Gametogenesis in Fundulus heteroclitus

Our present understanding of the structure of the gonads andof gametogenesis in Fundulus helerodilus is briefly reviewed. The testes contain spermatogenic tubules which distally arecomposed of linearly arranged germinal cysts with clones ofsynchronously developing germ cells, and proximally of efferentducts with mature sperm. Within the tubules, those cysts containingspermatogonia are found close to the testicular periphery, whereascysts with mature sperm are contiguous with the efferent ducts.Cytological details of the three principal stages of spermatogenesis,namely spermatocytogenesis, meiosis, and spermiogenesis, arepresented along with examples of the various somatic cells ofthe testis. The ovary consists of numerous ovigerous lamellae which containrandomly arranged follicles in various stages of development.Since follicular growth is asynchronous, follicles of all sizesare present in the ovary during the breeding season and eggsare continuously ovulated into the ovarian lumen. Oocyte growthis divided into five distinct stages: Primary growth (substagesA and B), cortical alveolus formation, vitellogenesis, oocytematuration (substages A and B), and the ovulated egg. This seriesof stages is based both on cytological observations and physiologicalevents.     

Nitrate Reductase in the Field Pea (Pisutn arvense L.)

The extraction and assay of a soluble, NADH-requiring nitratereductase is described. Induction of the enzyme by nitrate isdemonstrated in the roots and shoot of young seedlings and inthe leaves of older, nodulated plants grown without inorganicnitrogen. Induction occurs most readily in actively growingtissues. Studies with sterile cultures of excised roots confirmthe presence of an endogenous enzyme system within the root. Assays of the enzyme in vitro are combined with analyses offree nitrate and organic compounds of nitrogen in the bleedingsap. Either the root or shoot may act as the main centre forreduction of incoming nitrate. The extent to which these organsfunction is apparently influenced by environmental factors,particularly the level of nitrate in the rooting medium. Thediurnal rhythm of export of nitrogenous substances from theroot is correlated with observations on daily fluctuations inthe level of extractable enzyme in root and leaves. The activity of the enzyme is studied in different ages of leafof plants grown on a constant supply of nitrate. Assays suggestthat the enzyme is most active just as a leaf is fully expanded.Thereafter enzyme activity falls sharply, although small amountsof active enzyme may be recovered until a leaf becomes senescent.     

Simulation and Prediction of Plant Phenology for Five Crops Based on PhotoperiodxTemperature Interaction

This paper presents a plant phenological model based on genotypextemperaturexphotoperiodinteraction (GPTmodel). In the model, rate of development towardsa specified stage (e.g. flowering) for a given genotype is composedof three components: the genotype's maximum rate of development;any delay due to a non-optimal temperature; and any delay dueto a photoperiod response. It is assumed that development tothe specified stage is an autonomous process established bymost, if not all, genes other than the vernalization genes andthe photoperiod genes; and that this autonomous process is delayedby any activity of the photoperiod genes. Since all physiologicalprocesses are modulated by temperature, any photoperiod responseis inevitably a photoperiodxtemperature interaction. This interactionis simulated by assuming that the photoperiod gene activityoccurs only beyond a critical photoperiod (P_c) and is enlargedby temperature above a base temperature (T_bp) that allows thephotoperiod gene activity. The model is written asR=1/D_b-S_t(T-T_opt)²-S_p(T-T_bp)|P-P_c|, whereRis the expected rate of development to the specifiedstage under any combination of temperature (T) and photoperiod(P). The other model parameters are:S_p, the sensitivity to adelaying photoperiod;T_opt, the optimum temperature for developmentin the absence of the photoperiod response;S_t, the sensitivityto a non-optimum temperature; andD_b, the basic duration to thespecified stage (or intrinsic earliness), the inverse of whichis the maximum rate of development.D_bis observable only ifT=T_optandsimultaneouslyP