Bio 140.02 Workflow Module 3 plasmid DNA postlab PDF

Summary

This document describes a workflow for Module 3: DNA, focusing on the extraction of plasmid DNA via alkali lysis and subsequent visualization and analysis. It also includes an overview of DNA structure, prokaryotic and eukaryotic cells, and various DNA extraction sources.

Full Transcript

Workflow for
~

Module 3:
Sample used: recombinant E. coli with pET28a-sfGFP
DNA
2 introduced DNA from other species
Bacterial culture
Overnight culture of recombinant E. coli

Extraction of plasmid DNA Amplification of the sfGFP gene insert

Plasmid DNA Extraction via Alkali Lysis Polymerase Chain Reaction

Visualization of extracted DNA

Agarose Gel Electrophoresis

Spectrophotometric Analysis of Extracted DNA

Ultraviolet Spectrophotometry
 www.quora.com/How-is-DNA-different-in-prokaryotes-and-eukaryotes
negativecharge enphosphate
↑

polymer
=
polar

[ hitrybaseSi, Anti-paralled a Joisted
helix
into a

Single-stranded DNA: Double-stranded DNA: DNA double helix:

Prokaryotes (Bacteria and Archaea) Eukaryotes have a nucleus, and
have no nucleus, genomic DNA is genomic DNA is linear and
circular and “naked” organized as chromatin
"coiled around history
proteins
Prokaryotes and eukaryotes have non-genomic DNA.
J
mitoch
plasmidy(
&
chorplant
 DNA Extraction
Source: Cell cultures: Plant/animal tissue: Forensic evidence: Environmental samples

https://labshakers.wordpress.com/ www.youtube.com/watch?v=xlrwef2Y3f0 https://bigdata.cgiar.org/
https://sciencing.com/ https://www.deq.ok.gov/
(pure source I well wall
harder to Rondi long yung sample Lentire biome

lyse

high incentrations a
relatively pre
~ won't interfere
long
↳
as an it we
further methods camptis)
OBJECTIVE: high recovery of DNA with no impurities and inhibitors
applicable for downstream processes
DNA Extraction
OBJECTIVE: high recovery of DNA with no impurities and inhibitors
applicable for downstream processes

General steps:
1. Collection of cells /centrifugation pellet)>
-

2. Cell lysis of cells which releases the
DNA (and other cellular contents)
prote: cell wall a membrane

3. Separation of DNA from other -through reagents
/or centrifugated
and
cellular material
4. Precipitation and concentration of
DNA.
 DNA Extraction
OBJECTIVE: high recovery of DNA with no impurities and inhibitors
applicable for downstream processes
Recombinant bacterial cell cultures:
General steps:
1. Collection of cells
2. Cell lysis of cells which releases the
DNA (and other cellular contents)
https://labshakers.wordpress.com/
3. Separation of DNA from other
cellular material
4. Precipitation and concentration of
DNA.
 I markers
=

ampicillin resistance

Plasmid DNA
 Plasmid DNA
Lextra chromosomal ANA
DNA
reparated from generic independent replication
~
covalently closed: circular

-naturally occuting or synth-via recog. DNA Jech (otoning)

Plasmid DNA
Plasmid DNA extraction via Alkali Lysis
Workflow: OBJECTIVE: recovery of DNA applicable for
downstream processes
(with no impurities and inhibitors to
inhibit PCR)

cresuspension)
inc -
osmotic pressure
Al regulator
chelator :
binds divalent ions (cofactors of nucleased

Calkali lysis)
& MWANS denatured
alkali
=
makessample ;

denatures proteins ; lytis

(neutralization soln)
dissolved
7 ↓ pl (acidic)
AND and
precip of
>
-

Yields plasmid
complexes (IMWANAd proteins)
] precip plasmid ANA from soon

store plasmid here

pl
ph ,
chelator
Recombinant Escherichia coli

https://labshakers.wordpress.com/

Cultured in LB Broth with Kanamycin
Plasmid DNA

'
Danamyin
s

orig of replic.

https://www.addgene.org/85492
DNA Extraction: next steps
Visualization: agarose gel
electrophoresis Downstream applications:
Amplification via PCR
DNA sequencing
Cloning for recombinant DNA
applications

Quantitative/Qualitative analysis:
UV spectrophotometry
 Workflow for Module 3:
Sample used: recombinant E. coli with pET28a-sfGFP
DNA
Bacterial culture
Overnight culture of recombinant E. coli

Extraction of plasmid DNA Amplification of the sfGFP gene insert

Plasmid DNA Extraction via Alkali Lysis Polymerase Chain Reaction

Visualization of extracted DNA

Agarose Gel Electrophoresis

Spectrophotometric Analysis of Extracted DNA

Ultraviolet Spectrophotometry
Electrophoresis

*
0008-yellow
·
: 88-bhe
= -wood -
small
travels
Electrophoresis is the migration through a matrix of charged faster
d

molecules in solution by applying an electric field farther

Speed of migration: depends on charge, shape, size of the molecule;
and the gel concentration
Molecular separation technique
Agarose gel:

Source: https://www.wisegeek.com/what-is-agarose-gel.htm
Agarose is a linear polysaccharide extracted from red
marine algae

D-galactose 3,6-anhydro-L-galactose
DNA and RNA: migration thru the gel
-much

↑ pares -

↓ van

↓ powers ↑ conot usgen ↳
bacir (bp)
,

small

1 kb Plus DNA Marker, NEB
www.neb.com
https://thebumblingbiochemist.com/ https://bit.ly/2Oujks8
 Agarose gel electrophoresis (AGE)
OBJECTIVE: confirm the success of genomic DNA extraction

 Agarose gel preparation  Sample loading and electrophoresis  Visualization

https://commons.wikimedia.org/wiki/File:Loading_DNA_sample
_into_to_agarose_gel_electrophoresis.jpg
Electrophoresis components
Source: http://www.mupid.com/

Source:
UV excites

LEBr for

visualization
 but
Buffer system: Loading buffers: >
-
not stain
lotoes only for
visualization of
movement
Tris-acetate-EDTA (TAE) Blue
Tris-borate-EDTA (TBE) Tracking dyes
Glycerol ine density
-

Buffer/ddH2O para
di

magfloat

Source: Agarose Gel Electrophoresis
Tip #1: TAE vs TBE
https://youtu.be/eQqhOSp80Qg
Source:
https://commons.wikimedia.org/wiki/File:Loading_DNA_sample_i
nto_to_agarose_gel_electrophoresis.jpg
Visualizing DNA:

WARNING:
Ethidium bromide is highly MUTAGENIC!
 Gel Red 

↑makakapa
Gel Red 
molecules
it

Safer alternative to ethidium bromide:
Gel Red  L
nuc-acids
IUPAC name:
5,5'-(6,22-dioxo-11,14,17-trioxa-7,21-
diazaheptacosane-1,27-diyl)bis(3,8-diamino-6-
phenylphenanthridin-5-ium) iodide
Other names: Dye No. 35
 louent crosslinking permanent get NUC
- form
Dada-larger
SDS-PAGE vs AGE, Protein vs NA proteins - maller
I will meld is
Resolving Power
neated
Molecular Weight
vertical horizontal

http://book.bionumbers.org/

https://thebumblingbiochemist.com/
 DNA supercoiling: Circular DNA
ladder

MW' =
linear

Plasmid-cir  Open circular (relaxed) of is d

I
is MW need
kaioil
just for ng
tranking of micle
weight
Movement
&
same plazaid
 Supercoiled of is M sila
 Plasmid DNA (pET28a-sfGFP, MW 5975bp ) was extracted from recombinant pET28a-sfGFP, MW 5975bp
E. coli via Alkali Lysis, run in a 1% agarose gel at 100 v for 45 minutes, and
stained with ethidium bromide. For all samples, 5 ul was mixed with 2 ul gel
loading dye and the entire volume loaded into the gel. The MW marker
used was CSL-MDNA-1K (Cleaver Scientific)
Group 1 Group 2
1 2 3 4 5 1 2 3 4 5

a
Hand

camd MW marker guide CSL-MDNA-1K

A
s

degraded
near
I

Bio 140.02 SU, 1st Sem, SY 24-25
 Plasmid DNA (pET28a-sfGFP, MW 5975bp ) was extracted from recombinant pET28a-sfGFP, MW 5975bp
E. coli via Alkali Lysis, run in a 1% agarose gel at 100 v for 45 minutes, and
stained with ethidium bromide. For all samples, 5 ul was mixed with 2 ul gel
loading dye and the entire volume loaded into the gel. The MW marker
used was CSL-MDNA-1K (Cleaver Scientific)
Group 3 Group 4
1 2 3 4 5 1 2 3 4 5

MW marker guide CSL-MDNA-1K

Bio 140.02 SU, 1st Sem, SY 24-25
 Workflow for Module 3:
Sample used: recombinant E. coli with pET28a-sfGFP
DNA
Bacterial culture
Overnight culture of recombinant E. coli

Extraction of plasmid DNA Amplification of the sfGFP gene insert

Plasmid DNA Extraction via Alkali Lysis Polymerase Chain Reaction

Visualization of extracted DNA

Agarose Gel Electrophoresis

Spectrophotometric Analysis of Extracted DNA

Ultraviolet Spectrophotometry
The electromagnetic spectrum
Many biological molecules
intrinsically absorb light in the UV
range
Absorption can be measured with a
spectrophotometer

https://imagine.gsfc.nasa.gov/science/toolbox/emspectrum1.html

Basic structure of spectrophotometers
(illustrated by Heesung Shim, https://chem.libretexts.org/ )
UV Spectrophotometry
A UV-VIS spectrophotometer
and cuvettes
www.medicalexpo.com

