Mechanisms of Disease 2 HC7: Clinical relevance of genetic repair mechanisms
HC7: Clinical relevance of genetic repair mechanisms
Introduction
BRCA and Lynch syndrome occur very frequently in the population. Both syndromes are caused by DNA repair genes.
Even though germline mutations are equally distributed through the genome, hereditary cancer cases associate with syndromes caused by mutations in DNA repair genes. On the other hand, cancers related to inherited APC-mutations are also relatively frequent.
Damage and clinical prognosis
There is an association between DNA repair defects and clinical prognosis. Lung cancers have much more mutations than breast cancers. However, if there are more mutations, a tumor doesn’t necessarily have a worse prognosis. There are several reasons for this:
- There can be too much DNA damage in cancer cells → essential cancer genes are hit → the cell dies due to excessive damage
- Point-mutations are not the only alterations that occur in a cancer cell → tumors with very few mutations may have very abundant chromosomal mutations
Colorectal cancer genetics and prognosis:
Colorectal cancer can develop in several different ways:
- A minority develops under very specific defects in the DNA repair machine
- A small proportion (less than 5%) develops under deficiencies in the proofreading domain of polymerase chains → accumulate to a lot of mutations in their coding gene
- 15-20% develops under the context of mismatch repair deficiency
- A large majority has a low number of mutations in their genome but a large chromosomal instability
Even though MMR-deficient (mismatch repair deficient) or POLE-mutated (polymerase mutated) tumors have more mutations than MMR-proficient tumors, they have a better prognosis up to stage 3. In stage 4, the prognosis is equally bad for all tumors. This means that more mutations actually result in a better prognosis. This can be explained by:
- There being too much damage → affects the tumor cells
- Chromosomal instability leading to a worse prognosis than mutations
MMR-deficient and POLE-mutated tumors have a lot of lymphatic infiltrates in their tumors.
Endometrial cancer and prognosis:
In endometrial cancer, MMR-deficient and POLE-mutated tumors are also present. Here, POLE-mutated patients do better than patients who are MSS (microsatellite stable) or MSI (microsatellite instable). MSI-patients are MMR-deficient and MSS-patients are MMR-proficient. POLE-mutated and MSI patients have more lymphocyte infiltrates, which mainly consist of CD8 T-cells, than MSS-patients.
BRCA status and breast cancer prognosis:
Approximately 10% of all breast cancers carry defects in the BRCA genes, of which half are due to germline mutations. There has been a long debate about whether there is a relation between prognosis in breast cancer and the status of BRCA mutations. Recently, a big study has shown that there is no difference between BRCA-positive and BRCA-negative patients.
Arguments supporting an association between BRCA1 mutations and worse prognosis are:
- 70-90% of BRCA1 related tumors are triple-negative
- Don’t express estrogen-receptors or HER2-receptors
Arguments against an association between BRCA1 mutations and a worse prognosis are:
- BRCA-related cancers are detected at earlier stages
- If looking at triple-negative tumors, BRCA mutations are associated with a slightly better prognosis
- More mutations
- More inflamed profile → the immune system may be involved
In conclusion, more studies need to be conducted to confirm the relation between BRCA1 mutations and a worse or better prognosis.
Targeting homologous recombination defects in breast cancer
BRCA deficiency represents the failure of the homologous recombination DNA repair system in cells, but also in other responses to DNA damage. BRCA1 can be seen as a general DNA response protein.
Cisplatin:
Cisplatin is a chemotherapeutic which can be used for breast cancer treatment. It is both used in neoadjuvant and adjuvant situations:
- Neoadjuvant therapies are delivered before the primary treatment
- Adjuvant therapies after the primary treatment
Lab experiments show that loss of BRCA1 function increases the antitumor response of cisplatin against human breast cancer xenografts in vivo. When cisplatin is used in triple-negative breast cancers, the prognosis for patients with BRCA-mutations is slightly better than for patients without a BRCA mutation.
BRCA2-mutated ovarian cancer patients specifically benefit from platinum-based chemotherapies. However, there still isn’t a clear-cut association between the response of BRCA-patients to cisplatin.
There is a trend towards a relation between BRCA status and clinical responses, but this is non-significant. This can be explained by the fact that cisplatin mostly targets the resolution of intra-strand crosslinks, and not really the formation of double strand products.
Synthetic lethality:
If part of a system in a cell is down, another system can compensate for it → if homologous recombination is down it can be compensated. However, if both complementary and compensative systems to BRCA are taken down, the tumor cells are left without alternative.
The occurrence of single strand breaks of DNA can intervene with homologous recombination:
- As single strand breaks occur, they are recognized by a DNA damaged response protein → PARP-1
- PARP-1 recruits a BER
- BER: base excision repair machine
- BER repairs the single strand break
If the action of PARP-1 is inhibited, the replication fork may collapse when the DNA strand is being replicated. This requires homologous recombination to operate, otherwise the cell dies.
