The applications of advanced proteomic and genomic

techniques in cancer

Seminar by

Dr. Ayat Al-Ghafari

Thursday 21^st November 2013



Overview (cancer)



Protein synthesis



What does proteomic mean?

1.

Two-dimensional gel electrophoresis

2.

Mass spectrometry (MS)



What does genomic mean?

1.

Gene expression microarray

Outlines



Cancer is a life threatening disease.



It is a heterogeneous and multifactorial disease.



Although many advances have been made to treat cancer, the survival rate for patients with some types of cancer remains poor.



A main reason behind this is the limitation in understanding the biology of cancer.

Overview (cancer)

 Recently, advanced proteomic and genomic approaches have been used to understand cancers and to improve the response of patients to currently used drugs.

 In this seminar, I will focused on two major proteomic and one major genomic techniques that are widely used to

elucidate the differences in protein and gene expressions, respectively and their correlation with cancer.

 Before that I will briefly mentioned how proteins are formed in our cells.

Overview (cancer)

 The two main processes involved in protein synthesis are:

1. The (transcription) of genomic information from DNA to mRNA in the same way as the DNA is replicated during cell division. This process takes place in the nucleus.

2. The conversion of mRNA to protein at the ribosome (translation) which takes place in the cytoplasm.

Protein synthesis

Protein synthesis

So……

What does proteomic

mean???

 The analysis and identification of thousands of proteins in a cell or tissue mixture has become easier since the

introduction of two-dimensional gel electrophoresis in 1975 and protein mass spectrometry in 1985.

 Proteomic is the study of proteome (the collection of all proteins in the cell).

 It was first invented in 1997by Marc Wilkins when he was working on the concept as a PhD student.

Overview (Proteomic)

 Detect the different proteins expressed by tissue, cell culture, or organism using 2-Dimensional Gel Electrophoresis .

 Store those information in a database.

 Compare expression profiles between a healthy cell vs. a diseased cell.

 The data comparison can then be used for testing and rational drug design.

Aims of Proteomic

 Is a separation technique based on the motion of charged molecules in an electric field.

 Usually used a porous matrix (Agarose or polyacrylamide).

 For protein separation: Polyacrylamide gel provides a porous matrix (PAGE – Polyacrylamide Gel Electrophoresis)

 Sample is stained with comassie blue or bromophenol blue to make it visible in the gel when we load the sample on the gel and during the run.

Gel Electrophoresis

Gel Electrophoresis Steps

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 Separation in only 1 dimension based on the molecular weight.

 Smaller molecules travel further through the gel.

 Electric field across gel separates molecules based on the charge of the molecules.

 Proteins are treated with the

denaturing detergent SDS (sodium dodecyl sulfate) which coats the protein with negative charges, hence SDS-PAGE.

1-Dimensional (1-D)

Gel electrophoresis

 It is a technique used to separate proteins based on two properties:

1. In the first dimension, proteins are separated according to their isoelectric point (pI) in a process known as isoelectric focusing (IEF) along a strip that has an immobilized pH gradient range.

2. In the second dimension, proteins are separated in a vertical direction according to their denatured molecular weight through a gradient polyacrylamide gel.

Two-dimensional (2-D) gel electrophoresis

 Is a technique used to separate different molecules by differences in their isoelectric point (pI).

 The pI is the pH where NO charge is on the amino acid.

 It is not necessarily that pI=0 in pH=7.

 The pI is different for different amino acids.

Isoelectric focusing (IEF)

COO - C

N H₃₊

R H

at pI charge = 0

IEF

 Usually the protein spots are determined after scanning the gels and using a software to compare the expression changes among several samples or tissues through these steps:

Determination of protein spots

Image QC

Spots detection Gel

alignment Reference

image selection Experiment

design setup Progenesis

stats

Protein identification

by MS

 MS is an analytical technique that

produces spectra of the masses of the atoms or molecules comprising a

sample.

 If there is a mixture of different

molecules in a sample, all the masses are measured simultaneously. So you get a spectrum.

 The mass spectrum is a plot of the (relative) abundances of the ions at each m/z ratio.

Mass Spectrometry (MS)

Each peak corresponds to a different type of molecule in your sample

10000 1200 1400 1600 1800 2000 2200 2400 2600 2800 3000 m/z

100

%

2790.22

1324.60

1265.62

1179.41

2789.22

1325.62

2466.18 2465.20 1759.93

1326.60

1477.62 1327.61 1460.59

1748.86 1478.61

1540.63

1974.94 1760.93

1761.92

1975.93

2356.10 2355.11 1976.92

2179.87

2467.19

2468.20

2469.17 2746.23 2791.23

2792.23

2793.23

3104.41 2794.20

3103.43

2795.06 3106.42

...

