Physical characterization of bacteriophage MX4, a generalized transducing phage for Myxococcus xanthus.

A generalized transducing bacteriophage of Myxococcus xanthus has been examined. The phage particle consists of an isometric head and a contractile tail. The genome of the phage is a linear DNA molecule of molecular weight 39 ± 2.1 × 10⁶, which contains the normal DNA bases 70% of which are guanosine + cytosine. No overall heterogeneity of base composition is present. The DNA does not carry easily detectable cohesive ends nor is it cyclically permuted. It does contain a large and somewhat variable terminal redundancy. Heating phage particles in the presence of EDTA causes tail sheath contraction and ejection of DNA, some of which remains attached to the tail. Digestion of tail-bound DNA with restriction enzymes shows that the phage tail can be attached to either end of the DNA. Thus the DNA probably contains recognition sites for the packaging of its DNA at both ends. These results suggest possible mechanisms for the genesis of transducing particles by phage MX4.     

Unused protein synthetic capacity of Escherichia coli grown in phosphate-limited chemostats

When solutions of bacteriophage λ are treated with a water-soluble carbodiimide (CMC), then lysed with formamide and observed with the electron microscope, over 90% of the DNA molecules are found to be attached to phage heads and tails. Sedimentation analysis shows that lysis is complete, and denaturation mapping shows that the right-hand end² of the DNA, and never the left-hand end, is attached to the phage tails. When the carbodiimide-treated phage are lysed and the DNA cleaved with RI endonuclease, the shortest fragment, which contains the right end of λ DNA, is as expected the only fragment found attached to the tails. Comparison of the length of the tail-linked fragment with the length of the free DNA fragment shows that the DNA does not extend to the end of the tail. It does appear to intrude a short distance (30% of the length of the tail, or 130 DNA base-pairs), but this distance is just at the limit of resolution. When phage are placed in 80% formamide and then immediately spread for electron microscopy, about 10% of the phage have partially ejected DNA. Denaturation mapping shows that it is the right end of the DNA which is ejected first.     

Head length determination in bacteriophage T4: The role of the core protein P22

We have found that two different temperature-sensitive mutations in gene 22, tsA74 and ts22-2, produce high frequencies (up to 85%) of petite phage particles when grown at a permissive or intermediate temperature. Moreover, the ratio of petite to normal particles in a lysate depends upon the temperature at which the phage are grown. These petite phage particles appear to have approximately isometric heads when viewed in the electron microscope, and can be distinguished from normal particles by their sedimentation coefficient and by their buoyant density in CsCl. They are biologically active as detected by their ability to complement a co-infecting amber helper phage. Lysates of both mutants grown at a permissive temperature reveal not only a significant number of petite phage particles in the electron microscope, but also sizeable classes of wider-than-normal particles, particles having abnormally attached tails, and others having more than one tail.Striking protein differences exist between the purified phage particles of tsA74 or ts22-2 and wild-type T4. B1¹, a 61,000 molecular weight head protein, is completely absent from the phage particles of both mutants, and the internal protein IPIII¹ is present in reduced amounts as compared to wild type. The precursor to B1¹ is present in the lysates, but these mutations appear to prevent its incorporation into heads, so it does not become cleaved.The product of gene 22 (P22) is known to be the major protein of the morphogenetic core of the T4 head. Besides the mutations reported here, several mutations which affect head length have been found in gene 23, which codes for the major capsid protein (Doermann et al., 1973b). We suggest a model in which head length is determined by an interaction between the core (P22 and IPIII) and the outer shell (P23).     

Multiple density classes of phage P1 due to tetramer formation

Summary Stocks of coliphage P1 contain infective phage particles (P1), a smaller morphological variant (pP1) and single phage tails. In crude stocks and under certain conditions these particles form stable aggregates of four by adhesion of their base plates. It happens that all the aggregates of P1, pP1 and tails having densities above 1.41 g/cm³ are distributed around five values: 1.422, 1.435, 1.450, 1.459 and 1.473 g/cm³. Consequently they form five rather distinct bands when examined by analytical centrifugation. Formation and dissociation of tetramers results in loss and recovery of phage infectivity. Tetramers formed of four P1 particles have a sedimentation constant of 1,185 S as compared to 715 S for single P1 particles. Within the limits of our methods we could not detect any P1 or pP1 particles containing amounts of DNA different from 10^–16 g and 4×10^–17 g, respectively.     

