纳米孔测序技术应用于食品微生物检测的可行性分析

近些年来DNA测序技术发展迅速,已经从第一代生化测序发展到第三代单分子测序。作为第三代测序技术中的一种不同于当前流行的其他测序技术,纳米孔测序技术是基于电信号的一种物理方法测序。许多研究者通常将高通量测序技术应用于食品微生物的研究,但是将纳米孔测序技术应用于食品中微生物的检测却鲜有报道。Oxford Nanopore Technologies(牛津纳米孔科技公司)研发的DNA测序仪MinION,是世界首例用于商业测序的纳米孔测序仪,经过不断完善,近年来MinION在DNA测序中被广泛应用。MinION 测序一次需要的DNA量约1μg,其标准识别速度为一秒钟识别250个碱基,平均读长可至13kb~20kb,测序准确率可以达到98%。纳米孔测序的高识别速度和高准确率,完全满足快速检测的要求,将其应用于食品中微生物检测是完全可行的。     

基于纳米孔测序技术的柑橘黄龙病检测方法建立

柑橘黄龙病(Huanglongbing)是柑橘生产上最具毁灭性的病害,及时快速地进行早期检测和诊断是防控黄龙病的关键措施之一.本文利用掌上纳米孔测序仪MinION对携带黄龙病菌Candidatus Liberibacter asiaticus的DNA样品进行测序,并利用Blast、GraphMap、minimap2以及两种bwa的比对方法将测序结果比对到黄龙病菌基因组上,比对结果均匀的比对到黄龙病菌基因组上,并未发现严重的偏倚现象,验证了其测序结果的可靠性.本技术可弥补因柑橘木虱Diaphorina citri(Kuwayama)虫体过小或损坏难以进行光学识别的不足,并可同时检测虫体是否携带有黄龙病菌,对有黄龙病发生风险但尚未有黄龙病实际发生的柑橘种植区提供实时实地的监控与预警.     

不同DNA聚合酶对运用ARTIC工作流的新型冠状病毒纳米孔测序的影响

摘要 目的：为了验证不同高保真DNA聚合酶是否会对运用ARTIC工作流进行新型冠状病毒纳米孔测序产生影响。方法：使用英国Nanopore公司MinION测序仪对2份已获得全基因组序列的新冠肺炎确诊病例核酸样本分别采用KAPA HiFi HotStart ReadyMix,PrimeSTAR?誖GXL DNA Polymerase和NEBNext High-Fidelity 2X PCR Master Mix进行ARTIC工作流的多重PCR扩增,对扩增产物进行测序,并对测序质量进行分析。结果：不同高保真DNA聚合酶在相同扩增条件下,扩增产物的质检结果和测序质量均不相同,NEBNext High-Fidelity 2X PCR Master Mix在覆盖度和测序深度上明显好于另外两种酶。结论：NEBNext High-Fidelity 2X PCR Master Mix在纳米孔新型冠状病毒ARTIC快速测序工作流中的应用效果较好。     

基于MegaBACE 1000的荧光(marker)开发

MegaBACETM 1000 DNA测序仪是由美国Pharmacia公司生产的一种高通量的DNA测序仪,利用这套测序仪,可以进行DNA测序、遗传分析等相关研究。但该公司生产的用于遗传分析的DNA标记物（marker）（ET550-R Size Standards）价格不菲,出于节省成本的考虑,自行开发了荧光标记物,经过验证,这个标记完全可以在MegaBACE 1000 DNA测序仪上使用。利用这套标记物和自己开发的标记物识别软件,构建了一套基于MegaBACE 1000 DNA测序仪的改良的、高通量的AFLP操作流程。     

蓖麻蚕五龄幼虫整体及几个主要器官DNA和RNA含量的变化

朱洗教授从国外引进蓖麻蚕,为我国蚕业生产做出了巨大贡献。为了更好的发展蓖麻蚕丝的生产,目前对改善蓖麻蚕经济性状的研究,逐渐引起人们的重视。我们(1981)曾将家蚕DNA注射给五龄蓖麻蚕,引起了蓖麻蚕某些遗传性状发生了变异。为了探索外源DNA诱导变异的适宜条件,有必要对这一发育时期的核酸代谢情况进行研究。Tashiro等(1968)和Shigematsu等(1978)对家蚕核酸进行研究。辜祥荣等(1981)对蓖麻蚕后部丝腺核酸含量变化进行过研究。本文研究了五龄蓖麻蚕整体和几个主要器官DNA和RNA含量的变化,同时也研究了~3H-胸腺嘧啶及~3H-尿嘧啶在不同时间对不同组织DNA和RNA的参入,现将结果报告如下。     