If BER can be inhibited in cells that are already homologous recombination deficient, the tumor cells are left without any alternative to repair these type of mistakes. Olaparib is a drug which specifically targets PARP-1 which stops BER of single strand breaks. This is useful to treat tumors which lack homologous recombination. This concept is called synthetic lethality.
Synthetic lethality arises when there is a combination of deficiencies in 2 or more genes which leads to cell death, while deficiency in 1 gene allows the cell to survive. PARP inhibition such as olaparib can be used in BRCA-mutant breast and ovarian cancer. However, tumors do develop resistances to these type of therapeutic approaches.
Testing for homologous recombination defects
To apply therapy targeting HR-defects, there needs to be a way to distinguish these cancers. Moreover, homologous deficiencies can also arise due to deficiencies in other components of the homologous recombination process. Different methodologies have been applied to assess whether cancer cells are homologous recombination deficient or not, without having to sequence actual genes.
BRCA1 or BRCA2 defects and mutational signatures:
BRCA1 or BRCA2 deficient cancers have specific mutational signatures which indicate the deficiency:
- Large chromosomal alterations
- Genomic scars that suggest that HR is not working properly
By reading these type of signatures, HR deficient tumors can be identified → are susceptible to PARP-1 treatment. HRDetect is superior to screening for the detection of HR-deficient cancers.
RAD51 foci for assaying HR-deficiency:
One of the final steps of homologous recombination includes the accumulation of RAD51 proteins → causes the DNA to break. If an antibody against RAD51 with immunofluorescence is used, dots become visible → demonstrates that RAD51 is accumulating in the nucleus and is binding naked chains of DNA.
Researches are trying to expose vivo patient material to ionizing radiation, making it possible for them to determine if RAD51 foci are formed:
- If RAD51 foci are visible, homologous recombination is functional
- If RAD51 foci aren’t present, homologous recombination isn’t working properly
- These patients can receive drugs like olaparib
Mismatch repair deficiency and 5-FU chemotherapy:
Some tumors, such as Lynch syndrome related cancers, are mismatch repair deficient (MMR-deficient). 5-FU is a common chemotherapy used for colorectal cancer. It is a nucleoside analog which interferes in the metabolism of nucleotides that compose the DNA and RNA molecules. While it is metabolized, it binds enzymes that are involved in the normal processing of nucleotides → inhibits nucleotide metabolism and integrates itself in DNA and RNA molecules, disturbing their structure.
MMR-deficient tumors do not respond to 5-FU treatment. It is unknown what causes this, but a proposition is:
- Cells can activate apoptosis by recognizing that something strange has been incorporated in their DNA → can be recognized through the activity of the MMR-system → apoptosis
- If the MMR-system isn’t active, apoptosis pathways aren’t activated → MMR-deficient tumors can survive with 5-FU incorporated in their DNA
Join with a free account for more service, or become a member for full access to exclusives and extra support of WorldSupporter >>
Mechanisms of Disease 2 2020/2021 UL
- Mechanisms of Disease 2 HC2: Cancer genetics
- Mechanisms of Disease 2 HC3: Cancer biology
- Mechanisms of disease 2 HC4: Cancer etiology
- Mechanisms of disease 2 HC5: Hereditary aspects of cancer
- Mechanisms of Disease 2 HC6: Cancer and genome integrity
- Mechanisms of Disease 2 HC7: Clinical relevance of genetic repair mechanisms
- Mechanisms of Disease 2 HC8: General principles: diagnostic pathology
- Mechanisms of Disease 2 HC9: Nomenclature and grading of cancer
- Mechanisms of Disease 2 HC10: General principles: metastasis
- Mechanisms of Disease 2 HC11: General principles: molecular diagnostics
- Mechanisms of Disease 2 HC12: How did cancer become the emperor of all maladies?
