Title: ADVANCED MOLECULAR BIOLOGY
1(No Transcript)
2 MOLECULAR MEDICINE David
Blicq dblicq_at_rrc.mb.ca Chemical Bioscience
Technology               Â
3A Fantastic Voyage?
4Or the future of Medicine?
5Topics
- Diagnostics for Infectious Disease
- Diagnostics for Genetic Disease
- Gene Therapy
- Stem Cells
- Nanomedicine
61. Diagnosis of Infectious Disease
- Recent developments have significantly altered
the monitoring and diagnosis of infectious
diseases - There are two general methods for examining
infectious disease - microbial phenotype characterization
- nucleic acid techniques
7Shift to DNA-based testing
8Old School Diagnosis
- Microbial Phenotying (examine physical
characteristics) - Biotyping (grow organisms on media)
- Protein content (of pathogen)
- Bacteriophage profiles (virus analysis)
- Chromatography (membrane lipids)
- Antibiotic (susceptibility testing)
9Old School Diagnosis
- Biotyping (grow them)
- examines the physical / morphological
characteristics - includes growth media, biochemical uptake /
usage, staining, etc. - produces a "biogram" (a combination of analytical
information) - not always definitive, not always stable
10Old School Diagnosis
- Antibiotics / Resistograms
- test an organism's resistance to specific
antibiotics - develop a "resistogram" or "antibiogram" (a
detailed profile of antibiotic resistance to a
range of compounds) - Problem! - common resistance to an antibiotic
does not always indicate organisms are related!
11Old School Diagnosis
- Challenges
- Time have to culture and grow pathogen
- Lab Safety need to keep many pathogenic
cultures alive in lab - Accuracy not always definitive
- Limited Info no information on antibiotic
resistance or virulence factors
12Molecular Diagnosis
- Can detect disease-causing agents without having
to grow them (directly from sample) - Can detect slow / hard to culture microbes
- Can amplify DNA to get more accurate results
- ID sub-species (excellent discrimination)
- ID genes that impart drug resistance (i.e. target
the treatments) - Fast results - automated systems available
13Molecular Diagnosis
- Overall - PCR and nucleic acid amplification
technology has one enormous benefit bacterial
growth is no longer necessary to detect and
characterize microorganisms! - "Amplicons" (amplified products) are
characterized by - nucleic acid probe hybridization (labeled probes)
- analysis of fragments after restriction digestion
- direct sequence analysis
14Molecular Diagnosis
- Nucleic Acid Techniques
- Plasmid profiling (when characteristic plasmids
are available) - RFLP analysis (restriction fragment length
polymorphisms - use RE to produce characteristic
gel fragments) - PCR (amplify key sequences which distinguish
target microorganisms)
15Molecular Diagnosis
- Plasmid Analysis
- plasmids are small, self-replicating circular DNA
molecules found in many bacteria - plasmids often code for resistance to antibiotics
and certain virulence factors - widely-used for tracking resistance in disease
outbreaks / pandemics - can track transfer of resistance between
hospitals, organisms, and countries - weakness - can transfer between microbes
16Molecular Diagnosis
- Restriction Enzyme Pattern
- Cut DNA at specific location using natural
enzymes restriction endonucleases - get characteristic fragments RFLP's /
restriction fragment length polymorphisms - see fragments via electrophoresis
- very accurate can ID between microbial strains
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18Molecular Diagnosis
- Uses of Restriction Enzyme Patterns
- identification of bacterial populations
- epidemiology (spread of disease through
population), pandemic science - study of Tuberculosis in HIV-positive patients
- combined with DNA fingerprinting (southern blot,
etc.) it is a very powerful tool
19Molecular Diagnosis
- PCR Polymerase Chain Reaction
- Making copies of a DNA sequence
- PCR is conducted in vitro (beaker / test tube)
- 20 cycles of PCR can allow for a 1,000,000 X
amplification of DNA samples - Typical PCR reactions use small (ng-mg)
quantities of DNA and go through 30-40
amplification cycles - PCR has revolutionized RD in biology / medicine
and helped refine criminology and law
20PCR
21Molecular Diagnosis
- Nucleic Acid Probes - MicroArray
- can identify organisms at, or below species level
- can detect fastidious organisms directly
(bacteria, viruses, mycobacteria, fungi and
parasites) - Commercial kits available Gen-probe, Microprobe,
Digene etc. (all FDA approved) - procedures are well-standardized
- use short, synthetic DNA probes for well
understood characteristic sequences
22Molecular Diagnosis Probe/Microarray
23Summary - Molecular Diagnosis
- many different nucleic-acid based methods
- don't have to culture / grow organism (excellent
for dangerous / fastidious organisms) - can detect disease-causing gene mutations (in
humans, etc.) - can track drug resistance
- fast, sensitive, and improving all the time
- limit - contamination and amplification of
contaminants
242. Diagnostics for Genetic Disease
- Genetic diseases are transferred through families
- Often seemingly random
- Early awareness can lead to early therapy
25Genetic Disease - Trends
- reduced prevalence of infectious diseases due to
vaccination, antibiotics and improved sanitation - increased prevalence of genetic diseases due to
increased life expectancies reduced prevalence of
infectious diseases
26Why study Genetic Disease?
