Title: Natural transformation of the filamentous cyanobacterium Phormidium 1
lacuna 2
Running title: Natural transformation of Phormidium lacuna 3
Authors: Fabian Nies, Marion Mielke, Janko Pochert, Tilman Lamparter 4
Affiliation: Botanical Institute, Karlsruhe Institute of Technology (KIT), Fritz Haber Weg 4, 76131 5
Karlsruhe, Germany 6
Corresponding author: Tilman Lamparter, e-mail [email protected] 7
8
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Abstract 9
Research for biotechnological applications of cyanobacteria focuses on synthetic pathways and 10
bioreactor design, while little effort is devoted to introduce new, promising organisms in the field. 11
Applications are most often based on recombinant work, and the establishment of transformation 12
can be a risky, time-consuming procedure. In this work we demonstrate the natural transformation 13
of the filamentous cyanobacterium Phormidium lacuna and insertion of a selection marker into the 14
genome by homologous integration. This is the first example for natural transformation of a member 15
of the order Oscillatoriales. We found that Phormidium lacuna is polyploid, each cell has about 20-16
100 chromosomes. Transformed filaments were resistant against up to 15 mg/ml of kanamycin, and 17
the high resistance feature allowed for rapid segregation into all chromosomes. Formerly, natural 18
transformation in cyanobacteria has been considered a rare and exclusive feature of a few unicellular 19
species. Our finding suggests that natural competence is more distributed among cyanobacteria than 20
previously thought. This is supported by bioinformatic analyses which show that all protein factors 21
for natural transformation are present in the majority of the analyzed cyanobacteria. 22
23
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Introduction 24
Biotechnology oriented research with cyanobacteria ranges from the production of low-cost material 25
like bulk chemicals or biofuels (1) to high-value compounds like pharmaceutics (2). Advancements in 26
cyanobacterial biotechnology are based on continued optimization of photobioreactors, the 27
introduction and improvement of metabolic pathways by recombinant DNA technology, and the 28
search for suitable organisms (3, 4). The establishment of protocols for gene transfer can be 29
challenging for new cyanobacteria, because of barriers like extracellular materials and nucleases 30
(reviewed in (5)). There are three common methods for gene transfer into cyanobacteria: 31
electroporation, conjugation, and natural transformation (NT). For NT, cells have to be in a 32
physiological state, termed natural competence, in which the recipient cell is able to actively 33
transport DNA into the cytoplasm. Protocols for NT are generally simple and straight forward (6, 7), 34
but only few naturally competent cyanobacteria (NCC) are known: diverse Synechococcus (8, 9) and 35
Synechocystis (10, 11) strains, Microcystis aeruginosa PCC 7806 (12) and Thermosynechococcus 36
elongatus BP-1 (13). These cyanobacteria have a unicellular lifestyle, and NT was frequently 37
described as a unique feature of few unicellular cyanobacteria (6, 14, 15). We also found one report 38
about NT of the filamentous cyanobacterium Nostoc muscorum (16), but are not aware of other 39
filamentous cyanobacteria. 40
Natural transformation in bacteria is dependent on pil proteins of type IV pili. Furthermore, the 41
competence proteins ComEA, ComEC, and ComF as well as the DNA processing protein DprA and the 42
DNA recombination and repair protein RecA are essential (17-19). For the cyanobacterium 43
Synechocystis sp. PCC 6803 , comEA, comF, pilA1, pilB1, pilD, pilM, pilN, pilO, pilQ, and pilT1 knockout 44
mutants are deficient in NT (20-23). Although in a recent survey, homologs of these and other 45
competence related genes were found in most cyanobacterial genomes (24) there is so far no 46
experimental evidence for NT in a novel species since more than a decade. 47
Most cyanobacteria possess multiple chromosomes per cell (25-29). After transformation, 48
homologous recombination results in the integration into one chromosome. Segregation into the 49
