Topographic organization of the karyometric response to neonatal castration of the male mouse in the paraventricular and ventromedial hypothalamic nuclei

We have analysed the karyometric development of four topographic subdivisions of the paraventricular nucleus (rostral, medial, lateral and caudal) and three topographic subdivisions of the ventromedial nucleus (ventral, central and dorsal) of the hypothalamus in neonatally castrated male mice. Castration at birth produces a decrease of the nuclear sizes from the 10th to the 35th postnatal day, but after this age, no differences were detected in comparison with the sizes of the control male mice. Neonatal gonadal hormone deprivation also produces changes in the nuclear shape of the nuclei, that tend to be more spherical in both centres, as we could establish after the study of the form factor parameter (perimeter/area ratio). We have found differences in the response of both hypothalamic nuclei to neonatal castration and differences in the response of the topographic subdivisions of both of them.     

Regional differences in enhanced neurogenesis in the dentate gyrus of adult rats after transient forebrain ischemia

Neurogenesis in the dentate gyrus occurs throughout life. We observed regional differences in neurogenesis in the dentate gyrus of adult rats following transient forebrain ischemia. Nine days after ischemic-reperfusion or sham manipulation, rats were given 5-bromo-2'-deoxyuridine-5'-monophosphate (BrdU), a marker for dividing cells. They were killed 1 or 28 days later to distinguish between cell proliferation and survival. Neurogenesis was evaluated by BrdU incorporation as well by identifying neuronal and glial markers in six regions of the dentate gyrus: rostral, middle and caudal along the rostrocaudal axis, each further divided into suprapyramidal and infrapyramidal blade subregions. In control rats BrdU-positive cells in the rostral subregions were significantly lower in the suprapyramidal than in the infrapyramidal blades at both 1 and 28 days after BrdU injection. One day after injection, BrdU-positive cells had increased more in five of the subregions in the ischemic rats than in the controls, the exception being the suprapyramidal blade of the rostral subregion. At 28 days after BrdU injection, numbers of BrdU-positive cells were higher in four subregions in the ischemic group, the exceptions being the rostral suprapyramidal and middle infrapyramidal blades. At 28 days after BrdU injection, the percentages of BrdU positive cells that expressed a neuronal marker (NeuN) were the same in the dentate granule cell layers of ischemic and control rats. Our data thus demonstrate regional differences in enhanced neurogenesis in the dentate gyrus of adult rats after transient forebrain ischemia.     

Development of the subfornical organ and area postrema of the male albino mouse. Karyometric effect of neonatal and prepuberal castration

We have studied the karyometric development of the nuclei of the ependymal cells and neurons of the subfornical organ and the area postrema in the male albino mouse from the 5th to the 190th postnatal day. We have found similar patterns of development in both although the area postrema showed more significant postnatal oscillations than those of the subfornical organ, suggesting a more intimate chronological relationship to gonadal development. We have furthermore analyzed the development in two experimental groups: in the one animals were castrated at birth, in the other, castration was made on the 20th postnatal day. We have found that neonatal castration produced a significant decrease of nuclear sizes; this was more evident in the subfornical organ than in the area postrema in earlier stages of development while the response was similar in both at peripuberal ages. The response to prepuberal castration was similar in both organs.     

Intrinsic organization of snake lateral cortex

Lateral cortex is the most laterally placed of the four cortical areas in snakes. Earlier studies suggest that it is composed of several subdivisions but provide no information on their organization. This paper first investigates the structure of lateral cortex in boa constrictors (Constrictor constrictor), garter snakes (Thamnophis sirtalis), and banded water snakes (Natrix sipedon) using Nissl and Golgi preparations; and secondly examines the relation of main olfactory bulb projections to the subdivisions of lateral cortex using Fink-Heimer and electron microscopic preparations. Lateral cortex is divided on cytoarchitectonic grounds into two major parts called rostral and caudal lateral cortex. Each part is further divided into dorsal and ventral subdivisions so that lateral cortex has a total of four subdivisions: dorsal rostral lateral cortex (drL), ventral rostral lateral cortex (vrL), dorsal caudal lateral cortex (dcL) and ventral caudal lateral cortex (vcL). Systematic analyses of Golgi preparations indicate that the rostral and caudal parts each contain distinct populations of neurons. Rostral lateral cortex contains bowl cells whose dendrites arborize widely in the outer cortical layer (layer 1). The axons of some bowl cells can be traced medially into dorsal cortex, dorsomedial cortex and medial cortex. Caudal lateral cortex contains pyramidal cells whose somata occur in layers 2 and 3 and whose dendrites extend radially up to the pial surface. In addition, three populations of neurons occur in both rostral and caudal lateral cortex. Stellate cells occur in all three layers and have dendrites which arborize in all directions. Double pyramidal cells occur primarily in layer 2 and have dendrites which form two conical fields whose long axes are oriented radially. Horizontal cells occur in layer 3 and have dendrites oriented concentric with the ependyma. Fink-Heimer preparations of snakes which underwent lesions of the main olfactory bulb show that the primary olfactory projections to cortex are bilateral and restricted precisely to rostral lateral cortex. Electron microscopic degeneration experiments indicate that the olfactory bulb fibers end as terminals which have clear, spherical vesicles and asymmetric active zones. The majority are presynaptic to dendritic spines in outer layer 1. These studies establish that lateral cortex in snakes is heterogeneous and contains two major parts, each containing two subdivisions. The rostral and caudal parts have characteristic neuronal populations. Primary olfactory input is restricted to rostral lateral cortex and seems to terminate heavily on the distal dendrites of bowl cells. Axons of some of these cells leave lateral cortex, so that the rostral lateral cortex forms a direct route by which olfactory information reaches other cortical areas. The functional role of caudal lateral cortex is not clear.     

A new species of Oswaldocruzia (Molineidae: Nematoda) in Chaunus marinus (Amphibian: Bufonidae) (Linneaus, 1758) from Brazil

Oswaldocruzia belenensis n. sp. (Strongylida: Molineidae) from the small intestine of Chaunus marinus (L.) from Belém, Pará State, Brazil is described and illustrated by light and scanning electron microscopy. Oswaldocruzia belenensis n. sp. is a neotropical species of this genus, harboring caudal bursa Type II, spicules divided in 3 branches, i.e., a blade, shoe, and fork. The blade is divided in 4 points, of which at least 2 are bifurcated. Cervical alae are absent; there is a simple cephalic vesicle and synlophe with low ridges perpendicular to the body without chitinous supports. The most closely related species are O. bonsi and O. lescurei. Oswaldocruzia belenensis n. sp. differs from O. lescurei and O. bonsi by the number and location of cephalic papillae, rays 2-3 and 5-6 running parallel and slightly separated, ray 6 not overlapping ray 8, and body structure morphometry. Oswaldocruzia belenensis n sp. also differs from O. lescurei by the discontinuity of the longitudinal ridges, the number of subdivisions of the blade, and the absence of extra processes at the bifurcation level of the fork of the spicules. The new species differs from O. bonsi by male and female body dimensions, the symmetry of the caudal bursa, dimension and subdivisions of the spicules without extra processes of the fork, 2 extra processes at the distal division of the blade, and location of ray 7 at the anterior margin of the cloacal aperture. Oswaldocruzia belenensis n. sp. represents the 82nd species assigned to the genus.     

Late Maturation of Adult-Born Neurons in the Temporal Dentate Gyrus

Hippocampal function varies along its septotemporal axis, with the septal (dorsal) pole more frequently involved in spatial learning and memory and the temporal (ventral) pole playing a greater role in emotional behaviors. One feature that varies across these subregions is adult neurogenesis. New neurons are more numerous in the septal hippocampus but are more active in the temporal hippocampus during water maze training. However, many other aspects of adult neurogenesis remain unexplored in the context of septal versus temporal subregions. In addition, the dentate gyrus contains another functionally important anatomical division along the transverse axis, with the suprapyramidal blade showing greater experience-related activity than the infrapyramidal blade. Here we ask whether new neurons differ in their rates of survival and maturation along the septotemporal and transverse axes. We found that neurogenesis is initially higher in the infrapyramidal than suprapyramidal blade, but these cells are less likely to survive, resulting in similar densities of neurons in the two blades by four weeks. Across the septotemporal axis, neurogenesis was higher in septal than temporal pole, while the survival rate of new neurons did not differ. Maturation was assessed by immunostaining for the neuronal marker, NeuN, which increases in expression level with maturation, and for the immediate-early gene, Arc, which suggests a neuron is capable of undergoing activity-dependent synaptic plasticity. Maturation occurred approximately 1–2 weeks earlier in the septal pole than in the temporal pole. This suggests that septal neurons may contribute to function sooner; however, the prolonged maturation of new temporal neurons may endow them with a longer window of plasticity during which their functions could be distinct from those of the mature granule cell population. These data point to subregional differences in new neuron maturation and suggest that changes in neurogenesis could alter different hippocampus-dependent behaviors with different time courses.     

典型盐地植物小獐毛的生态学研究

通过茎、叶显微结构的解剖观察,表明小獐毛（Aeluropuslittoralis（Gouan）Parl．）与其它盐地植物相比,具有含晶细胞数目多,叶片中鞘细胞伸展区发达,茎、叶表皮细胞外壁硅质化明显,叶栅栏组织发达,而机械组织不发达等特点。结合小獐毛自然生境、群落特征,初步分析了其外部形态、解剖结构与盐地生境的适应关系。     

Development of cholinergic innervation in the hippocampal formation of the rat. I. Histochemical demonstration of acetylcholinesterase activity

The postnatal development of acetylcholinesterase (AChE) activity in the hippocampal formation of the developing rat brain, as demonstrated histochemically by the copper-thiocholine technique, serves as a marker for the ingrowing cholinergic afferent fibers. The discrete laminar pattern of staining characteristic of the adult hippocampal formation develops entirely after birth. Stain deposit is observable earliest (about 4 days after birth) at the septal end of the hippocampus. During the following week, AChE activity can be demonstrated in successively temporal segments until, about 11 days after birth, all parts of the hippocampal formation exhibit activity. Within each segment, the pattern of developing activity suggests association with three distinct fiber projections emanating from the fimbria, each with its own characteristic time of appearance and rate of growth: (1) a projection through stratum oriens of hippocampus regio inferior to stratum oriens of regio superior; (2) fibers which cross straum pyramidale of regio inferior, run in the suprapyramidal zone of that region and continue into the supra- and infragranular zones in the external leaf of the dentate gyrus; (3) a projection through stratum oriens of regio inferior which continues into the supra- and infragranular zones in the internal leaf of the dentate gyrus.     

Application of multilevel models to morphometric data. Part 2. Correlations.

Multilevel organization of morphometric data (cells are "nested" within patients) requires special methods for studying correlations between karyometric features. The most distinct feature of these methods is that separate correlation (covariance) matrices are produced for every level in the hierarchy. In karyometric research, the cell-level (i.e., within-tumor) correlations seem to be of major interest. Beside their biological importance, these correlation coefficients (CC) are compulsory when dimensionality reduction is required. Using MLwiN, a dedicated program for multilevel modeling, we show how to use multivariate multilevel models (MMM) to obtain and interpret CC in each of the levels. A comparison with two usual, "single-level" statistics shows that MMM represent the only way to obtain correct cell-level correlation coefficients. The summary statistics method (take average values across each patient) produces patient-level CC only, and the "pooling" method (merge all cells together and ignore patients as units of analysis) yields incorrect CC at all. We conclude that multilevel modeling is an indispensable tool for studying correlations between morphometric variables.     

The Dorsocross T-box transcription factors promote tissue morphogenesis in the Drosophila wing imaginal disc

The Drosophila wing imaginal disc is subdivided into notum, hinge and blade territories during the third larval instar by formation of several deep apical folds. The molecular mechanisms of these subdivisions and the subsequent initiation of morphogenic processes during metamorphosis are poorly understood. Here, we demonstrate that the Dorsocross (Doc) T-box genes promote the progression of epithelial folds that not only separate the hinge and blade regions of the wing disc but also contribute to metamorphic development by changing cell shapes and bending the wing disc. We found that Doc expression was restricted by two inhibitors, Vestigial and Homothorax, leading to two narrow Doc stripes where the folds separating hinge and blade are forming. Doc mutant clones prevented the lateral extension and deepening of these folds at the larval stage and delayed wing disc bending in the early pupal stage. Ectopic Doc expression was sufficient to generate deep apical folds by causing a basolateral redistribution of the apical microtubule web and a shortening of cells. Cells of both the endogenous blade/hinge folds and of folds elicited by ectopic Doc expression expressed Matrix metalloproteinase 2 (Mmp2). In these folds, integrins and extracellular matrix proteins were depleted. Overexpression of Doc along the blade/hinge folds caused precocious wing disc bending, which could be suppressed by co-expressing MMP2RNAi.     

The neurons of origin of non-cortical afferent connections to the oculomotor nucleus. A retrograde labeling study in the rabbit.