- may provide the biochemical basis to the disease
(help designing therapies) - can devise a screening program
- Identify mutant genes in individuals who are
carriers - To find the approximate position of the gene in
the human genome (ex. breast cancer) - Most have no family history of the disease in
some a predisposition to acquiring the disease
27Methods of studying Genetic Disease
- Linkage analysis - Comparing the inheritance
pattern for the target gene with the inheritance
patterns for healthy individuals - Pedigree analysis need to obtain DNA samples
from at least three generations of each family - Example breast cancer research at HSC
28Pedigree / Linkage Analysis
293. Gene Therapy
- Techniques that aim to cure an inherited disease
by providing the patient with a correct copy of
the defective gene - Can include gene addition or gene subtraction
30Gene Therapy for Inherited Diseases
- Germline therapy uses a fertilized egg, so the
gene is present in all cells of the resulting
individual - Somatic cell therapy healthy cells are removed
from an organism then placed back in the body
(with a retrovirus-based vector)
31Gene Therapy for Inherited Diseases
- Somatic cell therapy - good for inherited blood
diseases (e.g., haemophilia, thalassemia stem
cells from the bone marrow) and lung diseases
(e.g., cystic fibrosis periodic inhaling of DNA
in rats) - no good method available yet for replacing a
defective gene (necessary for a dominant one) - Current therapies add a gene but cant replace
the defective information yet
32Gene Therapy and Cancer
- gene therapy can be applied not only to inherited
/ infectious diseases but also cancer - specific killing of cancer cells using
cancer-specific promoters and toxin genes - cause tumor cells to synthesize strong antigens
that are efficiently recognized by the immune
system - suitable delivery methods to the cancerous cells
are not yet available
33Gene Therapy and Cancer
344. Stem Cells
- Stem cells are poised to revolutionize medical
science - Re-grow damaged tissues
- Fix otherwise lethal abnormalities
- Potential to repair birth defects before symptoms
ever appear - Cure incurable diseases (MS, ALS, etc.)
35Stem Cells
- There are two core characteristic of stem cells
that set them apart from other cell and tissue
types - Differentiation - they can differentiate into
many different cell types - Replication - they continue to grow and replicate
to replace tissues, etc.
36Stem Cells
37Somatic Stem Cells
- Somatic stem cells occur in different types
- Haematopoietic stem cells blood-forming stem
cells are found in the bone marrow as well as the
umbilical cord of newborn babies. - Stromal stem cells (bone marrow cells) can
differentiate into cartilage, fat/adipocytes and
bone. - Neural stem cells can differentiate into various
neural cells including neurons and the
myelin-sheath producing oligodendrocytes.
38Embryonic Stem Cells
- Derived from cells of the inner cell mass of the
blastocyst (lt5 day old embryonic cell mass)
-typically has less than 160 cells in total. - Like Somatics, Embryonic stem cells have two core
characteristics - an unlimited capacity to self-replicate
- Â the capability (potency) of differentiating into
any one of the more than two hundred identified
tissue types found in the human body.Â
39 40Save Your Cells!
- Currently, more than 45 disorders can be treated
with with therapies that involve the use of stem
cells from umbilical cord blood - A number of independent companies now offer to
"bank" a baby's umbilical cord blood as a
potential source of stem cells which could one
day combat currently untreatable disordersÂ
41Stem Cell Therapy Requirements
- Proliferation - stem cells must replicate in
quantities that make them therapeutically - Differentiation - stem cells must possess the
appropriate level of differentiation - Biocompatibility - stem cells must not illicit an
antigenic response from the - Longevity - therapeutic stem cells must survive
as long as the cells they are intended to
replace.
42Therapy Research
435. Nanomedicine
- Nanotechnology is the study and interaction with
materials and systems at the nanoscale level - or
approximately 0.1-100 x 10-9 meters. - At this microscopic scale, scientists and
engineers are interacting with materials at the
molecular and even atomic level, where the
chemical, physical, electrical and biological
properties are being viewed and understood as
never before
44Nano technologies
- nanomedicine
- biological sensors and diagnostics
- micro-mechanical devices and nano-machinery
- detection and treatment of disease
- molecular-level assembly and manufacturing
- nano-factories and production
- self-replicating mico-machines
- manipulation of events "atom by atom"
45Nano benefits
- Enhanced Diagnostics - diagnosis and repair
before the disease occurs - Sensitivity and Resolution - small, even
molecular-level conditions can be observed and
assessed at the cellular level - Automation - self-directing nano-machines will
find diseased cells and initiating repairs - Artificial Immunology - micromachines could be
set to track down and eliminate specific diseases
46Example
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48Free Online Resources - click to visit site
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50Free Online Resources - click to visit site
51Free Online Resources - click to visit site
52Free Online Resources - click to visit site
53 MOLECULAR MEDICINE David
Blicq dblicq_at_rrc.mb.ca Chemical Bioscience
Technology               Â