BeWo, NTERA-2 and NUGC3 in comparison to a non-binding control ADC conjugated to the same payload, and it also showed potent bystander killing. In vivo, a single dose intravenous (IV) of the Claudin-6 ADC demonstrated potent anti-tumour activity in multiple solid tumour xenograft models, including OVCAR3 and PA-1. Furthermore, administration of the Claudin-6 ADC to cynomolgus monkeys was well tolerated up to 40 mg/kg IV when given on Day 1 and 22. Cell membrane expression of Claudin-6 was confirmed by immunohistochemistry (IHC) in ovarian cancer (70%), testicular cancer (98%), endometrial cancer (30%), NSCLC (28%) and gastric cancer (24%), confirming expression of Claudin-6 in indications with high unmet need. In summary, this novel Claudin-6 ADC demonstrated potent, specific anti-tumour activity in Claudin-6 expressing cancer-derived models and was well tolerated in cynomolgus monkey, supporting future clinical development of this ADC. Citation Format: Nicola Tsang, Nicolas Veillard, Elizabeth Horsley, Karin Havenith, Narinder Janghra, Kristina Zaitseva, Cecile Oblette, Ian Kirby, Paul W. Hogg, Francesca Zammarchi, Lolke de Haan, Patrick H. van Berkel. Preclinical development of a novel camptothecin-based antibody-drug conjugate targeting solid tumors expressing Claudin-6 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 3122.

HPV16 E7 modulates the cell surface expression of MET and CD109 via the AP2 complex

Multiple cellular pathways are affected by HPV E6 and E7 oncoproteins, including endocytic and cellular trafficking. HPV-16 E7 can target the adaptor protein (AP) complex, which contains proteins important during endocytosis transport. To further investigate the role of HPV E7 during this process, we analysed the expression of cell surface proteins in NIKS cells expressing HPV-16 E7. We show that different cell surface proteins are regulated by HPV-16 E7 via interaction with AP2. We observed that the expression of MET and CD109 membrane protein seems to be upregulated in cells expressing E7. Moreover, the interaction of MET and CD109 with AP2 proteins is disrupted by HPV-16 E7. In addition, in the absence of HPV-16 E7, there is a downregulation of the cell membrane expression of MET and CD109 in HPV-positive cell lines. These results expand our knowledge of the functions of E7 and open new potential cellular pathways affected by this oncoprotein.