Absence of SUN-domain protein Slp1 blocks karyogamy and switches meiotic recombination and synapsis from homologs to sister chromatids.

Citation:

Vasnier C, De Muyt A, Zhang L, Tessé S, Kleckner NE, Zickler D, Espagne E. Absence of SUN-domain protein Slp1 blocks karyogamy and switches meiotic recombination and synapsis from homologs to sister chromatids. Proc Natl Acad Sci U S A. 2014;111 (38) :E4015-23.

Date Published:

2014 Sep 23

Abstract:

Karyogamy, the process of nuclear fusion is required for two haploid gamete nuclei to form a zygote. Also, in haplobiontic organisms, karyogamy is required to produce the diploid nucleus/cell that then enters meiosis. We identify sun like protein 1 (Slp1), member of the mid-Sad1p, UNC-84-domain ubiquitous family, as essential for karyogamy in the filamentous fungus Sordaria macrospora, thus uncovering a new function for this protein family. Slp1 is required at the last step, nuclear fusion, not for earlier events including nuclear movements, recognition, and juxtaposition. Correspondingly, like other family members, Slp1 localizes to the endoplasmic reticulum and also to its extensions comprising the nuclear envelope. Remarkably, despite the absence of nuclear fusion in the slp1 null mutant, meiosis proceeds efficiently in the two haploid "twin" nuclei, by the same program and timing as in diploid nuclei with a single dramatic exception: the normal prophase program of recombination and synapsis between homologous chromosomes, including loading of recombination and synaptonemal complex proteins, occurs instead between sister chromatids. Moreover, the numbers of recombination-initiating double-strand breaks (DSBs) and ensuing recombinational interactions, including foci of the essential crossover factor Homo sapiens enhancer of invasion 10 (Hei10), occur at half the diploid level in each haploid nucleus, implying per-chromosome specification of DSB formation. Further, the distribution of Hei10 foci shows interference like in diploid meiosis. Centromere and spindle dynamics, however, still occur in the diploid mode during the two meiotic divisions. These observations imply that the prophase program senses absence of karyogamy and/or absence of a homolog partner and adjusts the interchromosomal interaction program accordingly.

Key Publications by Subject Area

Chromosomes as Mechanical Objects

• Kleckner, N., Zickler, D., Jones, G.H., Henle, J., Dekker, J. and Hutchinson, J. 2004. A mechanical basis for chromosome function. Proc. Natl. Acad. Sci. USA, 101, 12592-12597.

• Fisher, J.K. and Kleckner, N. 2014. Magnetic Force Micropiston: an integrated force microfluidic device for the application of compressive forces in a confined environment. Rev. Sci. Instrum. 85 023704 (2014)

Mammalian chromosome dynamics

• Liang, Z., Zickler, D., Prentiss, M., Chang, F.S., Witz, G., Maeshima, K. and Kleckner, N. 2015. Chromosomes progress to metaphase in multiple discrete steps via global compaction/expansion cycles. Cell 161: 1124-1137.

E.coli chromosome dynamics

• Fisher, J.K., Bourniquel, A., Witz, G., Weiner, B., Prentiss, M. and Kleckner, N. 2013. Four-dimensional imaging of E. coli organization and dynamics in living cells. Cell 153, 882-895.

• Kleckner, N., Fisher, J.K., Stouf, M., White, M.A., Bates, D. and Witz, G. 2014. The bacterial nucleoid: nature, dynamics and sister segregation. Curr. Opin. Microbiol. 22: 127-137.

Meiotic Crossover Interference

• Zhang, L., Wang, S., Yin, S., Hong, S. Kim, K.P. and Kleckner, N. 2014. Topoisomerase II mediates meiotic crossover interference. Nature 511: 551-556.

• Zhang, L, Espagne, E., De Muyt, A., Zickler, D. and Kleckner, N. 2014. Interference-mediated synaptonemal complex formation with embedded crossover-designation. Proc. Natl. Acad. Sci. U.S.A. 111(47):E5059-68. doi: 10.1073/pnas.1416411111.

• Wang, S., Zickler, D., Kleckner, N. and Zhang, L. 2015. Meiotic crossover patterns: obligatory crossover, interference and homeostasis in a single process. Cell Cycle, 14(3): 305-314.

Homologous Chromosome Pairing

• Zickler, D. and Kleckner, N. 2015. Recombination, pairing and synapsis of homologs in meiosis. In Kowalczykowski, S., Hunter, N. and Heyer, W.-D., DNA Replication (Cold Spring Harbor: Cold Spring Harbor Press) Cold Spring Harb Perspect Biol 2015;7:a016626 doi: 10.1101/CSHPERSPECT.a016626.

• Gladyshev E. and Kleckner, N. 2014. Direct recognition of homology between double helices of DNA in Neurospora crassa. Nat. Commun. 5: 3509 doi: 10.1038/ncomms4509.

• Mirkin, E.V., Chang, F. S. and Kleckner, N. 2013. Dynamic trans interactions in yeast chromosomes. PLoS One 8(9): e75895. doi:10.1371/journal.pone.0075895

• Danilowicz, C., Lee, C.H., Kim K., Hatch, K., Coljee, V.W., Kleckner, N. and Prentiss, M. 2009. Single molecule detection of direct, homologous DNA/DNA pairing. Proc. Natl. Acad. Sci. USA, 106, 19,824-19,829.

• Weiner, B.M. and Kleckner, N. 1994. Chromosome pairing via multiple interstitial interactions before and during meiosis in yeast. Cell 77: 977-991.

• Burgess, S.M., Kleckner, N. and Weiner, B.M. 1999. Somatic pairing of homologs in budding yeast: existence and modulation. Genes Dev. 13, 1627-1641.

• Kleckner, N. and Weiner, B.M. 1993. Potential advantages of unstable interactions for pairing of chromosomes in meiotic, somatic and premeiotic cells. Cold Spring Harbor Symp. Quant. Biol. 58: 553-565.

Meiotic Sordaria Chromosomes

• De Muyt A, Zhang, L., Piolot, T., Kleckner, N., Espagne,, E. and Zickler D. 2014. E3 ligase Hei10: a multi-faceted structure-based signaling molecule with roles within and beyond meiosis. Genes Dev 28: 1111-1123.

• Storlazzi, A., Gargano, S., Ruprich-Robert, G., Falque, M., David, M., Kleckner, N. and Zickler, D. 2010. Recombination proteins mediate meiotic spatial chromosome organization and pairing. Cell 141 94-106.

Nancy Kleckner

Herchel Smith Professor of Molecular Biology

Absence of SUN-domain protein Slp1 blocks karyogamy and switches meiotic recombination and synapsis from homologs to sister chromatids.

Citation:

Date Published:

Abstract:

Key Publications by Subject Area