Genetic Variation and Sickle Cell Disease Severity: A Systematic Review and Meta-Analysis.

Importance: Sickle cell disease (SCD) is a monogenic disorder, yet clinical outcomes are influenced by additional genetic factors. Despite decades of research, the genetics of SCD remain poorly understood. Objective: To assess all reported genetic modifiers of SCD, evaluate the design of associated studies, and provide guidelines for future analyses according to modern genetic study recommendations. Data Sources: PubMed, Web of Science, and Scopus were searched through May 16, 2023, identifying 5290 publications. Study Selection: At least 2 reviewers identified 571 original, peer-reviewed English-language publications reporting genetic modifiers of human SCD phenotypes, wherein the outcome was not treatment response, and the comparison was not between SCD subtypes or including healthy controls. Data Extraction and Synthesis: Data relevant to all genetic modifiers of SCD were extracted, evaluated, and presented following STREGA and PRISMA guidelines. Weighted z score meta-analyses and pathway analyses were conducted. Main Outcomes and Measures: Outcomes were aggregated into 25 categories, grouped as acute complications, chronic conditions, hematologic parameters or biomarkers, and general or mixed measures of SCD severity. Results: The 571 included studies reported on 29 670 unique individuals (50% ≤ 18 years of age) from 43 countries. Of the 17 757 extracted results (4890 significant) in 1552 genes, 3675 results met the study criteria for meta-analysis: reported phenotype and genotype, association size and direction, variability measure, sample size, and statistical test. Only 173 results for 62 associations could be cross-study combined. The remaining associations could not be aggregated because they were only reported once or methods (eg, study design, reporting practice) and genotype or phenotype definitions were insufficiently harmonized. Gene variants regulating fetal hemoglobin and α-thalassemia (important markers for SCD severity) were frequently identified: 19 single-nucleotide variants in BCL11A, HBS1L-MYB, and HBG2 were significantly associated with fetal hemoglobin (absolute value of Z = 4.00 to 20.66; P = 8.63 × 10-95 to 6.19 × 10-5), and α-thalassemia deletions were significantly associated with increased hemoglobin level and reduced risk of albuminuria, abnormal transcranial Doppler velocity, and stroke (absolute value of Z = 3.43 to 5.16; P = 2.42 × 10-7 to 6.00 × 10-4). However, other associations remain unconfirmed. Pathway analyses of significant genes highlighted the importance of cellular adhesion, inflammation, oxidative and toxic stress, and blood vessel regulation in SCD (23 of the top 25 Gene Ontology pathways involve these processes) and suggested future research areas. Conclusions and Relevance: The findings of this comprehensive systematic review and meta-analysis of all published genetic modifiers of SCD indicated that implementation of standardized phenotypes, statistical methods, and reporting practices should accelerate discovery and validation of genetic modifiers and development of clinically actionable genetic profiles.

DYRK gene structure and erythroid-restricted features of DYRK3 gene expression.

DYRKs are an emerging family of dual-specificity kinases that play key roles in cell proliferation, survival, and development. Up to seven mammalian DYRK isoforms have been reported, but only the DYRK1A gene (and its products) has been well characterized. Defined here are the genomic structures (and phylogenetics) of DYRK3, four additional murine and/or human DYRKs, and two related HIPK genes. For murine DYRK3, direct BAC sequences are provided, a basis for differential processing of murine versus human transcripts is defined, and tissue expression profiles plus a functional DYRK3 promoter are characterized. Unlike complex DYRKs 1A, 1B, and 4A, DYRK3 and DYRK2 possess simple 4-exon structures. For DYRK3, expression is strong in erythroid cells and testis, but is also detected in adult kidney and liver in situ. In addition, a 1930-bp DYRK3 promoter drives erythroid expression and transcript expression is inhibited sharply on GATA1-induced G1E cell differentiation.