Clock genes, oscillators, and cellular networks in the suprachiasmatic nuclei

The mammalian SCN contains a biological clock that drives remarkably precise circadian rhythms in vivo and in vitro. Recent advances have revealed molecular and cellular mechanisms required for the generation of these daily rhythms and their synchronization between SCN neurons and to the environmental light cycle. This review of the evidence for a cell-autonomous circadian pacemaker within specialized neurons of the SCN focuses on 6 genes implicated within the pace making mechanism, an additional 4 genes implicated in pathways from the pacemaker, and the intercellular and intracellular mechanisms that synchronize SCN neurons to each other and to solar time.     

On the statistical distribution of volumes of cell nuclei and on the dependence of volumes of cell nuclei and DNA amounts in the cell nuclei

Conclusion Based on the simplified model of the cell nucleus it has been shown that (V) is Gaussian. It follows also from this model the independence ofX andV. A number of further reasons for independence ofX andV is shown too.     

Biorhythm of arginine-vasopressin in the paraventricular, supraoptic and suprachiasmatic nuclei of rats

The diurnal variations in content of arginine-vasopressin in the supraoptic nucleus, the paraventricular nucleus and the suprachiasmatic nucleus of rats were determined using radioimmunoassay. In the supraoptic nucleus and the paraventricular nucleus the arginine-vasopressin level was relatively constant during the light phase (the inactive phase). When it became dark, the level of arginine-vasopressin lowered during the early and middle dark phase and then increased to the highest level during the late dark phase. In the suprachiasmatic nucleus the level was stable during the light phase, while in the early and the late dark phase it was significantly higher than that in the middle dark phase.     

Migration and division of cleavage nuclei in the gall midge,Wachtliella persicariae

Summary The control of nuclear division and migration was studied in time-lapse films of the multinucleate egg cell of a gall midge by experimental alterations of the mitotic pattern. During each cleavage cycle, a wave of randomly oriented saltations of yolk particles (WROS) is seen to travel through the ooplasm. This wave proved to be an indispensable prerequisite for the accompanying anaphase wave and for the activation of the nuclear migration cytasters: WROS cycles can occur autonomously without cleavage nuclei being present, but there is no anaphase without a WROS passing the dividing nucleus. WROSs and mitotic waves can be inverted, and the WROS cycles and the cleavage cycles can be desynchronized by temperature grandients or by locally impaired gas exchange. If a nucleus is not ready for anaphase when met by a WROS, it will only divide in the course of the next WROS. WROSs thus indicate autonomous anaphase-triggering waves governing the cleavage divisions. Rhythmic ooplasmic movements continue even if the WROSs as well as the nuclear divisions are inhibited by colchinine. The characteristics of the WROSs support the hypothesis that each of them is the visible effect of a wave of calcium release (similar to that established in vertebrate eggs) which acts locally on the microtubular system and may continue even if the WROSs are suppressed. The correlations between a possible calcium release, WROS activity, microtubule disassembly and nuclear cycle are discussed.     

Migration and division of cleavage nuclei in the gall midge,Wachtliella persicariae

Summary In the eggs ofWachtliella persicariae the cleavage nuclei move relative to the surrounding ooplasm. This active migration is caused by an organelle whose ultrastructure was studied throughout the mitotic cycle. It consists of a greatly enlarged polar cytaster derived from the mitotic apparatus, linked to the nucleus by 100 Å filaments. The microtubules of the cytaster were found only during periods of active nuclear migration, i.e., from the onset of anaphase to the early prophase of the next mitotic cycle. They are always solitary and follow the course of the astral rays, which are known to temporarily adhere to peripheral structures of the egg cell and to exert tractive forces. In contrast to the cytaster microtubules, the microtubules in the spindle are bundled and persist from early metaphase through late telophase.During ontogenesis the first migration cytaster is built up between 3 and 12 min after oviposition near the anterior egg pole, in the vicinity of the sperm nucleus. In non-inseminated eggs time lapse films show a migration cytaster to develop autonomously in a region free from nuclei, but it does not follow the normal path of the male pronucleus. In several cases the female pronucleus, which remains without a cytaster of its own, was observed to move to the cytaster generated in the absence of the male pronucleus. Whether or not it is adhering to a nucleus, the cytaster divides into two at the correct time, i.e, corresponding to the first cleavage division in fertilized eggs. In some non-inseminated eggs this type of pseudocleavage has been observed to occur repeatedly, giving rise to an increasing number of anucleate cytasters.     

