Structure and expression of the human ubiquitin fusion-degradation gene (UFD1L)

Genetic Screening of Targeted Region on the Chromosome 22q11.2 in Patients with Microtia and Congenital Heart Defect

Microtia is a congenital malformation characterized by a small, abnormally shaped auricle (pinna) ranging in severity. Congenital heart defect (CHD) is one of the comorbid anomalies with microtia. However, the genetic basis of the co-existence of microtia and CHD remains unclear. Copy number variations (CNVs) of 22q11.2 contribute significantly to microtia and CHD, respectively, thus suggesting a possible shared genetic cause embedded in this genomic region. In this study, 19 sporadic patients with microtia and CHD, as well as a nuclear family, were enrolled for genetic screening of single nucleotide variations (SNVs) and CNVs in 22q11.2 by target capture sequencing. We detected a total of 105 potential deleterious variations, which were enriched in ear- or heart-development-related genes, including TBX1 and DGCR8. The gene burden analysis also suggested that these genes carry more deleterious mutations in the patients, as well as several other genes associated with cardiac development, such as CLTCL1. Additionally, a microduplication harboring SUSD2 was validated in an independent cohort. This study provides new insights into the underlying mechanisms for the comorbidity of microtia and CHD focusing on chromosome 22q11.2, and suggests that a combination of genetic variations, including SNVs and CNVs, may play a crucial role instead of single gene mutation.

Accessing Gene Expression in Treatment-Resistant Schizophrenia

Schizophrenia (SCZ) is a mental disorder arising from a complex interaction of genetic and environmental factors. It has been suggested that treatment-resistant schizophrenia (TRS) is a distinct, more severe, and homogenous subgroup of schizophrenia that could present specific biological markers. Our aim was to characterize expression of target genes in blood of TRS patients compared with non-TRS (NTRS) patients and healthy controls (HC). TRS has been defined using failure to respond to two previous antipsychotic trials. We hypothesized that genes involved in neurodevelopment, myelination, neuroplasticity, neurotransmission, and miRNA processing could be involved in treatment resistance; then, we investigated 13 genes related to those processes in 256 subjects, being 94 healthy controls and 162 schizophrenia patients treated with antipsychotics. Of those, 78 were TRS patients and 84 were NTRS patients. Peripheral blood samples were collected from all subjects and RNA was isolated. Gene expression analysis was performed using the TaqMan low-density array (TLDA) technology. To verify the influence of expression quantitative trait loci (eQTLs), we evaluated single-nucleotide polymorphism (SNP) of all genes using data from GTEx Project. SNP genotypes were obtained from HumanOmniExpress BeadChip. We did not detect gene expression differences between TRS and NTRS subjects, indicating candidate genes specific to treatment resistance. We detected an upregulation of CNR1 and UFD1L gene expression in patients (TRS and NTRS groups) when compared to controls, that may be associated with the release of neurotransmitters, which can influence neuronal plasticity, or with a stress response-activating protein degradation. DICER1 and AKT1 expression increased slightly across the groups and could differentiate only the extreme opposite groups, HC and TRS. Both genes act in heterogeneous pathways, such as cell signaling and miRNA processing, and seem to have an increased demand in the TRS group. We did not detect any eQTLs in our sample that could explain differences in mRNA levels, suggesting a possible regulation by other mechanism, not driven by genotypes. Our data strengthen the importance of several biological pathways involved in the schizophrenia refractoriness and severity, adding knowledge to develop more effective treatments in the future.

Gene expression analysis in blood of ultra-high risk subjects compared to first-episode of psychosis patients and controls

OBJECTIVES

This study aimed to investigate peripheral blood gene expression in ultra-high-risk subjects (UHR) compared to first-episode psychosis individuals (FEP) and healthy controls (HC).

METHODS

We enrolled 22 UHR, 66 FEP and 67 HC and investigated the expression of 12 genes using Taqman assays. We used the Univariate General Linear Model, as well as Bonferroni correction for multiple comparisons.

RESULTS

We found that UFD1L (ubiquitin fusion degradation 1 like (yeast)) gene was upregulated in UHR group compared to HC and FEP (P = 3.44 × 10^-6 ; P = 9.41 × 10^-6). MBP (myelin basic protein) was downregulated in UHR compared to FEP (P = 6.07 × 10^-6). DISC1 (disrupted in schizophrenia 1) was also upregulated in UHR compared to FEP but lost statistical significance when corrected for age.

