9q34.3 deletion syndrome
| 9q34.3 deletion syndrome | |
|---|---|
| Other names | Kleefstra syndrome |
 | |
| This photo shows person with Kleefstra syndrome, with unibrow, relative mandibular prognathism, a short nose with wide base, hypertelorism with epicanthus. Although, not shown in the picture, this person also has overfolded ears that are posteriorly angulated with a deep notch on the left ear lobe. | |
| Specialty | Medical genetics  |
| Symptoms | Arched eyebrows, small head circumference, midface hypoplasia, prominent jaw and a pouting lower lip.[1] |
| Causes | Genetics. |
| Diagnostic method | Fluorescence in situ hybridization, multiplex ligation-dependent probe amplification, array comparative genomic hybridization, and EHMT1 sequencing.[2] |
| Differential diagnosis | Down syndrome, Smith-Magenis syndrome, Pitt-Hopkins syndrome, Angelman syndrome, and MBD5 haploinsufficiency.[3] |
| Named after | Tjitske Kleefstra |
9q34 deletion syndrome, now known as Kleefstra syndrome, is a rare genetic disorder. Terminal deletions of chromosome 9q34 have been associated with childhood hypotonia, distinctive facial appearance and intellectual disability. Most individuals fall within the moderate to severe range of intellectual disability, while a minority shows mild delays and have total IQ scores within the low-normal range.[4] Typical facial features include arched eyebrows, microcephaly, midface hypoplasia, a prominent jaw and a pouting lower lip. Affected individuals often exhibit speech impairments, including significant speech delays. Severe expressive language delays with limited speech production are common; however, general language development is often more advanced, enabling non-verbal communication.[3] Other common features include epilepsy, congenital and urogenital anomalies, microcephaly, obesity, and psychiatric disorders.[1] Through analysis of chromosomal breakpoints, as well as gene sequencing in suggestive cases, Kleefstra and colleagues identified EHMT1 as the causative gene:[5] this gene is responsible for producing the protein histone methyltransferase whose function is to alter histones. Histone methyltransferases are also important in deactivating certain genes needed for proper growth and development. Moreover, a frameshift, missense, or nonsense error in the coding sequence of EHMT1 can result in this condition in an individual.[3]
Signs and symptoms
[edit]Physical symptoms
- Heart defects
- Characteristics of autism
- Genital defects (in males)
- Childhood hypotonia
- Respiratory infections
- Motor delay
- Renal defects
- Severe delay or total lack of speech
- Happy disposition
- Dysmorphic facial features
- Visual issues (hypermetropia)
- Hearing loss (sensorineural and/or conductive)
Behavioural symptoms
- Passiveness
- Sociability
- Aggression
- Biting or hitting
- Moodiness
- Disliking routine changes[3][6]
- Extreme apathy
Genetics
[edit]
Despite the associated effects of Kleefstra Syndrome, there is limited information regarding its lethality. Most documented cases are de novo with the exception of one case due to hereditary factors; however, some cases may result from chromosomal translocations.
In the hereditary case, the mother transferred the EHMT1 point mutation on to her child as she was a carrier of this gene defect. According to Mitter, et al. (2012), the mother's phenotype for the NM_024757.4:c.2712+1G>A mutation exhibits tissue-specific mosaicism. This mutation led to the skipping of exon 18 in the EHMT1 gene, rather than its removal by spliceosomes. In another transcript, however, an intron was inserted between exons 18 and 19 of the EHMT1 gene. The combination of the intron retention and maternalmosaicism was transferred to the child, resulting in the pathogenesis of the disease.[7]
In the past, research showed that the austerity of the disease was directly proportional to the number of EHMT1 deletions prevalent in an individual. The greater the deletions, the greater the severity of the condition. However, recent studies indicate that Kleefstra syndrome (or 9q34 deletion syndrome) may result from a non-functional EHMT1 gene, regardless of whether the gene is deleted or mutated.[2]
Diagnosis
[edit]Tests are conducted either at birth or later in early childhood using techniques such as fluorescence in situ hybridization (FISH), multiplex ligation-dependent probe amplification (MLPA), array comparative genomic hybridization (aCGH), and EHMT1 gene sequencing.[2]
FISH is a screening method that uses fluorescently labeled probes or comparative genomic hybridization to find any chromosome irregularities in a genome. It is commonly used for gene mapping, detecting aneuploidy, locating tumours etc. The florescent probes hybridize to specific DNA sequences.[8]
