Characterization of the mutant lytic state in lambda expression systems

The two propagative phases of bacteriophage lambda, lysogeny and lysis, can be used in concert to enhance productivity of recombinant expression systems. Lambda vectors carrying mutations to prevent both cell lysis and lambda DNA packaging in the lytic state have been shown to yield 100% stability of the product gene in lysogeny and to produce up to 15% of total cell protein as product beta-galactosidase in a mutant lytic state.(14) Despite these mutations, partial lysis of the culture was observed following induction of the cells from a lysogenic phase into the lytic state. To understand better the phage-host cell interactions and to investigate the possible cause(s) of lysis in these highly productive expression systems, we have made a detailed study of the suppressor-free system JM105(NM1070). We have found high levels of product (15% of total cell protein as beta-glactosidase) to be due chiefly to a high-copy number of lambda DNA in the mutant lytic state. There is partial lysis of the culture even in this suppressor-free system caused by a low-level natural suppression of the amber mutation in gene S of NM1070, resulting in accumulation of lambda endolysin. We have also monitored changes in cell growth and morphology upon induction of the lysogen. There is a slight increase in cell number that follows a linear relationship with time and a 25-fold increase in cell volume during recombinat protein production in the mutant lytic state.     

A novel biotinylated degradable polymer for cell-interactive applications

We previously demonstrated that the lambda system integrated into the host chromosome can overcome the instability encountered in continuous operations of unstable plasmid-based expression vectors. High stability of a cloned gene in a lysogenic state and a high copy number in a lytic state provide cloned-gene stability and overexpression in a two-stage continuous operation. But the expression by the commonly used S- mutant lambda was only twice as high as that of the single copy. To increase the expression in the lambda system, we constructed a Q- mutant lambda vector that can be used in long-term operations such as a two-stage continuous operation. The Q- mutant phage lambda is deficient in the synthesis of proteins involved in cell lysis and lambda DNA packaging, while the S- mutant is deficient in the synthesis of one of two phage proteins required for lysis of the host cell and liberation of the progeny phage. Therefore, it is expected that the replicated Q- lambda DNA containing a cloned gene would not be coated by a phage head and would remain naked for ample expression of the cloned gene and host cells would not lyse easily and consequently would produce larger amounts of cloned-gene products. The beta-galactosidase expression per unit cell by the Q- mutant in a lytic state was about 30 times higher than that in a lysogenic state, while the expression by the commonly used S- mutant in a lytic state was twice as high as that in a lysogenic state. The optimal switching time of the Q- mutant from the lysogenic state to the lytic state for the maximum production of beta-galactosidase was 5.3 h, which corresponds to an early log phase in the batch operation.     

Recruitment of host ATP-dependent proteases by bacteriophage lambda

Upon infection of a bacterial cell, the temperate bacteriophage lambda executes a regulated temporal program with two possible outcomes: (1) Cell lysis and virion production or (2) establishment of a dormant state, lysogeny, in which the phage genome (prophage) is integrated into the host chromosome. The prophage is replicated passively as part of the host chromosome until it is induced to resume the lytic cycle. In this review, we summarize the evidence that implicates every known ATP-dependent protease in the regulation of specific steps in the phage life cycle. The proteolysis of specific regulatory proteins appears to fine-tune phage gene expression. The bacteriophage utilizes multiple proteases to irreversibly inactivate specific regulators resulting in a temporally regulated program of gene expression. Evolutionary forces may have favored the utilization of overlapping protease specificities for differential proteolysis of phage regulators according to different phage life styles.     

