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Modification of EcoRI restriction sites by Caulobacter vibrioides
Gene, 17 (1982) 163-166 Elsevier Biomedical Press
Modification
163
of EcoRI restriction sites by Caulobacter vibrioides
(Plasmid RPl; endonuclease susceptibility; stalked bacteria)
David R. Scholl *, R. Bruce Patterson Jr. and Joseph D. Jo&k Department of Zoology and Microbiology and The College of OsteopathicMedicine, Ohio lJniversity,Athens, OH45701 (U.S.A.) (Received October 14th, 1981) (Accepted November 9th, 1981)
SUMMARY
of EcoRI digestion profiles of plasmid RPl isolated from Caulobacter vibrioides WS48 and Escherichia coli CSH29 demonstrated that EcoRI sites were modified by WS48. A comparison
INTRODUCTION
Two types of DNA modification in bacteriophagehost systems are recognized: hypermodiflcation of DNA, as seen with E. coli phage T4, resulting from the phage-specified methylation of host-derived cytosines (Warren, 1980); and modification of specific nucleotide sequences, affecting the susceptibility of DNA to site-specific restriction endonucleases (Nathans and Smith, 1975). The possibility that Caulobacter vibrioides WS48 might modify EcoRI sites was suggested during characterization of its phage $6. We found that the double-stranded DNA of this phage was EcoRI insen* Present address: Roche Institute of Molecular Biology, Nutley, NJ 07110 (U.S.A.). Address reprint requests to D.R.S. Abbreviations: cfu, colony-forming units; EtBr, ethidium bromide; SDS, sodium dodecyl sulfate.
0378-1119/82/0000-0000/$02.75
0 Elsevier BiomedicalPress
sitive and also that WS48 chromosomal DNA was resistant to this enzyme. Gross chemical modification of phage $6 DNA was not detected by enzymatic digestion and subsequent paper chromatopaphy. However, the possibility of specific minimal modification of the DNA at EcoRI sites could not be excluded. Evidence for methylation of Caulobacter DNA has been reported, but the functional relationship between the methylated nucleotides and restriction endonuclease activity was not addressed (Degnen and Morris, 1973). It was reasonable to assume that if phage $6 DNA was being modified by WS48 then other DNA introduced into this host should undergo similar modification. We selected plasmid RPl, since Alexander and Jollick (1977) previously reported the transfer of this broad-host-range plasmid from Pseudomonas aenrginosa and E. coli to Caulobacter, and since Grinsted et al. (1977) reported the presence of only a single EcoRI site in RPl .
164
MATERIALS
AND METHODS
(d) Isolation
(a) Organisms
of plasmid RPl
Plasmid RPl DNA was extracted from CSH29 and WS48 by a modification of the method of Birnboim
Bacterial strains used in this study, i.e. Caulobacter vibrioides WS48*, Escherichia coli CSH29 and Pseuplasmid RPl ,
domonas aeruginosa PA067, containing as well as bacterial growth conditions detail by Hua et al. (1981).
are described in
Bacteriophage
propaga-
tion was by the agar layer method (Adams, 1959).
and Doly (1979).
Cells were collected
from 1 liter
broth cultures (approx. lo9 cfulml) by centrifugation and the cell pellets from each culture were resuspended
in 36 ml of 50 mM glucose,
10 mM EDTA
and 25 mM Tris, pH 8.0. After adding 80 ml of 0.2 M NaOH and 1% SDS, the solutions were thoroughly mixed, cooled on ice for 10 min and 40 ml of 3 M
(b) Mating procedure
potassium
acetate (pH 4.8) was added. The bacterial
lated on L-agar (per liter: 10 g tryptone, 5 g yeast extract, 0.5 g NaCl, 2 ml 1 N NaOH, 15 g agar and 10
chromosomal DNA precipitate was removed by centrifugation and the supernatant was filtered through sterile Whatman 3 MM filter paper. Plasmid DNA and contaminating RNA in the supernatant were precipitated with 100 ml of isopropanol at -20°C. The plasmid DNA precipitate was rinsed in cold 70% ethanol and air-dried. The dried precipitate was dissolved in 3.8 ml of 10 mM Tris, pH 7.5, 10 mM EDTA to which was added 0.4 ml of a stock EtBr solution (5 mg/ml). This solution was brought to a density of 1.72 g/cm3 by addition of CsCI. The CsClplasmid mixture was centrifuged for 40 h at 17”C, 40 000 rev./min in a Beckman SW 50.1 rotor. Plasmid bands were collected and diluted with 4 ~01s. of distilled water followed by precipitation with 2
ml of a sterile 20% glucose solution)
~01s. of cold 95% ethanol.