Mechanism of head assembly and DNA encapsulation in Salmonella phage p22. I. Genes, proteins, structures and DNA maturation

The functions of ten known late genes are required for the intracellular assembly of infectious particles of the temperate Salmonella phage P22. The defective phenotypes of mutants in these genes have been characterized with respect to DNA metabolism and the appearance of phage-related structures in lysates of infected cells. In addition, proteins specified by eight of the ten late genes were identified by sodium dodecyl sulfate/polyacrylamide gel electrophoresis; all but two are found in the mature phage particle. We do not find cleavage of these proteins during morphogenesis.The mutants fall into two classes with respect to DNA maturation; cells infected with mutants of genes 5, 8, 1, 2 and 3 accumulate DNA as a rapidly sedimenting complex containing strands longer than mature phage length. 5^? and 8^? lysates contain few phage-related structures. Gene 5 specifies the major head structural protein; gene 8 specifies the major protein found in infected lysates but not in mature particles. 1^?, 2^? and 3^? lysates accumulate a single distinctive class of particle (“proheads”), which are spherical and not full of DNA, but which contain some internal material. Gene 1 protein is in the mature particle, gene 2 protein is not.Cells infected with mutants of the remaining five genes (10, 26, 16, 20 and 9) accumulate mature length DNA. 10^? and 26^? lysates accumulate empty phage heads, but examination of freshly lysed cells shows that many were initially full heads. These heads can be converted to viable phage by in vitro complementation in concentrated extracts. 16^? and 20^? lysates accumulate phage particles that appear normal but are non-infectious, and which cannot be rescued in vitro.From the mutant phenotypes we conclude that an intact prohead structure is required to mature the virus DNA (i.e. to cut the overlength DNA concatemer to the mature length). Apparently this cutting occurs as part of the encapsulation event.     

Orientation of the DNA in the filamentous bacteriophage f1

The filamentous bacteriophage f1 consists of a molecule of circular single-stranded DNA coated along its length by about 2700 molecules of the B protein. Five molecules of the A protein and five molecules of the D protein are located near or at one end of the virion, while ten molecules of the C protein are located near or at the opposite end. The two ends of the phage can be separated by reacting phage fragments, which have been generated by passage of intact phage through a French press, with antibody directed against the A protein (Grant et al., 1981a). By hybridizing the DNA isolated from either end of ³²P-labeled phage to specific restriction fragments of fl replicative form I DNA, we have determined that the single-stranded DNA of the filamentous bacteriophage f1 is oriented within the virion. For wild-type phage, the DNA that codes for the gene III protein is located at the A and D protein end and that which corresponds to the intergenic region is located close to the C protein end of the particle. The intergenic region codes for no protein but contains the origins for both viral and complementary strand DNA synthesis. Analysis of the DNA orientation in phage in which the plasmid pBR322 has been inserted into different positions within the intergenic region of fl shows that the C protein end of all sizes of filamentous phage particles appears to contain a common sequence of phage DNA. This sequence is located near the junction of gene IV and the intergenic region, and probably is important for normal packaging of phage DNA into infectious particles. There appears to be no specific requirement for the origins of viral and complementary strand DNA synthesis to be at the end of a phage particle.     

Integration of the plasmid prophages P1 and P7 into the chromosome of Escherichia coli.

The prophages of the related temperate bacteriophages P1 and P7, which normally exist as plasmids, suppress Escherichia coli dnaA (ts) mutants by integrating into the host chromosome. The locations of the sites on the prophage used for integrative recombination were identified by restriction nuclease analysis and DNA-DNA hybridization techniques. The integration of P1 and P7 often involves a specific site on the host DNA and a specific site on the phage DNA; the latter is probably the end of the phage genetic map. When this site is utilized, the host Rec⁺ function is not required. In Rec⁺ strains, P1 and P7 may also recombine with homologous regions on the host chromosome; at least one of these regions is an IS1 element. In some integration events, prophage deletions are observed which are often associated with inverted repeat structures on the phage DNA. Thus, P1 and P7 may employ one of several different mechanisms for integration.     

