Your search keyword '"Comini, Maddalena"' showing total 7 results

1. Neanderthal introgression in SCN9A impacts mechanical pain sensitivity

Author

Faux, Pierre, Ding, Li, Ramirez-Aristeguieta, Luis Miguel, Chacón-Duque, J. Camilo, Comini, Maddalena, Mendoza-Revilla, Javier, Fuentes-Guajardo, Macarena, Jaramillo, Claudia, Arias, William, Hurtado, Malena, Villegas, Valeria, Granja, Vanessa, Barquera, Rodrigo, Everardo-Martínez, Paola, Quinto-Sánchez, Mirsha, Gómez-Valdés, Jorge, Villamil-Ramírez, Hugo, Silva de Cerqueira, Caio C., Hünemeier, Tábita, Ramallo, Virginia, Gonzalez-José, Rolando, Schüler-Faccini, Lavinia, Bortolini, Maria-Cátira, Acuña-Alonzo, Victor, Canizales-Quinteros, Samuel, Poletti, Giovanni, Gallo, Carla, Rothhammer, Francisco, Rojas, Winston, Schmid, Annina B., Adhikari, Kaustubh, Bennett, David L., and Ruiz-Linares, Andrés

Published

2023

2. Investigating genotype-phenotype relationship of extreme neuropathic pain disorders in a UK national cohort.

Author

Themistocleous, Andreas C., Baskozos, Georgios, Blesneac, Iulia, Comini, Maddalena, Megy, Karyn, Sam Chong, Deevi, Sri V. V., Ginsberg, Lionel, Gosal, David, Hadden, Robert D. M., Horvath, Rita, Mahdi-Rogers, Mohamed, Manzur, Adnan, Mapeta, Rutendo, Marshall, Andrew, Matthews, Emma, McCarthy, Mark I., Reilly, Mary M., Renton, Tara, and Rice, Andrew S. C.

Published

2023

3. CLC Anion/Proton Exchangers Regulate Secretory Vesicle Filling and Granule Exocytosis in Chromaffin Cells.

Author

Comini, Maddalena, Sierra-Marquez, Juan, Guzman, Gustavo, Franzen, Arne, Willuweit, Antje, Katona, Istvan, Hidalgo, Patricia, Fahlke, Christoph, and Guzman, Raul E.

Abstract

ClC-3, ClC-4, and ClC-5 are electrogenic chloride/proton exchangers that can be found in endosomal compartments of mammalian cells. Although the association with genetic diseases and the severe phenotype of knock-out animals illustrate their physiological importance, the cellular functions of these proteins have remained insufficiently understood. We here study the role of two Clcn3 splice variants, ClC-3b and ClC-3c, in granular exocytosis and catecholamine accumulation of adrenal chromaffin cells using a combination of high-resolution capacitance measurements, amperometry, protein expression/gene knock out/down, rescue experiments, and confocal microscopy. We demonstrate that ClC-3c resides in immature as well as in mature secretory granules, where it regulates catecholamine accumulation and contributes to the establishment of the readily releasable pool of secretory vesicles. The lysosomal splice variant ClC-3b contributes to vesicle priming only with low efficiency and leaves the vesicular catecholamine content unaltered. The related Cl2/H1 antiporter ClC-5 undergoes age-dependent downregulation in wild-type conditions. Its upregulation in Clcn32/2 cells partially rescues the exocytotic mutant defect. Our study demonstrates how different CLC transporters with similar transport functions, but distinct localizations can contribute to vesicle functions in the regulated secretory pathway of granule secretion in chromaffin cells. [ABSTRACT FROM AUTHOR]

Published

2022

4. Studying human nociceptors: from fundamentals to clinic.

Author

Middleton, Steven J, Barry, Allison M, Comini, Maddalena, Li, Yan, Ray, Pradipta R, Shiers, Stephanie, Themistocleous, Andreas C, Uhelski, Megan L, Yang, Xun, Dougherty, Patrick M, Price, Theodore J, and Bennett, David L

Subjects

NOCICEPTORS, INDUCED pluripotent stem cells, DRUG target, TREATMENT effectiveness, HUMAN experimentation, CHRONIC pain, RESEARCH, ANIMAL experimentation, RESEARCH methodology, MEDICAL cooperation, EVALUATION research, COMPARATIVE studies, RESEARCH funding, MEDICAL research

Abstract

Chronic pain affects one in five of the general population and is the third most important cause of disability-adjusted life-years globally. Unfortunately, treatment remains inadequate due to poor efficacy and tolerability. There has been a failure in translating promising preclinical drug targets into clinic use. This reflects challenges across the whole drug development pathway, from preclinical models to trial design. Nociceptors remain an attractive therapeutic target: their sensitization makes an important contribution to many chronic pain states, they are located outside the blood-brain barrier, and they are relatively specific. The past decade has seen significant advances in the techniques available to study human nociceptors, including: the use of corneal confocal microscopy and biopsy samples to observe nociceptor morphology, the culture of human nociceptors (either from surgical or post-mortem tissue or using human induced pluripotent stem cell derived nociceptors), the application of high throughput technologies such as transcriptomics, the in vitro and in vivo electrophysiological characterization through microneurography, and the correlation with pain percepts provided by quantitative sensory testing. Genome editing in human induced pluripotent stem cell-derived nociceptors enables the interrogation of the causal role of genes in the regulation of nociceptor function. Both human and rodent nociceptors are more heterogeneous at a molecular level than previously appreciated, and while we find that there are broad similarities between human and rodent nociceptors there are also important differences involving ion channel function, expression, and cellular excitability. These technological advances have emphasized the maladaptive plastic changes occurring in human nociceptors following injury that contribute to chronic pain. Studying human nociceptors has revealed new therapeutic targets for the suppression of chronic pain and enhanced repair. Cellular models of human nociceptors have enabled the screening of small molecule and gene therapy approaches on nociceptor function, and in some cases have enabled correlation with clinical outcomes. Undoubtedly, challenges remain. Many of these techniques are difficult to implement at scale, current induced pluripotent stem cell differentiation protocols do not generate the full diversity of nociceptor populations, and we still have a relatively poor understanding of inter-individual variation in nociceptors due to factors such as age, sex, or ethnicity. We hope our ability to directly investigate human nociceptors will not only aid our understanding of the fundamental neurobiology underlying acute and chronic pain but also help bridge the translational gap. [ABSTRACT FROM AUTHOR]

