Lingfei Luo

NF-κB and Snail1a coordinate the cell cycle with gastrulation

The cell cycle needs to strictly coordinate with developmental processes to ensure correct generation of the body plan and different tissues. However, the molecular mechanism underlying the coordination remains largely unknown. In this study, we investigate how the cell cycle coordinates gastrulation cell movements in zebrafish. We present a system to modulate the cell cycle in early zebrafish embryos by manipulating the geminin-Cdt1 balance. Alterations of the cell cycle change the apoptotic level during gastrulation, which correlates with the nuclear level of antiapoptotic nuclear factor κB (NF-κB). NF-κB associates with the Snail1a promoter region on the chromatin and directly activates Snail1a, an important factor controlling cell delamination, which is the initial step of mesendodermal cell movements during gastrulation. In effect, the cell cycle coordinates the delamination of mesendodermal cells through the transcription of Snail1a. Our results suggest a molecular mechanism by which NF-κB and Snail1a coordinate the cell cycle through gastrulation.

Retinoic Acid Signaling Sequentially Controls Visceral and Heart Laterality in Zebrafish

During zebrafish development, the left-right (LR) asymmetric signals are first established around the Kupffer vesicle (KV), a ciliated organ generating directional fluid flow. Then, LR asymmetry is conveyed and stabilized in the lateral plate mesoderm. Although numerous molecules and signaling pathways are involved in controlling LR asymmetry, mechanistic difference and concordance between different organs during LR patterning are poorly understood. Here we show that RA signaling regulates laterality decisions at two stages in zebrafish. Before the 2-somite stage (2So), inhibition of RA signaling leads to randomized visceral laterality through bilateral expression of nodal/spaw in the lateral plate mesoderm, which is mediated by increases in cilia length and defective directional fluid flow in KV. Fgf8 is required for the regulation of cilia length by RA signaling. Blockage of RA signaling before 2So also leads to mild defects of heart laterality, which become much more severe through perturbation of cardiac bmp4 asymmetry when RA signaling is blocked after 2So. At this stage, visceral laterality and the left-sided Nodal remain unaffected. These findings suggest that RA signaling controls visceral laterality through the left-sided Nodal signal before 2So, and regulates heart laterality through cardiac bmp4 mainly after 2So, first identifying sequential control and concordance of visceral and heart laterality.

Geminin is required for left-right patterning through regulating Kupffer's vesicle formation and ciliogenesis in zebrafish.

Geminin plays an important role in coordinating the cell cycle with anterior-posterior patterning during embryonic development. However, whether it is involved in the regulation of left-right (LR) patterning remains unknown. Here, we reported that geminin is required for setting up heart and visceral laterality during zebrafish development. Defective heart and visceral laterality was observed in geminin morphants. Further study demonstrated that the left-sided nodal/spaw in the lateral plate mesoderm (LPM) as well as the sideness of its downstream targets lefty2 and lefty1 was perturbed in geminin morphants. Upstream of the left-sided Nodal signal along the regulatory cascade of LR asymmetry, knock down of geminin resulted in defective Kupffers vesicle (KV) formation and ciliogenesis rather than middle line defects. Predominant distribution of an antisense morpholino against geminin in dorsal forerunner cells (DFCs) led to defective KV morphogenesis and perturbed LR asymmetry, similar to those of geminin morphants, indicating a cell-autonomous role of geminin in regulating KV formation and ciliogenesis. Our results demonstrate that geminin is required for proper KV formation and ciliogenesis, thus playing an important part in setting up LR asymmetry.

