Spiral growth in the radially-expanding piloboloid mutants ofPhycomyces blakesleeanus

The growth zone of the sporangiophore of a piloboloid mutant,pil, ofPhycomyces expands radially at an increased rate until the growth zone becomes nearly spherical, in sharp contrast to that of the wild-type sporangiophore which exhibits longitudinal elongation only and is conical. The rotation of thepil sporangiophore reverses its direction from clockwise (CW) to counterclockwise (CCW) during the period of increased radial expansion, and the CCW rotation continues as long as does the radial expansion. The direction of rotation and the time of reversal are correlated with the relative rates of cell-wall expansion in the longitudinal and transverse directions. The CCW rotation of the sporangiophore of this mutant can be explained by the behavior of the microfibrils, as previously proposed to explain the rotation of the wild-type sporangiophore.Abbreviations CW clockwise - CCW counterclockwise — both as viewed from above     

Negative phototropism in the piloboloid mutants of Phycomyces blakesleeanus Bgff.

The sporangiophore (spph) of a piloboloid mutant, genotype pil, of Phycomyces ceases elongation and expands radially in the growth zone shortly after reaching the developmental stage IV b. The pil spph is always negatively phototropic to unilateral visible light when its diameter exceeds 210 m. Photoinduction of spph initiation, light-growth response, threshold of light energy fluence rate for the negative phototropism, avoidance and gravitropism in the pil mutant are all normal. In liquid paraffin, the pil spph shows negative phototropism as does the wild-type spph. Genetic analyses indicate that the negative phototropism of the pil mutant is governed by the phenotypic characteristics of pil but not by specific gene(s) responsible for negative phototropism. These facts imply that the reverse phototropism of the pil mutant results from a loss of the convergent lens effect of the cell because of the increase in cell diameter.Abbreviations spph(s) sporangiophore(s) - wt(s) wild type(s)     

TEMPERATURE AND IRRADIANCE EFFECTS ON GROWTH OF PITHOPHORA OEDOGONIA (CHLOROPHYCEAE) AND SPIROGYRA SP. (CHAROPHYCEAE)1

Growth responses of Pithophora oedogonia (Mont.) Wittr. and Spirogyra sp. to nine combinations of temperature (15°, 25°, and 35°C) and photon flux rate (50, 100, and 500 μmol·m^?2·s^?1) were determined using a three-factorial design. Maximum growth rates were measured at 35°C and 500 pmol·m^?2·s^?1 for P. oedogonia (0.247 d^?1) and 25°C and 500 μmol·m^?2·s^?1 for Spirogyra sp. (0.224 d^?1). Growth rates of P. oedogonia were strongly inhibited at 15°C (average decrease= 89%of maximum rate), indicating that this species is warm stenothermal. Growth rates of Spirogyra sp. were only moderately inhibited at 15° and 35°C (average decrease = 36 and 30%, respectively), suggesting that this species is eurythermal over the temperature range employed. Photon flux rate had a greater influence on growth of Spirogyra sp. (31% reduction at 50 pmol·m^?2·s^?1 and 25°C) than it did on growth of P. oedogonia (16% reduction at 50 μmol·m^?2·s^?1 and 35°C). Spirogyra sp. also exhibited much greater adjustments to its content of chlorophyll a (0.22–3.34 μg·mg fwt^?1) than did P. oedogonia (1.35–3.08 μg·mg fwt^?1). The chlorophyll a content of Spirogyra sp. increased in response to both reductions in photon flux rate and high temperatures (35°C). Observed species differences are discussed with respect to in situ patterns of seasonal abundance in Surrey Lake, Indiana, the effect of algal mat anatomy on the internal light environment, and the process of acclimation to changes in temperature and irradiance conditions.     

