A conformational study of adenylyl-(3'',5'')-adenosine and adenylyl-(2'',5'')-adenosine in aqueous solution by carbon-13 magnetic resonance spectroscopy.

The solution conformation of adenylyl-(3',5')-adenosine and adenylyl-(2',5')-adenosine in both the stacked and unstacked states was studied by carbon-13 magnetic resonance spectroscopy. Large chemical shift differences between the base carbons in the dimers and those in the corresponding monomers are attributed in part to the influence of base-base interaction. Carbon-phosphorus couplings across three bonds revealed the preferred populations for certain backbone rotamers, demonstrating that significant changes in conformation about the "c(3')-O and C(5')-O bonds do not occur in the temperature or salt-induced unstacking of adenylyl-(3',5')-adenosine. However, rotations about the C(2')-O and C(5')-O bonds occur in the temperature-mediated unstacking of adenylyl-(2',5')-adenosine.     

The rapid labeling of adenosine triphosphate by 32P-labeled inorganic phosphate and the exchange of phosphate oxygens as related to conformational coupling in oxidative phosphorylation.

Evidence is presented that extends and amplifies the concept that in oxidative phosphorylation energy input serves to bring about release of ATP formed at a catalytic site by reversal of hydrolysis. The evidence with beef heart submitochondrial particles includes additional demonstration of uncoupler insensitive Pi leads to HOH exhchange, demonstration that this exchange is sensitive to the specific phosphorylation inhibitor, oligomycin, and demonstration that the small burst of uncoupler-insensitive ATP, rapidly labeled after addition of a tracer of 32Pi, behaves in a manner consistent with its participation as a membrane-bound intermediate in the Pi leads to HOH exchange. In addition, data are presented showing that addition of hexokinase plus glucose to submitochondrial particles in presence of ADP and Pi considerably lowers the Pi leads to HOH exchange but that further addition of cyanide or 2,4-dinitrophenol or both has little additional effect. Such data are compatible with no energy requirement for formation of bound ATP. However, with a large excess of hexokinase, the rate of the Pi leads to HOH exchange is further depressed. This could reflect some use of energy to promote formation of ATP at the catalytic site or to maintain the integrity of the phosphorylation system. Relationships of these findings to related information in the field are discussed.     

Hydrogen exchange in nucleosides and nucleotides. Measurement of hydrogen exchange by stopped-flow and ultraviolet difference spectroscopy.

Time-dependent changes in the ultraviolet absorbance of the adenine chromophore are observed in the stopped-flow spectrophotometer when adenosine and its analogs are rapidly transferred from protium oxide to deuterium oxide. These absorbance changes are shown to result from hydrogen exchange in the exocyclic amino groups of the purine ribonucleosides by using derivatives of adenosine in which methyl groups replace exchangeable hydrogens and by showing that the general characteristics of hydrogen exchange in adenosine analogs agree with those found here. A study of the dependence of hydrogen-exchange rate constants on adenosine, AMP, and phosphate concentration showed there is a second-order dependence on AMP concentration which is primarily due to intermolecular catalysis by the phosphate group of the nucleotide. The deuterium oxide perturbation difference spectrum, obtained at equilibrium, was found to contain two components that result from blue shifts of the adenine chromophore absorbance: (1) a shift cause by the substitution of deuterium for protium in the ring (N1) nitrogen and exocyclic nitrogens, and (2) a shift associated with a change in the polarizability of the medium. Since the theory of solvent perturbation, which is used to measure the relative "exposure" of chromophores in macromolecules, assumes that the spectral shifts observed are solely due to (2) above, the use of deuterium oxide as a measure of chromophore exposure to perturbants the size of water must be reexamined.     

A proton magnetic resonance investigation of the glycosyl torsion angle of uracil nucleosides and nucleotides.

The use of line-shape decomposition techniques permitted the small 5-bond (5-J51') and 4-bond (4-J61') proton-proton coupling constants of a series of uracil nucleosides and nucleotides to be determined accurately. From an analysis of these coupling constants we have determined that the uracil base is in a predominantly anti conformation in aqueous solution and the mean position is not substantially altered by phosphate substitution at the 2', 3', or 5' positions, by changing the furanose stereochemistry from a ribose to a deoxyribose or an arabinose, or by an increase in temperature of 43 degree C.     

Ataxin1L Is a Regulator of HSC Function Highlighting the Utility of Cross-Tissue Comparisons for Gene Discovery

Hematopoietic stem cells (HSCs) are rare quiescent cells that continuously replenish the cellular components of the peripheral blood. Observing that the ataxia-associated gene Ataxin-1-like (Atxn1L) was highly expressed in HSCs, we examined its role in HSC function through in vitro and in vivo assays. Mice lacking Atxn1L had greater numbers of HSCs that regenerated the blood more quickly than their wild-type counterparts. Molecular analyses indicated Atxn1L null HSCs had gene expression changes that regulate a program consistent with their higher level of proliferation, suggesting that Atxn1L is a novel regulator of HSC quiescence. To determine if additional brain-associated genes were candidates for hematologic regulation, we examined genes encoding proteins from autism- and ataxia-associated protein–protein interaction networks for their representation in hematopoietic cell populations. The interactomes were found to be highly enriched for proteins encoded by genes specifically expressed in HSCs relative to their differentiated progeny. Our data suggest a heretofore unappreciated similarity between regulatory modules in the brain and HSCs, offering a new strategy for novel gene discovery in both systems.     

Biology and Functional Ecology of Equisetum with Emphasis on the Giant Horsetails

Horsetails are unique survivors of a very ancient group of vascular plants, the Sphenophyta, which has a history reaching back to the Upper Devonian. Despite the striking conservatism of Equisetum architecture and anatomy and the small number of species (15) in the modern flora, their ability to thrive under a wide range of conditions is remarkable. This is due to a diverse suite of adaptations that allow tolerance of disturbance, soil anoxia, high metals, and salinity, along with efficient nutrient uptake and nitrogen fixation. The giant horsetails represent the largest living Sphenophyta and provide insights into how their larger ancestors lived and how this ancient lineage has managed to survive in tropical regions.     

Dormancy and germination: making every seed count in restoration

From 50 to 90% of wild plant species worldwide produce seeds that are dormant upon maturity, with specific dormancy traits driven by species' occurrence geography, growth form, and genetic factors. While dormancy is a beneficial adaptation for intact natural systems, it can limit plant recruitment in restoration scenarios because seeds may take several seasons to lose dormancy and consequently show low or erratic germination. During this time, seed predation, weed competition, soil erosion, and seed viability loss can lead to plant re‐establishment failure. Understanding and considering seed dormancy and germination traits in restoration planning are thus critical to ensuring effective seed management and seed use efficiency. There are five known dormancy classes (physiological, physical, combinational, morphological, and morphophysiological), each requiring specific cues to alleviate dormancy and enable germination. The dormancy status of a seed can be determined through a series of simple steps that account for initial seed quality and assess germination across a range of environmental conditions. In this article, we outline the steps of the dormancy classification process and the various corresponding methodologies for ex situ dormancy alleviation. We also highlight the importance of record‐keeping and reporting of seed accession information (e.g. geographic coordinates of the seed collection location, cleaning and quality information, storage conditions, and dormancy testing data) to ensure that these factors are adequately considered in restoration planning.