Noncanonical function of threonyl-tRNA synthetase regulates vascular development in zebrafish

The canonical functions of Aminoacyl-tRNA synthetases (AARSs) are indispensable for protein synthesis. However, recent evidence indicates that some AARSs possess additional biological functions (noncanonical functions) related to immune responses and vascular development. Here, we identified a zebrafish cq16 mutant presenting the disorganized vessels with abnormal branching of the established intersegmental vessels (ISVs) as well as aberrant patterning of the brain vascular network after 50 h post fertilization. The cq16 mutant gene is responsible for encoding threonyl-tRNA synthetase (tars) with a missense mutation. The abnormal branching of ISVs was caused by the increased expression of vascular endothelial growth factor A (vegfa) in tars(cq16) mutant. Inhibition of Vegf signaling suppresses the abnormal vascular branching observed in tars(cq16) mutant. Furthermore, injection of human TARS mRNA potently reduced the vascular aberrant branching in tars(cq16) mutant, indicating a conserved function of tars in regulating angiogenesis between zebrafish and human. Therefore, we conclude that noncanonical function of tars regulates vascular development presumably by modulating the expression of vegfa.

Cyp2aa9 regulates haematopoietic stem cell development in zebrafish.

Definitive haematopoiesis occurs during the lifetime of an individual, which continuously replenishes all blood and immune cells. During embryonic development, haematopoietic stem cell (HSC) formation is tightly controlled by growth factors, signalling molecules and transcription factors. But little is known about roles of the cytochrome P450 (CYP) 2 family member in the haematopoiesis. Here we report characterization and functional studies of Cyp2aa9, a novel zebrafish Cyp2 family member. And demonstrate that the cyp2aa9 is required for the HSC formation and homeostasis. Knockdown of cyp2aa9 by antisense morpholino oligos resulted the definitive HSC development is defective and the Wnt/β-catenin activity becomes reduced. The impaired HSC formation caused by cyp2aa9 morpholino can be rescued by administration of PGE2 through the cAMP/PKA pathway. Furthermore, the in vivo PGE2 level decreases in the cyp2aa9 morphants, and none of the PGE2 precursors is able to rescue phenotypes in the Cyp2aa9-deficient embryos. Taken together, these data indicate that Cyp2aa9 is functional in the step of PGE2 synthesis from PGH2, thus promoting Wnt activation and definitive HSC development.

Loss of Gspt1l disturbs the patterning of the brain central arteries in zebrafish

The cranial vasculature is crucial for the survival and development of the central nervous system and is closely related to brain pathologies. Characterizations of the underlying mechanisms by which cranial vessels acquire their stereotypic patterning remain to be the key interest in the cerebrovascular research. In this report, we show an interesting zebrafish cq37 mutant displaying aberrant patterning of the central arteries. Genetic mapping results indicate that the gene responsible for cq37 encodes G1 to S phase transition 1, like (Gspt1l) with a nonsense mutation. Complementation studies with a CRISPR-generated allele, as well as mRNA rescues, together strongly demonstrate that gspt1l is the cq37 gene. Zebrafish gspt1l is broadly expressed in the brain with enhanced expression in hindbrain during central artery sprouting. Further studies reveal that vascular endothelial growth factor (VEGF) signaling and unfolded protein response (UPR) pathway are activated in gspt1lcq37 mutants. In addition, expression analysis shows that vegfa and activating transcription factor-4 (atf4) are strongly upregulated in regions of gspt1l expression. Our results suggest that loss of Gspt1l activates the UPR pathway, which in turn induces ectopic expression of vegfa via Atf4, thus disturbing the patterning of the central arteries.

C1qr and C1qrl redundantly regulate angiogenesis in zebrafish through controlling endothelial Cdh5

Angiogenesis plays central role in the formation of functional circulation system. Characterizations of the involved factors and signaling pathways remain to be the key interest in the angiogenesis research. In this report, we showed that c1qr/cd93 and c1qrl/clec14a are specifically expressed in the vascular endothelial cells during zebrafish development. Single mutation of c1qr or c1qrl is associated with slightly malformation of inter-segmental vessels (ISVs), whereas double mutant exhibits severe defects in the ISVs formation without affecting early vasculogenesis. Further studies reveal that the endothelial-endothelial junctional molecule Cdh5 becomes absent in the ISVs of the double mutant. Replenishment of Cdh5 efficiently rescue the impaired angiogenesis in the c1qr/c1qrl double mutant. These data demonstrate that c1qr and c1qrl redundantly regulate angiogenesis through controlling the expression of the endothelial junctional molecule Cdh5, thus playing an important role in angiogenesis.

