耐碳青霉烯类肺炎克雷伯菌对多黏菌素耐药性的研究进展

多黏菌素是目前临床治疗耐碳青霉烯类肺炎克雷伯菌(carbapenem-resistant Klebsiella pneumoniae,CRKP)感染为数不多的抗生素.近年来,对多黏菌素耐药的CRKP显著增加,为临床抗感染治疗带来前所未有的挑战.目前,CRKP对多黏菌素耐药的可能机制主要包括表达质粒介导的mcr基因、激活...     

质粒介导的黏菌素耐药基因mcr-1研究进展

mcr-1基因是迄今为止国际上首次发现的质粒介导的黏菌素耐药基因,可介导肠杆菌科细菌对多粘菌素类药物产生耐药并可通过质粒进行水平转移。最新研究表明该基因已通过IncI2、IncX4和IncHI2等流行性质粒以及可移动元件,在全球35个不同国家和地区的人、动物和环境源多种肠杆菌中广泛传播。这些研究对于深入了解mcr-1基因介导的黏菌素耐药和传播机制、全球流行分布特征奠定了基础,丰富了耐药性形成理论。文章主要介绍了不同来源肠杆菌科细菌中mcr-1的分布流行情况、耐药和传播机制、基因环境等方面的研究进展,探讨了其临床风险性以及后续应对措施,以期为相关科研人员和临床工作者提供参考,共同应对抗生素耐药日益严峻的局面。     

CRISPR-Cas9技术在细菌耐药性防控研究进展

近年来,多种新型耐药基因的出现和全球性流行,严重威胁了全球公众健康。CRISPR-Cas9系统(clustered regularly interspaced short palindromic repeats-CRISPR associated protein 9 system)是细菌的一种适应性免疫系统,可切割耐药基因、抵御外来核酸入侵,现已作为一种新型基因编辑工具应用于防控细菌耐药性研究。本团队已建立了一种单质粒介导靶向mcr-1基因的CRISPR-Cas9系统,能有效并特异性消除黏菌素耐药大肠杆菌中的mcr-1,恢复其对黏菌素的敏感性。同时也发现在临床中应用还需要优化其递送方式。本文对近几年该技术在细菌耐药性防控方面的研究进展进行了综述,包括CRISPR-Cas9系统的发现过程、作用机制、递送方式、在体外检测实验结果的进展以及当前存在的问题等方面,以期为防控细菌耐药性提供新思路。     

多黏菌素的流行状况与耐药机制的研究

近年来,由于革兰阴性菌(Gram-negative bacteria)多药耐药性的增加,严重地威胁着人类的健康。由于可选择的抗菌药物越来越少,感染病医师和临床微生物学家需重新评估多黏菌素的临床应用。多黏菌素是治疗临床碳青霉烯类耐药革兰阴性菌的最后一道抗生素。现结合国内外最新研究报道,对多黏菌素耐药流行状况、耐药机制、耐药基因类型、预防干预措施等方面作一概述。     

质粒介导的喹诺酮耐药基因qnr的分类、耐药机制及其在国内的流行状况北大核心CSCD

喹诺酮类抗菌药物从早期主要用于治疗尿道感染发展到后来治疗肠道感染和呼吸道感染,目前已在临床、畜牧业和水产业中广泛使用,细菌对其耐药性也逐渐呈蔓延趋势,耐药机制日趋复杂。喹诺酮类耐药机制主要分为染色体介导的耐药和质粒介导的耐药,后者对细菌耐药性的广泛传播起着重要作用。1998年首次报道了质粒介导的喹诺酮类耐药机制,即质粒上qnr基因介导的细菌对氟喹诺酮耐药机制,qnr基因可在不同细菌中迅速水平传播,引发的感染不易控制,使得院内感染大范围的流行。此外,qnr基因通常与β-内酰胺类耐药基因相关或存在于复杂整合子中与其它多重耐药基因共同整合,缩小了临床医生治疗相关细菌感染时选药或联合用药的空间,给我们带来了严峻的挑战。本文就qnr基因的发现历史、耐药机理及在国内的流行状况做了详细概述。     

新型可移动RND家族外排泵TMexCD-TOprJ的研究进展

抗生素被认为是现代医学的基石之一，但包括抗生素在内抗菌药物的滥用也加速了可抵抗多种抗菌药物“超级细菌”的出现。耐药基因是导致细菌产生耐药性的关键因素，可通过质粒、转座子(transposon, Tn)、插入序列(insertion sequence, IS)等可移动元件(mobile genetic elements, MGEs)进行水平转移，严重威胁公共卫生安全。近年来，面对碳青霉烯类药物和多黏菌素耐药性的暴发，替加环素被视为人类面临多重耐药细菌感染的最后一道防线。近期发现了一种主要存在于质粒上的新型可移动外排泵基因簇tmexCD-toprJ，可编码耐药结节细胞分化家族(resistance-nodulation-cell division, RND)外排泵，排出菌体内包括替加环素在内的多种抗生素，大幅提升了细菌的耐药性。tmexCD-toprJ基因簇可以随质粒等可移动元件进行水平转移，已经传播至人、动物和环境中，给公共卫生健康造成了严重威胁。然而，目前人们对于其具体结构和功能作用机制等研究仍不透彻。本文系统总结tmexCD-toprJ耐药基因的分布特征、传播机制及外排泵结构等研究现状，并基于同一健康(One Health)理念提出了阻遏其扩散的措施，为减缓tmexCD-toprJ传播提供科学依据。     

喹诺酮外排泵耐药基因oqxAB的耐药机制及其流行情况

oqx AB是编码Oqx AB外排泵蛋白的多重耐药基因,由2个开放阅读框oqx A和oqx B组成,其主要介导细菌对喹诺酮类药物的耐药。该基因最早是在大肠埃希菌pOLA52质粒上被发现,是质粒介导的喹诺酮耐药基因的重要成员之一。目前已经分别发现了11个oqxA和32个oqxB等位基因。oqxAB通过质粒进行水平传播,使受体菌株容易形成耐药性,增加了临床治疗的难度。该基因目前主要流行于肠杆菌科,但不能排除也存在于非肠杆菌科细菌,给人类与家畜健康造成巨大的威胁。本文综述了喹诺酮外排泵耐药基因oqxAB及其等位基因的发现、耐药机制、国内外流行特点,以期为临床和畜牧生产中合理使用喹诺酮类抗菌药物,减少oqxAB基因的流行提供资料。     

抗生素耐药性的研究进展与控制策略

抗生素是治疗细菌感染的有效药物,然而抗生素在人类医学及农业生产中的大规模使用催生了细菌耐药性在环境中的快速扩散和传播,特别是多种抗生素的联合使用更是促进了多重耐药性的产生,严重威胁着人类和动物健康及食品与环境安全,相关问题已经引起人们的警觉。因此新研究主要集中在以下几方面:利用组学及合成生物学等方法挖掘并合成新型抗生素;利用高通量技术等系统分析环境中耐药菌及耐药基因新的传播途径及产生的新耐药机制;减抗、替抗及控制耐药基因的策略及其相关工艺。因此,在全面认识耐药基因在环境中传播规律的基础上,如何绿色高效地切断传播途径仍是目前研究的热点。基于此,本文在细菌水平上阐述了抗生素的研发历程、耐药性的发展及控制策略,从而为有效遏制细菌耐药性的发展提供思路。     

水平基因转移介导抗菌素耐药性传播机制的研究进展

近几十年来,病原菌耐药性的出现和蔓延已上升为严峻的公共卫生问题。越来越多研究表明,抗菌素抗性基因(antibiotic resistance genes,ARGs)不仅仅见于临床所分离的病原体,而是包括所有的致病菌、共生菌以及环境中的细菌,它们都能在可移动遗传元件和噬菌体的作用下,通过水平基因转移(horizontal gene transfer,HGT)途径获得耐药性,进而形成抗菌素耐药基因簇(耐药基因组)。HGT可导致抗菌素的耐药性在环境共生菌和病原菌之间传播扩散,这可通过临床上一些重要的抗菌素耐药基因的传播证实。传统观念认为HGT的三种机制中,接合对ARGs的传播影响最大,最近研究表明转化和转导对ARGs播散起到不可忽视的作用。通过深入了解耐药基因组的传播及其在动员病原菌耐药中发挥的作用,对于控制这些基因的播散是至关重要的。将讨论耐药基因组的概念,提供临床相关的抗菌素抗性基因水平基因转移的例子,对当前已研究的促使抗菌素耐药性传播的各种HGT机制进行回顾。     

大熊猫源细菌耐药性研究进展

耐药菌和耐药基因已成为一种新型环境污染物,引发世界公共卫生问题。细菌耐药性尤其是多重耐药菌在人医临床、畜禽养殖以及环境传播等多个方面得到越来越多的关注,而关于大熊猫等野生动物的耐药性研究相对较少。大熊猫(Ailuropoda melanoleuca)是世界公认的珍稀野生动物,其种群数量易受到各种疾病的威胁,尤其是肠道细菌性疾病。随着抗菌药物在疾病预防和控制中的普遍使用,由此带来的耐药性危害日益明显。本文总结了关于大熊猫源细菌耐药的国内外研究报道,对其耐药表型、耐药基因型、耐药机制及水平传播机制等方面内容进行了综述,旨在为大熊猫源细菌耐药性的研究和防控提供依据,为临床科学用药提供理论参考,从而助力大熊猫迁地保护。     

A Unique Protease Cleavage Site Predicted in the Spike Protein of the Novel Pneumonia Coronavirus (2019-nCoV) Potentially Related to Viral Transmissibility

正Dear Editor,In December 2019, a novel human coronavirus caused an epidemic of severe pneumonia(Coronavirus Disease 2019,COVID-19) in Wuhan, Hubei, China(Wu et al. 2020; Zhu et al. 2020). So far, this virus has spread to all areas of China and even to other countries. The epidemic has caused 67,102 confirmed infections with 1526 fatal cases     

Curcuminoids as inhibitors of thioredoxin reductase: A receptor based pharmacophore study with distance mapping of the active site

Curcumin is the yellow pigment of turmeric that interacts irreversibly forming an adduct with thioredoxin reductase (TrxR), an enzyme responsible for redox control of cell and defence against oxidative stress. Docking at both the active sites of TrxR was performed to compare the potency of three naturally occurring curcuminoids, namely curcumin, demethoxy curcumin and bis-demethoxy curcumin. Results show that active sites of TrxR occur at the junction of E and F chains. Volume and area of both cavities is predicted. It has been concluded by distance mapping of the most active conformations that Se atom of catalytic residue SeCYS498, is at a distance of 3.56 from C13 of demethoxy curcumin at the E chain active site, whereas C13 carbon atom forms adduct with Se atom of SeCys 498. We report that at least one methoxy group in curcuminoids is necessary for interation with catalytic residues of thioredoxin. Pharmacophore of both active sites of the TrxR receptor for curcumin and demethoxy curcumin molecules has been drawn and proposed for design and synthesis of most probable potent antiproliferative synthetic drugs.     

Comparative morphology of the carpel in the Liliaceae: Hewardieae, Petrosavieae, and Tricyrteae

The young pistils in the melanthioid tribes, Hewardieae, Petrosavieae and Tricyrteae, are uniformly tricarpellate and syncarpous. They lack raphide idioblasts. All are multiovulate, with bitegmic ovules. The Petrosavieae are marked by the presence of septal glands and incomplete syncarpy. Tepals and stamens adhere to the ovary in the Hewardieae and the Petrosavieae but not in the Tricyrteae. Two vascular bundles occur in the stamens of the Hewartlieae and Tricyrtis latifolia. Ventral bundles in the upper part of the ovary of the Hewardieae are continuous with compound septal bundles and placental bundles in the lower part. Putative ventral bundles occur in the alternate position in the Tricyrteae and putative placental bundles in the opposite. position in the Petrosavieae. The dichtomously branched stigma in each carpel of the Tricyrteae is supplied by a bifurcated dorsal bundle.     

Selection with two alleles and complete dominance

For a plant selection model with frequency-independent viabilities, fertilities and selfing rates, it is shown that apart from global fixation, for certain parameter combinations a protected polymorphism and facultative fixation (either allele may become fixed according to initial frequencies) may both occur. Facultative fixation requires different selling rates for the dominant and recessive type. Protection of the polymorphism requires resource allocation for male and female function. In this connection the problem of purely genetically caused population extinction is discussed.
For general frequency dependence and regular segregation, the chances for establishment of a completely recessive gene are compared to those of a completely dominant gene. It is proven that the process of establishment of the recessive gene, despite a fitness advantage, may be considerably endangered by drift effects if random mating prevails. The recessive gene may reach the same effectivity in establishment as a dominant gene, only if the recessive homozygote mates exclusively with its own type during the period of establishment.     

Perinatal Vertical Transmission of Chikungunya Virus in Ruili,a Town on the Border between China and Myanmar

正Dear Editor,Chikungunya virus (CHIKV), an arbovirus in the family of Togaviridae, genus Alphavirus, is transmitted by the A.aegyptii or A. albopictus mosquito, and causes disease in humans characterized by fever, rash, and arthralgia (Silva and Dermody 2017; Suhrbier 2019). It was first reported in 1953 in Tanzania, and caused only a few outbreaks and sporadic cases in Africa and Asia in last century. However, in the epidemic in 2004, CHIKV acquired mutations that conferred enhanced transmission by the A. albopictus mosquito(Schuffenecker et al. 2006). Since then, it has successively caused outbreaks in Africa, the Indian Ocean, South East Asia, the South America, and Europe (Zeller et al. 2016).