MLPA is a test that finds and records DNA copy change numbers through the use of polymerase chain reaction (PCR). This technique can identify chromosomal abnormalities as well as tumor-related copy number variations, such as those found in glial cells of the brain.[9]
Array-based comparative genomic hybridization (aCGH) detects chromosomal deletions and duplications by labelling patient and reference DNA samples with fluorescent dyes and hybridizing them onto microarray slides containing genomic sequences. The DNA fragments analyzed typically range from 25 to 80 base pairs in length.[10]
Finally, EHMT1 gene sequencing involves isolating the DNA strand of the EHMT1 gene and synthesizing complementary strands using DNA polymerase. This process enables scientists to determine the precise nucleotide sequence of the gene, facilitating accurate diagnosis.[11]
Treatment
[edit]Individual manifestations are managed by a multidisciplinary team,[3] including speech therapists, physioterapists and other healthcare professionals. In particular, it is essential that the individual is monitored by a neurologist to ensure that treatment plans are appropriately adapted over time.[12]
Emerging treatments
[edit]Although there is currently no cure for Kleefstra Syndrome, ongoing research is focused on developing targeted therapies that address the underlying causes of the condition. Gene therapy and pharmacological interventions aimed at modulating gene expression represent promising areas of investigation.[13]
Epidemiology
[edit]Kleefstra Syndrome affects males and females equally and approximately 75% of documented cases are caused by disruptions in the EHMT1 gene, while the remaining 25% are due to terminal deletions in the 9q34.3 region of chromosome 9.[3] Currently, there are no reliable statistics on life expectancy due to the limited amount of long-term data available.[3]
History
[edit]Kleefstra syndrome was first identified in 2006 by Tjtske Kleefstra et al.[5] It is a relatively newly recognized condition, with fewer than 200 reported cases worldwide. Due to the rarity of the syndrome, the historical background and the origin of the condition remain poorly understood.[14]
Research
[edit]A study published in the American Journal of Human Genetics conducted an EHMT1 mutation analysis on 23 patients exhibiting symptoms consistent with 9q34 deletion syndrome. The patients varied in age, but the clinical discussion focused on five individuals, most of whom were children. The first patient developed epilepsy early in childhood and experienced persistent speech delays beyond age 8. He had midfacial hypoplasia and prominent facial features, particularly of the lips and mouth. The second patient had mild hypotonia but no family history of mitral regurgitation (MR). The third patient, the oldest at 36, began walking at age 3, experienced weight gain at age 11 anche developed epilepsy in her late twenties. The fourth patient had feeding difficulties in early childhood and was diagnosed with developmental delay. Patient five presented behavioral issues, struggled with MR and was overweight. The researchers identified three novel mutations in the EHMT1 gene: one interstitial deletion, one nonsense mutatione and one frameshift mutation. these findings support the hypothesis that disruptions in EHMT1 contribute to the pathogenesis of Kleefstra Syndrome.[15]
In another study published in the Journal of Medical Genetics, DNA from 40 patients were extracted and analyzed using MLPA, FISH or EHMT1 gene sequencing. The cohort was divided into two groups: 16 patients with a 9q34 deletion, and 24 patients with typical FISH/MPLA results. Researchers examined the potential functional impact of missense mutations using DNA modeling. After screening, results from the first group revealed that six patients had same 700 kb deletion. In the second group, EHMT1 sequencing identified six intragenic mutations. The researchers concluded that these mutations may act as causative factors in the development of the disease. Finally, the patients’ behavioral, physical, and psychiatric features were documented in a detailed data chart.[16]
See also
[edit]References
[edit]- ^ a b Willemsen MH, Vulto-van Silfhout AT, Nillesen WM, Wissink-Lindhout WM, van Bokhoven H, Philip N, Berry-Kravis EM, Kini U, van Ravenswaaij-Arts CM, Delle Chiaie B, Innes AM, Houge G, Kosonen T, Cremer K, Fannemel M, Stray-Pedersen A, Reardon W, Ignatius J, Lachlan K, Mircher C, Helderman van den Enden PT, Mastebroek M, Cohn-Hokke PE, Yntema HG, Drunat S, Kleefstra T (2012). "Update on Kleefstra Syndrome". Mol Syndromol. 2 (3–5): 202–212. doi:10.1159/000335648. PMC 3366700. PMID 22670141.
- ^ a b c Rare Chromosome Disorder Support Group, "Kleefstra Syndrome" Archived 2013-07-04 at the Wayback Machine, Kleefstra Syndrome, 2009
- ^ a b c d e f g Kleefstra T, Nillesen WM, Yntema HG (7 May 2015). "Kleefstra Syndrome". Seattle:GeneReviews. GeneReviews. PMID 20945554. Retrieved 3 February 2017.
