Model suicide vector for containment of genetically engineered microorganisms.

A model suicide vector (pBAP19h), designed for the potential containment of genetically engineered microorganisms, was made by constructing a plasmid with the hok gene, which codes for a lethal polypeptide, under the control of the lac promoter. The vector plasmid also codes for carbenicillin resistance. In the absence of carbenicillin, induction of the hok gene in vitro caused elimination of all detectable cells containing the suicide vector; pBAP19h-free cells of the culture survived and grew exponentially. In the presence of carbenicillin, however, the number of cells containing pBAP19h initially declined after induction of hok but then multiplied exponentially. The surviving cells still had a fully functional hok gene and had apparently developed resistance to the action of the Hok polypeptide. Thus, high selective pressure against the loss of the suicide vector led to a failure of the system. Soil microcosm experiments confirmed the ability of a suicide vector to restrict the growth of a genetically engineered microorganism in the absence of selective pressure against the loss of the plasmid, with 90 to 99% elimination of hok-bearing cells within 24 h of hok induction. However, some pBAP19h-bearing cells survived in the soil microcosms after hok induction. The surviving cells contained an active hok gene but were not capable of normal growth even after elimination of the hok gene; it appears that a mutation that made them Hok resistant also reduced their capacity for membrane functions needed for energy generation and exponential cell growth. Thus, the model suicide vector was shown to be functional in soil as well as in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)     

Translational control and differential RNA decay are key elements regulating postsegregational expression of the killer protein encoded by the parB locus of plasmid R1

The parB locus of plasmid R1, which mediates plasmid stability via postsegregational killing of plasmid-free cells, encodes two genes, hok and sok. The hok gene product is a potent cell-killing protein. The hok gene is regulated at the translational level by the sok gene-encoded repressor, a small anti-sense RNA complementary to the hok mRNA. The hok mRNA is extraordinarily stable, while the sok RNA decays rapidly. The mechanism of postsegregational killing is explained by the following model; the sok RNA molecule rapidly disappears in cells that have lost a parB-carrying plasmid, leading to translation of the stable hok mRNA. Consequently, the Hok protein is synthesized and killing of the plasmid-free cell follows.     

Cloning of hok gene into anhydrotetracycline inducible pASK75 vector reveals potent antimicrobial effect of 19 amino acid long N-terminal fragment of hok peptide

An important toxin-antitoxin (TA) system hok/sok, encoded by R1 plasmid of Escherichia coli, is involved in the post segregation killing of cells that have lost the plasmid. The lethal properties of hok protein have been utilized for the environmental containment of microbes and the development of potential vaccine candidates. This study aimed to demonstrate the potent anti-microbial property of a 19 amino acid (AA) long N-terminal fragment of hok peptide. This was accomplished by designing a conditional suicide system based on hok gene expression cloned in an anhydrotetracycline (aTc) inducible vector – pASK75. Heat shock and electroporation were utilized for the transformation of Escherichia coli and Vibrio cholerae cells, respectively. The minimal induction concentration (MI_dC) of aTc, determined by analyzing the expression of green fluorescent protein cloned separately into pASK75 vector, was 30 ng/mL. As hok gene was synthesized de novo (using recombinant polymerase chain reaction) in our study, various random sized hok fragments were generated (as a result of the error-prone nature of Taq polymerase). The smallest hok fragment able to bring about effective antimicrobial killing was a 19 AA long N-terminal fragment of hok having the wild type sequence, except for the carboxy terminus AA residue. The MI_dC of aTc in our experiments was 6-fold lower than previously reported, making our bacterial clones suitable for use in mammalian systems as potential vaccine candidates. Based on our experiments, we hypothesize the 19 AA long N-terminal fragment of hok peptide to be the smallest possible hok fragment sufficient to bring about effective antimicrobial killing.     

Mechanism of postsegregational killing by the hok gene product of the parB system of plasmid R1 and its homology with the relF gene product of the E. coli relB operon.

The parB region of plasmid R1 encodes two genes, hok and sok, which are required for the plasmid-stabilizing activity exerted by parB. The hok gene encodes a potent cell-killing factor, and it is regulated by the sok gene product such that cells losing a parB-carrying plasmid during cell division are rapidly killed. Coinciding with death of the host cell, a characteristic change in morphology is observed. Here we show that the killing factor encoded by the hok gene is a membrane-associated polypeptide of 52 amino acids. A gene located in the Escherichia coli relB operon, designated relF, is shown to be homologous to the hok gene. The relF gene codes for a polypeptide of 51 amino acids, which is 40% homologous to the hok gene product. Induced overexpression of the hok and relF gene products results in the same phenomena: loss of cell membrane potential, arrest of respiration, death of the host cell and change in cell morphology. The parB region and the relB genes were cloned into unstably inherited oriC minichromosomes. Whereas the parB region also conferred a high degree of genetic stability to an oriC minichromosome, the relB operon (with relF) did not; therefore the latter does not appear to 'stabilize' its replicon (the chromosome). The function of the relF gene is not known.     

Antimicrobial properties of the Escherichia coli R1 plasmid host killing peptide

The 52 amino acid host killing peptide (Hok) from the hok/sok post-segregational killer system of the Escherichia coli plasmid R1 was synthesized using Fmoc (9-fluorenylmethoxycarbonyl) chemistry, and its molecular weight was confirmed by mass spectroscopy. Hok kills cells by depolarizing the cytoplasmic membrane when it is made in the cytosol. Six microorganisms, E. coli, Bacillus subtilis, Pseudomonas aeruginosa, P. putida, Salmonella typhimurium, and Staphylococcus aureus were exposed to the purified peptide but showed no significant killing. However, electroporation of Hok (200 microgml(-1)) into E. coli cells showed a dramatic reduction (100000-fold) in the number of cells transformed with plasmid DNA which indicates that the synthetic Hok peptide killed cells. Electroporation of Hok into P. putida was also very effective with a 500-fold reduction in electrocompetent cells (100 microgml(-1)). Heat shock in the presence of Hok (380 microgml(-1)) resulted in a 5-fold reduction in E. coli cells but had no effect on B. subtilis. In addition, three Hok fragments (Hok(1-28), Hok(31-52) and Hok(16-52)) killed cells when electroporated into E. coli at 200 microgml(-1) (over 1000-fold killing for Hok(1-28), 50-fold killing for Hok(16-52) and over 1000-fold killing for Hok(31-52)). E. coli cells electroporated with Hok and visualized using transmission electron microscopy showed the same morphological changes as control cells to which Hok was induced using a plasmid inside the cell.     

Mechanism of post-segregational killing: translation of Hok, SrnB and Pnd mRNAs of plasmids R1, F and R483 is activated by 3''-end processing.

The gene systems hok/sok of R1, srnB of F and pnd of R483 mediate plasmid maintenance by killing of plasmid-free segregants. Translation of the very stable mRNAs encoding the killer proteins is regulated by small unstable antisense RNAs. The differential decay rates of the inhibitory antisense RNAs and the mRNAs encoding the killer proteins is the basis for the onset of killer mRNA translation in newborn plasmid-free segregants and the killing of these cells. We have suggested previously that this requires that the killer mRNAs occur in two forms. A translationally inactive form was proposed to be converted into a 3'-truncated, translationally active mRNA. In the presence of the antisense RNA, translation from this killer mRNA should be inhibited. In this communication we present in vivo and in vitro evidence that support this model. The requirement for 3'-processing for killer gene expression is demonstrated. By using in vitro techniques it is shown that full-length Hok mRNA is translationally inactive, whereas a 3'-end truncated version of the Hok mRNA is translationally active. In vitro secondary structure probing suggests that the 3'-end of the full-length Hok mRNA folds back onto the translational initiation region of the mok gene and thereby inhibits translation of the mRNA. By inference we conclude that the Pnd and SrnB mRNAs are regulated by a similar mechanism.     

Combining the hok/sok, parDE, and pnd postsegregational killer loci to enhance plasmid stability.

To enhance plasmid segregational stability in bacterial cells, two pairs of independent postsegregational killing loci (genes which induce host killing upon plasmid loss) isolated from plasmids R1, R483, or RP4 (hok+/sok+ pnd+ or hok+/sok+ parDE+) were cloned into a common site of the beta-galactosidase expression vector pMJR1750 (ptac::lacZ+) to form a series of plasmids in which the effect of one or two stability loci on segregational plasmid stability could be discerned. Adding two antisense killer loci (hok+/sok+ pnd+) decreased the specific growth rate by 50% though they were more effective at reducing segregational instability than hok+/sok+ alone. With the ptac promoter induced fully (2.0 mM isopropyl-beta-D-thiogalactopyranoside) and no antibiotic selection pressure, the combination of a proteic killer locus (parDE+) with antisense killer loci (hok+/sok+) had a negligible impact on specific growth rate, maintained high beta-galactosidase expression, and led to a 30 and 190% increase in segregational stability (based on stable generations) as compared to plasmids containing either hok+/sok+ or parDE+ alone, respectively. Use of hok+/sok+ or parDE+ alone with high cloned-gene expression led to ninefold and fourfold increases in the number of stable generations, respectively. Two convenient cloning cassettes have been constructed to facilitate cloning the dual hok+/sok+ parDE+ and hok+/sok+ pnd+ killer systems.     

低温菌启动子探针质粒的构建

为了在宿主菌Acinetobacter sp.DWC6中构建低温菌蛋白表达载体,以pBR322质粒为基础,去除质粒上β-内酰胺酶基因的启动子片段,取而代之为来源于质粒pJRD215的卡那霉素抗性基因片段,并在pBR322中插入Acinetobacter菌属特异性ori的DNA片段,构建了能在Acinetobacter sp.DWC6和E.coli中正常复制的启动子探针质粒pBAP1。通过在质粒pBAP1中的β-内酰胺酶基因上游随机导入Acinetobacter sp.DWC6基因组片段,通过检测宿主细胞的氨苄青霉素抗性和β-内酰胺酶活性,来筛选强启动子片段,并分析了启动子探针质粒载体的功能及启动子的强度。     

Exclusion of T4 phage by the hok/sok killer locus from plasmid R1.

The hok (host killing) and sok (suppressor of killing) genes (hok/sok) efficiently maintain the low-copy-number plasmid R1. To investigate whether the hok/sok locus evolved as a phage-exclusion mechanism, Escherichia coli cells that contain hok/sok on a pBR322-based plasmid were challenged with T1, T4, T5, T7, and lambda phage. Upon infection with T4, the optical density of cells containing hok/sok on a high-copy-number plasmid continued to increase whereas the optical density for those lacking hok/sok rapidly declined. The presence of hok/sok reduced the efficiency of plating of T4 by 42% and decreased the plaque size by approximately 85%. Single-step growth experiments demonstrated that hok/sok decreased the T4 burst size by 40%, increased the time to form mature phage (eclipse time) from 22 to 30 min, and increased the time to cell lysis (latent period) from 30 to 60 min. These results further suggest that single cells exhibit altruistic behavior.     

Development of efficient suicide mechanisms for biological containment of bacteria.

To optimize plasmid containment, we have systematically investigated the factors that limit the killing efficiency of a suicide system based on the relF gene from Escherichia coli controlled by inducible lac promoters and placed on plasmids. In induction experiments with this suicide system, killing efficiency was unaffected by temperature and growth medium; there was no requirement for great promoter strength or high plasmid copy number. We could demonstrate that the factors limiting killing were the mutation rate of the suicide function and the reduced growth rate caused by a basal level of expression of the suicide gene during normal growth, which can give a selective growth advantage to cells with mutated suicide functions. The capacity of the plasmid-carried killing system to contain the plasmid was tested in transformation, transduction, and conjugational mobilization. The rate of plasmid transfer detected in these experiments seemed too high to provide adequate biological containment. As expected from the induction experiments, plasmids that escaped containment in these transfer experiments turned out to be mutated in the suicide function. With lac-induced suicide as a test, the efficiency of the system was improved by tightening the repression of the suicide gene, thereby preventing selection of cells mutated in the killing function. Reduction of the mutational inactivation rate of the suicide system by duplication of the suicide function augmented the efficiency of the suicide dramatically. These results permit the construction of extremely efficient biological containment systems.     

Development of efficient suicide mechanisms for biological containment of bacteria

To optimize plasmid containment, we have systematically investigated the factors that limit the killing efficiency of a suicide system based on the relF gene from Escherichia coli controlled by inducible lac promoters and placed on plasmids. In induction experiments with this suicide system, killing efficiency was unaffected by temperature and growth medium; there was no requirement for great promoter strength or high plasmid copy number. We could demonstrate that the factors limiting killing were the mutation rate of the suicide function and the reduced growth rate caused by a basal level of expression of the suicide gene during normal growth, which can give a selective growth advantage to cells with mutated suicide functions. The capacity of the plasmid-carried killing system to contain the plasmid was tested in transformation, transduction, and conjugational mobilization. The rate of plasmid transfer detected in these experiments seemed too high to provide adequate biological containment. As expected from the induction experiments, plasmids that escaped containment in these transfer experiments turned out to be mutated in the suicide function. With lac-induced suicide as a test, the efficiency of the system was improved by tightening the repression of the suicide gene, thereby preventing selection of cells mutated in the killing function. Reduction of the mutational inactivation rate of the suicide system by duplication of the suicide function augmented the efficiency of the suicide dramatically. These results permit the construction of extremely efficient biological containment systems.     

