Brain vascular volume, electrolytes and blood-brain interface in the cuttlefish Sepia officinalis (Cephalopoda)

Fine structure of the central brain in the octopod Eledone cirrhosa (Lamarck, 1798) (Mollusca-Octopoda)

This study aims to investigate the fine structure of the different cell types in the central brain of Eledone cirrhosa; the organelles in the neurons and the glial cells; the glial hemolymph-brain barrier; the neuro-secretions and the relationships between glial and nerve cells. The brain is surrounded by a non-cellular neurilemma followed by a single layer of perilemmal cells. Ependymal cells, highly prismatic glial cells, astrocytes, oligodendrocytes and epithelial processes were observed. The perikarya of the neurons are filled with slightly oval nuclei with heterochromatin, a strongly tortuous ER, numerous mitochondria and Golgi apparatus with two types of vesicles. In the cellular cortex, glial cells are much less numerous than the neurons and they are located preferably at the border between perikarya and neuropil. Furthermore, they send many branching shoots between the surrounding neuron perikarya and the axons. The glial cytoplasmic matrix appears more electrodense than that of the neurons. Only few ribosomes are attached to the membranes of the ER; the vast majorities are free. In the perikarya of the glial cells, mitochondria, multi-vesicular bodies, various vacuoles and vesicles are present. The essential elements of the hemolymph-brain barrier are the endothelial cells with their tight junctions. The cytoplasm contains various vesicles and mitochondria. However, two other cell types are present, the pericytes and the astrocytes, which are of great importance for the function of the hemolymph-brain barrier. The cell-cell interactions between endothelial cells, pericytes and astrocytes are as close as no other cells.

Microvessel surface area, density and dimensions in brain and muscle of the cephalopod Sepia officinalis

The microvasculature of brain and muscle in the cuttlefish Sepia was studied with stereological techniques to provide information about the surface area for exchange at the blood-tissue interface which was necessary for a parallel study of the permeability of the blood-brain barrier in Sepia . Microvessel density, length, dimensions and volume fraction, and the radius of the ‘Krogh cylinder’ of tissue supplied by each microvessel were also estimated. Vertical lobe (VL) and optic lobe (OL) of brain, outer collar valve muscle (VM) and tentacle muscle (TM) were analysed in 1 μm sections of aldehyde-fixed, Epon-embedded material. ‘Microvessels’ (diameter less than 20 μm) had a surface area density S v (in the order VL, OL, VM, TM) of 134, 176, 67.9 and 13.8 cm 2 cm -3 respectively. The numbers of microvessels per unit area tissue, Q A , were 211, 395, 157 and 43 mm -2 respectively. The length density of microvessels J V = 2 x Q A . The microvessel density was significantly greater in synaptic neuropil (NP) than neuron cell body (CB) zones. Total vessel volume density V V was 3.49, 4.73, 1.88 and 0.28%, in good agreement with previous estimates using intravascular tracers. Mean microvessel diameter d̄ was in the range 4.1-6.5 μm (mode 3.9-4.9 μm). The radius of the Krogh cylinder, R, was 28, 20, 32 and 61 μm. Calculations with the Krogh-Erlang equation show that brain and valve muscle are unlikely to be hypoxic under physiological conditions, while tentacle muscle may be. The vascular parameters correlate well with the known biochemistry of cephalopod tissues. This study represents a detailed analysis of the microvasculature in a complex invertebrate and permits useful comparisons with vertebrate tissues. Values for microvascular S V , Q A , J V and d̄ in Sepia brain are similar to those of the rat, while Sepia muscle vascularity is less than in the rat.

