Uptake and metabolism of [3H]norepinephrine in the cerebral hemispheres of chick embryos

Abstract— The uptake and metabolism of [³H]norepinephrine were studied in slices of cerebral hemispheres removed from chick embryos at 10, 15 and 20 days of embryonic age, as well as from 90-day-old hens. Brain tissue from all age groups concentrated [³H]norepinephrine to much greater levels at 37°C than at 0°C. There was a marked increase in the rate of accumulation of [³H]norepinephrine in tissues from 10 to 15 days of embryonic age, with no further increase in the rate observed from 15 to 20 days of embryonic age. Tissue slices were incubated for 20 min with [³H]norepinephrine, and the deaminated metabolites of norepinephrine were separated by paper chromatography. In tissues from all age groups, the neutral metabolites were produced in greater amounts than the acid metabolites. A significant increase in the amounts of deaminated metabolites formed was observed in the period from 10 to 15 days of embryonic age and a significant decrease in the amounts formed was observed in the period from 15 to 20 days of embryonic age. The deamination at 20 days was very similar to that observed in the adult. A significant decrease in the level of the deaminated metabolites was noted in all age groups in response to cocaine (an inhibitor of neuronal uptake mechanisms), an observation suggesting that mechanisms for neuronal uptake of NE are functional by 10 days of embryonic development in the chick. However, a significant increase in the level of deaminated metabolites in response to reserpine (an inhibitor of uptake of NE into storage granules) was observed only in slices taken from 20-day embryos and from the 90-day-old hen. The effect in the hen was more prominent than in the 20-day embryo. These results were interpreted to indicate that mechanisms for the uptake of NE develop at an earlier embryonic age than mechanisms for the storage of NE and that mechanisms for storage continue to develop after hatching.     

Adverse effects of tempol on hidrosaline balance in rats with acute sodium overload

We studied the effects of tempol, an oxygen radical scavenger, on hydrosaline balance in rats with acute sodium overload. Male rats with free access to water were injected with isotonic (control group) or hypertonic saline solution (0.80 mol/l NaCl) either alone (Na group) or with tempol (Na-T group). Hydrosaline balance was determined during a 90 min experimental period. Protein expressions of aquaporin 1 (AQP1), aquaporin 2 (AQP2), angiotensin II (Ang II) and endothelial nitric oxide synthase (eNOS) were measured in renal tissue. Water intake, creatinine clearance, diuresis and natriuresis increased in the Na group. Under conditions of sodium overload, tempol increased plasma sodium and protein levels and increased diuresis, natriuresis and sodium excretion. Tempol also decreased water intake without affecting creatinine clearance. AQP1 and eNOS were increased and Ang II decreased in the renal cortex of the Na group, whereas AQP2 was increased in the renal medulla. Nonglycosylated AQP1 and eNOS were increased further in the renal cortex of the Na-T group, whereas AQP2 was decreased in the renal medulla and was localized mainly in the cell membrane. Moreover, p47-phox immunostaining was increased in the hypothalamus of Na group, and this increase was prevented by tempol. Our findings suggest that tempol causes hypernatremia after acute sodium overload by inhibiting the thirst mechanism and facilitating diuresis, despite increasing renal eNOS expression and natriuresis.     

A genetic analysis of dicentric minichromosomes in Saccharomyces cerevisiae

We have developed an assay in S. cerevisiae in which clones of cells that contain intact dicentric minichromosomes are visually distinct from those that have rearranged to monocentric minichromosomes. We find that the instability of dicentric minichromosomes is apparently due to mitotic nondisjunction accompanied by occasional structural rearrangements. Monocentric minichromosomes arising by rearrangement of the plasmid are rapidly selected in the population since dicentric minichromosomes depress the rate of cell division. We show that the ability of one centromere to compete with another in dicentric minichromosomes requires the presence of both of the conserved structural elements, CDE II and CDE III. Dicentric minichromosomes can be stabilized if one of the centromeres on the molecule is functionally hypomorphic because of mutations in CDE II even though these mutant centromeres are highly efficient in monocentric molecules. Stable dicentric molecules can also be produced by decreasing the space between two wild-type centromeres on the same molecule. These results suggest plausible pathways for changes in chromosome number that accompany evolution.     

Thermodynamic theory explains the temperature optima of soil microbial processes and high Q10 values at low temperatures

Our current understanding of the temperature response of biological processes in soil is based on the Arrhenius equation. This predicts an exponential increase in rate as temperature rises, whereas in the laboratory and in the field, there is always a clearly identifiable temperature optimum for all microbial processes. In the laboratory, this has been explained by denaturation of enzymes at higher temperatures, and in the field, the availability of substrates and water is often cited as critical factors. Recently, we have shown that temperature optima for enzymes and microbial growth occur in the absence of denaturation and that this is a consequence of the unusual heat capacity changes associated with enzymes. We have called this macromolecular rate theory – MMRT (Hobbs et al., 2013 , ACS Chem. Biol. 8:2388). Here, we apply MMRT to a wide range of literature data on the response of soil microbial processes to temperature with a focus on respiration but also including different soil enzyme activities, nitrogen and methane cycling. Our theory agrees closely with a wide range of experimental data and predicts temperature optima for these microbial processes. MMRT also predicted high relative temperature sensitivity (as assessed by Q₁₀ calculations) at low temperatures and that Q₁₀ declined as temperature increases in agreement with data synthesis from the literature. Declining Q₁₀ and temperature optima in soils are coherently explained by MMRT which is based on thermodynamics and heat capacity changes for enzyme‐catalysed rates. MMRT also provides a new perspective, and makes new predictions, regarding the absolute temperature sensitivity of ecosystems – a fundamental component of models for climate change.     

Culture of meristem tips and micropropagation of 12 commercial clones of poplar in vitro

Twelve commercial clones of poplar were cultured in vitro from meristem lips (0.3–0.5 mm diameter), shoot tips (4–6 mm long) and nodal segments (5–10 mm long). Shoot-producing cultures were obtained from 4, 32 and 70% of meristem lips, shoot tips and nodal segments within 12, 6 and 4 weeks, respectively. The genotype of cultures had a greater influence on development of shoot-producing cultures than medium composition. Cultivars Max/Ber and Oxford had the highest rates of establishment in culture and subsequent shoot proliferation, while P. tacamahaca, P. trichocarpa and cv. Robusta exhibited very low rates of establishment and low vigor in vitro. Shoot tip development was best on agar-solidified medium whereas liquid medium resulted in vitrification. Higher rates of axillary shoot production from established cultures were obtained with benzyladeninc or zeutin than with 2-isopen-tenyladenine. deducting the benzyladenine concentration from 4,4 to 1.1 μ M , increased the production of elongated shoots suitable for rooting.     

Mutations define cross-talk between the N-terminal nucleotide-binding domain and transmembrane helix-2 of the yeast multidrug transporter Pdr5: possible conservation of a signaling interface for coupling ATP hydrolysis to drug transport

The yeast Pdr5 multidrug transporter is an important member of the ATP-binding cassette superfamily of proteins. We describe a novel mutation (S558Y) in transmembrane helix 2 of Pdr5 identified in a screen for suppressors that eliminated Pdr5-mediated cycloheximide hyper-resistance. Nucleotides as well as transport substrates bind to the mutant Pdr5 with an affinity comparable with that for wild-type Pdr5. Wild-type and mutant Pdr5s show ATPase activity with comparable K(m)((ATP)) values. Nonetheless, drug sensitivity is equivalent in the mutant pdr5 and the pdr5 deletion. Finally, the transport substrate clotrimazole, which is a noncompetitive inhibitor of Pdr5 ATPase activity, has a minimal effect on ATP hydrolysis by the S558Y mutant. These results suggest that the drug sensitivity of the mutant Pdr5 is attributable to the uncoupling of NTPase activity and transport. We screened for amino acid alterations in the nucleotide-binding domains that would reverse the phenotypic effect of the S558Y mutation. A second-site mutation, N242K, located between the Walker A and signature motifs of the N-terminal nucleotide-binding domain, restores significant function. This region of the nucleotide-binding domain interacts with the transmembrane domains via the intracellular loop-1 (which connects transmembrane helices 2 and 3) in the crystal structure of Sav1866, a bacterial ATP-binding cassette drug transporter. These structural studies are supported by biochemical and genetic evidence presented here that interactions between transmembrane helix 2 and the nucleotide-binding domain, via the intracellular loop-1, may define at least part of the translocation pathway for coupling ATP hydrolysis to drug transport.     

