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  • Podsumowanie
  • Streszczenie
  • Wprowadzenie
  • Protokół
  • Wyniki
  • Dyskusje
  • Ujawnienia
  • Podziękowania
  • Materiały
  • Odniesienia
  • Przedruki i uprawnienia

Podsumowanie

Phormidium lacuna is a filamentous cyanobacterium that was isolated from marine rockpools. This article describes the isolation of filaments from natural sources, DNA extraction, genome sequencing, natural transformation, expression of sfGFP, cryoconservation, and motility methods.

Streszczenie

Cyanobacteria are the focus of basic research and biotechnological projects in which solar energy is utilized for biomass production. Phormidium lacuna is a newly isolated filamentous cyanobacterium. This paper describes how new filamentous cyanobacteria can be isolated from marine rockpools. It also describes how DNA can be extracted from filaments and how the genomes can be sequenced. Although transformation is established for many single-celled species, it is less frequently reported for filamentous cyanobacteria. A simplified method for the natural transformation of P. lacuna is described here. P. lacuna is the only member of the order Oscillatoriales for which natural transformation is established. This paper also shows how natural transformation is used to express superfolder green fluorescent protein (sfGFP). An endogenous cpcB promoter induced approximately 5 times stronger expression than cpc560, A2813, or psbA2 promoters from Synechocystis sp. PCC6803. Further, a method for the cryopreservation of P. lacuna and Synechocystis sp. CPP 6803 was established, and methods for assessing motility in a liquid medium and on agar and plastic surfaces are described.

Wprowadzenie

Cyanobacteria are prokaryotic organisms that utilize photosynthesis as an energy source1,2. Research is increasingly focused on cyanobacterial species. Several cyanobacteria can be transformed with DNA3. Genes can be knocked out or overexpressed in these species. However, transformation is restricted to a few species4,5,6,7,8,9,10,11, and it can be difficult to establish transformation in strains from culture collections or the wild8. Strains of the filamentous species Phormidium lacuna (Figure 1) were isolated from marine rockpools, in which environmental conditions, such as salt concentrations or temperature, fluctuate over time. These filamentous cyanobacteria can be used as model organisms for the order Oscillatoriales12 to which they belong.

During trials testing gene transfer by electroporation13,14 it was found that P. lacuna can be transformed by natural transformation15. In this process, DNA is taken up naturally by some cells. Compared to other methods of transformation16,17, natural transformation has the advantage of not requiring additional tools that could complicate the procedure. For example, electroporation requires proper cuvettes, intact wires, and selection of the proper voltage. P. lacuna is presently the only Oscillatoriales member susceptible to natural transformation. Because the original protocol is based on electroporation protocols, it still included several washing steps that might be unnecessary. Different approaches were tested to simplify the protocol, leading to the transformation protocol presented here.

The genome sequence is essential for further molecular studies based on gene knockout or overexpression. Although genome sequences can be obtained with next-generation sequencing machines within short periods, the extraction of DNA can be difficult and depends on the species. With P. lacuna, several protocols were tested. A modified cetyl trimethyl ammonium bromide (CTAB)-based method was then established, resulting in acceptable purity of DNA and DNA yields of each purification cycle for continued work in the laboratory. The genome of five strains could be sequenced with this protocol. The next logical transformation step was to establish protein expression in P. lacuna.

The sfGFP used as a marker protein in this protocol can be detected with any fluorescence microscope. All promoters that were tested could be used for P. lacuna sfGFP expression. The increasing number of strains arising from transformation has resulted in the need for a method for storing the cultures. Such methods are established for Escherichia coli and many other bacteria18. In standard protocols, glycerol cultures are prepared, transferred in liquid nitrogen, and stored at -80 °C. This method requires only a few steps and is highly reliable for those species for which it is established. The standard protocol was not feasible for P. lacuna because living cells could not be recovered in all cases. However, when glycerol was removed after thawing, cells of all trials survived. Simple methods are presented for the analysis of motility of P. lacuna, which can be combined with knockout mutagenesis to investigate type IV pili or the role of photoreceptors. These assays are different from those of single-celled cyanobacteria19,20,21 and can also be useful for other Oscillatoria.

