Upload
others
View
21
Download
0
Embed Size (px)
Citation preview
MOLECULAR PATHOLOGY IN SYSTEM PATHOLOGY
HISTOPATHOLOGY - PRACTICE2019/2020
BARBORA VLKOVÁINSTITUTE OF MOLECULAR BIOMEDICINE
1
cell
DNA
genes
chromosomes
mutations
growth factors
cell cycle
tumor suppresor genes
oncogenes
Eukaryotic cell
DNA Structure
DNA in a Chromosome
DNA Structure
The structure of genes
DNA repair
Tumor Suppressor Genes
Breast CancerSusceptibility Genes
Cell cycle control systems
The p53 Protein,a Guardian of the Genome
Cell cycle control systems
Retinoblastoma
Intracellular Signal Transduction Systems
Origin of TumorsInfluence of Growth Factors on Cell Division
Cellular Oncogenes
Colon cancer
Targeted therapies in cancer
40
Targeted therapies in cancer
• Part of standard treatment
• Depend on the stage of the disease
• Tumor expresses the target of drug
• Clinical trails
41
Types of targeted therapies
• Hormone therapies
• Signal transduction inhibitors
• Gene expression modulators
• Apoptosis inducers
• Angiogenesis inhibitors
• Immunotherapies
• Toxic monoclonal antibodies
Breast cancer & Estrogen
• 1 mil. new cases
• 0.4 mil. die
• The earliest targeted therapies
• Disrupting the activity of the hormone
43
Estrogen
44
Estrogen
45
Breast cancer & Estrogen
46
Inhibition Estrogen I
47
Inhibition Estrogen II
48
Inhibition Estrogen II
49
Hormone therapy for prostate cancer
Breast cancer & HER2
51
HER2 in normal cells
52
HER2 in Signalling
53
HER2 in Cancer Cells
54
HER2 in Cancer Cells
55
FISH
56
Inhibition HER2
57
Breast cancer & IGF
58
IGF in cancer cells
59
Inhibition IGF I
60
Inhibition IGF II
61
Inhibition IGF III
62
IGF & Insuline
63
Breast cancer & PARP
64
Breast cancer & PARP
65
PARP - poly(ADP ribose) polymerase 1
PARP in cancer cells
66
PARP - poly(ADP ribose) polymerase 1
Inhibition PARP
67PARP - poly(ADP ribose) polymerase 1
Inhibition PARP & mutant BRCA
68PARP - poly(ADP ribose) polymerase 1
69
Myeloma & NF-kB
70
NF-kB in Normal Cells
71
NF-kB in Normal Cells
72
NF-kB in Normal Cells
73
NF-kB in Cancer Cells
74
Inhibiting NF-kB
75
Myeloma & HDAC
76
HDACs in Normal Cells
HDAC - histone acetylases
77
HDACs in Normal Cells
HDAC - histone deacetylases
78
HDACs in Normal Cells
79
HDACs in Normal Cells
HDAC - histone acetylases
80
HDACs in Normal Cells
HDAC - histone deacetylases
81
HDACs in Cancer Cells
HDAC - histone deacetylases
82
Inhibiting HDACs
Why do we need molecular pathology?
• The diagnosis
• The prognosis
• The therapy
1. Clinical background
• 57 years old male
• the emergency
– substermal chest pressure
– left forearm pain
– dyspnea at rest
• the medical history
– hypertension, hypercholesterolemia, peptic ulcer
• the social history – smoking
• ECG, laboratory results = myocardial infarction
• two stenotic coronary arteries
• metal stent
• antithrombotic therapy
• one month later – acute myocardial infaction
• thrombosis of the previously stented region of coronary artery
Reason for molecular testing
• a secondary coronary artery thrombosis
– despite treatment
• genetic variability in the CYP2C19 gene affects the pharmacokinetics and response to clopidogrel treatment
– some CYP2C19 variant alleles with reduced enzymatic function are associated with in-stent rethrombosis
• useful to identify resistant patients
– benefit from increased dosage or alternative drugs
• clinically relevant genetic variants of CYP2C19 associatedwith altered CYP2C19 enzymatic activity include CYP2C19*2,*3, and *17
• associated with a significantly increased risk forcardiovascular events including stroke, stent thrombosis,myocardial infarction, and death due to insufficient plateletinhibition
• warning on the package
• Does the CYP2C19 assay result explain the patient’s complications?