Mechanism of head assembly and DNA encapsulation in Salmonella phage P22. II. Morphogenetic pathway

We have identified and characterized structural intermediates in phage P22 assembly. Three classes of particles can be isolated from P22-infected cells: 500 S full heads or phage, 170 S empty heads, and 240 S “proheads”. One or more of these classes are missing from cells infected with mutants defective in the genes for phage head assembly. By determining the protein composition of all classes of particles from wild type and mutant-infected cells, and examining the time-course of particle assembly, we have been able to define many steps in the pathway of P22 morphogenesis.In pulse-chase experiments, the earliest structural intermediate we find is a 240 S prohead; it contains two major protein species, the products of genes 5 and 8. Gene 5 protein (p5) is the major phage coat protein. Gene 8 protein is not found in mature phage. The proheads contain, in addition, four minor protein species, PI, P16, P20 and PX. Similar prohead structures accumulate in lysates made with mutants of three genes, 1, 2 and 3, which accumulate uncut DNA. The second intermediate, which we identify indirectly, is a newly filled (with DNA) head that breaks down on isolation to 170 S empty heads. This form contains no P8, but does contain five of the six protein species of complete heads. Such structures accumulate in lysates made with mutants of two genes, 10 and 26.Experiments with a temperature-sensitive mutant in gene 3 show that proheads from such 3^? infected cells are convertible to mature phage in vivo, with concomitant loss of P8. The molecules of P8 are not cleaved during this process and the data suggest that they may be re-used to form further proheads.Detailed examination of 8^? lysates revealed aberrant aggregates of P5. Since P8 is required for phage morphogenesis, but is removed from proheads during DNA encapsulation, we have termed it a scaffolding protein, though it may have DNA encapsulation functions as well.All the experimental observations of this and the accompanying paper can be accounted for by an assembly pathway, in which the scaffolding protein P8 complexes with the major coat protein P5 to form a properly dimensioned prohead. With the function of the products of genes 1, 2 and 3, the prohead encapsulates and cuts a headful of DNA from the concatemer. Coupled with this process is the exit of the P8 molecules, which may then recycle to form further proheads. The newly filled heads are then stabilized by the action of P26 and gene 10 product to give complete phage heads.     

The lambda head-tail joining reaction: purification, properties and structure of biologically active heads and tails

Procedures were developed to obtain biologically active lambda heads and tails at high purity with 20 to 40% recovery. Free heads, free tails and phage particles differ markedly in stability. Phage are stable in solutions containing Mg²⁺ but tails are not. The protein subunits which form the shaft of the tail dissociate in the presence of Mg²⁺ and form multisubunit spherical structures. EDTA protects free tails against inactivation but disrupts heads and phage particles. The four carbon diamine, putrescine, stabilizes heads against inactivation; the three and five carbon diamines are less effective. Electron micrographs reveal a new “knob” structure at the distal end of the tail fiber of phage and of free tails. Tails released from EDTA-disrupted phage possess a “head-tail connector”, a structure not present on the tail before its joining with a head.     

Packaging of an oversize transducing genome by Salmonella phage P22

The DNA in specialized transducing particles of the Salmonella phage P22 was examined by electron microscopy. The transducing particles of P22Tc-10 (which transduce tetracycline-resistance) are shown to contain DNA molecules that are incomplete permuted fragments of an oversize genome, as predicted by the genetic results of Chan et al. (1972). The oversize transducing genome differs from the P22 wild-type genome by a large (mol. wt 2.5 × 10⁶) insertion of foreign DNA. The insertion, as seen in heteroduplexes, has an unusual lariat-like structure, which suggests that the insertion contains a non-tandem reverse duplication.By comparing wild-type P22 with P22Tc-10 and deletion revertants of P22Tc-10, we show by direct physical means, that the amount of terminal repetition in P22 phage DNA is a direct function of the genome size, as predicted from the model for circular permutation and terminal repetition suggested by Streisinger et al. (1967).     

