Schmidtea mediterranea as a Model Organism to Study the Molecular Background of Human Motile Ciliopathies
Abstract
:1. Introduction–Cilia and Ciliopathies
1.1. Primary Ciliary Dyskinesia
1.2. The Validation of New Genes Underlying PCD and PCD-like Ciliopathies—The Role of Model Organisms
2. Schmidtea mediterranea
2.1. Advantages of the S. mediterranea as a Model Organism
2.2. S. mediterranea Model in the Context of Studying Cilia Biology
2.3. S. mediterranea Model in the Context of Studying PCD and PCD-like Ciliopathies
3. Perspectives
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Gene (Alias) | Role in Motile Cilia Biogenesis or Part of Axonemal Structure | Defects (Mode of Detection) | Confirmation from Selected Animal Models | Seminal References |
---|---|---|---|---|
Cytoplasmic proteins | ||||
CCNO MCIDAS | Centriole amplification „ | Sparse cilia (light microscope, TEM, IF against AcAT) | Xenopus Xenopus | [30] [29,30] |
FOXJ11; autos. dominant RPGR; X-linked OFD1; X-linked GAS2L2 | BB stabiliz./orientation BB docking BB docking BB stabilization | BB mislocalized and more (TEM–except for GAS2L2; IF against BB elements) | Xenopus, Drerio, mouse, Smed Drerio Paramecium, Smed, mouse Mouse, Xenopus | [31,48,49,50] [51,52,53] [54,55,56,57,58] [59] |
DNAAF3 (c19orf51) CFAP300 (c11orf70) SPAG1 (DNAAF13) DNAAF1 (LRRC50) DNAAF5 (HEATR2) DNAAF6 (PIH1D3); X-linked DNAAF7 (ZMYND10) DNAAF11 (LRRC6) CFAP298 (c21orf59) DNAAF2 (KTU) DNAAF4 (DYX1C1) DAW1 (WDR69,ODA16) | ODA/IDA preassembly „ „ „ „ „ „ „ „ Distal ODA preassembly “ “ | Absent/shortened DA (TEM; IF against ODA or IDA elements) | Chlamy, Drerio Chlamy, Paramecium, Smed Drerio Chlamy, Tryp, Drerio, Smed Drosi, mouse Drerio, Drosi, mouse Drerio, Drosi, Xenopus, mouse Drosi, Drerio, mouse Drerio, Chlamy, Smed medaka, Chlamy, mouse Drerio, mouse Drerio, Smed, mouse, Chlamy | [60] [61,62,63] [64] [65,66,67,68] [69,70] [71,72,73,74] [75,76] [75,77,78,79,80] [81] [82] [83] [84,85,86] |
TTC12 | IDA assembly (in sperm IDA and ODA) | Some IDA types absent (TEM; IF against IDA elements, e.g., DNALI1) | Paramecium | [87] |
Elements of axonemal ultrastructure | ||||
DNAI1 DNAI2 DNAH52 TXNDC3 (NME8; DNAI8) DNAL1 DNAH113 DNAH93 | ODA “ “ “ “ Proximal ODA Distal ODA | Absent/shortened ODA (TEM–except for DNAH11; IF against ODA elements, e.g., DNAH5, DNAI2) | Chlamy Chlamy, Smed Chlamy Ciona Chlamy, Smed, Tryp Chlamy, mouse Chlamy, Paramecium, mouse | [88,89] [90,91,92] [93,94] [95,96] [91,97,98,99] [94,100,101] [94,102,103] |
CCDC114 (ODAD1) ARMC4 (ODAD2) TTC25 (ODAD4) CCDC151 (ODAD3) CCDC1034 LRRC56 (DNAAF12) | ODA targeting/docking „ „ „ Distal ODA targeting/docking “ | Absent/shortened ODA (TEM; IF against ODA elements) | Chlamy Drerio, mouse Xenopus, mouse, Drerio Chlamy, Smed, Drerio, mouse Chlamy, Drerio Tryp | [104,105] [106] [107,108] [109,110,111] [112,113] [114] |
CFAP57(WDR65) | IDA assembly | No TEM defect (IF) | Chlamy | [115,116] |
CCDC39 (CFAP59) CCDC40 (CFAP172) | AR “ | Mislocalized MTs, absent IDA (TEM; IF against AR elements or GAS8) | Drerio, mouse, dog Drerio, mouse | [117] [118] |
GAS8 (GAS11; DRC4) DRC1 (CCDC164) CCDC65 (DRC2; CFAP250) | NDR complex „ „ | MT mislocalized or no visible defect (IF against GAS8) | Chlamy, Tryp, Drerio, mouse Chlamy Chlamy, Drerio | [119,120,121,122] [123] [81,124,125] |
RSPH1 RSPH4A RSPH9 RSPH3 DNAJB13 (RSPH16A) NME5 (RSPH23) | RS head „ „ RS stalk „ RS neck | Central pair and MTs mislocalized (TEM except for DNAJB13; IF against RS’ elements) | mouse mouse Chlamy, Drerio, mouse Chlamy Chlamy, mouse Drerio, dog | [126,127,128] [129,130] [129] [131,132] [133,134,135] [136,137] |
HYDIN STK36 (FUSED) SPEF2 CFAP74 | CP complex “ “ “ | CP complex defects (no visible defect in TEM; IF against SPEF2, STK36; not for CFAP74) | Chlamy, mouse, Tryp Smed, Drerio, mouse mouse Chlamy | [138,139,140,141,142] [143,144,145] [139,146] [147,148] |
CFAP221 (PCDP1) | “ | No TEM defect | mouse, Chlamy | [148,149,150] |
Gene (Alias) | Role in Motile Cilia Biogenesis or Part of Axonemal Structure | Relevance for PCD | Confirmation from Selected Animal Models | Seminal References |
---|---|---|---|---|
CCDC19 (CFAP45) | Inner lumen protein | Only mild respiratory symptoms | Ch. reinhardtii, S. mediterranea, mouse | [24,151] |
WDR16 (CFAP52) | Inner lumen protein | Only mild respiratory symptoms | Ch. reinhardtii, S. mediterranea | [24,151,152] |
TP73; lissencephaly | Ciliogenesis | Strong PCD candidate | mouse | [153,154] |
NEK10 | Centrosome; kinase | PCD candidate | medaka | [155,156] |
CCDC113 (CCDC96) | NDR complex | PCD candidate | T. thermophila | [22] |
TEKT1 | Centrosome, BB, axoneme | PCD candidate | D. rerio | [157] |
CEP164 | Centriole; BB docking | PCD candidate | mouse | [158,159] |
CFAP206 | BB and axoneme | PCD candidate | T. thermophila, Ch. reinhardtii, X. laevis, mouse | [160,161,162] |
MNS1 | ODA docking | Laterality defect, male infertility | mouse | [163,164] |
BRWD1 | Axoneme | Male infertility | - | [165] |
CFAP43 | Axoneme | Male infertility | X. laevis, mouse | [166] |
CCDC11 (CFAP53) | Ciliogenesis | Laterality defects | X. laevis | [167,168] |
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Rabiasz, A.; Ziętkiewicz, E. Schmidtea mediterranea as a Model Organism to Study the Molecular Background of Human Motile Ciliopathies. Int. J. Mol. Sci. 2023, 24, 4472. https://doi.org/10.3390/ijms24054472
Rabiasz A, Ziętkiewicz E. Schmidtea mediterranea as a Model Organism to Study the Molecular Background of Human Motile Ciliopathies. International Journal of Molecular Sciences. 2023; 24(5):4472. https://doi.org/10.3390/ijms24054472
Chicago/Turabian StyleRabiasz, Alicja, and Ewa Ziętkiewicz. 2023. "Schmidtea mediterranea as a Model Organism to Study the Molecular Background of Human Motile Ciliopathies" International Journal of Molecular Sciences 24, no. 5: 4472. https://doi.org/10.3390/ijms24054472
APA StyleRabiasz, A., & Ziętkiewicz, E. (2023). Schmidtea mediterranea as a Model Organism to Study the Molecular Background of Human Motile Ciliopathies. International Journal of Molecular Sciences, 24(5), 4472. https://doi.org/10.3390/ijms24054472