100 µL – 1000 µL sample volume

NabiTM UV VIS nano
Basic structure of spectrophotometers spectrophotometer
(illustrated by Heesung Shim, https://chem.libretexts.org/ ) www.md-best.com/nabi.html/

0.5 µL – 2.0 µL sample volume
Microvolume spectrophotometers have allowed the
reading of absorbance of samples without the need
for containment devices like cuvettes or capillaries
DNA UV Spectrophotometry Workflow:
OBJECTIVE: check purity and concentration of DNA extract

NabiTM UV VIS nano
spectrophotometer
www.md-best.com/nabi.html/

0.5 µL – 2.0 µL sample volume
 DNA and UV Spectophotometry
Nitrogenous bases Protein backbone, salts, phenol Amino Acids (aromatic rings)
260 nm 230 nm 280 nm
because dis
nitro

peal maxabs & zoonuh
o lit because o
-

-
-
max abs & 280

Depfre as
I because of amae

↳

www.biotek.com/assets/tech_resources/A260A280_Spectral_Scanning_App_Note.pdf
 UV Spectrophotometry to assess purity
Pure preparation of DNA: 1.8 < (Abs260/Abs280) < 1.9
Protein contamination: (Abs260/Abs280) < 1.8
RNA: (Abs260/Abs280) > 2.0
Pure preparation of DNA: 2.3 < (Abs260/Abs230) < 2.4
⑧
l used
secondary
as

measure

… and to estimate concentration
[dsDNA] = (Abs260) x (dilution factor) x (50 µg/mL)
Where: dilution factor = total volume of diluted solution/volume of sample
UV Spectrophotometry to estimate concentration

[dsDNA] = (Abs260) x (dilution factor) x (50 µg/mL)
Where: dilution factor = total volume of diluted solution/volume of sample

Derived from the Beer-Lambert law, the amount of light absorbed at 260 nm is
proportional to the concentration of nucleic acid in solution.

Extinction coefficients have been determined for dsDNA, RNA, and ssDNA using a
10 mm path length and allow the creation of conversion factors in the absence of a
standard curve.

For example, a dsDNA sample with A260 = 1 will have a concentration of 50 ng/µl
(for pure samples only!)
DNA UV Spectrophotometry Workflow:
OBJECTIVE: check purity and concentration of DNA extract

it is blank

needfera
no
NabiTM UV VIS nano
spectrophotometer
www.md-best.com/nabi.html/

0.5 µL – 2.0 µL sample volume
 Class Results

Sample Abs 230 Abs 260 Abs 280 Abs260/ Abs 260/ Purity Estimated
Abs280 Abs230 ng/uL DNA
 Workflow for Module 3:
Sample used: recombinant E. coli with pET28a-sfGFP
DNA
Bacterial culture
Overnight culture of recombinant E. coli

Extraction of plasmid DNA Amplification of the sfGFP gene insert

Plasmid DNA Extraction via Alkali Lysis Polymerase Chain Reaction

Visualization of extracted DNA

Agarose Gel Electrophoresis

Spectrophotometric Analysis of Extracted DNA

Ultraviolet Spectrophotometry
 All notes are on

Polymerase Chain Reaction (PCR) cellmo) notebook

In vitro cloning of DNA using Kary Mullis (1944 – 2019)
Invented PCR in 1983
a thermostable DNA Nobel Prize (Chemistry) 1993

polymerase
C:\Documents and Settings\AMOR\My Documents\RAs folder\trinket\MBB Primer (VDM)\ver.2\PCR.jpg
 Polymerase Chain Reaction (PCR)
Thermal cycling:
PCR uses repeated rounds of: Denaturation
1. Denaturation, of dsDNA Extension of primers
by DNA pol
2. Annealing, and (“elongation”)

3. Elongation
Hybridization
to amplify DNA (“annealing”)
of primers
 Polymerase Chain Reaction (PCR)
Each cycle doubles the
amount of DNA in the
previous cycle to that
after a few cycles, the
predominant DNA in the
reaction is identical to
the sequence specified
by the primer pair.
 Sample Results: PCR of plasmid DNA
DNA Template DNA used PCR amplification product
Dilute DNA to use as template

PCR: amplify gene insert

23,130 bp
21,226 bp
2,322

564 1,584 900 bp

Target for amplification using forward and
reverse primers is indicated in RED, expected
MW of PCR product is approximately 900 bp.
 Optimization of PCR reaction mixes and
cycling parameters:
PCR experiments often have to be OPTIMIZED so that stringent
conditions yield specific products.