Plasmid RPl transfer was by conjugation. Donor and recipient cell titers were adjusted to approximately 3 X lOa cfu/ml, mixed at a donor/recipient ratio of 1 : 10 and then incubated for 3 h, at the optimum growth temperature of the recipient. Mating mixtures were then diluted and plated on appropriate selective media. In the case of transfer of RPl from PA067 to CSH29, transcipients were isolated on minimal thiamine
medium containing tryptophan (40 pg/ml), (5 pg/ml) and kanamycin (2O/.&ml). Plas-
mid RPl was also transferred from C. vibrioides WS48 to CSH29. Transcipients in this cross were iso-
benicillin
(25 /&ml).
containing
Counter-selection
car-
of the CauZo-
batter donor was effected by its inability
to grow on
L-agar. In all cases, newly isolated transcipients
were
tested for kanamycin, tetracycline and carbenicillin resistance as well as susceptibility to the RPl-specific phages PRRl
and PRDl .
(c) Preparation Bacteriophage
of phage $6 DNA $6 suspensions
containing
1O’* pfu/
ml were treated with five cycles of Tris-EDTA-saturated phenol extractions. Phenol was removed from the aqueous DNA fraction by exhaustive dialysis.
The plasmid DNA pellet
was rinsed in cold 70% ethanol, air-dried and dissolved in 200 1.11TNE buffer (50 mM Tris, pH 7.5, 100 mM NaCl and 5 mM EDTA). RNase was added to give 100 E.cg/mland the solution incubated
at 37°C
for 1 h. The solution was brought to 0.5% SDS and protease was added to give 100 pg/ml. Incubation at 37°C was continued for 1 h. The RNased, proteased plasmid preparation was extracted with 1 vol. of phenol and then reprecipitated in cold 95% ethanol. The plasmid precipitate was rinsed with 70% ethanol, air-dried and finally dissolved in 1 mM EDTA, 10 mM Tris, pH 7.5, prior to agarose gel electrophoresis or restriction endonuclease digestion. (e) Agarose gel electrophoresis
* C. vibrioides WS48 is the new designation of C. vibrioides CV6 described in previous publications. The change is made to conform to a uniform Caulobacter strain designation scheme proposed by Dr. B. Ely.
Horizontal gels containing 0.8% agarose were made up in a low salt buffer containing 40 mM Tris-acetate and 2 mM EDTA adjusted to pH 7.9. Gel runs were usually 200 volt-hours constant voltage. Gels were stained with EtBr and photographed using a 300 nm UV light source and Polaroid type 667 film.
165
(f) Restriction
endonuclease
All restriction
endonucleases
Research Laboratories conditions
were
E. coli. The same three bands representing
digestion were from Bethesda
(BRL). Digestion
those
described
buffers and
in the
enzyme
product profile supplied by BRL.