A multicopy suppressor ofnin1-1 of the yeastSaccharomyces cerevisiae is a counterpart of theDrosophila melanogaster diphenol oxidase A2 gene,Dox-A2

NIN1 is an essential gene for growth of the yeastSaccharomyces cerevisiae and was recently found to encode a component of the regulatory subunit of the 26S proteasome. Thenin1-1 mutant is temperature sensitive and its main defect is in G₁/S progression and G₂/M progression at non-permissive temperatures. One of the two multicopy suppressors ofnin1-1, SUN2 (SUppressor of Nin1-1), was found to encode a protein of 523 amino acids whose sequence is similar to those ofDrosophila melanogaster diphenol oxidase A2 and the mouse mast-cell Tum^? transplantation antigen, P91A. The C-terminal half of Sun2p was found to be functional as Sun2p at 25° C, 30° C, and 34° C but not at 37° C. The open reading frame (ORF) of theDrosophila diphenol oxidase A2 gene (Dox-A2) was obtained from a lambda phage cDNA library using the polymerase chain reaction technique. TheDox-A2 ORF driven by theTDH3 promoter complemented the phenotype of a strain deleted forsun2. ThisDox-A2-dependent strain was temperature sensitive and accumulated dumb-bell-shaped cells, with an undivided nucleus at the isthmus, after temperature upshift. This morphology is similar to that ofnin1-1 cells kept at a restrictive temperature. These results suggest thatSUN2 is a functional counterpart ofDox-A2 and that these genes play a pivotal role in the cell cycle in each organism.     

A cold-sensitive mutant ofNeurospora crassa obtained using tritium-suicide enrichment that is conditionally defective in the biosynthesis of cytoplasmic ribosomes

The purpose of this investigation was to use tritium-suicide enrichment with a mutagenized population of wild-typeNeurospora crassa to isolate cold-sensitive mutants with conditional defects in the production of cytoplasmic ribosomes. Eighty-six cold-sensitive mutant strains were obtained following tritium-suicide enrichment using [5-³H]uridine. Zone sedimentation analysis of cytoplasmic ribosomes produced by the strains at 10°C (the nonpermissive temperature) indicated that one strain,PJ31562, is defective in the accumulation of ribosomal subunits at that temperature. The properties of strainPJ31562 are: (1) At 10°C the growth rate is 28 times slower than at 25°C, whereas the factor for the wild type is 5.1. At 25°C the mutant's growth rate is 90% that of the wild type. (2) At 10°C the mutant accumulates the two ribosomal subunits, 60 and 37 S, in markedly disproportionate amounts apparently as a result of the underproduction of, or an instability of, the 17 S ribosomal RNA component of the small ribosomal subunit. At 25°C the mutant strain still exhibits a disproportionality in ribosomal subunit accumulation but to a much lesser degree than at 10°C. (3) Genetic studies have shown that a single nuclear gene is responsible for both the cold sensitivity and ribosome biosynthesis defect of strainPJ31562. The mutation involved is located in linkage group IV and appears to be closely linked to, and not allelic with, the cold-sensitive mutation carried by strainPJ30201 which has been shown previously to exhibit a similar phenotype with respect to ribosomal subunit accumulation, and which defines thecrib-1 locus. Thus tritium-suicide enrichment can be used to isolate cold-sensitive mutants ofNeurospora among which a relatively low frequency have conditional defects in ribosome production.     

The effect of temperature on the growth,development and survival of Macropetasma africanus (Balss) (Penaeoidea:Penaeidae) larvae reared in the laboratory

Macropetasma africanus (Balss) has been successfully spawned and its larvae reared under controlled laboratory conditions. The relationship between egg number (E) and female total length (L) was E = 18.59 L^2.11. An experiment was designed to test the effect of temperature on larval development, survival and growth. Temperature effected larval development time, from 13–15 days at 25°C, to 25 days at 15°C (nauplius 1 to post-larva). Mortality was low for the naupliar stages at 25, 22 and 18°C, while at 15°C only 52% of the larvae reached nauplius 6. Mortality was highest from nauplius 6 to protozoea 1 (17, 21, and 18% at 25, 22, and 18°C, respectively), but decreased considerably for all temperatures once the mysis stage was reached. Overall survival rates from nauplius 1 to post-larva decreased with decreasing temperature (65, 54, 48, and 39% at 25, 22, 18, and 15°C respectively). Temperature also significantly affected larval growth. At 25°C mean total length was significantly (P < 0.05) larger than at 15°C (protozoea 2 to post-larva), while from protozoea 3 to post-larva total length differences were significantly different (P < 0.05) between 18 and 25°C. M. africanus has a major spawning peak in summer, suggesting that there may be a selective advantage to reproducing during the warmer months.     

Subject index vol. 70 (1980)

Antibiotic-resistant (either to erythromycin or chloramphenicol) temperature-sensitive mutants were isolated with about the same frequency in 2 strains of the petite negative yeast K. lactis.The ery^R and cap^R mutants isolated in the strain K. lactis CBS 2359 showed with high frequency both a lethal-conditioned (lc) or a petite temperature-sensitive (pts) phenotype, whereas amongst the many ery^R and cap^R mutants isolated in the strain K. lactis CBS 2360 only lc phenotypes appeared. In the mutants isolated from K. lactis CBS 2360, one growth cycle in the presence of ethidium bromide irreversibly blocked the transmission of antibiotic resistance and temperature sensitivity (lc and pts), whereas at least 2 growth cycles were required to give the same results for the mutants isolated in K. lactis CBS 2359.The spontaneous reversion frequencies for the temperature sensitivity were about the same for the lc mutants isolated in the 2 strains, but the frequencies of co-reversion of the antibiotic resistance were higher in ery^Rlc and cap^Rlc mutants isolated from K. lactis CBS 2360.The analysis of the effect of the exposure to erythromycin or to the temperature of 36°C on protein synthesis carried out by isolated mitochondria of 2 ery^Rlc mutants of K. lactis CBS 2360 and CBS 2359 showed that, in these mutants, mitochondrial protein synthesis became resistant to the drug and sensitive to temperature. The exposure at 36°C, before protein synthesis was inactived, determined in these mutants a condition of sensitivity to the antibiotic, suggesting that even though the 2 K. lactis strains differ in some aspects concerning the behaviour of their mitochondrial information they might depend, as to their petite-negative character, on the role that mitochondrial protein synthesis has in cell division.     

Engineering the thermostability of a xylanase from Aspergillus oryzae by an enhancement of the interactions between the N-terminus extension and the β-sheet A2 of the enzyme

A mesophilic Aspergillus oryzae xylanase (AoXyn11A) belongs to glycoside hydrolase family 11. Hydrogen bonds and a disulfide bridge were introduced between the N-terminus extension and the β-sheet A2 of AoXyn11A, which were located in the corresponding region of a hyperthermostable xylanase. The mutants were designated as AoXyn11A^C5 and AoXyn11A^C5–C32, respectively. The thermostabilities of AoXyn11A and the mutants were assessed by the molecular dynamics simulations. After being incubated at 55 °C for 30 min, AoXyn11A^C5–C32 retained 49 % of its original activity, AoXyn11A^C5 retained 12 % and AoXyn11A retained 3 %. The interactions between the N-terminus extension and the β-sheet A2 were analyzed in depth: there was enhancement of the interactions between the N-terminus extension and the β-sheet A2 of AoXyn11A that improved its thermostability.     

Evidence for the involvement of unsaturated fatty acids in initiating chromosome replication in Escherichia coli

The analogue 3-decynoyl-N-acetylcysteamine inhibits the synthesis of unsaturated fatty acids in Escherichia coli, resulting in the accumulation of saturated fatty acids in the membrane (Kass, 1968).In the presence of this analogue, DNA, RNA and protein synthesis continue at a linear rate for approximately two doubling times, and then cease. On the other hand, the analogue will inhibit the formation of new replication forks (premature initiation), which normally arise as a result of thymine starvation.Unlike other temperature-sensitive DNA mutants, mutants that are defective in initiating DNA replication (dnaA or dnaC) are unable to replicate DNA at a permissive temperature if they terminate replication at 42 °C in the presence of 3-decynoyl-N-acetylcysteamine.When replication is terminated at 42 °C, cultures of dnaA or dnaC mutants normally will reinitiate replication upon lowering the temperature to 30 °C. For each mutant this reinitiation is characterized by a particular temperature sensitivity. Such mutants become more temperature sensitive if the temperature is lowered in the presence of 3-decynoyl-N-acetylcysteamine. All the effects of this analogue can be reversed by the addition of unsaturated fatty acids.These results are interpreted using a model in which replication is initiated at a particular lipid site on the membrane. In the absence of unsaturated fatty acids functional lipid sites are not made. Functional sites, however, can be used again provided they are not inactivated by interaction with an inactive dnaA or dnaC product.     

Optimization of cultivation conditions for fatty acid composition and EPA production in the eustigmatophycean microalga Trachydiscus minutus

We determined the effects of cultivation conditions (nitrogen source, salinity, light intensity, temperature) on the composition of polyunsaturated fatty acids (PUFAs) and the production of eicosapentaenoic acid (EPA) in the laboratory cultured eustigmatophycean microalga, Trachydiscus minutus. T. minutus was capable of utilizing all nitrogen compounds tested (potassium nitrate, urea, ammonium nitrate, ammonium carbonate) with no differences in growth and only minor differences in fatty acid (FA) compositions. Ammonium carbonate was the least appropriate for lipid content and EPA production, while urea was as suitable as nitrates. Salinity (0.2 % NaCl) slightly stimulated EPA content and inhibited growth. Increasing salinity had a marked inhibitory effect on growth and PUFA composition; salinity at or above 0.8 % NaCl was lethal. Both light intensity and temperature had a distinct effect on growth and FA composition. The microalga grew best at light intensities of 470–1,070 μmol photons m^?2 s^?1 compared to 100 μmol photons m^?2 s^?1, and at 28 °C; sub-optimal temperatures (20, 33 °C) strongly inhibited growth. Saturated fatty acids increased with light intensity and temperature, whereas the reverse trend was found for PUFAs. Although the highest level of EPA (as a proportion of total FAs) was achieved at a light intensity of 100 μmol photons m^?2 s^?1 (51.1?± 2.8 %) and a temperature of 20 °C (50.9?±?0.8 %), the highest EPA productivity of about 30 mg L^?1?day^?1 was found in microalgae grown at higher light intensities, at 28 °C. Overall, for overproduction of EPA in microalgae, we propose that outdoor cultivation be used under conditions of a temperate climatic zone in summer, using urea as a nitrogen source.     

Maize growth and developmental responses to temperature and ultraviolet-B radiation interaction

Plant response to the combination of two or more abiotic stresses is different than its response to the same stresses singly. The response of maize (Zea mays L.) photosynthesis, growth, and development processes were examined under sunlit plant growth chambers at three levels of each day/night temperatures (24/16°C, 30/22°C, and 36/28°C) and UV-B radiation levels (0, 5, and 10 kJ m^?2 d^?1) and their interaction from 4 d after emergence to 43 d. An increase in plant height, leaf area, node number, and dry mass was observed as temperature increased. However, UV-B radiation negatively affected these processes by reducing the rates of stem elongation, leaf area expansion, and biomass accumulation. UV-B radiation affected leaf photosynthesis mostly at early stage of growth and tended to be temperature-dependent. For instance, UV-B radiation caused 3–15% decrease of photosynthetic rate (P _N) on the uppermost, fully expanded leaves at 24/16°C and 36/28°C, but stimulated P _N about 5–18% at 30/22°C temperature. Moreover, the observed UV-B protection mechanisms, such as accumulation of phenolics and waxes, exhibited a significant interaction among the treatments where these compounds were relatively less responsive (phenolics) or more responsive (waxes) to UV-B radiation at higher temperature treatments or vice versa. Plants exposed to UV-B radiation produced more leaf waxes except at 24/16°C treatment. The detrimental effect of UV-B radiation was greater on plant growth compared to the photosynthetic processes. Results suggest that maize growth and development, especially stem elongation, is highly sensitive to current and projected UV-B radiation levels, and temperature plays an important role in the magnitude and direction of the UV-B mediated responses.     

The growth of four species of Azolla as affected by temperature

The growth of 22 strains of Azolla pinnata R. Br., 3 strains of A. filiculoides Lam. and one strain each of A. mexicana Presl and A. caroliniana Willd. was tested separately in liquid culture media kept in controlled, artificial light (30 klux) growth cabinets. Three temperature levels were used: 33°C (37/29°C day/night), 29°C (33/25°C) and 22°C (26/18°C)/ Photoperiod was 12 h a day.For most A. pinnata strains (except three) and an A. mexicana strain the maximum weekly relative growth rate was higher at 33°C than at 22°C, but not for A. filiculoides and A. caroliniana. The highest value of maximum relative growth rate corresponded to 1.9 doubling days and in most strains this occurred in the first week. As the plants grew, the growth rate slowed down more severely at higher temperatures. The maximum biomass was higher at 22°C than at 33°C in all strains. At 22°C, it took 30–50 days to attain maximum biomass and the highest value was 14 g N m^?2 or 320 g dry m^?2 by A. caroliniana, followed by 12 g N m^?2 or 290 g dry wt. m^?2 by one strain of A. filiculoides. At 29°C, the maximum biomass was attained in 20–35 days. The highest value was 6.3 g N m^?2 or 154 g dry wt. m^?2 by A. caroliniana. At 33°C, most A. pinnata strains gave a maximum biomass of less than 4 g N m^?2 after 13–23 days, while some strains grew up to 30 days, resulting in a higher maximum biomass. The highest maximum biomass at 33°C was 5.5 g N m^?2 or 140 g m^?2 dry wt. by A. pinnata from Cheng Mai while the maximum biomass of A. filiculoides and A. caroliniana was much less. Azolla filiculoides requires lower temperature than other species for its growth. Azolla pinnata has the best tolerance to high temperatures among the four species. Azolla mexicana could not be discriminated from A. pinnata in its response to temperature. Azolla caroliniana may keep an intermediate position between A. filiculoides and A. pinnata in temperature response.The formation of ammonia in the medium was examined and it occurred mostly under stationary growth conditions, but, at 33°C, some strains of A. pinnata and A. mexicana released or formed ammonia at 0.3–0.8 μg N ml^?1 per week during their initial exponential growth stage.     

Experimentelle Untersuchungen zum Stockwachstum und zur Medusenbildung bei dem marinen HydrozoonEirene viridula

The development of both slide-grown and non-substrate bound colonies ofE. viridula (Thecata-Leptomedusae) ranging in size from 1 to 50 hydranths was investigated under various temperature conditions. The majority of slide-grown colonies reached a larger final size than non-substrate bound ones, in 20°, 25° and 29° C. Raising the temperature did not stimulate propagation of hydranths as expected. Most of the colonies transferred to 25° or 29° C finally were even smaller than those reared at 20° C. This was partially due to resorption of several hydranths about 9 days after the temperature rise; the influence of “physiological competition” between development of new hydranths and budding of medusae on colony growth is discussed. Transfer from higher to lower temperatures affected colony growth negatively. Raising the temperature from 20° to 25° or 29° C initiated formation of gonozooids from the distal part of hydranth stalks and development of medusa buds in both types of colonies. With the exception of slide-grown colonies transferred to 25° C, also young medusae were budded off. There was a remarkable coincidence in predominance of colony growth in slide-grown colonies and of medusa budding in non-substrate bound cultures. In the latter, medusa buds developed 1 to 2 days earlier. Most buds did not differentiate into liberated medusae, but were resorbed. Transformation of medusa buds into hydranths was not observed. In the clone ofE. viridula, onset of medusa budding did not depend on a “minimal colony size”. Even single hydranths were able to produce medusa buds after transfer to higher temperatures; budded off medusae were recorded from non-substrate bound colonies with an initial size of 3 hydranths. In slide-grown cultures, medusa buds developed into colonies with an initial size of only 3 hydranths. No hydranth propagation prior to medusa budding occurred in these cases. After raising temperature from 25° to 29° C medusa buds were observed in nonsubstrate bound colonies only; a small number of medusae were budded off from some of these colonies. Lowering the temperature from 29° or 25° to 20° C caused resorption of existing medusa buds. In several non-substrate bound colonies, transfer from 29° to 25° C induced development of gonozooids with medusa buds and, in some cases, of young medusae. Incubation with the alkylating cytostaticTrenimon and transfer from 20° to 25° C caused irreversible resorption of all hydranths when 4 × 10^?2 mg/ml were administered for 10 mins. Thereafter, only development of stolonial structures was observed. With one exception, the colonies treated with 4 × 10^?3 mg/ml, and all others submitted to 4 × 10^?4 mgTrenimon/ml were able to produce new hydranths and also medusa buds; some of the colonies first had to overcome a degressive phase. Treatment with 4 × 10^?2 mg destroyed all interstitial cells (I-cells). Incubation with 1 × 10^?3 or 1 × 10^?4 mg/ml left the I-cells at least partially intact. It is concluded that I-cells are indispensable for hydranth and medusan morphogenesis inE. viridula.     

Low Root Temperature Retardation of the Mineral Nitrogen Induced Decline in N2Fixation by a Northern Ecotype of White Clover

Nodulated white clover plants (Trifolium repensL.) of a Norwegian ecotype from Pasvik (70°N) were grown in flowing solution culture. Root temperature was 17°C until 51d after sowing, when it was lowered decrementally over 5d to 7°C in four of the eight plant culture units. After a further 24h, mineral N was supplied automatically at 20μMNH₄NO₃in three culture units at each root temperature (7 and 17°C) over 17d. The remaining two units provided control plants solely dependent on N₂fixation at 7 and 17°C.The supply of NH₄NO₃greatly reduced the nodule biomass per plant at 17°C over 17d compared with control plants, but had little effect at 7°C. The nodule decline at 17°C accompanied an acute and progressive decrease in specific rate of N₂fixation, from 9mmolN d^-1g^-1nodule d.wt on day 0 to zero by day 10. Whilst initial rates of N₂fixation were lower at 7°C, the mineral N-induced decrease in fixation rates was also less severe than at 17°C and specific fixation rates recovered after reaching a minimum on day 11. N₂fixation accounted for 36% of the total uptake of N by +min.N plants during the treatment period at 7°C as opposed to only 13% at 17°C. The total N₂fixed at 7°C was 86% of that fixed at 17°C, although the specific growth rate (d.wt) at 7°C was only 55% of that at 17°C. Addition of NH₄NO₃at 7°C had little effect on the gross amount of N₂fixed subsequently. In contrast, total N₂fixation by +min.N plants at 17°C was only 24% of that fixed by the corresponding controls. The possible mechanisms by which mineral N affects N₂fixation are discussed.     

Temperature-sensitive mutants of Corynebacterium ammoniagenes ATCC 6872 with a defective large subunit of the manganese-containing ribonucleotide reductase

Chemical mutagenesis of the nucleotide-producing strain Corynebacterium ammoniagenes ATCC 6872 with N-methyl-N-nitro-N-nitrosoguanidine followed by an enrichment protocol yielded 46 temperature-sensitive (ts) clones. A rapid assay for the allosterically regulated Mn-ribonucleotide reductase (RRase) was developed with nucleotide-permeable cells of C. ammoniagenes in order to screen for possible defects in DNA precursor biosynthesis at elevated temperature. Three mutants (CH 31, CH 32, and CH 33) grew well at 30° C but did not proliferate at 40° C because they did not reduce ribonucleotides to 2′-deoxyribonucleotides. They were designated nrd ^ts (nucleotide reduction defective). When the cultures were shifted from 30 to 40° C, the nrd ^ts mutants immediately ceased to incorporate radiolabeled nucleic acid precursors into the DNA fraction, while DNA chain elongation was barely affected. Thus, exhaustion of the deoxyribonucleotide pool ultimately inhibited cell division, leading to a filamentous growth morphology. In contrast to the wild-type, all three nrd ^ts mutants displayed a distinctly enhanced sensitivity of ribonucleotide reduction towards hydroxyurea (in permeabilized cells and in vitro) at 30° C. The results from assays for biochemical complementation of heat-inactivated (2 min, 37° C) mutant enzyme with either the small or the large subunit of wild-type Mn-RRase located the mutational defect on the large subunit. Received: 28 December 1995 / Revision received: 22 January 1997 / Accepted: 29 January 1997     

Abortive bacteriophage T4 head assembly in mutants of Escherichia coli

We describe two mutants (tabB-212 and tabB-127) of Escherichia coli K12 in which T-even phage production is temperature-sensitive. Both mutants are linked to purA and may identify a single new bacterial gene tabB. The uninfected bacterium is indistinguishable from wild type at both 30 °C and 42.4 °C. Sodium dodecyl sulphate—polyacrylamide gel electrophoresis of labelled extracts of tabB mutants infected by T4 wild-type phage shows that the modification of viral head precursors (Laemmli, 1970) does not occur, indicating that capsid formation is blocked. The effect is reversible with at least one of the tabB mutants: a shift to 30 °C leads to the cleavage of a significant fraction of precursors synthesized at 42.4 °C.Two classes of T4 mutants are described: one (com^B) which grows on tabB even at 42.4 °C, the other (k^B) which fails to grow on tabB even at the permissive temperature. Both mutants map in T4 gene 31, suggesting an interaction between gene 31 and tabB products.Since gene 31 mutants lead to the random aggregation of head precursors (Laemmli, 1970), we argue that a host product is involved in the ordered polymerization of T4 proteins into capsids or capsid-related structures.     

On the genetic control of cell cycles during morphogenesis in Ulva mutabilis

Development of the wild type and two temperature-sensitive mutants of the multicellular green alga Ulva mutabilis is compared. The mutants develop normal phenotypes at 22°C and abnormal phenotypes at 15°C. Normal development starts by formation of a filament consisting of a row of cells. The growth rate, the generation times, and the cell length at division change in a coordinated manner according to the positions of the cells within the filament. In the mutant cs₂ transfer to 15°C inhibits all cytoplasmic divisions during early development. In the mutant cs₆ the first three divisions proceed normally. Then cytoplasmic division is blocked in the most distal cells, while the proximal cells continue to divide according to a branched pattern. In the cs₂ mutant cell determination seems to occur at 15°C, while the differentiation of the determined cells can only occur at 22°C. In the mutant cs₆ the cells are not determined at 15°C. The cs₆⁺ gene, as well as the previously described Slender-like genes, presumably has a short period of activity and is concerned with more fundamental epigenetic processes than the cs₂⁺-gene and the previously described precocious-like genes, which seem to have more prolonged periods of activity.     

Seasonal variation in light- and temperature-dependent growth of marine planktonic diatoms in in situ dialysis cultures in the Trondheimsfjord,norway (63°N)

Three species of diatoms, Skeletonema costatum (Grev.) Cleve, Thalassiosira gravida Cleve, and T. pseudonana (Hustedt) Hasle et Heimdal, were grown in in situ dialysis culture in the Trondheimsfjord at depths of 0.5 and 4 m. The rates of growth and the chemical composition of exponentially growing cells were monitored and related to seasonal changes in illumination and temperature. Functions correlating growth rate with temperature were deduced. Growth took place from February to November. During this period temperature ranged from ?1 to 16°C, the average photon flux density (ifI) (per 24 h) from 9 to 570 μE · m^?2 · s^?1 (0.5 m depth), and the length of the days (I > 1 μE · m^?2 · s^?1) from 6 to 24 h. Light-limited growth was evident when the product of the average daily light and the chlorophyll/N ratio was < 10; this occurred mostly in early spring and late autumn. Peak densities (> 800 for the Thalassiosira spp. and > 1300–1400 μE · m^?2 · s^?1 for Skeletonema) seem to inhibit growth. The highest rates recorded were ≈1.6 doubl. · day^?1 (July, 15–16°C).The three species exhibit different ecological behaviour. Skeletonema is eurythermal (Q₁₀ = 1.8), whereas Thalassiosira pseudonana favours high temperatures, and T. gravida temperatures < 10°C. Moreover, Skeletonema has generally less chlorophyll and more phosphorus and ATP (≈ 1.4 ×) than the other two species. In Skeletonema, the ATP level seems related to the light-governed growth rate, and independent of temperature. In Thalassiosira no such correlation was found.     

Temperature tolerance polygon of Poecilia sphenops Valenciennes (Pisces: Poeciliidae)

1. The critical thermal maximum (CTMax) and minimum (CTMin), the upper and lower incipient lethal temperature, and the high and low avoidance temperature of Poecilia sphenops were established.2. The area of thermal tolerance of P. sphenops upon considering the lethal limits was 863.9 (°C)², the estimated area using the critical temperatures, as well as the zone of thermal preference were 959 and 323.4 (°C)², respectively.3. P. sphenops is a species highly eurythermical that possesses a high tolerance, resistance and capacity of adaptation to environmental variations.