47. Transformation of pSB1C3 and pET43.1a(+)
48. DNA measurements
49. Agarose gel (0.7 % agarose gel )
50. Electrophoresis on agarose gel of pET43.1 digest by XbaI and HindIII
51. Extraction gel of pET43.1 digest by XbaI and HindIII
52. Dephosphorylation of pET43.1 (digest by XbaI/HindIII) done previously
53. Dephosphorylation of pET43.1 (digest by XbaI/HindIII)
54. Ligation of dephosphorylated pET43.1 with C2
55. Ligation of pET43.1 dephosphorylate with C2
56. Electrophoresis on agarose gel of pET43.1 digest by XbaI and HindIII
57. Electrophoresis of pET43.1 digested by XbaI and Hind III
58. Plasmid concentrations
59. Transformation of DH5 competent cells
60. Verification of transformation of the 5/07/16
61. Cultivating colonies to recover the ligated plasmids-C1, or C2 inserts
62. Ligation of pET43.1 with C1 and C2
63. Digestion of insert B2
64. ligation of insert B2 in pET43.1
65. Check of the petri dish done on the July 6, 2016
66. Extraction of DNA of colonies from 06/07/2016
67. Agarose gel
68. Dosage of extracted DNA
69. Digestion of extracted DNA
70. Electrophoresis of pET43.1
71. Digestion of the recombinating plasmid
72. Electrophoresis of our results
73. Transformation of bacteria BL21DE3
Aim:We do again the previous experiment to understand why transformation in our bacteria does not work. Protocol: follow in this link What we did in the lab: Materials: • pET43.1a plamid (obtained with Midiprep done on June 8, 2016) • enzyme restriction (XbaI / HindIII) • Buffer Cutsmart 10X (NEB) • H2O • P10 pipet, P20 pipet, 1.5 mL eppendorf, 37°C and 65°C water bath Method: 1. For our manipulation, we used XbaI and HindIII enzymes and we used Cutsmart 10 X buffer because it is the most appropriate buffer. 2. Follow the next table to volumes:
| pET43.1a(+) à 130 ng/µl (3 µg) | |
|---|---|
DNA (µl) |
19 |
| XbaI (µl) | 2 |
| Hind III (µl) | 1 |
| H20 (µl) | 5 |
| CutSmart 10X (µl) | 24.5 |
| TOTAL (µl) | 51.5 |
Protocol: follow in this link
Aim:Check if digestion was successfully done Protocol: follow in this link What we did in the lab: Materials: • pET43.1a plasmid (obtained with Midiprep on june 8, 2016) • pET43.1a plasmid digested by XbaI/HindIII • gel 0.7% agarose • TAE 0.5X buffer • Electrophoresis generator ( at 50 V and after at 90 V) • DNA ladder (Thermoscientific gene ruler 1kb) • P10 and P20 pipet, 1.5 eppendorf, electrophoresis BIORAD Mini-Sub Cell GT Method: 1- Prepare an agarose gel at 0.7 % (Refer on the detail protocol which is on the protocol parts) 2- Fill electrophoresis chamber with TAE 1X 3- Follow the deposit Table 37:
| Line | L1 | L2 | L3 | L4 | L5 |
|---|---|---|---|---|---|
Name |
Marker weight | pET43.1a(+) X/H | pET43.1a(+) UNCUT | ||
| ADNA (µl) | 5 | 10 | 5 | ||
| H20 (µl) | 0 | 0 | 0 | ||
| Load buffer 6X | 0 | 2 | 1 |
Aim:To recover the pET43.1 which has been digested, and to purify out the band from the gel. Protocol: follow in this link What we did in the lab: Materials: • Results of electrophoresis (done previously) • Gel extraction kit from Qiagen • P10 and P20 pipet, 1.5 ml Eppendorf Method: To extract DNA we use the Gel Extraction Kit from Qiagen and we follow the different steps detailed in the kit. • Eppendorf mass : 1.4043 g • Eppendorf + Gel mass : 1.0817 g • Gel mass : 1.4043 – 1.0817 = 322.6 mg We must pour 3 volums of QG buffer, it means 967.8 µl. We added 322 µl of isopropanol and we split in two equals volums our experiment
| DNA Masses (mg) | DNA Volumes (ml)) | |
|---|---|---|
pET43.1a(+) |
322.6 | 1.073 |
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
Aim: Protocol: follow in this link What we did in the lab: Materials: Method: Results:
