Berkeley LBL/Methods
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=== Subcloning === | === Subcloning === | ||
- | The genes of interest from Rhodobacter sphaeroides, Synechocystis sp, and Heliobacillus mobilis were amplified using PCR (the details of which can be found in Protocols). The PCR fragments were then digested and ligated with the T7 expression vector pET3a in various ways, resulting in the constructs shown below. They were transformed into E.Coli (either DH10B or NovaBlue) and glycerol stocks for these cells were saved. | + | The genes of interest from ''Rhodobacter sphaeroides'', ''Synechocystis sp'', and ''Heliobacillus mobilis'' were amplified using PCR (the details of which can be found in Protocols). The PCR fragments were then digested and ligated with the T7 expression vector pET3a in various ways, resulting in the constructs shown below. They were transformed into ''E.Coli'' (either DH10B or NovaBlue) and glycerol stocks for these cells were saved. |
=== Constructs === | === Constructs === | ||
Line 58: | Line 58: | ||
|T7p-rbs-chlH-rbs-chlI-rbs-chlD-T7Term | |T7p-rbs-chlH-rbs-chlI-rbs-chlD-T7Term | ||
|} | |} | ||
+ | |||
'''Enzymes for reactions after Mg-insertion step'''<br> | '''Enzymes for reactions after Mg-insertion step'''<br> | ||
- | ''Heliobacillus mobilis'' | + | |
+ | ''Heliobacillus mobilis'' (T7 expression vector pET29bEBBX was used for subcloning of heliobacteria) | ||
+ | {| border="1" | ||
+ | |- | ||
+ | !Construct Name | ||
+ | !Construct Details | ||
+ | |- | ||
+ | |pET29-bchB | ||
+ | |T7p-rbs-bchB-T7Term | ||
+ | |- | ||
+ | |pET29-bchE | ||
+ | |T7p-rbs-bchE-T7Term | ||
+ | |- | ||
+ | |pET29-bchM | ||
+ | |T7p-rbs-bchM-T7Term | ||
+ | |- | ||
+ | |pET29-bchN | ||
+ | |T7p-rbs-bchN-T7Term | ||
+ | |- | ||
+ | |pET29-bchI | ||
+ | |T7p-rbs-bchI-T7Term | ||
+ | |- | ||
+ | |pET29-bchL | ||
+ | |T7p-rbs-bchL-T7Term | ||
+ | |} | ||
=== Expression === | === Expression === | ||
- | Once the constructs are inside DH10B or NovaBlue, they were minipreped and transformed in BL21 (DE3). These cells were then induced to overexpress the proteins of interest. After protein expression, the cell cultures were centrifuged at 10,000rpm for 20 minutes. The resulting cell pellets were dissolved in TRIS buffer (pH 7.8) and sonicated. The sonicated cell extracts were then centrifuged again, with the supernatant containing the soluble proteins. The soluble protein extract was used for enzyme activity assays. Along with the soluble protein extract, the total sonicated cell extract and the insoluble cell extract were analyzed on a SDS-PAGE gel. | + | Once the constructs are inside DH10B or NovaBlue, they were minipreped and transformed in BL21 (DE3). These cells were then induced to overexpress the proteins of interest. After protein expression, the cell cultures were centrifuged at 10,000rpm for 20 minutes. The resulting cell pellets were dissolved in TRIS buffer (pH 7.8) and sonicated. The sonicated cell extracts were then centrifuged again, with the supernatant containing the soluble proteins. The soluble protein extract was used for enzyme activity assays. Along with the soluble protein extract, the total sonicated cell extract and the insoluble cell extract were analyzed on a SDS-PAGE gel. (all expressions were done by Joyce, Mimi, and Konniam; gel was done on 10/24/07) |
=== Enzyme Activity Assays === | === Enzyme Activity Assays === | ||
- | The E.Coli cells with the constructs pET3a-R-bchHID and pET3a-S-bchHID have all the peptides necessary for the enzyme Mg-chelatase. The activity of these enzymes can be measured by the concentration of the reaction product, Mg-protoporphyrin IX. The concentrations were measured by the UV-vis spectroscopy and fluorescence emission spectroscopy, utilizing the Beer-Lambert law. By assuming that the concentration of the product is proportional to the activity of the enzymes, we can determine which enzyme (either from Rhodobacter sphaeroides or Synechocystis sp) is more efficient. | + | The ''E.Coli'' cells with the constructs pET3a-R-bchHID and pET3a-S-bchHID have all the peptides necessary for the enzyme Mg-chelatase. The activity of these enzymes can be measured by the concentration of the reaction product, Mg-protoporphyrin IX. The concentrations were measured by the UV-vis spectroscopy and fluorescence emission spectroscopy, utilizing the Beer-Lambert law. By assuming that the concentration of the product is proportional to the activity of the enzymes, we can determine which enzyme (either from ''Rhodobacter sphaeroides'' or ''Synechocystis sp'') is more efficient. |
- | == Protocols == | + | == '''Subcloning Protocols''' == |
+ | |||
+ | '''''Polymerase Chain Reaction (PCR) Protocols:''''' | ||
[[Berkeley_LBL/PCRphusion|PCR (Using Phusion Polymerase)]] | [[Berkeley_LBL/PCRphusion|PCR (Using Phusion Polymerase)]] | ||
[[Berkeley_LBL/PCRextaq|PCR (Using TaKaRa Ex Taq Polymerase)]] | [[Berkeley_LBL/PCRextaq|PCR (Using TaKaRa Ex Taq Polymerase)]] | ||
+ | |||
+ | '''''Clean Up/ Purification Protocols:''''' | ||
[[Berkeley_LBL/PCRcleanup|PCR Clean Up/Purification]] | [[Berkeley_LBL/PCRcleanup|PCR Clean Up/Purification]] | ||
+ | |||
+ | [[Berkeley_LBL/GelExtraction|Gel Extraction]] | ||
+ | |||
+ | '''''DNA Gel Eletrophoresis Protocol:''''' | ||
[[Berkeley_LBL/DNAGelElectrophoresis|DNA Gel Electrophoresis]] | [[Berkeley_LBL/DNAGelElectrophoresis|DNA Gel Electrophoresis]] | ||
- | + | '''''Restriction Digestion Protocols:''''' | |
[[Berkeley_LBL/Digestion|Digestion for PCR Product or Miniprepped DNA]] | [[Berkeley_LBL/Digestion|Digestion for PCR Product or Miniprepped DNA]] | ||
Line 86: | Line 119: | ||
[[Berkeley_LBL/Digestion2|Analytic Digestion]] | [[Berkeley_LBL/Digestion2|Analytic Digestion]] | ||
- | + | '''''Ligation Protocol:''''' | |
[[Berkeley_LBL/Ligation|Ligation]] | [[Berkeley_LBL/Ligation|Ligation]] | ||
+ | |||
+ | '''''Transformation Protocols:''''' | ||
[[Berkeley_LBL/CompetentCell|KCM Competent Cell Production]] | [[Berkeley_LBL/CompetentCell|KCM Competent Cell Production]] | ||
Line 95: | Line 130: | ||
[[Berkeley_LBL/Electroporation|Electroporation Transformation]] | [[Berkeley_LBL/Electroporation|Electroporation Transformation]] | ||
+ | |||
+ | '''''Miniprep Protocol:''''' | ||
+ | |||
+ | [[Berkeley_LBL/Miniprep|Miniprep]] | ||
+ | |||
+ | == '''Expression Protocols''' == | ||
+ | |||
+ | '''''Protein Expression Protocols:''''' | ||
[[Berkeley_LBL/Overexpression|Overexpression]] | [[Berkeley_LBL/Overexpression|Overexpression]] | ||
+ | |||
+ | '''''Protein Analysis Protocols:''''' | ||
[[Berkeley_LBL/Sonication|Sonication]] | [[Berkeley_LBL/Sonication|Sonication]] | ||
[[Berkeley_LBL/SDS-PAGE|SDS-PAGE]] | [[Berkeley_LBL/SDS-PAGE|SDS-PAGE]] |
Latest revision as of 06:51, 27 October 2007
Home | Project Description | Methods | Notebook | Results and Discussion | Resources |
Contents |
Experimental
Subcloning
The genes of interest from Rhodobacter sphaeroides, Synechocystis sp, and Heliobacillus mobilis were amplified using PCR (the details of which can be found in Protocols). The PCR fragments were then digested and ligated with the T7 expression vector pET3a in various ways, resulting in the constructs shown below. They were transformed into E.Coli (either DH10B or NovaBlue) and glycerol stocks for these cells were saved.