– the patient has a reduced function CYP2C19 allele(CYP2C19*2)
– it may have contributed to the stent thrombosis and acute myocardial infarction, due to reduced efficacy of clopidogrel and ineffective platelet inhibition
• Further Testing?
– no further laboratory testing was performed
– antiplatelet medication was changed
2. Clinical background
• a 5 year old boy
• microscopic hematuria and proteinuria
• blood count and metabolic panel normal
• renal ultrasound normal
• X-linked Alport syndrome (XLAS)
• urinalysis, renal function studies,audiometry, ophthalmic evaluation, and skin and/or kidney biopsy
• molecular testing for mutations in theCOL4A5 gene - defective collagen chain = changes in glomerular basement membrane
Reason for Molecular Testing
• no need for further genetic testing
• monitore kidney function for disease progression
• monitore an extra-renal manifestations
• the identification of a disease-causing mutation
– testing of at-risk family members
– targeted testing of COL4A5 exon 50 in mother and her sister to confirm a carrier status of XLAS
Further Testing?
3. Clinical background
• a 25 year old RhD-negative pregnant woman
• father of the fetus RhD-positive
• 1st pregnancy - an antibody screen negative at 15 weeks and remained negative
– treated with Rh immune globulin (RhIG) at 28 weeks
– labor at 40 weeks, the infant was RhD-positive and RhIG again
• 2nd pregnancy - anti-D detected at a titer of 1:8 at 15 weeks, 1:64 at 18 weeks
– the fetal red cells were coated with maternal alloantibodies
– intrauterine blood transfusion
– after delivered exchange transfusion and phototherapy
• 3rd pregnancy:
• What is the differential diagnosis?
– hemolytic disease of the fetus and newborn (HDFN)
– the RhD-negative mother is alloimmunized by exposure tofetal RhD-positive red cells
– maternal anti-D antibodies cross the placenta
– the antibodies lead to the destruction of the red blood cells
Reason for Molecular Testing
• molecular testing for paternal zygosity and prenataltesting of the fetus - a role in the proposedalgorithms for the management of HDFN
• the goal - to minimize invasive procedures (additional exposure to fetal red cells can cause further sensitization)
• paternal zygosity is used to predict the risk of HDFN in pregnancy
– homozygous for the RHD gene (RHD/D)
• the fetus is predicted to be RhD positive, the fetus can be monitored and invasive procedures may be avoided
– heterozygous (RHD/d) for the RHD gene
• fetal DNA testing through amniocentesis, chorionic villus sampling (CVS) or the testing of free fetal DNA in maternal plasma
– the father is RHD-negative
• the fetus is not at risk for HDFN related to anti-D
• RHD zygosity analysis of the paternal sample -father was heterozygous
Extracellular fetal DNA
Extracellular tumor DNA
• RHD zygosity analysis of the paternal sample - father was heterozygous
• the chance that offspring from this father will be RHD-positive is 50%
1 2 3
• the fetus tested positive for all of the RHD-specific targets, indicating that the sample was RHD-positive• the fetus is at risk for hemolytic disease of the newborn related to anti-D
• a 32 years old woman, pregnant for the first time
• no history of cystic fibrosis in her family
• CF carrier screening, she tested negative for the mutations analyzed
– the mutation panel had a detection rate of 93% in Caucasians
• at 16 weeks gestation, prenatal ultrasound identified an echogenic bowel abnormality
4. Clinical background
• What is the differential diagnosis?
