Interstitial deletion 2q33.3-q34 in a boy with a phenotype resembling the Seckel syndrome

Krüppel-like factor 7 deficiency causes autistic-like behavior in mice via regulating Clock gene

BACKGROUND

Krüppel-like factor 7 (klf7), a transcription factor in the nervous system to regulate cell proliferation and differentiation, has been recently identified as a causal gene for autism spectrum disorder (ASD), but the mechanism behind remains unknown.

RESULT

To uncover this mechanism, in this study we characterized the involvement of klf7 in circadian rhythm by knocking down klf7 in N2A cells and examining the rhythmic expression of circadian genes, especially Clock gene. We constructed klf7^-/- mice and then investigated into klf7 regulation on the expression of rhythm genes in vivo as well as the use of melatonin to rescue the autism behavior. Our results illustrated that circadian rhythm was disrupted in klf7 knockdown cells and that klf7^-/- mice showed autism-like behavior. Also, we found that Clock gene was downregulated in the brain of these klf7^-/- mice and that the downstream rhythm genes of Clock were disturbed. Melatonin, as a circadian regulation drug, could regulate the expression level and amplitude of rhythm genes in klf7 knockout cells and further rescue the autistic behavior of klf7^-/- mice.

CONCLUSION

Klf7 deficiency causes ASD by disrupting circadian rhythm related genes to trigger rhythm oscillations. To treat ASD, maintaining circadian homeostasis is promising with the use of melatonin.

Krüppel-like Transcription Factor 7 Is a Causal Gene in Autism Development

Background: Autism spectrum disorder (ASD) is a complex neurodevelopmental disease. To date, more than 1000 genes have been shown to be associated with ASD, and only a few of these genes account for more than 1% of autism cases. Klf7 is an important transcription factor of cell proliferation and differentiation in the nervous system, but whether klf7 is involved in autism is unclear. Methods: We first performed ChIP-seq analysis of klf7 in N2A cells, then performed behavioral tests and RNA-seq in klf7^+/− mice, and finally restored mice with adeno-associated virus (AAV)-mediated overexpression of klf7 in klf7^+/− mice. Results: Klf7 targeted genes are enriched with ASD genes, and 631 ASD risk genes are also differentially expressed in klf7^+/− mice which exhibited the core symptoms of ASD. When klf7 levels were increased in the central nervous system (CNS) in klf7^+/− adult mice, deficits in social interaction, repetitive behavior and majority of dysregulated ASD genes were rescued in the adults, suggesting transcriptional regulation. Moreover, knockdown of klf7 in human brain organoids caused dysregulation of 517 ASD risk genes, 344 of which were shared with klf7^+/− mice, including some high-confidence ASD genes. Conclusions: Our findings highlight a klf7 regulation of ASD genes and provide new insights into the pathogenesis of ASD and promising targets for further research on mechanisms and treatments.

Autistic and Rett-like features associated with 2q33.3-q34 interstitial deletion

We describe the fourth reported case of a de novo 2q33.3-q34 interstitial deletion and review the literature in attempt to identify relevant candidate genes. A 15-month-old female patient presented for evaluation with poor eye contact and developmental delay. She had microcephaly and mild dysmorphic features, such as downslanting palpebral fissures, high forehead, small mouth, high palate, and general hypotonia. At 30 months of age, she was referred to the genetic clinic for an evaluation of persistent developmental delay, autistic traits, and Rett-like features, including bruxism and repetitive movement of the left hand. Chromosome analysis revealed 46,XX at the 550 band level. No abnormalities were found on analysis of MECP2 gene for Rett syndrome and a DNA methylation test for Prader-Willi syndrome. An array comparative genomic hybridization analysis revealed a de novo 2q33.3-q34 heterozygous deletion (206,048,173-211,980,867). The deletion was estimated to be 5.9 Mb in size and contained 34 known genes. Candidate genes were identified as NRP2, ADAM23, KLF7, CREB1, MAP2, UNC80, and LANCL1 for the 2q33.3-q34 interstitial deletion.

A fetus with de novo 2q33.2q35 deletion including MAP2 with brain anomalies, esophageal atresia, and laryngeal stenosis

Deletions of the long arm of chromosome 2 are rare. Few cases of interstitial deletions of the 2q33q35 region have been reported. Individuals with deletions in this region have growth retardation, psychomotor retardation, micrognathia, microcephaly, and apparently low-set ears. We describe a female fetus with a de novo deletion of 2q33.2 to q35 with delayed gyral formation with widespread neuronal heterotopia of the white matter, small cerebellum, esophageal atresia, laryngeal stenosis, micrognathia, and intrauterine growth retardation. With the use of karyotyping and high-resolution array comparative genomic hybridization the boundaries and gene content of the deletion were identified. Our aim was to determine whether a candidate gene for the brain phenotype was present in the deletion. By this means and based on literature we pinpointed the microtubule associated gene MAP2 as a candidate for the brain anomalies.

2q24–q31 Deletion: Report of a case and review of the literature

We report a patient with a de novo interstitial deletion of the long arm of chromosome 2 involving bands 2q24.3-q31.1. The patient shows postnatal growth retardation, microcephaly, ptosis, down-slanting palpebral fissures, long eyelashes and micrognathia. Halluces are long, broad and medially deviated, while the other toes are laterally deviated and remarkably short with hypoplastic phalanges. She also showed developmental delay, seizures, lack of eye contact, stereotypic and repetitive hand movements and sleep disturbances with breath holding. Prenatal and three independent postnatal karyotypes were normal. Array-CGH analysis allowed us to identify and characterize a "de novo" 2q interstitial deletion of about 10.4Mb, involving segment between cytogenetic bands 2q24.3 and 2q31.1. The deletion was confirmed by quantitative PCR. About 30 children with 2q interstitial deletion have been reported. The deletion described here is overlapping with 15 of these cases. We have attempted to compare the clinical features of our patient with 15 overlapping cases. The emerging phenotypes include low birth weight, postnatal growth retardation, mental retardation and developmental delay, microcephaly, and peculiar facial dysmorphisms. Peculiar long and broad halluces with an increased distance between the first and the second toe are ("sandal gap" sign) present in most of the described patients. The gene content analysis of the deleted region revealed the presence of some genes that may be indicated as good candidates in generating both neurological and dysmorphic phenotype in the patient. In particular, a cluster of SCNA genes is located within the deleted region and it is known that loss of function mutations in SCNA1 gene cause a severe form of epilepsy.

Seckel-like syndrome: a patient with precocious puberty associated with nonclassical congenital adrenal hyperplasia

Seckel syndrome is a rare, recessively inherited disorder of severe growth retardation with low birth weight and distinct craniofacial, orodental and skeletal anomalies. In addition to these characteristics, some cardiovascular, hematopoietic, endocrine and central nervous system abnormalities have also been described. We report a patient with Seckel-like syndrome who has precocious puberty associated with non-classical congenital adrenal hyperplasia (NCCAH). She was admitted to our clinic three times. She was diagnosed as having Seckel-like syndrome and premature thelarche at the age of 8.9 years. At 10.9 years old she was admitted to our clinic with pubic hair and cliteromegaly. Hormonal findings revealed NCCAH and hydrocortisone therapy was offered but the patient was non-compliant. At 13.6 years she had acanthosis nigricans as an additional clinical finding and her pubertal stage was 4. She had irregular menses. On hormonal evaluation she had euglycemic hyperinsulinism accompanying mild hypertriglyceridemia and functional ovarian hyperandrogenism. Premature pubarche, hyper-insulinism, dyslipidemia, and hyperandrogenism, and some combinations of these, can be associated with reduced fetal growth. This is the first report of hyperinsulinism, and probably NCCAH, in association with Seckel syndrome.

Interstitial deletion of chromosome 2q32-34 associated with multiple congenital anomalies and a urea cycle defect (CPS I deficiency)

A de novo deletion of the long arm of chromosome 2 at 2q31-33 was observed in the fetal amniocyte G-banded karyotype performed because of possible multiple malformations identified by ultrasound at 23 weeks gestation. Two days after the uneventful term delivery of a 2.45 kg male, the neonate experienced cardiopulmonary decompensation and biochemical changes compatible with carbamoyl phosphate synthetase I (CPS I) deficiency (elevated ammonia with a peak of 948 micromol/L, deficiency of citrulline, and no increase in orotic acid). The child died on day 3 of life. Physical anomalies confirmed at autopsy included double superior vena cava, ectopic adrenal tissue, and metatarsus adductus. The autopsy also revealed histologic evidence consistent with CPS deficiency, most notably microvesicular steatosis of the liver and Alzheimer's Type II changes with hypertrophic astrocytes in the basal ganglia. A postnatal lymphocyte karyotype confirmed the chromosome 2q31-33 deletion. Enzyme analysis on postmortem liver tissue confirmed the diagnosis of CPS deficiency. CPS I is reported to be mapped to 2q35 by NCBI (http://www.ncbi.nlm.nih.gov/mapview/) and 2q34 by ENSEMBL (http://www.ensembl.org/). The UCSC Human Genome Browser July 2003 assembly also places the gene at 2q34 (http://genome.UCSC.edu/). Fluorescence in situ hybridization (FISH) analysis with a BAC clone (RP11-349G4) of CPS I demonstrated that one copy of the gene was deleted in this infant. Using additional probes corresponding to the bands in the region of deletion, we identified the deleted region as 2q32-2q34. Our observations support the CPS I map position (ENSEMBL, UCSC) at 2q34. Additionally, potential conditions associated with deletions narrowly defined by standard cytogenetic techniques merit consideration in prenatal counseling. As demonstrated here, deletions may not only result in malformations and mental retardation but also increase the likelihood of revealing mutated genes located in the undeleted region of the homologous chromosome.

