Yeast Nuclear Envelope Subdomains with Distinct Abilities to Resist Membrane Expansion

Little is known about what dictates the round shape of the yeast Saccharomyces cerevisiae nucleus. In spo7Δ mutants, the nucleus is misshapen, exhibiting a single protrusion. The Spo7 protein is part of a phosphatase complex that represses phospholipid biosynthesis. Here, we report that the nuclear protrusion of spo7Δ mutants colocalizes with the nucleolus, whereas the nuclear compartment containing the bulk of the DNA is unaffected. Using strains in which the nucleolus is not intimately associated with the nuclear envelope, we show that the single nuclear protrusion of spo7Δ mutants is not a result of nucleolar expansion, but rather a property of the nuclear membrane. We found that in spo7Δ mutants the peripheral endoplasmic reticulum (ER) membrane was also expanded. Because the nuclear membrane and the ER are contiguous, this finding indicates that in spo7Δ mutants all ER membranes, with the exception of the membrane surrounding the bulk of the DNA, undergo expansion. Our results suggest that the nuclear envelope has distinct domains that differ in their ability to resist membrane expansion in response to increased phospholipid biosynthesis. We further propose that in budding yeast there is a mechanism, or structure, that restricts nuclear membrane expansion around the bulk of the DNA.

Herpestype Virus and Type C Particles in Spontaneous Equine Lymphoma

Herpestype and type C virus particles are known to produce tumors in animals of certain species, and to be present in a variety of human tissues. Similar particles were found in a horse lymphoma.Electron microscope study was carried out on a tumorous prescapular lymph node from an adult female horse with spontaneous lymphoma. Lymph node cells grown in vitro for a total of 105 days (6th passage) were also studied. The lymph node was infiltrated by blastic cells of reticulum cell type and of lymphoblast type. No virus particles were found in the original lymph node. The cultured cells have a large cytoplasm with well developed rough endoplasmic reticulum and Golgi's apparatus, and an indented nucleus with marginated chromatin. Occasionally, intranuclear fibrous structures were observed. Elongated nuclear protrusion were frequently seen.

Ultrastructual studies on spematids and sertoli cells during early spermogenesis in the bandicoot Peramelea nasuta geoffroy (Marsupialia)

The present paper deals with spermiogenesis up to and including the attachment of spermatids to Sertoli cells. The first observed step in spermatid differentiation was the development of the anlage of the middle piece and principal piece. This anlage, called the axial filament complex, has the structure of a cilium and arises from the future longitudinal centriole, while the latter, together with the future transverse centriole, lies in the vicinity of the Golgi complex. The definitive acrosomal vacuole, which ultimately becomes attached to and invaginates the nuclear envelope, is formed by the enlargement and coalescence of Golgi vacuoles. While this definitive vacuole is developing, the centrioles and attached axial filament complex migrate to the opposite pole of the nucleus. Before and during migration a number of accessory structures are developed in association with the centrioles, and one of these structures, the proximal junctional body, invaginates the nuclear envelope when the centrioles reach their definitive abacrosomal position. During this period, a cytoplasmic canal forms around the intraspermatid part of the axial filament complex. The definitive acrosomal vacuole ultimately extends out to make close contact with the plasma membrane of the spermatid. This stage of development is followed by a process of nuclear protrusion, initiated by the migration of the nucleus towards the region of contact between acrosomal vacuole and spermatid plasma membrane. During the migratory phase, that part of the nuclear envelope previously invaginated by the acrosomal vacuole becomes everted and the latter collapses, finally becoming sandwiched in between the nucleus and the plasma membrane of the spermatid. The nucleus subsequently projects from the surface of the spermatid, its acrosome-covered apex becoming coneshaped. During these phases of development the accessory structures elaborated in association with the centrioles, and which now lie in the neck region of the spermatid, have become more highly organized. The manchette begins to develop in spermatids at the stage at which the acrosome has become sandwiched in between the nucleus and the plasma membrane of the spermatid. Concurrently the spermatids become surrounded on all sides by Sertoli cell cytoplasm. In the later stages of nuclear protrusion, the manchette elongates and its walls become thicker. The protruding nuclei become orientated with their acrosome-covered apices facing towards the basement membrane of the tubules. Aggregations of finely granular material appear in Sertoli cell cytoplasm in the region of contact with the acrosomal vacuole. The possible role of the manchette and of Sertoli cell cytoplasm in the phenomenon of nuclear protrusion and orientation is discussed.