the three
plasmid forms are seen in lane c, whereas only a single band representing linear RPl is seen in lane f. To demonstrate
that our EcoRI digestion protocols were
correct and that the Caulobacfer plasmid RF’1 preparation did not affect restriction we included
an internal
endonuclease
X DNA control
activity with RPl
from Caulobacter in an EcoRI digest. This control is in lane a and shows the three forms of RPI as seen in RESULTS AND DISCUSSION
lanes b and c, as well as the expected
EcoRI frag
ments generated from the h DNA. RPl plasmid DNA isolated from Pseudomonas or Escherichia contains
Lane d contains
the same Caulobacter RPl prepa-
a single EcoRI site and a single
ration as found in the first three lanes; however, it has
Hind111 site (Grinsted et al., 1977), the cleavages of which may be detected by a change in electrophoretic
been treated with HindIII. Hind111 digestion was included because although the site base sequence dif-
mobility as a result of the change from forms I and/or II to linear form III. Fig. 1 shows an agarose gel elec-
fers from that of EcoRI, the base compositions of the sites are identical. The bands representing forms I
trophoresis of EcoR.I and Hind111 digests of plasmid Rpl isolated from both Caulobacter and Escherichia, as well as of phage @6 and h DNA, and appropriate controls. The results indicate that plasmid RPl isolated from Caulobacter is not cleaved by EcoRI,
and II are no longer present and a heavy form III band is seen, as would be expected of a plasmid with
whereas that isolated from Escherichia is linearized. Both plasmid preparations are cleaved by HindIII. Lanes b and e, containing untreated RPl from Caulobacfer and Escherichia, respectively, show the same three bands representing the three plasmid forms. Lane c showsEcoRI-treated plasmid RPl from Caulobatter, and lane f shows EcoRI-treated plasmid from
a single Hind111 site. As expected, in lane g, Hind111 digestion of the E. coli plasmid also results in the change of forms I and II to linear form III. Lanes h, i, and k contain phage $6 DNA. Lane h, the untreated control, lane i the EcoRI digest and lane k the Hind111 digest, are identical in electrophore tic mobility. To assure that the EcoRI resistance of plasmid RI’1 derived from C. vibrioides WS48 was due to a host-specified modification and not the result of selection for a mutant plasmid, we also established the EcoRI restriction pattern of RPl that had been introduced
into E. coli CSH29 from WS48. Although
the EcoRI
did not cleave the plasmid isolated from
WS48, the EcoRI susceptibility
was reestablished
by
transfer of RI’1 from WS48. Fig. 2 shows an agarose gel electrophoresis of EcoRI and Hind111 digests of plasmid RPl isolated from E. coli that had received the plasrnid from WS48 (lanes d-f) and from Pseudomonas (lanes g-i), as well as RPl from WS48 (lanes a-c). Lanes a, d, and g represent the untreated controls. Lanes b, e, and h are the EcoRI-treated samples and lanes c, f, and i are the HindIII-treated Fig. 1. Agarose-gel electrophoresis of restrictionendonuclease digests of plasmid RPl from C. vibrioidesWS48 and E. coli CSH29 and of 06 DNA. a, RPl from WS48 + h DNA + EcoRI; b, RPl from WS48 untreated control; c, RPl from WS48 + EcoRI; d, RPl from WS48 +HindIII; e, RPl from CSH29 untreated control; f, RPl from CSH29 + EcoRI; g, RPl from CSH29 +HindIII; h, ~6 DNA untreated control; i, 06 DNA + EcoRI; k, @6 DNA + HindIII.
samples. The results described in this communication indicate that C. vibrioides WS48 has the capacity to modify the EcoRI site of plasmid RPl. The resistance of phage $6 DNA could be due to the modification of EcoRI sites or the absence of this specific sequence in the DNA. Further study will be required to deter-
date whether
a functional
correlation
exists between
these two observations.
ACKNOWLEDGEMENTS
We thank Dr. Christine discussions
K. Shewmaker
for helpful
and Ms. Mary C. Walker for excellent
technical assistance.