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other chromosomes can be achieved by selection on increasing antibiotic concentrations. Until 50
complete segregation is achieved, the transformants may be unstable and the integrated sequences 51
can be lost again under nonselective conditions (30, 31). 52
In this work we established an NT protocol for Phormidium lacuna, a filamentous cyanobacterium of 53
the order Oscillatoriales, a species isolated and characterized by our workgroup as a promising 54
candidate for biotechnological applications (32). This is to our knowledge the first transformation 55
protocol for the genus Phormidium and the first report of NT for the order Oscillatoriales. 56
Phormidium lacuna was transformed by the integration of the kanamycin (Kn) resistance cassette 57
(kanR) into the genome via homologous recombination. Clones were selected by Kn resistance and 58
integration into genome was validated by PCR. During clone validation it was found that Phormidium 59
lacuna is polyploid. This was confirmed by a DAPI fluorescence assay. By comprehensive BLAST 60
analysis based on sequences of essential proteins for natural transformation (natural transformation 61
factors, NTFs) we predict that a large fraction of cyanobacteria might be naturally transformable. 62
63
Methods 64
Plasmids for transformation 65
For transformation studies, we constructed plasmids with a Phormidium lacuna sequence sc_7_37 66
(position 37 in DNA scaffold 7) that is interrupted in the middle by a kanamycin resistance cassette. A 67
1138 bp and a 2167 bp product were generated by PCR using Q5 polymerase (NEB, Ipswich, MA, 68
USA) and HE10DO DNA as template. The primer pairs were t256: CGTGCGAGACTCAACCCAAAC / 69
t257: GAAACCTGATCGAACCGTTTTAC for the short sequence and F114: TTGTTCGAGGCAGTTGCG / 70
F115: TGACAATGGGGTGGAGGG for the long sequence. The sequences were integrated into pGEM-T 71
(Madison, WI, Promega, USA). The Phormidium lacuna sc_7_37 sequence encodes for a putative 72
hydrogenase (WP_087706519); the sequence of the strain used in the present study, HE10DO, is 73
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identical with Phormidium lacuna HE10JO for which the genome sequence is established (32). pGEM-74
T plasmids are not propagated in cyanobacteria due to incompatible origin of replication (33). 75
The kanamycin resistance cassette kanR was PCR amplified from pUC4K (34) using the primer pair 76
GG1: CAACAAGAAGACGGAACCTAGGCACCCCAGGCTTTACAC / GG2: 77
CAACAAGAAGACGCAAACTTTGCTTTGCCACGGAACGG. The plasmid with the long sc_7_37 insert was 78
amplified with the primers GG3: CAACAAGAAGACCCGTTTGCGAGGCTAAAGGC / GG: 4 79
CAACAAGAAGACACGGTTCCCACTCCCAAAGC. The resulting plasmid pFN_7_37_2k_kanRn was 80
generated by the type IIS restriction enzyme BbsI and T4 DNA ligase (both NEB, USA). Another 81
version of kanR with slightly different 5´ and 3´UTR was generated by PCR using the primer pair F13: 82
CAACAATCTAGACTCGTATGTTGTGTGGAATTG / F14: CAACAAGCTAGCCAAGTCAGCGTAATGCTCTG. This 83
cassette was inserted in the plasmids with the long and the short homologous sc_7_37 sequence. 84
Plasmids were amplified with the primer pair F5: CAACAAGCTAGCGTTTGCGAGGCTAAAGGCG / F6: 85
CAACAATCTAGAGGTTCCCACTCCCAAAGC and DNA sequences digested with XbaI and BmtI (NEB, 86
Ipswitch, MA, USA) and ligated. The resulting plasmids are termed pFN_7_37_kanR and 87
pFN_7_37_2k_kanR plasmids for transformation were purified using Macherey Nagel (Düren, 88
Germany) midi-prep plasmid purification kit. 89
90
Cultivation of Phormidium lacuna 91
Phormidium lacuna strains HE10DO and HE10JO were cultivated at 23 °C in f/2 salt water medium 92
(35, 36) or in f/2+ (in which nitrate and phosphate are 10x increased) under permanent illumination 93
(30 µmol m-2 s-1 white light from fluorescent tubes Lumilux-DeLuxe L 18/954, Osram, Munich, 94
Germany) and continuous shaking (70 rpm). For agar plates, f/2 medium without Na2SiO3 and with 95
1.5% Bacto Agar (BD Diagnostics, Franklin Lakes, NJ, USA) were used. 96
97
Transformation 98
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For transformation, Phormidium lacuna HE10DO (32) were cultivated in 100 ml f/2 medium to an 99
optical density OD750 nm of 0.25 - 0.35. The cell suspension was homogenized using an Ultraturrax 100
