Identifying key factors using λ contribution analysis

1. Key factor analysis is widely used as the first step in analysing census data to identify factors responsible for population change, but is generally considered to be flawed. The conceptual problems can be overcome by assessing the effects of variation in the life-history parameters on population growth rate, λ. We refer to this as λ-contribution analysis. The difference from key factor analysis is that now each life history parameter is weighted by the sensitivity of λ to that parameter. The rationale for this modification is that population growth rate is the best available measure of population change.
2. The advantages of the new method are: that it correctly assesses the effects of life history parameters on population growth rate; that birth rates are included in the analysis in a natural way without making arbitrary assumptions about birth rate mortalities; that post-reproductive individuals who do not contribute to population growth rate are zero-weighted; and that the analysis can be applied to populations with overlapping generations.
3. It is proposed that λ-contribution analysis should replace conventional key-factor analysis as the first step in a wider analysis of population change and density dependence. λ-contribution analysis also links census studies of natural populations with the use of life-table response experiments.     

Electrotransfection of Escherichia coli with λgt10 DNA

We have used electroporation to introduce lambda gt10 DNA into E. coli C600 (Electrotransfection). We obtained approximately 10(7) pfu (plaque forming units) per micrograms of lambda gt10 DNA. This frequency is 100-fold higher than the maximum reported for classical calcium chloride-induced transfection. We have also compared electrotransfection with in vitro packaging in cloning experiments using relatively small amounts (less than or equal to 10 ng) of DNA. Our results slow that electrotransfection can generate approximately 1000-fold more plaques than in vitro packaging at these concentrations.     

Virus DNA packaging: the strategy used by phage λ

Phage λ, like a number of other large DNA bacterio-phages and the herpesviruses, produces concatemeric DNA during DNA replication. The concatemeric DNA is processed to produce unit-length, virion DNA by cutting at specific sites along the concatemer. DNA cutting is coordinated with DNA packaging, the process of translocation of the cut DNA into the preformed capsid precursor, the prohead. A key player in the λ DNA packaging process is the phage-encoded enzyme terminase, which is involved in (i) recognition of the concatemeric λ DNA; (ii) initiation of packaging, which includes the introduction of staggered nicks at cosN to generate the cohesive ends of virion DNA and the binding of the prohead; (iii) DNA packaging, possibly including the ATP-driven DNA translocation; and (iv) following translocation, the cutting of the terminal cosN lo complete DNA packaging. To one side of cosN is the site cosB, which plays a role in the initiation of packaging; along with ATP, cosB stimulates the efficiency and adds fidelity to the endo-nuclease activity of terminase in cutting cosN. cosB is essential for the formation of a post-cleavage complex with terminase, complex I, that binds the prohead, forming a ternary assembly, complex II. Terminase interacts with cosN through its large subunit, gpA, and the small terminase subunit, gpNul, interacts with cosB. Packaging follows complex II formation. cosN is flanked on the other side by the site cosQ, which is needed for termination, but not initiation, of DNA packaging. cosQ is required for cutting of the second cosN, i.e. the cosN at which termination occurs. DNA packaging in λ has aspects that differ from other λ DNA transactions. Unlike the site-specific recombination system of λ, for DNA packaging the initial site-specific protein assemblage gives way to a mobile, translocating complete, and unlike the DNA replication system of λ, the same protein machinery is used for both initiation and translocation during λ DNA packaging.     

Molecular function of the dual-start motif in the λ S holin

The lambda S gene represents the prototype of holin genes with a dual-start motif, which leads to the synthesis of two polypeptides, S105 and S107. They differ at their N-terminus by only two amino acids, Met-1 and Lys-2, at the beginning of the longer product. Despite the minor difference, the two proteins have opposing functions in lysis, with protein S107 being an inhibitor and protein S105 being an effector of 'hole formation' in the inner membrane. Here, we have studied the molecular mechanism underlying the 'lysis clock' contributed by the dual-start motif. We have used protein fusions in which the secretory signal sequence of the M13 procoat protein VIII has been abutted to the N-terminal Met residues of S105 and S107 respectively. S-dependent 'hole formation' required removal of the signal sequence in both fusion proteins, as both the VIII-S105 and the VIII-S107 fusion proteins were non-functional when leader peptidase cleavage was inhibited. These results strongly supported the hypothesis that functional assembly of S proteins requires translocation of their N-terminus to the periplasm. Using signal sequence cleavage as a measure of translocation, we observed that the translocation kinetics of the N-terminus of the S107 moiety was reduced about threefold when compared with the N-terminus of the S105 moiety. Moreover, depolarization of the membrane resulted in an immediate cleavage of the signal sequence and 'hole formation' exerted by the S107 moiety of the VIII-S107 fusion protein. A model is presented in which S107 with a reversed topology of its N-terminus interacts with S105 and poisons 'hole formation'. Upon depolarization of the membrane, translocation of the N-terminus of S107 to the periplasm results in the functional assembly of S proteins, i.e. 'hole formation'.     

