Human PRP19 interacts with prolyl-hydroxylase PHD3 and inhibits cell death in hypoxia

Prolyl-hydroxylase PHDs are the key regulators of hypoxia-inducible factor (HIF) stability. PHD3 has been shown to form a large complex under hypoxic conditions. While attempting to characterize the complex by determining its components, we identified human PRP19. hPRP19 is a multi-functional protein that plays a role in splicing, ubiquitination, and cell growth. Here, we report that PHD3 efficiently forms a complex with hPRP19 under hypoxic conditions and prevents cell death under prolonged hypoxic conditions. hPRP19 interacts with PHD3 via its C-terminal WD40 region, and the interaction is enhanced under hypoxic conditions through the utilization of the N-terminal coiled-coil domain. Cell death observed under prolonged hypoxic conditions is suppressed by the forced expression of hPRP19 in PC12 and HEK293T cells. In contrast, hPRP19 silencing by siRNA increased the caspase activity and enhanced cell death under hypoxic conditions in HeLa cells. Further, silencing of both PHD3 and hPRP19 recovers the cell death induced by hPRP19 single siRNA. Taken together, the results of our study indicate that hPRP19 interacts with PHD3 to suppress the cell death under hypoxic conditions by limiting the function of PHD3 which leads to caspase activation.     

FGF signaling gradient maintains symmetrical proliferative divisions of midbrain neuronal progenitors

For the correct development of the central nervous system, the balance between self-renewing and differentiating divisions of the neuronal progenitors must be tightly regulated. To maintain their self-renewing identity, the progenitors need to retain both apical and basal interfaces. However, the identities of fate-determining signals which cells receive via these connections, and the exact mechanism of their action, are poorly understood. The conditional inactivation of Fibroblast growth factor (FGF) receptors 1 and 2 in the embryonic mouse midbrain–hindbrain area results in premature neuronal differentiation. Here, we aim to elucidate the connection between FGF signaling and neuronal progenitor maintenance. Our results reveal that the loss of FGF signaling leads to downregulation of Hes1 and upregulation of Ngn2, Dll1, and p57 in the ventricular zone (VZ) cells, and that this increased neurogenesis occurs cell-autonomously. Yet the cell cycle progression, apico-basal-polarity, cell–cell connections, and the positioning of mitotic spindle in the mutant VZ appear unaltered. Interestingly, FGF8-protein is highly concentrated in the basal lamina. Thus, FGFs may act through basal processes of neuronal progenitors to maintain their progenitor status. Indeed, midbrain neuronal progenitors deprived in vitro of FGFs switched from symmetrical proliferative towards symmetrical neurogenic divisions. We suggest that FGF signaling in the midbrain VZ is cell-autonomously required for the maintenance of symmetrical proliferative divisions via Hes1-mediated repression of neurogenic genes.     

鼻咽癌及癌旁上皮细胞的AgNORs定量分析及其生物学意义

目的通过鼻咽癌及癌旁上皮的细胞核仁组成区蛋白(NORs)图像定量分析,评价其反映细胞群体增生能力及分化程度等生物学意义。方法对70例鼻咽癌石蜡切片进行银染(AgNORs),应用CAS200图像分析仪分别测定29例癌旁正常腺上皮、19例增生／异型增生柱状上皮、10例增生／异型增生鳞状上皮、54例分化性非角化性癌和16例未分化癌的细胞群体AgNORs参数值并作比较分析;结果每核AgNOR计数、每核AgNOR面积和平均AgNOR面积／粒从正常腺上皮至增生／异型增生柱状上皮至分化性非角化性癌或未分化癌呈现显增加,平均核面积、每核AgNOR面积和平均AgNOR面积／粒从正常腺上皮至增生／异型增生鳞状上皮至未分化癌呈现显增加,差异均有显性,但增生／异型增生鳞状上皮与分化性非角化性癌的AgNOR数值差异没有显差异;与分化性非角化性癌比较,未分化癌的平均核面积、每核AgNOR面积和平均AgNOR面积／粒显增加。结论．AgNORs形态定量分析反映了鼻咽癌及癌旁不同类型鼻咽上皮的细胞增生活性和组织细胞分化程度,但不能反映细胞是否恶性转化;不同组织类型鼻咽癌细胞存在增殖能力的差异,其增生差异程度可能是影响病人对放射线治疗敏感性及其预后的重要因素之一。     

Comparative chromosomal studies on two minnow fish, Phoxinus phoxinus (Linnaeus, 1758) and Eupallasella perenurus (Pallas, 1814); an associated cytogenetic-taxonomic considerations

The present work provides new data on the banding pattern of two cyprinid fish species Phoxinus phoxinus and Eupallasella perenurus from Poland. C-banding, silver-staining (Ag), and fluorescent staining with chromomycin A₃ techniques were used to describe the karyotypes. Both of the species karyotypes of 2n=50 were characterised by one pair of acrocentric chromosomes, the largest in the set, and by two pairs of NOR-bearing chromosomes. In the chromosome set of Ph. phoxinus Ag-stained NORs were located on telomeres of two metacentric and two submetacentric chromosomes, but in most metaphases only one of the two homologous was observed. The karyotype of E. perenurus was characterised by Ag-NOR regions at a telomeric position on the shorter arm of two submetacentric chromosome pairs. In most metaphases only three NOR-bearing chromosomes were observed. In both investigated species the location of the A₃ positive signals corresponded with the location of Ag-stained NORs and these sites were associated with heterochromatin shown as C-bands. The results of cytogenetical studies on other related, mainly the North American phoxinins, species are compared and discussed.     