Studies on the structure, protein composition and aseembly of the neck of bacteriophage T4

We have developed an osmotic shock procedure which disconnects the tail from the head of intact bacteriophage T4, leaving the neck region attached to the tail. Purification of these necked tails permitted detailed structural observations of the neck and the collar/whisker complex attached to it, as well as comparison by gel electrophoresis with tails lacking the neck. Five or six neck proteins were found: N1 (M_r = 52,000; 39 copies/phage) is the product of the wac³ gene (Pwac), forms both the collar and six whiskers as a multimeric fibrous protein, and probably assembles onto phage after head to tail joining; N2 (M_r= 35,000; 5 to 6 copies/phage), N3 (M_r= 33,000; 17 copies/phage) identified here as P13, and N6 (M_r= 28,000; 10 to 11 copies/phage) are all assembled in heads prior to tail joining; N4 (M_r= 32,000; 6 to 9 copies/phage) is unusual in that it is present in wac or wac⁺ phage and necked tails but is absent from purified heads; N5 (M_r =29,000) is probably P14 and like N4 is not found in heads. However, while we find one to two copies of N5 per necked tail, we have not observed it in phage.An aberrant neck structure called the extension assembles on the distal end of the tail connector late (after 33 min, 30 °C) in head-defective, mutant-infected cells. The extension contains five of the six neck proteins (N2 is absent), and blocks head to tail joining in vitro. Mutations in genes 13 and 14, and the double mutant 49:Wac block extension assembly.Other results show that the wac mutant E727J is an amber lesion, and that Pwac can assemble on collarless, wac phage in vitro.     

Inhibition and eradication of Salmonella Typhimurium biofilm using P22 bacteriophage,EDTA and nisin

Abstract

P22 phage >10⁵ PFU ml^?1 could be used to inhibit Salmonella Typhimurium biofilm formation by 55–80%. Concentrations of EDTA >1.25?mM and concentrations of nisin >1,200?µg ml^?1 were also highly effective in reducing S. Typhimurium biofilm formation (≥96% and ≥95% reductions were observed, respectively). A synergistic effect was observed when EDTA and nisin were combined whereas P22 phage in combination with nisin had no synergistic impact on biofilm formation. Triple combination of P22 phage, EDTA and nisin could be also used to inhibit biofilm formation (≥93.2%) at a low phage titer (10² PFU ml^?1), and low EDTA (1.25?mM) and nisin (9.375?µg ml^?1) concentrations. A reduction of 70% in the mature biofilm was possible when 10⁷ PFU ml^?1 of P22 phage, 20?mM of EDTA and 150?μg ml^?1 of nisin were used in combination. This study revealed that it could be possible to reduce biofilm formation by S. Typhimurium by the use of P22 phage, EDTA and nisin, either alone or in combination. Although, removal of the mature biofilm was more difficult, the triple combination could be successfully used for mature biofilm of S. Typhimurium.     

Plaque forming specialized transducing phage P1: Isolation of P1CmSmSu, a precursor of P1Cm

Summary E. coli strains lysogenic for various types of P1-R hybrids were isolated. These carry all the essential genes for vegetative phage production and lysogenization including P1 immunity and P1 incompatibility, together with drug resistance genes derived from the R plasmid NR1. In particular, P1Cm and P1CmSmSu derivatives were studied. When strains lysogenic for these phages were induced in the absence of helper phage, yields of phage particles as high as with wild type P1 were obtained. All P1Cm phages isolated were of plaque forming type and usually every plaque contained Cm^r lysogens. Lysates of P1CmSmSu lysogens transduced Cm^rSm^rSu^r at high frequency and they formed plaques with an efficiency of 10^-4 to 10^-2 per phage particle. Only a minority of these plaques contained drug resistant bacteria. Cm^rSm^rSu^r transductants isolated from bacteria infected at a high multiplicity with phage P1CmSmSu were lysogens for the original P1CmSmSu. In contrast, Cm^rSm^rSu^r transductants isolated after infection at low multiplicity appeared to carry the Cm^rSm^rSu^r markers integrated into the host chromosome. The results described suggest that P1CmSmSu prophages carry the resistance genes transposed into the P1 genome without in principle causing a loss of essential gene functions. However, since these prophages are longer than the wild type P1 genome, the DNA packaged into phage particles has a reduced redundancy which seriously affects the reproduction and lysogenization abilities.Plaque forming P1Cm can be obtained from P1CmSmSu. Thus, P1CmSmSu is a precursor of P1Cm. P1Cm is also obtainable from P1 and NR1 under the recA ^- condition. The mechanism of formation of plaque forming P1Cm is discussed.     

EcoRI analysis of bacteriophage P22 DNA packaging.

