Sprouty (Spry) genes encode inhibitors of the receptor tyrosine kinase signaling cascade, which plays important roles in stem cells. However, the role of Spry4 in the stemness of embryonic stem cells has not been fully elucidated. Here, we used mouse embryonic stem cells (mESCs) as a model system to investigate the role of Spry4 in the stem cells. Suppression of Spry4 expression results in the decreases of cell proliferation, EB formation and stemness marker expression, suggesting that Spry4 activity is associated with stemness of mESCs. Teratoma assay showed that the cartilage maturation was facilitated in Spry4 knocked down mESCs. Our results suggest that Spry4 is an important regulator of the stemness and differentiation of mESCs.

Rad51 is a key component of homologous recombination (HR) to repair DNA double-strand breaks and it forms Rad51 recombinase filaments of broken single-stranded DNA to promote HR. In addition to its role in DNA repair and cell cycle progression, Rad51 contributes to the reprogramming process during the generation of induced pluripotent stem cells. In light of this, we performed reprogramming experiments to examine the effect of co-expression of Rad51 and four reprogramming factors, Oct4, Sox2, Klf4, and c-Myc, on the reprogramming efficiency. Co-expression of Rad51 significantly increased the numbers of alkaline phosphatase-positive colonies and embryonic stem cell-like colonies during the process of reprogramming. Co-expression ofRad51 significantly increased the expression of epithelial markers at an early stage of reprogramming compared with control cells. Phosphorylated histone H2AX (γH2AX), which initiates the DNA double-strand break repair system, was highly accumulated in reprogramming intermediates upon co-expression of Rad51. This study identified a novel role of Rad51 in enhancing the reprogramming efficiency, possibly by facilitating mesenchymal-to-epithelial transition and by regulating a DNA damage repair pathway during the early phase of the reprogramming process.

Some mutations in FOXL2 are responsible for premature ovarian failure accompanied with blepharophimosis-ptosis-epicanthusinversus syndrome (BPES) typeI disease, and FOXL2-null mice exhibit developmental defects of granulosa cells. Recently, a new somatic mutation in FOXL2,c.402C>G, leading top. C134W change, has been identified in a vast majority of adult-type ovarian garnulosa cell tumors (GCTs). In the current study, we investigated possible mechanisms by which the C134W mutation could contribute to GCT development. The wild-type (WT) FOXL2 and its mutant form displayed differential apoptotic activities, in which WT induced a significant granulosa cell death while the mutant exhibited a minimal cell death effect. The FOXL2-induced apoptotic response was greatly dependent on caspase8, BID, or BAK since the depletion of either of them prevented FOXL2 to elicitits full apoptotic responses. Stimulated activation of caspase8, consequently resulting increased production of truncated BID (tBID), up-regulation and oligomerization of BAK, and release of cytochromec were all associated with the apoptosis followed by WT FOXL2 expression. In contrast, the mutant FOXL2 was deficient to elicit the full apoptotic signaling responses. In addition, we found the differential up-regulations of expression of death receptors including Fas and TNF-R1 between the WT and the mutant. Moreover, granulosa cells expressing either the WT FOXL2 or its variant form (C134W) exhibited distinct cell death sensitivities by the activation of death receptors. Thus, these differential activities of FOXL2 and it mutant may partly account for the pathophysiology of GCT development occurred by the somatic mutation (C134W) of FOXL2.

BPES(Blepharophimosis/Ptosis/Epicanthus inversus Syndrome)는 FOXL2 유전자의 돌연변이에 의해 유발되는 상염색체 우성질환이다. 눈꺼풀이 갈라지거나 쳐지고 넓은 미간이 나타나는 특징이 있으며, 여성의 조기 난소 부전증(prema-ture ovarian failure, POF)을 일으켜 불임을 유발한다. FOXL2는 forkhead family에 속하는 전사인자로서 FOXL2가 결여된 난소에서는 granulosa cell의 분화가 진행되지 않아 난포 성숙과정의 멈춤과 난자의 폐쇄증을 유발한다. FOXL2를 bait로 하여 rat의 난소 cDNA 라이브러리의 yeast two-hybrid screening을 시행하여 FOXL2 단백질과 상호작용을 하는 small ubiquitin-related modifier(SUMO)-conjugating E2 효소인 UBE2I 단백질을 찾았다. UBC9이라고도 알려진 UBE2I 단백질은 SUMO 변형 과정을 위한 필수적인 단백질이다. Sumoylation은 수 많은 전사인자의 전사능력의 조절을 포함하여 다양한 신호전달체계에 관여하는 번역 후 변형과정이다. 본 연구에서 인간세포인 293T 내에서 면역침전반응 실험을 통해 FOXL2와 UBE2I의 단백질-단백질간의 상호작용을 확인하고, FOXL2의 돌연변이형을 제작하여 yeast two-hybrid system을 이용해 UBE2I와 결합에 필요한 FOXL2의 부분을 규명하였다. 따라서, FOX2에 상호작용하는 UBE2I의 규명은 sumoylation에 의한 FOXL2의 새로운 조절 메커니즘을 시사한다.