BIOSYNTHESIS AND COMPOSITION OF BRAIN GALACTOLIPIDS IN NORMAL AND HYPOTHYROID RATS

Abstract— Newborn rats were rendered hypothyroid by methimazole treatment. Incorporation of [1-¹⁴C]galactose both in vivo and in vitro into brain cerebrosides of hypothyroid rats was significantly lower than in normals. Biosynthesis of sulphatides was affected by hypothyroidism to a smaller extent than cerebrosides. Assay of cerebroside biosynthesis from [1-¹⁴C]galactose or UDP-[1-¹⁴C]galactose by brain preparations revealed that incorporation of the sugar in both cases is affected to the same extent by methimazole treatment, suggesting that the phenomenon is not due to impairment of the nucleotide biosynthesis. A radioactive galactolipid tentatively characterized as glycerogalactolipid was synthesized in vitro and its biosynthesis was reduced to a large extent in the brain preparations from hypothyroid rats. The fatty acid composition of cerebrosides and sulphatides from the brains of hypothyroid rats was found to be different from that of normal rats. The percentage of normal C₂₄ fatty acids was significantly decreased in the methimazole-treated rats. Brain sphingomyelin fatty acids did not differ between normal and hypothyroid rats.     

Plant regeneration of protoplasts isolated from suspension cultures of Solanum lycopersicoides

A protocol was developed for the isolation, culture and plant regeneration of protoplasts isolated from suspension cultures of Solanum lycopersicoides Dun. (LA 1990). Protoplasts were isolated by an overnight enzyme digestion, further purified by washing in W5 salts solution, and plated in two modified MS protoplast culture media with and without type VII agarose. The addition of agarose to the two culture media did not enhance plating efficiencies and shoot regeneration percentages and in some cases was even inhibitory. Unlike the experience with some other solanaceous species, the deletion of ammonium from the protoplast culture medium was not found to be beneficial. Protoplasts sustained continuous division in the modified MS media and up to 70% of the protoplast-derived calli readily regenerated shoots on MS salts and vitamins medium containing zeatin and GA.     

Coupling dynamic models of climate and vegetation

Numerous studies have underscored the importance of terrestrial ecosystems as an integral component of the Earth's climate system. This realization has already led to efforts to link simple equilibrium vegetation models with Atmospheric General Circulation Models through iterative coupling procedures. While these linked models have pointed to several possible climate–vegetation feedback mechanisms, they have been limited by two shortcomings: (i) they only consider the equilibrium response of vegetation to shifting climatic conditions and therefore cannot be used to explore transient interactions between climate and vegetation; and (ii) the representations of vegetation processes and land-atmosphere exchange processes are still treated by two separate models and, as a result, may contain physical or ecological inconsistencies. Here we present, as a proof concept, a more tightly integrated framework for simulating global climate and vegetation interactions. The prototype coupled model consists of the GENESIS (version 2) Atmospheric General Circulation Model and the IBIS (version 1) Dynamic Global Vegetation Model. The two models are directly coupled through a common treatment of land surface and ecophysiological processes, which is used to calculate the energy, water, carbon, and momentum fluxes between vegetation, soils, and the atmosphere. On one side of the interface, GENESIS simulates the physics and general circulation of the atmosphere. On the other side, IBIS predicts transient changes in the vegetation structure through changes in the carbon balance and competition among plants within terrestrial ecosystems. As an initial test of this modelling framework, we perform a 30 year simulation in which the coupled model is supplied with modern CO₂ concentrations, observed ocean temperatures, and modern insolation. In this exploratory study, we run the GENESIS atmospheric model at relatively coarse horizontal resolution (4.5° latitude by 7.5° longitude) and IBIS at moderate resolution (2° latitude by 2° longitude). We initialize the models with globally uniform climatic conditions and the modern distribution of potential vegetation cover. While the simulation does not fully reach equilibrium by the end of the run, several general features of the coupled model behaviour emerge. We compare the results of the coupled model against the observed patterns of modern climate. The model correctly simulates the basic zonal distribution of temperature and precipitation, but several important regional biases remain. In particular, there is a significant warm bias in the high northern latitudes, and cooler than observed conditions over the Himalayas, central South America, and north-central Africa. In terms of precipitation, the model simulates drier than observed conditions in much of South America, equatorial Africa and Indonesia, with wetter than observed conditions in northern Africa and China. Comparing the model results against observed patterns of vegetation cover shows that the general placement of forests and grasslands is roughly captured by the model. In addition, the model simulates a roughly correct separation of evergreen and deciduous forests in the tropical, temperate and boreal zones. However, the general patterns of global vegetation cover are only approximately correct: there are still significant regional biases in the simulation. In particular, forest cover is not simulated correctly in large portions of central Canada and southern South America, and grasslands extend too far into northern Africa. These preliminary results demonstrate the feasibility of coupling climate models with fully dynamic representations of the terrestrial biosphere. Continued development of fully coupled climate-vegetation models will facilitate the exploration of a broad range of global change issues, including the potential role of vegetation feedbacks within the climate system, and the impact of climate variability and transient climate change on the terrestrial biosphere.     