Distal deletion, del(2)(q33.3q33.3), in a patient with severe growth deficiency and minor anomalies

We report on an 18-month-old boy with a 2q33.3 deletion. The clinical findings observed in the propositus included minor anomalies of face and distal limbs, intrauterine and postnatal growth retardation, microcephaly and, so far, moderate developmental delay. Conventional GTG banded chromosome analysis indicated a small deletion in distal 2q. Subsequent analysis by fluorescent in situ hybridization (FISH) using different probes allowed us to narrow down the deletion to most or all of segment 2q33.3. This case shows the importance of the application of different YAC probes for a precise determination of breakpoints in small interstitial deletions.

Pierre Robin sequence and interstitial deletion 2q32.3-q33.2

Pierre Robin sequence (PRS) consists of the nonrandom association of micrognathia, cleft palate (CP), and glossoptosis. It also includes respiratory and feeding difficulties that appear to be neurogenic rather than mechanical in causation. Genetic determinants are thought to underlie this functional and morphological entity, based on the existence of Mendelian syndromes with PRS, and the rare observations of familial nonsyndromic PRS, in which some of the affected individuals have isolated CP. We report the association of PRS with deletion 2q32.3-q33.2 due to an unbalanced reciprocal translocation 46,XX, t(2;21), del 2(q32.3q33.2), and we refine the deletion interval with regard to YAC probes and polymorphic DNA markers. The deletion was shown to be flanked by D2S369 (telomeric) and D2S315 (centromeric), thus it maps to a recently determined chromosomal region known to be nonrandomly associated with CP. This observation supports the hypothesis for the genetic bases of nonsyndromic PRS, strengthens its possible genetic association with isolated CP, and provides a candidate PRS locus, in chromosomal region 2q32.3-q33.2.

Normal expression of the Fanconi anemia proteins FAA and FAC and sensitivity to mitomycin C in two patients with Seckel syndrome

Seckel syndrome is a rare autosomal recessive disorder. The classical presentation includes pre- and postnatal growth deficiency, mental retardation, and characteristic facial appearance. There have been several reports of associated hematological abnormalities and chromosomal breakage, findings suggestive of Fanconi anemia (FA). We tested for these findings in two Arabic patients with this syndrome. We compared the growth profile of lymphoblastoid cells from our patients and their parents with the FA group A cell line HSC72 in the presence and absence of mitomycin C (MMC). By Western analysis, we also determined the expression of FAA and FAC, two FA disease gene products that together account for approximately 80% of FA. Unlike HSC72 cells, cells from the patients were resistant to MMC, and both FAA and FAC proteins were expressed at similar levels in all cell lines. There is an increasing recognition of clinical variability and perhaps genetic heterogeneity in Seckel syndrome. Our results demonstrate that cross-link sensitivity comparable to FA is not a uniform finding in patients with Seckel syndrome.

Seckel-like syndrome in three siblings

Seckel syndrome has been described as the prototype of the primordial bird-headed type of dwarfism. Since Seckel originally defined the disorder, less than 60 cases have been reported. In addition to the characteristic craniofacial dysmorphism and skeletal defects, abnormalities have been described in the cardiovascular, hematopoietic, endocrine, and central nervous systems. This pleiotropy has implied genetic heterogeneity and prompted reviews of previously reported cases of Seckel syndrome. As a result, the characteristic diagnostic features of Seckel syndrome have been highly debated. Although deletions in chromosome 2q have been described, to date, no genetic defect has been defined. We report three cases of Seckel-like syndrome in siblings from nonconsanguinous Caucasian parents. In addition to the typical Seckel phenotypic features, all three cases were characterized by severe hydrocephalus. We review the literature and propose that there is a spectrum of Seckel conditions that share some common key features, but also demonstrate a wide range of phenotypic features.