iPSC-derived retinal pigmented epithelial cells from patients with macular telangiectasia show decreased mitochondrial function.

Patient-derived induced pluripotent stem cells (iPSCs) provide a powerful tool for identifying cellular and molecular mechanisms of disease. Macular telangiectasia type 2 (MacTel) is a rare, late-onset degenerative retinal disease with an extremely heterogeneous genetic architecture, lending itself to the use of iPSCs. Whole-exome sequencing screens and pedigree analyses have identified rare causative mutations that account for less than 5% of cases. Metabolomic surveys of patient populations and GWAS have linked MacTel to decreased circulating levels of serine and elevated levels of neurotoxic 1-deoxysphingolipids (1-dSLs). However, retina-specific, disease-contributing factors have yet to be identified. Here, we used iPSC-differentiated retinal pigmented epithelial (iRPE) cells derived from donors with or without MacTel to screen for novel cell-intrinsic pathological mechanisms. We show that MacTel iRPE cells mimicked the low serine levels observed in serum from patients with MacTel. Through RNA-Seq and gene set enrichment pathway analysis, we determined that MacTel iRPE cells are enriched in cellular stress pathways and dysregulation of central carbon metabolism. Using respirometry and mitochondrial stress testing, we functionally validated that MacTel iRPE cells had a reduction in mitochondrial function that was independent of defects in serine biosynthesis and 1-dSL accumulation. Thus, we identified phenotypes that may constitute alternative disease mechanisms beyond the known serine/sphingolipid pathway.

IsomiR-eQTL: A Cancer-Specific Expression Quantitative Trait Loci Database of miRNAs and Their Isoforms.

The identification of expression quantitative trait loci (eQTL) is an important component in efforts to understand how genetic variants influence disease risk. MicroRNAs (miRNAs) are short noncoding RNA molecules capable of regulating the expression of several genes simultaneously. Recently, several novel isomers of miRNAs (isomiRs) that differ slightly in length and sequence composition compared to their canonical miRNAs have been reported. Here we present isomiR-eQTL, a user-friendly database designed to help researchers find single nucleotide polymorphisms (SNPs) that can impact miRNA (miR-eQTL) and isomiR expression (isomiR-eQTL) in 30 cancer types. The isomiR-eQTL includes a total of 152,671 miR-eQTLs and 2,390,805 isomiR-eQTLs at a false discovery rate (FDR) of 0.05. It also includes 65,733 miR-eQTLs overlapping known cancer-associated loci identified through genome-wide association studies (GWAS). To the best of our knowledge, this is the first study investigating the impact of SNPs on isomiR expression at the genome-wide level. This database may pave the way for researchers toward finding a model for personalised medicine in which miRNAs, isomiRs, and genotypes are utilised.

Genetics of reticular pseudodrusen in age-related macular degeneration.

Reticular pseudodrusen (RPD) are subretinal deposits that, when observed with age-related macular degeneration (AMD), form a distinct phenotype, often associated with late-stage disease. To date, RPD genetic risk associations overlap six well-established AMD-risk regions. Determining RPD-specific underlying genetic causes by using adequate imaging methods should improve our understanding of the pathophysiology of RPD.

Severe COVID-19 May Impact Hepatic Fibrosis /Hepatic Stellate Cells Activation as Indicated by a Pathway and Population Genetic Study.

Coronavirus disease 19 (COVID-19) has affected over 112 million people and killed more than 2.5 million worldwide. When the pandemic was declared, Spain and Italy accounted for 29% of the total COVID-19 related deaths in Europe, while most infected patients did not present severe illness. We hypothesised that shared genomic characteristics, distinct from the rest of Europe, could be a contributor factor to a poor prognosis in these two populations. To identify pathways related to COVID-19 severity, we shortlisted 437 candidate genes associated with host viral intake and immune evasion from SARS-like viruses. From these, 21 were associated specifically with clinically aggressive COVID-19. To determine the potential mechanism of viral infections, we performed signalling pathway analysis with either the full list (n = 437) or the subset group (n = 21) of genes. Four pathways were significantly associated with the full gene list (Caveolar-mediated Endocytosis and the MSP-RON Signalling) or with the aggressive gene list (Hepatic Fibrosis/Hepatic Stellate Cell (HSC) Activation and the Communication between Innate and Adaptive Immune Cells). Single nucleotide polymorphisms (SNPs) from the ±1 Mb window of all genes related to these four pathways were retrieved from the dbSNP database. We then performed Principal Component analysis for these SNPs in individuals from the 1000 Genomes of European ancestry. Only the Hepatic Fibrosis/HSC Activation pathway showed population-specific segregation. The Spanish and Italian populations clustered together and away from the rest of the European ancestries, with the first segregating further from the rest. Additional in silico analysis identified potential genetic markers and clinically actionable therapeutic targets in this pathway, that may explain the severe disease.