(Silent Crusher M. Heidolph, Schwabach, Germany) with the dispersion tool 18F at 10,000 rpm for 3 101
min. The cell suspension was centrifuged at 6000 g and 4°C for 15 min. After each centrifugation 102
step, the supernatant was removed. Cells were resuspended in 20 ml water (4 °C) and centrifuged 103
again. This washing step was repeated. The cells were finally suspended in the residual liquid, 104
transferred into 1.5 ml tubes and centrifuged again at 6000 g at 4°C for 15 min. Cells were finally 105
suspended in 1 ml supernatant. Portions of 100 µl were mixed with 3-30 µg DNA in 10 µl water, 106
transferred into 10 ml f/2 medium and cultivated for 2 d. Cells were again centrifuged, resuspended 107
in 1 ml medium and transferred to f/2 agar plates with 0, 70 and 120 µg/ml Kn. Resistant lines were 108
selected after 10 -28 d. Transgenic cells were cultivated on increasing Kn concentrations in f/2+ 109
suspension culture until complete segregation was achieved. Electroporation experiments were 110
performed with both strains HE10DO and HE10JO, whereas natural transformation was performed 111
with the strain HE10DO only. 112
113
Validation of transformants 114
To test for homologous integration, ca. 10 mg cell samples were homogenized and lysed 115
mechanically by micropestle and subjected to PCR with Taq Polymerase (NEB, USA). The following 116
primers were used: F25: GGTCTAGGTGAGGCAATCC / F28: ACCTGATTTGTTTATATCTGACGC for 117
pFN_7_37_kanR transformants and F120: GGGTAGCCTAGACTCATCC / F121: 118
ATGCGGAAGTGACTGAGG for pFN_7_37_2k_kanR and pFN_7_37_2k_kanRn transformants. All 119
primers bind only in the Phormidium lacuna genome, upstream or downstream of the integration 120
site. 121
122
Bioinformatics 123
Protein sequences of the NTFs of Synechocystis sp. PCC 6803 were obtained from the NCBI data base. 124
NTF sequences of 6 naturally competent cyanobacteria (NCC) were identified by the offline NCBI tool 125
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BLAST+ (version: 2.7.1, (37)) based on the annotated NTFs of Synechocystis sp. PCC 6803. All NTFs 126
identified in this way were used in a BLAST query against all cyanobacterial sequences of the NCBI 127
non-redundant database (August 2018). Bit score as indicator of homology was processed by a 128
minimum homology quotient method: For each homolog, the bit score of each alignment was 129
divided the by smallest bit score of the respective NCC pairs. This value is given in Table 3. 130
131
Chromosome copy number 132
Phormidium lacuna liquid cultures were homogenized by an Ultraturrax for 3 min at 10,000 rpm. To 133
determine the cell concentration, the total length of all filaments in a given volume of a counting 134
chamber was estimated (about 50 filaments for each sample) and divided by the average cell length 135
(4 µm). Cells were quantitatively disrupted using an Aminco French pressure cell (Thermo Fischer, 136
Waltham, MA, USA). A fluorescence excitation spectrum from 300 to 400 nm was recorded at 490 137
nm emission. Thereafter, DAPI was added to a final concentration of 100 ng/ml. The fluorescence 138
spectrum was measured again. After addition of 5 µl DNase (75 Kunitz) the fluorescence decreased 139
over 2 h. The difference of peak values before and after DNA digestion was taken as measure for 140
DNA concentration. As a reference, calf thymus DNA at various concentrations was dissolved in the 141
same medium and the exact concentrations determined by A260 nm. The same fluorescence recordings 142
were performed as with Phormidium lacuna DNA. Final values were corrected by GC contents of both 143
species, since GC does not induce DAPI fluorescence (38). A genome size of 3.5 Mio bp from genome 144
sequencing was taken for Phormidium lacuna (32). 145
146
Results 147
We initially established a transformation protocol for Phormidium lacuna by electroporation that was 148
based on protocols for related filamentous cyanobacteria (39-42). For integration into cyanobacterial 149
DNA we used homologous recombination, which works at high efficiency in cyanobacteria (43) and 150
other bacteria. In the transformation vectors, the homologous sequence “sc_7_37” was interrupted 151