– echogenic bowel (normal fetuses, in fetuses with CF, or in fetuses with aneuploidy, intrauterine growth retardation, congenital viral infections, ...)
• She tested negative for CF mutations; could the fetus have CF?
– at risk for carrying a rare mutation
– more than 1,700 CFTR sequence variants have been identified
Reason for molecular testing
• echogenic bowel can be associated with CF
• CF is inherited, an autosomal recessive condition
• mother may have carried a rare mutation
• father could be a carrier of CF also
• carrier status - only molecular test for both parents
• prenatal testing if both parents were shown to be carriers
• CFTR sequence analysis of the fetus identified four sequence changes
Background and Molecular Pathology
• the most common AR disorders (1/2,500)
• life expectancy has increased to the late 30s
• the cystic fibrosis transmembrane conductance regulator (CFTR)
• defective chloride transport across membranes
• a 50 year old man
• a history of hypertension and hyperlipidemia
• malaise, fatigue, pain in the left upper quadrant
• an enlarged spleen was identified
• peripheral blood - marked leukocytosis consisting of increased granulocytic precursors at various stages of maturation
• a bone marrow biopsy showed increased granulocytic precursors with maturation
• family history was negative for any hematologic disorders
5. Clinical background
Reason for Molecular Testing
• various neoplastic myeloproliferative disorders can have overlapping clinical and pathological features
• the molecular testing has diagnostic significance
• testing for the BCR-ABL1 fusion transcript - identified at the chromosomal level as t(9;22)(q34;q11)
• other conditions will be negative for BCR-ABL1, while CML will be positive
• molecular testing in CML monitor the patient’s responseto therapy
Molecular Testing
• initial testing for a suspected case of CML
• RT-PCR assays which target the most common BCR-ABL1 fusion transcripts associated with CML
the qualitative RT-PCR assay
the quantitative RT-PCR assay
• the patient was positive for a high level of BCR-ABL1 fusion transcript with an e14a2 (b3a2):GUSB ratio of >100%
• together with the clinical findings is consistent with a diagnosis of CML
Further Testing?
Molecular monitoring during treatment
pretreatment level
initiation of therapy resistance to therapy response to new therapy
a resistance causing
mutation found in the
ABL1 kinase domain
of the BCR-ABL1
fusion transcript
• a 45 year old female nonsmoker
• complaining of dry cough, pleuritic pain, and headache
• chest X-ray revealed an opacity in the left lower lobe of the lung
• chest CT scan showed a 3.7-cm mass in the left lower lobe andmediastinal adenopathy
• cranial MRI demonstrated a 6.5-cm mass in the occipital lobe, with additional smaller cerebellar lesions
• a primary tumor in the lung
• a brain metastatic adenocarcinoma
Clinical background
• What is the role of molecular testing in this clinical context?
– to guide therapy selection, specifically with regards to the use of an EGFR tyrosine kinase inhibitor (EGFR-TKI)
– to detect activating mutations in exons 18 through 21 of the EGFR gene, the region that encodes the cytoplasmic tyrosine kinase domain of the epidermal growth factor receptor
Results
• sequence traces for part of exon 21, showing a T>Gtransversion at nucleotide 2573 causing a leucine to argininemutation at codon 858 (Leu858Arg)
• patients with this mutation do benefit from treatment with an EGFR kinase inhibitor
• cancergrace.org
inhibition of EGFR receptors/signaling
Why this patient did not respond to EGFR inhibition?
• because of its location downstream of EGFR, proliferativesignals from a mutated KRAS protein will not be inhibited by EGFR blockade
• as a result, KRAS mutant lung cancers do not respond to EGFR inhibition
• lung cancer – the most lethal cancer
• the outcomes typically poor
• 2003 – treatment targeting EGFR tyrosine kinase
• confirmed association between EGFR mutation status
and response to the TKI therapy
• female nonsmokers, asian ethnicity – sustained
responses
Background and Molecular Pathology
www.imbm.sk