On the fine structure of the perivascular cells in the neural lobe of rats

A framework for understanding the functions of biomolecular condensates across scales

Biomolecular condensates are found throughout eukaryotic cells, including in the nucleus, in the cytoplasm and on membranes. They are also implicated in a wide range of cellular functions, organizing molecules that act in processes ranging from RNA metabolism to signalling to gene regulation. Early work in the field focused on identifying condensates and understanding how their physical properties and regulation arise from molecular constituents. Recent years have brought a focus on understanding condensate functions. Studies have revealed functions that span different length scales: from molecular (modulating the rates of chemical reactions) to mesoscale (organizing large structures within cells) to cellular (facilitating localization of cellular materials and homeostatic responses). In this Roadmap, we discuss representative examples of biochemical and cellular functions of biomolecular condensates from the recent literature and organize these functions into a series of non-exclusive classes across the different length scales. We conclude with a discussion of areas of current interest and challenges in the field, and thoughts about how progress may be made to further our understanding of the widespread roles of condensates in cell biology.

Perivascular cells increase expression of ciliary neurotrophic factor following partial denervation of the rat neurohypophysis

The expression of ciliary neurotrophic factor (CNTF) was investigated immunocytochemically during the axonal degeneration and collateral axonal sprouting response that follows partial denervation of the rat neurohypophysis. A significant increase in the number of CNTF-immunoreactive (CNTF-ir) cells was observed in the neurohypophysis of partially denervated animals compared to age-matched sham-operated controls by 5 days post-denervation, remaining elevated throughout the 30 day post-denervation period. Stereometric assessment of the numbers of CNTF-ir cells within the partially denervated neurohypophysis demonstrated a 36% increase by 3 days following denervation reaching 130% of control values by 10 days post-lesion. The cell numbers remained elevated throughout the 30 day post-lesion period suggesting that CNTF may play a role in the neurosecretory axonal sprouting process known to occur between 10 and 30 days post-denervation. Subsequent preparations pairing anti-CNTF with antibodies against ED1, CR3, p75 low affinity neurotrophin receptor (p75(LNGFR)), and S100beta, demonstrated that CNTF was exclusively localized in a phenotypically-distinct population of perivascular cells. The association of perivascular cells with phagocytic activity was confirmed by dual-label fluorescence microscopy showing the colocalization of P75(LNGFR)-ir and OX-42-ir in cells expressing the ED-1 antigen. No increase in CNTF-ir was observed in non-injured animals in which heightened levels of neurosecretory activity were induced physiologically. These results suggest that increased CNTF-ir occurs in response to conditions which induce high levels of phagocytic activity by perivascular cells in the axotomized neurohypophysis which is sustained throughout a period in which axonal sprouting is known to occur in the partially denervated neurohypophysis.

Immunophenotypic evidence for distinct populations of microglia in the rat hypothalamo-neurohypophysial system

The morphology, distribution and immunophenotype of microglia throughout the adult rat hypothalamo-neurohypophysial system was examined. Four macrophage-associated antibodies (OX-42, F4/80, ED1 and ED2) were used; the expression of major histocompatibility complex antigens was investigated by use of antibodies against OX-6, OX-17 (MHC class II) and OX-18 (MHC class I). Three distinct types of microglia were identified. The first was located in the magnocellular nuclei; these 'radially branched' ('ramified') microglia had round cell bodies and long branched processes, and were strongly immunoreactive only for OX-42. The second was located outside the blood-brain barrier in the median eminence, pituitary stalk and neurohypophysis often close to blood vessels; these 'compact' microglia had irregular cell bodies and shorter processes, and were strongly labelled by OX-42 and F4/80, weakly labelled by OX-18, and generally unlabelled by ED1, ED2, OX-6 and OX-17. The third type was found in small numbers throughout the system at the surface of the nervous tissue or around blood vessels; these 'perivascular' microglia were elongated cells with no branching processes, and were strongly labelled by ED1, ED2, OX-18, OX-6, OX-17 and F4/80 antibodies but showed variable OX-42 immunoreactivity. Cells in a perivascular location were heterogeneous with respect to their immunophenotype. The presence in the normal adult rat hypothalamo-neurohypophysial system of MHC class-II molecules (OX-6 and OX-17) on a sub-set of perivascular microglia suggests that these cells are capable of presenting antigen to T lymphocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