Fig. 2. Agarose-gel electrophoresis of restrictionendonuclease digests of plasmid RPl from C. vibrioides WS48 (a-c) and E. coli CSH29 transcipients derived from matings with WS48-containing RPl (d-t) and Paeruginosa PA067containing RPl (g-i), a, RPl from WS48 untreated control; b, RPl from WS48+EcoRI; c, RPl from WS48+ifindIII; d, RPl from CSH29 untreated control; e, RPl from CSH29+ EcoRI; f, RPl from CSH29+HindIII; g, RPl from CSH29 untreated control; h, RPl from CSH29 + EcoRI; i, RPl from CSH29 +HindIII.
mine which case exists. Additionally, this study does not identify the nature of the modification. The capacity of WS48 to modify EcoRI restriction endonuclease sites is, however, to the best of our knowledge, the first report of a sequence-specific modification of DNA in Caulobacter. This finding is of additional interest since the report by Hua et al. (198 l), which showed functional modification of the plasmid RPl-specified pilus by C. vibrioides WS48. Further study is required to eluci-
REFERENCES Adams, M.H.: Bacteriophages, pp. 134-162. Interscience, New York, 1959. Alexander, J.L. and Jollick, J.D.: Transfer and expression of Pseudomonas plasmid RPl in Caulobacter. J. Gen. Microbiol. 99 (1977) 325-331. Birnboim, H.D. and Doly, J.: A rapid alkaline extraction procedure for screening recombinant plasmid DNA. Nucl. Acids Res. 7 (1979) 1513-1523. Degnen, S.T. and Morris, N.R.: Deoxyribonucleic acid methylation and development in Caulobacter bacteroides. J. Bacterial. 116 (1973) 48-53. Grinsted, J., Bennett, P.M. and Richmond, M.H.: A restriction enzyme map of the R plasmid RPl. Plasmid 1 (1977) 34-37. Hua, T.-C., Scholl, D.R. and Jollick, J.D.: Functional modification of the plasmid RPl-specified pilus by Caulobatter vibrioides. J. Gen. Microbial. 124 (1981) i19128. Nathans, D. and Smith, H.P.: Restriction endonucleases in the analysis and restructuring of DNA molecules. Annu. Rev. Biochem. 44 (1975) 273-293. Warren, R.A.J.: Modified bases in bacteriophage DNAs. Annu. Rev. Microbial. 34 (1980) 137-158. Communicated
by A.M. Skalka.
Modification
163
of EcoRI restriction sites by Caulobacter vibrioides
(Plasmid RPl; endonuclease susceptibility; stalked bacteria)
David R. Scholl *, R. Bruce Patterson Jr. and Joseph D. Jo&k Department of Zoology and Microbiology and The College of OsteopathicMedicine, Ohio lJniversity,Athens, OH45701 (U.S.A.) (Received October 14th, 1981) (Accepted November 9th, 1981)
SUMMARY
of EcoRI digestion profiles of plasmid RPl isolated from Caulobacter vibrioides WS48 and Escherichia coli CSH29 demonstrated that EcoRI sites were modified by WS48. A comparison
INTRODUCTION
Two types of DNA modification in bacteriophagehost systems are recognized: hypermodiflcation of DNA, as seen with E. coli phage T4, resulting from the phage-specified methylation of host-derived cytosines (Warren, 1980); and modification of specific nucleotide sequences, affecting the susceptibility of DNA to site-specific restriction endonucleases (Nathans and Smith, 1975). The possibility that Caulobacter vibrioides WS48 might modify EcoRI sites was suggested during characterization of its phage $6. We found that the double-stranded DNA of this phage was EcoRI insen* Present address: Roche Institute of Molecular Biology, Nutley, NJ 07110 (U.S.A.). Address reprint requests to D.R.S. Abbreviations: cfu, colony-forming units; EtBr, ethidium bromide; SDS, sodium dodecyl sulfate.
