Variability of CATCH-22 symptome complex within the framework of 22q11.2 deletion syndrome

Chromosomal pathology is one of the most common causes of congenital malformations. The CATCH-22 symptom complex is most often associated with a microdeletion of chromosome 22, upon detection of which it is customary to diagnose DiGeorge syndrome, a known primary immunodeficiency or syndrome of innate errors of immunity. According to our data on the frequency of occurrence among all chromosomal abnormalities, DiGeorge’s syndrome takes second place in the Sverdlovsk region after Down’s syndrome, but its diagnosis is not simple due to varying severity of clinical manifestations, as well as different forms of the chromosome 22 defects. Along with several typical variants of 22q11 microdeletions, there duplications of critical regions are also reported, accompanied by immunodeficiency and other symptoms of CATCH-22. The effectiveness of diagnosing chromosomal abnormalities both in pre- and postnatal period largely depends on the grouping criteria of the patients with suspected chromosomal abnormalities, and on the methods used to identify hereditary pathology. In our study, we analyzed and compared the results of studies of 23 patients with various rearrangements of the 22q11.2 region, which were observed by a geneticist and clinical immunologist. The paper presents data on the polymorphism of phenotypes associated with rearrangements of the 22q11.2 region with an analysis of pathomorphological manifestations depending on the type of structural anomaly, i.e, del22q11.2, or dup22q11.2. The results of analysis demonstrate importance of different diagnostic options for laboratory studies of microdeletion and microduplication syndromes associated with immune-dependent pathology. We also compared the results of molecular genetic diagnostics and phenotypic manifestations in deletions and duplications of the 22q11.2 region. To identify the rearrangements of 22q11.2 region, two different methods were used – Prenatal BoBs and multiplex ligase-dependent probes’ amplification (MLPA). In particular, the both methods were used in the same patient to verify diagnosis, thus enabling to show differences in their efficiency. It was concluded that 22q11.2 deletion syndrome exhibits wide heterogeneity in phenotypic traits: neurological and immunological manifestations, anomalies in musculoskeletal development and internal organs, skull deformities and facial dysmorphia. Each clinical case was unique, requiring careful analysis of clinical manifestations. It is necessary to have a wide range of laboratory options for molecular genetic verification of the diagnosis.

Rapid, Reference-Free Human Genotype Imputation with Denoising Autoencoders

Genotype imputation is a foundational tool for population genetics. Standard statistical imputation approaches rely on the co-location of large whole-genome sequencing-based reference panels, powerful computing environments, and potentially sensitive genetic study data. This results in computational resource and privacy-risk barriers to access to cutting-edge imputation techniques. Moreover, the accuracy of current statistical approaches is known to degrade in regions of low and complex linkage disequilibrium.Artificial neural network-based imputation approaches may overcome these limitations by encoding complex genotype relationships in easily portable inference models. Here we demonstrate an autoencoder-based approach for genotype imputation, using a large, commonly-used reference panel, and spanning the entirety of human chromosome 22. Our autoencoder-based genotype imputation strategy achieved superior imputation accuracy across the allele-frequency spectrum and across genomes of diverse ancestry, while delivering at least 4-fold faster inference run time relative to standard imputation tools.

A Pilot Study about Clinical Features of Aberrations Chromosome 22q

Objective A significant number of genetic variations have been identified in chromosome 22, using molecular genetic techniques. Various genomic disorders on chromosome 22, including cat's eye syndrome caused by extra copies of the proximal region of the 22q chromosome, are now well-defined.Our aim in the study was to show phenotypic variability associated with rearrangements of the 22q chromosomal region. Methods We focused our study on clinical aspects of these disorders, including genetic testing, genotype-phenotype correlation, and potential treatments. A total of 998 patients were referred for genetic analysis (Karyotyping, MLPA, array-CGH) during January 2015 to February 2020 because of intellectual deficiency, behavior issues, and/or multiple congenital abnormalities in several genetics departments. Informed consent was obtained from all the patients and/or their parents. Results 22q11.21 or 22q13.33 microdeletions and 22q11.22-q11.23 microduplication were identified in 31 patients out of referrals. The 22q aberrations were detected in 31/998 patients, giving a prevalence of 3.1%. In this study, 18 patients with 22q11.2 (LCR22A-H) deletion, three patients with 22q13.31 deletion, 9 patients with 22q11.2 duplication and one patient with 22q13.31 duplication were identified. We report on the clinical and molecular characterization of 31 individuals with distal deletions and duplications of chromosome 22q. Conclusions The current study demonstrated in the largest postnatal case series reporting the whole spectrum of atypical phenotypic and genotypic variations at 22q. We believe that when all the phenotypic differences are taken into account, various anomalies including developmental delay and intellectual disability might be considered as an indication to search for aberrations of 22q along with congenital heart diseases.

