|
RESEARCH
INTEREST
One of the most fascinating challenges in genome biology is deciphering
the non-coding genomic landscape, as the majority of the eukaryotic
complexity is thought to be encoded in our regulatory elements.
Studies in our lab focus on the functional relationship between
the regions that regulate DNA replication initiation (ORIs) and
transcription initiation in mammalian cells. We are testing the
hypothesis that ORIs are not randomly located across the chromosomes
but actively positioned to coordinate DNA replication with other
genomic functions, such as active transcription and chromatin
organization. To test this hypothesis we combine genomic analysis
by using microarrays with biochemical and molecular studies at
specific promoter-ORIs using pluripotent, primary and differentiated
mouse cells and human cell lines. Our specific approaches are:
1. Molecular analysis of
DNA replication initiation at ORIs associated with active promoters.
We have recently found that ORI activation is accompanied by the
overproduction of short DNA fragments that have undergone several
rounds of DNA synthesis during a single S-phase. These rereplicated
DNA fragments derive from the nucleosome-free region surrounding
the transcription initiation sites of active promoters associated
with replication origins. These findings suggest a mechanistic
link between the initiation of replication, transcription and
chromatin organization whose interdependence we are currently
investigating.
Analysis
by quantitative real-time PCR of the abundance of four
regions spanning across the ORI associated to the promoter
of the TIMM13 gene during a synchronous progression
through S-phase.
|
2. Genomic distribution of ORIs in the mouse genome. We have
performed an unbiased study of ORI location and efficiency at
large-scale to address ORI specification and maintenance through
cell differentiation. The data identify two types of origins with
distinct regulatory properties: highly efficient origins map at
promoters and low efficient origins locate elsewhere in association
with transcriptional units. We also found a remarkable parallel
organisation of the replication initiation sites and transcription
start sites at efficient promoter-origins that suggest a prominent
role of transcription initiation in setting the efficiency of
replication origin activation. This coordinated organisation of
replication and transcription likely contributes to maintain the
stability of the mammalian genome as it is overall conserved from
pluripotent cells to differentiated cells and cell lines.
| 
Distribution of short replication intermediates detected
by hybridisation of tiled mouse genomic arrays across
the eight promoter regions represented above.
|
|
|
REPRESENTATIVE
PUBLICATIONS
Sequeira-Mendes, J., Diaz-Uriarte, R., Apedaile, A., Huntley,
D., Brockdorff, N., Gómez, M. 2009. Transcription initiation activity
sets replication origin efficiency in mammalian cells.
PLoS Genet. 5: e1000446 Pubmed
Gómez, M. 2008. Controlled rereplication at DNA replication origins.
Cell Cycle 7: 1313-1314. Pubmed
Gómez, M., Antequera, F. 2008. Overeplication of short DNA
regions during S phase in human cells. GenesDev.
22: 375-385. Pubmed
Gómez, M., Brockdorff, N. 2004"Heterochromatin on the
inactive X chromosome delays replication timing without affecting
origin usage". PNAS 101:
6923-6928. PubMed
Goto, Y., Gómez, M., Brockdorff, N., Feil, R. 2002. "Differential
patterns of histone methylation and acetylation distinguish active
and repressed alleles at X-linked genes". Cyt.
Genom. Res. 99:66-74. PubMed
Segurado, M., Gómez, M., Antequera, F. 2002. "Increased
recombination intermediates and homologous recombination hotspots
at DNA replication origins". Mol.
Cell. 10, 907-16. PubMed
Gómez, M., Antequera, F. 1999. "Organization of DNA replication
origins in the fission yeast genome". EMBO
J. 18, 5683-569. PubMed
Delgado, S., Gómez, M., Bird, A., Antequera, F. 1998. "Initiation
of DNA replication at CpG islands in mammalian chromosomes"
EMBO J. 17, 2426-2435. PubMed
FUNDED
PROJECTS
Functional organisation of the
mammalian genome: replication origins, promoters and chromatin
(BFU2007-66827/BMC). 2008-2010. Principal investigator: María
Gómez, PhD
Genomic mapping of mouse DNA replication origins in pluripotent,
primary and tumoral cells using microarrays (SAN196/SA12/07):
2007-2008. Principal investigator: María Gómez, PhD
Especificación, regulación y dinámica de orígenes de replicación
durante el desarrollo (BFU2004-0295). 2005-2008. Principal investigator:
María Gómez, PhD
Regulación epigenética de orígenes de replicación en el genoma
de ratón (CSI03B05). 2005-2007. Principal investigator: María
Gómez, PhD
OPPORTUNITIES
If you are interested in any of our work and would
like to join the group as a graduate student or postdoctoral fellow,
then please write to Dra. MARIA GOMEZ (mgvf@usal.es)
and include a copy of your current C.V. |