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by a kanR resistance cassette. With these vectors, we obtained Kn resistant lines in about 40% of 152
trials. During electroporation studies, we isolated a resistant line from a control experiment in which 153
cells were incubated with DNA, but no electroporation pulse was given. The transformation protocol 154
could be optimized (Table 2 and methods) so that in almost all transformation assays, DNA was 155
integrated in Phormidium lacuna cells. Fig. 1 shows examples for filaments on selection medium at 156
different time points after transformation. 157
During our studies, we used plasmids pFN_7_37_kanR and pFN_7_37_2k_kanR(n) (Fig. 2 A and 158
methods) that differ by the length of the homologous sequence; the kanR resistance cassette is 159
flanked by ca. 500 bp or 1000 bp homologous sequences on each side, respectively. In a comparison 160
of electroporation and NT that were performed under similar conditions (Table 1 and methods 161
section), the success rate was always higher for NT as compared to electroporation (Table 2). When 162
the pFN_7_37_2k_kanR(n) vectors was used , 15 out of 16 NT transformation trials were successful, 163
i.e. resulted in the isolation of resistant lines that could be confirmed by PCR (see below). In the 164
electroporation experiments, only 44 % transformation trials were successful. We assume that the 165
deleterious effect of the electric pulse overrides the positive effect that the pulse might have on DNA 166
incorporation into the cells. For Synechocystis sp. PCC 6803 it was observed that longer flanking 167
sequences are beneficial for the homologous recombination into the genome (44). For Phormidium 168
lacuna, we found no significant difference of transformation success between 500 bp and 1000 bp 169
flanking sequences (Table 2). The length of the insert can also be critical for integration into the 170
genome. In further transformation experiments we used inserts up to a length of 4241 bp. These 171
could also be integrated into the genome of Phormidium lacuna, although with lower transformation 172
efficiencies. It should be noted that the electroporation experiments were performed with both 173
strains HE10JO and HE10DO, whereas natural transformation experiments were only performed with 174
HE10DO. 175
176
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We found that transformants with the kanR cassette were resistant against very high Kn 177
concentrations. Transformed lines could be routinely cultivated up to at least 15 mg/ml Kn (Fig. 2). In 178
50 mg/ml Kn, transformants remained green for few days but did not survive the first week. The 179
upper limit for Kn resistance is thus around 20-40 mg/ml. Escherichia coli DH5α and Synechocystis sp. 180
PCC 6803 cells, transformed with the same kanR, were resistant up to ca. 200 µg/ml and ca. 500 181
µg/ml Kn, respectively. In an extensive literature survey we found a report about an environmental 182
Enterococcus strain that was resistant up to 2 mg/ml Kn (45), but no report about higher Kn 183
resistance. Thus, transformed Phormidium lacuna has probably the strongest Kn resistance reported 184
so far. 185
We wanted to integrate the resistance cassette into a neutral site in order to allow expression of 186
additional introduced genes in future experiments. The selected homologous sequence codes for a 187
hydrogenase homolog (WP_087706519). Cyanobacterial hydrogenases are oxygen sensitive (46) and 188
should not be active under our standard growth conditions with continuous illumination. Indeed, the 189
transformants did not display an observable phenotype. 190
The integration into the genome was validated by PCR. Figure 3 shows results from a transformation 191
with pFN_7_37_KanR. The used primers bind to regions in the genome of Phormidium lacuna just 192
upstream or downstream of the insertion site, respectively. In wild type extracts, an expected short 193
PCR product of 1200 bp was detected (Fig. 3). Lines T1a and T1b are from filaments that had been 194
cultivated in liquid medium with 1000 µg / ml kanamycin for 4 weeks after transformation and the 195
