siRNA干扰PDGF对新生儿血管瘤干细胞的增殖和分化的影响

婴儿血管瘤是一种血管瘤,表现出独特的快速生长的特征,然后随着时间而消退。血管瘤来自CD133+干细胞,当植入免疫缺陷小鼠时,它们分化成内皮细胞。同样克隆扩增的干细胞也产生脂肪细胞,从而重现血管瘤的消退期。本研究主要阐明了使用血管瘤来源的干细胞(hemSC)增殖和分化的内在机制。本研究发现血小板衍生生长因子(PDGF)在增殖期升高并可能抑制脂肪细胞分化。hemSC表达高水平的PDGF-b并且在基础(未刺激)条件下显示PDGF受体的持续酪氨酸磷酸化。PDGF受体信号传导的抑制导致hemSCs中的脂肪生成增强。此外,hemSCs暴露于外源性PDGF-b降低了脂肪含量和脂肪细胞特异性转录因子的表达。总之,本研究将PDGF信号传导鉴定为血管瘤退化的内在负调节因子,并强调了破坏PDGF信号传导治疗血管瘤的治疗潜力。     

Anti-idiotypic antiserum to monoclonal anti-Sm inhibits the autoantigen-induced proliferative response

Anti-idiotypic sera were produced in BALB/c mice against three established monoclonal anti-Sm antibodies. Inhibition assays showed that the anti-idiotypic antibodies recognized determinants that were present on all three monoclonal antibodies but not on normal mouse IgG from unimmunized BALB/c mice or myeloma proteins. Normal (+/+) and autoimmune (lpr/lpr) MRL/MpJ or C3H/HeJ mice were immunized with Sm in complete Freund's adjuvant. Immune T cells from the draining lymph nodes proliferated in response to the addition of Sm in vitro. Anti-idiotypic serum added to these cultures inhibited the proliferative response by 50 to 70%, whereas normal BALB/c serum had no effect. This inhibition of proliferation was antigen specific, because the anti-idiotypic serum did not inhibit the T cell proliferative response to an irrelevant antigen, TNP-KLH, or ovalbumin. Kinetic studies showed that the anti-idiotypic serum inhibited an early event in antigen-induced proliferative response, because the addition of serum late in culture did not cause any significant reduction in proliferation. The reduced proliferative response was due to direct action of the anti-idiotypic serum on the Lyt-1+, 2- T cell population.     

Theory of allosteric effects in serine proteases.

The classical Botts-Morales theory for the action of a modifier on the catalytic properties of an enzyme has been extended to deal with allosteric effects in serine proteases. The exact analytical solution derived for the linkage scheme at steady state provides a rigorous framework for the study of many biologically relevant systems, including enzymes activated by monovalent cations and cofactor-controlled protease-zymogen interactions in blood coagulation. When the enzyme obeys Michaelis-Menten kinetics, the exact solution of the kinetic linkage scheme simplifies considerably. Of particular importance for practical applications is a simple equation expressing the dependence of the specificity constant of the enzyme, kcat/Km, on the concentration of the modifier, from which the equilibrium binding constant for the formation of the enzyme-modifier complex can be estimated. Analysis of the allosteric changes in thrombin activity induced by thrombomodulin and Na+ in terms of this equation yields accurate determinations of the equilibrium binding constants for both effectors.     

Cleavage of PrePL by Lon promotes growth and pathogenesis in Magnaporthe oryzae

ATP-dependent Lon proteases function in bacterial pathogenesis by regulating the expression of the Type III secretion system; however, little is known about how Lon proteases regulate fungal pathogenesis. We previously investigated Lon-binding proteins involved in fungal pathogenesis that interact with PrePL, the smallest Magnaporthe oryzae Lon-binding protein. Here, we show that Lon cleaves PrePL and produces Pc, an extracellular 11-kDa isoform with catalase and peroxidase activity. The ΔPrePL loss-of-function strain showed stronger sporulation and accelerated disease development, suggesting a temporally specific negative regulatory mechanism controlled by PrePL in disease progression. Neither the truncated Pc, nor the full-length PrePL missing the Lon cleavage site complemented the ΔPrePL phenotype, suggesting that full-length PrePL and Pc both function in fungal development. PrePL targeted to the mitochondria undergoes hydrolysis by Lon to produce Pc, which accumulates in the fungal apoplast. Importantly, recombinant Pc induced plant defence responses and cell death after being infiltrated into selected plant leaves, indicating that it functions as an avirulence factor. This work thus reveals a novel pathogenic factor in the fungal Lon-mediated pathway. Additionally, our results provide new insight into the functions of a full-length protein and its cleaved isoform in fungal pathogenesis.     

Agnogene Deletion in a Novel Pathogenic JC Virus Isolate Impairs VP1 Expression and Virion Production

Infection of glial cells by the human polyomavirus JC (JCV) causes progressive multifocal leukoencephalopathy (PML). JCV Encephalopathy (JCVE) is a newly identified disease characterized by JCV infection of cortical pyramidal neurons. The virus JCV_CPN associated with JCVE contains a unique 143 base pair deletion in the agnogene. Contrary to most JCV brain isolates, JCV_CPN has an archetype-like regulatory region (RR) usually found in kidney strains. This provided us with the unique opportunity to determine for the first time how each of these regions contributed to the phenotype of JCV_CPN. We characterized the replication of JCV_CPN compared to the prototype virus JCV_Mad-1 in kidney, glial and neuronal cell lines. We found that JCV_CPN is capable of replicating viral DNA in all cell lines tested, but is unable to establish persistent infection seen with JCV_Mad-1. JCV_CPN does not have an increased ability to replicate in the neuronal cell line tested. To determine whether this phenotype results from the archetype-like RR or the agnogene deletion, we generated chimeric viruses between JCV_CPN of JCV_Mad-1. We found that the deletion in the agnogene is the predominant cause of the inability of the virus to maintain a persistent infection, with the introduction of a full length agnogene, either with or without agnoprotein expression, rescues the replication of JCV_CPN. Studying this naturally occurring pathogenic variant of JCV provides a valuable tool for understanding the functions of the agnogene and RR form in JCV replication.