蓖麻蚕不同组织脂酶同工酶的研究

本工作为蚕类同工酶研究中的一部分,研究了蓖麻蚕五龄幼虫不同组织器官酯酶的分布情况,试图逐渐建立酶谱化。目的在于利用聚丙烯酰胺凝胶电泳,检验家蚕的DNA对蓖麻蚕的诱变作用（陈元霖等,1981）,以期供体、受体与转化体之间几种酶谱的异同,从分子生物学的角度对蚕类DNA诱导遗传性变异加以阐述。     

蓖麻蚕血型脓病的病原简介

近十年来广西饲养蓖麻蚕,流行血型脓病,已查明是由蓖麻蚕核型多角体病毒侵染所致。目前尚无有效治疗方法。 本病毒棒状,大小为160—280×30一40毫微米。病原通过蚕的肠胃及血液侵染,存在于向细胞、脂肪细胞、生殖腺膜细胞和皮肤上、气管大核细胞层。先在细胞核内繁殖,以后形成多角体(包含体)。病毒在多角体内,全都具有发育膜。其分布方问、间隔和数目,都没有规则。在病蚕的血清内,有不具发育膜的游离病     

科间昆虫DNA诱导遗传变异成功

DNA是遗传信息的载体,通过外源DNA作用的方法改变动物固有的遗传性状的研究有着重要的理论和实践意义。我们选用两种不同科的昆虫,即家蚕蛾科的桑蚕(Bombyx mori)和天蚕蛾科的蓖麻蚕(Attacus Cynthia ricini)作为试验研究的对象,从桑蚕中幼虫具有不同斑纹的黑蚕、671和华合×东肥三个品系的蛹或幼虫,提取DNP(DNA蛋白)和DNA,注入姬蚕品系的蓖麻蚕五龄幼虫体内,在受过注射的     

蓖麻蚕去氧核糖核酸诱导家蚕遗传变异的初步研究

为了研讨不同科的昆虫之间异源核酸诱导遗传变异的可能性,在继家蚕去氧核糖核酸蛋白(DNP)诱导蓖麻蚕变异的试验获得成功后,我们又进行了用蓖麻蚕DNA和DNP诱导家蚕遗传变异可能性的研究。作为核酸来源(供体)的品系,是白血系统的蓖麻蚕姬蚕品系,该品系的蛾子具黑色复眼,产白色卵;作为受体的家蚕品系是沄文皮斑点,其蛾子具     

野桑蚕、蓖麻蚕及家蚕基因组的RFLP分析

以家蚕Bombyx mori丝素重链基因、丝胶基因1和胰凝乳蛋白酶抑制因子13基因为探针,对野桑蚕B.mandarina、蓖麻蚕Philosamia cynthia ricini和家蚕B.mori基因组DNA进行限制性片段长度多态性分析。结果发现,在野桑蚕、蓖麻蚕基因组中存在着家蚕丝素重链基因、丝胶基因1的同源序列,而在中日野桑蚕以及蓖麻蚕品种间存在着限制性酶切位点差异;丝胶基因1在中国野桑蚕基因组的EcoRⅠ酶切图谱较日本野桑蚕与家蚕更为一致,表明家蚕与中国野桑蚕亲缘关系更近。此外,在野桑蚕基因组中发现了家蚕胰凝乳蛋白酶抑制因子13基因的同源序列,并且在家蚕品种间以及中日野桑蚕之间也存在着多态性。这些结果表明不同绢丝昆虫在适应生存环境的进化过程中,基因组发生了结构改变。     

Synthesis and characterization of chimeric silkworm silk

A synthetic gene encoding a chimeric silklike protein was constructed that combined a polyalanine encoding region (Ala)(18), a sequence slightly longer than the (Ala)(12-13) found in the silk fibroin from the wild silkworm Samia cynthia ricini, and a sequence encoding GVGAGYGAGAGYGVGAGYGAGVGYGAGAGY, found in the silk fibroin from the silkworm Bombyx mori. A tetramer of the chimeric repeat sequence encoding a approximately 29 kDa protein was expressed as a fusion protein in Escherichia coli. In comparison to S. c. ricini silk, the chimeric protein demonstrated improved solubility because it could be dissolved in 8 M urea. The purified protein assumed an alpha-helical structure based on solid-state (13)C CP/MAS NMR and was less prone to conformational transition to a beta-sheet, unlike native silk proteins from S. c. ricini. Model peptides representing the crystalline region of S. c. ricini silk fibroin, (Ala)(12) and (Ala)(18), formed beta-sheet structures. Therefore, the solubility and structural transitions of the chimeric protein were significantly altered through the formation of this chimeric silk. This experimental strategy to the study of silk structure and function can be used to develop an improved understanding of the contributions of protein domains in repetitive silkworm and spider silk sequences to structure development and structural transitions.     

Structures of Bombyx mori and Samia cynthia ricini silk fibroins studied with solid-state NMR

There are many kinds of silks spun by silkworms and spiders, which are suitable to study the structure-property relationship for molecular design of fibers with high strength and high elasticity. In this review, we mainly focus on the structural determination of two well-known silk fibroin proteins that are from the domesticated silkworm, Bombyx mori, and the wild silkworm, Samia cynthia ricini, respectively. The structures of B. mori silk fibroin before and after spinning were determined by using an appropriate model peptide, (AG)(15), with several solid-state NMR methods; (13)C two-dimensional spin-diffusion solid-state NMR and rotational echo double resonance (REDOR) NMR techniques along with the quantitative use of the conformation-dependent (13)C CP/MAS chemical shifts. The structure of S. c. ricini silk fibroin before spinning was also determined by using a model peptide, GGAGGGYGGDGG(A)(12)GGAGDGYGAG, which is a typical repeated sequence of the silk fibroin, with the solid-state NMR methods. The transition from the structure of B. mori silk fibroin before spinning to the structure after spinning was studied with molecular dynamics calculation by taking into account several external forces applied to the silk fibroin in the silkworm.     

Uptake of atmospheric carbon dioxide into silk fiber by silkworms

The relation between the uptake of atmospheric CO(2) and insect's production of silk fiber has not yet been reported. Here, we provide the first quantitative demonstrations that four species of silkworms (Bombyx mori, Samia cynthia ricini, Antheraea pernyi, and Antheraea yamamai) and a silk-producing spider (Nephila clavata) incorporate atmospheric CO(2) into their silk fibers. The abundance of (13)C incorporated from the environment was determined by mass spectrometry and (13)C NMR measurements. Atmospheric CO(2) was incorporated into the silk fibers in the carbonyl groups of alanine, aspartic acid, serine, and glycine and the C(gamma) of aspartic acid. We show a simple model for the uptake of atmospheric CO(2) by silkworms. These results will demonstrate that silkworm has incorporated atmospheric CO(2) into silk fiber via the TCA cycle; however, the magnitude of uptake into the silk fibers is smaller than that consumed by the photosynthesis in trees and coral reefs.     

Development of a multiplex polymerase chain reaction for the simultaneous detection of microsporidians, nucleopolyhedrovirus, and densovirus infecting silkworms

We have developed a novel PCR-based assay for individual and simultaneous detection of three major pathogens (microsporidians, nucleopolyhedrovirus (NPV) and densovirus (DNV)) infecting the silkworm, Bombyx mori. Multiplex PCR, using three primer pairs, two of which were designed from the conserved regions of 16S small subunit ribosomal RNA gene of microsporidians, and polyhedrin gene of NPVs respectively, and a third primer pair designed from the internal sequences of B. mori DNVs (BmDNV), showed discrete and pathogen specific PCR products. The assay showed high specificity and sensitivity for the pathogenic DNA. Under optimized PCR conditions, the assay yielded a 794 bp DNA fragment from Nosema bombycis, 471 bp fragment from B. mori NPV (BmNPV) and 391 bp fragment from BmDNV. Further, this detection method was successfully applied to other silkworm species such as Antheraea mylitta and Samia cynthia ricini, in detecting same or similar pathogens infecting them. This method is a valuable supplement to the conventional microscopic diagnostic methods and can be used for the early detection of pathogens infecting silkworms. Furthermore it can assist research and extension centers for the safe supply of disease-free silkworms to farmers.     