Identification of genetic factors influencing metabolic dysregulation and retinal support for MacTel, a retinal disorder.

Macular Telangiectasia Type 2 (MacTel) is a rare degenerative retinal disease with complex genetic architecture. We performed a genome-wide association study on 1,067 MacTel patients and 3,799 controls, which identified eight novel genome-wide significant loci (p < 5 × 10-8), and confirmed all three previously reported loci. Using MAGMA, eQTL and transcriptome-wide association analysis, we prioritised 48 genes implicated in serine-glycine biosynthesis, metabolite transport, and retinal vasculature and thickness. Mendelian randomization indicated a likely causative role of serine (FDR = 3.9 × 10-47) and glycine depletion (FDR = 0.006) as well as alanine abundance (FDR = 0.009). Polygenic risk scoring achieved an accuracy of 0.74 and was associated in UKBiobank with retinal damage (p = 0.009). This represents the largest genetic study on MacTel to date and further highlights genetically-induced systemic and tissue-specific metabolic dysregulation in MacTel patients, which impinges on retinal health.

Promoter Methylation of Tumor Suppressors in Thyroid Carcinoma: A Systematic Review.

Background: The tumor suppressor genes play a critical role in cellular and molecular mechanisms such as cell cycle processes, cell differentiation and apoptosis. Aberrant DNA methylation of tumor suppressor genes and subsequent gene expression changes have shown to be involved in the initiation and progression of various malignancies including thyroid malignancies. In this review, we investigated what is known about the impact of promoter hypermethylation on the key tumor suppressor genes known to be involved in cell growth and/or apoptosis of thyroid cancer. Methods: The most important databases were searched for research articles until June 2020 to identify reported tumor suppressor genes that are modulated by methylation modulation changes in thyroid carcinoma. Following the inclusion and exclusion criteria, 26 studies were reviewed using the full text to meet the inclusion and exclusion criteria. Results: The tumor suppressor genes reviewed here are suggestive biomarkers and potential targetable drugs. Inactivation of RASSF1A, DAPK1, SLCFA8, and TSHR through aberrant epigenetic methylation could activate BRAF/MEK/ERK kinase pathways with potential clinical implications in thyroid cancer patients. RARß2 and RUNX3 could suppress cell cycle and induce apoptosis in malignant cells. TIMP3 and PTEN could prevent angiogenesis and invasion through PIP3 pathway and arrest VEFG activity. Conclusion: The methylation status of key genes in various types of thyroid malignancies could be used in early diagnosis as well as differentiation of malignant and benign thyroid. This is valuable in drug repurposing and discovering alternative treatments or preventions in thyroid cancer.

Pathway Analysis of Genes Identified through Post-GWAS to Underpin Prostate Cancer Aetiology.

Understanding the functional role of risk regions identified by genome-wide association studies (GWAS) has made considerable recent progress and is referred to as the post-GWAS era. Annotation of functional variants to the genes, including cis or trans and understanding their biological pathway/gene network enrichments, is expected to give rich dividends by elucidating the mechanisms underlying prostate cancer. To this aim, we compiled and analysed currently available post-GWAS data that is validated through further studies in prostate cancer, to investigate molecular biological pathways enriched for assigned functional genes. In total, about 100 canonical pathways were significantly, at false discovery rate (FDR)< 0.05), enriched in assigned genes using different algorithms. The results have highlighted some well-known cancer signalling pathways, antigen presentation processes and enrichment in cell growth and development gene networks, suggesting risk loci may exert their functional effect on prostate cancer by acting through multiple gene sets and pathways. Additional upstream analysis of the involved genes identified critical transcription factors such as HDAC1 and STAT5A. We also investigated the common genes between post-GWAS and three well-annotated gene expression datasets to endeavour to uncover the main genes involved in prostate cancer development/progression. Post-GWAS generated knowledge of gene networks and pathways, although continuously evolving, if analysed further and targeted appropriately, will have an important impact on clinical management of the disease.

