DNA Polymerase λ Can Elongate on Dna Substrates Mimicking Non-Homologous End Joining and Interact With XRCC4-Ligase IV Complex

Fan, Wei, Wu, Xiaoming

29 October 2004

Non-homologous end joining (NHEJ) is one of two pathways responsible for the repair of double-strand breaks in eukaryotic cells. The mechanism involves the alignment of broken DNA ends with minimal homology, fill in of short gaps by DNA polymerase(s), and ligation by XRCC4-DNA ligase IV complex. The gap-filling polymerase has not yet been positively identified, but recent biochemical studies have implicated DNA polymerase λ (pol λ), a novel DNA polymerase that has been assigned to the pol X family, in this process. Here we demonstrate that purified pol λ can efficiently catalyze gap-filling synthesis on DNA substrates mimicking NHEJ. By designing two truncated forms of pol λ, we also show that the unique proline-rich region in pol λ plays a role in limiting strand displacement synthesis, a feature that may help its participation in in vivo NHEJ. Moreover, pol λ interacts with XRCC4-DNA ligase IV via its N-terminal BRCT domain and the interaction stimulates the DNA synthesis activity of pol λ. Taken together, these data strongly support that pol λ functions in DNA polymerization events during NHEJ.

DNA polymerase λ

double-strand break repair

non-homologous end joining

XRCC4-DNA ligase IV

Molecular basis for the structural role of human DNA ligase IV / Base moléculaire pour le rôle structural de l'ADN humain Ligase IV

De Melo, Abinadabe Jackson

19 September 2016

Les défauts dans la réparation des cassures double-brin de l'ADN (DSBs) peuvent avoir d'importantes conséquences pouvant entrainer une instabilité génomique et conduire à la mort cellulaire ou au développement de cancers. Dans la plupart des cellules mammifères, le mécanisme de Jonction des Extrémités Non Homologues (NHEJ) est le principal mécanisme de réparation des DSBs. L'ADN Ligase IV (LigIV) est une protéine unique dans sa capacité à promouvoir la NHEJ classique. Elle s'associe avec deux autres protéines structuralement similaires, XRCC4 et XLF (ou Cernunnos). LigIV interagit directement avec XRCC4 pour former un complexe stable, tandis que l'interaction entre XLF et ce complexe est médiée par XRCC4. XLF stimule fortement l'activité de ligation du complexe LigIV/XRCC4 par un mécanisme encore indéterminé. Récemment, un rôle structurel non catalytique a été attribué à LigIV (Cottarel et al., 2013). Dans le travail de thèse présenté ici, nous avons reconstitué l'étape de ligation de la NHEJ en utilisant des protéines recombinantes produites dans des bactéries afin d’une part, d'explorer les bases moléculaires du rôle structural de LigIV, d’autre part de comprendre le mécanisme par lequel XLF stimule le complexe de ligation, et enfin de mieux comprendre comment ces trois protéines coopèrent au cours de la NHEJ. Nos analyses biochimiques suggèrent que XLF via son interaction avec XRCC4 lié à LigIV, pourrait induire un changement conformationnel dans la LigIV. Ce réarrangement de la ligase exposerait son interface de liaison à l'ADN ce qui lui permettrait alors de ponter deux molécules indépendantes d'ADN, une capacité indépendante de l'activité catalytique de LigIV. / Failure to repair DNA double-strand breaks (DSBs) may have deleterious consequences inducing genomic instability and even cell death. In most mammalian cells, Non-Homologous End Joining (NHEJ) is a prominent DSB repair pathway. DNA ligase IV (LigIV) is unique in its ability to promote classical NHEJ. It associates with two structurally related proteins called XRCC4 and XLF (aka Cernunnos). LigIV directly interacts with XRCC4 forming a stable complex while the XLF interaction with this complex is mediated by XRCC4. XLF strongly stimulates the ligation activity of the LigIV/XRCC4 complex by an unknown mechanism. Recently, a structural noncatalytic role of LigIV has been uncovered (Cottarel et al., 2013). Here, we have reconstituted the end joining ligation step using recombinant proteins produced in bacteria to explore not only the molecular basis for the structural role of LigIV, but also to understand the mechanism by which XLF stimulates the ligation complex, and how these three proteins work together during NHEJ. Our biochemical analysis suggests that XLF, through interactions with LigIV/XRCC4 complex, could induce a conformational change in LigIV. Rearrangement of the LigIV would expose its DNA binding interface that is able to bridge two independent DNA molecules. This bridging ability is fully independent of LigIV’s catalytic activity. We have mutated this interface in order to attempt to disrupt the newly identified DNA bridging ability. In vitro analysis of this LigIV mutant will be presented as well as a preliminary in vivo analysis.

Cassures double-Brin de l'ADN (DSBs)

DNA Ligase IV

Xrcc4

Xlf

DNA double-Strand breaks (DSBs)

Non-Homologous End Joining (NHEJ)

DNA Ligase IV

Xrcc4

Xlf

570

Mismatch ligation during non-homologous end joining pathway: kinetic characterization of human DNA ligase IV/XRCC4 complex

Wang, Yu

10 July 2007

No description available.

Chemistry, Biochemistry

double strand break repair

non-homologous end joining

mismatch ligation

DNA ligase IV/XRCC4 complex

DNA ligase I