Meeusella and the origin of stamens

Meeusella gen. nov. is a strobilate pollen organ from the Lower Cretaceous of Transbaikalie (east of the Lake Baikal); the branched lateral branches (paracladia), if fully developed, bear a subterminal pair of stalked synangial heads. In some cases the latter are reduced to a pair of sessile heads or the paracladia are sterile. It is suggested that the synangial heads might be further reduced to a pair of bisporangiate thecae, while the paracladium apex between them might form a prominent connective of a typical stamen. ▭ Androecium, androclade, angiosperms, proangiesperms, stamen, evolutionary morphology.     

A Carbon-balance Model of Stand Growth: a Derivation Employing Pipe-model Theory and the Self-thinning Rule

A carbon-balance model of the growth of an even-aged, self-thinning,mono-specific stand of trees is derived using a structural frameworkbased on pipe-model theory. Within the pipe-model framework,dry matter arising from extension of roots and shoots is separablefrom that arising from the cross-sectional expansion of stems.This permits the derivation of models describing the growthof average stem length, total basal area, and total volume ofthe stand. Variations of these models are described for twosituations: (1) where the annual rates of substrate productionand feeder-root turnover can be assumed constant over time;and (2) where these rates are expected to change over time,such as in polluted environments. The model describing the growthof stand volume for the first situation fits published yieldtables. Growth-rate models applicable to individual trees arealso described. Carbon-balance model, dry-matter partitioning, pipe-model theory, stand growth, self-thinning     

Hydrogen isotope fractionation during H2/CO2 acetogenesis: hydrogen utilization efficiency and the origin of lipid-bound hydrogen

Hydrogen metabolism was studied in the anaerobic bacterium, Sporomusa sp. strain DMG 58, by measuring natural abundance levels of deuterium in H₂, H₂O, and individual fatty acids during acetogenic growth on H₂/CO₂. Four cultures were grown, each in medium with a distinct hydrogen‐isotopic composition (δD‐H₂O). The δD value of H₂ was quantified in the residual gas exiting the growth chambers and found to decrease concurrently with net H₂ consumption, indicating rapid isotope exchange between H₂ and H₂O. An isotopic mass balance was used to constrain the efficiency with which H₂ was activated by the cell and the reducing equivalents catabolized, which we term the H₂ utilization efficiency. Results indicate that H₂ utilization efficiency in these cultures is less than 20% during the growth phase, and less than 2% after the growth phase. The gross rate of cellular H₂ activation was similar in the growth phase and afterward. Biomass harvested at the end of each experiment was used to analyse the D/H of individual membrane lipids. Values of δD were highly correlated between lipids and water (δD‐lipids = 0.59 × δD‐water – 381‰; R² = 0.995), indicating the source of lipid hydrogen is in isotopic equilibrium with water. Results are consistent with two possibilities: (i) water is the sole source of hydrogen to lipids, and the fractionation during biosynthesis is significantly larger than previously observed (α = 0.59), or (ii) hydrogen from H₂ is incorporated into lipids, but only after reaching isotopic equilibrium with H₂O. Fatty acids were strongly depleted in deuterium relative to all other organisms studied thus far, and such large depletions may prove useful as biomarkers for studying H₂ cycling in anoxic environments as well as in the geological record.