Perivascular microglia in the rat neural lobe engulf magnocellular secretory terminals during osmotic stimulation

The response of microglia in the rat neural lobe to osmotic stimulation has been studied. Microglia were identified by immunoreactivity for the macrophage markers OX-42 and F4/80. The numerical density of microglia did not change significantly with osmotic stimulation but microglia in the perivascular space partially or completely enclosed significantly greater numbers of neurosecretory terminals in osmotically stimulated animals.

Microglia in the rat neurohypophysis increase expression of class I major histocompatibility antigens following central nervous system injury

An immunocytochemical study of the expression of major histocompatibility complex (MHC) class I and II antigens by glial cells of the rat neurohypophysis was performed. Numerous cells with the appearance of microglia were found to constitutively express class I MHC antigens, while only rare cells expressed class II (Ia) antigens. Stereological analysis revealed that expression of class I MHC antigens increased significantly within 10 days after a unilateral hypothalamic lesion known to cause axonal degeneration and compensatory collateral axonal sprouting within the neurohypophysis. In addition, however, a brain lesion which did not affect the axonal population of the neurohypophysis also produced a significant increase in microglial expression of class I MHC antigens in this structure. Neither lesion affected the expression of class II MHC antigens in the neurohypophysis. Simultaneous immunofluorescent labeling for MHC I antigens and glial fibrillary acidic protein (GFAP, a pituicyte marker) or for MHC I and the C3bi complement receptor (a microglial marker) confirmed that the MHC class I-reactive cells were microglia. MHC I-positive cells also bound Griffonia simplicifolia B4 isolectin (GSA I-B4), consistent with their identification as microglia. The majority of MHC class I-reactive microglia were located in close apposition to blood vessels. These results indicate that an unusually large proportion of microglia within the neurohypophysis constitutively express MHC I antigens. In addition, neurohypophysial microglia are capable of responding to penetrating brain injury by upregulation of MHC I antigens in the absence of local tissue degeneration, possibly because of the absence of a blood-brain barrier.

Detection of bovine pancreatic trypsin inhibitor (bPTI) in bovine and ovine pituitaries, bovine brain, and adrenal medulla. A specific radioimmunoassay for bPTI

An antiserum against bovine pancreatic trypsin inhibitor (bPTI) has been raised in rabbits. The antiserum does not cross-react with known pituitary hormones and other proteins. A specific radioimmunoassay for bPTI has been developed. The ED50 is about 250 fmol per assay tube and the sensitivity is reliable to 15 fmol per tube. Immunoreactivity could be detected in bovine and sheep pituitaries, bovine brain, and adrenal medulla, but not in human, pig, and rat pituitaries. In the bovine pituitary the immunoreactivity is restricted to the posterior lobe.

Immunocytochemical localization of the brain-specific S-100 protein in the pituitary gland of adult rat

The brain-specific S-100 protein was localized at the electron microscopic level in the anterior and posterior pituitary gland of adult rat by indirect immunoperoxidase histology. The protein was found in the stellate cells of the pars distalis and tuberalis, in the marginal cells that line the hypophyseal cleft and in the glia-like cells, the pituicytes, of the neural lobe. The pituicytes, the stellate cells and the marginal cells have in common at least two properties: they all express a brain-specific marker and they are satellite cells to the secretory axons in the neural lobe and of the secretory cells in the adenohypophysis. These properties suggest that the S-100 cells in the pituitary gland are neuroectodermal in origin, possibly glial in nature.