expected long PCR product with 2600 bp was detected. In T2a and T2b, which are from filaments that 196
were cultivated for 9 d in liquid culture with 250 µg/ml Kn, both the 1200 bp and the 2600 bp PCR 197
products were present. Such a “partial integration” is known from transformations of other 198
cyanobacteria where it results from the polyploid character of these cells (25). In our Phormidium 199
lacuna transformation experiments, the pattern of partial integration during early selection and 200
complete integration after prolonged selection was observed in 8 independent experiments. In order 201
to find out whether Phormidium lacuna cells are also polyploid, we estimated the number of 202
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chromosome copies by a DAPI based fluorescence assay. In single experiments, the estimated values 203
of chromosome copies varied between ca. 20 and ca. 120. Phormidium lacuna has thus multiple 204
chromosome copies per cell. We assume that the large variations are not only due to methodological 205
variations, since in control measurements with calf thymus DNA the variations were much smaller. 206
Although cultivation was performed under standardized conditions, yet unknown factors must affect 207
the chromosome copy number of whole samples. However, when the Phormidium lacuna data were 208
plotted against cell densities (Fig. 3), values at lower densities i.e. shorter time of propagation, 209
correlated with higher numbers of chromosome copies; at higher OD, the copy numbers were 210
around 20. Thus, there is an influence of growth phase on the chromosome copy number in 211
Phormidium lacuna, which has also been reported for Synechocystis sp. PCC 6803 (24, 28). 212
We also studied by PCR how the Kn concentration in the medium affects the segregation of kanR in 213
the genome (Fig. 4). After transformation and selection of a resistant line and one cultivation cycle in 214
suspension culture with 100 µg/ml Kn, the filaments were divided and cultured at 0, 100, 980 and 215
8300 µg/ml in suspension culture with subcultivation every 7 d for 4 weeks. After the first 216
subcultivation, two PCR bands were observed in all cultures, indicating that Kn resistance was 217
integrated in a part of the chromosomes but not in all (Fig. 4 a). Without antibiotic pressure, the 218
2600 bp PCR product decreased transiently and increased again after the 4th subcultivation, and the 219
1200 bp wild type PCR product was present through all subcultivations. In the 100 µg/ml Kn samples, 220
the wild type band was diminished after the third subcultivation and almost, but not completely, lost 221
after the 4th subcultivation. The results were similar for the selection on 980 µg/ml Kn. With 8300 222
µg/ml Kn, the wild type band disappeared almost completely already after the 2nd subcultivation and 223
was apparently lost after the 3rd and 4th subcultivations. Thus, high concentrations of Kn result in 224
rapid segregation of kanR into all chromosomes. The high Kn resistance of Phormidium lacuna 225
transformants could therefore provide an advantage for fast segregation of the selection marker in 226
comparison to other cyanobacteria (47). 227
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Phormidium lacuna HE10DO is the first representative of the order Oscillatoriales for which a NT 228
protocol was established. According to mutant studies with Synechocystis sp. PCC 6803, proteins of 229
the type IV pili PilA1, PilB1, PilD, PilM, PilN, PilO, PilQ, PilT1 and the DNA receptor ComEA and ComF 230
are NTFs, i.e. required for NT (20-23). Other NTFs that are essential for NT in general (but loss of NT 231
has not been demonstrated in cyanobacteria) are ComEC, DprA and RecA (19). A functional type IV 232
pilus in combination with this set of expressed non-pili proteins is probably not only crucial but also 233
sufficient for NT. We can therefore assume that the probability for NT is high if a species has 234
functional homologs of all proteins. In order to get an overview about the distribution of these 235
proteins in selected cyanobacteria, we first identified NTF BLAST homologs in the naturally 236
competent cyanobacteria (NCC), Synechocystis sp. PCC 6803, Synechococcus elongatus PCC 7942, 237