Bacteriophage P22 linear DNA molecules are a set of circularly permuted sequences with ends located in a limited region of the physical map. This mature form of the viral chromosome is cut in headful lengths from a concatemeric precursor during DNA encapsulation. Packaging of P22 DNA begins at a specific site, which we have termed pac, and then proceeds sequentially to cut lengths of DNA slightly longer than one complete set of P22 genes (Tye et al., 1974b). The sites of DNA maturation events have been located on the physical map of EcoRI cleavage sites in P22 DNA. EcoRI digestion products of mature P22 wild-type DNA were compared with EcoRI fragments of two deletion and two insertion mutant DNAs. These mutations decrease or increase the length of the genome, but do not alter the DNA encapsulation mechanism. Thus the position of mature molecular ends relative to EcoRI restriction sites is different in each mutant, and comparison of the digests shows which fragments come from the ends of linear molecules. From the positions of the ends of molecules processed in sequential headfuls, the location of pac and the direction of encapsulation relative to the P22 map were deduced. The pac site lies in EcoRI fragment A, 4.1 × 10³ base-pairs from EcoRI cleavage site 1. Sequential packaging of the concatemer is initiated at pac and proceeds in the counterclockwise direction relative to the circular map of P22. One-third of the linears in a population are cut from the concatemer at pac, and most packaging sequences do not extend beyond four headfuls.Fragment D is produced by EcoRI cleavage at a site near the end of a linear chromosome which has been encapsulated starting at pac. The position of the pac site is therefore defined by one end of fragment D. The pac site is not located near genes 12 and 18, the only known site for initiation of P22 DNA replication, but lies among late genes at a position on the physical gene map approximately analogous to the cohesive end site (cos) of bacteriophage λ at which λ DNA is cleaved during encapsulation. Our results suggest that P22 and λ DNA maturation mechanisms have many common properties.     

Electron microscope study of the structures of the Bacillus subtilis prophages, SPO2 and phi105

Circular duplex structures of the correct length are observed in the electron microscope in hybridization mixtures of lysogen DNA and mature phage DNA for the case of the temperate Bacillus subtilis bacteriophage SPO2. This result shows that the sequence order of the prophage is a circular permutation of that of the mature phage. By making heteroduplexes of prophage DNA with that of the SPO2 deletion mutants, R90 and S25, the att site of the phage has been mapped at 61.2 ± 0.6% from one end of the mature phage DNA, which has a length of 38,600 base pairs. In the same co-ordinate system, the R90 deletion extends from 58.9 ± 0.7 to 66.8 ± 0.8% on the SPO2 chromosome, whereas the S25 deletion extends from 63.2 ± 0.6 to 66.9 ± 0.7%. In similar experiments with lysogen and mature phage DNA's of the temperate B. subtilis phage, φ105, no circular structures were seen. This result shows that the sequence order in the prophage and the phage are colinear, without circular permutation.     

Lethal modifications of DNA via the transmutation of32P and33P incorporated in the genome of the S13 bacteriophage

Summary When circular single-stranded DNA of phage S13 is labelled with³²P or³³P, the transmutations very efficiently bring about a loss of phage infectiousness (efficiency = 1 for³²P and 0.73 for³³P). For both radionuclides, the lethal efficiencies as well as the lethal events are different. In the case of³²P, the lethal event is the loss of the circular integrity of the DNA molecule, occurring as a consequence of a systematic single strand-break caused by each³²P decay (100%). Conversely, in the case of³³P, the lethal events are either a single strand-break (40%) or a local stereochemical modification (33%). The same primary event, the substitution at each³³P decay of a phosphate by a sulfate molecule, leads to one of these lethal events in relation to the decay site. Moreover, neither the phage adsorption nor its genome injection into bacteria depends on the physical state of the genome, and thus lethality is revealed at only the genetic level.     

