Lecture Summaries

The history of modern day chemotherapy is strongly intertwined with the chemical warfare agents used in World Wars I and II. As we will learn from the first paper, during the first World War medical examinations of people exposed to mustard gas and subsequent autopsy reports described signs of severely impaired bone marrow function and a loss of white blood cells, suggesting that exposure to mustard gas could inhibit the proliferation of specific cell types.

Interest in this phenomenon was renewed in 1943, when the German air raid in Bari, Italy on the SS John Harvey battleship exposed more than 1000 people—both US service men on the ship and civilians in the surrounding town—to its secret cargo containing mustard gas bombs. Medical examinations and autopsy reports reinforced the observations of impaired bone marrow function and loss of blood cells described in the first paper. This event also emphasized the risks associated with war gases such as mustard gas, and underscored the need to understand their mechanisms of action. By the 1940s, it was recognized that mustard gas and chemically related nitrogen mustards exerted the most severe effects on highly proliferative cells (those undergoing frequent cell division).

Therefore, scientists who were searching for chemicals that could be used to inhibit the growth of cancer hypothesized that diseases such as lymphoma, which is characterized by an inappropriate proliferation of blood cells, could be treated therapeutically with alkylating agents such as mustard gas. The second paper to be discussed presents one of the first clinical studies of the use of alkylating agents as chemotherapeutic drugs to treat patients with lymphomas, leukemias, and Hodgkin's disease.

The mismatch repair (MMR) pathway primarily functions to increase the fidelity of DNA replication by correcting errors (such as mispaired bases and short insertions or deletions) that occur during DNA synthesis and escape proofreading, in which an incorrect base is recognized and excised by the exonuclease activity of the replicative polymerase so the correct base can be re-inserted. In the simplest terms, initiation of mismatch repair requires the recognition and binding of base/base mismatches or 1–2 nt insertions/deletions by MutSα (MSH2/MSH6 heterodimer). MutSα recognition serves to recruit components of the excision machinery, including MutLα (MLH1/PMS2 heterodimer), the processivity factor proliferating cell nuclear antigen, or PCNA, and EXO1 exonuclease which load onto the DNA at a preexisting nick and degrade it past the mispaired region. Repair synthesis of the degraded strand by a high-fidelity polymerase followed by DNA ligation completes the repair. Interestingly, the status of the MMR pathway plays a role in both cancer susceptibility and biological outcomes following chemotherapeutic treatments.

The first paper is an early study that derives a model for mismatch repair in yeast through analyzing the in vitro interactions among purified MSH2, MLH1 and PMS1 and DNA. The second paper explores the relationship between the status of the mismatch repair pathway in cells and sensitivity to the cytotoxic O⁶-methylguanine lesions induced by the prototypical alkylating agent MNNG or the alkylation-based chemotherapeutic agent TMZ. This study begins to explore the highly coordinated effort between the MMR and DNA damage response pathways to stimulate cell cycle checkpoints and repair or programmed cell death in response to alkylation-induced damage.

Base excision repair (BER) is initiated by distinct glycosylases that recognize specific aberrant bases and cleave the glycosidic bond between the damaged base and the DNA backbone leaving an apurinic/apyrimidinic (AP) site. The phosphodiester backbone is then hydrolyzed by AP endonuclease (APE1) to create a single-strand break with 3'OH and 5'deoxyribose-5-phosphate (5'dRP) termini. DNA polymerase β functions to remove the 5'dRP with its lyase domain and reincorporate the missing nucleotide with its polymerase domain. Finally, the nick is resealed by either DNA ligase I or the XrccI/Ligase IIIα complex.

Importantly, if the entire multi-step BER is not completed, an accumulation of mutagenic and/or cytotoxic intermediates can arise which can potentially block transcription and replication or induce stress responses that can lead to apoptosis. Intriguingly, these intermediates might contribute to the onset of disease as well as to cytotoxic side effects of chemotherapeutics that function by inducing damage in both tumor and adjacent tissues.

The first paper uses mouse genetic experiments to address how expression of the Alkyladenine DNA glycosylase (Aag), which recognizes 7-methylguanine and 3-methyladenine lesions among others, can mediate alkylation-induced tissue damage and whole-animal lethality. The second paper utilizes a mutated version of the uracil-DNA glycosylase (UDG) to induce an excessive number of AP sites specifically in the mitochondrial genome to study how the accumulation of BER intermediates can contribute to behavioral defects, premature aging and neurodegenerative diseases similar to Parkinson's and Alzheimer's diseases.

Blueprint Medicines is a bio-pharmaceutical company located in Cambridge. The vision of Blueprint Medicines is, "to improve the lives of patients by transforming subsets of cancer from acute diseases to manageable conditions." We will visit Blueprint Medicines to tour its facilities and introduce students to the research strategies Blueprint Medicines uses in cancer research to systematically develop drugs that will personalize treatment and target specific genetic aberrations that drive the formation and progression of cancer.

While the majority of cancer drugs used in the clinic function by damaging DNA to prevent cell division or induce cell death, mutations in genes involved in DNA repair pathways can cause tumors to become resistant to these particular therapies. We will learn how Blueprint Medicines uses molecular signatures to develop drugs that are selective against cells with specific aberrations that cause cancer and mechanisms of resistance to drugs.

Anyone who has a sunburn knows firsthand about the consequences of exposing skin cells to ultraviolet radiation. Ultraviolet radiation in sunlight induces several types of DNA damage, including pyrimidine dimers and 6–4 photoproducts (light-induced molecular rearrangements of DNA bases). These types of DNA damage involve the formation of chemical bonds between two DNA bases. They constitute major structural disruptions that block both DNA polymerase and RNA polymerase and can induce mutations or cell death; peeling dead skin after a sunburn is the result of massive cell death triggered by exposure to UV light.

Cells are equipped with a DNA repair pathway known as nucleotide excision repair (NER), which deals with this type of DNA damage. Some individuals are born with the disease xeroderma pigmentosum (XP), which is caused by mutations in genes that are critical for efficient NER. XP is a rare disease that afflicts fewer than 1 in 20,000 live births and is characterized by premature aging. Because of the NER defect, people with XP are extremely sensitive to sun exposure, and have a nearly 2000-fold increased risk of skin cancer in sun-exposed skin. In the first paper, we will learn how cell lines derived from XP patients were used to deduce important details of the mechanism of NER. In the second paper, we will learn about single nucleotide polymorphisms (differences in the DNA sequences of people in the general population) in NER genes that predict disease susceptibility and therapeutic outcome.

Stem cells are distinguished by their ability to differentiate into multiple different types of cells. This important biological role for stem cells raises the question: are they subject to any special standards with regard to maintaining the integrity of their genomes? The first paper we will discuss today explores this question in detail from the perspective of researchers who would like to use stem cells for regenerative medicine; DNA repair capacity in four pathways that we have discussed in previous weeks is compared in stem cells and non-stem cells.

A second intriguing question is whether there are particular consequences for human health when a DNA repair defect occurs in stem cells. In the case of the disease Fanconi anemia (FA), a defect in the repair pathway that deals with DNA inter-strand cross-links is associated with an inability to generate blood cells. Although the FA defect is manifest in all cells in affected individuals, the disproportionate effect on blood cells suggests that the repair defect is particularly harmful to hematopoetic stem cells (the progenitor cells that differentiate into blood cells). The second paper explores this topic at the molecular level by mechanistically investigating factors that control the DNA damage response in hematopoietic stem cells.