Lactobacillus casei-01 Facilitates the Ameliorative Effects of Proanthocyanidins Extracted from Lotus Seedpod on Learning and Memory Impairment in Scopolamine-Induced Amnesia Mice

Learning and memory abilities are associated with alterations in gut function. The two-way proanthocyanidins-microbiota interaction in vivo enhances the physiological activities of proanthocyanidins and promotes the regulation of gut function. Proanthocyanidins extracted from lotus seedpod (LSPC) have shown the memory-enhancing ability. However, there has been no literature about whether Lactobacillus casei-01 (LC) enhances the ameliorative effects of LSPC on learning and memory abilities. In this study, learning and memory abilities of scopolamine-induced amnesia mice were evaluated by Y-maze test after 20-day administration of LC (10⁹ cfu/kg body weight (BW)), LSPC (low dose was 60 mg/kg BW (L-LSPC) and high dose was 90 mg/kg BW (H-LSPC)), or LSPC and LC combinations (L-LSPC+LC and H-LSPC+LC). Alterations in antioxidant defense ability and oxidative damage of brain, serum and colon, and brain cholinergic system were investigated as the possible mechanisms. As a result, the error times of H-LSPC+LC group were reduced by 41.59% and 68.75% relative to those of H-LSPC and LC groups respectively. LSPC and LC combinations ameliorated scopolamine-induced memory impairment by improving total antioxidant capacity (TAOC) level, glutathione peroxidase (GSH-Px) and total superoxide dismutase (T-SOD) activities of brain, serum and colon, suppressing malondialdehyde (MDA) level of brain, serum and colon, and inhibiting brain acetylcholinesterase (AchE), myeloperoxidase, total nitric oxide synthase and neural nitric oxide synthase (nNOS) activities, and nNOS mRNA level. Moreover, LC facilitated the ameliorative effects of H-LSPC on GSH-Px activity of colon, TAOC level, GSH-Px activity and ratio of T-SOD to MDA of brain and serum, and the inhibitory effects of H-LSPC on serum MDA level, brain nNOS mRNA level and AchE activity. These results indicated that LC promoted the memory-enhancing effect of LSPC in scopolamine-induced amnesia mice.     

从胚胎干细胞到视网膜

视网膜退行性病变影响着全世界数百万人。然而,视网膜是人体再生能力很差的一类组织,成年机体无法自我更新那些病变中丢失的视网膜细胞,导致视网膜退行性病变的不可逆性。因此,恢复患者视觉将依赖于引入外源细胞替代丢失的视网膜神经元。胚胎干细胞（ES细胞）具有无限的自我更新能力和形成机体所有类型细胞的巨大分化潜力。这两个特性使得ES细胞成为细胞替代疗法的理想供体细胞。近年来,人们在探索将ES和诱导多能干细胞（iPS细胞）体外定向诱导分化为视网膜神经元,甚至整个视网膜方面已取得多项进展,并且体外形成的视网膜细胞可以与宿主视网膜整合。在此篇综述中,首先简要概括哺乳动物视网膜的组织结构、发育过程和调控机制,然后,重点阐述近年来科研工作者探索ES/iPS细胞体外诱导分化为视网膜细胞和组织的研究进展。     

Molecular Cloning and Expression Analysis of the Starch-branching Enzyme III Gene from Common Wheat (Triticum aestivum )

The starch-branching enzyme (SBE) catalyzes the formation of branch points by cleaving the α-1,4 linkage in polyglucans and reattaching the chain via an α-1,6 linkage. Three types of SBE isoforms (SBEI, SBEII, and SBEIII) exist in higher plants, with the number of SBE isoforms being species-specific. This study isolated the SBEIII cDNA sequence (3,780 bp), designated TaSBEIII (accession no. JQ346193), from common wheat (Triticum aestivum L.) using the RACE method, revealing that the SBEIII gene exists in common wheat. The open reading frame of TaSBEIII was 2,748 bp. The predicted protein of 916 amino acids contained the specific characteristics of the SBEIII protein: four highly conserved regions and a central (α/β)₈ barrel domain. The SBE activity of the protein expressed in Escherichia coli (BL21) was also measured and verified. During the wheat grain filling period, TaSBEIII was constitutively expressed. The role of the TaSBEIII gene in starch synthesis is discussed.     

Expression of Mutant α1 Na/K-ATPase Defective in Conformational Transition Attenuates Src-mediated Signal Transduction

The α1 Na/K-ATPase possesses both pumping and signaling functions. Using purified enzyme we found that the α1 Na/K-ATPase might interact with and regulate Src activity in a conformation-dependent manner. Here we further explored the importance of the conformational transition capability of α1 Na/K-ATPase in regulation of Src-related signal transduction in cell culture. We first rescued the α1-knockdown cells by wild-type rat α1 or α1 mutants (I279A and F286A) that are known to be defective in conformational transition. Stable cell lines with comparable expression of wild type α1, I279A, and F286A were characterized. As expected, the defects in conformation transition resulted in comparable degree of inhibition of pumping activity in the mutant-rescued cell lines. However, I279A was more effective in inhibiting basal Src activity than either the wild-type or the F286A. Although much higher ouabain concentration was required to stimulate Src in I279A-rescued cells, extracellular K⁺ was comparably effective in regulating Src in both control and I279A cells. In contrast, ouabain and extracellular K⁺ failed to produce detectable changes in Src activity in F286A-rescued cells. Furthermore, expression of either mutant inhibited integrin-induced activation of Src/FAK pathways and slowed cell spreading processes. Finally, the expression of these mutants inhibited cell growth, with I279A being more potent than that of F286A. Taken together, the new findings suggest that the α1 Na/K-ATPase may be a key player in dynamic regulation of cellular Src activity and that the capability of normal conformation transition is essential for both pumping and signaling functions of α1 Na/K-ATPase.     

