盐度对卵形鲳鲹幼鱼渗透压调节和饥饿失重的影响

为探讨盐度对卵形鲳鲹(Trachinotus ovatus)渗透压调节的影响,研究了深水网箱养殖的卵形鲳鲹幼鱼鳃Na+-K+-ATP酶(NKA)活性,血浆、鳃和肾渗透压以及饥饿失重在盐度渐变条件下的反应。实验设5个盐度梯度组,分别为5、15、25、30和35。结果显示,鳃NKA活性除盐度15外都呈先下降后升高随之回落并趋于稳定的趋势,在2 d后的各时间节点随盐度变化呈"U"型分布;血浆渗透压在相同盐度下随时间延长呈先升高后下降再升高随后回落并趋于稳定,2 d后在各时间节点与盐度呈正相关关系,盐度30和35组的血浆渗透压显著高于其它盐度组(P0.05);肾脏对盐度变化的渗透调节比鳃敏感,在低盐度时(30以下),鰓和肾共同完成对渗透压的调节,在较高盐度(30以上),肾对渗透压的调节起主导作用。盐度变化对卵形鲳鲹的饥饿失重率有极显著的影响。研究表明,卵形鲳鲹幼鱼对盐度的渗透调节能力较强,在盐度5—35范围内的盐度变化均能适应,一般在1—2 d内可达到稳定,且更适于在低盐度水环境中生活。     

Structural Insights into the C1q Domain of Caprin-2 in Canonical Wnt Signaling

Previously, we have identified Caprin-2 as a new regulator in canonical Wnt signaling through a mechanism of facilitating LRP5/6 phosphorylation; moreover, we found that its C-terminal C1q-related domain (Cap2_CRD) is required for this process. Here, we determined the crystal structures of Cap2_CRD from human and zebrafish, which both associate as a homotrimer with calcium located at the symmetric center. Surprisingly, the calcium binding-deficient mutant exists as a more stable trimer than its wild-type counterpart. Further studies showed that this Caprin-2 mutant disabled in binding calcium maintains the activity of promoting LRP5/6 phosphorylation, whereas the mutations disrupting Cap2_CRD homotrimer did impair such activity. Together, our findings suggested that the C-terminal CRD domain of Caprin-2 forms a flexible homotrimer mediated by calcium and that such trimeric assembly is required for Caprin-2 to regulate canonical Wnt signaling.     

The Short N-terminal Domains of STIM1 and STIM2 Control the Activation Kinetics of Orai1 Channels

STIM1 and STIM2 are dynamic transmembrane endoplasmic reticulum Ca²⁺ sensors, coupling directly to activate plasma membrane Orai Ca²⁺ entry channels. Despite extensive sequence homology, the STIM proteins are functionally distinct. We reveal that the short variable N-terminal random coil sequences of STIM1 and STIM2 confer profoundly different activation properties. Using Orai1-expressing HEK293 cells, chimeric replacement of the 43-amino-acid STIM1 N terminus with that of STIM2 attenuates Orai1-mediated Ca²⁺ entry and drastically slows store-induced Orai1 channel activation. Conversely, the 55-amino-acid STIM2 terminus substituted within STIM1 strikingly enhances both Orai1-mediated Ca²⁺ entry and constitutive coupling to activate Orai1 channels. Hence, STIM N termini are powerful coupling modifiers, functioning in STIM2 to “brake” the otherwise constitutive activation of Orai1 channels afforded by its high sensitivity to luminal Ca²⁺.The transmembrane ER⁴ proteins STIM1 and STIM2 function as sensors of Ca²⁺ within ER stores (1, 2). Depletion of luminal Ca²⁺ within the ER triggers aggregation and translocation of STIMs into junctions closely associated with the plasma membrane, where they activate the highly Ca²⁺-selective Orai family of store-operated channels (SOCs) via conformational coupling (3–8). Recent investigations of the cytoplasmic portion of STIM1 revealed that it alone is sufficient to activate Orai (9–12) via a short (∼100 amino acids) region centered around the second coiled-coil domain (see Fig. 1) (13–15). However, although activation of Orai1 is mediated entirely within the C-terminal portion of STIM, physiological control of STIM1 and STIM2 is exerted via their N-terminal ER-luminal Ca²⁺-sensing domains. The extent to which structural differences between these domains in STIM1 and STIM2 contribute to their distinct properties (16–19) remains poorly understood. Although STIM2 has the capacity to sense ER Ca²⁺ and activate SOCs (16, 17, 19), overexpressed STIM2 inhibits endogenous SOCs (18). Moreover, the kinetics of SOC activation by STIM2 are much slower than STIM1 (17). STIM2 was recently revealed to have a decreased Ca²⁺-sensing affinity when compared with STIM1 by virtue of three amino acid substitutions in the Ca²⁺-binding EF-hand domain (16). Although the lower affinity of the STIM2 EF-hand accounts for differences in the activation thresholds of STIM1 and STIM2 (16, 20, 21), it does not explain the slow kinetics of STIM2 nor its dominance over endogenous SOC activation. However, recent investigations reveal similar abilities of the cytosolic portions of STIM1 and STIM2 to activate Orai1 (12). Hence, although activation of Orai1 is mediated entirely within the C-terminal portion of STIM, physiological control of STIM1 and STIM2 is exerted via their N-terminal ER-luminal Ca²⁺-sensing domains.Open in a separate windowFIGURE 1.Schematic diagram depicting the domain structure of STIM1, STIM2, and STIM chimeras. The currently defined domains of STIM1 and STIM2 are depicted as canonical (cEF) and hidden (hEF) EF-hands, SAM domains, transmembrane domains (TM), coiled-coil structures, a proline-rich domain (P), and a polybasic tail (K). The sequences of the STIM1 and STIM2 N-terminal domains were aligned using the lalign program and depicted with red indicating identical amino acids and blue indicating similarity.The initial triggering events for STIM1 and STIM2 proteins involve the unfolding and aggregation of the N-terminal domains resulting from dissociation of Ca²⁺ from the luminal EF-hand Ca²⁺ binding domains (20–23). Recent evidence reveals that this unfolding is much slower for the N terminus of STIM2 than for STIM1 (21). Although most of the N termini of STIM1 and STIM2 are highly homologous, significant variability exists in the first 60 N-terminal amino acids upstream from the EF-hands, comprising a flexible random coil domain (21). Intriguingly, these upstream sequences appear to markedly modify the stability of the N-terminal domains of STIM1 and STIM2 (21). We reveal here that these sequences confer profound distinctions between STIM1 and STIM2 in their coupling to activate SOCs. In STIM2, this domain acts as a powerful “brake” to restrict constitutive activation of SOCs, occurring as a result of its high sensitivity to luminal Ca²⁺.     