CONCLUSIONS

These genes are directly related to neurodevelopmental processes and have been associated to schizophrenia. Recent findings described that DISC1 overexpression can disrupt MBP expression, thus, we think that these alterations in UHR individuals could be associated with a common process. UFD1L showed a different pattern of expression only for UHR group, suggesting that they can be under an acute endoplasmatic reticulum stress, demanding elevated levels of Ufd1. Further studies can improve knowledge on disease progression and putative targets to preventive strategies.

Polymorphisms in schizophrenia candidate gene UFD1L may contribute to cognitive deficits

We aimed to investigate UFD1L polymorphisms in schizophrenia and in relation to cognition. A total of 299 cases and 363 controls were genotyped, and 130 patients completed nine neuropsychological tests. We found that rs5992403 AA-genotype carriers showed lower scores on the set-shifting task. Therefore, UFD1L may participate in the core cognitive deficits observed in schizophrenia.

A family- and population-based study of the UFD1L gene for schizophrenia

The present work was undertaken to investigate the association of the UFD1L locus with schizophrenia among 304 Chinese family trios of Han descent. We detected four single nucleotide polymorphisms (SNPs) in the 5'-end region of the UFD1L gene. The transmission disequilibrium test (TDT) revealed allelic associations for rs5746744 (chi(2) = 8.02, P = 0.005) and rs1547931 (chi(2) = 7.18, P = 0.007), but failed to replicate disease association for rs5992403 present in the promoter region, which was initially found in Italian and Canadian samples. The allelic association for rs5746744 and rs1547931 was replicated with independently recruited case-control samples. The 2-SNP haplotype analysis showed an association for the rs5992403-rs5746744 haplotypes (chi(2) = 18.92, df = 3, P = 0.0003), the rs5746744-rs1547931 haplotypes (chi(2) = 11.06, df = 3, P = 0.011) and the rs1547931-rs2238769 haplotypes (chi(2) = 18.88, df = 3, P = 0.0003). The 4-SNP haplotype analysis also showed strong association with illness (chi(2) = 29.54, df = 9, P = 0.0005) but there were more than one individual haplotypes with a low frequency excessively non-transmitted. The four SNPs tested were not located in the same LD block among the Chinese population. This study raises the possibility that a disease-resistant variant may be carried by two or more haplotypes at the UFD1L locus due to frequent recombination during meiosis.

Global changes in STAT target selection and transcription regulation upon interferon treatments

The STAT (signal transducer and activator of transcription) proteins play a crucial role in the regulation of gene expression, but their targets and the manner in which they select them remain largely unknown. Using chromatin immunoprecipitation and DNA microarray analysis (ChIP-chip), we have identified the regions of human chromosome 22 bound by STAT1 and STAT2 in interferon-treated cells. Analysis of the genomic loci proximal to these binding sites introduced new candidate STAT1 and STAT2 target genes, several of which are affiliated with proliferation and apoptosis. The genes on chromosome 22 that exhibited interferon-induced up- or down-regulated expression were determined and correlated with the STAT-binding site information, revealing the potential regulatory effects of STAT1 and STAT2 on their target genes. Importantly, the comparison of STAT1-binding sites upon interferon (IFN)-gamma and IFN-alpha treatments revealed dramatic changes in binding locations between the two treatments. The IFN-alpha induction revealed nonconserved STAT1 occupancy at IFN-gamma-induced sites, as well as novel sites of STAT1 binding not evident in IFN-gamma-treated cells. Many of these correlated with binding by STAT2, but others were STAT2 independent, suggesting that multiple mechanisms direct STAT1 binding to its targets under different activation conditions. Overall, our results reveal a wealth of new information regarding IFN/STAT-binding targets and also fundamental insights into mechanisms of regulation of gene expression in different cell states.

Mechanisms of delivery of ubiquitylated proteins to the proteasome: new target for anti-cancer therapy?

