A comparison of the inhibitory effects of melatonin and indomethacin on platelet aggregation and thromboxane release

Collagen-induced platelet aggregation and thromboxane release is inhibited, in a concentration response relationship, by preincubation of gel-filtered platelets with melatonin in the concentration range 430 nM – 4.3 mM. Inhibition of platelet aggregation and thromboxane release also occurs in the presence of indomethacin (4.3 nM – 4.3 mM), a known potent inhibitor of prostaglandin synthesis. Arachidonic acid-induced platelet aggregation and thromboxane release was inhibited in the presence of 4.0 mM melatonin. We therefore propose that inhibition of prostaglandin synthesis maybe the mechanism by which melatonin expresses its activity. Its antigonadotropic activity may result from inhibition of PGE₂ synthesis in the hypothalamus and median eminence.     

Growth interactions among blue-green (Anabaena Oscillarioides,Microcystis aeruginosa) and green (Chlorella sp.) algae

The growth interactions amongst the blue-green algal species Anabaena oscillarioides, Microcystis aeruginosa and the green alga, Chlorella sp. were studied both in mixed cultures and in filter cultures separated by a membrane filter in the two arms of an interaction U-tube. The role of nutrients especially phosphate upon the interaction has also been studied. Anabaena and Microcystis both inhibited the growth of Chlorella while Microcystis also inhibited the growth of Anabaena. The inhibitory effect of Microcystis was found to be dependent on high concentrations of the initial algal inocula and independent of the initial concentration of nutrients such as inorganic phosphate, indicating that the nature of the inhibition is probably due to the production of inhibitory extracellular products by Microcystis. On the other hand, the inhibitory effect of Anabaena on Chlorella is the consequence of nutrient competition with Anabaena competing more effectively for the available phosphate.     

Developmental requirements of the univoltine species Chrysopa downesi: Photoperiodic stimuli and sensitive stages

Chrysopa downesi reproduces only in the spring and the resulting adults enter an aestival-autumnal-hibernal diapause which is primarily controlled by photoperiod. In the laboratory, constant photoperiods result in diapause induction and maintenance, whereas a series of short days followed by long days prevents or terminates diapause and promotes reproduction. The stages most sensitive to the diapause-averting stimulus are the free-living third instar, the third instar within the cocoon, and the pupa.C. downesi responds in different ways to three aspects of photoperiod: (a) an all-or-none response (diapause prevention or induction) to a sequence of two critical photoperiods, (b) an all-or-none response (diapause prevention or induction) to the difference between the long and short daylengths (a 4 hr difference is sufficient to avert diapause but a 2 hr difference is not), and (c) a quantitative response to the absolute duration of day (or night) length (after the short day requirement is fulfilled the rate of diapause termination is related to daylength).Differences and similarities in phenological adaptations and in photoperiodic responses of C. downesi, C. carnea, and C. harrisii reflect the degree of phylogenetic relationship between these closely related species.     

Physiological responses underlying the timing of vernal activities in insects

Temperate zone insect species have evolved three general strategies for synchronizing the end of hibernation with the return of favorable conditions. Recent eco-physiological studies of insect dormancy and development indicate that the prevailing concepts of the adaptations regulating hibernation and the resumption of spring activity, need revision. In particular, experimental evidence shows that despite implications in the term, dormancy is a dynamic state; the organism, by constantly monitoring the constantly-changing environmental parameters, is kept in phase with the seasons at its particular locality. Furthermore, the insect's ability to respond to environmental factors generally changes as the season progresses. Therefore, the construction of realistic predictive models of insect seasonality should be based on investigations of natural populations undergoing hibernation in the field, combined with ecologically and physiologically meaningful laboratory studies.Presented at the Seventh International Biometeorological Congress, 17–23 August 1975, College Park, Maryland, USA.     

Mid51/Fis1 mitochondrial oligomerization complex drives lysosomal untethering and network dynamics

Lysosomes are highly dynamic organelles implicated in multiple diseases. Using live super-resolution microscopy, we found that lysosomal tethering events rarely undergo lysosomal fusion, but rather untether over time to reorganize the lysosomal network. Inter-lysosomal untethering events are driven by a mitochondrial Mid51/Fis1 complex that undergoes coupled oligomerization on the outer mitochondrial membrane. Importantly, Fis1 oligomerization mediates TBC1D15 (Rab7-GAP) mitochondrial recruitment to drive inter-lysosomal untethering via Rab7 GTP hydrolysis. Moreover, inhibiting Fis1 oligomerization by either mutant Fis1 or a Mid51 oligomerization mutant potentially associated with Parkinson’s disease prevents lysosomal untethering events, resulting in misregulated lysosomal network dynamics. In contrast, dominant optic atrophy–linked mutant Mid51, which does not inhibit Mid51/Fis1 coupled oligomerization, does not disrupt downstream lysosomal dynamics. As Fis1 conversely also regulates Mid51 oligomerization, our work further highlights an oligomeric Mid51/Fis1 mitochondrial complex that mechanistically couples together both Drp1 and Rab7 GTP hydrolysis machinery at mitochondria–lysosome contact sites. These findings have significant implications for organelle networks in cellular homeostasis and human disease.