Systemic inoculation of Escherichia coli causes emergency myelopoiesis in zebrafish larval caudal hematopoietic tissue

Emergency granulopoiesis occurs in response to severe microbial infection. However, whether and how other blood components, particularly monocytes/macrophages and their progenitors, including hematopoietic stem/progenitor cells (HSPCs), participate in the process and the underlying molecular mechanisms remain unknown. In this study, we challenged zebrafish larvae via direct injection of Escherichia coli into the bloodstream, which resulted in systemic inoculation with this microbe. The reaction of hematopoietic cells, including HSPCs, in the caudal hematopoietic tissue was carefully analysed. Both macrophages and neutrophils clearly expanded following the challenge. Thus, emergency myelopoiesis, including monopoiesis and granulopoiesis, occurred following systemic bacterial infection. The HSPC reaction was dependent on the bacterial burden, manifesting as a slight increase under low burden, but an obvious reduction following the administration of an excessive volume of bacteria. Pu.1 was important for the effective elimination of the microbes to prevent excessive HSPC apoptosis in response to stress. Moreover, Pu.1 played different roles in steady and emergency monopoiesis. Although Pu.1 was essential for normal macrophage development, it played suppressive roles in emergency monopoiesis. Overall, our study established a systemic bacterial infection model that led to emergency myelopoiesis, thereby improving our understanding of the function of Pu.1 in this scenario.

The effector of Hippo signaling, Taz, is required for formation of the micropyle and fertilization in zebrafish

The mechanisms that ensure fertilization of eggs by a single sperm are not fully understood. In all teleosts, a channel called the ‘micropyle’ is the only route of entry for sperm to enter and fertilize the egg. The micropyle forms by penetration of the developing vitelline envelope by a single specialized follicle cell, the micropylar cell, which subsequently degenerates. The mechanisms underlying micropylar cell specification and micropyle formation are poorly understood. Here, we show that an effector of the Hippo signaling pathway, the Transcriptional co-activator with a PDZ-binding domain (Taz), plays crucial roles in micropyle formation and fertilization in zebrafish. Genome editing mutants affecting taz can grow to adults, however, eggs from homozygous taz females are not fertilized even though oocytes in mutant females are histologically normal with intact animal-vegetal polarity, complete meiosis and proper ovulation. However, taz mutant eggs have no micropyle. We show that Taz protein is specifically enriched from mid-oogenesis onwards in two follicle cells located at the animal pole of the oocyte, and co-localizes with the actin and tubulin cytoskeleton. Taz protein and micropylar cell are not detected in taz mutant ovaries. Our work identifies a novel role for the Hippo/Taz pathway in micropylar cell specification in zebrafish, and uncovers the molecular basis of micropyle formation in teleosts.

Cerebrovascular damages induce lymphatic invasion into brain parenchyma to guide vascular regeneration

Damage to regional brain vasculature and neuronal tissues occurs during acute cerebrovascular diseases, such as ischemic stroke. Promoting vascular regeneration is the most promising therapeutic approach. To understand cellular and molecular mechanisms underlying brain vascular regeneration, we developed two zebrafish cerebrovascular injury models using genetic ablation and photochemical thrombosis. Although brain parenchyma is physiologically devoid of lymphatic vasculature, we found that cerebrovascular injuries induce rapid ingrowth of meningeal lymphatics into the injured parenchyma. The ingrown lymphatics on one hand become lumenized to drain interstitial fluid to resolve brain oedema, on the other hand act as “growing tracks” for nascent blood vessels and produce Vegfa to promote the neoangiogenesis. The ingrown lymphatic vessels undergo apoptosis and clearance after cerebrovascular regeneration. This study reveals a pathological function of meningeal lymphatics, through previously unexpected ingrowth into brain parenchyma and a newly identified lymphatic function as vascular “growing tracks”.