Physiological and Biochemical Changes Associated with Cotton Fibre Development. IV. Glycosidases and {beta}-1,3-Glucanase Activities

Developing cotton fibre was analysed from 12 days post anthesis(DPA) till maturity for the activity of wall degrading enzymes,ß-galactosidase, ß-glucosidase, -mannosidaseand ß-1,3-glucanase. Each enzyme was estimated inthree different fractions namely cytoplasmic, ionically wall-boundand covalently wall-bound. There was a significant correlationbetween ß-galactosidase and ß-glucosidaseactivities in the covalently bound fraction, and the rate offibre elongation. Similarly, covalently bound ß-1,3-glucanaseactivity showed an increasing trend up to 18 DPA, i.e. aboutthe time when maximum rate of fibre elongation was achieved. The results presented here suggest that covalently wall-boundglycosidases may have an importafit role in cell wall loosening.Earlier reports providing evidence against the involvement ofthese enzymes in elongation growth in intact system, may perhapsbe due to scant attention paid to the subcellular distributionof these enzymes. Gossypium hirsutum, cotton fibre, glucanase, glycosidase, wall-loosening     

Inter‐specific gene flow dynamics during the Pleistocene‐dated speciation of forest‐dependent mosquitoes in Southeast Asia

Tropical forests have undergone repeated fragmentation and expansion during Pleistocene glacial and interglacial periods, respectively. The effects of this repeated forest fragmentation in driving vicariance in tropical taxa have been well studied. However, relatively little is known about how often this process results in allopatric speciation, since it may be inhibited by recurrent gene flow during repeated secondary contact, or to what extent Pleistocene‐dated speciation results from ecological specialization in the face of gene flow. Here, divergence times and gene flow between three closely‐related mosquito species of the Anopheles dirus species complex endemic to the forests of Southeast Asia, are inferred using coalescent based Bayesian analysis. An Isolation with Migration model is applied to sequences of two mitochondrial and three nuclear genes, and 11 microsatellites. The divergence of An. scanloni has occurred despite unidirectional nuclear gene flow from this species into An. dirus. The inferred asymmetric gene flow may result from the unique evolutionary adaptation of An. scanloni to limestone karst habitat, and therefore the fitness advantage of this species over An. dirus in regions of sympatry. Mitochondrial introgression has led to the complete replacement of An. dirus haplotypes with those of An. baimaii through a recent (～62 kya) selective sweep. Speciation of An. baimaii and An. dirus is inferred to have involved allopatric divergence throughout much of the Pleistocene. Secondary contact and bidirectional gene flow has occurred only within the last 100 000 years, by which time the process of allopatric speciation seems to have been largely completed.     

Optimization of ammonium acquisition and metabolism by potassium in rice (Oryza sativa L. cv. IR-72)

We present the first characterization of K⁺ optimization of N uptake and metabolism in an NH₄⁺‐tolerant species, tropical lowland rice (cv. IR‐72). ¹³N radiotracing showed that increased K⁺ supply reduces futile NH₄⁺ cycling at the plasma membrane, diminishing the excessive rates of both unidirectional influx and efflux. Pharmacological testing showed that low‐affinity NH₄⁺ influx may be mediated by both K⁺ and non‐selective cation channels. Suppression of NH₄⁺ influx by K⁺ occurred within minutes of increasing K⁺ supply. Increased K⁺ reduced free [NH₄⁺] in roots and shoots by 50–75%. Plant biomass was maximized on 10 mm NH₄⁺ and 5 mm K⁺, with growth 160% higher than 10 mm NO₃^‐‐grown plants, and 220% higher than plants grown at 10 mm NH₄⁺ and 0.1 mm K⁺. Unlike in NH₄⁺‐sensitive barley, growth optimization was not attributed to a reduced energy cost of futile NH₄⁺ cycling at the plasma membrane. Activities of the key enzymes glutamine synthetase and phosphoenolpyruvate carboxylase (PEPC) were strongly stimulated by elevated K⁺, mirroring plant growth and protein content. Improved plant performance through optimization of K⁺ and NH₄⁺ is likely to be of substantial agronomic significance in the world's foremost crop species.     

Geographical variation in AdhF and alcoholic resource utilization in Indian populations of Drosophila melanogaster

Indian geographical populations of Drosophila melanogaster, collected at latitude 10–32.3 ^oN, longitude 76.1–80.1 ^oE and altitude 16–2050 m, were analysed for changes in Adh ¹ frequency and utilization potential of diverse alcoholic resources. Until now, there have been limited data on climatic association of correlated changes on these aspects in continental populations of D. melanogaster. Indian populations demonstrate an increase in Adh ^F frequency by 0.04 per degree latitude and significantly higher utilization of ethanol (9.0–15.2%), acetic acid (8.1–12.5%), n-propanol (2.55-4.25%), 2-propanol (1.5-3.5%), n-butanol (2.15 3.5%) and 2-butanol (0.68-1.2%). Data also revealed significant correlation with latitude as well as altitude. Regression analysis of climatic data from collection sites confirmed the observed clinal variation of Adh ^F as well as alcoholic utilization in D. melanogaster. On the Indian subcontinent, variation in Adh ^F frequency and alcoholic resource utilization along increasing latitude as well as altitude are due to climatic selection factors such as temperature and rainfall.     

Nitrogen acquisition, PEP carboxylase, and cellular pH homeostasis: new views on old paradigms

The classic biochemical pH-stat model of cytosolic pH regulation in plant cells presupposes a pH-dependent biosynthesis and degradation of organic acids, specifically malic acid, in the cytosol. This model has been used to explain the higher tissue accumulation of organic acids in nitrate (NO₃^–)-grown, relative to ammonium (NH₄⁺)-grown, plants, the result of proposed cytosolic alkalinization by NO₃^– metabolism, and acidification by NH₄⁺ metabolism. Here, a critical examination of the model shows that its key assumptions are fundamentally problematic, particularly in the context of the effects on cellular pH of nitrogen source differences. Specifically, the model fails to account for proton transport accompanying inorganic nitrogen transport, which, if considered, renders the H⁺ production of combined transport and assimilation (although not the accumulation) to be equal for NO₃^– and NH₄⁺ as externally provided N sources. We show that the model's evidentiary basis in total-tissue mineral ion and organic acid analysis is not directly relevant to subcellular (cytosolic) pH homeostasis, while the analysis of the ionic components of the cytosol is relevant to this process. A literature analysis further shows that the assumed greater activity of the enzyme phosphoenolpyruvate (PEP) carboxylase under nitrate nutrition, which is a key characteristic of the biochemical pH-stat model as it applies to nitrogen source, is not borne out in numerous instances. We conclude that this model is not tenable in its current state, and propose an alternative model that reaffirms the anaplerotic role of PEP carboxylase within the context of N nutrition, in the production of carbon skeletons for amino acid synthesis.