The role of the OOP antisense RNA in coliphage λ development

We have made a derivative of bacteriophage lambda that makes no OOP antisense RNA. The mutant phage carries a point mutation that inactivates the OOP promoter, po. The phages lambda + and lambda po- have identical plaque morphologies, one-step growth curves, and frequencies of lysogenization of a sensitive host. OOP RNA synthesis is weakly repressed by the Escherichia coli LexA protein. Consonant with this inducibility of OOP RNA synthesis by ultraviolet light, we find a two-fold greater phage burst following ultraviolet induction of a lambda + than of a lambda po- prophage. In lambda + infections, OOP RNA causes two cleavage events in cll mRNA: one is in the 3'-end of the coding region, and the second is in the intercistronic region between the cll and O genes. The cll gene fragments are subject to additional hydrolytic events, and cll mRNA levels are several-fold lower in lambda + than in lambda po- infections late in the infection cycle. However, O mRNA levels are almost unaffected by the po- mutation.     

Mutations in the terminase genes of bacteriophage λ that bypass the necessity for FI

DNA maturation in bacteriophage λ is the process by which the concatemeric precursor DNA is cleaved at sites called cos to generate mature λ DNA molecules. These DNA molecules are then packaged into procapsids, the empty capsid precursors. The enzyme that catalyses these events is λ DNA terminase. It is composed of two subunits, made of 181 and 641 amino acids, the products of genes Nu1 and A, respectively. The product of the FI gene (gpFI ) stimulates the formation of an intermediate in capsid assembly called complex II, which contains a procapsid, terminase and DNA. The mechanism of stimulation remains unknown. It has been suggested that gpFI may also stimulate terminase-mediated cos cleavage, in the absence of procapsids, by increasing enzyme turnover. Mutants in FI fail to mature and package DNA but, in comparison with other capsid gene mutants, FI mutants are leaky. Second site mutants of FI phages, called ‘fin’ (for FI independence), bypass the necessity for gpFI. These mutants were originally localized to the region of Nu1 and A and are of two classes: finA includes those that induce the synthesis of fourfold more gene A product (gpA ) than wild-type phages, and finB includes those that produce normal amounts of gpA. Whereas all finA mutants analysed map to Nu1, finB mutants have been found both in E and in Nu1. The existence of E mutants able to bypass the necessity for gpFI in vivo shows that gpE and gpFI interact, directly or indirectly. Here we have analysed and sequenced two finA mutants and one finB mutant. All of these map in Nu1. Of the two finA mutants, one corresponds to an Ala163Ser change and the other is a silent mutation. It is likely that the finA mutations alter mRNA conformation in a manner that results in an increase in the efficiency of A mRNA translation. The fourfold increase in gpA synthesis translates into a 10-fold increase in terminase activity. These results show that terminase overproduction is sufficient to bypass the necessity for gpFI and that such an overproduction can be achieved by changes in the efficiency of translation of A due to subtle changes in the sequence upstream of the gene. The finBcs₁₀₃ mutation is a His-87→Tyr change in Nu1. Therefore, an alternative way in which to bypass the requirement for gpFI involves an alteration in the structure of gpNu1. It is likely that the altered gpNu1 would increase cleavage and packaging efficiency directly or indirectly. We have determined that DNA cleavage in vivo does not occur in the absence of gpFI. Therefore it seems that gpFI somehow facilitates an otherwise latent capacity of terminase to autoactivate its nucleolytic activity.     

A lamB expression plasmid for extending the host range of phage λ to other enterobacteria

Abstract We have constructed a multicopy plasmid vector (pAMH62) expressing lamB , the gene coding for the phage λ receptor protein in Escherichia coli . In this construction, the lamB structural gene was fused to the ompR promoter of E. coli . The ompR promoter was employed because: (i) it can function in other gram negative bacteria; (ii) it expresses lamB in a multicopy state at a level comparable to that of maltose-induced chromosomal lamB in E. coli . The vector pAMH62 was tested in E. coli and Salmonella typhimurium . In both cases the LamB protein was produced in similar amounts, was properly integrated to the outer membrane and was functional as phage λ receptor. Thus pAMH62 should provide a useful tool for extending the host range of phage λ and λ-derived vectors to other Gram-negative bacteria.     

Regulation of copy number and stability of phage λ derived pTCλ1 plasmid in the light of the dimer/multimer catastrophe hypothesis

The dimer catastrophe hypothesis has been proposed previously to explain instability of multicopy plasmids whose partitioning is random, contrary to low copy number plasmids which are stably maintained and actively partitioned. Until now, this hypothesis has been investigated using multicopy ColE1 plasmids. However, for more detailed testing of the dimer/multimer catastrophe hypothesis, one should use a plasmid which can be maintained at either low or high copy number and still possesses the same mechanism of replication regulation. Here we used a modified lambda plasmid, pTC lambda 1. The advantage of this plasmid is that it can be maintained at different copy numbers depending on the concentration of an inducer which stimulates the initiation of plasmid replication. Results obtained with this plasmid in recombination proficient and deficient cells generally support the dimer/multimer catastrophe hypothesis, but also suggest some modification in the model.     

The int genes of bacteriophages P22 and λ are regulated by different mechanisms

Bacteriophage P22 and λ are related bacteriophages with similar gene organizations. In λ the cII-dependent P_I promoter is responsible for λint gene expression. The only apparent counterpart to P_I in P22 is oriented in the opposite direction, and cannot transcribe the P22 int gene. We show that this promoter, called P_al, is active both in vivo and in vitro, and is dependent upon the P22 cII-like gene, called c1. We have also determined the DNA sequence of a 3.3 kb segment that closes the gap between previously reported sequences to give a continuous sequence between the P22 p_L promoter and the int gene. The newly determined sequence is densely packed with genes from the p_L direction, and the proteins predicted by the sequence show excellent correlation with the proteins mapped by Youderian and Susskind in 1980. However, the sequence contains no apparent genes in the opposite (p_al) direction, and no additional binding motifs for the P22 c1 protein. We conclude that int gene expression in P22 is regulated by a different mechanism than in λ.     

Characterization of a Labile Naloxone Binding Site (λ Site) in Rat Brain

A high-affinity binding site selective for naloxone and other 4,5-epoxymorphinans (lambda site) has been previously described in rat brain. Following homogenization of freshly dissected brain, the lambda sites convert from a high-affinity to a low-affinity state. When measured with [3H]naloxone, the decay is very rapid at 20 degrees C (t 1/2 less than 2 min), whereas it is progressively slowed at lower temperatures. Proteinase inhibitors, antoxidants, and sulfhydryl group-protecting agents failed to prevent this conversion. Kinetic measurements of mu and lambda binding at varying temperatures demonstrated that the decrease in lambda binding does not coincide with the concurrent increase in mu binding and that the loss of high-affinity lambda binding at 20 degrees C can be partially restored when the temperature is lowered to 0 degrees C. The low-affinity state of the lambda site is rather stable in the Tris buffer homogenates and is susceptible to digestion by a protease. The (-)-isomer of WIN 44,441, a benzomorphan drug, binds to lambda sites with moderate affinity (dissociation constant, KD = 63 nM), whereas the (+)-isomer does not (KD greater than 10,000 nM), thus establishing stereoselectivity of the binding process. Neither the high-affinity nor the low-affinity state of lambda binding is significantly affected by the presence of 100 mM sodium chloride or 50 microM Gpp(NH)p, (a GTP analog), which is in contrast to the dramatic effect of these agents on the established opioid receptor system. Naltrexone, naloxone, nalorphine, and morphine (in this order of decreasing potency) bind to the lambda site in vivo in intact rat brain over dosage ranges that are commonly employed in pharmacological studies.     

What makes the bacteriophage λ Red system useful for genetic engineering: molecular mechanism and biological function

Recent studies have generated interest in the use of the homologous recombination system of bacteriophage lambda for genetic engineering. The system, called Red, consists primarily of three proteins: lambda exonuclease, which processively digests the 5'-ended strand of a dsDNA end; beta protein, which binds to ssDNA and promotes strand annealing; and gamma protein, which binds to the bacterial RecBCD enzyme and inhibits its activities. These proteins induce a 'hyper-rec' state in Escherichia coli and other bacteria, in which recombination events between DNA species with as little as 40 bp of shared sequence occur at high frequency. Red-mediated recombination in the hyper-rec bacterium proceeds via a number of different pathways, and with the involvement of different sets of bacterial proteins, depending in part on the nature of the recombining DNA species. The role of high-frequency double-strand break repair/recombination in the life cycle of the lambdoid phages is discussed.     

A novel Ti-plasmid-convertible λ phage vector system suitable for gene isolation by genetic complementation of Arabidopsis thaliana mutants

A new λ phage vector system, λTI, has been constructed to facilitate genetic complementation of higher plant mutations. The λTI vectors are stable, and by using the Cre— lox site-specific recombination, are automatically convertible into Ti-plasmid binary vectors which are capable of expressing genes in higher plants. Two λTI vectors were constructed: (i) λTI1, which can generate a Ti-plasmid that contains the cauliflower mosaic virus (CaMV) 35S promoter and is suitable for the expression of cDNA in transformed plants and (ii) λTI2, which can generate a Ti-plasmid with the multicloning site (MCS). cDNA and genomic libraries, which were constructed from the cruciferous plant Arabidopsis thaliana in these λTI vectors, can be probed by large DNA fragments of more than 100 kb, such as yeast artificial chromosomes (YACs), enabling the direct screening of the clones in the chromosome region containing a specified genetic locus. These libraries will certainly become powerful tools for the genetic complementation of Arabidopsis mutant phenotypes by quickly providing transformation-competent clones.     

Mutations of the coat protein gene of bacteriophage λ that overcome the necessity for the FI gene; the EFi domain

The functions of most of the 10 genes involved in phage λ capsid morphogenesis are well understood. The function of the FI gene is one of the exceptions. Mutants in FI fail to mature and package DNA. The gene product (gpFI) seems to act as a catalyst for the formation of an intermediate in capsid assembly called complex II, which contains a procapsid (an empty capsid precursor), terminase (the enzyme that cleaves the DNA precursor and packages it into the procapsid) and DNA. The mechanism for this stimulation remains unknown. It has also been reported that gpFI appeared to stimulate terminase-mediated cos cleavage, in the absence of procapsids, by increasing enzyme turnover. In comparison with other head-gene mutants, FI mutants are leaky, producing approx. 0.1 phage per infected cell. Some second-site revertants of FI ^? phages, called ‘fin’, that bypass the necessity for gpFI, have been isolated and found to harbour a mutation in the genes that code for the two subunits of terminase. In the course of mapping additional fin mutants, it was discovered that some mapped outside the terminase genes. To localize the mutations, restriction fragments of fin mutant DNAs were subcloned into plasmids and their ability to contribute to fin function was determined by marker-rescue analysis. The location of the fin mutation was further delineated by deletion analysis of a plasmid that was positive for fin. This showed that some fin mutations mapped to a region comprising genes E, D and a portion of C. The sequencing of this entire region in several fin isolates showed that the fin mutations are clustered in a small region of gene E corresponding to a portion of 26 amino acid residues of the coat protein (gpE). We have called this region of the protein the EFi domain. All the mutations result in an increase in positive charge relative to the wild-type protein. These results suggest that DNA maturation and packaging are in part controlled by an interaction between gpFI and capsid gpE.     

Response of Escherichia coli cell membranes to induction of λc1857 prophage by heat shock

Heat shock induces protein aggregation in Escherichia coli and E. coli (lambda cl857). The aggregates (S fraction) appear 15 min post-induction and are separable from membranes by sucrose density-gradient centrifugation. The S fraction quickly disappears in wild type strains but persists in rpoH mutant with concomitant quick inner membrane destruction. We propose that: (1) the disappearance of the S fraction reflects a rpoH-dependent processing, (2) the membrane destruction explains the lethality of the rpoH mutation at elevated temperatures; and (3) the protection of the inner membrane integrity is an important physiological function of the heat-shock response. We assume that the S fraction of aggregated proteins represents the signal inducing the heat-shock response. The prophage thermo-induction results in an increase (35 min post-induction) in the A fraction resembling that of the adhesion zones of the membranes. This fraction is greater than the corresponding fraction from uninduced cells. The increase is mediated by the lambda late genes, since it is absent in the induced E. coli (lambda cl857 Qam21). Since heat shock is widely used for induction of the lambda promoters in expression vectors it is possible that the formation of the protein aggregates (though transient in WT strains) and/or the fragility of membranes in rpoH mutants may be the cause of poor expression of cloned genes or may lead to mistaken localization of their expression products.