Your search keyword '"Camille Nicolas-Frank"' showing total 6 results

1. Exome sequencing identifies a likely causative variant in 53% of families with ciliopathy-related features on renal ultrasound after excluding NPHP1 deletions

Author

Konstantin Deutsch, Verena Klämbt, Thomas M. Kitzler, Tilman Jobst-Schwan, Ronen Schneider, Florian Buerger, Steve Seltzsam, Sherif El Desoky, Jameela A. Kari, Farkhanda Hafeez, Maria Szczepańska, Loai A. Eid, Hazem S. Awad, Muna Al-Saffar, Neveen A. Soliman, Velibor Tasic, Camille Nicolas-Frank, Kirollos Yousef, Luca M. Schierbaum, Sophia Schneider, Abdul Halawi, Izzeldin Elmubarak, Katharina Lemberg, Shirlee Shril, Shrikant M. Mane, Nancy Rodig, and Friedhelm Hildebrandt

Subjects

Medicine (General), R5-920, Genetics, QH426-470

Published

2024

2. Whole exome sequencing identifies potential candidate genes for spina bifida derived from mouse models

Author

Chunyan Wang, Steve Seltzsam, Bixia Zheng, Chen‐Han Wilfred Wu, Camille Nicolas‐Frank, Kirollos Yousef, Kit Sing Au, Nina Mann, Dalia Pantel, Sophia Schneider, Luca Schierbaum, Thomas M. Kitzler, Dervla M. Connaughton, Youying Mao, Rufeng Dai, Makiko Nakayama, Jameela A. Kari, Sherif El Desoky, Mohammed Shalaby, Loai A. Eid, Hazem S. Awad, Velibor Tasic, Shrikant M. Mane, Richard P. Lifton, Michelle A. Baum, Shirlee Shril, Carlos R. Estrada, and Friedhelm Hildebrandt

Subjects

Disease Models, Animal, Mice, Exome Sequencing, Genetics, Animals, Humans, Exome, Spinal Dysraphism, Article, Genetics (clinical)

Abstract

BACKGROUND: Spina bifida (SB) is the second most common nonlethal congenital malformation. The existence of monogenic SB mouse models and human monogenic syndromes with SB features indicate that human SB may be caused by monogenic genes. We hypothesized that whole exome sequencing (WES) allows identification of potential candidate genes by i) generating a list of 136 candidate genes for SB, and ii) by unbiased exome-wide analysis. METHODS: We generated a list of 136 potential candidate genes from three categories: and evaluated WES data of 50 unrelated SB cases for likely deleterious variants in 136 potential candidate genes, and for potential SB candidate genes exome-wide. RESULTS: We identified 6 likely deleterious variants in 6 of the 136 potential SB candidate genes in 6 of the 50 SB cases, whereof 4 genes were derived from mouse models, 1 gene was derived from human non-syndromic SB, and 1 gene was derived from candidate genes known to cause human syndromic SB. In addition, by unbiased exome-wide analysis, we identified 12 genes as potential candidates for SB. CONCLUSIONS: Identification of these 18 potential candidate genes in larger SB cohorts will help decide which ones can be considered as novel monogenic causes of human SB.

Published

2022

3. Kidney Regenerative Medicine: Promises and Limitations

Author

Astgik Petrosyan and Camille Nicolas Frank

Subjects

Transplantation, medicine.medical_specialty, Kidney, Hepatology, business.industry, Xenotransplantation, medicine.medical_treatment, Immunology, medicine.disease, Regenerative medicine, Extracellular vesicles, medicine.anatomical_structure, Transplant surgery, Nephrology, medicine, Surgery, Stem cell, Intensive care medicine, business, Kidney disease

Abstract

Advances in renal regenerative medicine are crucial to address the increased rate of kidney disease. Clinicians and researchers are investigating new renal therapeutics aimed at promoting endogenous repair and/or at designing new technologies for organ and tissue regeneration. This review explores the potential promises and limitations of recent renal regenerative medicine approaches. Current research directions include efforts to delay and deter acute and chronic kidney disease progression by exploiting the immune-modulatory and tissue regenerative properties of pharmacology agents, stem cells, and extracellular vesicles. Furthermore, advancement of novel technologies in the field of xenotransplantation, and transplantable devices are showing progress towards the design of de novo replacement organs. With integrated collaborations of multiple disciplinaries, improvements in novel technologies, and understanding of kidney disease progression, the field of renal regenerative medicine is progressing forward with promising therapeutic potential.

Published

2020

4. Reverse phenotyping facilitates disease allele calling in exome sequencing of patients with CAKUT

Author

Luca Schierbaum, Amar J. Majmundar, Friedhelm Hildebrandt, Hanan M. Fathy, Avram Z. Traum, Bixia Zheng, Ankana Daga, Sophia Schneider, Florian Buerger, Konstantin Deutsch, Mohammed Shalaby, Steve Seltzsam, Rufeng Dai, Caroline M. Kolvenbach, Jameela A. Kari, Daanya Salmanullah, Michelle A. Baum, Ronen Schneider, Verena Klämbt, Youying Mao, Nancy Rodig, Kirollos Yousef, Deborah R. Stein, Loai A. Eid, Michael A. J. Ferguson, Neveen A. Soliman, Isabel Ottlewski, Franziska Kause, Makiko Nakayama, Sherif El Desoky, Ethan W. Lai, Nina Mann, Hazem S. Awad, Stuart B. Bauer, Michael J. Somers, Dalia Pantel, Velibor Tasic, Ana C. Onuchic-Whitford, Shrikant Mane, Chunyan Wang, Dervla M. Connaughton, Chen-Han Wilfred Wu, Ghaleb Daouk, Shirlee Shril, and Camille Nicolas-Frank

Subjects

Genetics, Vesico-Ureteral Reflux, business.industry, Disease, medicine.disease, Kidney, Phenotype, Article, Clinical diagnosis, Urogenital Abnormalities, medicine, Humans, Exome, Allele, business, Urinary Tract, Gene, Clinical syndrome, Genetics (clinical), Exome sequencing, Alleles, Kidney disease

Abstract

Purpose Congenital anomalies of the kidneys and urinary tract (CAKUT) constitute the leading cause of chronic kidney disease in children. In total, 174 monogenic causes of isolated or syndromic CAKUT are known. However, syndromic features may be overlooked when the initial clinical diagnosis of CAKUT is made. We hypothesized that the yield of a molecular genetic diagnosis by exome sequencing (ES) can be increased by applying reverse phenotyping, by re-examining the case for signs/symptoms of the suspected clinical syndrome that results from the genetic variant detected by ES. Methods We conducted ES in an international cohort of 731 unrelated families with CAKUT. We evaluated ES data for variants in 174 genes, in which variants are known to cause isolated or syndromic CAKUT. In cases in which ES suggested a previously unreported syndromic phenotype, we conducted reverse phenotyping. Results In 83 of 731 (11.4%) families, we detected a likely CAKUT-causing genetic variant consistent with an isolated or syndromic CAKUT phenotype. In 19 of these 83 families (22.9%), reverse phenotyping yielded syndromic clinical findings, thereby strengthening the genotype–phenotype correlation. Conclusion We conclude that employing reverse phenotyping in the evaluation of syndromic CAKUT genes by ES provides an important tool to facilitate molecular genetic diagnostics in CAKUT.

Published

2021

5. Effect of disease progression on the podocyte cell cycle in Alport Syndrome

Author

Roger E. De Filippo, Paolo Cravedi, Camille Nicolas Frank, Rui Zhao, Fadi Salem, Astgik Petrosyan, Kevin V. Lemley, Laura Perin, Valentina Villani, Xiaogang Hou, Joshua R. Hansen, and Geremy Clair

Subjects

Male, Proteomics, Cell, Nephritis, Hereditary, Biology, urologic and male genital diseases, Podocyte, Mice, Downregulation and upregulation, medicine, Animals, Humans, Alport syndrome, Adaptor Proteins, Signal Transducing, Podocytes, Cell Cycle, Microfilament Proteins, Glomerulosclerosis, Cell cycle, LIM Domain Proteins, medicine.disease, female genital diseases and pregnancy complications, Cell biology, medicine.anatomical_structure, Nephrology, Disease Progression, Female, Cytokinesis, Kidney disease

Abstract

Progression of glomerulosclerosis is associated with loss of podocytes with subsequent glomerular tuft instability. It is thought that a diminished number of podocytes may be able to preserve tuft stability through cell hypertrophy associated with cell cycle reentry. At the same time, reentry into the cell cycle risks podocyte detachment if podocytes cross the G1/S checkpoint and undergo abortive cytokinesis. In order to study cell cycle dynamics during chronic kidney disease (CKD) development, we used a FUCCI model (fluorescence ubiquitination-based cell cycle indicator) of mice with X-linked Alport Syndrome. This model exhibits progressive CKD and expresses fluorescent reporters of cell cycle stage exclusively in podocytes. With the development of CKD, an increasing fraction of podocytes in vivo were found to be in G1 or later cell cycle stages. Podocytes in G1 and G2 were hypertrophic. Heterozygous female mice, with milder manifestations of CKD, showed G1 fraction numbers intermediate between wild-type and male Alport mice. Proteomic analysis of podocytes in different cell cycle phases showed differences in cytoskeleton reorganization and metabolic processes between G0 and G1 in disease. Additionally, in vitro experiments confirmed that damaged podocytes reentered the cell cycle comparable to podocytes in vivo. Importantly, we confirmed the upregulation of PDlim2, a highly expressed protein in podocytes in G1, in a patient with Alport Syndrome, confirming our proteomics data in the human setting. Thus, our data showed that in the Alport model of progressive CKD, podocyte cell cycle distribution is altered, suggesting that cell cycle manipulation approaches may have a role in the treatment of various progressive glomerular diseases characterized by podocytopenia.

Published

2021

6. Quantifiable and reproducible phenotypic assessment of a constitutive knockout mouse model for congenital nephrotic syndrome of the Finnish type

Author

Katharina Lemberg, Nils D. Mertens, Kirollos Yousef, Ronen Schneider, Lea M. Merz, Bshara Mansour, Daanya Salmanullah, Caroline M. Kolvenbach, Ken Saida, Seyoung Yu, Selina Hölzel, Andrew Steinsapir, Kevin A. Goncalves, Camille Nicolas Frank, Gijs A. C. Franken, Shirlee Shril, Florian Buerger, and Friedhelm Hildebrandt

Subjects

Medicine, Science

Abstract

Abstract Steroid-resistant nephrotic syndrome (SRNS) is the second most frequent cause of childhood chronic kidney disease. Congenital nephrotic syndrome of the Finnish type (CNF) (MIM# 256300) is caused by biallelic variants in the gene NPHS1, encoding nephrin, an integral component of the kidney filtration barrier. No causal treatments exist, and children inevitably require kidney replacement therapy. In preparation for gene replacement therapy (GRT) in CNF, we established a quantifiable and reproducible phenotypic assessment of the nephrin-deficient CNF mouse model: 129/Sv-Nphs1 tm1Rkl /J. We assessed the phenotypic spectrum of homozygous mice (Nphs1 tm1Rkl /Nphs1 tm1Rkl ) compared to heterozygous controls (Nphs1 tm1Rkl /Nphs1 WT ) by the following parameters: 1. cohort survival, 2. podocyte foot process (FP) density per glomerular basement membrane (GBM) using transmission electron microscopy, 3. tubular microcysts in brightfield microscopy, and 4. urinary albumin/creatinine ratios. Nphs1 tm1Rkl /Nphs1 tm1Rkl mice exhibited: 1. perinatal lethality with median survival of 1 day, 2. FP effacement with median FP density of 1.00 FP/µm GBM (2.12 FP/µm in controls), 3. tubular dilation with 65 microcysts per section (6.5 in controls), and 4. increased albumin/creatinine ratio of 238 g/g (4.1 g/g in controls). We here established four quantifiable phenotyping features of a CNF mouse model to facilitate future GRT studies by enabling sensitive detection of phenotypic improvements.

Published

2024