- ^ Aydin, H., Bucak, I. H., & Bagis, H. (2022). Kleefstra Syndrome. Journal of the College of Physicians and Surgeons--Pakistan : JCPSP, 32(4), S76–S78. https://doi.org/10.29271/jcpsp.2022.Supp1.S76
- ^ a b Kleefstra, T (2005). "Disruption of the gene Euchromatin Histone Methyl Transferase1 (Eu-HMTase1) is associated with the 9q34 subtelomeric deletion syndrome". Journal of Medical Genetics. 42 (4): 299–306. doi:10.1136/jmg.2004.028464. ISSN 1468-6244. PMC 1736026. PMID 15805155.
- ^ Andrea Belanger, "Kleefstra Syndrome", Mommies of Miracles, 2011
- ^ Rump, A; Hildebrand, L; Tzschach, A; Ullmann, R; Schrock, E; Mitter, D (August 2013). "A mosaic maternal splice donor mutation in the EHMT1 gene leads to aberrant transcripts and to Kleefstra syndrome in the offspring". European Journal of Human Genetics. 21 (8): 887–90. doi:10.1038/ejhg.2012.267. PMC 3722677. PMID 23232695.
- ^ Bishop, R. (27 February 2010). "Applications of fluorescence in situ hybridization (FISH) in detecting genetic aberrations of medical significance". Bioscience Horizons. 3 (1): 85–95. doi:10.1093/biohorizons/hzq009.
- ^ Jeuken, Judith; Cornelissen, Sandra; Boots-Sprenger, Sandra; Gijsen, Sabine; Wesseling, Pieter (September 2006). "Multiplex Ligation-Dependent Probe Amplification". The Journal of Molecular Diagnostics. 8 (4): 433–443. doi:10.2353/jmoldx.2006.060012. PMC 1867615. PMID 16931583.
- ^ Peng, H.H., & Van den Veyyer, I.B. "HOW DOES ARRAY-BASED COMPARATIVE GENOMIC HYBRIDIZATION WORK?", 2008
- ^ N/A, "Principles of DNA Sequencing" Archived 2013-04-04 at the Wayback Machine, 2013
- ^ Kleefstra, T., Kramer, J. M., Neveling, K., Willemsen, M. H., Koemans, T. S., Vissers, L. E., Wissink-Lindhout, W., Fenckova, M., van den Akker, W. M., Kasri, N. N., Nillesen, W. M., Prescott, T., Clark, R. D., Devriendt, K., van Reeuwijk, J., de Brouwer, A. P., Gilissen, C., Zhou, H., Brunner, H. G., Veltman, J. A., … van Bokhoven, H. (2012). Disruption of an EHMT1-associated chromatin-modification module causes intellectual disability. American journal of human genetics, 91(1), 73–82. doi.org/10.1016/j.ajhg.2012.05.003
- ^ "Sindrome di Kleefstra".
- ^ "What is Kleefstra syndrome?". Kleefstrasyndrome.org. Retrieved 3 February 2017.
- ^ Kleefstra, Tjitske; Brunner, Han G.; Amiel, Jeanne; Oudakker, Astrid R.; Nillesen, Willy M.; Magee, Alex; Geneviève, David; Cormier-Daire, Valérie; van Esch, Hilde; Fryns, Jean-Pierre; Hamel, Ben C.J.; Sistermans, Erik A.; de Vries, Bert B.A.; van Bokhoven, Hans (August 2006). "Loss-of-Function Mutations in Euchromatin Histone Methyl Transferase 1 (EHMT1) Cause the 9q34 Subtelomeric Deletion Syndrome". The American Journal of Human Genetics. 79 (2): 370–377. doi:10.1086/505693. PMC 1559478. PMID 16826528.
- ^ Kleefstra, T; van Zelst-Stams, W A; Nillesen, W M; Cormier-Daire, V; Houge, G; Foulds, N; van Dooren, M; Willemsen, M H; Pfundt, R; Turner, A; Wilson, M; McGaughran, J; Rauch, A; Zenker, M; Adam, M P; Innes, M; Davies, C; Lopez, A G.-M.; Casalone, R; Weber, A; Brueton, L A; Navarro, A D.; Bralo, M P.; Venselaar, H; Stegmann, S P A; Yntema, H G; van Bokhoven, H; Brunner, H G (4 March 2009). "Further clinical and molecular delineation of the 9q subtelomeric deletion syndrome supports a major contribution of EHMT1 haploinsufficiency to the core phenotype". Journal of Medical Genetics. 46 (9): 598–606. doi:10.1136/jmg.2008.062950. PMC 3395372. PMID 19372089.