A change of developmental program induces the remodeling of the interchromatin domain during microspore embryogenesis in Brassica napus L.

After a stress treatment, in vitro-cultured pollen changes its normal gametophytic developmental pathway towards embryogenesis producing multicellular embryos from which, finally, haploid and double haploid plants develop. The architecture of the well-organized nuclear functional domains changes in response to DNA replication, RNA transcription, processing and transport dynamics. A number of subnuclear structures present in the interchromatin region (IR, the nuclear domain between chromosome territories) have been shown as involved, either directly or indirectly, in transcriptional regulation. These structures include the interchromatin granule clusters (IGCs), perichromatin fibrils (PFs), Cajal bodies (CBs) and perichromatin granules (PGs). In this work, we present a cytochemical, immunocytochemical, quantitative and morphometric analysis at the light, confocal and electron microscopy levels to characterize the changes in the functional architecture of the nuclear interchromatin domain during two developmental programs followed by the microspore: differentiation to mature pollen grains (transcriptionally inactive), and microspore embryogenesis involving proliferation in the first stages (highly engaged in transcription). Our results revealed characteristic changes in size, shape and distribution of the different interchromatin structures as a consequence of the reprogramming of the microspore, allowing us to relate the remodeling of the interchromatin domain to the variations in transcriptional activities during proliferation and differentiation events, and suggesting that RNA-associated structures could be a regulatory mechanism in the process. In addition, we document the presence of two structurally different types of CBs, and of IGC and CB-associated regions, similar to those present in animal cells, and not yet described in plants.

Defined nuclear changes accompany the reprogramming of the microspore to embryogenesis.

The switch of the gametophytic developmental program toward pollen embryogenesis to form a haploid plant represents an important alternative for plant breeding. In the present study, the switch of the gametophytic developmental program toward a sporophytic pathway, "embryogenesis," has been studied in three different plant species, Brassica, tobacco, and pepper. The switch has been induced by stress (heat shock) at the very responsive stage of the microspore, which is the vacuolate period. As a result, the cell nucleus undergoes striking structural changes with regard to late gametophytic development, including alterations of biosynthetic activities and proliferative activity. An enrichment in HSP70 heat-shock protein and in the presence of Ntf6-MAP kinase was observed after inductive treatment in the nuclei during early embryogenesis. This apparently reflected the possible roles of these proteins, specifically the protective role of HSP70 for the nuclear machinery, and signal transduction of Ntf6-MAPK for the entry of cells into proliferation. Importantly, the observed nuclear changes were similar in the three species investigated and represented convenient markers for early monitoring of embryogenesis and selection purposes for obtaining double-haploid plants in plant breeding.

Histones and DNA ultrastructural distribution in plant cell nucleus: a combination of immunogold and cytochemical methods.

In this work we report for the first time the ultrastructural distribution of histones and DNA in the nuclear compartments in two different plant cell types: Allium cepa L. root meristems and Capsicum annuum L. microspores and pollen grains, by using antibodies against histones H2B and H4 and anti-DNA. Immunolocalizations were combined with ultrastructural cytochemistry for nucleic acids (methylation-acetylation method), DNA (NAMA-Ur) and RNPs (EDTA), to relate the subcellular location of histones and DNA with the chemical subcompartmentalization of the cell nucleus. This is particularly interesting concerning the presence of histones or not on fibers of the interchromatin region and on the fibrillar components of the nucleolus, nuclear subcompartments where transcription has been shown to take place at some regions. Our methodological approach permitted to define precisely the structures where histones were detected in relation to the ultrastructural localization of chromatin in various structural condensation levels. Concerning the localization of DNA and histones on the different components of the nucleolus, the combination of immunogold labeling with the methylation-acetylation cytochemical method, developed in our laboratory, was very useful, thus permitting a clear recognition of the nucleolar components and a correct assignment of labeling, which is not always evident on uranyl-lead-stained Lowicryl sections. Double immunogold assays were also done for a simultaneous visualization of histones and DNA. Our results show a coincident distribution of histones and DNA on the same nuclear compartments revealing the presence of both antigens on condensed chromatin, fibers of the interchromatin region, principally located at the periphery of the condensed chromatin, and in the fibrillar components of the nucleolus.