为害黄芪种子的广肩种子小蜂属四新种(膜翅目:广肩小蜂科)

据我们在北京和内蒙古等地多年研究表明,黄芪的植食性种子小蜂包括广肩小蜂科Bruchophagus属5种和金小蜂科Habrocytus属1种,为多种混合群体。我们通过大量标本的形态比较以及交配行为的观察,结合其生物学特性研究以及应用扫描电镜对其并胸腹节花纹的超微结构观察,鉴定出黄芪种子里有5种广肩种子小蜂,即黄芪种子小蜂Bruchophagus huonchi Liao et Fan及本文的4新种。     

^137Cs,^134Cs在人工海洋小生境中的行为

在自行建立的人工海洋小生境中,采用示踪法综合地研究~(137)Cs、~(134)Cs在人工小生境中的行为。结果表明,~(137)Cs和~(134)Cs具有共同的生理生态行为,并表现出相似的规律、沉积物对~(137)Cs、~(134)Cs的吸附能力甚低,~(137)Cs、~(134)Cs在海洋动物体内趋于全身性的分布。各主要生化物质均能检出~(137)Cs、~(134)Cs。排泄实验后,海洋动物的胃肠、肝(消化腺)~(137)Cs、~(134)Cs损失显著。沉积物表现为解吸-重吸附的过程。     

包囊游仆虫包囊形成和解脱过程中纤毛器的分化

包囊游仆虫(Euplotes encysticus)形成包囊时,各类纤毛器中的纤毛杆被部分地或全部地吸收,毛基体被保留下来。休眠包囊中,背纤毛器的定位无明显变化,但原腹面纤毛器中的口围带和波动膜、额腹棘毛和横棘毛,以及左、右尾棘毛都按序陷入在细胞质内深处,并相互汇聚在一起。脱包囊时,纤毛结构在原毛基体上再分化,新纤毛器按口围带、横棘毛、额腹棘毛和左、右尾棘毛的顺序从细胞内显露出来。     

中华绒螯蟹血淋巴20-羟蜕皮酮诱发蜕皮和卵巢发育的作用

通过放射免疫法测定了中华绒螯蟹蜕皮周期血淋巴20-羟蜕皮酮(20-HE)含量的变化。血淋巴20-HE同卵母细胞发育各个阶段有密切的时相关系:在卵母细胞小生长期血淋巴20-HE持续上升,经青春蜕皮进入卵母细胞大生长期后又迅速降低。不能及时青春蜕皮的青春期前雌蟹,稍后仍出现20-HE下降的趋势。对不同实验条件和生理状态下雌蟹的比较表明,20-HE具有诱发蜕皮的特性。卵母细胞早期生长必需高浓度的血淋巴20-HE。外源注射的20-HE有刺激卵巢增重的作用。     

Biosynthesis of Prostacyclin in Rat Cerebral Microvessels and the Choroid Plexus

Abstract: Microvessels, predominantly capillaries, were isolated from rat cerebrum by a modification of published procedures. The morphology and purity of the preparations were monitored by light and electron microscopy and by enrichment in alkaline phosphatase, γ-glutamyl transpeptidase, and prostacyclin synthetase. A reversed-phase high-pressure liquid chromatographic method was used in the purification of prostaglandins after extraction from aqueous incubation solutions. Prostacyclin synthesis in brain is localized in cerebral blood vessels and capillaries. The endogenous biosynthetic capacity of the isolated cerebral capillary fractions for prostacyclin, measured as its chemically stable breakdown product, 6-keto-prostaglandin F_1α, was 11 ng/mg protein/10 min. Choroid plexus and intact surface vessels synthesized 6-keto-prostaglandin F_1α at 37 and 35 ng/mg protein/10 min, respectively. The prostacyclin-synthesizing enzyme of the cerebral capillaries also converted the exogenously added prostaglandin endoperoxides to 6-keto-prostaglandin F_1α. Comparison of the synthesis of prostaglandins 6-keto-F_1α, E₂, and F_2α showed that 6-keto-prostaglandin F_1α was the major prostaglandin formed in the microvessels, in the larger surface vessels, and in the choroid plexus. Prostaglandin D₂ was not detected. Prostacyclin synthesis by the cerebral vasculature is similar to that in other blood vessels and cultured human endothelial cells. Possible physiological roles of prostacyclin in the cerebral microvasculature are discussed with special regard to the autoregulation of cerebral blood flow.     

Urinary excretion of a novel hexasaccharide and glycopeptide analogue in fucosidosis.

Repeated Biogel P6 chromatography of the urine from a patient with fucosidosis yielded several fractions containing fucosyloligosaccharides and glycopeptides. Two of these were shown by ¹H nuclear magnetic resonance (¹H-n.m.r.) spectroscopy and permethylation analysis to have the following structures respectively: (I) αfuc (1→3) [βgal (1→4)] βglcNAc (1→2) αman ($\text{1→}\text{3}\text{6}$) βman (1→4) glcNAc and (II) αfuc (1→3) [βgal (1→4)] βglcNAc (1→2) αman ($\text{1→}\text{3}\text{6}$) βman (1→4) βglcNAc (1→4) [αfuc ($\text{1→}\text{3}\text{6}$)] βglcNAc-Asn.     

ZAKβ antagonizes and ameliorates the cardiac hypertrophic and apoptotic effects induced by ZAKα

ZAK (sterile alpha motif and leucine zipper containing kinase AZK), a serine/threonine kinase with multiple biochemical functions, has been associated with various cell processes, including cell proliferation, cell differentiation, and cardiac hypertrophy. In our previous reports, we found that the activation of ZAKα signaling was critical for cardiac hypertrophy. In this study, we show that the expression of ZAKα activated apoptosis through both a FAS‐dependent pathway and a mitochondria‐dependent pathway by subsequently inducing caspase‐3. ZAKβ, an isoform of ZAKα, is dramatically expressed during cardiac hypertrophy and apoptosis. The interaction between ZAKα and ZAKβ was demonstrated here using immunoprecipitation. The results show that ZAKβ has the ability to diminish the expression level of ZAKα. These findings reveal an inherent regulatory role of ZAKβ to antagonize ZAKα and to subsequently downregulate the cardiac hypertrophy and apoptosis induced by ZAKα.