Inhibition of BMP activity by the FGF signal promotes posterior neural development in zebrafish

The expression patterns of region-specific neuroectodermal genes and fate-map analyses in zebrafish gastrulae suggest that posterior neural development is initiated by nonaxial signals, distinct from organizer-derived secreted bone morphogenetic protein (BMP) antagonists. This notion is further supported by the misexpression of a constitutively active form of zebrafish BMP type IA receptor (CA-BRIA) in the zebrafish embryos. It effectively suppressed the anterior neural marker, otx2, but not the posterior marker, hoxb1b. Furthermore, we demonstrated that the cells in the presumptive posterior neural region lose their neural fate only when CA-BRIA and Xenopus dominant-negative fibroblast growth factor (FGF) receptors (XFD) are coexpressed. The indications are that FGF signaling is involved in the formation of the posterior neural region, counteracting the BMP signaling pathway within the target cells. We then examined the functions of Fgf3 in posterior neural development. Zebrafish fgf3 is expressed in the correct place (dorsolateral margin) and at the correct time (late blastula to early gastrula stages), the same point that the most precocious posterior neural marker, hoxb1b, is first activated. Unlike other members of the FGF family, Fgf3 had little mesoderm-inducing activity. When ectopically expressed, Fgf3 expands the neural region with suppression of anterior neural fate. However, this effect was mediated by Chordino (zebrafish Chordin), because Fgf3 induces chordino expression in the epiblast and Fgf3-induced neural expansion was substantially suppressed in dino mutants with mutated chordino genes. The results obtained in the present study reveal multiple actions of the FGF signal on neural development: it antagonizes BMP signaling within posterior neural cells, induces the expression of secreted BMP antagonists, and suppresses anterior neural fate.     

The lens organizes the anterior segment: specification of neural crest cell differentiation in the avian eye

During the development of the anterior segment of the eye, neural crest mesenchyme cells migrate between the lens and the corneal epithelium. These cells contribute to the structures lining the anterior chamber: the corneal endothelium and stroma, iris stroma, and trabecular meshwork. In the present study, removal of the lens or replacement of the lens with a cellulose bead led to the formation a disorganized aggregate of mesenchymal cells beneath the corneal epithelium. No recognizable corneal endothelium, corneal stroma, iris stroma, or anterior chamber was found in these eyes. When the lens was replaced immediately after removal, a disorganized mass of mesenchymal cells again formed beneath the corneal epithelium. However, 2 days after surgery, the corneal endothelium and the anterior chamber formed adjacent to the lens. When the lens was removed and replaced such that only a portion of its anterior epithelial cells faced the cornea, mesenchyme cells adjacent to the lens epithelium differentiated into corneal endothelium. Mesenchyme cells adjacent to lens fibers did not form an endothelial layer. The cell adhesion molecule, N-cadherin, is expressed by corneal endothelial cells. When the lens was removed the mesenchyme cells that accumulated beneath the corneal epithelium did not express N-cadherin. Replacement of the lens immediately after removal led to the formation of an endothelial layer that expressed N-cadherin. Implantation of lens epithelia from older embryos showed that the lens epithelium maintained the ability to support the expression of N-cadherin and the formation of the corneal endothelium until E15. This ability was lost by E18. These studies provide evidence that N-cadherin expression and the formation of the corneal endothelium are regulated by signals from the lens. N-cadherin may be important for the mesenchymal-to-epithelial transformation that accompanies the formation of the corneal endothelium.     

FGF signalling pathways in development of the midbrain and anterior hindbrain

Development of the central nervous system is coordinated by intercellular signalling centres established within the neural tube. The isthmic organizer (IsO), located between the midbrain and anterior hindbrain, is one such centre. Important signal molecules secreted by the IsO include members of the fibroblast growth factor and Wnt families. These signals are integrated with dorsally and ventrally derived signals to regulate development of the midbrain and rhombomere 1 of the hindbrain. The IsO is operational for a remarkably long period of time. Depending on the developmental stage, it controls a variety of processes such as cell survival, cell identity, neural precursor proliferation, neuronal differentiation and axon guidance. This review focuses on the fibroblast growth factor signalling, its novel molecular regulatory mechanisms and how this pathway regulates multiple aspects of cell behaviour in the developing midbrain and anterior hindbrain.