酿酒酵母代谢工程技术

自20世纪90年代初期诞生以来,代谢工程历经了30年的快速发展。作为代谢工程的首选底盘细胞之一,酿酒酵母细胞工厂已被广泛应用于大量大宗化学品和新型高附加值生物活性物质的生物制造,在能源、医药和环境等领域取得了巨大的突破。近年来,合成生物学、生物信息学以及机器学习等相关技术也极大地促进了代谢工程的技术发展和应用。文中回顾了近30年来酿酒酵母代谢工程重要的技术发展,首先总结了经典代谢工程的常用方法和策略,以及在此基础上发展而来的系统代谢工程和合成生物学驱动的代谢工程技术。最后结合最新技术发展趋势,展望了未来酿酒酵母代谢工程发展的新方向。     

家蚕CRISPR/Cpf1基因编辑系统建立

自CRISPR/Cas9基因编辑系统成功应用于模式生物以来,因其快速、高效、便捷等特点,广泛应用于基因功能研究、基因治疗和基因工程等研究领域。与此同时,CRISPR/Cas系统不断在微生物界的发现也加速了新的基因编辑工具的不断涌现。CRISPR/Cpf1是第二类 (Ⅴ型) 能够编辑哺乳动物基因组的CRISPR系统,相比于CRISPR/Cas9基因编辑系统,能够利用5′T-PAM富集区增加基因组覆盖率,具有其切割位点为粘性末端和更不易同源重组修复等诸多优势。基于此,本研究构建了能够在家蚕细胞表达的3个不同来源的CRISPR/Cpf1 (AsCpf1、FnCpf1和LbCpf1) 表达载体,选择高度保守的家蚕热休克蛋白基因BmHSP60和家蚕ATP酶家族BmATAD3A基因分别设计靶标gRNA,构建gHSP60-266R和gATAD3A-346R基因编辑载体。通过T7E1酶切分析和T克隆测序,鉴定3个Cpf1基因编辑系统AsCpf1、FnCpf1和LbCpf1对靶标基因BmHSP60和BmATAD3A的编辑效率。同时,利用Western blotting分析不同基因编辑系统敲除靶基因后对其BmATAD3A和BmHSP60蛋白翻译的影响。本研究成功构建了家蚕CRISPR/Cpf1基因编辑系统,能够在家蚕细胞中有效编辑家蚕基因组,为家蚕基因功能研究、基因工程和遗传育种开发了新技术与新方法。     

耐高盐枯草芽孢杆菌XP合成球形纳米硒及其抑制草莓病原真菌生物活性

生物方法合成纳米材料具有低能耗、高安全性以及环境友好等优良特点,因而备受人们关注。利用细菌将硒酸盐或亚硒酸盐还原为单质硒,不仅可以降低硒毒性,而且还能获得价值更高的生物纳米材料。文中选用可耐受高盐环境胁迫的枯草芽孢杆菌亚种Bacillus subtilis subspecies stercoris strain XP构建生物模型,分别以LB液体培养基和亚硒酸钠为介质和底物 (电子受体),解析菌株XP合成纳米硒的基本规律。通过扫描电镜 (Scanning electron microscope,SEM) 观察、X射线能谱分析 (X-ray energy dispersive spectral analysis,EDAX)、X射线衍射 (X-ray diffraction,XRD) 分析、傅里叶红外变换光谱 (Fourier transform infrared spectroscopy,FTIR) 技术对合成的纳米硒进行物理化学表征分析,同时选用草莓枯萎、红叶、紫斑病病原真菌对其抗菌活性进行分析。结果表明,菌株XP介导合成的单质硒为球形纳米颗粒 (Selenium nanoparticles,SeNPs),其生成量与反应时间呈正相关 (0–48 h),且细胞形态未发生褶皱或破损等变化 (耐受力强);SeNPs为非晶态,粒径范围在135–165 nm,表面元素组成以Se为主,同时存在C、O、N、S等有机元素;颗粒表面包裹生物大分子物质,-OH、C=O、N-H、C-H等官能团与SeNPs稳定性和生物活性密切相关;高浓度纳米硒对枯萎、红叶、紫斑病病原真菌均有显著抑制活性 (P<0.05),其中对草莓红叶病与枯萎病病原真菌的抑制活性明显优于对紫斑病病原真菌的抑制活性。总而言之,菌株XP不仅耐受高盐胁迫能力强,同时还可介导合成生物SeNPs,其合成的纳米硒颗粒具有良好的稳定性和生物活性,在草莓病害防治以及绿色富硒草莓种植等领域具有潜在的应用价值。     

CRISPR在食源性致病菌进化分析、检测分型及毒力耐药调控中的应用进展

规律成簇间隔的短回文重复序列 (Clustered regularly interspaced short palindromic repeats,CRISPR) 与其相关蛋白基因系统可通过限制基因的水平转移而有效防御噬菌体等外源基因元件的入侵,不同细菌之间的CRISPR结构有所差异。基于CRISPR系统的差异性,文中对近几年CRISPR在食源性致病菌进化分析、检测与分型、毒力与耐药中的应用研究进行概述,并对基于CRISPR序列特点开发的细菌检测分型方法以及CRISPR与食源性致病菌的毒力、耐药性之间的相关性进行重点总结分析。此外,文中探讨了CRISPR在进化分析、检测与分型、毒力与耐药应用中的不足,提出将CRISPR分型方法标准化、完善与扩充致病菌CRISPR数据库、进一步探究噬菌体与细菌之间的共进化关系等建议,为进一步探索CRISPR功能提供参考。     

中欧组织间合作研究项目MIX-UP助力实现“碳中和”

随着全球塑料循环体系的变革升级,提高塑料的回收利用不仅可以减少塑料在生命周期中的碳排放,还可以解决废塑料潜在的生态环境危害。文中介绍了2019年国家自然科学基金组织间国际 (地区) 合作研究项目“废塑料资源高效生物降解转化的关键科学问题与技术 (MIXed plastics biodegradation and UPcycling using microbial communities,MIX-UP)”。该项目聚焦“塑料污染”这一全球化的问题,围绕中欧双方确定的“塑料生物降解菌群”研究领域,联合中欧双方14家优势科研单位,开展实质性的重大前沿合作研究。针对废塑料生物降解中存在的解聚与重塑两个难题,项目以难降解石油基塑料 (PP、PE、PUR、PET和PS) 以及生物可降解塑料 (PLA和PHA) 的混合废塑料作为研究对象,从塑料微生物降解途径解析及关键元件的挖掘与改造、塑料高效降解混菌/多酶体系的构建与功能调控、塑料降解物的高值化炼制途径设计与利用策略3个方面展开研究。本项目将突破废塑料生物降解转化中高效降解元件挖掘、塑料降解物高值化利用的关键科学问题与技术,探索一条废塑料资源化、高值化、循环化、低碳化的新塑料循环路线,建立以“降塑再造”为核心理念的废塑料生物炼制体系,丰富我国固废资源化生物技术利用平台。项目的实施不仅有助于提升我国塑料 (生物) 循环经济的理论基础和关键技术水平,还可以推动我国与国际科研院所的多边交流与合作,促进我国在生物技术领域的创新发展,助力我国碳中和目标的实现。     

Banana defence responses to Cosmopolites sordidus feeding and methyl jasmonate application

Each year 25–75% of banana and plantain yields are lost because of rhizome damages caused by banana weevil (Cosmopolites sordidus) in growing regions of sub‐Saharan Africa. However, the specific plant defence response of the rhizome tissue in relation to the C. sordidus attack is unknown. Consequently, in this study, we evaluated whether plant defence substances in the rhizome are correlated with the degree of larval damage and whether applications of methyl jasmonate (MJ) elicit a greater induction of the plant defence potential against C. sordidus. Moreover, we attempted to reveal cellular modifications in response to the root feeding herbivore through histochemical staining. The banana cultivars “Km5” and “Mbwazirume” with tolerance and susceptibility to C. sordidus, respectively, were used in a pot experiment to evaluate percent rhizome damage, leaf chlorophyll content, total phenolic content (TPC), antioxidant capacity and cell morphology in response to C. sordidus attack and/or MJ applications compared to untreated control plants. We found that C. sordidus‐induced rhizome damage was 30% in the susceptible cultivar but less than 5% in the tolerant cultivar. The percent rhizome damage was not related to leaf chlorophyll content but showed a significant negative linear relationship to both TPC and antioxidant capacity. Larvae feeding induced a considerably greater increase of polyphenolic defence compounds in Km5 than in Mbwazirume; however, this response was opposite in the MJ treatment, suggesting that the phytohormone induced the susceptible plant to invest more into the synthesis of defence chemicals that in turn lead to reduced C. sordidus damage. Tissue staining demonstrated a greater deposition of lignin and suberin in C. sordidus challenged rhizome, presumably to seal off healthy tissue with a physical barrier from continued pest attack. It is concluded that MJ induces polyphenolics in susceptible Mbwazirume banana that reduced C. sordidus damage.     

Genetic diversity in oak populations under intensive management for fuelwood in the Sierra de Zongolica,Mexico

Firewood and charcoal are used on a daily basis both in rural areas and in cities. This type of energy is produced by one of the most ancient traditional methods, known as coppice, which harvest tree sprouts. There is controversy about its effects on forests: it preserves populations and tree cover of species used, but reduces density, inhibits sexual reproduction and generates genetic erosion. We inquired if it was possible to identify a loss of genetic diversity in oak populations traditionally used for charcoal by the Zongolica Nahuas in Veracruz state, Mexico. We studied populations of Quercus laurina, Quercus calophylla and Quercus rugosa in three different altitudes. Molecular analysis with eight nuclear codominant microsatellites was performed to determine the diversity, structure and gene flow of these species. Results for Q. laurina were Na = 8.458, I = 1.766, Ho = 0.679, polymorphism = 100%, Fis = 0.079, with intraindividual variation of 81.55%. For Q. calophylla: Na = 7.250, I = 1.563, Ho = 0.646, polymorphism = 91.67%, Fis = 0.083, with intraindividual variation of 83.80%. For Q. rugosa: Na = 6.958, I = 1.510, Ho = 0.574, polymorphism = 91.67%, Fis = 0.204, with intraindividual variation of 81.99%; this species shows signals of an early genetic isolation process. Our findings indicate that Quercus genetic diversity for the three species is high and comparable with oak species in Mexico and worldwide. We conclude that at the present, coppice is preserving a historical diversity in adult trees kept alive through sprouting. Nonetheless, problems with coppice systems elsewhere, unregulated harvesting and expansion of pine plantation in the region suggest that further studies, hand in hand with a landscape management approach that improve charcoal and firewood production, may be valuable for Sierra de Zongolica genetic biodiversity conservation.     

On computation of semiparametric maximum likelihood estimators with shape constraints

Large sample theory of semiparametric models based on maximum likelihood estimation (MLE) with shape constraint on the nonparametric component is well studied. Relatively less attention has been paid to the computational aspect of semiparametric MLE. The computation of semiparametric MLE based on existing approaches such as the expectation‐maximization (EM) algorithm can be computationally prohibitive when the missing rate is high. In this paper, we propose a computational framework for semiparametric MLE based on an inexact block coordinate ascent (BCA) algorithm. We show theoretically that the proposed algorithm converges. This computational framework can be applied to a wide range of data with different structures, such as panel count data, interval‐censored data, and degradation data, among others. Simulation studies demonstrate favorable performance compared with existing algorithms in terms of accuracy and speed. Two data sets are used to illustrate the proposed computational method. We further implement the proposed computational method in R package BCA1SG , available at CRAN.