The proteasome is the main proteolytic machinery of the cell. It is responsible for the basal turnover of many intracellular polypeptides, the elimination of abnormal proteins and the generation of the vast majority of peptides presented by class I major histocompatibility complex molecules. Proteasomal proteolysis is also involved in the control of virtually all cellular functions and major decisions through the spatially and timely regulated destruction of essential cell regulators. Therefore, the elucidation of its molecular mechanisms is crucial for the full understanding of the physiology of cells and whole organisms. Conversely, it is increasingly clear that proteasomal degradation is either altered in numerous pathological situations, including many cancers and diseases resulting from aberrant cell differentiation, or instrumental for the development of these pathologies. This, consequently, makes it an attractive target for therapeutical intervention. There is ample evidence that most cell proteins must be polyubiquitylated prior to proteasomal degradation. If the structure and the mode of functioning of the proteasome, as well as the enzymology of ubiquitylation, are relatively well understood, how substrates are delivered to and recognized by the proteolytic machine has remained mysterious till recently. The recent literature indicates that the mechanisms involved are multiple, complex and exquisitely regulated and provides new potential targets for anti-cancer pharmacological intervention.

Functional characterization of the 5' flanking region of human ubiquitin fusion degradation 1 like gene (UFD1L)

UFD1L (Ubiquitin Fusion Degradation 1 Like) gene encodes for a component of a multi-complex involved in the degradation of ubiquitin fusion proteins. The gene maps on chromosome 22q11, in a region commonly deleted in severe congenital disorders such as DiGeorge (DGS) and velo-cardio-facial (VCFS) syndromes. UFD1L is a single copy gene ubiquitously expressed in high levels in the pharyngeal pouches and fourth branchial arch artery during development. To understand the regulation of UFD1L expression we performed a functional analysis of its 5' regulatory region. 5'-RACE and primer extension analyses revealed the presence of different transcription start sites in adult and fetal tissues. UFD1L 5' flanking region contains a TATA-box motif and is also very GC-rich with a CpG island encompassing exon 1. Transcriptional activity of this region was examined by transfection experiments of promoter-GFP reporter gene constructs in a human epithelial cell line. These experiments revealed the importance of the region between -17 and -463 nt which contains the TATA-box. EMSA assay resulted in the detection of five functional consensus sequences respectively for the transcription complex TFIID and for the transcription factors AP-1 (one site), AP-2 (one) and Sp1 (two).

Association study of a promoter polymorphism of UFD1L gene with schizophrenia

Schizophrenia or schizoaffective disorders are often found in patients affected by DiGeorge/velo-cardio-facial syndrome (DGS/VCFS) as a result of hemizygosity of chromosome 22q11.2. We evaluated the UFD1L gene, mapping within the DGS/VCFS region, as a potential candidate for schizophrenia susceptibility. UFD1L encodes for the ubiquitin fusion degradation 1 protein, which is expressed in the medial telencephalon during mouse development. Using case control, simplex families (trios), and functional studies, we provided evidence for association between schizophrenia and a single nucleotide functional polymorphism, -277A/G, located within the noncoding region upstream the first exon of the UFD1L gene. The results are supportive of UFD1L involvement in the neurodevelopmental origin of schizophrenia and contribute in delineating etiological and pathogenetic mechanism of the schizophrenia subtype related to 22q11.2 deletion syndrome.

Characterization of the bi-directional transcriptional control region between the human UFD1L and CDC45L genes

The human UFD1L and CDC45L genes, adjacently located in the head-to-head direction on chromosome 22q11, are separated by a 884 base-pair (bp) segment constituting the putative transcriptional control region. In this region we mapped one transcription start site at 69 bp upstream of UFD1L gene, and one major and one minor start sites at 76 bp and 503 bp upstream of CDC45L gene, which are to center in the putative core promoters designated as P(UFD1L), P(CDC45L/major), and P(CDC45L/minor), respectively. The three core promoters lacked a TATA-motif and had a high GC-content. To determine the approximate ranges for the regulatory promoters, the 884-bp fragment or those with a series of deletions were placed between firefly and renilla luciferase genes present in the head-to-head direction in a single plasmid, and the resulting plasmids were assayed for the two transiently induced enzyme activities. The P(UFD1L) and P(CDC45L/major) regulatory promoters were within 418 and 454 bp upstream of the respective start sites and their greater parts were not overlapping. The activity of P(CDC45L/minor) regulatory promoter was markedly enhanced when P(CDC45L/major) and its regulatory promoter were deleted. The deletion analyses revealed the basal activities of the three core promoters, which were enhanced by approximately twofold by the respective regulatory promoters, on the transfected DNA templates.

Rapid detection of the 22q11.2 deletion with quantitative real-time PCR

We report the detection of 22q11.2 deletions using TaqMan(TM)PCR-based gene dosage analysis of patients previously diagnosed by fluorescent in situ hybridization (FISH). We performed quantitative PCR of the UFD1L gene from this region and showed a 99.7% statistical correlation between the two methods. The advantages of this method over FISH include: (i) rapidity; (ii) ease; (iii) relatively low cost and; (iv) the small quantities of DNA needed.

The 22q11.2 deletion: from diversity to a single gene theory

The 22q11 deletion syndromes are a group of conditions in which a characteristic spectrum of congenital cardiac defects may be associated with a wide range of noncardiological congenital anomalies. These syndromes are all linked by a deletion in the long arm of chromosome 22. Although it is a large deletion, containing many genes, recent advances have led to the belief that the etiology of the diverse abnormalities of these syndromes may be a single gene deletion. This review outlines the historical development of the various "22q deletion syndromes," including the DiGeorge, velocardiofacial, Takao, Cayler, and CATCH-22 syndromes, briefly describes the relevant cardiac embryogenesis, and then explains how a single gene deletion may encompass the full phenotypic spectrum.

T cell receptor repertoire and function in patients with DiGeorge syndrome and velocardiofacial syndrome

DiGeorge syndrome (DGS) and velocardiofacial syndrome (VCFS) are associated with chromosome 22q11.2 deletion. Limited information is available on the T cell receptor (TCR) Vbeta repertoire. We therefore investigated TCR Vbeta families in lymphocytes isolated from blood and thymic samples of seven patients with DGS and seven patients with VCFS, all with 22q11.2 deletion. We also studied activities related to TCR signalling including in vitro proliferation, anti-CD3-induced protein tyrosine phosphorylation, and susceptibility to apoptosis. Reduced CD3+ T cells were observed in most patients. Spontaneous improvement of T cell numbers was detected in patients, 3 years after the first study. Analysis of CD4+ and CD8+ TCR Vbeta repertoire in peripheral and thymic cells showed a normal distribution of populations even if occasional deletions were observed. Lymphoproliferative responses to mitogens were comparable to controls as well as anti-CD3-induced protein tyrosine phosphorylation. Increased anti-CD3-mediated apoptosis was observed in thymic cells. Our data support the idea that in patients surviving the correction of cardiac anomalies, the immune defect appears milder than originally thought, suggesting development of a normal repertoire of mature T cells.

UFD1L and CDC45L: a role in DiGeorge syndrome and related phenotypes?

Molecular genetics is contributing to the understanding of normal and abnormal cardiovascular development and morphogenesis. Deletions of chromosome 22q11.2 have been associated with distinct phenotypes that result from a failure to form derivatives of third and fourth branchial arches, including DiGeorge syndrome (DGS) and velo-cardio-facial syndrome (VCFS). The biochemical mechanisms underlying these phenotypes remain undetermined. A recent study provides new insight into the mechanism by which gene deletions produce the DGS and VCFS phenotypes.

A molecular pathway revealing a genetic basis for human cardiac and craniofacial defects

Microdeletions of chromosome 22q11 are the most common genetic defects associated with cardiac and craniofacial anomalies in humans. A screen for mouse genes dependent on dHAND, a transcription factor implicated in neural crest development, identified Ufd1, which maps to human 22q11 and encodes a protein involved in degradation of ubiquitinated proteins. Mouse Ufd1 was specifically expressed in most tissues affected in patients with 22q11 deletion syndrome. The human UFD1L gene was deleted in all 182 patients studied with 22q11 deletion, and a smaller deletion of approximately 20 kilobases that removed exons 1 to 3 of UFD1L was found in one individual with features typical of 22q11 deletion syndrome. These data suggest that UFD1L haploinsufficiency contributes to the congenital heart and craniofacial defects seen in 22q11 deletion.