Post-GWAS in prostate cancer: from genetic association to biological contribution.

Genome-wide association studies (GWAS) have been successful in deciphering the genetic component of predisposition to many human complex diseases including prostate cancer. Germline variants identified by GWAS progressively unravelled the substantial knowledge gap concerning prostate cancer heritability. With the beginning of the post-GWAS era, more and more studies reveal that, in addition to their value as risk markers, germline variants can exert active roles in prostate oncogenesis. Consequently, current research efforts focus on exploring the biological mechanisms underlying specific susceptibility loci known as causal variants by applying novel and precise analytical methods to available GWAS data. Results obtained from these post-GWAS analyses have highlighted the potential of exploiting prostate cancer risk-associated germline variants to identify new gene networks and signalling pathways involved in prostate tumorigenesis. In this Review, we describe the molecular basis of several important prostate cancer-causal variants with an emphasis on using post-GWAS analysis to gain insight into cancer aetiology. In addition to discussing the current status of post-GWAS studies, we also summarize the main molecular mechanisms of potential causal variants at prostate cancer risk loci and explore the major challenges in moving from association to functional studies and their implication in clinical translation.

Frequency of α-Globin Gene Triplications and Coinheritance with ß-Globin Gene Mutations in the Iranian Population.

Numerical variation in α-globin genes is very important due to their roles as an effective factor for phenotype presentation. An unequal crossover from misalignment of a homologous sequence of an α-globin gene during meiosis can produce a numerical alteration. A single α-globin gene deletion is the most frequent mutation in α-thalassemia (α-thal) worldwide, while the additional α-globin chain is relatively common. The excess α-globin gene plays a critical role in pathophysiology of thalassemia, especially when in coinherited with ß-thalassemia (ß-thal). α-Globin triplication leads to an imbalanced ratio between α- and ß-globin chains, thus, it can exacerbate the clinical and hematological features of ß-thal. Different studies have been performed in various countries to determine the frequency of α-globin triplication and its genotype-phenotype correlation with ß-thal. In this study, we focused on the frequency of α-globin gene triplication and its characterization, either solely or in coexistence with ß-globin gene mutations in Iranian populations. We have investigated the α-globin gene rearrangements in 4010 individuals from different provinces of Iran with normal to abnormal hematological parameters. In total, the frequency of the αααanti 3.7 triplication was 1.7% and phenotype aggravation was observed in α-globin triplication patients who were carriers of ß-thal. Therefore, identification of genotype-phenotype correlation of α-globin triplication with ß-thal can be very useful for predicting the severity of clinical manifestations during genetic counseling.

Molecular basis of α-thalassemia.

α-Thalassemia is an inherited, autosomal recessive, disorder characterized by a microcytic hypochromic anemia. It is one of the most common monogenic gene disorders in the world population. The clinical severity varies from almost asymptomatic, to mild microcytic hypochromic, and to a lethal hemolytic condition, called Hb Bart's Hydrops Foetalis Syndrome. The molecular basis are usually deletions and less frequently, point mutations affecting the expression of one or more of the duplicated α-genes. The clinical variation and increase in disease severity is directly related to the decreased expression of one, two, three or four copies of the α-globin genes. Deletions and point mutations in the α-globin genes and their regulatory elements have been studied extensively in carriers and patients and these studies have given insight into the α-globin genes are regulated. By looking at naturally occurring deletions and point mutations, our knowledge of globin-gene regulation and expression will continue to increase and will lead to new targets of therapy.

First Report of a Dominantly Inherited ß-Thalassemia Caused by a Novel Elongated ß-Globin Chain.