Design, expression and solid-state NMR characterization of silk-like materials constructed from sequences of spider silk, Samia cynthia ricini and Bombyx mori silk fibroins

Silk has a long history of use in medicine as sutures. To address the requirements of a mechanically robust and biocompatible material, basic research to clarify the role of repeated sequences in silk fibroin in its structures and properties seems important as well as the development of a processing technique suitable for the preparation of fibers with excellent mechanical properties. In this study, three silk-like protein analogs were constructed from two regions selected from among the crystalline region of Bombyx mori silk fibroin, (GAGSGA)(2), the crystalline region of Samia cynthia ricini silk fibroin, (Ala)(12), the crystalline region of spider dragline silk fibroin, (Ala)(6), and the Gly-rich region of spider silk fibroin, (GGA)(4). The silk-like protein analog constructed from the crystalline regions of the spider dragline silk and B. mori silk fibroins, (A(6)SCS)(8), that constructed from the crystalline regions of the S. c.ricini and B. mori silk fibroins, (A(12)SGS)(4), that constructed from and the crystalline region of S. c.ricini silk fibroin and the glycine-rich region of spider dragline silk fibroin, (A(12)SGS)(4),were expressed their molecular weights being about 36.0 kDa, 17.0 kDa and 17.5 kDa, respectively in E. coli by means of genetic engineering technologies. (A(12)SCS)(4) and (A(12)SGS)(4 )undergo a structural transition from alpha-helix to beta-sheet on a change in the solvent treatment from trifluoroacetic acid (TFA) to formic acid (FA). However, (A(6)SCS)(8) takes on the beta-sheet structure predominantly on TFA treatment and FA treatment. Structural analysis was performed on model peptides selected from spider dragline and S. c.ricini silks by means of (13)C CP/MAS NMR.     

Oxford Nanopore MinION Sequencing and Genome Assembly

The revolution of genome sequencing is continuing after the successful second-generation sequencing (SGS) technology. The third-generation sequencing (TGS) technology, led by Pacific Biosciences (PacBio), is progressing rapidly, moving from a technology once only capable of providing data for small genome analysis, or for performing targeted screening, to one that pro-mises high quality de novo assembly and structural variation detection for human-sized genomes. In 2014, the MinION, the first commercial sequencer using nanopore technology, was released by Oxford Nanopore Technologies (ONT). MinION identifies DNA bases by measuring the changes in electrical conductivity generated as DNA strands pass through a biological pore. Its portability, affordability, and speed in data production makes it suitable for real-time applications, the release of the long read sequencer MinION has thus generated much excitement and interest in the geno-mics community. While de novo genome assemblies can be cheaply produced from SGS data, assem-bly continuity is often relatively poor, due to the limited ability of short reads to handle long repeats. Assembly quality can be greatly improved by using TGS long reads, since repetitive regions can be easily expanded into using longer sequencing lengths, despite having higher error rates at the base level. The potential of nanopore sequencing has been demonstrated by various studies in gen-ome surveillance at locations where rapid and reliable sequencing is needed, but where resources are limited.     

Species Specificity of the Insect Prothoracicotropic Hormone (PITH): the Presence of Bombyx-and Samia-Specific PTTHs in the Brain of Bombyx mori

Crude extracts of Bombyx mori brains can provoke adult development when injected into brain-removed dormant pupae of Bombyx mori and Samia Cynthia ricini. From this fact the prothoracicotropic hormone (PTTH) of Bombyx has long been thought to be species-nonspecifically active on Samia. Chemical fractionation of Bombyx brain or head extracts by fractional precipitation with acetone, Sephadex G-50 gel-filtration, and DEAE-Sepharose CL-6B chromatography, however, separated the fractions which activated Bombyx brainless pupae from those which activated Samia. Those results reveal the existence of two species-specific PTTHs.     

Harnessing the MinION: An example of how to establish long‐read sequencing in a laboratory using challenging plant tissue from Eucalyptus pauciflora

Long‐read sequencing technologies are transforming our ability to assemble highly complex genomes. Realizing their full potential is critically reliant on extracting high‐quality, high‐molecular‐weight (HMW) DNA from the organisms of interest. This is especially the case for the portable MinION sequencer which enables all laboratories to undertake their own genome sequencing projects, due to its low entry cost and minimal spatial footprint. One challenge of the MinION is that each group has to independently establish effective protocols for using the instrument, which can be time‐consuming and costly. Here, we present a workflow and protocols that enabled us to establish MinION sequencing in our own laboratories, based on optimizing DNA extraction from a challenging plant tissue as a case study. Following the workflow illustrated, we were able to reliably and repeatedly obtain >6.5 Gb of long‐read sequencing data with a mean read length of 13 kb and an N50 of 26 kb. Our protocols are open source and can be performed in any laboratory without special equipment. We also illustrate some more elaborate workflows which can increase mean and average read lengths if this is desired. We envision that our workflow for establishing MinION sequencing, including the illustration of potential pitfalls and suggestions of how to adapt it to other tissue types, will be useful to others who plan to establish long‐read sequencing in their own laboratories.     