The cellular origin of the brainstem projections to the oculomotor nucleus in the rabbit has been investigated by using free (HRP) and lectin-conjugated horseradish peroxidase (WGA-HRP). Following injections of these tracers into the somatic oculomotor nucleus (OMC), retrogradely labeled cells have been observed in numerous brainstem structures. In particular, bilateral labeling has been found in the four main subdivisions of the vestibular complex, predominantly in the superior and medial vestibular nuclei and the interstitial nucleus of Cajal, while ipsilateral labeling was found in the rostral interstitial nucleus of the medial longitudinal fascicle (Ri-MLF), the Darkschewitsch and the praepositus nuclei. Neurons labeled only contralaterally have been identified in the following structures: mesencephalic reticular formation dorsolateral to the red nucleus, abducens internuclear neurons, group Y, several areas of the lateral and medial regions of the pontine and medullary reticular formation, ventral region of the lateral cerebellar nucleus and caudal anterior interpositus nucleus. This study provides also information regarding differential projections of some centers to rostral and caudal portions of the OMC. Thus, the rostral one-third appears to receive predominant afferents from the superior and medial vestibular nuclei, while the caudal two-thirds receive afferents from all the four vestibular nuclei. Finally, the group Y sends afferents to the middle and caudal, but not to the rostral OMC.     

Ontogeny of endocrine cells in the respiratory system of Syrian golden hamsters

The ontogeny of protein gene product 9.5 (PGP 9.5), serotonin (5-HT), calcitonin gene-related peptide (CGRP), and calcitonin (CT) immunoreactivity was evaluated in small-granule endocrine cells of hamster laryngotracheal epithelium from fetal day 11 to adulthood. Two centrifugal (proximal-to-distal) patterns of differentiation occur. The first pattern begins during fetal life. Endocrine cells, single and clustered in groups (presumptive-or protoneuroepithelial bodies, pNEBs), initially colocalize immunostaining for PGP 9.5, 5-HT, and CGRP in the larynx and proximal 2/3 of the trachea on day 12 and spread to the caudal trachea on day 13.5-HT disappears fleetingly during the 24 h preceding birth; other-wise immunoreactivity for all three substances persists into adulthood. The clusters of endocrine cells survive beyond birth but are so diluted by expansion of the nonendocrine epithelium as to become inconspicuous. Since innervation was not actually observed, these clusters may persist as pNEBs, without developing connections to afferent or efferent nerve fibers. The second pattern concerns single small-granule cells stainable for CGRP but not for 5-HT. These cells first appear in the larynx and cartilaginous part of the cranial trachea on postnatal day 3, and in the middle and caudal trachea, on day 5. The cells increase in number on day 7. In adults, they predominate among endocrine cells of the cartilaginous region. A subset of these cells begins to co-express CT proximally on postnatal day 10, reaching the caudal end of the trachea by 3 weeks. A few elements of the older 5-HT-positive population may also become immunoreactive for CT in juvenile hamsters.     

Elevational Variation of Leaf Traits in Montane Rain Forest Tree Species at La Chinantla, Southern México1

Variation in leaf traits of dominant tree species in six montane rain forest communities was analyzed along an elevational gradient ranging from 1220 to 2560 m within a single basin at La Chinantla, Oaxaca, México. Three groups of characters were used: morphological (leaf shape, margin, blade configuration, and phyllotaxy), morphometric (leaf area, leaf mass per area, stomatal density, and blade length/width ratio), and anatomical (thicknesses of blade, palisade [PP], and spongy [SP] parenchymae, PP/SP ratio, and epidermis and cuticle thicknesses). The variation of morphological characteristics was only evident at the highest elevations; in contrast, thickness of leaf blade, PP, SP, as well as leaf mass per area clearly increased along the gradient, whereas leaf area was the only variable that significantly decreased with elevation. Thicknesses of epidermis and of the two cuticles were not significantly correlated with elevation. A classification analysis based on a leaf trait matrix led to the distinction between low and high elevation communities, with an approximate limit between them at ca 2300 to 2400 m. The results are discussed in light of environmental changes occurring along elevational gradients. Leaf characteristics of montane rain forest plants offer important insights about the complex roles of abiotic factors operating in these environments and supplement the traditional physiognomic classification schemes for these communities.     