Protein degradation in E. coli: the lon mutation and bacteriophage lambda N and cII protein stability

The Ion gene of E. coli controls the stability of two bacteriophage lambda proteins. The functional half-life of the phage N gene product, measured by complementation, is increased about 5-fold in Ion mutant strains, from 2 min to 10 min. The chemical half-life of N protein, determined by its disappearance on polyacrylamide gels following pulse-chase labeling, increases about three-fold in Ion cells. In contrast to its effect on the N protein, the Ion mutation produces a 50% decrease in the chemical half-life of cII protein. The decay rate of many other phage proteins, including the unstable gene O product, remains unaffected by a host Ion defect. A Ion mutation alters lambda physiology in two ways. First, upon infection, the phage enters the lytic pathway predominantly. This may result from the deficiency of cII protein caused by its decreased stability, since cII product is required for establishment of lysogeny. Second, brief thermal induction of a Ion (lambda c1857) lysogen leads irreversibly to lysis; repression cannot be restablished and the treated cells are committed to forming infective centers. Although N product is normally required for rapid commitment, Ion lysogens become committed more rapidly than Ion+ lysogens, even in the absence of N function. These results identify for the first time native proteins whose stability is affected by the Lon proteolytic pathway. They also indicate that the Lon system may be important in regulating gene expression in E. coli.     

Two-stage fermentation with bacteriophage lambda as an expression vector in Escherachia coli

The potential of bacteriophage lambda as an expression vector for a large scale production of cloned-gene proteins was evaluated in batch and continuous bioreactors using a temperature-sensitive mutant in the cl gene, which allows a simple manipulation of temperature as a means to control the phage in the lysogenic or lytic state. A temperature switch from 32 degrees C (or below) to 38 degrees C (or above) forces the phage to go from the lysogenic state to the lytic state. Temperature cycling and a two-reactor system were used for continuous cultures. For the latter the first reactor is maintained in the lysogenic state at a lower temperature to stably maintain the foreign DNA in the host cell, while the second reactor is maintained in the lytic state to force replication of the cloned-gene and overproduction of its products. The results are promising but suggest a greater potential for a mutant which lacks the Q gene which is responsible for host cell lysis and packaging of phage particles.     

Lysis protein S of phage lambda functions in Saccharomyces cerevisiae.

The lambda S lysis gene was cloned into a Saccharomyces cerevisiae expression vector under GAL1 control. Induction with galactose in S. cerevisiae terminated cell growth and prevented colony formation. Several membrane proteins immunoreactive with anti-S antibody accumulated in the membranes, indicating that sodium dodecyl sulfate-resistant oligomers of S are formed, similar to those observed in the membranes of Escherichia coli cells killed by expression of the S gene. These observations suggest that the S gene product functions as a cytotoxic protein in the yeast cytoplasmic membrane as it does in the bacterial membrane.     

Functional domains of bacteriophage Mu transposase: properties of C-terminal deletions

We have generated a series of 3' deletions of a cloned copy of the bacteriophage Mu transposase (A) gene. The corresponding truncated proteins, expressed under the control of the lambda PI promoter, were analysed in vivo for their capacity to complement a super-infecting MuAam phage, both for lytic growth and lysogeny, and for their effect on growth of wild-type Mu following infection or induction of a lysogen. Using crude cell extracts, we have also examined binding properties of these proteins to the ends of Mu. The results allow us to further define regions of the protein important in replicative transposition, establishment of lysogeny and DNA binding.     

Control of bacteriophage lambda CII activity by bacteriophage and host functions

We have studied the regulation of the lambda cII gene in vivo using cloned lambda fragments. Lambda N protein stimulated cII expression. Surprisingly, although very high cII protein levels were detected by gel electrophoresis, little cII protein activity, measured as stimulation of the lambda pI and pE promoters, was observed. The half-life of cII protein depended critically on its initial level. At low concentrations its half-life was as short as 1.5 min, whereas at high cII protein levels, it could be as long as 22 min. The Escherichia coli mutant ER437 directs lambda towards lysogeny; cII protein was more stable in this strain than in the wild type. On the other hand, although cyclic AMP is required for efficient lysogeny, it did not appear to influence the synthesis, stability, or activity of cII protein.     

