Your search keyword '"Pilch, J"' showing total 10 results

1. Goldberg–Shprintzen syndrome is determined by the absence, or reduced expression levels, of KIFBP

Author

MacKenzie, K.C., Graaf, B.M. (Bianca) de, Syrimis, A., Zhao, Y, Brosens, E. (Erwin), Mancini, G.M.S. (Grazia), Schot, R. (Rachel), Halley, D., Wilke, M. (Martina), Vøllo, A., Flinter, F. (Frances), Green, A., Mansour, S, Pilch, J. (Jacek), Stark, Z, Zamba-Papanicolaou, E., Christophidou-Anastasiadou, V., Hofstra, R.M.W. (Robert), Jongbloed, J.D., Nicolaou, N. (Nayia), Tanteles, G.A., Brooks, A.S. (Alice), Alves, M.M. (Maria), MacKenzie, K.C., Graaf, B.M. (Bianca) de, Syrimis, A., Zhao, Y, Brosens, E. (Erwin), Mancini, G.M.S. (Grazia), Schot, R. (Rachel), Halley, D., Wilke, M. (Martina), Vøllo, A., Flinter, F. (Frances), Green, A., Mansour, S, Pilch, J. (Jacek), Stark, Z, Zamba-Papanicolaou, E., Christophidou-Anastasiadou, V., Hofstra, R.M.W. (Robert), Jongbloed, J.D., Nicolaou, N. (Nayia), Tanteles, G.A., Brooks, A.S. (Alice), and Alves, M.M. (Maria)

Abstract

Goldberg–Shprintzen syndrome (GOSHS) is caused by loss of function variants in the kinesin binding protein gene (KIFBP). However, the phenotypic range of this syndrome is wide, indicating that other factors may play a role. To date, 37 patients with GOSHS have been reported. Here, we document nine new patients with variants in KIFBP: seven with nonsense variants and two with missense variants. To our knowledge, this is the first time that missense variants have been reported in GOSHS. We functionally investigated the effect of the variants identified, in an attempt to find a genotype–phenotype correlation. We also determined whether common Hirschsprung disease (HSCR)‐associated single nucleotide polymorphisms (SNPs), could explain the presence of HSCR in GOSHS. Our results showed that the missense variants led to reduced expression of KIFBP, while the truncating variants resulted in lack of protein. However, no correlation was found between the severity of GOSHS and the location of the variants. We were also unable to find a correlation between common HSCR‐associated SNPs, and HSCR development in GOSHS. In conclusion, we show that reduced, as well as lack of KIFBP expression can lead to GOSHS, and our results suggest that a threshold expression of KIFBP may modulate phenotypic variability of the disease.

Published

2020

2. Goldberg-Shprintzen syndrome is determined by the absence, or reduced expression levels, of KIFBP

Author

MacKenzie, KC, de Graaf, BM, Syrimis, A, Zhao, Y, Brosens, E, Mancini, GMS, Schot, R, Halley, D, Wilke, M, Vollo, A, Flinter, F, Green, A, Mansour, S, Pilch, J, Stark, Z, Zamba-Papanicolaou, E, Christophidou-Anastasiadou, V, Hofstra, RMW, Jongbloed, JDH, Nicolaou, N, Tanteles, GA, Brooks, AS, Alves, MM, MacKenzie, KC, de Graaf, BM, Syrimis, A, Zhao, Y, Brosens, E, Mancini, GMS, Schot, R, Halley, D, Wilke, M, Vollo, A, Flinter, F, Green, A, Mansour, S, Pilch, J, Stark, Z, Zamba-Papanicolaou, E, Christophidou-Anastasiadou, V, Hofstra, RMW, Jongbloed, JDH, Nicolaou, N, Tanteles, GA, Brooks, AS, and Alves, MM

Abstract

Goldberg-Shprintzen syndrome (GOSHS) is caused by loss of function variants in the kinesin binding protein gene (KIFBP). However, the phenotypic range of this syndrome is wide, indicating that other factors may play a role. To date, 37 patients with GOSHS have been reported. Here, we document nine new patients with variants in KIFBP: seven with nonsense variants and two with missense variants. To our knowledge, this is the first time that missense variants have been reported in GOSHS. We functionally investigated the effect of the variants identified, in an attempt to find a genotype-phenotype correlation. We also determined whether common Hirschsprung disease (HSCR)-associated single nucleotide polymorphisms (SNPs), could explain the presence of HSCR in GOSHS. Our results showed that the missense variants led to reduced expression of KIFBP, while the truncating variants resulted in lack of protein. However, no correlation was found between the severity of GOSHS and the location of the variants. We were also unable to find a correlation between common HSCR-associated SNPs, and HSCR development in GOSHS. In conclusion, we show that reduced, as well as lack of KIFBP expression can lead to GOSHS, and our results suggest that a threshold expression of KIFBP may modulate phenotypic variability of the disease.

Published

2020

3. Cardiac phenotype in ATP1A3-related syndromes A multicenter cohort study

Author

Balestrini, S, Mikati, MA, Alvarez-Garcia-Roves, R, Carboni, M, Hunanyan, AS, Kherallah, B, McLean, M, Prange, L, De Grandis, E, Gagliardi, A, Pisciotta, L, Stagnaro, M, Veneselli, E, Campistol, J, Fons, C, Pias-Peleteiro, L, Brashear, A, Miller, C, Samoes, R, Brankovic, V, Padiath, QS, Potic, A, Pilch, J, Vezyroglou, A, Bye, AME, Davis, AM, Ryan, MM, Semsarian, C, Hollingsworth, G, Scheffer, IE, Granata, T, Nardocci, N, Ragona, F, Arzimanoglou, A, Panagiotakaki, E, Carrilho, I, Zucca, C, Novy, J, Parowicz, M, Weckhuysen, S, Pons, R, Groppa, S, Sinden, DS, Pitt, GS, Tinker, A, Ashworth, M, Michalak, Z, Thom, M, Cross, JH, Vavassori, R, Kaski, JP, Sisodiya, SM, Dzieiyc, K, Mazurkiewicz-Beldzinska, M, Balestrini, S, Mikati, MA, Alvarez-Garcia-Roves, R, Carboni, M, Hunanyan, AS, Kherallah, B, McLean, M, Prange, L, De Grandis, E, Gagliardi, A, Pisciotta, L, Stagnaro, M, Veneselli, E, Campistol, J, Fons, C, Pias-Peleteiro, L, Brashear, A, Miller, C, Samoes, R, Brankovic, V, Padiath, QS, Potic, A, Pilch, J, Vezyroglou, A, Bye, AME, Davis, AM, Ryan, MM, Semsarian, C, Hollingsworth, G, Scheffer, IE, Granata, T, Nardocci, N, Ragona, F, Arzimanoglou, A, Panagiotakaki, E, Carrilho, I, Zucca, C, Novy, J, Parowicz, M, Weckhuysen, S, Pons, R, Groppa, S, Sinden, DS, Pitt, GS, Tinker, A, Ashworth, M, Michalak, Z, Thom, M, Cross, JH, Vavassori, R, Kaski, JP, Sisodiya, SM, Dzieiyc, K, and Mazurkiewicz-Beldzinska, M

Abstract

OBJECTIVE: To define the risks and consequences of cardiac abnormalities in ATP1A3-related syndromes. METHODS: Patients meeting clinical diagnostic criteria for rapid-onset dystonia-parkinsonism (RDP), alternating hemiplegia of childhood (AHC), and cerebellar ataxia, areflexia, pes cavus, optic atrophy, and sensorineural hearing loss (CAPOS) with ATP1A3 genetic analysis and at least 1 cardiac assessment were included. We evaluated the cardiac phenotype in an Atp1a3 knock-in mouse (Mashl+/-) to determine the sequence of events in seizure-related cardiac death. RESULTS: Ninety-eight patients with AHC, 9 with RDP, and 3 with CAPOS (63 female, mean age 17 years) were included. Resting ECG abnormalities were found in 52 of 87 (60%) with AHC, 2 of 3 (67%) with CAPOS, and 6 of 9 (67%) with RDP. Serial ECGs showed dynamic changes in 10 of 18 patients with AHC. The first Holter ECG was abnormal in 24 of 65 (37%) cases with AHC and RDP with either repolarization or conduction abnormalities. Echocardiography was normal. Cardiac intervention was required in 3 of 98 (≈3%) patients with AHC. In the mouse model, resting ECGs showed intracardiac conduction delay; during induced seizures, heart block or complete sinus arrest led to death. CONCLUSIONS: We found increased prevalence of ECG dynamic abnormalities in all ATP1A3-related syndromes, with a risk of life-threatening cardiac rhythm abnormalities equivalent to that in established cardiac channelopathies (≈3%). Sudden cardiac death due to conduction abnormality emerged as a seizure-related outcome in murine Atp1a3-related disease. ATP1A3-related syndromes are cardiac diseases and neurologic diseases. We provide guidance to identify patients potentially at higher risk of sudden cardiac death who may benefit from insertion of a pacemaker or implantable cardioverter-defibrillator.

Published

2020

4. Goldberg–Shprintzen syndrome is determined by the absence, or reduced expression levels, of KIFBP

Author

MacKenzie, Katherine, de Graaf, Bianca, Syrimis, A, Zhao, Yuying, Brosens, Erwin, Verheijen - Mancini, Grazia, Schot, Rachel, Halley, Dicky, Wilke, Martina, Vøllo, A, Flinter, F, Green, A, Mansour, S, Pilch, J, Stark, Z, Zamba-Papanicolaou, E, Christophidou-Anastasiadou, V, Hofstra, Robert, Jongbloed, JD, Nicolaou, N, Tanteles, GA, Brooks, Alice, Alves, Maria, MacKenzie, Katherine, de Graaf, Bianca, Syrimis, A, Zhao, Yuying, Brosens, Erwin, Verheijen - Mancini, Grazia, Schot, Rachel, Halley, Dicky, Wilke, Martina, Vøllo, A, Flinter, F, Green, A, Mansour, S, Pilch, J, Stark, Z, Zamba-Papanicolaou, E, Christophidou-Anastasiadou, V, Hofstra, Robert, Jongbloed, JD, Nicolaou, N, Tanteles, GA, Brooks, Alice, and Alves, Maria

Published

2020

5. Differential regulation of two FLNA transcripts explains some of the phenotypic heterogeneity in the loss-of-function filaminopathies

Author

Jenkins, ZA, Macharg, A, Chang, C-Y, van Kogelenberg, M, Morgan, T, Frentz, S, Wei, W, Pilch, J, Hannibal, M, Foulds, N, McGillivray, G, Leventer, RJ, Garcia-Minaur, S, Sugito, S, Nightingale, S, Markie, DM, Dudding, T, Kapur, RP, Robertson, SP, Jenkins, ZA, Macharg, A, Chang, C-Y, van Kogelenberg, M, Morgan, T, Frentz, S, Wei, W, Pilch, J, Hannibal, M, Foulds, N, McGillivray, G, Leventer, RJ, Garcia-Minaur, S, Sugito, S, Nightingale, S, Markie, DM, Dudding, T, Kapur, RP, and Robertson, SP

Abstract

Loss-of-function mutations in the X-linked gene FLNA can lead to abnormal neuronal migration, vascular and cardiac defects, and congenital intestinal pseudo-obstruction (CIPO), the latter characterized by anomalous intestinal smooth muscle layering. Survival in male hemizygotes for such mutations is dependent on retention of residual FLNA function but it is unclear why a subgroup of males with mutations in the 5' end of the gene can present with CIPO alone. Here, we demonstrate evidence for the presence of two FLNA isoforms differing by 28 residues at the N-terminus initiated at ATG+1 and ATG+82 . A male with CIPO (c.18_19del) exclusively expressed FLNA ATG+82 , implicating the longer protein isoform (ATG+1 ) in smooth muscle development. In contrast, mutations leading to reduction of both isoforms are associated with compound phenotypes affecting the brain, heart, and intestine. RNA-seq data revealed three distinct transcription start sites, two of which produce a protein isoform utilizing ATG+1 while the third utilizes ATG+82 . Transcripts sponsoring translational initiation at ATG+1 predominate in intestinal smooth muscle, and are more abundant compared with the level measured in fibroblasts. Together these observations describe a new mechanism of tissue-specific regulation of FLNA that could reflect the differing mechanical requirements of these cell types during development.

Published

2018

6. BEER - The Beamline for European Materials Engineering Research at the ESS

Author

Fenske, J, Rouijaa, M, Šaroun, Jan, Kampmann, R., Staron, P, Nowak, Gabriel, Pilch, J, Beran, P, Šittner, P, Strunz, P., Brokmeier, H-g, Ryukhtin, V, Kadeřávek, L, Strobl, Markus, Müller, M, Lukáš, P, Schreyer, A, Fenske, J, Rouijaa, M, Šaroun, Jan, Kampmann, R., Staron, P, Nowak, Gabriel, Pilch, J, Beran, P, Šittner, P, Strunz, P., Brokmeier, H-g, Ryukhtin, V, Kadeřávek, L, Strobl, Markus, Müller, M, Lukáš, P, and Schreyer, A

Published

2016

7. BEER - The Beamline for European Materials Engineering Research at the ESS

Author

Fenske, J, Rouijaa, M, Šaroun, Jan, Kampmann, R., Staron, P, Nowak, Gabriel, Pilch, J, Beran, P, Šittner, P, Strunz, P., Brokmeier, H-g, Ryukhtin, V, Kadeřávek, L, Strobl, Markus, Müller, M, Lukáš, P, Schreyer, A, Fenske, J, Rouijaa, M, Šaroun, Jan, Kampmann, R., Staron, P, Nowak, Gabriel, Pilch, J, Beran, P, Šittner, P, Strunz, P., Brokmeier, H-g, Ryukhtin, V, Kadeřávek, L, Strobl, Markus, Müller, M, Lukáš, P, and Schreyer, A

Published

2016

8. Meiotic and pedigree segregation analyses in carriers of t(4;8)(p16;p23.1) differing in localization of breakpoint positions at 4p subband 4p16.3 and 4p16.1

Author

Midro, AT, ZOLLINO, MARCELLA, Wiland, E, Panasiuk, B, Iwanowski, PS, MURDOLO, MARINA, Śmigiel, R, Sąsiadek, M, Pilch, J, Kurpisz, M, Midro, AT, ZOLLINO, MARCELLA, Wiland, E, Panasiuk, B, Iwanowski, PS, MURDOLO, MARINA, Śmigiel, R, Sąsiadek, M, Pilch, J, and Kurpisz, M

Published

2015

9. Meiotic and pedigree segregation analyses in carriers of t(4;8)(p16;p23.1) differing in localization of breakpoint positions at 4p subband 4p16.3 and 4p16.1

Author

Midro, At, Zollino, Marcella, Wiland, E, Panasiuk, B, Iwanowski, P, Murdolo, Marina, Śmigiel, R, Sąsiadek, M, Pilch, J, Kurpisz, M., Zollino, Marcella (ORCID:0000-0003-4871-9519), Midro, At, Zollino, Marcella, Wiland, E, Panasiuk, B, Iwanowski, P, Murdolo, Marina, Śmigiel, R, Sąsiadek, M, Pilch, J, Kurpisz, M., and Zollino, Marcella (ORCID:0000-0003-4871-9519)

Abstract

The purpose of this study was to compare meiotic segregation in sperm cells from two carriers with t(4;8)(p16;p23.1) reciprocal chromosome translocations (RCTs), differing in localization of the breakpoint positions at the 4p subband-namely, 4p16.3 (carrier 1) and 4p16.1 (carrier 2)-and to compare data of the pedigree analyses performed by direct method.

Published

2015

10. Wolf-Hirschhorn syndrome due to pure and translocation forms of monosomy 4p16.1 → pter

Author

Iwanowski, P, Panasiuk, B, Van Buggenhout, G, Murdolo, Marina, Myśliwiec, M, Maas, Nmc, Lattante, Serena, Korniszewski, L, Posmyk, R, Pilch, J, Zajączek, S, Fryns, J, Zollino, Marcella, Midro, At, Lattante, Serena (ORCID:0000-0003-2891-0340), Zollino, Marcella (ORCID:0000-0003-4871-9519), Iwanowski, P, Panasiuk, B, Van Buggenhout, G, Murdolo, Marina, Myśliwiec, M, Maas, Nmc, Lattante, Serena, Korniszewski, L, Posmyk, R, Pilch, J, Zajączek, S, Fryns, J, Zollino, Marcella, Midro, At, Lattante, Serena (ORCID:0000-0003-2891-0340), and Zollino, Marcella (ORCID:0000-0003-4871-9519)

Abstract

The aim of this study was to obtain a quantitative definition of Wolf-Hirschhorn syndrome (WHS) through systematic phenotypic analyses in a group of six children with 4p15.32 → pter, 4p15.33 → pter, or 4p16.1 → pter monosomy (considered together as M4p16.1). These results were used for evaluation of the phenotypic effects of a double chromosome imbalance in one child with 4p16.1 → pter monosomy and additional 11q23.3 → qter trisomy. Children with pure M4p16.1 presented with a total of 227 clinical and morphological traits, of which 119 were positive in at least two of them. These traits overlap to a great extent with clinical criteria defining the WHS phenotype. Among the 103 traits identified in the child with unbalanced translocation der(4)t(4;11)(p16.1;q23.3), most clinical and developmental traits (but only 11 morphological) were found to be shared by WHS children with pure M4p16.1 and at least one reported patient with pure 11q trisomy. Forty-six traits of this child corresponded solely to those identified in at least one child with pure M4p16.1. Only five traits of the hybrid phenotype were present in at least one child with pure distal 11q trisomy but in none of the present children with pure M4p16.1. In conclusion, most of the morphological traits of the hybrid phenotype in the child with der(4)t(4;11)(p16.1;q23.3) can be attributed to the M4p16.1, whereas their overlap with those associated with pure distal 11q trisomy is less evident. Phenotype analyses based on the same systematic data acquisition may be useful in understanding the phenotypic effects of different chromosome regions in complex rearrangements. © 2011 Wiley-Liss, Inc.

Published

2011