Bacteriophage T4 Head Morphogenesis IV. Comparison of Gene 16-, 17-, and 49-Defective Head Structures2

Defective heads present in extracts of bacteriophage T4 gene 16, 17, or 49 mutant-infected cells have been characterized. All appeared as empty shells when examined by negative-stain electron microscopy and showed essentially the same polypeptide pattern on sodium dodecyl sulfate-acrylamide gels. However, when analyzed by several other methods, gene 16- and 17-defective heads were shown to differ markedly from phage heads present in gene 49-defective extracts. First, the gene 16- and 17-defective structures were found to possess a large number of attached tails (50%, rather than about 5%). Second, they contained less nuclease-resistant deoxyribonucleic acid (DNA) (3 versus 18% of a phage equivalent), had a smaller sedimentation coefficient (240 versus 315S), and a lighter density (1.31 vs. 1.34 g/ml) than gene 49-defective heads. Third, they were not attached to the intracellular DNA pool through a deoxyribonuclease-sensitive linkage. Finally, 8-nm diameter capsomers were clearly revealed on the surface of many gene 16- and 17-defective structures. There was a total of 305 ± 25 capsomers per particle, which yielded an approximate molecular weight of 84 × 10⁶ for these heads. The capsomers were presumably not seen on gene 49-defective heads because of the large amount (18%) of associated DNA.     

Tests of spool models for DNA packaging in phage lambda

Experiments are reported which bear on two spool models proposed for packaging the DNA of phage lambda. Both spool models fill an assumed spherical cavity with DNA wrapped in cylindrical or quasi-cylindrical layers composed of adjacent circular turns. In the curved-spool model, a single continuous segment of DNA, about 20% of the DNA length and probably located near the left end of the DNA, is in contact with the coat protein of the phage capsid. In the straight spool model, there are several DNA segments in contact with the capsid; they are concentrated in one half (probably the left half) of lambda DNA. We have identified the loci on the DNA which are in contact with the capsid by chemical crosslinking, induced by ultraviolet-irradiation of phage containing 5-bromodeoxyuridine in place of thymine.In an electron microscope experiment, phage are first lysed with EDTA, and then spread in a cytochrome c film by the formamide method. The disrupted capsid, which has the appearance of a phage ghost, serves as a marker showing where the DNA is crosslinked to the coat. The left end of the DNA is not distinguished from the right end, and so the map of DNA-capsid contacts is folded over on itself. Contacts are found nearly randomly over the entire map.In a second experiment, DNA from lysed, crosslinked phage is cut either with EcoRI or HindIII restriction endonucleases and the cut restriction fragments are labeled at their ends with ³²P. Density centrifugation in a CsCl gradient separates free DNA from restriction fragments crosslinked to protein. After digestion with proteinase k, the DNA fragments previously crosslinked to protein are identified by size after agarose gel electrophoresis. DNA fragments from all parts of the genome are found.These two experiments show that, if the DNA of each phage is packaged identically, then the curved-spool model is ruled out and the straight spool model is unlikely. Alternatively, the manner of packaging the DNA may vary from one phage to the next. These results agree with other recent experiments on λ DNA packaging by Hall & Schellman (1982a,b), and by Haas et al. (1982).A different experiment is also reported. The psoralen derivative aminomethyltrioxalen (AMT) is allowed to intercalate into λ phage and then the DNA strands are crosslinked by ultraviolet-irradiation after the rapid phase of AMT intercalation is complete. The DNA is subsequently denatured by glyoxal modification and spread for electron microscopy in a cytochrome c film by the formamide method. Sites of AMT crosslinking appear duplex; uncrosslinked regions appear as single-stranded loops. AMT is found to intercalate throughout the λ DNA. Patterns of reacted sites appear different from one DNA molecule to the next, and no consistent pattern can be found. More extensive intercalation occurs with the deletion mutant λb221 than with phage of wild-type DNA length, and free DNA shows much more reaction than the DNA inside either phage type. In order for intercalation to occur, the DNA helix must unwind and become further extended. This experiment shows that regions throughout the entire DNA molecule can unwind and be extended by intercalation, which is not confined to a single DNA segment or to segments in one half of the DNA molecule, as would be expected for the two spool models if only the DNA in contact with the capsid were accessible to the dye.     

Distribution of "minor" nicks in bacteriophage T5 DNA.

Bacteriophage T5 DNA can be released from the phage particle in such a way that one end of 5 to 10% of the DNA molecules remains attached to either the phage head or tail. Under partial denaturation conditions, the DNA preferentially denatures in the vicinity of a nick so that the nicks can be located relative to the end that remains attached to the phage head or tail. Two classes of nicks were found. "Major" nicks were those found in more than 20% of the molecules and were located at the same points along the DNA molecule as reported by others. "Minor" nicks were found in 5 to 10% of the molecules and often occurred at specific locations near a "major" nick.