… 2789.22 3597.0 2790.22 5018.0 2791.23 4406.0 2792.23 2868.0 2793.23 1234.0

…

… peak list

Components of MS

1. Ionisation-Gaseous atoms of a particular element are bombarded with electrons fired from an electron gun.

These electron particles will give the gaseous atoms of the specific element a charge. This charge may vary; or some atoms may have no charge at all.

2. Acceleration-The atoms, now charged, are called ions and because these ions are charged they can be

accelerated by an electric field.

3. Deflection-The charged ions of the particular element,

now being accelerated through the deflector, will now be deflected by a magnetic or electric field.

4. Detection-By the charged ions being deflected, they

will hit a detection material-either electric or

photographic.

Components of MS

^cont…….

Drift region (D)

MALDI Time-of-flight

Putting These Steps Together

MALDI TOF

Final result = the spectrum

www.csd.uwo.ca



The final step is the detection of the protein of interest in the database and this can be done through the

following steps:

1.

The mass of the protein in the sample is detected by spectrometer.

2.

Then the unknown masses in our sample were compared to other known masses in database to determine the protein type.

Final step in Protein “identification” with

MS

Next, we will talk about

genomic applications

 Before understanding what genomics mean, we need to know what is genome????

 A genome is “all the DNA contained in an organism or a cell, which includes both the chromosomes within the

nucleus and the DNA in mitochondria… all our genes together [Source: National Human Genome Research Institute].

 Genomics is “the study of functions and interactions of all the genes in the genome, including their interactions with

environmental factors” [Collins, F. and Guttmacher, A. “Genomic Medicine—A Primer,” NEJM, Vol. 347:1512-1520].

Overview (Genomic)



Genetic variations are important factors in cancer.



Understanding how these genes alterations can

increase the risk of cancer and affect the therapies is important to draw a comprehensive picture about it and help to design a new therapy regimen.

Overview (Genomic)

^Cont

…..

 Genetic testing

◦To detect mutations.

 Pharmacogenomics

◦The development of drugs tailored to specific subpopulations based on genes.

◦Pharmacogenomics has the potential to:

 Decrease side effects of drugs.

 Increase drug effectiveness.

 Make drug development faster and less costly.

Aims of genomics

 Recent research in genomics includes

◦Learning more about the genetic underpinnings of chronic diseases

◦Developing mouse models of human genes

◦Developing genetic fingerprinting for childhood cancer

◦Conducting stem cell research

◦Identifying tumor suppressor genes

Aims of genomics



One of the major genomic applications which plays an important role in understanding cancer biology is gene

expression microarray.



In a gene expression experiment, the expression levels of thousands of genes are simultaneously monitored to study the effects of certain treatments, diseases, and developmental stages on gene expression by comparing gene expression in infected to that in uninfected cells or tissues.

Gene expression microarray

(DNA Microarray)



A DNA microarray is a collection of microscopic DNA spots attached to a solid surface.



Each DNA spot contains picomoles (10

⁻¹²

moles) of a

specific DNA sequence, known as probes.

 These probes can be a short section of a gene or other DNA element that are used to hybridize a complimentary DNA (cDNA) sample under high-stringency conditions.

 Probe-target hybridization is usually detected and quantified by detection of fluorescent or

chemiluminescence-labeled targets to determine relative abundance of nucleic acid sequences in the target.

Workflow of GeneChip Microarray steps

Final result will be presented in different colors. Each color

represent different expression pattern for the genes. These colors known as probes intensities.

The black features represent no intensity. The intensity level from

lowest to highest by color is: Dark blue -> Blue -> Light Blue -> Green ->

Yellow -> Orange -> Red - > White.

These are the different analyses obtained from software that showed expression patterns.

 HANAHAN, D. & WEINBERG, R. 2000. The hallmarks of cancer. Cell, 100, 57-70.

 O'FARRELL, P. H. 1975. High resolution two-dimensional electrophoresis of proteins. The Journal of Biological Chemistry, 250, 4007-4021.

 WHITEHOUSE, C. M., DREYER, R. N., YAMASHITA, M. & FENN, J. B. 1985.

Electrospray interface for liquid chromatographs and mass spectrometers.

Analytical Chemistry, 57, 675-679.

 GRESHOCK, J., NATHANSON, K., MARTIN, A. M., ZHANG, L., COUKOS, G., WEBER, B. L. & ZAKS, T. Z. 2007. Cancer cell lines as genetic models of their parent histology: analyses based on array comparative genomic hybridization. Cancer Research, 67, 3594-3600

References

Thanks for your attention ………