砀山酥梨不同程度缺铁叶片生长素抑制蛋白基因表达分析

以‘砀山酥梨’为材料,采用酶联免疫分析法(ELISA),测定叶片中内源IAA的含量.依据已构建的缺铁叶片SSH文库中生长素抑制蛋白(ARP)基因片段的序列信息,应用RACE技术克隆其cDNA全长,通过实时荧光定量(qRT-PCR)技术,分析ARP基因的相对表达量.结果表明:(1)ARP基因cDNA全长为707 bp,其中开放阅读框为351 bp,编码116个氨基酸,推测的蛋白质分子量为12.82 kD;该蛋白可能定位于微体,属于非分泌型、非跨膜蛋白类,并具有ARP基因家族的保守结构域.(2)在不同程度缺铁叶片中ARP基因的表达量存在差异,随着缺铁程度的增加,表达量显著升高,同时叶片中内源IAA含量逐渐降低.据此推测,ARP基因可能负反馈调节缺铁黄化叶片中IAA的水平,从而调控叶片的生长发育.     

A Novel Acidic Matrix Protein,PfN44, Stabilizes Magnesium Calcite to Inhibit the Crystallization of Aragonite

Magnesium is widely used to control calcium carbonate deposition in the shell of pearl oysters. Matrix proteins in the shell are responsible for nucleation and growth of calcium carbonate crystals. However, there is no direct evidence supporting a connection between matrix proteins and magnesium. Here, we identified a novel acidic matrix protein named PfN44 that affected aragonite formation in the shell of the pearl oyster Pinctada fucata. Using immunogold labeling assays, we found PfN44 in both the nacreous and prismatic layers. In shell repair, PfN44 was repressed, whereas other matrix proteins were up-regulated. Disturbing the function of PfN44 by RNAi led to the deposition of porous nacreous tablets with overgrowth of crystals in the nacreous layer. By in vitro circular dichroism spectra and fluorescence quenching, we found that PfN44 bound to both calcium and magnesium with a stronger affinity for magnesium. During in vitro calcium carbonate crystallization and calcification of amorphous calcium carbonate, PfN44 regulated the magnesium content of crystalline carbonate polymorphs and stabilized magnesium calcite to inhibit aragonite deposition. Taken together, our results suggested that by stabilizing magnesium calcite to inhibit aragonite deposition, PfN44 participated in P. fucata shell formation. These observations extend our understanding of the connections between matrix proteins and magnesium.     

Engineered Thermoplasma acidophilum factor F3 mimics human aminopeptidase N (APN) as a target for anticancer drug development

Human aminopeptidase N (hAPN) is an appealing objective for the development of anti-cancer agents. The absence of mammalian APN experimental structure negatively impinges upon the progression of structure-based drug design. Tricorn interacting factor F3 (factor F3) from Thermoplasma acidophilum shares 33% sequence identity with hAPN. Engineered factor F3 with two point directed mutations resulted in a protein with an active site identical to hAPN. In the present work, the engineered factor F3 has been co-crystallized with compound D24, a potent APN inhibitor introduced by our lab. Such a holo-form experimental structure helpfully insinuates a more bulky pocket than Bestatin-bound Escherichia coli APN. This evidence discloses that compound D24 targetting the structure of E. coli APN cannot bind to the activity cleft of factor F3 with high affinity. Thus, there is a potential risk of inefficiency to design hAPN targeting drug while using E. coli APN as the target model. We do propose here now that engineered factor F3 can be employed as a reasonable alternative of hAPN for drug design and development.     

Determination of Zygosity in Adult Chinese Twins Using the 450K Methylation Array versus Questionnaire Data

Previous studies have shown that both single nucleotide polymorphisms (SNPs) and questionnaires-based method can be used for twin zygosity determination, but few validation studies have been conducted using Chinese populations. In the current study, we recruited 192 same sex Chinese adult twin pairs to evaluate the validity of using genetic markers-based method and questionnaire-based method in zygosity determination. We considered the relatedness analysis based on more than 0.6 million SNPs genotyping as the golden standards for zygosity determination. After quality control, qualified twins were left for relatedness analysis based on identical by descent calculation. Then those same sex twin pairs were included in the zygosity questionnaire validation analysis. Logistic regression model was applied to assess the discriminant ability of age, sex and the three questions in zygosity determination. Leave one out cross-validation was used as a measurement of internal validation. The results of zygosity determination based on 65 SNPs in 450k methylation array were all consistent with genotyping. Age, gender, questions of appearance confused by strangers and previously perceived zygosity consisted of the most predictable model with a consistency rate of 0.8698, cross validation predictive error of 0.1347. For twin studies with genotyping and\or 450k methylation array, there would be no need to conduct other zygosity testing for the sake of costs consideration.     