Synechococcus sp. PCC 7002, Thermosynechococcus elongatus BP-1, Microcystis aeruginosa PCC 7806 238
and, Phormidium lacuna HE10JO (8-13). The strains Phormidium lacuna HE10JO and HE10DO are very 239
similar and the genomic data for HE10JO is considered also relevant for the strain HE10DO (31). This 240
set of proteins is used to define a range of similarity to decide whether other homologs are 241
functional or not. We BLASTed all NTFs of all NCCs against the genomes of selected other 242
cyanobacteria. In order to normalize each target, the highest bit-score (out of 6) was divided by the 243
lowest bit-score among the 6 NCCs (i.e. the most unrelated NTF pair among NCCs). If the quotient is 244
>= 1, we regard the target protein as functional homolog, because it is then within the range of NCC. 245
If all NTF homologs of a species have values >= 1, the chances are high that NT is possible. Among 30 246
cyanobacterial species for which no NT is reported, 19 have quotients >=1 for all 13 NTF homologs 247
and are thus promising candidates for NT. Among them are 14 filamentous cyanobacteria including 248
two members of the genera Arthrospira / Spirulina and Trichodesmium with high economic impact. 249
For other species the quotient for one or more NTFs is below 1, yet all essential genes for NT seem to 250
be present in the genome but in lower homology to the NCC. These organisms may also be naturally 251
transformable but it may be less likely due to the homology based prediction. Quotients ≤ 0.2 are 252
considered as indicative for random hits during the BLAST search. Therefore, the 5 species that have 253
at least one quotient ≤ 0.2 are regarded as critical for NT. 254
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Discussion 255
Even though natural competence is known for several single celled cyanobacterial species and one 256
filamentous cyanobacterium, Nostoc muscorum (16), this mechanism was considered as rare trait 257
among cyanobacteria (6, 14, 15). The finding of natural competence in Phormidium lacuna, the first 258
example for the order Oscillatoriales, was therefore unexpected and surprising. Since now a new 259
order of cyanobacteria is addressed, we assume that natural competence is broadly distributed 260
among cyanobacteria. Our bioinformatic studies on the distribution of NTF homologs among 30 261
species, which are intended to be a representative selection of the cyanobacterial phylum, supports 262
this hypothesis: functional homologs of all NTFs are present in at least 19 species. Thus, NT seems to 263
be a widely distributed physiological function in cyanobacteria and could contribute more to 264
evolutionary adaptations than previously suggested. It might play a major role in horizontal gene 265
transfer, genetic recombination, and DNA repair in this phylum. Natural transformation is easy and 266
uncomplicated and a more widespread use would be a benefit for basic and applied research in the 267
field. 268
Our bioinformatic analysis gives example that the rapidly increasing numbers of cyanobacterial 269
genomes will help to identify potentially transformable species and offers a simple way to rank 270
potential candidates. A recently published similar analysis (24) also comes to the conclusion that 271
natural competence could be a common feature among cyanobacteria. However, not only the 272
complete set of essential genes for natural competence but also their coordinated expression is 273
important. Gene expression of NTFs is probably dependent on internal or environmental parameters. 274
Studies on the regulation of natural competence are mostly limited to the gram positive genera 275
Bacillus and Streptococcus and the gram negative Vibrio cholerae (48, 49). 276
All Phormidium lacuna filaments are highly motile on agar medium (35), and motility of 277
cyanobacteria is thought to be dependent on type IV pili (50), the same structure that mediates NT. 278
Motility indicates that pil genes are expressed, and a preselection of motile strains or conditions that 279
increase motility could help in successful NT. The filamentous growth and motility on agar surfaces 280