Components of PCR
Source: www.goldbio.com/goldbios-pcr-overview
 PCR experiments often have to be
Trouble shooting PCR OPTIMIZED so that stringent
conditions yield specific products.

Common problems Things to check:
No product/low DNA template
amplification Primers
Incorrect product size Other reaction
Multiple bands/non- components:
specific amplification/ Mg2+
smears Polymerase
Primer dimers Contaminants in the
reaction
False positive (negative
control amplifies) Cycling parameters

Technical References: https://international.neb.com/tools-and-resources/troubleshooting-guides/pcr-troubleshooting-guide
https://www.thermofisher.com/ph/en/home/life-science/cloning/cloning-learning-center/invitrogen-school-of-molecular-
biology/pcr-education/pcr-reagents-enzymes/pcr-troubleshooting.html
Polymerase Chain Reaction (PCR)
OBJECTIVE: amplify the uperfolder GFP gene insert in the pET28
plasmid
Plasmid DNA - PCR
Template DNA

Target for amplification using T7 forward and
reverse primers is indicated in RED, expected MW
of PCR product is approximately 900 bp. https://www.addgene.org/85492
Polymerase Chain Reaction (PCR)
PCR cycling parameters:
Initial denaturation 94C 30 secn
27 cycles:
Denaturation 94C 30 sec
Annealing 41C 40 sec
Extension 68C 60 sec
Final extension 68C 5 min
Hold 4C  ֹֹ
Horn, I. R., Verleg, P. A., Ibrahim, N. Z., Soeleman, K., van Kampen,
F., Ruesen, M. O.,... & Gravendeel, B. (2020). Mushroom DNA
barcoding project: Sequencing a segment of the 28S rRNA
gene. Biochemistry and Molecular Biology Education, 48(4), 404-
410. https://doi.org/10.1002/bmb.21388
 Molecular Weight Marker Guide, VC 1kb DNA

Class result:
Groups 4 and 8

pET28a-sfGFP, MW 5975bp

Target for amplification using T7 forward and
reverse primers is indicated in RED, expected
MW of PCR product is approximately 900 bp.
 Virtual Lab: Bacterial ID

https://www.biointeractive.org/classroom-resources/bacterial-identification-virtual-lab
Overall objective of virtual lab

?
https://en.wikipedia.org/wiki/DNA_barcoding
 PCR & DNA Barcoding

https://doi.org/10.3389/fevo.2020.00028

https://blog.nationalgeographic.org/2017/06/16/sushi-roulette-
is-the-fish-you-ordered-the-one-you-got/
https://www.boredpanda.com/fish-fraud-dna-test-biology-students-homework/
https://twitter.com/AwesomeBioTA
https://www.eurekalert.org/news-releases/938896
Barcoding of Life: digital identification for life http://www.ibol.org/
 The chemistry of DNA synthesis
DEOXYNUCLEOSIDE TRIPHOSPHATES
(dNTPs)

DIDEOXYNUCLEOSIDE TRIPHOSPHATES
(ddNTPs)

Sanger sequencing (aka chain-
termination or dideoxy
H
sequencing) which makes use of
ddNTPs.
Chain-termination
sequencing (automated)
1. Reaction components
Template DNA (to be sequenced)
DNA polymerase
Oligonucleotide primer
Standard dNTPs
ddNTPs – each labelled with a
different fluorescent marker
Thermal cycle sequencing
2. Separation of fragments using
capillary gel electrophoresis
Source: Automated DNA Sequencing
www.magazinescience.com/en/biology/automated-dna-sequencing/
 www.wired.com/2008/07/british-institu/

Source: Automated DNA Sequencing
www.magazinescience.com/en/biology/automated-dna-sequencing/
Sequencing files (results)

1. Chromatogram (.abi,.pdf)
2. DNA sequence (FASTA,.txt)

Sample files from ZAN Maini
NGS: next generation sequencing (current, 2 nd gen)

High throughput
Micro- and nano-technology
Different technologies by
different companies
Sequencing of DNA libraries
“shotgun,” “parallel”
Massive parallel sequencing
= A LOT OF DATA Source: “The third wave of next generation sequencing”
https://bit.ly/3rkNf3I

Reduce sample size, cost and Third gen:
time
Single molecule sequencing
Information databases: public domain

The International Nucleotide
Sequence Database Collaboration is
the core infrastructure for sharing
nucleotide sequence data in the
public domain

The total size of sequence data
maintained by the INSDC has
exceeded 9 petabytes in 2020.
BLAST
 BLAST

“find regions of local similarity between sequences. The
program compares nucleotide or protein sequences to
sequence databases and calculates the statistical
significance of matches. BLAST can be used to infer
functional and evolutionary relationships between
sequences as well as help identify members of gene
families.”
BLAST
https://microbenotes.com/bioinformatics-introduction-and-applications/https://microbenotes.com/bioinformatics-introduction-and-applications/