Constructs
The T7 expression vector pET3a was used for the subcloning of the genes for magnesium-chelatase. The following constructs were built by inserting various fragments genes from the three organisms into pET3a.
Magnesium-Chelatase
Rhodobacter sphaeroides
Construct Name | Construct Details |
---|---|
pET3a-R-bchH | T7p-rbs-bchH-T7Term |
pET3a-R-bchI | T7p-rbs-bchI-T7Term |
pET3a-R-bchD | T7p-rbs-bchD-T7Term |
pET3a-R-bchHID | T7p-rbs-bchH-rbs-bchI-rbs-bchD-T7Term |
Synechocystis sp.
Construct Name | Construct Details |
---|---|
pET3a-S-chlH | T7p-rbs-chlH-T7Term |
pET3a-S-chlI | T7p-rbs-chlI-T7Term |
pET3a-S-chlD | T7p-rbs-chlD-T7Term |
pET3a-S-chlHID | T7p-rbs-chlH-rbs-chlI-rbs-chlD-T7Term |
Enzymes for reactions after Mg-insertion step
Heliobacillus mobilis (T7 expression vector pET29bEBBX was used for subcloning of heliobacteria)
Construct Name | Construct Details |
---|---|
pET29-bchB | T7p-rbs-bchB-T7Term |
pET29-bchE | T7p-rbs-bchE-T7Term |
pET29-bchM | T7p-rbs-bchM-T7Term |
pET29-bchN | T7p-rbs-bchN-T7Term |
pET29-bchI | T7p-rbs-bchI-T7Term |
pET29-bchL | T7p-rbs-bchL-T7Term |
Expression
Once the constructs are inside DH10B or NovaBlue, they were minipreped and transformed in BL21 (DE3). These cells were then induced to overexpress the proteins of interest. After protein expression, the cell cultures were centrifuged at 10,000rpm for 20 minutes. The resulting cell pellets were dissolved in TRIS buffer (pH 7.8) and sonicated. The sonicated cell extracts were then centrifuged again, with the supernatant containing the soluble proteins. The soluble protein extract was used for enzyme activity assays. Along with the soluble protein extract, the total sonicated cell extract and the insoluble cell extract were analyzed on a SDS-PAGE gel. (all expressions were done by Joyce, Mimi, and Konniam; gel was done on 10/24/07)
Enzyme Activity Assays
The E.Coli cells with the constructs pET3a-R-bchHID and pET3a-S-bchHID have all the peptides necessary for the enzyme Mg-chelatase. The activity of these enzymes can be measured by the concentration of the reaction product, Mg-protoporphyrin IX. The concentrations were measured by the UV-vis spectroscopy and fluorescence emission spectroscopy, utilizing the Beer-Lambert law. By assuming that the concentration of the product is proportional to the activity of the enzymes, we can determine which enzyme (either from Rhodobacter sphaeroides or Synechocystis sp) is more efficient.
Subcloning Protocols
Polymerase Chain Reaction (PCR) Protocols:
PCR (Using Phusion Polymerase)
PCR (Using TaKaRa Ex Taq Polymerase)
Clean Up/ Purification Protocols:
DNA Gel Eletrophoresis Protocol:
Restriction Digestion Protocols:
Digestion for PCR Product or Miniprepped DNA
Ligation Protocol:
Transformation Protocols:
KCM Competent Cell Transformation
Electroporation Transformation
Miniprep Protocol:
Expression Protocols
Protein Expression Protocols:
Protein Analysis Protocols: