Genomic Instability and Cancer Laboratory / Travis Stracker: Genomic Instability and Cancer Laboratory / Oncology / IRB Barcelona

Genomic Instability and Cancer Laboratory

Travis Stracker

Group Leader
Office Tel : +34 93 40 31183
Lab Tel : +34 93 403 11 97
e-mail : travis.strackerirbbarcelona.org

Background

The recognition of many types of DNA lesions activates the cellular DNA damage response (DDR). The DDR orchestrates the appropriate cellular programs to maintain genome integrity after genotoxic stress. Indices of an activated DDR are evident in many pre-cancerous and cancerous lesions and it has been proposed to act as an inducible barrier to malignancy. This proposition is supported by both animal models and human genetic instability disorders that are caused by mutations in proteins that control the DDR. Understanding the signal transduction networks governed by the DDR, and the consequences of their impairment, will facilitate our understanding of tumor development and enhance cancer treatment methods.

Research Interests

Studies in our lab will focus on the role of the DDR in tumor suppression. Rare human diseases, including Ataxia-telangiectasia and Nijmegen Breakage Syndrome, lead to developmental disorders and tumor predisposition due to mutations in genes involved in the DDR. Using patient samples and murine models of the human diseases, we will analyze the molecular signaling that controls various components of the DDR and determine their role in tumor suppression.

Research Lines

1.The role of the Mre11 complex in tumor suppression.
Genetic studies in mice suggest that the G2/M checkpoint, which prevents cells with DNA damage from entering mitosis, is important for maintaining genome stability and suppressing cancer. We will further analyze the role of the Mre11 complex (Mre11, Rad50, Nbs1) in this checkpoint response, identify the cellular requirements to initiate and maintain the checkpoint, and determine its role in preventing malignancy.

2. The regulation of apoptosis by the Chk2 kinase.
The checkpoint kinase Chk2 plays a key role in triggering apoptosis in response to ionizing radiation and mice lacking Chk2 are resistant to radiation toxicity. We have observed that loss of Chk2 in mice with hypomorphic Mre11 complex mutations leads to a broad spectrum of tumors. To understand the role of Chk2 in tumor suppression we are analyzing its regulation by other members of the DDR and taking numerous approaches to identify relevant targets of its kinase activity.

Figure legend: A. Nbs1, a component of the Mre11 complex, localizes to the nucleus (top panel) and accumulates in foci at sites of damage following ionizing radiation (IR) treatment (bottom panel). B. Radiation induced chromosomal instability in mouse (top) or human (bottom) cells with mutations in the Mre11 complex. Chromatid breaks are indicated by red arrows. C. Tumors from mice with mutations in the Mre11 complex and Chk2. H&E stained sections of a high grade angiosarcoma (left) and a high grade osteogenic sarcoma (right) at 400X. Images courtesy of Sam Singer.

3. The influence of the damage response on chromatin composition.
The modulation of chromatin composition and the remodeling of DNA ends by the Mre11 complex and other DDR proteins is important for DNA repair as well as initiating the appropriate cellular responses. We will elucidate the signaling pathways that connect recognition of DNA lesions with essential changes in chromatin composition.

More info

Stracker Group Scientific Report 2009

Genomic Instability and Cancer Laboratory

The MRE11 complex: starting from the ends
Stracker TH, Petrini JH.
Nat Rev Mol Cell Biol., 12 (2), 90-103 (2011)

Taking the time to make important decisions: the checkpoint effector kinases Chk1 and Chk2 and the DNA damage response
Stracker TH, Usui T and Petrini JHJ
DNA Repair (Epub ahead of print) (2009)

Differential DNA damage signaling accounts for different neuropathology associated with ATLD and NBS
Shull ERP, Lee Y, Nakane H, Stracker TH, Zhao J, Russell HR, Petrini JHJ and McKinnon PJ
Genes Dev, 23 (2) (2009)

Artemis and NHEJ-independent influence of DNA-PKcs on chromosome stability
Stracker TH, Williams BR, Deriano L, Theunissen JW, Adelman CA, Roth DB and Petrini JHJ
Mol Cell Biol, 29 (2), 503-514 (2009)

Roles for NBS1 in alternative nonhomologous end-joining of V(D)J recombination intermediates
Deriano L, Stracker TH, Baker A, Petrini JHJ and Roth DB
Mol Cell, 34 (1), 13-25 (2009)

Working together and apart: the twisted relationship of the Mre11 complex and Chk2 in apoptosis and tumor suppression
Stracker TH and Petrini JHJ
Cell Cycle, 7 (23), 3618-3621 (2008)

CHK2 suppresses the oncogenic potential of DNA replication-associated DNA damage
Stracker TH, Couto SS, Cordon-Cardo C, Matos T and Petrini JHJ
Mol Cell, 31, 21-32 (2008)

The carboxy terminus of NBS1 is required for induction of apoptosis by the MRE11 complex
Stracker TH, Hussein H, Morales M, Couto SS, Hussein H and Petrini JHJ
Nature, 447 (7141), 218-221 (2007)

The Adenovirus E4orf3 protein targets the Mre11 complex to cytoplasmic aggresomes
Araujo F, Stracker TH, Carson CT, Lee D and Weitzman MD
J Virology, 79 (17), 11382-11391 (2005)

Serotype-specific reorganization of the Mre11 complex by adenoviral E4orf3 proteins
Stracker TH, Lee D, Carson CT, Araujo F and Weitzman MD
J Virology, 79 (11), 6664-6673 (2005)

The Rep protein of adeno-associated virus interacts with single-stranded DNA binding proteins that enhance viral replication
Stracker TH, Cassell G, Ward P, Loo M, van Breukelen B, Hamatake R, van der Vliet P, Weller S, Melendey T and Weitzman MD
J Virology, 78 (1), 441-453 (2004)

Structural and functional analysis of Mre11-3
Arthur LM, Gustausson K, Hopfner KP, Carson CT, Stracker TH, Karcher A, Felton D, Weitzman MD, Tainer J and Carney JP
Nucleic Acids Res, 32 (6), 1886-1893 (2004)

The Mre11 complex is required for ATM activation and the G2/M checkpoint in mammalian cells
Carson CT, Schwartz R, Stracker TH, Lilley CE, Lee D and Weitzman MD
EMBO J, 22 (24), 6610-6620 (2003)

Roles of host cell factors in the circularization of retroviral DNA
Kilzer JM, Stracker TH, Beitzel B, Meek K, Weitzman MD and Bushman FD
Virology, 314 (1), 460-467 (2003)

Adenovirus oncoproteins inactivate the Mre11-Rad50-NBS1 DNA repair complex
Stracker TH, Carson CT and Weitzman MD
Nature, 418 (6895), 348-352 (2002)

Characterization of the AeaHP gene and its expression in the mosquito Aedes aegypti (Diptera:Culicidae)
Stracker TH, Thompson S, Grossman GL, Riehle M, Brown MR
J Med Entomol, 39 (2), 331-342 (2002)

A genetic screen identifies a cellular regulator of adeno-associated virus
Cathomen T, Stracker TH, Gilbert LB and Weitzman MD
Proc Nat Acad Sci USA, 98, 14991-14996 (2001)

Identification of a steroidogenic neurohormone in female mosquitoes
Brown MR, Graf R, Swiderek KM, Fendley D, Stracker TH, Champagne DE and Lea AO
J Biol Chem, 273 (7), 3967-3971 (1998)