Published

2021

5. Spatial filter and its application in three-dimensional single molecule localization microscopy.

Author

Fan, Xiaoming, Hendriks, Johnny, Comini, Maddalena, Katranidis, Alexandros, Büldt, Georg, and Gensch, Thomas

Published

2020

6. Genetic associations of neuropathic pain and sensory profile in a deeply phenotyped neuropathy cohort.

Author

Åkerlund M, Baskozos G, Li W, Themistocleous AC, Pascal MMV, Rayner NW, Attal N, Baron R, Baudic S, Bennedsgaard K, Bouhassira D, Comini M, Crombez G, Faber CG, Finnerup NB, Gierthmühlen J, Granovsky Y, Gylfadottir SS, Hébert HL, Jensen TS, John J, Kemp HI, Lauria G, Laycock H, Meng W, Nilsen KB, Palmer C, Rice ASC, Serra J, Smith BH, Tesfaye S, Topaz LS, Veluchamy A, Vollert J, Yarnitsky D, van Zuydam N, Zwart JA, McCarthy MI, Lyssenko V, and Bennett DL

Abstract

Abstract: We aimed to investigate the genetic associations of neuropathic pain in a deeply phenotyped cohort. Participants with neuropathic pain were cases and compared with those exposed to injury or disease but without neuropathic pain as control subjects. Diabetic polyneuropathy was the most common aetiology of neuropathic pain. A standardised quantitative sensory testing protocol was used to categorize participants based on sensory profile. We performed genome-wide association study, and in a subset of participants, we undertook whole-exome sequencing targeting analyses of 45 known pain-related genes. In the genome-wide association study of diabetic neuropathy (N = 1541), a top significant association was found at the KCNT2 locus linked with pain intensity (rs114159097, P = 3.55 × 10-8). Gene-based analysis revealed significant associations between LHX8 and TCF7L2 and neuropathic pain. Polygenic risk score for depression was associated with neuropathic pain in all participants. Polygenic risk score for C-reactive protein showed a positive association, while that for fasting insulin showed a negative association with neuropathic pain, in individuals with diabetic polyneuropathy. Gene burden analysis of candidate pain genes supported significant associations between rare variants in SCN9A and OPRM1 and neuropathic pain. Comparison of individuals with the "irritable" nociceptor profile to those with a "nonirritable" nociceptor profile identified a significantly associated variant (rs72669682, P = 4.39 × 10-8) within the ANK2 gene. Our study on a deeply phenotyped cohort with neuropathic pain has confirmed genetic associations with the known pain-related genes KCNT2, OPRM1, and SCN9A and identified novel associations with LHX8 and ANK2, genes not previously linked to pain and sensory profiles, respectively., (Copyright © 2024 The Author(s). Published by Wolters Kluwer Health, Inc. on behalf of the International Association for the Study of Pain.)

Published

2024

7. Human pain channelopathies.

Author

Comini M, Themistocleous AC, and Bennett DLH

Subjects

Humans, Mutation genetics, NAV1.7 Voltage-Gated Sodium Channel genetics, Pain genetics, Neuralgia genetics, Channelopathies genetics

Abstract

There has been significant progress in our understanding of the molecular basis by which nociceptors transduce and transmit noxious (tissue damaging) stimuli. This is dependent on ion channels, many of which are selectively expressed in nociceptors. Mutations in such proteins have recently been linked to inherited pain disorders in humans. An exemplar is the voltage-gated sodium channel (VGSC) Na V 1.7. Loss of function mutations in Na V 1.7 result in congenital inability to experience pain while gain-of-function mutations can cause a number of distinct neuropathic pain disorders, including erythromelalgia, paroxysmal extreme pain disorder, and small-fiber neuropathy. Furthermore, variants in the VGSCs 1.8 and 1.9 have also been linked to human pain disorders. There is a correlation between the impact of mutations on the biophysical properties of the ion channel and the severity of the clinical phenotype. Pain channelopathies are not restricted to VGSCs: a mutation in the ligand-gated ion channel TRPA1, (which responds to environmental irritants) causes a familial episodic pain disorder. Ion channel variants have also been linked to more common neuropathic pain disorders such as painful diabetic neuropathy. Not only do these ion channels present targets for novel analgesics, but stratification based on genotype may improve treatment selection of existing analgesics., (Copyright © 2024 Elsevier B.V. All rights are reserved, including those for text and data mining, AI training, and similar technologies.)

Published

2024