0378-1119/82/0000-0000/$02.75
0 Elsevier BiomedicalPress
sitive and also that WS48 chromosomal DNA was resistant to this enzyme. Gross chemical modification of phage $6 DNA was not detected by enzymatic digestion and subsequent paper chromatopaphy. However, the possibility of specific minimal modification of the DNA at EcoRI sites could not be excluded. Evidence for methylation of Caulobacter DNA has been reported, but the functional relationship between the methylated nucleotides and restriction endonuclease activity was not addressed (Degnen and Morris, 1973). It was reasonable to assume that if phage $6 DNA was being modified by WS48 then other DNA introduced into this host should undergo similar modification. We selected plasmid RPl, since Alexander and Jollick (1977) previously reported the transfer of this broad-host-range plasmid from Pseudomonas aenrginosa and E. coli to Caulobacter, and since Grinsted et al. (1977) reported the presence of only a single EcoRI site in RPl .
164
MATERIALS
AND METHODS
(d) Isolation
(a) Organisms
of plasmid RPl
Plasmid RPl DNA was extracted from CSH29 and WS48 by a modification of the method of Birnboim
Bacterial strains used in this study, i.e. Caulobacter vibrioides WS48*, Escherichia coli CSH29 and Pseuplasmid RPl ,
domonas aeruginosa PA067, containing as well as bacterial growth conditions detail by Hua et al. (1981).
are described in
Bacteriophage
propaga-
tion was by the agar layer method (Adams, 1959).
and Doly (1979).
Cells were collected
from 1 liter
broth cultures (approx. lo9 cfulml) by centrifugation and the cell pellets from each culture were resuspended
in 36 ml of 50 mM glucose,
10 mM EDTA
and 25 mM Tris, pH 8.0. After adding 80 ml of 0.2 M NaOH and 1% SDS, the solutions were thoroughly mixed, cooled on ice for 10 min and 40 ml of 3 M
(b) Mating procedure
potassium
acetate (pH 4.8) was added. The bacterial
lated on L-agar (per liter: 10 g tryptone, 5 g yeast extract, 0.5 g NaCl, 2 ml 1 N NaOH, 15 g agar and 10
chromosomal DNA precipitate was removed by centrifugation and the supernatant was filtered through sterile Whatman 3 MM filter paper. Plasmid DNA and contaminating RNA in the supernatant were precipitated with 100 ml of isopropanol at -20°C. The plasmid DNA precipitate was rinsed in cold 70% ethanol and air-dried. The dried precipitate was dissolved in 3.8 ml of 10 mM Tris, pH 7.5, 10 mM EDTA to which was added 0.4 ml of a stock EtBr solution (5 mg/ml). This solution was brought to a density of 1.72 g/cm3 by addition of CsCI. The CsClplasmid mixture was centrifuged for 40 h at 17”C, 40 000 rev./min in a Beckman SW 50.1 rotor. Plasmid bands were collected and diluted with 4 ~01s. of distilled water followed by precipitation with 2
ml of a sterile 20% glucose solution)
~01s. of cold 95% ethanol.
Plasmid RPl transfer was by conjugation. Donor and recipient cell titers were adjusted to approximately 3 X lOa cfu/ml, mixed at a donor/recipient ratio of 1 : 10 and then incubated for 3 h, at the optimum growth temperature of the recipient. Mating mixtures were then diluted and plated on appropriate selective media. In the case of transfer of RPl from PA067 to CSH29, transcipients were isolated on minimal thiamine
medium containing tryptophan (40 pg/ml), (5 pg/ml) and kanamycin (2O/.&ml). Plas-
mid RPl was also transferred from C. vibrioides WS48 to CSH29. Transcipients in this cross were iso-
benicillin
(25 /&ml).
containing
Counter-selection
car-
of the CauZo-
batter donor was effected by its inability
to grow on
L-agar. In all cases, newly isolated transcipients
were
tested for kanamycin, tetracycline and carbenicillin resistance as well as susceptibility to the RPl-specific phages PRRl
and PRDl .
(c) Preparation Bacteriophage
of phage $6 DNA $6 suspensions
containing
1O’* pfu/
ml were treated with five cycles of Tris-EDTA-saturated phenol extractions. Phenol was removed from the aqueous DNA fraction by exhaustive dialysis.
The plasmid DNA pellet
was rinsed in cold 70% ethanol, air-dried and dissolved in 200 1.11TNE buffer (50 mM Tris, pH 7.5, 100 mM NaCl and 5 mM EDTA). RNase was added to give 100 E.cg/mland the solution incubated
at 37°C
for 1 h. The solution was brought to 0.5% SDS and protease was added to give 100 pg/ml. Incubation at 37°C was continued for 1 h. The RNased, proteased plasmid preparation was extracted with 1 vol. of phenol and then reprecipitated in cold 95% ethanol. The plasmid precipitate was rinsed with 70% ethanol, air-dried and finally dissolved in 1 mM EDTA, 10 mM Tris, pH 7.5, prior to agarose gel electrophoresis or restriction endonuclease digestion. (e) Agarose gel electrophoresis
* C. vibrioides WS48 is the new designation of C. vibrioides CV6 described in previous publications. The change is made to conform to a uniform Caulobacter strain designation scheme proposed by Dr. B. Ely.
Horizontal gels containing 0.8% agarose were made up in a low salt buffer containing 40 mM Tris-acetate and 2 mM EDTA adjusted to pH 7.9. Gel runs were usually 200 volt-hours constant voltage. Gels were stained with EtBr and photographed using a 300 nm UV light source and Polaroid type 667 film.
165
(f) Restriction
endonuclease
All restriction
endonucleases
Research Laboratories conditions
were
E. coli. The same three bands representing
digestion were from Bethesda
(BRL). Digestion
those
described
buffers and
in the
enzyme
product profile supplied by BRL.
the three
plasmid forms are seen in lane c, whereas only a single band representing linear RPl is seen in lane f. To demonstrate
that our EcoRI digestion protocols were
correct and that the Caulobacfer plasmid RF’1 preparation did not affect restriction we included
an internal
endonuclease
X DNA control
activity with RPl
from Caulobacter in an EcoRI digest. This control is in lane a and shows the three forms of RPI as seen in RESULTS AND DISCUSSION
lanes b and c, as well as the expected
EcoRI frag
ments generated from the h DNA. RPl plasmid DNA isolated from Pseudomonas or Escherichia contains
Lane d contains
the same Caulobacter RPl prepa-
a single EcoRI site and a single
ration as found in the first three lanes; however, it has
Hind111 site (Grinsted et al., 1977), the cleavages of which may be detected by a change in electrophoretic
been treated with HindIII. Hind111 digestion was included because although the site base sequence dif-
mobility as a result of the change from forms I and/or II to linear form III. Fig. 1 shows an agarose gel elec-
fers from that of EcoRI, the base compositions of the sites are identical. The bands representing forms I
trophoresis of EcoR.I and Hind111 digests of plasmid Rpl isolated from both Caulobacter and Escherichia, as well as of phage @6 and h DNA, and appropriate controls. The results indicate that plasmid RPl isolated from Caulobacter is not cleaved by EcoRI,
and II are no longer present and a heavy form III band is seen, as would be expected of a plasmid with
whereas that isolated from Escherichia is linearized. Both plasmid preparations are cleaved by HindIII. Lanes b and e, containing untreated RPl from Caulobacfer and Escherichia, respectively, show the same three bands representing the three plasmid forms. Lane c showsEcoRI-treated plasmid RPl from Caulobatter, and lane f shows EcoRI-treated plasmid from
a single Hind111 site. As expected, in lane g, Hind111 digestion of the E. coli plasmid also results in the change of forms I and II to linear form III. Lanes h, i, and k contain phage $6 DNA. Lane h, the untreated control, lane i the EcoRI digest and lane k the Hind111 digest, are identical in electrophore tic mobility. To assure that the EcoRI resistance of plasmid RI’1 derived from C. vibrioides WS48 was due to a host-specified modification and not the result of selection for a mutant plasmid, we also established the EcoRI restriction pattern of RPl that had been introduced
into E. coli CSH29 from WS48. Although
the EcoRI
did not cleave the plasmid isolated from
WS48, the EcoRI susceptibility
was reestablished
by
transfer of RI’1 from WS48. Fig. 2 shows an agarose gel electrophoresis of EcoRI and Hind111 digests of plasmid RPl isolated from E. coli that had received the plasrnid from WS48 (lanes d-f) and from Pseudomonas (lanes g-i), as well as RPl from WS48 (lanes a-c). Lanes a, d, and g represent the untreated controls. Lanes b, e, and h are the EcoRI-treated samples and lanes c, f, and i are the HindIII-treated Fig. 1. Agarose-gel electrophoresis of restrictionendonuclease digests of plasmid RPl from C. vibrioidesWS48 and E. coli CSH29 and of 06 DNA. a, RPl from WS48 + h DNA + EcoRI; b, RPl from WS48 untreated control; c, RPl from WS48 + EcoRI; d, RPl from WS48 +HindIII; e, RPl from CSH29 untreated control; f, RPl from CSH29 + EcoRI; g, RPl from CSH29 +HindIII; h, ~6 DNA untreated control; i, 06 DNA + EcoRI; k, @6 DNA + HindIII.
samples. The results described in this communication indicate that C. vibrioides WS48 has the capacity to modify the EcoRI site of plasmid RPl. The resistance of phage $6 DNA could be due to the modification of EcoRI sites or the absence of this specific sequence in the DNA. Further study will be required to deter-
date whether
a functional
correlation
exists between
these two observations.
ACKNOWLEDGEMENTS
We thank Dr. Christine discussions
K. Shewmaker
for helpful
and Ms. Mary C. Walker for excellent
technical assistance.
Fig. 2. Agarose-gel electrophoresis of restrictionendonuclease digests of plasmid RPl from C. vibrioides WS48 (a-c) and E. coli CSH29 transcipients derived from matings with WS48-containing RPl (d-t) and Paeruginosa PA067containing RPl (g-i), a, RPl from WS48 untreated control; b, RPl from WS48+EcoRI; c, RPl from WS48+ifindIII; d, RPl from CSH29 untreated control; e, RPl from CSH29+ EcoRI; f, RPl from CSH29+HindIII; g, RPl from CSH29 untreated control; h, RPl from CSH29 + EcoRI; i, RPl from CSH29 +HindIII.
mine which case exists. Additionally, this study does not identify the nature of the modification. The capacity of WS48 to modify EcoRI restriction endonuclease sites is, however, to the best of our knowledge, the first report of a sequence-specific modification of DNA in Caulobacter. This finding is of additional interest since the report by Hua et al. (198 l), which showed functional modification of the plasmid RPl-specified pilus by C. vibrioides WS48. Further study is required to eluci-
REFERENCES Adams, M.H.: Bacteriophages, pp. 134-162. Interscience, New York, 1959. Alexander, J.L. and Jollick, J.D.: Transfer and expression of Pseudomonas plasmid RPl in Caulobacter. J. Gen. Microbiol. 99 (1977) 325-331. Birnboim, H.D. and Doly, J.: A rapid alkaline extraction procedure for screening recombinant plasmid DNA. Nucl. Acids Res. 7 (1979) 1513-1523. Degnen, S.T. and Morris, N.R.: Deoxyribonucleic acid methylation and development in Caulobacter bacteroides. J. Bacterial. 116 (1973) 48-53. Grinsted, J., Bennett, P.M. and Richmond, M.H.: A restriction enzyme map of the R plasmid RPl. Plasmid 1 (1977) 34-37. Hua, T.-C., Scholl, D.R. and Jollick, J.D.: Functional modification of the plasmid RPl-specified pilus by Caulobatter vibrioides. J. Gen. Microbial. 124 (1981) i19128. Nathans, D. and Smith, H.P.: Restriction endonucleases in the analysis and restructuring of DNA molecules. Annu. Rev. Biochem. 44 (1975) 273-293. Warren, R.A.J.: Modified bases in bacteriophage DNAs. Annu. Rev. Microbial. 34 (1980) 137-158. Communicated
by A.M. Skalka.