Fate mapping the avian epiblast with focal injections of a fluorescent-histochemical marker: ectodermal derivatives

A microinjection technique is described for fate mapping the epiblast of avian embryos. It consists of injecting the epiblast of cultured blastoderms with a fluorescent-histochemical marker, examining rhodamine fluorescence at the time of injection in living blastoderms, and assaying for horseradish peroxidase activity in histological sections obtained from the same embryos collected 24 h postinjection. Our results demonstrate that this procedure routinely marks cells, allowing their fates to be determined and prospective fate maps to be constructed. Two such maps are presented for ectodermal derivatives of the epiblast: one for late stages of Hensen's node progression (stages 3c through 4) and one for early stages of node regression (stages 4 + through 5). These new maps have six significant features. First, they show that regardless of whether the node is progressing or regressing, the flat neural plate extends at least 300 microns cranial to, 300 microns bilateral to and 1 mm caudal to the center of Hensen's node. Second, they confirm our previous fate mapping studies based on quail/chick chimeras. Namely, they show that the prenodal midline region of the epiblast forms the floor of the forebrain and the ventrolateral part of the optic vesicles as well as MHP cells (i.e., mainly wedge-shaped neurepithelial cells contained within the median hinge point of the bending neural plate); in contrast, paranodal and postnodal regions contribute L cells (i.e., mainly spindle-shaped neurepithelial cells constituting the lateral aspects of the neural plate). Third, they reveal a second source of MHP cells, Hensen's node, verifying previous studies of others based on tritiated thymidine labeling. Fourth, they demonstrate, in contrast to studies of other based on vital staining, carbon marking, and chorioallantoic grafting but in accordance with our previous studies based on quail/chick chimeras, that the cells contributing to the four craniocaudal subdivisions of the neural tube (i.e., forebrain, midbrain, hindbrain, and spinal cord) are not yet spatially segregated from one another at the flat neural plate stage, although more cranial neural plate cells tend to form more cranial subdivision and more caudal cells tend to form more caudal subdivisions. Thus, single injections routinely mark multiple neural tube subdivisions. Probable reasons for the discrepancy between our present results and the previous results of others is discussed. Fifth, they suggest that cells contributing to the surface ectoderm and neural plate are not yet completely spatially segregated from one another at the flat neural plate stage, particularly in caudal postnodal regions. Sixth, they delineate the locations of the otic placodes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Modeling temporal behavior of postnatal cat retinal ganglion cells

During development, mammalian retinal ganglion cells (RGCs) go through marked ontogenetic changes with respect to their excitable membrane properties. Voltage-clamp studies conducted in our laboratory have shown that the amplitude, voltage-dependence and kinetics of activation and inactivation (where present) of Na(+), K(+) and Ca(2+) conductances all exhibit developmental changes during a time when the firing patterns of mammalian ganglion cells shift from being transient to being predominantly sustained in nature. In order to better understand the contribution of each conductance to the generation of spikes and spiking patterns, we have developed a model based on our experimental data. For simplicity, we have initially used experimental data obtained from postnatal ganglion cells. At this age the ontogenetic changes observed in the characteristics of the various ionic currents are complete. Utilizing the methods adopted by Hodgkin and Huxley for the giant squid axon, we have determined rate equations for the activation and inactivation properties of the I(A), I(K dr), I(Na), I(Ca L), I(Ca N), and I(leak) currents in postnatal cat RGCs. Combining these with a simplified model of the calcium-activated potassium current (I(KCa)), we have solved and analysed the resulting differential equations. While spikes and spiking patterns resembling experimental data could be obtained from a model in which [Ca(2+)i] was averaged across the whole cell, more accurate simulations were obtained when the diffusion of intracellular Ca(2+) was modeled spatially. The resulting spatial calcium gradients were more effective in gating I(KCa), and our simulations more accurately matched the recorded amplitude and shape of individual spikes as well as the frequency of maintained discharges observed in mammalian postnatal RGCs.     

A morphological and karyometric study of the secretory cells in mint

Morphological and karyometric peculiarities of oil-synthesizing secretory structures in mint forms differing by rate of oil biosynthesis were investigated. Significant similarity in morphology of secretory structures in investigated forms during differentiation and functioning was shown. Character of changes in karyometric properties of oil-synthesizing cells also was similar: nuclear and nucleolar volumes increased and then decreased during differentiation of secretory structures. A functional increase of nuclear and nucleolar volumes was found at the stage before essential oil secretion. Higher parameters at all stages of differentiation and before secretion were revealed in highly oil-production mint. This fact may serve as indirect indicator of increased functional activity of oil-synthesizing cells and intensity of oil-producing process. The obtained results are discussing with well-known data.     