Fine structure of the blood-brain interface in the cuttlefish Sepia officinalis (Mollusca, Cephalopoda)

The blood-brain interface was studied in a cephalopod mollusc, the cuttlefish Sepia officinalis, by thin-section electron microscopy. Layers lining blood vessels in the optic and vertical lobes of the brain, counting from lumen outwards, include a layer of endothelial cells and associated basal lamina, a layer of pericytes and a second basal lamina, and perivascular glial cells. The distinction between endothelial cells and pericytes breaks down in small vessels. In the smallest microvessels, equivalent to capillaries, and in venous channels, and endothelial and pericyte layers are discontinuous, but a layer of glial cells is always interposed between blood and neural tissue, except where neurosecretory endings reach the second basal lamina. In microvessels in which cell membranes of the entire perivascular glial sheath could be followed, the glial layer was apparently 'seamless', not interrupted by an intercellular cleft, in ca 90% (27/30) of the profiles. Where a cleft did occur, it showed an elongated overlap zone between adjacent cells. The walls of venous channels are formed by lamellae of overlapping glial processes. In arterial vessels, the pericyte layer is thicker and more complete, with characteristic sinuous intercellular clefts. Arterioles are defined as vessels containing 'myofilaments' within pericytes, and arteries those in which the region of the second basal lamina is additionally expanded into a wide collagenous zone containing fibroblast-like cells and cell processes enclosing myofilaments. The 'glio-vascular channels' observed in Octopus brain are not a prominent feature of Sepia optic and vertical lobe. The organization of cell layers at the Sepia blood-brain interface suggests that it is designed to restrict permeability between blood and brain.

Freeze-fracture evidence for a novel restricting junction at the blood-brain barrier of the cuttlefish Sepia officinalis

The blood-brain barrier in the cuttlefish Sepia officinalis has been studied with the freeze-fracture technique. Previous thin-section electron microscopy showed that a restricting junction is formed between perivascular glial processes in microvessels and venous vessels, and between pericytes in arterial vessels; the restriction appeared not to be a classical zonula occludens or septate junction. In freeze-fracture replicas from brain optic and vertical lobe, endothelial cells, pericytes and perivascular glia could be recognized by their morphology and relation to the vascular lumen. In microvessels, endothelial and pericyte membranes showed sparse but uniform distribution of P-face intramembranous particles, with no particular particle aggregations. Perivascular glial membranes had a higher density of intramembranous particles but again no particle alignments characteristic of known restricting junctions were seen, although clusterings of intramembranous particles resembling gap junctions were present. In larger venous vessels, the perivascular glial layer showed a multilamellated organization, but again no arrays of intramembranous particles were detected, although this should be a favourable site for visualization of the restricting junctions. The walls of arterial vessels showed collagen deposits and cell processes with apparent intracellular myofilamentous profiles, but no intramembranous junctional particle arrays. It is concluded that the junctional zone observed in thin section electron microscopy is not associated with aligned aggregations of intramembranous particles detectable in freeze-fracture replicas, strengthening the evidence that this is a novel type of restricting junction.

Tightness of the blood-brain barrier and evidence for brain interstitial fluid flow in the cuttlefish, Sepia officinalis

Cephalopod molluscs have complex brains and behaviour, yet little is known about the permeability of their blood-brain interface. The accompanying paper characterized the fluid compartments of the brain and presented evidence for restricted permeability of the blood-brain interface to albumin. The present paper investigates the permeability of the interface to small non-electrolytes. [14C]Polyethylene glycol (PEG, mol. wt. 4000), and [51Cr]EDTA (mol. wt. 342) were injected intravenously or intramuscularly, and their penetration into brain and muscle studied up to 48 h. Tracers equilibrated with muscle interstitial fluid (ISF) at relatively short times, but in brain ISF reached only 0.5-0.65 X their plasma concentration. This is qualitative evidence for the presence in brain of a barrier to these molecules and an efficient drainage mechanism for ISF. Quantitative treatment of the uptake data allows calculation of the permeability X surface area product (PS) and the permeability coefficient (P). For the brain PS and P are in the range 1-3 X 10(-4) ml g-1 min-1 and 1-3 X 10(-8) cm s-1 respectively, (PEG), and 3 X 10(-4) ml g-1 min-1 and 3-4 X 10(-8) cm s-1 respectively (Cr-EDTA). The P values are close to those reported for mammalian brain. Assuming that the lack of equilibration in brain is due to ISF flow, the rate of flow can be calculated. Values for vertical and optic lobe are approximately 0.2 microliter g-1 min-1, again close to those reported for mammalian brain. It is concluded that the tightness of the Sepia blood-brain barrier approaches that of mammals, and a flowing ISF system is present. An association between a tight barrier and higher central nervous system integrative function is suggested. The significance of these findings for the evolution of control of the brain microenvironment is discussed.