Study of protein conformation and orientation in silkworm and spider silk fibers using Raman microspectroscopy

Raman microspectroscopy has been used for the first time to determine quantitatively the orientation of the beta-sheets in silk monofilaments from Bombyx mori and Samia cynthia ricini silkworms, and from the spider Nephila edulis. It is shown that, for systems with uniaxial symmetry such as silk, it is possible to determine the order parameters P2 and P4 of the orientation distribution function from intensity ratios of polarized Raman spectra. The equations allowing the calculation of P2 and P4 using polarized Raman microspectroscopy for a vibration with a cylindrical Raman tensor were first derived and then applied to the amide I band that is mostly due to the C=O stretching vibration of the peptide groups. The shape of the Raman tensor for the amide I vibration of the beta-sheets was determined from an isotropic film of Bombyx mori silk treated with methanol. For both the Bombyx mori and Samia cynthia ricini fibroin fibers, the values of P2 and P4 obtained are equal to -0.36 +/- 0.03 and 0.19 +/- 0.02, respectively, even though the two types of silkworm fibroins strongly differ in their primary sequences. For the Nephila edulis dragline silk, values of P2 and P4 of -0.32 +/- 0.02 and 0.13 +/- 0.02 were obtained, respectively. These results clearly indicate that the carbonyl groups are highly oriented perpendicular to the fiber axis and that the beta-sheets are oriented parallel to the fiber axis, in agreement with previous X-ray and NMR results. The most probable distribution of orientation was also calculated from the values of P2 and P4 using the information entropy theory. For the three types of silk, the beta-sheets are highly oriented parallel to the fiber axis. The orientation distributions of the beta-sheets are nearly Gaussian functions with a width of 32 degrees and 40 degrees for the silkworm fibroins and the spider dragline silk, respectively. In addition to these results, the comparison of the Raman spectra recorded for the different silk samples and the polarization dependence of several bands has allowed to clarify some important band assignments.     

Characterization by Raman microspectroscopy of the strain-induced conformational transition in fibroin fibers from the silkworm Samia cynthia ricini

Raman microspectroscopy has been used to quantitatively study the effect of a mechanical deformation on the conformation and orientation of Samia cynthia ricini (S. c. ricini) silk fibroin. Samples were obtained from the aqueous solution stored in the silk gland and stretched at draw ratios (lambda) ranging from 0 to 11. Using an appropriate band decomposition procedure, polarized and orientation-insensitive spectra have been analyzed to determine order parameters and the content of secondary structures, respectively. The data unambiguously show that, in response to mechanical deformation, S. c. ricini fibroin undergoes a cooperative alpha-helix to beta-sheet conformational transition above a critical draw ratio of 4. The alpha-helix content decreases from 33 to 13% when lambda increases from 0 to 11, while the amount of beta-sheets increases from 15 to 37%. In comparison, cocoon silk is devoid of alpha-helical structure and always contains a larger amount of beta-sheets. Although the presence of isosbestic points in different spectral regions reveals that the conformational change induced by mechanical deformation is a two-state process, our results suggest that part of the glycine residues might be incorporated into beta-poly(alanine) structures. The beta-sheets are initially isotropically distributed and orient along the fiber axis as lambda increases, but do not reach the high level of orientation found in the cocoon fiber. The increase in the orientation level of the beta-sheets is found to be concomitant with the alpha --> beta conformational conversion, whereas alpha-helices do not orient under the applied strain but are rather readily converted into beta-sheets. The components assigned to turns exhibit a small orientation perpendicular to the fiber axis in stretched samples, showing that, overall, the polypeptide chains are aligned along the stretching direction. Our results suggest that, in nature, factors other than stretching contribute to the optimization of the amount of beta-sheets and the high degree of orientation found in natural cocoon silk.