A Functional Indel Polymorphism Within MIR155HG Is Associated With Sudden Cardiac Death Risk in a Chinese Population

Sudden cardiac death (SCD) is a devastating complication of multiple disease processes and has gradually became a major public health issue. miR-155 is one of the best characterized miRNAs and plays a critical role in several physiological and pathological process, including cardiovascular diseases. In this study, we systematically screened the whole region of miR-155 host gene (MIR155HG) and identified a 4-bp insertion/deletion variant (rs72014506) residing in the intron region of MIR155HG as the candidate polymorphism. The association of rs72014506 with SCD susceptibility was evaluated using 166 SCD cases and 830 healthy controls in a Chinese population. Logistic regression analysis suggested that the homozygote del/del genotype significantly decreased the risk of SCD [odds ratio (OR) = 0.29; 95% confidence interval (CI) = 0.12–0.74; Ptrend = 0.0004]. Further genotype–expression association study using human myocardium tissue samples suggested that the deletion allele was intimately linked to lower the expression of both MIR155HG and mature miR155. Luciferase activity assay also revealed that the deletion allele of rs72014506 inhibited gene transcriptional activity. Finally, we performed electrophoretic mobility shift assay and verified the preferential binding affinity of the deletion allele with POU2F1 (POU domain class 2 transcription factor 1). Collectively, we have successfully identified a SCD risk conferring polymorphism in the MIR155HG gene and a likely biological mechanism for the decreased risk of SCD associated with the deletion allele. This novel variant may thus serve as a potential genetic marker for SCD diagnosis and prevention in natural populations, if validated by further studies with a larger sample size.

Multi-enhancer transcriptional hubs confer phenotypic robustness

We previously showed in Drosophila melanogaster embryos that low-affinity Ultrabithorax (Ubx)-responsive shavenbaby (svb) enhancers drive expression using localized transcriptional environments and that active svb enhancers on different chromosomes tended to colocalize (Tsai et al., 2017). Here, we test the hypothesis that these multi-enhancer ‘hubs’ improve phenotypic resilience to stress by buffering against decreases in transcription factor concentrations and transcriptional output. Deleting a redundant enhancer from the svb locus led to reduced trichome numbers in embryos raised at elevated temperatures. Using high-resolution fluorescence microscopy, we observed lower Ubx concentration and transcriptional output in this deletion allele. Transcription sites of the full svb cis-regulatory region inserted into a different chromosome colocalized with the svb locus, increasing Ubx concentration, the transcriptional output of svb, and partially rescuing the phenotype. Thus, multiple enhancers could reinforce a local transcriptional hub to buffer against environmental stresses and genetic perturbations, providing a mechanism for phenotypical robustness.

ASSOCIATION OF THE DELETION ALLELE OF THE INSERTION/DELETION POLYMORPHISM OF αIIbβ3 INTEGRIN GENE AND METABOLIC SYNDROME IN YOUNG NORTHERNERS

The rationale for the present study is explained by a high spread of metabolic syndrome among the young population, living in an area equivalent to the Far North. The study is aimed at the investigation of the association between a deletion allele of the polymorphism of deletion/insertion in the αIIbβ3 integrin gene and metabolic syndrome in young residents Khanty-Mansiysk Autonomous Okrug – Ugra (Russia). The 758 young people aged 18-44 (mean age 36.62±5.12 years old) with metabolic syndrome and 77 healthy young people without metabolic disorders were examined. The carriership of the allele I associated with the cardiovascular risk was revealed in 63% of the examined patients that had an increased risk of the development of metabolic disorders (OR 1.409, 95% CI 0.858-2.311, p=0.253). There was no significant difference between the native and non-native populations in the rate of occurrence of allele I (62.2% and 64.7%). Genotype II had significant association with arterial hypertension (OR 1.377, 95 % CI 0.912-2.080, p=0.073), obesity (OR 1.353, 95% CI 0.825-2.219, p=0.071), hypercholesterinemia (OR 1.386, 95% CI 0.977-1.966, p=0.115), hypertriglyceridemia (OR 1.232, 95% CI 0.889-1.706, p=0.097). It was established that the non-native population had a higher risk of the development of abdominal obesity, arterial hypertension, and hypercholesterinemia, unlike the native population that had a significantly higher risk of the development of triglyceridemia. The materials of the article can be useful for the evaluation of genetic predisposition to myocardial infarction, stroke, and thromboembolism, which will allow for timely indication of preventive measures.

Multi-enhancer transcriptional hubs confer phenotypic robustness

We had previously shown inDrosophila melanogasterembryos that low-affinity Ultrabithorax (Ubx)-responsiveshavenbaby(svb) enhancers drive robust expression using localized transcriptional environments and that activesvbenhancers tended to colocalize, even when placed on different chromosomes (Tsai et al., 2017). Here, we test the hypothesis that these multi-enhancer “hubs” improve robustness by increasing transcription factor retention near transcription sites. Deleting a redundant enhancer from thesvblocus led to reduced trichome numbers in embryos raised at elevated temperatures. Using high-resolution fluorescence microscopy, we observed lower Ubx concentration and transcriptional output in this deletion allele. Transcription sites of the fullsvb cis-regulatory region inserted into a different chromosome colocalized with thesvblocus, increasing Ubx concentration, the transcriptional output ofsvb, and partially rescuing the phenotype. Thus, multiple enhancers could reinforce a local transcriptional hub to buffer against environmental stresses and genetic perturbations, providing a mechanism for phenotypical robustness.Impact statementMultiple enhancers in physical proximity can reinforce shared transcriptional “hubs” to retain transcription factors, providing a buffer during environmental stresses and genetic perturbations to preserve phenotypic robustness.

