青海湖鸟岛斑头雁种群对H5N1亚型禽流感病毒的免疫状况

斑头雁（Anser indicus）是2005年青海湖H5N1型高致病性禽流感的主要被感染物种。为了解斑头雁目前对H5N1亚型禽流感病毒(AIV)免疫状况,2008年春季,在青海湖鸟岛采集该种群弃卵（68枚）和巢卵（125枚）,以血凝抑制试验（HI）检测抗H5N1亚型禽流感病毒的卵黄母源抗体（IgY）。根据测试结果推断,在高致病性禽流感暴发3年后,青海湖鸟岛繁殖的斑头雁种群有26.5%～35.2%的繁殖对可能已经获得了对H5N1型禽流感病毒的免疫能力。另外,以斑头雁巢密度和抗体效价进行相关分析发现,斑头雁母源抗体水平与斑头雁巢密度正相关(r=0.736, P=0.000),表明高密度繁殖群内的母源抗体传递更具有适应性意义。     

云南产玉米须的化学成分研究

从玉米须60%乙醇提取液中分离得到了14个化合物,经波谱学方法分别鉴定为柯伊利素-7-O-β-D-葡萄糖苷(1)、柯伊利素-6-C-β-波伊文糖-7-O-β-葡萄糖苷(2)、柯伊利素-6-C-β-波伊文糖苷(3)、L-鼠李糖(4)、豆甾-4-烯-3β,6β-二醇(5)、7α-羟基谷甾醇(6)、7β-羟基谷甾醇(7)、胡萝卜苷棕榈酸酯(8)、大豆脑苷I(9)、7α-羟基谷甾醇-3-O-β-D-葡萄糖苷(10)、麦角甾-7,22-二烯-3β,5α,6β-三醇(11)、棕榈酸(12)、胡萝卜苷(13)和β-谷甾醇(14),其中化合物1、4和7～12为首次从玉米须中分离得到。     

Functional Characterization of PRKAR1A Mutations Reveals a Unique Molecular Mechanism Causing Acrodysostosis but Multiple Mechanisms Causing Carney Complex

The main target of cAMP is PKA, the main regulatory subunit of which (PRKAR1A) presents mutations in two genetic disorders: acrodysostosis and Carney complex. In addition to the initial recurrent mutation (R368X) of the PRKAR1A gene, several missense and nonsense mutations have been observed recently in acrodysostosis with hormonal resistance. These mutations are located in one of the two cAMP-binding domains of the protein, and their functional characterization is presented here. Expression of each of the PRKAR1A mutants results in a reduction of forskolin-induced PKA activation (measured by a reporter assay) and an impaired ability of cAMP to dissociate PRKAR1A from the catalytic PKA subunits by BRET assay. Modeling studies and sensitivity to cAMP analogs specific for domain A (8-piperidinoadenosine 3′,5′-cyclic monophosphate) or domain B (8-(6-aminohexyl)aminoadenosine-3′,5′-cyclic monophosphate) indicate that the mutations impair cAMP binding locally in the domain containing the mutation. Interestingly, two of these mutations affect amino acids for which alternative amino acid substitutions have been reported to cause the Carney complex phenotype. To decipher the molecular mechanism through which homologous substitutions can produce such strikingly different clinical phenotypes, we studied these mutations using the same approaches. Interestingly, the Carney mutants also demonstrated resistance to cAMP, but they expressed additional functional defects, including accelerated PRKAR1A protein degradation. These data demonstrate that a cAMP binding defect is the common molecular mechanism for resistance of PKA activation in acrodysosotosis and that several distinct mechanisms lead to constitutive PKA activation in Carney complex.     