- Mechanisms of Disease 2 HC13: Heterogeneity in cancer
- Mechanisms of Disease 2 HC14: Cancer immunity and immunotherapy
- Mechanisms of Disease 2 HC15: Framework oncology and staging
- Mechanisms of Disease 2 HC16+17: Pharmacology I&II
- Mechanisms of Disease 2 HC18: Biomarkers for early detection of cancer
- Mechanisms of Disease 2 HC19: Surgical oncology
- Mechanisms of Disease 2 HC20: Radiation oncology
- Mechanisms of Disease 2 HC21: Medical oncology
- Mechanisms of Disease 2 HC22: Chemoradiation
- Mechanisms of Disease 2 HC23: Normal hematopoiesis
- Mechanisms of Disease 2 HC24: Diagnostics in hematology
- Mechanisms of Disease 2 HC25: Myeloid malignancies
- Mechanisms of Disease 2 HC26: Malignant lymphomas
- Mechanisms of Disease 2 HC27+28: Allogenic stem cell transplantation and donor lymphocyte infusion I&II
- Mechanisms of Disease 2 HC29: HLA & minor histocompatibility antigens
- Mechanisms of Disease 2 HC30: Changes in patients’ experiences
- Mechanisms of Disease 2 HC31: Targeted therapy and hematological malignancies
- Mechanisms of Disease 2 HC32+33: Primary hemostasis
- Mechanisms of Disease 2 HC34+35: Secondary hemostasis I&II
- Mechanism of Disease 2 HC36: Fibrinolysis and atherothrombosis
- Mechanisms of Disease 2 HC37: Cancer, coagulation and thrombosis
- Mechanisms of Disease 2 HC38: Bleeding disorders
- Mechanisms of Disease 2 HC39: Thrombosis
Contributions: posts
Spotlight: topics
Mechanisms of Disease 2 2020/2021 UL
Deze bundel bevat uitwerkingen van alle hoorcolleges, patientdemonstraties en eventuele (proef)tentamens van het blok Mechanisms of Disease 2 van de studie Geneeskunde aan de universiteit Leiden.
- Lees verder over Mechanisms of Disease 2 2020/2021 UL
- 1641 keer gelezen
Online access to all summaries, study notes en practice exams
- Check out: Register with JoHo WorldSupporter: starting page (EN)
- Check out: Aanmelden bij JoHo WorldSupporter - startpagina (NL)
How and why use WorldSupporter.org for your summaries and study assistance?
- For free use of many of the summaries and study aids provided or collected by your fellow students.
- For free use of many of the lecture and study group notes, exam questions and practice questions.
- For use of all exclusive summaries and study assistance for those who are member with JoHo WorldSupporter with online access
- For compiling your own materials and contributions with relevant study help
- For sharing and finding relevant and interesting summaries, documents, notes, blogs, tips, videos, discussions, activities, recipes, side jobs and more.
Using and finding summaries, notes and practice exams on JoHo WorldSupporter
There are several ways to navigate the large amount of summaries, study notes en practice exams on JoHo WorldSupporter.
- Use the summaries home pages for your study or field of study
- Use the check and search pages for summaries and study aids by field of study, subject or faculty
- Use and follow your (study) organization
- by using your own student organization as a starting point, and continuing to follow it, easily discover which study materials are relevant to you
- this option is only available through partner organizations
- Check or follow authors or other WorldSupporters
- Use the menu above each page to go to the main theme pages for summaries
- Theme pages can be found for international studies as well as Dutch studies
Do you want to share your summaries with JoHo WorldSupporter and its visitors?
- Check out: Why and how to add a WorldSupporter contributions
- JoHo members: JoHo WorldSupporter members can share content directly and have access to all content: Join JoHo and become a JoHo member
- Non-members: When you are not a member you do not have full access, but if you want to share your own content with others you can fill out the contact form
Quicklinks to fields of study for summaries and study assistance
Main summaries home pages:
- Business organization and economics - Communication and marketing -International relations and international organizations - IT, logistics and technology - Law and administration - Leisure, sports and tourism - Medicine and healthcare - Pedagogy and educational science - Psychology and behavioral sciences - Society, culture and arts - Statistics and research
- Summaries: the best textbooks summarized per field of study
- Summaries: the best scientific articles summarized per field of study
- Summaries: the best definitions, descriptions and lists of terms per field of study
- Exams: home page for exams, exam tips and study tips
Main study fields:
Business organization and economics, Communication & Marketing, Education & Pedagogic Sciences, International Relations and Politics, IT and Technology, Law & Administration, Medicine & Health Care, Nature & Environmental Sciences, Psychology and behavioral sciences, Science and academic Research, Society & Culture, Tourisme & Sports
Main study fields NL:
- Studies: Bedrijfskunde en economie, communicatie en marketing, geneeskunde en gezondheidszorg, internationale studies en betrekkingen, IT, Logistiek en technologie, maatschappij, cultuur en sociale studies, pedagogiek en onderwijskunde, rechten en bestuurskunde, statistiek, onderzoeksmethoden en SPSS
- Studie instellingen: Maatschappij: ISW in Utrecht - Pedagogiek: Groningen, Leiden , Utrecht - Psychologie: Amsterdam, Leiden, Nijmegen, Twente, Utrecht - Recht: Arresten en jurisprudentie, Groningen, Leiden
JoHo can really use your help! Check out the various student jobs here that match your studies, improve your competencies, strengthen your CV and contribute to a more tolerant world
1574 |
Add new contribution