Projections of the central cerebellar nuclei to the intralaminar thalamic nuclei in cats

Projections of the central cerebellar nuclei to the intralaminar thalamic nuclei were studied in cats with the use of light and electron microscopy. Almost all intralaminar nuclei were shown to obtain cerebello-thalamic projections. The entire complex of the central cerebellar nuclei serves as a source of such projections; yet, involvement of different nuclei is dissimilar. Destruction of the central and, especially, caudal regions of the fastigial nucleus evoked in the intralaminar thalamic nuclei degenerative changes in the nerve fibers (from swelling and development of varicosities up to total fragmentation). Pathological phenomena could be noticed in the most caudal regions of the above thalamic nuclear group, including the medial dorsal nucleus. Projections of the cerebellar interpositus nucleus were directed toward nearly the same regions of the intralaminar nuclei; degeneration was more intensive (covered thecentrum medianum) when posterior regions of the interpositus nucleus were destroyed. Destruction of the lateral cerebellar nucleus evoked a similar pattern of pathological changes, but degeneration was also observed in some structures of the ventral and anterior nuclear groups of the thalamus. Electron microscopic examination showed that degeneration of dark and light types developed in the fiber preterminals and terminals. It can be concluded that the central cerebellar nuclei project not only to the ventral complex of the thalamic nuclei, but also to the anterior, medial, and intralaminar nuclear groups (rostral and caudal portions).     

Microphotometry of rat liver nucleoproteins during the cell cycle, and comparison of diploid nuclei in the G2 period with tetraploid nuclei.

The following facts were established with a microphotometric investigation of isolated nuclei from rat liver in different stages of the cell cycle. During the mitotic wave occurring in the liver of newborn animals after injection of casein it was found that the naphtol yellow S (NYS) protein content of the nuclei increases about 30% during the G1-period. A second increase of around 70% was established during the S-phase whereas no increase could be observed during the G2-phase. An indication for the existence of a "critical protein mass" of the nuclei before the onset of the S-phase could be observed. The protein content of diploid nuclei in the G1-phase of adult animals is about 50% higher than in newborns. This makes it probable that there is no significant difference in the NYS-protein content of diploid nuclei in the G2-period and tetraploid nuclei of adult rats. No differences were observed between diploid nuclei in the G2-period of newborn rats and tetraploid nuclei of adult rats in their Fastgreen histon, RNA and SH plus SS content. The only criterion to distinguish between G2 nuclei and tetraploid nuclei seems to be the number of nucleoli, but this is rather unreliable.     

Functional interactions between the intralaminar nuclei of the thalamus and the caudate nuclei in the formation of motor programs

It has been shown that at the beginning of motor program forming, homogeneous and cyclic excitations take place between the nonspecific thalamic structures and caudate nuclei. Later on reciprocity of the afferent inflows to the nuclei under consideration occurs, that indicates a different pattern of the involvement of these structures into intercentral integration controlling avoidance behavior.     

Neuronal-vascular relationships in the raphe nuclei, locus coeruleus, and substantia nigra in primates.

A fluorescence histochemical and electron microscopic study of the monoaminergic cell groups in the squirrel monkey and Rhesus monkey brains has revealed the direct apposition of blood vessels to perikarya and dendrites of monoaminergic neurons. Capillaries and small arterioles or venules, ranging from 8-50 microns in diameter, showed perikarya and dendrites abutting the basement membrane without evidence of glial interposition. This neuronal-vascular relationship was present in 20% to 30% of the small vessels in the serotonergic nuclei raphe dorsalis and centralis superior and in the noradrenergic locus coeruleus. Such contacts were clearly present but observed less frequently in the dopaminergic substantia nigra pars compacta and in the serotonergic nuclei raphe obscurus, pallidus, magnus, and pontis. We postulate that monoamine-containing neurons apposed to blood vessels in certain regions of the brain may be influenced directly by hormones or other substances in blood.