Case Report: The Emerging Role of Ring Chromosome 22 in Phelan-McDermid Syndrome With Atypical Teratoid/Rhabdoid Tumor: The First Child Treated With Growth Hormone

Atypical teratoid/rhabdoid tumors (AT/RTs) in the rhabdoid tumor predisposition syndromes are most often caused by germline mutations of the SMARCB1 gene located in chromosome 22q11.2. Although rarely, it can also result from the constitutional ring chromosome 22 (r22): during mitosis the ring chromosome may lead to an increased rate of somatic mutations, resulting in rhabdoid tumor predispositions when the tumor-suppressor gene SMARCB1 is involved. Individuals with r22 may present similar features as those with Phelan-McDermid syndrome (PMDS) due to 22q13.3 deletion, including the SHANK3 gene. Despite several reports on AT/RT in children with r22 and/or PMDS have been published, the role of constitutional r22 as new oncogenic mechanism for AT/RT is still under investigation. There is not a lot of data available on therapeutic and prognostic implications of r22 in AT/RT and PMDS. Herein, we present the first case of a child with constitutional r22, PMDS and AT/RT of the brain, who is a long term survivor and is been treated with growth hormone. We also describe an unexpected adverse reaction to midazolam.

Congenital Acute Lymphoblastic Leukemia – A Mosaic Trisomy Chromosome 22 and t(5;15)(p15;q15) : A Case Report

Neonatal leukaemia is a rare blood cancer occurring in baby less than 30 days of life is characterized by proliferation of white cells without known and obvious reasons. We report a case of a 7-day- old girl diagnosed with congenital leukaemia. At the time of presentation, she was evaluated as early neonatal sepsis. However, her laboratory investigations were consistent with B cell acute lymphoblastic leukaemia. Her cytogenetic analysis showed 46 XX trisomy 22, t(5,15) (p15,q15) and del 7 (q33,q35). She was managed with standard Interfant 06 protocol and had achieved marrow remission during the course of chemotherapy. Our case highlights the differentiation between lymphocytic leukemoid reaction and lymphoblastic malignant cells and also congenital acute lymphoblastic leukaemia who had a good outcome from the chemotherapy.

A Turner syndrome case associated with dic(Y;22)

Background Constitutional telomeric associations are very rare events and the mechanism underlying their development is not well understood. Case presentation We here describe a female case of Turner syndrome with a 45,X,add(22)(p11.2)[25]/45,X[5]. We reconfirmed this karyotype by FISH analysis as 45,X,dic(Y;22)(p11.3;p11.2)[28]/45,X[2].ish dic(Y;22)(SRY+,DYZ1+). A possible mechanism underlying this mosaicism was a loss of dic(Y;22) followed by a monosomy rescue of chromosome 22. However, SNP microarray analysis revealed no loss of heterozygosity (LOH) in chromosome 22, although a mosaic pattern of LOH was clearly detectable at the pseudoautosomal regions of the sex chromosomes. Conclusions Our results suggest that the separation of the dicentric chromosome at the junction resulted in a loss of chromosome Y without a loss of chromosome 22, leading to this patient’s unique mosaicism. Although telomere signals were not detected by FISH at the junction, it is likely that the original dic(Y;22) chromosome was generated by unstable telomeric associations. We propose a novel “pulled apart” mechanism as the process underlying this mosaicism.

Prenatal diagnosis of Meier-Gorlin syndrome 7: a case presentation

Background Meier-Gorlin syndrome 7 (MGS7) is a rare autosomal recessive condition. We reported a fetus diagnosed with Meier-Gorlin syndrome 7. The antenatal sonographic images were presented, and compound heterozygous mutations of CDC45 on chromosome 22 were identified by whole-exome sequencing (WES). Case presentation Fetal growth restriction (FGR), craniosynostosis, and brachydactyly of right thumb were found in a fetus of 28th gestational weeks. The fetus was diagnosed as MGS7 clinically. After extensive counseling, the couple opted for prenatal diagnosis by cordocentesis and termination of pregnancy. Karyotype analysis and WES were performed. Chromosomal karyotyping showed that the fetus was 46, XY. There were 2 mutations of CDC45, the causal gene of MGS7 on chromosome 22, which were inherited from the couple respectively were identified by WES. Facial dysmorphism, brachydactyly of right thumb, and genitalia abnormally were proved by postpartum autopsy, and craniosynostosis was confirmed by three-dimensional computed tomography (3D-CT) reconstruction. Conclusions It is possible to detect multiple clinical features of Meier-Gorlin syndrome in prenatal sonography. Deteriorative FGR complicated with craniosynostosis indicates MGS7. Combination of 2D and 3D ultrasonography helps to detect craniosynostosis. The affected fetus was confirmed a compound heterozygote of CDC45 related MGS by whole-exome sequencing, which is critical in identifying rare genetic diseases.

Mayer-Rokitansky-Küster-Hauser syndrome with 22q11.21 microduplication: a case report

Background Mayer-Rokitansky-Küster-Hauser (MRKH) syndrome (Online Mendelian Inheritance in Man [OMIM] #277000) is a congenital condition characterized by the total or partial agenesis of vagina and uterus. Agenesis can be isolated (MRKH 1) or associated with other renal, vertebral or cardiac defects (MRKH 2). Case presentation In this paper, we report a case of a Caucasian patient showing the clinical signs associated with MRKH. Array-based comparative genomic hybridization (a-CGH) analysis revealed a microduplication of approximately 3.01 megabases (Mb) located on the long arm of chromosome 22 (22q11.21). Microduplications affecting the 22q11.21 region have been shown to be associated with MRKH syndrome and Müllerian aplasia. The phenotype of patients with 22q11.2 duplication (OMIM #608363) appears extremely variable, ranging from apparently normal to mild learning difficulties or with multiple defects, sharing features with DiGeorge/velocardiofacial (DGS/VCFS) syndrome. Conclusions The altered gene expression together with other genetic, nongenetic, epigenetic or environmental factors can cause the extremely variable phenotype in patients carrying such duplication. Therefore, we can consider MRKH syndrome to be one of the clinical features of DGS/VCFS syndrome.

Involving FCGR images in studying fractality and multifractality in human chromosome 22 and bacteria complete genome

The frequency chaos game representation (FCGR) is a simple yet powerful visualization method of DNA sequences. It provides the possibility of representing genomes by images, revealing in such a way different fractal structures. In this paper, we perform a fractal and multifractal analysis of Human chromosome 22 and some complete genomes based on the FGCR image. We used the fractal dimension (FD) and the multifractality degree (ΔDq) to characterize and distinguish genomes. First, we construct the FCGR image with different orders of human chromosome 22. Next, we calculate the fractal dimension, the general dimension spectrum and the multifractal spectrum of each FCGR image using the box-counting method. Then, we examine the FCGR image fractal and multifractal characteristics impact on highlighting the existence of repetitive DNA sequences in human chromosome 22. We also observe the relationship between fractality and multifractality. After that, we apply this study to bacteria completes genomes and C.elegans chromosome I. The obtained results show that the multifractal spectra of all organisms studied are multifractal-like and chromosome 22 strong multifractality proves its richness of repetitive sequences. Also, we observed that with the increasing the FCGR order value, the multifractality grows and the fractal dimension lessens. Finally, by assigning to each sequence a point in two-dimensional space (FD, ΔDq), we obtained three classes of genomes. We can easily distinguish the human chromosome 22 from other genomes and Bacteria are almost close in the spaces (FD, ΔDq).