Protokół

1. Isolation from the natural environment

NOTE: Green algae, diatoms, filamentous cyanobacteria, and other microalgae can be isolated. The protocol can be used for any microalga species from rockpools growing under laboratory conditions. Filamentous cyanobacteria that belong to Oscillatoriales can be easily recognized by their movement and filamentous shape. The species can be identified in a semipure state by genome sequencing or 16S rRNA sequencing.

  1. Transfer liquid seawater samples from marine rockpools (i.e., cavities in the rocky coast) into 50 mL flasks. For each flask, note the exact place or coordinates of the natural source. If possible, filter the content through 50 µm nets to reduce the amounts of zooplankton. Store the samples at 4 °C until they can be subcultured.
  2. Transfer 1 mL cultures to 10 cm Petri dishes containing 3% bacto-agar in f/2 medium22,23 (see the Table of Materials). Prepare up to 20 plates. Cultivate under white light of 50 µmol m-2 s-1.
    NOTE: Higher light intensities may be used for cultivation. Intensity up to 400 µmol m-2 s-1 can be used for P. lacuna, although other species might be more light-sensitive.
  3. After one week, transfer the desired cells to fresh agar plates using sterile forceps. Isolate the cells under a binocular microscope under sterile conditions. Store the old agar plate at 4 °C until cells appear and grow on the new agar plate.
  4. Repeat this transfer step every week to eliminate contamination. Use the naked eye for detecting heavy contamination and a microscope with 400x magnification for additional checks for contamination.
  5. If a sample seems free of contamination, test for bacterial or fungal contamination on agar plates. Transfer a fraction of the culture with an inoculation loop to an LB24 agar plate (10 cm diameter), keep the plate at room temperature, and check for the growth of contaminants over 1-3 days.
  6. If a sterile filamentous cyanobacterial species is obtained, use it for further culture work. Cultivate P. lacuna in liquid or on bacto-agar plates. Use 250 mL flasks with 50 mL of f/2 medium or f/2+ medium for liquid culture.

2. DNA extraction

NOTE: This method is adopted from 25 26

  1. Prepare two flasks with 50 mL of f/2 medium. Inoculate each with ~1 mL of P. lacuna filaments from other growing cultures. Keep the cultures for 7 days or longer under agitation (horizontal rotation) at 50 rpm under white light (50 µmol m-2 s-1) at 25 °C.
  2. Treat the culture with ultrasound (see the Table of Materials) for 2 min with full energy. Measure OD at 750 nm; check to ensure it is ~0.5. Continue to grow the cultures if the OD is too low.
  3. Collect the filaments by 5,000 × g, 20 min centrifugation. Remove the supernatant. Transfer the filaments with residual liquid to the chamber of a French Press27. Set the pressure of the French Press to 20,000 psi and extract the cells.
    NOTE: The French Press will lyse all the cells and release the DNA; strong shear forces will produce 1,500 bp DNA fragments.
  4. Centrifuge the sample for 10 min at 10,000 × g and remove the supernatant.
  5. Add 400 µL of lysis buffer (4 M urea, 0.1 M Tris/Cl, pH 7.4) and 50 µL of proteinase K (10 mg/mL) to the pellet. Heat the sample to 55 °C for 60 min with shaking at 550 rpm.
  6. Add 1 mL of DNA extraction buffer (3% CTAB, 1.4 M NaCl, 10 mM EDTA, 0.1 M Tris/Cl, 1% Sarkosyl, 0.1 M DTT, pH 8) and incubate for 60 min at 55 °C and 550 rpm. Transfer the solutions to centrifugation tubes, and add two volumes of chloroform/isoamylalcohol (24/1).
  7. After shaking, centrifuge the sample for 5 min at 9,000 × g. Transfer the upper, aqueous phase into reaction vials and add 1 mL of ice-cold ethanol and 50 µL of 3 M sodium acetate.
  8. Vortex the sample and place it at -20 °C for 1 h or longer.
  9. Centrifuge for 5 min at 10,000 × g (4 °C) and discard the supernatant. Wash the pellet with 70% ethanol.
  10. Centrifuge the sample again. Remove the supernatant and dry the pellet overnight. Dissolve the DNA in nuclease-free water. Measure the DNA spectrum to check whether the OD 260 nm/OD 280 nm is between 1.6 and 1.9.
  11. Analyze the size of the DNA on an agarose electrophoresis gel28.
  12. Sequence the genomic DNA by next-generation sequencing for 300 cycles, with a paired-end setting and read length of 150 bases (see the Tables of Materials).
  13. Perform the assembly with the appropriate computer program; see the example given in the Table of Materials.
  14. Submit the draft genome to the RAST server for annotation.
    ​NOTE: Upload DNA sequences to obtain complete annotation within a few minutes.

3. Natural transformation and GFP expression

NOTE: Transformation is based on a plasmid vector propagated in E. coli; pGEM-T or pUC19 may be used as backbone vectors. Cloning techniques are established in many laboratories; see also standard protocols28 and the articles on transformation vectors for P. lacuna15,29. Examples for vectors for sfGFP expression are described in the representative results section. Details of four yet unpublished vectors are provided in Supplemental File 1.

  1. Perform all steps using sterile material under sterile laboratory conditions (clean bench, sterile glassware).
  2. Inoculate 2 x 50 mL of f/2 liquid medium in two 250 mL flasks with 2 x 1 mL of P. lacuna filaments from a running culture. Cultivate in white light (50 µmol m-2 s-1) under agitation (horizontal rotation, 50 rpm) for ~5 days at 25 °C.
  3. Prepare ~200 µg of the transformation vector DNA using a midi prep kit (see the Table of Materials) according to the manufacturer's instructions.
  4. Homogenize 100 mL of P. lacuna cell suspension (see the Table of Materials) at 10,000 rpm for 3 min. Measure OD at 750 nm (desired value = 0.35).
  5. Centrifuge the cell suspension for 15 min at 6,000 × g. Remove the supernatant, and suspend the pellet in 800 µL (total volume including residual liquid and filaments) of the remaining liquid and additional f/2+ medium.
  6. Take eight f/2+ bacto-agar plates (10 cm diameter) containing 120 µg/mL kanamycin. Pipette 10 µg of DNA into the middle of each agar plate. Immediately pipette 100 µL of cell suspension into the middle of each agar plate (on top of the DNA).
  7. Keep the agar plate without a lid on the clean bench to allow the excess liquid to evaporate. Close the plate and cultivate it in white light at 25 °C for 2 days.
  8. Distribute the filaments of each agar plate with an inoculation loop onto several fresh f/2+ bacto-agar plates containing 120 µg/mL kanamycin. Cultivate the plates in white light at 25 °C and check the cultures regularly under a microscope.
  9. Identify living, transformed filaments after 7-28 days under the microscope. Look for healthy, green filaments (Figure 2) that are different from other filaments. If these green filaments can be identified, continue with the next step; otherwise, keep the plate for another 7 days.
  10. Use forceps to transfer these identified living filaments into 50 mL of liquid f/2+ medium with 250 µg/mL kanamycin. Cultivate in white light at 25 °C on a shaker (horizontal rotation, 50 rpm). Observe growth for up to four weeks.
  11. Transfer the filaments back to agar medium containing 250 µg/mL kanamycin and wait for the filaments to grow. After several days, transfer single filaments to a fresh agar plate with a higher concentration of kanamycin, e.g., 500 µg/mL. Keep the original plate.
  12. Ensure that the filaments are propagated in a high concentration of kanamycin in liquid culture or on agar. Increase the kanamycin concentration again to speed up segregation.
    NOTE: Transformed P. lacuna grows in up to 10,000 µg/mL kanamycin. Other species might not tolerate such high concentrations.
  13. If resistant cells are grown and distributed broadly over a plate, test the integration of the insert into the genome of P. lacuna by performing PCR with outer and inner primers.
    1. Use primers that were designed for cloning of the insertion as inner primers.
    2. For design of the outer primers, select sequences that are 5' and 3' of the proposed insertion site on the genome of P. lacuna but outside the insertion. 
    3. For PCR reactions, use inner primers and outer primers. Use the resistant strain(s) and the wild type. 
      NOTE: Inner primers indicate that the insert is present; outer primers show that the insert is inserted at the correct locus.
  14. For each PCR reaction, place ~10 mg of the filaments directly in the PCR tubes and perform PCR according to standard protocols24. If no product is obtained, vary the annealing temperature and wash the filaments with water.
    NOTE: Many different polymerases can be used in PCR. Standard polymerases, such as Taq polymerase, have a higher error rate than error-checking polymerases, which are more expensive. This analytical PCR does not require any error-checking polymerase. However, error-checking polymerase should be tested if no PCR product is obtained with a standard polymerase.
  15. Analyze the PCR products of the resistant line on agarose electrophoresis24.
    1. Compare band positions with marker and compare the wild type and transformant. With inner and outer primers, look for a larger band for the transformant than the wild type (due to the insertion of the resistance cassette) or two bands for the transformant: one with the size of the wild-type band and a larger one. As the latter case indicates incomplete segregation, continue cultivation with high kanamycin concentrations.
      NOTE: For more details on PCR and electrophoresis, see15,24 or other standard literature.
  16. For GFP expression: observe single filaments with a fluorescence microscope (see the Table of Materials) at a magnification of the objective set at 40x or 63x. Capture a brightfield transmission image and a fluorescence image. Use the following settings for GFP: 470 nm bandpass for excitation, 525 nm bandpass for emission, and a 495 nm beam splitter, initial exposure time of 500 ms.
  17. Adjust the exposure time for clear fluorescence signals, avoiding saturating intensities. Try to use the same setting for all samples.
  18. As the wild-type filaments will also display fluorescence, capture images with the same settings as above for this background fluorescence.
    ​NOTE: The strain expressing GFP must have a higher signal; otherwise, it is not expressing GFP.
  19. Based on exposure times and the pixel intensities of the fluorescence images, calculate and compare the GFP content of the different filaments.

4. Cryoconservation

NOTE: P. lacuna and the single-celled cyanobacterium Synechocystis sp. PCC 6803 are used. The present method works better for P. lacuna.

  1. Cultivate P. lacuna or Synechocystissp PCC 6803 for at least 10 days in 10 mL of f/2+ or BG-11 medium, respectively, under white light (50 µmol m-2 s-1) at 25 °C under agitation (horizontal rotations, 50 rpm).
  2. Homogenize the P. lacuna culture (see the Table of Materials) at 10,000 rpm for 3 min or with an ultrasound device (see the Table of Materials) for 2 min at full energy. Determine OD 750 nm of either culture to check whether the value is between 1 and 7.
  3. Collect the cells by centrifugation at 6,000 × g for 15 min. Remove the supernatant.
  4. Suspend the cell pellet in 800 µL of f/2+ or BG-11 medium (final volume) and transfer to a 2 mL cryovial. Add 800 µL of a 50% glycerol solution to the cell suspension. Close the vial and mix by repeated inverting.
  5. Transfer the cryovial to liquid nitrogen and store it in a cryobox in a -80 °C freezer. Note the position of the box within the freezer and the coordinates of the sample within the box.
  6. For recovery of the cells, take out the cryovial and thaw the contents at room temperature. Transfer the contents to a 2 mL reaction tube.
  7. Wash the sample twice. For the 1st wash, centrifuge at 6,000 × g for 5 min. Remove the supernatant, and resuspend the pellet in 2 mL of f/2+ or BG-11 medium. For the 2nd wash, recentrifuge at 6,000 × g for 5 min, remove the supernatant, and suspend the pellet in 2 mL of f/2+ or BG-11 medium.
  8. To check the integrity of these cells that are ready for cultivation, transfer the pellet to 9 mL of medium and cultivate them in white light (50 µmol m-2 s-1) under agitation (55 rpm). Compare the OD 750 nm of the culture on the first day and after 1 week.

5. Motility of Phormidium lacuna

NOTE: Three different assays will be described. The same culture is used in all cases.

  1. Cultivate P. lacuna in f/2 medium under horizontal agitation (50 rpm) in white light (50 µmol m-2 s-1) for ~5 days until the estimated OD 750 nm is 0.35. Store the sample at 4 °C until use.
  2. Homogenize the filaments (see the Table of Materials) at 10,000 rpm for 3 min or with ultrasound (see the Table of Materials) for 1 min at maximum power and cycle of 1. Measure OD 750 nm. If above 0.35, dilute the fraction with f/2 medium. Use this solution in motility assays in steps 5.3, 5.4, and 5.5.
  3. Assay for movement in liquid medium
    1. For direct observation of motility, transfer 8 mL of medium containing P. lacuna (from step 5.2) into a 6 cm Petri dish. Wait a few minutes until the sample reaches room temperature. Cover the Petri dish with cellophane foil.
    2. Place a microscope slide on the x-y table of a standard microscope with a camera. Switch on the microscope light. Ideally, always use the same electrical and optical settings for the lighting. Move a 4x or 10x objective into the path of the light.
    3. Place the Petri dish on top of the slide. Adjust single filaments or filament bundles by x, y, and z movements of the table.
      NOTE: Due to the three-dimensional arrangement, only a part of the relevant section can be in focus. The cellophane foil allows adjusting the focus without restriction.
    4. Observe movements of single filaments or bundles. Ensure that the objective lens does not touch the liquid. Record the movements of filaments with a standard microscope camera (see Supplemental Video S1).
  4. Assay for movement on the surface
    1. For the observation of filament motility on agar surfaces, prepare 6 cm Petri dishes with f/2 bacto-agar. Ensure that the agar is high enough for the objective lens to get close to the agar surface. Alternatively, prepare a ~3 mm thick agar layer and record the filaments through the agar (keep the plate upside down or use an inverted microscope).
    2. Pipette 0.5 mL of a solution containing P. lacuna (from step 5.2) on the bacto-agar surface of a 6 cm Petri dish. Allow the liquid to enter the surface. Close the Petri dish and observe the movement of the filaments on the surface using a 4x or 10x objective.
    3. Ensure that the same electrical and optical settings of the microscope are used throughout the recording and in subsequent recordings.
    4. Capture time-lapse recordings using an ocular camera and minicomputer system. Ensure that the time interval between subsequent images is 5 s-1 min. Program the Linux script of the minicomputer to control the time-lapse recording. See Supplemental File 2 for an example script and Supplemental Video S2 as an example.
  5. Assay for phototaxis
    1. For phototaxis experiments, prepare light-emitting diode (LED) holders (here, with a 3D printer) in which the selected 5 mm LEDs are mounted to irradiate an area of 20 mm2 from below to above (Figure 3). If required, use many LED holders in parallel, connecting each LED electrically through a resistor and potentiometer to an adjustable power supply. Measure and adjust the LED intensities, depending on the experiment. Ensure that the whole setting is in a dark room or a closed dark container.
    2. Place 8 mL of the medium containing P. lacuna (from step 5.2) into a 6 cm Petri dish. Adjust the light intensity of the LED. Close the Petri dish with the lid and place it on an LED holder so that the LED is in the center of the Petri dish.
    3. After the desired duration (typically 2 days), capture an image of the Petri dish with a smartphone camera aimed directly at the position of the light treatment. Use a white LED panel for irradiation of the specimen. Use the manual settings of the camera; avoid reflections of light; always adjust to get the same distance between the camera lens and the specimen. Ensure that the exposure settings give an image suitable for later analyses using ImageJ.
    4. Quantify the diameter of the central circle of filaments using ImageJ software.
      1. Open ImageJ, click on File | Open, select the desired file, and click Enter.
      2. Select the Straight button (with a straight line). Press the left mouse button to draw a line from one end of the Petri dish to the opposite end. Ensure that the line passes through the center of the circle of filaments.
      3. Press Ctrl-K on the keyboard or click Analyze | Plot Profile in the ImageJ menu. Look for an x-y window with pixel intensities plotted versus distance-a 1D profile of the Petri dish. Ensure that the lowest pixel intensity is slightly above 0 and the highest value below 255.
      4. Estimate an average value for the pixel intensity outside the circle and another average value for the pixel intensity in the circle. At the y- position between these values, estimate the x-values of both sides of the circle by pointing with the mouse on these positions. Note both values and calculate the difference.
      5. Obtain the highest x-value by pointing the mouse at the y-axis on the right. Note that this value e represents the diameter of the Petri dish. If this diameter is 5 cm, calculate the diameter of the central filament circle as d/e × 5 cm.

Wyniki

Following the above-mentioned methods, 5 different strains of P. lacuna were isolated from rockpools and sequenced (Figure 1 and Table 1). All cultures were sterile after ~1 year of subculturing except P. lacuna HE10JO. This strain is still contaminated with Marivirga atlantica, a marine bacterium. During subsequent Helgoland excursions, other filamentous cyanobacteria were isolated from rock pools, which are different from P. lacuna and n...

Dyskusje

Although many strains of cyanobacteria are available from culture collections32,33,34,35,36, there is still a demand for new cyanobacteria from the wild because these species are adapted to specific properties. P. lacuna was collected from rockpools and is adapted to variations of salt concentrations and temperature30. Strains ...

Ujawnienia

The authors have no conflicts of interest to disclose.

Podziękowania

The work was supported by the Karlsruher Institute of Technology.

Materiały

NameCompanyCatalog NumberComments
Autoclave 3870 ELVTuttnauer3870 ELV
Bacto AgarOttoNorwald214010
BG-11 Freshwater SolutionSigma AldrichC3061
BG-11 mediumMerck73816-250ML
Boric acidMerck10043-35-3H3BO3
Calcium chloride dihydrateCarl Roth10035-04-8CaCl2 · 2 H2O
Cell culture flasks Cellstar with filter screw cap, sterile, 250 mLGreiner658190
Cell culture flasks Cellstar with filter screw cap, sterile, 50 mLGreiner601975
Centrifuge LYNX 4000Thermo Scientific75006580and rotor
Centrifuge microstar 17VWR InternationalN/Afor up to 13,000 rpm
Cetyltrimethylammonium Bromide (CTAB)PanReac AppliChem57-09-0C19H42BrN
Chloroform : Isoamyl Alcohol 24 : 1PanReac AppliChem
A1935
Cobalt(II) chloride hexahydrateMerck7791-13-1CoCl2 · 6 H2O
Copper(II) sulphate pentahydrateMerck7758-99-8 CuSO4 · 5 H2O
D(+)-BiotinCarl Roth58-85-5 C10H16N2O3S
DNA ladder 1 kbNew England BiolabsN3232
DNA ladder 100 bpNew England BiolabsN3231
Electrical pipetting help accujet-pro SBrand GmbH26360for pipetting 1-25 mL
EthanolVWR64-17-5C2H6O
Ethylenediamine tetraacetic acid disodium salt dihydrateCarl Roth6381-92-6EDTA-Na2 · 2 H2O
Fluorescence microscope ApoTomeZeiss
Fluorescence microscope Axio Imager 2Zeiss
French Pressure Cell PressAmerican Instrument CompanyN/A
Gel documation System Saffe ImageInvitrogen
Gelelctrophoresis system Mupid-One/-exuADVANCED
Glassware, different
GlycerolCarl Roth56-81-5C3H8O3
Iron(III) chloride hexahydrateMerck10025-77-1 FeCl3 · 6 H2O
KanamycinSigma-Aldrich25389-94-0
Kanamycin sulphateCarl Roth25389-94-0C18H36N4O11 · H2SO4
Lauroylsarcosine, Sodium Salt (Sarcosyl)Sigma Aldrich137-16-6C15H28NO3 · Na
LB Broth (Lennox)Carl RothX964.4
Light source, fluorescent tube L18W/954 daylightOSRAMcultivation of cyanobacteria
Light source, LED panel XL 6500K 140 WBloom StarN/Acultivation of cyanobacteria, up to 1,000 µmol m-2 s-1
Magnesium chloride hexahydrateCarl Roth7791-18-6MgCl2 · 6 H2O
Manganese(II) chloride tetrahydrateServa13446-34-9MnCl2 · 4 H2O
Microscope DM750Zeiss
Midi prep plasmid extraction kit NucleoBond Xtra Midi kitMacherey-NAGEL GmbH & Co. KGREF740410.50
Minicomputer Raspberry Pi 4 +Conrad Electronics2138863-YDfor time-lapse recording
Ocular camera EC3Leicafor continuous recording up to 30 s
Ocular camera MikrOkular Full HDBresserfor time-lapse recordings, coupled to Raspberry Pi minicomputer
Petri dishes polystyrole, 100 mm x 20 mmMerckP5606-400EA
Petri dishes polystyrole, 60 mm x 15 mmMerckP5481-500EA
Photometer Nanodrop ND-1000Peqlab Biotechnologie