Genetic analysis of the lytic replicon of bacteriophage P1. I. Isolation and partial characterization

Despite the extensive genetic analysis of bacteriophage P1, the region of the viral genome that is responsible for its lytic (vegetative) replication has not been identified. In this paper we describe the identification of various fragments of P1 DNA that can replicate an otherwise replication-defective lambda vector when they are cloned into that vector. The fragments share a 2800 base-pair segment of the P1 genome that is located adjacent to the immI region of the phage. Replication mediated by the cloned P1 fragments is abolished by the product of the P1 c1 gene, the repressor of phage lytic functions. Since these properties resemble those of the P1 lytic replicon, we suggest that the 2800 base-pair segment identified here contains that replicon.     

Genetic and physiological control of host cell lysis by bacteriophage lambda.

The timing of host cell lysis at the end of the lytic cycle of phage lambda is under complex control. The lambda S protein stimulates lysis. Another physiological system, the lysis regulator, inhibitis lysis from occurring prematurely. The effects of a series of phage and bacterial mutations on these controls are described. They show that the lambda rex gene plays a role in regulating lysis under suboptimal growth conditions. In certain mutant cells, and especially under anaerobic culture conditions, the rex gene aids in the scheduling of host cell lysis. The data also suggest that the lysis regulator may control the transition of the lambda S protein from an inactive to an active state.     

Programmed Escherichia coli cell lysis by expression of cloned T4 phage lysis genes

Self-disruptive Escherichia coli that produces foreign target protein was developed. E. coli was co-transformed with two vector plasmids, a target gene expression vector and a lysis gene expression vector. The lytic protein was produced after the expression of the target gene, resulting in simplification of the cell disruption process. In this study, the expression of cloned T4 phage gene e or t was used for the disruption of E. coli that produced beta-glucuronidase (GUS) as a model target protein. The expression of gene e did not lead to prompt cell disruption but weakened the cell wall. Resuspension with deionized water facilitated cell lysis, and GUS activity was observed in the resuspended liquid. Expression of gene e at mid logarithmic growth phase was the optimal induction period for GUS production and release. On the other hand, the expression of gene t induced immediate cell lysis, and intracellular GUS was released to the culture medium. Maximum GUS production was obtained when gene t was induced at late logarithmic growth phase.     

Controllable alteration of cell genotype in bacterial cultures using an excision vector

We have used recombinant DNA techniques to construct a derivative of phage lambda, called an excision vector, which retains only those functions necessary for conditional maintenance of lysogeny and integration/excision. The tyrA+ gene was cloned on this excision vector, integrated into the Escherichia coli chromosome, and stably maintained and expressed under permissive conditions. Upon shift to non-permissive conditions, the excision vector and its passenger gene were very efficiently excised from the chromosome and lost, leaving a culture of Tyr- bacteria. This illustrates a new class of conditional mutations in which the genotype changes in response to external stimuli.     

改造稀有密码子提高SEA蛋白表达量

利用重叠PCR技术突变了sea基因上一个稀有密码子簇,将此段中稀有密码子全部更换成E.coli最常用密码子,得到sea^m。将sea和sea^m分别克隆于7ZTS表达载体上,并转化JM109（DE3）菌株。结果表明,sea基因的表达十分微弱,而sea^m基因的表达量十分高,约占菌体总蛋白的15 ％。表达产物在体内具有一定的抗肿瘤活性。     

Optimization of bacteriophage λQ −-containing recombinant Escherichia coli fermentation process

Q^m mutant phage 5 is deficient in the synthesis of the proteins involved in cell lysis and 5 DNA packaging. As a result, the replicated Q^m 5 DNA containing a cloned gene is not easily coated by a phage head and remains naked for the ample expression of the cloned gene, and also the host cells do not lyse easily and larger amounts of cloned gene products are produced. In a two-phase operation, the first phase is operated at a low temperature to keep the phage in the lysogenic state for cell growth and cloned gene stability, while the second phase is operated at a high temperature to induce the lytic state for the amplification of the cloned gene and overproduction of its product. This two-phase operation was optimized by determining both the optimal temperatures for the growth and production phases and the optimal switching time between the growth to the production phase. The optimal temperatures for growth and production phases were 33 and 40 °C, respectively. The optimal switching time was 3 h. The recombinant #-galactosidase production using this optimal process was about 20 times higher than in the single-copy lysogenic state.