Phosphoenolpyruvate Carboxykinase 1 Gene (Pck1) Displays Parallel Evolution between Old World and New World Fruit Bats

Bats are an ideal mammalian group for exploring adaptations to fasting due to their large variety of diets and because fasting is a regular part of their life cycle. Mammals fed on a carbohydrate-rich diet experience a rapid decrease in blood glucose levels during a fast, thus, the development of mechanisms to resist the consequences of regular fasts, experienced on a daily basis, must have been crucial in the evolution of frugivorous bats. Phosphoenolpyruvate carboxykinase 1 (PEPCK1, encoded by the Pck1 gene) is the rate-limiting enzyme in gluconeogenesis and is largely responsible for the maintenance of glucose homeostasis during fasting in fruit-eating bats. To test whether Pck1 has experienced adaptive evolution in frugivorous bats, we obtained Pck1 coding sequence from 20 species of bats, including five Old World fruit bats (OWFBs) (Pteropodidae) and two New World fruit bats (NWFBs) (Phyllostomidae). Our molecular evolutionary analyses of these sequences revealed that Pck1 was under purifying selection in both Old World and New World fruit bats with no evidence of positive selection detected in either ancestral branch leading to fruit bats. Interestingly, however, six specific amino acid substitutions were detected on the ancestral lineage of OWFBs. In addition, we found considerable evidence for parallel evolution, at the amino acid level, between the PEPCK1 sequences of Old World fruit bats and New World fruit bats. Test for parallel evolution showed that four parallel substitutions (Q276R, R503H, I558V and Q593R) were driven by natural selection. Our study provides evidence that Pck1 underwent parallel evolution between Old World and New World fruit bats, two lineages of mammals that feed on a carbohydrate-rich diet and experience regular periods of fasting as part of their life cycle.     

吸氢对大鼠颅脑损伤引起的急性炎症反应的抑制作用

为了探讨吸氢对大鼠创伤性颅脑损伤（traumatic brain injury,TBI）急性期炎症反应的影响,将6周龄雄性SD大鼠随机分为假手术组、TBI组和吸氢治疗组。采用悬浮芯片技术检测TBI后2、6和24 h的血清细胞因子水平;TBI后24 h采用改良的神经功能缺失评分法（modified neurological severity score,mNss）评估吸氢的神经保护作用,同时取脑组织进行尼氏染色分析并对血清生化指标进行检测。神经功能评分表明,TBI大鼠吸氢后24 h内神经功能就有显著改善,尼氏染色进一步验证了吸氢对神经元的保护作用;血清细胞因子的检测表明,吸氢对TBI引起的急性炎症反应具有很好的抑制作用,表现为7种促炎因子的血清水平在TBI后2 h明显降低。此外,吸氢还可明显降低血清中心脏和肝脏标志物水平,提示吸氢对TBI急性期心脏和肝脏功能损伤具有保护作用。研究提示吸氢可能通过抑制TBI急性期的炎症反应发挥其神经保护作用。     

Involvement of Polypyrimidine Tract-Binding Protein (PTB)-Related Proteins in Pollen Germination in Arabidopsis

The pollen grains of most angiosperms contain stores of RNAsand their translation products required for pollen germinationand subsequent early elongation of pollen tubes. Polypyrimidinetract-binding protein (PTB), which is involved in the regulationof pre-mRNA alternative splicing, internal ribosomal entry site(IRES)-mediated translation and mRNA localization/sorting, isknown to act as a bridging molecule between RNAs and a varietyof cellular factors to fulfill cellular functions in both thenucleus and cytoplasm. Moreover, it has been reported that PTBplays roles in the differentiation and development of animalcells and tissues. In the Arabidopsis genome, there are twoPTB-related genes, tentatively termed AtPTB1 and AtPTB2. Inthe present study, the physiological functions of AtPTBs wereinvestigated using genetic and cytological approaches. The AtPTBpromoter was highly active in vegetative cells of mature pollengrains, and AtPTB was localized in the nucleus and cytoplasmof these vegetative cells. Mutations in the AtPTB genes resultedin decreased germination efficiency, and this effect was rescuedby introduction of the AtPTB2 promoter::AtPTB2–GFP. Takentogether, these findings suggest that AtPTB is involved in pollengermination through possible RNA metabolism processes in late-maturingand mature pollen grains.     

Progressive pseudogenization: vitamin C synthesis and its loss in bats

For the past 50 years, it was believed that all bats, like humans and guinea pigs, did not synthesize vitamin C (Vc) because they lacked activity of L-gulonolactone oxidase (GULO) in their livers. Humans and guinea pigs lack the activity due to pseudogenization of GULO in their genomes, but there is no genetic evidence to show whether such loss in bats is caused by pseudogenization. Unexpectedly, our successful molecular cloning in one frugivorous bat (Rousettus leschenaultii) and one insectivorous bat (Hipposideros armiger) ascertains that no pseudogenization occurs in these species. Furthermore, we find normal GULO protein expression using bat-specific anti-GULO polyclonal antibodies in bats, evaluated by Western blotting. Most surprisingly, GULO activity assays reveal that these two bat species have retained the ability to synthesize Vc, but at low levels compared with the mouse. It is known that bats in the genus Pteropus have lost GULO activity. We then found that functional constraints acting on the GULO of Pteropus vampyrus (which lost its function) are relaxed. These results imply that the ability to synthesize Vc in bats has not been lost completely in species as previously thought. We also suggest that the evolution of bat GULO genes can be a good model to study genetic processes associated with loss-of-function.