Aberrantly Expressed APOBEC3B Induces Mutations in Multiple Myeloma

Multiple myeloma (MM) is a malignant plasma cell tumor that arises secondarily from monoclonal gammopathy of uncertain significance (MGUS) due to accumulation of genetic abnormalities. Apolipoprotein B mRNA editing enzyme catalytic polypeptide-like (APOBEC) is a family of DNA cytosine deaminases that play critical roles in innate and acquired immunity. APOBEC proteins catalyze cytosine to uracil deamination and eventually induce C to T mutations in DNA. Recent genome-wide analysis revealed that APOBEC-induced signature DNA mutations accumulate during progression of MM and are associated with poor prognosis (Bolli et. al., Nat Commun. 2014). We previously found that one of the APOBEC3 proteins, APOBEC3B (A3B), induces genomic DNA mutations in a human cell culture model (Shinohara et. al., Sci Rep. 2012) and hypothesized that A3B might induce DNA mutations during onset and progression of MGUS and MM. A deletion polymorphism that removes the entire A3B gene is reported to affect breast cancer prognosis, therefore we first investigated the frequency of A3B deletion allele in 88 Japanese MM/MGUS patients and in healthy controls. 41 patients (46.6%) showed wild type, 42 patients (47.7%) heterozygous, and 5 patients (5.7%) had homozygous deletion allele. We could not detect a significant difference between MM/MGUS patients and healthy controls, suggesting that A3B may not contribute to disease initiation. In contrast, real-time PCR analysis revealed a considerably high expression of A3B mRNA in 23 bone marrow specimens from MM/MGUS patients, except for two samples with homozygous deletion allele. We sorted myeloma cells using anti-CD138 beads and the enriched myeloma cell samples exhibited even higher A3B mRNA expression in 9 MM/MGUS patients (relative quantity to peripheral blood cells [PBMC]: range 1.06 to 55.14, median 7.67). Next, we investigated the APOBEC3 family protein expression profile in six myeloma cell lines: U266, RPMI8226, SKMM1, AMO1, OPM2 and THK72. As expected, all of these cell lines demonstrated remarkably high levels of A3B expression by real-time PCR analysis (relative quantity to PBMC: range 1.22 to 489.4, median 62.47). Western blot analysis using an anti-A3B antibody that we newly generated also confirmed the high A3B protein expression in these myeloma cell lines. In addition, fluorescent immunostaining analysis confirmed high expression of A3B protein localized in the nucleus. Because previous studies showed that A3B expression is activated via the NF-kB signaling pathway, we investigated the regulation of A3B transcription in myeloma cells by p65 knockdown through shRNA lentivirus, resulting in suppression of A3B at protein level. To investigate the mutagenic potential of aberrantly expressed A3B in myeloma cell lines, we evaluated somatic mutations in genomic DNA by differential DNA denaturation PCR (3D-PCR) using stable A3B knock-down cells by shRNA lentivirus simultaneously transduced with a fluorescent gene, mCherry. Interestingly, we detected that scramble shRNA-transduced cells lost fluorescence much faster than those transduced with shRNA against A3B. 3D-PCR amplified mCherry fragments more efficiently at a lower denaturation temperature, indicating that these fragments include more AT-rich sequences. We cloned these DNA fragments and sequenced about 4000 bp in total, and detected prominently more TC > TT mutations in the mCherry sequences from control shRNA-transduced cells (C to T mutation, 3.001%) than in those from A3B shRNA-tranduced cells (C to T mutation, 0.0024%). Additionally, the amplified mCherry sequences from scramble shRNA-transduced cells contained various deletions which may be repaired by microhomology-mediated end joining. Since DNA double strand breaks (DSB) are constitutively activated in myeloma cells, we also examined whether aberrantly expressed A3B can induce DSBs. A3B knockdown in RPMI8226 decreased gH2AX signals by fluorescent immunostaining and Western blot analysis, suggesting that A3B induces DSBs. The present study clearly shows that myeloma cells express aberrantly high levels of A3B and suggests that A3B might play crucial roles in clonal evolution or genomic instability of MM/MGUS albeit A3B may not contribute to initiation of MGUS/MM. Whether A3B accelerates chemoresistance or disease progression remains to be elucidated, however, A3B might be a potential therapeutic target in MM/MGUS. Disclosures Iida: Janssen Pharmaceuticals: Honoraria, Research Funding; Celgene: Honoraria, Research Funding. Takaori-Kondo:Mochida Pharmaceutical: Research Funding; Takeda Pharmaceutical: Research Funding; Pfizer: Research Funding; Kyowa Kirin: Research Funding; Astellas Pharma: Research Funding; Eisai: Research Funding; Alexion Pharmaceuticals: Research Funding; Chugai Pharmaceutical: Research Funding; Janssen Pharmaceuticals: Speakers Bureau; Merck Sharp and Dohme: Speakers Bureau; Bristol-Myers Squibb: Speakers Bureau; Shionogi: Research Funding; Toyama Chemical: Research Funding; Cognano: Research Funding.