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and different membranes is the reason why no colonies are obtained after transformation and the 281
respective frequencies cannot be calculated as cfu/µg of plasmid DNA. 282
Genetic engineering is now possible for another cyanobacterium, which can be used in the future for 283
basic research and biotechnological applications. The established protocol includes few washing 284
steps, DNA addition and subcultivation, and clear results are obtained after about 4 weeks. 285
Homogenization of filaments and subsequent washings could remove extracellular polymeric 286
materials and nucleases (5) and could thereby promote NT. Members of the genus Arthrospira (or 287
Spirulina), for which high nuclease activities were reported (40, 51), might be transformed by the 288
same or a similar approach. Trials with other cyanobacteria that follow either the standard protocol 289
or a simplified version of it are easy and can rapidly provide clear results. 290
The Phormidium lacuna transformants have an extraordinarily high resistance against Kn. We have in 291
the meantime targeted other loci and found a strong antibiotic resistance for these transformants as 292
well. We therefore would rule out a gene-positional effect on kanR expression. Although the origin of 293
this strong resistance is unclear, it could accelerate the segregation into chromosomes and thereby 294
speed up the entire transformation process. 295
We have shown that a newly isolated cyanobacterium Phormidium lacuna can be transformed by 296
natural transformation and homologous recombination during which a kanR resistance cassette is 297
integrated into the genome, that the transformants are extraordinarily resistant against Kn, that the 298
cyanobacterium has multiple chromosome copies and that rapid segregation of the kanR resistance 299
cassette into all chromosomes can be by achieved by the high resistance. We hope that our results 300
stimulate trials on natural transformation of other cyanobacteria and thereby contribute to a 301
broadening of research on more species, especially the filamentous ones. 302
Acknowledgments 303
The work for supported by the PhD fellowship of the Nagelschneider Foundation to Fabian Nies. We 304 thank Nadja Wunsch for technical assistance. 305
Confilct of interest: The authors declare that there is no conflict of interest with other parties 306
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Tables 307
Table 1. Summary of NT protocol for Phormidium lacuna. Additional details are given in the methods 308
section. 309
310
Duration
Cultivate of 100 ml Phormidium lacuna until OD750 nm = 0.3 6 d
Ultraturrax treatment and OD750 measurements 20 min
Centrifuge and remove supernatant 20 min
Suspend cells in 20 ml H2O and centrifuge, 4°, repeat 1 x 40 min
Suspend cells in 1 ml H2O and centrifuge (for 10 transformations) 20 min
Mix 100 µl cell suspension with 30 µg DNA (from midi prep) 15 min
Cultivate in 10 ml f/2 2 d
Centrifuge 1 x 15 min
Growth on agar plates with and without Kn 2 - 4 weeks
Select resistant filaments under microscope, transfer into f/2 with Kn 30 min for each
Growth in f/2+ with Kn 2 weeks
PCR test for insertion and segregation 5 h
311
312
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Table 2. Transformation of Phormidium lacuna HE10DO by electroporation and natural 313
transformation. The numbers stand for successful transformations i.e. 1 or more resistant lines could 314
be isolated in the relevant trial. Electroporation was performed in 1 mm cuvettes and 300 V pulses. 315
Mixed plasmid DNA and cell suspensions were suspended in 1 ml medium and transferred into 316
culture flasks directly after the electric pulse. 317
Homologous
sequences on either
side of kanR
Electroporation Natural
transformation
Vector pFN_7_37_kanR 500 bp 44 % (15 of 34) 67 % (2 of 3)
Vector
pFN_7_37_2k_kanR
1000 bp 44 % (8 of 18) 94 % (15 of 16)
318
319
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320
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Table 3. Summary of minimum bit score values of (putative) NTFs of 36 cyanobacterial species. In the 321 first step, NTF homologs of 6 naturally competent cyanobacteria (indicated by NCC in the last line) 322 were identified. These NTFs were used as queries in a BLAST search against protein sequences of 30 323 cyanobacterial species. The bit score of each homology hit was divided the by smallest bit score of 324 the respective NCC pairs. 325