TopBP1 Governs Hematopoietic Stem/Progenitor Cells Survival in Zebrafish Definitive Hematopoiesis

In vertebrate definitive hematopoiesis, nascent hematopoietic stem/progenitor cells (HSPCs) migrate to and reside in proliferative hematopoietic microenvironment for transitory expansion. In this process, well-established DNA damage response pathways are vital to resolve the replication stress, which is deleterious for genome stability and cell survival. However, the detailed mechanism on the response and repair of the replication stress-induced DNA damage during hematopoietic progenitor expansion remains elusive. Here we report that a novel zebrafish mutant^cas003 with nonsense mutation in topbp1 gene encoding topoisomerase II β binding protein 1 (TopBP1) exhibits severe definitive hematopoiesis failure. Homozygous topbp1^cas003 mutants manifest reduced number of HSPCs during definitive hematopoietic cell expansion, without affecting the formation and migration of HSPCs. Moreover, HSPCs in the caudal hematopoietic tissue (an equivalent of the fetal liver in mammals) in topbp1^cas003 mutant embryos are more sensitive to hydroxyurea (HU) treatment. Mechanistically, subcellular mislocalization of TopBP1^cas003 protein results in ATR/Chk1 activation failure and DNA damage accumulation in HSPCs, and eventually induces the p53-dependent apoptosis of HSPCs. Collectively, this study demonstrates a novel and vital role of TopBP1 in the maintenance of HSPCs genome integrity and survival during hematopoietic progenitor expansion.     

Exercise‐induced α‐ketoglutaric acid stimulates muscle hypertrophy and fat loss through OXGR1‐dependent adrenal activation

The authors approached the journal to correct a mistake in the data presented in Appendix␣Fig S3D. The authors state that the mouse images in Appendix␣Fig S3D mistakenly displayed images from Fig 2F and Appendix␣Fig S1F. The images in Appendix␣Fig S3D are herewith corrected. The authors state that this change does not affect the conclusions or the statistics. The source data for these panels have been added to the original publication.The authors note that the following sentence needs to be corrected from: Appendix Figure S3D. Original. Appendix Figure S3D. Corrected. “Interestingly, several well‐established accumulation signatures of succinate, malate, hypoxanthine, and xanthine induced by endurance exercise (Lewis et␣al, 2010) were found to be decreased by endurance exercise (Figs 1D and EV1A–D)”.to“Interestingly, several well‐established accumulation signatures of succinate, malate, hypoxanthine, and xanthine induced by endurance exercise (Lewis et␣al, 2010) were found to be decreased by resistance exercise (Figs 1D and EV1A–D)”.Further, the authors requested to amend the legend of Appendix␣Fig S3R to indicate that the same sample for the iWAT group, “WT+2%AKG” treatment, is shown in Fig 3P. The corrected legend reads: “(R‐S). Representative images (R) and quantification (S) of p‐HSL DAB staining from male OXGR1OE^AG mice treated with AKG for 12 weeks (n = 6 per group). The same sample is shown as in Fig 3P ”.The authors regret these errors and any confusion they may have caused. All authors approve of this correction.     

Stable isotope labeling by amino acids in cell culture-based liquid chromatography–mass spectrometry assay to measure microtubule dynamics in neuronal cell cultures

Microtubules (MTs) are highly dynamic polymers composed of α- and β-tubulin heterodimers. Dysregulation of MT dynamics in neurons may be a contributing factor in the progression of various neurodegenerative diseases. We developed a stable isotope labeling by amino acids in cell culture (SILAC)-based liquid chromatography–mass spectrometry (LC–MS) method to measure the fraction of [¹³C₆]leucine-labeled α-tubulin-derived surrogate peptides. Using this approach, we measured the time course of incorporation of [¹³C₆]leucine label into the MT and dimer pools isolated from cycling cells and rat primary hippocampal neurons. We found that the MT pool is in rapid equilibrium with the dimer pool in the cycling cells, consistent with rapid MT polymerization/depolymerization during cell proliferation. Conversely, in neurons, we found that labeling of the MT pool was rapid, whereas the dimer pool was delayed. These results suggest that newly synthesized α-tubulin is first incorporated into MTs or complexes that co-sediment with MTs and that appearance of labeled α-tubulin in the dimer pool may be a consequence of MT depolymerization or breakdown. Our results demonstrate that a SILAC-based approach can be used to measure MT dynamics and may have utility for exploring MT dysregulation in various models of neurodegenerative disease.     

Assignment of the gene for uroporphyrinogen decarboxylase to human chromosome 1 by somatic cell hybridization and specific enzyme immunoassay

Summary A specific enzyme immunoassay of uroporphyrinogen decarboxylase was developed and applied to the detection of the human enzyme in man-rodent somatic cell hybrids. This method allowed to assign the gene for uroporphyrinogen decarboxylase to human chromosome 1.