shRNA随机文库结合TK自杀基因筛选靶向HIV-1LTR相关宿主因子

构建shRNA随机文库与HIV-1 LTR启动胸苷激酶基因(TK基因)稳定表达的稳定细胞系HEK293/TK,将两者结合起来,筛选靶向HIV-1 LTR相关宿主因子.方法:通过化学合成含有19个随机脱氧核苷酸的发夹结构,将其退火补平后与合成的接头Linker连接进行PCR反应,将PCR产物酶切后置于慢病毒载体pLenti-U6启动子下游由此构建shRNA随机文库;利用重叠PCR将HIV-1 LTR片段和TK基因连接起来,连接产物经酶切后与pcDNA3.1载体连接;将连接正确的质粒转染HEK293细胞同时用G418加压筛选获得稳定细胞系HEK293/TK;将所获得的文库质粒包装成慢病毒后侵染所构建的HEK293/TK细胞系,通过加入药物GCV进行加压筛选获得存活细胞.结果:成功筛选到加药后存活下来的细胞,抽提细胞基因组,采用巢式PCR扩增目的干扰序列并用Western blot对干扰序列进行验证,鉴定获得一个克隆所表达的shRNA能对TK基因的表达起到抑制作用,通过测序分析获得其干扰序列,该序列很有可能针对HIV-1 LTR某宿主相关因子.结论:成功构建了一种筛选HIV-1 LTR相关宿主因子的方法,筛选所得序列可以定位到具体相关宿主因子,为靶向筛选抗HIV-1药物提供了重要手段.     

Evaluation of the hok/sok killer locus for enhanced plasmid stability

The effectiveness of the hok/sok plasmid stability locus and mechanism of cloned-gene loss was evaluated in shake-flask cultures. Addition of the hok/sok locus dramitically increasedapparent plasmid segregational stability to the hok/sok(-) control. In terms of the number of generations before 10%of the population became plasmid-free, segregational stability was increased by 11- to 20-fold in different media in the absence of induction of the cloned-gene (hok/sok(+) plasmid stable for over 200 generations in all media tested). With constant expression of beta-galactosidase in the absence of an tibiotic, the segregational stability of the plasmid containing hok/sok was incresed more than 17- to 30-fold when beta-galactosidase was expressed at 7-15 wt % of total cell protein. Although the hok/sok system stabilized the plasmid well infour different media (Luria-Bertani (LB), LB glucose, M9C Trp, and a representative fedbatch medium), the ability of hok/sok to maintain the plasmid with induction of the cloned gene decreased as the complexity of the media increased. This result is better interpreted in terms of the influence of cloned-gene expression on plasmidmaintenance; plasmid segregational stability decreased linearly as specificbeta-galactosidase activity increased. (c) 1994 John Wiley & Sons, Inc.     

Construction of tracer plasmids for Bacillus sphaericus 1593 utilizing the xylE gene from Pseudomonas putida

Genetically engineered microorganisms (GEMS) released into the environment must be traceable in order to accurately assess their impact on the area of release. Tracer genes other than those that introduce antibiotic resistance are preferred for use in identifying genetically engineered strains. In this study, we describe the construction of a series of tracer plasmids for use in Bacillus sphaericus using the xylE gene from the Pseudomonas putida TOL plasmid. This gene codes for the enzyme catechol 2,3-dioxygenase which converts the colorless substance catechol to 2-hydroxymuconic semialdehyde, a yellow product which is easily detected. Colonies of cells which express the xylE gene turn yellow shortly after being exposed with a solution of catechol.     

大肠杆菌-长双歧杆菌穿梭载体的构建及PTEN在长双歧杆菌中的表达

长双歧杆菌可特异地定植于实体瘤低氧区,可用做肿瘤靶向性基因治疗的载体,而构建大肠杆菌-长双歧杆菌穿梭质粒则被证明是外源基因在长双歧杆菌中稳定表达的有效途径。为了构建能在长双歧杆菌中稳定表达外源基因的穿梭质粒并检测携带抑癌基因的工程菌对小鼠实体瘤的抑制效果,利用软件设计并合成了48条部分序列相互重叠的引物,通过PCR合成了长双歧杆菌质粒pMB1序列及长双歧杆菌HU启动子区序列,插入克隆载体pMD18-T,构建穿梭载体pMB-HU,该载体可在大肠杆菌DH5α及长双歧杆菌L17中稳定复制。PTEN基因编码具有蛋白质和酯类双重特异性磷酸酶活性的抑癌因子。将PTEN基因cDNA序列插入载体pMB-HU中HU启动子下游,构建重组质粒pMB-HU-PTEN,电击转化长双歧杆菌后,Western blot检测表明,表达产物中存在55kDa的PTEN蛋白特异条带。抑癌试验表明:与对照组相比,携带PTEN基因的长双歧杆菌可显著抑制小鼠实体瘤的生长。上述结果为以长双歧杆菌为载体的实体瘤靶向性基因治疗研究奠定了基础。