The involvement of sortase A in high virulence of STSS-causing Streptococcus suis serotype 2

Sortase A (SrtA), originally identified as a transpeptidase in Staphylococcus aureus, plays key roles in full virulence of pathogenic bacteria. In silico genome-wide search suggested a srtA homologue from 05ZYH33, a Chinese human isolate of streptococcal toxic shock syndrome (STSS)-causing Streptococcus suis serotype 2 (S. suis 2, SS2). An isogenic srtA mutant (ΔsrtA) of 05ZYH33 strain was obtained by homologous recombination. Immunofluorescence analysis revealed that two known virulence-associated surface proteins featuring Leu-Pro-X-Thr-Gly motif, muramidase-released protein and surface antigen one, were absent in the ΔsrtA. Piglet infection experiments showed that deletion of srtA attenuated the full virulence of 05ZYH33 strain, and impaired its colonizing potential in specific organs. Furthermore, the ΔsrtA displayed significant reduction in adherence to human cells (Hep-2 and human umbilical vein endothelial cells). Collectively, we concluded that SrtA was involved in the virulence manifestation of STSS-causing SS2. Jiaqi Tang, Changjun Wang designed the study; Changjun Wang, Feng Zheng, Ming Li, Youjun Feng, Yaqing Dong, Gong Cheng, Jing Wang, Dan Hu, Xiaodan Feng, Fuquan Hu, and Junchao Ge performed the experiments; Changjun Wang, Ming Li, Youjun Feng, Feng Zheng, Yaqing Dong, Gong Cheng, Xiuzhen Pan, Di Liu, and Min Cao analyzed the data; Changjun Wang, Jiaqi Tang, Youjun Feng, and Ming Li wrote the paper.     

STIM and Orai: Dynamic Intermembrane Coupling to Control Cellular Calcium Signals

Ca²⁺ signals controlling a vast array of cell functions involve both Ca²⁺ store release and external Ca²⁺ entry. These two events are coordinated through a dynamic intermembrane coupling between two distinct membrane proteins, STIM and Orai. STIM proteins are endoplasmic reticulum (ER) luminal Ca²⁺ sensors that undergo a profound redistribution into discrete junctional ER domains closely juxtaposed with the plasma membrane (PM). Orai proteins are PM Ca²⁺ channels that migrate and become tethered by STIM within the ER-PM junctions, where they mediate exceedingly selective Ca²⁺ entry. We describe a new understanding of the nature of the proteins and how they function to mediate this remarkable intermembrane signaling process controlling Ca²⁺ signals.     

