Riassunti dei progetti del corso di dottorato di ricerca in biologia molecolare e cellulare

Project leader: MARTIN KATER (martin.kater@unimi.it)

Location: Department of Biosciences, University of Milan, Italy

RESEARCH PROJECT SUMMARY

The proposed PhD research project will be integrated in a research line that focuses on the molecular control of ovule and seed development. Recently, the Kater group identified OsMADS13 as a key regulator of ovule and seed development (Dreni et al., 2007). The PhD fellow will be involved in the identification of the regulatory pathways that are controlled by OsMADS13. This research has an unique starting point since a subset of candidate genes were already identified very recently by using a RNA-seq transcriptome analysis approach. For this analysis we used laser microdissected ovule primordia of wild-type and osmads13 mutant plants. Furthermore, we also profiled genome-wide expression of developing seeds in the osmads13 mutant and higher order mutants of genes (OsMADS3, OsMADS58 and OsMADS21) that act redundantly with OsMADS13 during seed development. The research program will focus on the identification of direct targets and their functional characterization. This research should finally provide deep insight into the molecular mechanisms that control the formation of seeds in monocot species.

Dreni, L., Jacchia, S., Fornara, F., Fornari, M., Ouwerkerk, P., An, G., Colombo, L., Kater, M.M. (2007). The D-lineage MADS-box gene OsMADS13 Controls Ovule Identity in Rice. Plant J. 52, 690-699.

Li, H., Liang, W., Hu, Y., Zhu, L., Yin, C., Xu, J, Dreni, L., Kater, M.M., and Zhang, D. (2011). Rice MADS6 Interacts with the Floral Homeotic Genes SUPERWOMAN1, MADS3, MADS58, MADS13, and DROOPING LEAF in Specifying Floral Organ Identities and Meristem Fate. Plant Cell 23, 2536-2552.

Dreni, L., Pilatone, A., Yun, D., Erreni, S., Pajoro, A., Caporali, E., Zhang, D., and Kater, M.M. (2011). Functional Analysis of all AGAMOUS Subfamily Members in Rice Reveals their Roles in Reproductive Organ Identity Determination and Meristem Determinacy. Plant Cell 23, 2850-2863.

Dreni, L, Osnato, M. and Kater M.M. (2013). The Ins and Outs of the Rice AGAMOUS Subfamily. Mol. Plant 6, 650-664.

Yun, D., Liang, W., Dreni, L., Yin, C., Zhou, Z., Kater, M.M. and Zhang, D. (2013). OsMADS16 genetically interacts with OsMADS3 and OsMADS58 in specifying floral patterning in rice. Mol. Plant (in press)

Project leader: FEDERICO LAZZARO (federico.lazzaro@unimi.it)

Location: Department of Biosciences, University of Milan, Italy

RESEARCH PROJECT SUMMARY

It has been found that replicative DNA polymerases can incorporate rNTPs in place of dNTPs during DNA replication with an unexpected high frequency (~ 1/1000 nt) (McElhinny, Kumar, et al., 2010a; McElhinny, Watts, et al., 2010b). rNMPs embedded in chromosomal DNA represent an imprint, positioned in S-phase, that regulates DNA transactions (Dalgaard, 2012). RNase H enzymes are crucial for the removal of these rNMPs from genomic DNA and for the maintenance of chromosome integrity. Recently we have found that impairment of RNase H1 and RNase H2 in yeast causes rNMPs accumulation in the genome and chronic activation of the post-replication repair (PRR) system which is becoming essential for cell survival (Lazzaro et al., 2012).

The high rate of rNTPs mis-incorporation observed under normal conditions (1/1000 dNTPs) suggests possible physiological functions for the presence of rNMPs in newly replicated DNA. In a collaborative study we recently demonstrated that the presence of rNMPs during leading strand DNA synthesis acts as a strand discrimination signal for the Mismatch DNA repair machinery(Ghodgaonkar et al., 2013).

In this project we will focus our studies on: 1) mapping of specific regions where DNA replicative polymerases could incorporate rNMPs; 2) analysis of the structural effects of the presence of rNMPs within a DNA molecule using AFM studies in collaboration with Dr. Podestà (Dep. of Physics, Univ. Milano). (3) We will study the effects of rNMPs incorporation on chromatin structures and the biological consequences on DNA repair, transcription, silencing.

Cerritelli, S. M., & Crouch, R. J. (2009). Ribonuclease H: the enzymes in eukaryotes. FEBS J, 276(6), 1494–1505. doi:10.1111/j.1742-4658.2009.06908.x

Dalgaard, J. Z. (2012). ScienceDirect.com - Trends in Genetics - Causes and consequences of ribonucleotide incorporation into nuclear DNA. Trends Genet, 1–6. doi:10.1016/j.tig.2012.07.008

Ghodgaonkar, M. M., Lazzaro, F., Olivera-Pimentel, M., Artola-Borán, M., Cejka, P., Reijns, M. A., et al. (2013). Ribonucleotides Misincorporated into DNA Act as Strand-Discrimination Signals in Eukaryotic Mismatch Repair. Molecular Cell, 50(3), 323–332. doi:10.1016/j.molcel.2013.03.019

Lazzaro, F., Novarina, D., Amara, F., Watt, D. L., Stone, J. E., Costanzo, V., et al. (2012). RNase H and postreplication repair protect cells from ribonucleotides incorporated in DNA. Mol Cell, 45(1), 99–110. doi:10.1016/j.molcel.2011.12.019

McElhinny, S. A. N., Kumar, D., Clark, A. B., Watt, D. L., Watts, B. E., Lundstr o m, E.-B., et al. (2010a). Genome instability due to ribonucleotide incorporation into DNA. Nat Chem Biol, 6(10), 774–781. doi:10.1038/nchembio.424

McElhinny, S. A. N., Watts, B. E., Kumar, D., Watt, D. L., Lundstr o m, E.-B., Burgers, P. M. J., et al. (2010b). Abundant ribonucleotide incorporation into DNA by yeast replicative polymerases. Proc Natl Acad Sci U S A, 107(11), 4949–4954. doi:10.1073/pnas.0914857107