Whole-exome sequencing reveals SALL4 variants in premature ovarian insufficiency: an update on genotype-phenotype correlations.

Premature ovarian insufficiency (POI) is a severe female disorder characterized by primary or secondary amenorrhea before 40 years of age. Genetic factors have been implicated in the pathogenesis of POI, but known POI-associated genes account for only a small fraction of heritability. Here, we performed whole-exome sequencing (WES) to explore pathogenic genes in Han Chinese subjects with POI. Intriguingly, we identified novel or rare heterozygous missense variants of SALL4 (spalt-like transcription factor 4) in 3 (6%) of 50 POI subjects. The SALL4 c.541G>A and c.2279C>T variants were paternally inherited, while c.1790A>G was inherited from an affected mother with early menopause. SALL4 encodes a transcription factor that is highly expressed in oocytes and early embryos. Our in vitro functional assays suggested that all of these SALL4 missense variants had significantly increased SALL4 protein expression with enhanced regulatory activity in regard to its downstream target POU5F1 compared to that of wild-type SALL4. Notably, previous studies demonstrated the genetic involvement of SALL4 loss-of-function variants in Okihiro syndrome and related syndromic developmental disorders. Through our analysis of genotype-phenotype correlations, we suggest that different variation types of SALL4 might have different effects on SALL4 activity, resulting in phenotypic variability. Our findings highlight the genetic contribution of SALL4 missense variants with enhanced regulatory activities to POI and underscore the importance of variant classification and evaluation for molecular diagnosis and genetic counseling.

Rare variants in FANCA induce premature ovarian insufficiency.

Premature ovarian insufficiency (POI) is a major cause of reduced female fertility and affects approximately 1% women under 40 years of age. Recent advances emphasize the genetic heterogeneity of POI. Fanconi anemia (FA) genes, traditionally known for their essential roles in DNA repair and cytogenetic instability, have been demonstrated to be involved in meiosis and germ cell development. Here, we conducted whole-exome sequencing (WES) in 50 Han Chinese female patients with POI. Rare missense variants were identified in FANCA (Fanconi anemia complementation group A): c.1772G > A (p.R591Q) and c.3887A > G (p.E1296G). Both variants are heterozygous in the patients and very rare in the human population. In vitro functional studies further demonstrated that these two missense variants of FANCA exhibited reduced protein expression levels compared with the wild type, suggesting the partial loss of function. Moreover, mono-ubiquitination levels of FANCD2 upon mitomycin C stimulation were significantly reduced in cells overexpressing FANCA variants. Furthermore, a loss-of-function mutation of Fanca was generated in C57BL/6 mice for in vivo functional assay. Consistently, heterozygous mutated female mice (Fanca+/-) showed reduced fertility and declined numbers of follicles with aging when compared with the wild-type female mice. Collectively, our results suggest that heterozygous pathogenic variants in FANCA are implicated in non-syndromic POI in Han Chinese women, provide new insights into the molecular mechanisms of POI and highlight the contribution of FANCA variants in female subfertility.

A de novo mutation in DHD domain of SKI causing spina bifida with no craniofacial malformation or intellectual disability.

Shprintzen-Goldberg syndrome (SGS) is a rare systemic connective tissue disorder characterized by craniofacial, skeletal, and cardiovascular manifestations. It is associated with a significant risk of intellectual disability, a feature which distinguishes it from Marfan and Loeys-Dietz syndromes. SGS is mainly caused by mutations in the SKI gene, a repressor of TGF-ß activity. Most SKI mutations are found in exon 1 of the gene and are located in the R-SMAD domain, a proposed hotspot for de novo mutations. Here, we report on a de novo SKI mutation located in the DHD domain of SKI. By adding our finding to previously reported de novo SKI mutations, a new mutational hotspot in the DHD domain is proposed. Our patient presented with a lipomeningomyelocele, tethered cord, and spina bifida but with no SGS-related clinical findings apart from a marfanoid habitus and long slender fingers. Specifically, she did not have an intellectual disability, craniofacial, or cardiovascular abnormalities. By comparing the clinical findings on patients with mutations in the R-SMAD and DHD domains of SKI, we propose that mutations in those domains have different effects on TGF-ß activity during embryonic development with resulting phenotypic differences.