| 11556448 | Microdeletion del(22)(q12.1) excluding the MN1 gene in a patient with craniofacial anomalies. | Bosson C, etal., Am J Med Genet A. 2016 Feb;170A(2):498-503. doi: 10.1002/ajmg.a.37450. Epub 2015 Nov 6. | Several studies have recently reported that 22q12.1 deletions encompassing the MN1 gene are associated with craniofacial anomalies. These observations are consistent with the hypothesis that MN1 haploinsufficiency may be sol ely responsible for craniofacial anomalies and/or cleft palate. We report here the case of a 4-year-old boy presenting with global developmental delay and craniofacial anomalies including severe maxillary protrusion and retromicrognathia. Array-CGH detected a 2.4 Mb de novo deletion of chromosome 22q12.1 which did not encompass the MN1 gene thought to be the main pathological candidate in 22q12.1 deletions. This observation, combined with data from other patients from the Database of Chromosomal Imbalance and Phenotype in Humans Using Ensemble Resources (DECIPHER), suggests that other gene(s) in the 22q12.1 region are likely involved in craniofacial anomalies and/or may contribute to the phenotypic variability observed in patients with MN1 deletion. | 26545049 | 2016-11-01 |
| 11536322 | Chromosome 22q12.1 microdeletions: confirmation of the MN1 gene as a candidate gene for cleft palate. | Breckpot J, etal., Eur J Hum Genet. 2016 Jan;24(1):51-8. doi: 10.1038/ejhg.2015.65. Epub 2015 May 6. | We report on seven novel patients with a submicroscopic 22q12 deletion. The common phenotype constitutes a contiguous gene deletion syndrome on chromosome 22q12.1q12.2, featuring NF2-related schwannoma of the vestibular nerve, corpus callosum agenesis and palatal defects. Combining our results with the literature, eight patients are recorded with palatal defects in association with haploinsufficiency of 22q12.1, including the MN1 gene. These observations, together with the mouse expression data and the finding of craniofacial malformations including cleft palate in a Mn1-knockout mouse model, suggest that this gene is a candidate gene for cleft palate in humans. | 25944382 | 2016-09-01 |
| 1600423 | Cloning and characterization of MN1, a gene from chromosome 22q11, which is disrupted by a balanced translocation in a meningioma. | Lekanne Deprez RH, etal., Oncogene. 1995 Apr 20;10(8):1521-8. | We have isolated a gene, called MN1, which resides on chromosome 22 and which was found to be disrupted by a balanced translocation (4;22) in meningioma 32. The MN1 gene spans about 70 kb and consists of at least two large e xons of approximately 4.7 kb and 2.8 kb. The MN1 cDNA codes for a protein of 1319 amino acids when the first methionine in the open reading frame is used. The MN1 cDNA contains two CAG repeats, one of which codes for a string of 28 glutamines. The t(4;22) disrupts the 5'-exon within the open reading frame. In meningioma 32 no expression of the MN1 mRNA is observed. These results suggest that inactivation of the MN1 gene in this tumour may contribute to its pathogenesis. | 7731706 | 1995-03-01 |
| 598119328 | Gain-of-Function MN1 Truncation Variants Cause a Recognizable Syndrome with Craniofacial and Brain Abnormalities. | Miyake N, etal., Am J Hum Genet. 2020 Jan 2;106(1):13-25. doi: 10.1016/j.ajhg.2019.11.011. Epub 2019 Dec 12. | MN1 was originally identified as a tumor-suppressor gene. Knockout mouse studies have suggested that Mn1 is associated with craniofacial development. However, no MN1-related phenotypes h ave been established in humans. Here, we report on three individuals who have de novo MN1 variants that lead to a protein lacking the carboxyl (C) terminus and who presented with severe developmental delay, craniofacial abnormalities with specific facial features, and structural abnormalities in the brain. An in vitro study revealed that the deletion of the C-terminal region led to increased protein stability, an inhibitory effect on cell proliferation, and enhanced MN1 aggregation in nuclei compared to what occurred in the wild type, suggesting that a gain-of-function mechanism is involved in this disease. Considering that C-terminal deletion increases the fraction of intrinsically disordered regions of MN1, it is possible that altered phase separation could be involved in the mechanism underlying the disease. Our data indicate that MN1 participates in transcriptional regulation of target genes through interaction with the transcription factors PBX1, PKNOX1, and ZBTB24 and that mutant MN1 impairs the binding with ZBTB24 and RING1, which is an E3 ubiquitin ligase. On the basis of our findings, we propose the model that C-terminal deletion interferes with MN1's interaction molecules related to the ubiquitin-mediated proteasome pathway, including RING1, and increases the amount of the mutant protein; this increase leads to the dysregulation of MN1 target genes by inhibiting rapid MN1 protein turnover. | 31839203 | 2020-01-02 |
| 598116546 | MN1 C-terminal truncation syndrome is a novel neurodevelopmental and craniofacial disorder with partial rhombencephalosynapsis. | Mak CCY, etal., Brain. 2020 Jan 1;143(1):55-68. doi: 10.1093/brain/awz379. | MN1 encodes a transcriptional co-regulator without homology to other proteins, previously implicated in acute myeloid leukaemia and development of the palate. Large deletions encompassing MN1 have been reported in individual s with variable neurodevelopmental anomalies and non-specific facial features. We identified a cluster of de novo truncating mutations in MN1 in a cohort of 23 individuals with strikingly similar dysmorphic facial features, especially midface hypoplasia, and intellectual disability with severe expressive language delay. Imaging revealed an atypical form of rhombencephalosynapsis, a distinctive brain malformation characterized by partial or complete loss of the cerebellar vermis with fusion of the cerebellar hemispheres, in 8/10 individuals. Rhombencephalosynapsis has no previously known definitive genetic or environmental causes. Other frequent features included perisylvian polymicrogyria, abnormal posterior clinoid processes and persistent trigeminal artery. MN1 is encoded by only two exons. All mutations, including the recurrent variant p.Arg1295* observed in 8/21 probands, fall in the terminal exon or the extreme 3' region of exon 1, and are therefore predicted to result in escape from nonsense-mediated mRNA decay. This was confirmed in fibroblasts from three individuals. We propose that the condition described here, MN1 C-terminal truncation (MCTT) syndrome, is not due to MN1 haploinsufficiency but rather is the result of dominantly acting C-terminally truncated MN1 protein. Our data show that MN1 plays a critical role in human craniofacial and brain development, and opens the door to understanding the biological mechanisms underlying rhombencephalosynapsis. | 31834374 | 2020-01-01 |
| 1600424 | Translocation (12;22) (p13;q11) in myeloproliferative disorders results in fusion of the ETS-like TEL gene on 12p13 to the MN1 gene on 22q11. | Buijs A, etal., Oncogene. 1995 Apr 20;10(8):1511-9. | In myeloid and lymphoid leukemias recurrent chromosomal aberrations can be detected in chromosome region 12p13. We characterized the genes involved in t(12;22) (p13;q11) in two patients with myeloid leukemia and one with myelodysplastic syndrome (MDS). MN1, a ge ne on chromosome 22q11 was shown to be fused to TEL, a member of the family of ETS transcription factors on chromosome 12p13. The translocation results in transcription of the reciprocal fusion mRNAs, MN1-TEL and TEL-MN1, of which MN1-TEL is likely to encode an aberrant transcription factor containing the ETS DNA-binding domain of TEL. In addition to fusion of TEL to the PDGF beta receptor in t(5;12) in chronic myelomonocytic leukemia (CMML), our data suggest that the involvement of this protein in myeloid leukemogenesis could be dual; its isolated protein-protein dimerization and DNA-binding domains may be crucial for the oncogenic activation of functionally different fusion proteins. | 7731705 | 1995-03-01 |