A complete complementary DNA for the oncodevelopmental calcium-binding protein, oncomodulin

RNA from a rat liver tumor (Morris hepatoma 5123tc) was used to construct cDNAs together comprising the complete coding sequence of rat oncomodulin mRNA. Information obtained from these cDNAs as well as from primer extension analysis gave a deduced length for the complete oncomodulin mRNA of approximately 680 nucleotides (excluding the poly(A) tail) including a 5'-untranslated region of 97 +/- 2 nucleotides, a 324-nucleotide-coding sequence and a 259-nucleotide 3'-noncoding region. Comparison of the oncomodulin cDNA sequence with those coding for other members of the calcium-binding protein family shows little homology with the exception of a recently reported parvalbumin cDNA where the oncomodulin and parvalbumin nucleotide sequences are 59% identical in the protein-coding region. RNA blot analysis of poly(A+) RNA from normal adult rat liver gave no evidence of oncomodulin expression in this tissue. A single RNA species was detected, however, in RNA extracts from the hepatoma and from rat and human placentas. A probe prepared from one of the rat oncomodulin cDNAs hybridized with a single DNA species in restriction digests of hepatoma and normal DNA from rat and sequences in DNA of humans and other mammals. A 38-nucleotide sequence spanning the 5'-untranslated region and the first seven codons of the oncomodulin cDNA, was far less homologous than was the same region of a parvalbumin cDNA, to a chicken calmodulin cDNA sequence coding for the first calcium-binding domain. The oncomodulin gene appears to have diverged more from that of calmodulin than has the parvalbumin gene.     

Transmembrane helical interactions: zeta chain dimerization and functional association with the T cell antigen receptor.

Members of the zeta family of receptor subunits (zeta, eta and gamma) are structurally related proteins found as components of the T cell antigen receptor (TCR) and certain Fc receptors. These proteins share the ability to form disulfide-linked dimers with themselves and with other members of the family. Comparison of the amino acid sequences of zeta and gamma reveals a significant degree of homology, which is highest within their membrane-spanning domains. Analysis of their transmembrane sequences on a helical wheel projection suggests that all of the identical amino acids are clustered on one face of a potential alpha-helix. This face contains the only cysteine residue within zeta, suggesting that this conserved region may function to mediate dimerization. Indeed, replacing the transmembrane domain of the Tac antigen (alpha chain of the interleukin-2 receptor) by that of the zeta chain resulted in the formation of disulfide-linked dimers of Tac. The conserved aspartic acid residue found in the zeta and gamma transmembrane sequences was found to play a role in disulfide linkage. Replacing the aspartic acid with a lysine but not with an alanine or valine residue allowed formation of disulfide-linked dimers. The ability of the aspartic acid residue to support dimerization was dependent upon its position within the helix. Thus, these observations indicate that residues within the zeta transmembrane domain play a critical role in the formation of disulfide-linked dimers. Expression of zeta mutants in zeta-deficient T cells revealed that the zeta transmembrane domain is also responsible for reconstituting transport of functional TCR complexes to the cell surface and differentiated the requirements for disulfide-linked dimerization per se from assembly of the TCR complex.