A distinct set of mutations on the ß-globin gene leads to dominantly inherited ß-thalassemia (ß-thal) that is associated with a disease phenotype in a single mutant copy. We described molecular and hematological characteristics of a novel elongated ß-globin chain in combination with a known hemoglobin (Hb) variant (N-Baltimore or HBB: c.286A>G) in cis. The highly unstable Hb variant caused typical features of ß-thal major (ß-TM) or ß-thal intermedia (ß-TI) in two members of a family depending on their α-globin genotypes. The ß mutant allele of the mother was transmitted in an autosomal dominant fashion to her daughter. They resemble severe forms of ß-thal due to ineffective erythropoiesis. Taken together with previously published data, this result indicates that a dominant form of ß-thal should be regarded as a phenotypic term of hemoglobinopathies caused by ß chain variants that are highly unstable.

Point mutations which should not be overlooked in Hb H disease.

BACKGROUND: Hb H disease is an alpha-thalassemia (α-thal) syndrome characterized by chronic hemolytic anemia that occurs when three of total four α-globin genes lost their function due to completely deletions or different kind of mutations. OBJECTIVE: We here described 66 patients who have been diagnosed for Hb H disease during the last five years in our center. The genotypes involving point mutations present more severe phenotype than deletional forms that make them of primary important to health management. STUDY DESIGN: Hb H subjects carry different α-globin genotypes including deletional and non-deletional mutations showing heterogenous clinical manifestations. RESULTS: The Hb H patients presenting a wide range of phenotype carried different deletional, non-deletional mutations or compound heterozygosity of them. CONCLUSION: We emphasize the importance of some point mutations responsible for more severe form of Hb H disease in Iranian population and the necessity for consideration of prenatal diagnosis (PND) in high-risk couples.

Characterization of Homozygous Hb Setif (HBA2: c.283G>T) in the Iranian Population.

Hemoglobin (Hb) variants are abnormalities resulting from point mutations in either of the two α-globin genes (HBA2 or HBA1) or the ß-globin gene (HBB). Various reports of Hb variants have been described in Iran and other countries around the world. Hb Setif (or HBA2: c.283G>T) is one of these variants with a mutation at codon 94 of of the α2-globin gene that is characterized in clinically normal heterozygous individuals. We here report clinical and hematological findings in two homozygous cases of Iranian origin for this unstable Hb variant.

Identification of Mutations Causing Aberrant Termination and Deficient Splice Donor Site on the HBA1 Gene.

α-Thalassemia (α-thal) is a common genetic disorder in Iran and many parts of the world. Genetic defects on the α-globin gene cluster can result in α-thal that may develop a clinical phenotype varying from almost asymptomatic to a lethal hemolytic anemia. In the present study, four Iranian individuals with hypochromic microcytic anemia, who revealed none of the known mutations responsible for α-thal, were subjected for further investigations. The thalassemic phenotype of these patients resulted from abnormal RNA splicing sites owing to a missense at the splice donor site, a truncated protein or hemoglobin (Hb) variants as a result of two different substitutions on the α1-globin gene. The clinical presentation of mild anemia in these individuals showed the contribution of these novel mutations in α-thal in spite of the dominantly expressed α2-globin gene. This study describes hematological manifestations of subjects carrying some novel mutations comparable to the reported phenotype of α(+)-thal trait.

Diagnostic pitfalls of less well recognized HbH disease.

HbH disease had been introduced as a mild anemia disease. It recently has become the most challenging hemoglobinopathy due to the increasingly described genotype patterns and very variable phenotypic presentations in different ethnics. Phenotypic severity of HbH syndrome is not simply related to the degree of α-globin deficiency and being influenced by several environmental and/or genetic factors. Hence, more investigation needs to identify factors like other genetic loci linked and/or unlinked to the α-globin genes affecting molecular mechanisms that influence clinical expression of HbH disease. Altogether, the complicated pathophysiology of HbH disease makes it to be known as a poorly understood syndrome. It may offer the hypothesis that it is a multifactorial disease, which needs to be investigated by more comprehensive genetic approach like genome wide association studies (GWAS) looking for genetic variants. Moreover, extended haplotype analysis to find out probable specific association between haplotypes of modifier genes and disease severity in patients with a specific HbH genotype may be a key point. In this review, we aim to provide important information regarding phenotypic presentation of different genotypes that have been described worldwide. It may help geneticists regarding challenging health care aspects of HbH disease in a specific ethnic.

