Histone gene switch in the sea urchin embryo. Identification of late embryonic histone messenger ribonucleic acids and the control of their synthesis.

During embryogenesis in the sea urchin Strongylocentrotus purpuratus, there is a shift from one histone mRNA population to another. The early and late embryonic histone mRNAs, previously shown to differ considerably in sequence from each other by hybrid melting studies, are shown here to differ also in electrophoretic mobility on polyacrylamide gels as the positions of the early and late mRNAs are completely noncoincident. The various species of both early and late samples are identified as particular histone mRNAs by hybridization to cloned histone DNAs containing part of the early-type repeat unit or to restriction enzyme fragments derived from these unit. Four bands in the early mRNA sample are identified as H1, H3, H2A " H2B, and H4 mRNA while at least 10 bands can be seen in the late mRNA preparation with unambiguous identification of H1, H2B, and H4 mRNAs. A cluster of late species is shown to contain both H3 and H2A mRNA. When a polysomal RNA preparation from the 26-h embryo is hybridized to the histone DNA, eluted, and then translated in vitro in a wheat germ system, the histone products migrate in the position of late histones when subjected to electrophoresis on Triton X-urea gels. Using DNA which contains genes for H2A + H3 or H2A alone, we demonstrate the specificity of the early-type DNA probes for these two late histones. Therefore, by hybridization of newly synthesized RNAs and translation of the total polysomal RNA present in the late embryo, it is shown that mRNAs for all five histone classes may cross-react with the cloned early-type DNA. The hybrids formed, however, are much less stable than those formed with the early histone mRNA. In vitro translation of total cytoplasmic RNA from various embryonic stages indicates that transition between the two classes occurs during most of the blastula period.     

Human CDC6/Cdc18 Associates with Orc1 and Cyclin-cdk and Is Selectively Eliminated from the Nucleus at the Onset of S Phase

In a two-hybrid screen for proteins that interact with human PCNA, we identified and cloned a human protein (hCdc18) homologous to yeast CDC6/Cdc18 and human Orc1. Unlike yeast, in which the rapid and total destruction of CDC6/Cdc18 protein in S phase is a central feature of DNA replication, the total level of the human protein is unchanged throughout the cell cycle. Epitope-tagged protein is nuclear in G₁ and cytoplasmic in S-phase cells, suggesting that DNA replication may be regulated by either the translocation of this protein between the nucleus and the cytoplasm or the selective degradation of the protein in the nucleus. Mutation of the only nuclear localization signal of this protein does not alter its nuclear localization, implying that the protein is translocated to the nucleus through its association with other nuclear proteins. Rapid elimination of the nuclear pool of this protein after the onset of DNA replication and its association with human Orc1 protein and cyclin-cdks supports its identification as human CDC6/Cdc18 protein.     

Regulation of ethylene biosynthesis after short-term heat treatment in etiolated pea stems

Incubation of plant tissues at a constant elevated temperature greatly inhibits both basal and wound ethylene production. However, recovery from heat treatment is relatively rapid and is followed by stimulated ethylene production. The present investigation examines the kinetics of ethylene production after short-term heal treatment and the regulation of heat-altered ethylene production. Subapical stem segments of 7-day-old etiolated pea L. cv. Alaska) seedlings were analyzed for ethylene production, 1-aminocyclopropane-l-carboxylic acid (ACC) oxidation, and ACC and l-(malonylamino)cyclopropane-l-carboxylic acid (MACC) content after a 2-min 40°C heat pulse. The short-term heat pulse transiently inhibited ethylene production and ACC oxidation accompanied by a slight ACC accumulation within a 30-min time period. Conjugation to MACC did not appear to play an integral role in heat-regulated ethylene production. It was concluded that the major factor affecting ethylene production after heat treatment is the temporary inactivation of ACC oxidation. The possible roles of ACC synthase, ACC oxidase and lipoxygenase in regulating ethylene production after heat treatment are discussed.     

Effects of a lignin peroxidase-expressing recombinant, Streptomyces lividans TK23.1, on biogeochemical cycling and the numbers and activities of microorganisms in soil.

A recombinant actinomycete, Streptomyces lividans TK23.1, expressing a pIJ702-encoded extracellular lignin peroxidase gene cloned from the chromosome of Streptomyces viridosporus T7A, was released into soil in flask- and microcosm-scale studies to determine its effects on humification and elemental cycling and on the numbers, types, and activities of microorganisms native to the soil. Strain TK23.1 had been shown previously to transiently increase the rate of organic carbon mineralization in soil via an effect that was recombinant specific and particularly significant in nonsterile soils already possessing an active microflora. The results of this study confirmed the previous findings and showed that additional effects were measurable upon release of the recombinant strain TK23.1 into unamended soil and into soil amended with lignocellulose. In addition to a transient enhancement of carbon mineralization, the recombinant affected soil pH, the rate of incorporation of carbon into soil humus fractions, nitrogen cycling, the relative populations of some microbial groups, and also certain soil enzyme activities. Whereas the survival or persistence in soil of the recombinant TK23.1 strain and that of its parent, TK23, were similar, the observed effects on microbial numbers, types, and activities were recombinant specific and did not occur when the parental strain was released into soil. All of the measured effects were transient, generally lasting for only a few days. While the effects were statistically significant, their ecological significance appears to be minimal. This is the first report showing that a recombinant actinomycete can affect the microbial ecology of soil in ways that can be readily monitored by using a battery of microbiological, enzymological, and chemical assays.     

Assessing the role of fine roots in carbon and nutrient cycling

Fine roots remain one of the most difficult and important areas to study in terrestrial ecosystems. Recent investigations have focused on carbon and nitrogen balances to assess their dynamics in natural systems. The results of these new, system-level, budgeting approaches together with those of the more conventional biomass measurement methods may provide valuable insight into fine root carbon and nutrient cycling dynamics. These findings, in turn, may facilitate a more holistic understanding of ecosystem structure and function, which is critical for the assessment and prediction of disturbances to terrestrial systems.     

G1 cyclin degradation: the PEST motif of yeast Cln2 is necessary, but not sufficient, for rapid protein turnover.

The 545-residue Cln2 protein, like the other G1 cyclins of Saccharomyces cerevisiae, is a very unstable protein. This instability is thought to play a critical role in regulating cell cycle progression. The carboxyl-terminal domains of Cln2 and the other G1 cyclins contain sequences rich in Pro, Glu (and Asp), Ser, and Thr (so-called PEST motifs) that have been postulated to make up the signals that are responsible for the rapid degradation of these and other unstable proteins. To test this hypothesis, the carboxyl-terminal 178 residues of Cln2 were fused to the C terminus of a reporter enzyme, a truncated form of human thymidine kinase (hTK delta 40). The resulting chimeric protein (hTK delta 40-Cln2) retained thymidine kinase activity but was markedly less stable than hTK, hTK delta 40, or an hTK-beta-galactosidase fusion protein, as judged by enzyme assay, immunoblotting with anti-hTK antibodies, pulse-chase analysis of the radiolabeled polypeptides, and ability to support the growth of a thymidylate auxotroph (cdc21 mutant) on thymidine-containing medium. Thus, the presence of the Cln2 PEST domain was sufficient to destabilize a heterologous protein. Furthermore, the half-life of hTK delta 40-Cln2 was similar to that of authentic Cln2, and the rate of degradation of neither protein was detectably enhanced by treatments known to cause G1 arrest, including exposure of MATa haploids to alpha-factor mating pheromone and shifting cdc28ts and cdc34ts mutants to the restrictive temperature. These results suggest that the major signals responsible for Cln2 instability are confined to its C-terminal third. Because hTK delta 40-Cln2 and Cln2 were expressed from heterologous promoters yet their half-lives both in asynchronous cultures and when arrested at various cell cycle stages were always similar, the Cln2 PEST domain contains a signal for rapid protein turnover that is constitutively active and operative throughout the cell cycle. Removal of the 37 codons that encode the most prominent PEST-like segment from either hTK delta 40-Cln2 or Cln2 decreased the turnover rate of the resulting proteins, as expected; however, an hTK delta 40 chimera containing only this 37-residue segment was not detectably destabilized, suggesting that this PEST sequence, when removed from its normal context, is not a self-contained determinant of protein instability.     

Differential activation within costal diaphragm during rapid-eye-movement sleep in cats

Simultaneous recordings of the diaphragmatic electromyogram (EMG) were made from two separate regions of the costal diaphragm in six normal cats. The diaphragmatic activities were always synchronous and the amplitudes and rates of rise were similar during slow-wave sleep. In contrast, during natural rapid-eye-movement (REM) sleep, different activity was often present in the two leads. These differences were in the time of onset and offset, as well as in the amplitude and spike patterns, and occurred in approximately 5-20% of the diaphragmatic bursts averaged over the entire REM sleep period. With respect to eye movement density, the rate of differential activation was higher during periods of high density (26%) than in the absence of eye movements (1%) in the four animals for which these data were available. Differential activation of portions of the costal diaphragm is apparently a normal event of REM sleep. This could result from descending state-specific phasic neuronal activity that bypasses the medullary respiratory generator. Differential activation of portions of the diaphragm could contribute to disordered ventilation during REM sleep.     

A method for constraining the age of origination of derived characters

Fossils are the physical records of the history of morphological character evolution on Earth and can provide valuable information concerning the sequence and timing of origination of derived characters. Knowledge of the timing of origination of synapomorphies makes it possible to estimate when unobserved character changes occurred in the geological past. Here we present a method for estimating the temporal interval during which synapomorphies evolved. The method requires either direct inclusion of fossil taxa (with or without extant taxa) in cladistic analyses based on morphological or combined data, or indirectly using the “molecular scaffold approach.” Second, characters of interest are mapped on a most parsimonious tree and “minimum age node mapping” is used to place minimum ages on the nodes of the tree. Finally, characters of interest are evaluated for younger and/or older temporal constraints on the time of their origination; application of the older bound assumes ancestry of fossil terminals included in the tree. A key is provided herein describing the method. Among other applications, this approach has the potential to provide a powerful test of purported evolutionary cause–effect relationships. For example, the method has the ability to discover that derived characters of suggested adaptational significance may considerably pre‐date the cause(s) that are hypothesized to have favored their establishment. © The Willi Hennig Society 2007.     

The unusual macrocycle forming thioesterase of mycolactone

Mycolactone is a polyketide natural product secreted by Mycobacterium ulcerans, the organism responsible for the tropical skin disease Buruli ulcer. The finding that this small molecule virulence factor is sufficient to reconstitute the necrotic pathology associated with Buruli ulcer suggests that a better understanding of mycolactone biosynthesis, particularly the processes which are distinct from those in human metabolism, may provide a unique avenue for the development of selective therapeutics. In the present study we have cloned, expressed, and biochemically characterized the putative macrocycle forming thioesterase for mycolactone, MLSA2 TE. We have evaluated the enzyme both as the truncated thioesterase domain and as a carrier protein-linked didomain construct. The results of these analyses distinguish MLSA2 TE from traditional fatty acid and polyketide synthase TE-domains in terms of its sequence, kinetic parameters, and susceptibility to traditional active-site directed inhibitors. These findings suggest that MLSA2 TE utilizes a unique biochemical mechanism for macrocycle formation.