326
327
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328
Figure legends 329
Fig. 1. Filaments of Phormidium lacuna after transformation with pFN_7_37_kanR during or after 330
selection on agar plates. A) 2 weeks after transformation and growth on 70 µg / ml Kn. Brownish and 331
greenish filaments can be distinguished which represent non-transformed or transformed cells, 332
respectively. B) 2 weeks after transformation and growth on 120 µg / ml Kn after, in this area of agar 333
plate, living and dead filaments are clearly distinguished C) 4 weeks after growth on 120 µg/ml Kn, all 334
filaments are resistant. Bundles of parallel filaments are characteristic for growth on agar, the growth 335
pattern is comparable to that of wild type on Kn-free agar. Scale bars 100 µm. 336
337
Fig. 2 Kanamycin resistance of Phormidium lacuna HE10JO wild type and pFN_7_37_kanR 338
transformants, liquid cultures 1 week after inoculation and growth under white light. Wild type 339
cannot proliferate at 50 µg/ml Kn or above, while pFN_7_37_kanR transformants can grow up to 340
14.3 mg/ml Kn. Kanamycin concentration from left to right: 0, 50, 100, 200 μg/ml; 4.5, 8.3, 11.5, 14.3 341
mg/ml. 342
Fig. 3 Validation of Phormidium lacuna transformants by PCR 343
a) Plasmid map of pFN_7_37_kanR, red - homologous sequences of the sc_7_37 locus, blue - 344
kanamycin resistance cassette kanR, yellow - origin of replication (f1 - bacteriophage origin, other - 345
pUC origin for E. coli), purple - ampicillin resistance cassette. 346
b) Integration site of pFN_7_37_kanR and primer binding sites. red - homologous sequences encoded 347
on the vector, pale red - Phormidium lacuna chromosome, blue - kanamycin resistance gene. Primer 348
pair: F25/F28 covering whole insertion site. 349
c) Agarose gel for the PCR with the primer pair that covers the full insert for Phormidium lacuna WT 350
and transformants. Transformants T1a and T1b were cultivated after selection on agar plate for one 351
cultivation period (7 days) in f/2+ liquid medium with 250 µg/ml Kn and one period in f/2+ with 1000 352
µg/ml Kn. T2a and T2b were cultivated only for one period at 250 µg/ml Kn. M: 1kb DNA ladder (NEB, 353
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USA). Integration of the kanR cassette into the genome of Phormidium lacuna is indicated by the 354
larger PCR product (2560 bp). 355
356
Fig. 4. Chromosome copies of Phormidium lacuna cells estimated by DAPI fluorescence of filaments 357
grown 1-5 days after inoculation. Each data point represents one independent measurement as 358
described in detail in the methods section. Values are plotted against OD750 nm. 359
360
Fig. 5 Detection of wild type and recombinant chromosomes in Kn resistant Phormidium lacuna 361
pFN_7_37_kanR lines. Following cultivation in 100 µg/ml Kn until 2 weeks after transformation, the 362
sample was divided and subcultivated one to four times on the Kn concentrations given in the panel. 363
Primers: F25, F28. Marker: 1 kb DNA ladder (NEB, USA). 364
365
366
367
References 368
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487
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not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprint (which wasthis version posted December 10, 2019. ; https://doi.org/10.1101/870006doi: bioRxiv preprint
not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprint (which wasthis version posted December 10, 2019. ; https://doi.org/10.1101/870006doi: bioRxiv preprint
not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprint (which wasthis version posted December 10, 2019. ; https://doi.org/10.1101/870006doi: bioRxiv preprint
not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprint (which wasthis version posted December 10, 2019. ; https://doi.org/10.1101/870006doi: bioRxiv preprint
not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprint (which wasthis version posted December 10, 2019. ; https://doi.org/10.1101/870006doi: bioRxiv preprint