Photometer Uvikon XSGoebel Instrumentelle Analytik GmbH
Pipetman 100-1,000 µLGilsonSKU: FA10006M
Pipetman 10-100 µLGilsonSKU: FA10004M
Plastic pipettes 10 mL, sterileGreiner607107
Plastic tube, sterile, 15 mLGreiner188271
Plastic tube, sterile, 50 mLGreiner227261
Potassium bromideCarl Roth7758-02-3KBr
Potassium chlorideCarl Roth7447-40-7KCl
Power supply Statron 3252-1Statron Gerätetechnik GmbH
Power supply Voltcraft PPS 16005Conrad Electronicsfor LED
Proteinase KPromegaMC500Cfrom Maxwell 16 miRNA Tissue Kit AS1470
Q5 polymeraseNew England BiolabsM0491S
Sequencing kit NextSeq 500/550 v2.5Illumina
Sequencing system NextSeq 550 SY-415-1002Illumina
Shaker Unimax 2010Heidolph Instrumentsfor cultivation
Sodium acetateCarl Roth127-09-3NaCH3COO
Sodium chlorideCarl Roth7647-14-5NaCl
Sodium dihydrogen phosphate monohydrateCarl Roth10049-21-5NaH2PO4 · H2O
Sodium fluorideCarl Roth7681-49-4NaF
Sodium hydrogen carbonateCarl Roth144-55-8NaHCO3
Sodium molybdate dihydrateServa10102-40-6Na2MoO4 · 2 H2O
Sodium nitrateMerck7631-99-4NaNO3
Sodium sulphateCarl Roth7757-82-6Na2SO4
Strontium chloride hexahydrateCarl Roth10025-70-4SrCl2 · 6 H2O
Thiamine hydrochlorideMerck67-03-8C12H17ClN4OS · HCl
TRISCarl Roth77-86-1C4H11NO3
Ultrasonic device UP100H with sonotrode MS3Hielscher Ultrasound TechnologyUP100H
Ultraturrax Silent Crusher MHeidolph Instrumentshomogenizer
UreaCarl Roth57-13-6CH4N2O
Vitamin B12Sigma68-19-9C63H88CoN14O14P
Vitamin solution0.3 µM thiamin-HCl, 2.1 nM biotin, 0.37 nM cyanocobalamin
Water Stills, Water treatmentVEOLIA water technologiesELGA_21001
Zinc sulphate heptahydrateSigma7446-20-0ZnSO4 · 7 H2O
software, URL
gatb-minia program for DNA assemblyhttps://github.com/GATB/gatb-minia-pipelinemakes large scaffolds from short DNA reads, Linux based
ImageJsoftware for immage processing (pixel intensities, circle diameter)
RAST annotation serverhttps://rast.nmpdr.orginput: genome DNA sequence, detects open reading frames, lists protein sequences and their functions
Culture media
Artificial seawater0.41 M NaCl , 53 mM MgCl2,28 mM Na2SO4, 10 mM CaCl2 , 9 mM  KCl , 2.4 mM NaHCO3 ,0.84 mM KBr, 0.49 mM H3BO3, 90 µM SrCl2, 72 µM NaF
f/2 -liquid mediumartificial seawater, 0.1 % (v/v) trace element solution, 0.05 % (v/v) vitamin solution, 0.88 mM NaNO3, 36 µM NaH2PO4 
f/2+ liquid mediumf/2-medium, with 10 times increased NaNO3 and NaH2PO4 (0.88 mM NaNO3, 36 µM NaH2PO4
f/2+-agar3 % (w/v) bacto agar, artificial seawater, 0.1 % (v/v) trace element solution, 0.05 % (v/v) vitamin solution ,8.8 mM NaNO3, 0.36 mM NaH2PO4
f/2-agar3 % (w/v) bacto agar, artificial seawater, 0.1 % (v/v) trace element solution, 0.05 % (v/v) vitamin solution ,0.88 mM NaNO3, 36 µM NaH2PO4
Trace element solution0.36 mM NaH2PO4, 12 µM Na2EDTA, 39 nM CuSO4, 26 nM Na2MoO4 , 77 nM ZnSO4, 42 nM CoCl2, 0.91 µM MnCl2
Vitamin solution0.3 µM thiamin-HCl, 2.1 nM biotin, 0.37 nM cyanocobalamin

Odniesienia

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