Proteomic studies highlight outer‐membrane proteins related to biofilm development in the marine bacterium Pseudoalteromonas sp. D41

Bacterial biofilm development is conditioned by complex processes involving bacterial attachment to surfaces, growth, mobility, and exoproduct production. The marine bacterium Pseudoalteromonas sp. strain D41 is able to attach strongly onto a wide variety of substrates, which promotes subsequent biofilm development. Study of the outer‐membrane and total soluble proteomes showed ten spots with significant intensity variations when this bacterium was grown in biofilm compared to planktonic cultures. MS/MS de novo sequencing analysis allowed the identification of four outer‐membrane proteins of particular interest since they were strongly induced in biofilms. These proteins are homologous to a TonB‐dependent receptor (TBDR), to the OmpW and OmpA porins, and to a type IV pilus biogenesis protein (PilF). Gene expression assays by quantitative RT‐PCR showed that the four corresponding genes were upregulated during biofilm development on hydrophobic and hydrophilic surfaces. The Pseudomonas aeruginosa mutants unable to produce any of the OmpW, OmpA, and PilF homologues yielded biofilms with lower biovolumes and altered architectures, confirming the involvement of these proteins in the biofilm formation process. Our results indicate that Pseudoalteromonas sp. D41 shares biofilm formation mechanisms with human pathogenic bacteria, but also relies on TBDR, which might be more specific to the marine environment.     

First record of a spawning aggregation for the tropical eastern Pacific endemic grouper Mycteroperca olfax in the Galapagos Marine Reserve

This study provides direct and indirect evidence of temporally and spatially consistent spawning aggregations for the grouper Mycteroperca olfax. Recently reported declines in population numbers, probably related to the direct targeting of aggregations by artisanal fishermen, highlight the urgent need for species‐specific management actions in the Galapagos Marine Reserve, such as minimum and maximum landing sizes, and the importance of protecting key aggregation sites with the declaration of no‐take areas and the establishment of total fishing bans during the reproductive season.     

PIK3R1 Mutations Cause Syndromic Insulin Resistance with Lipoatrophy

Short stature, hyperextensibility of joints and/or inguinal hernia, ocular depression, Rieger anomaly, and teething delay (SHORT) syndrome is a developmental disorder with an unknown genetic cause and hallmarks that include insulin resistance and lack of subcutaneous fat. We ascertained two unrelated individuals with SHORT syndrome, hypothesized that the observed phenotype was most likely due to de novo mutations in the same gene, and performed whole-exome sequencing in the two probands and their unaffected parents. We then confirmed our initial observations in four other subjects with SHORT syndrome from three families, as well as 14 unrelated subjects presenting with syndromic insulin resistance and/or generalized lipoatrophy associated with dysmorphic features and growth retardation. Overall, we identified in nine affected individuals from eight families de novo or inherited PIK3R1 mutations, including a mutational hotspot (c.1945C>T [p.Arg649Trp]) present in four families. PIK3R1 encodes the p85α, p55α, and p50α regulatory subunits of class IA phosphatidylinositol 3 kinases (PI3Ks), which are known to play a key role in insulin signaling. Functional data from fibroblasts derived from individuals with PIK3R1 mutations showed severe insulin resistance for both proximal and distal PI3K-dependent signaling. Our findings extend the genetic causes of severe insulin-resistance syndromes and provide important information with respect to the function of PIK3R1 in normal development and its role in human diseases, including growth delay, Rieger anomaly and other ocular affections, insulin resistance, diabetes, paucity of fat, and ovarian cysts.     

From insulin receptor signalling to Glut 4 translocation abnormalities in obesity and insulin resistance

Insulin resistance is commonly associated with obesity in rodents. Using mice made obese with goldthioglucose (GTG-obese mice), we have shown that insulin resistance results from defects at the level of the receptor and from intracellular alterations in insulin signalling pathway, without major alteration in the number of the Glut 4 glucose transporter. Activation of phosphatidylinositol 3-kinase (PI 3-kinase) was found to be profoundly affected in response to insulin. This defect appears very early in the development of obesity, together with a marked decrease in IRS 1 tyrosine phosphorylation. In order to better understand the abnormalities in glucose transport in insulin resistance, we have studied the pathway leading from the insulin receptor kinase stimulation to the translocation of the Glut 4 containing vesicles. This stimulation involves the activation of PI 3-kinase, which in turns activates protein kinase B. We have then focussed at the mechanism of vesicle exocytosis, and more specifically at the role of the small GTPase Rab4 in this process. We have shown that Rab4 participates, first in the intracellular retention of the Glut 4 containing vesicles, second in the insulin signalling pathway leading to glucose transporter translocation.