Ontogeny of endocrine cells in the respiratory system of Syrian golden hamsters

The ontogeny of protein gene product 9.5 (PGP 9.5), serotonin (5–HT), calcitonin gene-related peptide (CGRP), and calcitonin (CT) immunoreactivity was evaluated in small-granule endocrine cells of hamster laryngotracheal epithelium from fetal day 11 to adulthood. Two centrifugal (proximal-to-distal) patterns of differentiation occur. The first pattern begins during fetal life. Endocrine cells, single and clustered in groups (presumptive- or protoneuroepithelial bodies, pNEBs), initially co-localize immunostaining for PGP 9.5, 5–HT, and CGRP in the larynx and proximal 2/3 of the trachea on day 12 and spread to the caudal trachea on day 13. 5–HT disappears fleetingly during the 24 h preceding birth; otherwise immunoreactivity for all three substances persists into adulthood. The clusters of endocrine cells survive beyond birth but are so diluted by expansion of the nonendocrine epithelium as to become inconspicuous. Since innervation was not actually observed, these clusters may persist as pNEBs, without developing connections to afferent or efferent nerve fibers. The second pattern concerns single small-granule cells stainable for CGRP but not for 5–HT. These cells first appear in the larynx and cartilaginous part of the cranial trachea on postnatal day 3, and in the middle and caudal trachea, on day 5. The cells increase in number on day 7. In adults, they predominate among endocrine cells of the cartilaginous region. A subset of these cells begins to co-express CT proximally on postnatal day 10, reaching the caudal end of the trachea by 3 weeks. A few elements of the older 5–HT-positive population may also become immunoreactive for CT in juvenile hamsters.     

Complex secretory products in the oviduct of the plethodontid salamander Bolitoglossa dofleini (Amphibia, Urodela)

The ultrastructure of the secretory granules in the cells of the subdivisions of the oviduct in the neotropical plethodontid salamander Bolitoglossa dofleini was studied by transmission electron microscopy. In addition, we applied the cationic dye Cuprolinic Blue (CB) at different electrolyte concentrations to demonstrate proteoglycans, and the pyrogallol red-copper (PR-C) method to stain proteins at the ultrastructural level. The entire oviduct is lined by a simple epithelium that contains ciliated and microvillous cells in the first subdivision, the aglandular pars recta; microvillous cells show a moderate secretory activity. The following pars convoluta is differentiated into five glandular subdivisions and the aglandular “uterine portion”. Especially in the glandular parts, the epithelium is arranged in longitudinal folds. At their crests ciliated and microvillous cells similar to those in the pars recta occur. Gland cells are crowded with secretory granules that differ in their structural complexity (with and without electron-dense spheres or masses; elaborated, homogeneous or granular matrix; spherical; distorted) along the various subdivisions. Further, as suggested by the CB-technique, the cranial subdivisions contain large amounts of sulphated proteoglycans that decrease in the caudal direction. Carboxylated proteglycans appear to be present in all subdivisions examined. Electron-dense spheres of secretory granules are largely free of CB-precipitates, but stain more or less intensely with PR-C. The ultrastructure of the pars recta, and especially the “uterine portion” indicates transporting capability. The epithelial cells of the “uterus” have coated pits and a considerable amount of lysosome-like bodies.     

Hypothalamo-neurohypophysial complex in leukemia L 1210-bearing mice.

Mice of the DBA strain were inoculated with 4.5 x 10(6) L1210 ascites cells and the time response of the hypothalamo-neurohypophysial complex was studied. The amount of neurosecretory material was determined in the neuroendocrine cells of supraoptic and paraventricular nuclei, throughout the hypothalamo-neurohypophysial tract and in the neural lobe of the hypophysis. Three methods of response evaluation were employed: the amoount of neurosecretory material was estimated according to an arbitrary scale, by cytophotometry while for the hypothalamic cell-nuclei the karyometric method was used. The existence of a functional interrelation between the presence of leukemic cells and the activity of the hormonogenic sites in the hypothalamus is suggested. A clear response to the tumor inoculation was established both in the amount of stainable substance and in the nuclear volume of the secretory neurones. It is suggested that an accelerated synthesis and release of neurosecretory material in tumor recipient mice reduces renal excretion in order to compensate a dehydration caused by the production of ascitic fluid.