Copy number variations of six and seven α-globin genes in a family with intermedia and major thalassemia phenotypes.

BACKGROUND: Copy number variations in α-globin genes are results of unequal crossover between homologous segments in the α-globin gene cluster that misalign during the meiosis phase of the gametogenesis process. Reduction or augmentation of α-globin genes leads to imbalance of α/ß chains in hemoglobin tetramer and consequently attenuate or worsen the ß-thal clinical symptoms, respectively. OBJECTIVE: Multiplications in α-globin genes have been found in some populations, justifying unexpected severe phenotype of ß-thal carriers. STUDY DESIGN: Unexpected severe phenotype in the family members may result from coexistence of extra α-globin genes, which is an important factor in the causation of thalassemia intermedia and major in heterozygous ß-thalassemia. RESULTS: We described different multiplications in α-globin locus in an Iranian family with one, two or three extra α-globin genes (ααα/αα, αααα/αα and αααα/ααα). CONCLUSION: The excess α-globin gene/genes cause increment in ß/α chain imbalance and leads to worsening pathophysiology and clinical severity of ß-thalassemia carriers.

Mutations on the α2-Globin Gene That May Trigger α(+)-Thalassemia.

In the present study, a total of 11 individuals with hypochromic microcytic anemia who did not reveal the most common α-thalassemia (α-thal) deletions or mutations, were subjected to more investigations by DNA sequencing of the α-globin genes. Seven novel nondeletional α-thal mutations localized on the α2-globin gene in the heterozygous state were identified. These mutations either corrupted regulatory splice sites and consequently affected RNA processing or created unstable hemoglobin (Hb) variants. The mutations described here produced globin gene variants that lead to amino acid changes in critical regions of the globin chain. The clinical presentation of most patients was a persistent mild microcytic anemia similar to an α(+)-thal. In the last decade, numerous α-globin mutations have been observed leading to an α-thal phenotype and these studies have been considered to be important as discussed here.

Homozygosity for the AATAAA > AATA- - Polyadenylation Site Mutation on the α2-Globin Gene Causing Transfusion-Dependent Hb H Disease in an Iranian Patient: A Case Report.

We describe a case of Hb H disease associated with homozygosity for a two nucleotide deletion in the polyadenylation signal of the α2-globin gene (HBA2: c.*93_*94delAA). The patient, a 27-year-old son of a consanguineous couple, needs regular blood transfusions every 6 months.

Interaction of an α-Globin Gene Triplication with ß-Globin Gene Mutations in Iranian Patients with ß-Thalassemia Intermedia.

The 3.7 kb triplicated α-globin gene (ααα(anti 3.7)) mutation has been found in most populations. It results from an unequal crossover between misaligned homologous segments in the α-globin gene cluster during meiosis. The pathophysiology and clinical severity of ß-thalassemia (ß-thal) are associated with the degree of α chain imbalance. The excess of α-globin chains plays an important role in the pathophysiology of ß-thal. When heterozygous/homozygous ß-thal coexists with an α gene numerical alteration, the clinical and hematological phenotype of thalassemia could change to mild anemia in case of an α deletion (-α/αα) or severe anemia in the case of an α triplication (αα/ααα). The coexistence of an ααα(anti 3.7) triplication is considered an important factor in the severity of ß-thal, exacerbating the phenotypic severity of ß-thal by causing more globin chain imbalance. This study shows that the ααα(anti 3.7) triplication is an important factor in the causation of ß-thal intermedia (ß-TI) in heterozygous ß-thal. This type of phenotype modification has rarely been observed and reported in the Iranian population. Here we report the coinheritance of a triplicated α-globin gene arrangement and heterozygous/homozygous ß-thal in 23 cases, presenting with a ß-TI or ß-thal major (ß-TM) phenotype. Some of these patients were considered to have a mild ß-TI phenotype as they needed no blood transfusions; some occasionally received blood transfusions in their lifetime (for example on delivery) but some are dependent on regular blood transfusions (every 20 to 40 days). Our study was focused on the importance of detecting the α-globin gene triplication in genotype/phenotype prediction in Iranian thalassemia patients.