Validated hydrophilic interaction LC-MS/MS method for determination of N-methyl-2-pyrrolidinone residue: Applied to a depletion study of N-methyl-2-pyrrolidinone in swine liver following intramuscular administration of drug N-methyl-2-pyrrolidinone formulation

A hydrophilic interaction high-performance liquid chromatography coupled with tandem mass spectrometry method for determination of N-methyl-2-pyrrolidinone in swine liver was developed and validated. After the fortification of N-methyl-d(3)-2-pyrrolidinone-d(6) as the deuterium-labeled internal standard, N-methyl-2-pyrrolidinone in swine liver was extracted by acetonitrile and the supernatant was led through a C18+WAX mixed-mode SPE cartridge for removal of the matrix interferences. The final eluate was acidified by formic acid and then injected onto a 3μm 15cm×2.1mm TX column for hydrophilic interaction chromatographic analysis. Mass spectrometry detection was carried on a PE Sciex API 4000 triple quadrupole mass spectrometer using positive turbo-ion spray ionization mode. The MRM transitions were 100→58 for N-methyl-2-pyrrolidinone and 109→62 for N-methyl-d(3)-2-pyrrolidinone-d(6). Solvent calibration standards could be readily used for quantitative analysis of N-methyl-2-pyrrolidinone with excellent precision and accuracy, although there are endogenous levels of N-methyl-2-pyrrolidinone in many blank matrices. The true recovery was nearly 100% and the MRM signal of N-methyl-2-pyrrolidinone was suppressed about 30% because of the matrix effect. Nevertheless, N-methyl-d(3)-2-pyrrolidinone-d(6) completely compensated the ion-suppression effect and the injection-to-injection variation. The detection limit was 5ngg(-1) swine liver. The validated method was applied to a depletion study of N-methyl-2-pyrrolidinone in swine liver following intramuscular administration of a drug N-methyl-2-pyrrolidinone formulation.     

Dimerization of CPAP Orchestrates Centrosome Cohesion Plasticity

Centrosome cohesion and segregation are accurately regulated to prevent an aberrant separation of duplicated centrosomes and to ensure the correct formation of bipolar spindles by a tight coupling with cell cycle machinery. CPAP is a centrosome protein with five coiled-coil domains and plays an important role in the control of brain size in autosomal recessive primary microcephaly. Previous studies showed that CPAP interacts with tubulin and controls centriole length. Here, we reported that CPAP forms a homodimer during interphase, and the fifth coiled-coil domain of CPAP is required for its dimerization. Moreover, this self-interaction is required for maintaining centrosome cohesion and preventing the centrosome from splitting before the G₂/M phase. Our biochemical studies show that CPAP forms homodimers in vivo. In addition, both monomeric and dimeric CPAP are required for accurate cell division, suggesting that the temporal dynamics of CPAP homodimerization is tightly regulated during the cell cycle. Significantly, our results provide evidence that CPAP is phosphorylated during mitosis, and this phosphorylation releases its intermolecular interaction. Taken together, these results suggest that cell cycle-regulated phosphorylation orchestrates the dynamics of CPAP molecular interaction and centrosome splitting to ensure genomic stability in cell division.     

Anti‐inflammatory function of Withangulatin A by targeted inhibiting COX‐2 expression via MAPK and NF‐κB pathways

Withangulatin A (WA), an active component isolated from Physalis angulata L., has been reported to possess anti‐tumor and trypanocidal activities in model systems via multiple biochemical mechanisms. The aim of this study is to investigate its anti‐inflammatory potential and the possible underlying mechanisms. In the current study, WA significantly suppressed mice T lymphocytes proliferation stimulated with LPS in a dose‐ and time‐dependent manner and inhibited pro‐inflammation cytokines (IL‐2, IFN‐γ, and IL‐6) dramatically. Moreover, WA targeted inhibited COX‐2 expression mediated by MAPKs and NF‐κB nuclear translocation pathways in mice T lymphocytes, and this result was further confirmed by the COX‐1/2 luciferase reporter assay. Intriguingly, administration of WA inhibited the extent of mice ear swelling and decreased pro‐inflammatory cytokines production in mice blood serum. Based on these evidences, WA influences the mice T lymphocytes function through targeted inhibiting COX‐2 expression via MAPKs and NF‐κB nuclear translocation signaling pathways, and this would make WA a strong candidate for further study as an anti‐inflammatory agent. J. Cell. Biochem. 109: 532–541, 2010. © 2009 Wiley‐Liss, Inc.     

Synthesis and antifungal activities in vitro of novel pyrazino [2,1-a] isoquinolin derivatives

A series of novel pyrazino[2,1-a]isoquinolin compounds were designed and synthesized, and their antifungal activities in vitro were evaluated. The results showed that all of the compounds exhibited antifungal activities. Some of them exhibited stronger antifungal activities than that of lead compounds and among them compound 11b was the most potent one, which showed more potent than that of the active control fluconazole to the four of the five tested fungi. The studies presented here provide a new structural type for the development of novel antifungal agents.