Hantavirus as important emerging agents in South America

The dawning of the 20th century was marked by the emergence of new infectious disease agents and the appearance of others previously thought controlled. Both phenomena were possibly connected with ecological disturbances that led to the recognition of a dramatic climate change, of which the effects are only now becoming noticeable. Among the variety of agents to be considered, the many new viruses stand out, not only for their numerical proliferation, but also for their genetic versatility. It is this quality that provides them dexterity for evolving new strategies and adaptations to changing environmental conditions. Recently, some of the most ubiquitous and well-publicized viral agents in the American continents have been the rodent-borne viruses, and among these are the hantaviruses, etiological agents of pulmonary syndromes. Approximately 18 hantaviruses (belonging to the family Bunyaviridae), have been discovered in South America during the last 20 years, and although most of them cause persistent infections and subclinical infections in wild rodents (particularly members of the subfamily Sigmodontinae) and humans respectively; some others might also be highly lethal for humans. The goal herein is to review the state of the art regarding general aspects of hantaviruses and the diseases they cause around the world, highlighting the most recent findings in Colombia. Finally, the many unanswered questions will be recognized and highlighted concerning clinical importance and socio-economic impact of these agents on quality of public health in Colombia.     

Chromosomal aberrations and sister-chromatid exchanges in Chinese hamster cells treated in vitro with hexavalent chromium compounds.

Chinese hamster cells (CHO line) were treated in vitro for 30--39 h with hexavalent chromium compounds (K2Cr2O7 and Na2CrO7), at concentrations ranging from 0.1 to 1.0 microgram of Cr6+ per ml, in medium containing BUdr. Chromosomal aberrations and sister-chromatid exchanges were scored on BUdr-labelled 2nd division metaphases, collected at the end of treatment and stained with Giemsa. Treatment with mitomycin C 0.009--0.030 microgram/ml) was carried out as a control for the responsiveness of the cell system to chromosomal damage. Both chromium compounds induced marked mitotic delays. Chromosomal aberrations were increased about 10-fold by exposure to Cr6+ (1.0 microgram/ml). The principal aberrations observed were single chromatid gaps, breaks and interchanges, whose frequencies increased proportionally to the concentration of chromium. Dicentric chromosomes, isochromatid breaks, chromosome and chromatid rings were also induced. The frequenyc of sister-chromatid exchanges was hardly doubled 30 h after exposure to Cr6+ at 0.3 microgram/ml, whereas it was trebled 39 h after treatment, in the cells whose division cycle had been slowed down by chromium.     

Identification of candidate loci for adaptive phenotypic plasticity in natural populations of spadefoot toads

Phenotypic plasticity allows organisms to alter their phenotype in direct response to changes in the environment. Despite growing recognition of plasticity's role in ecology and evolution, few studies have probed plasticity's molecular bases—especially using natural populations. We investigated the genetic basis of phenotypic plasticity in natural populations of spadefoot toads (Spea multiplicata). Spea tadpoles normally develop into an “omnivore” morph that is favored in long‐lasting, low‐density ponds. However, if tadpoles consume freshwater shrimp or other tadpoles, they can alternatively develop (via plasticity) into a “carnivore” morph that is favored in ephemeral, high‐density ponds. By combining natural variation in pond ecology and morph production with population genetic approaches, we identified candidate loci associated with each morph (carnivores vs. omnivores) and loci associated with adaptive phenotypic plasticity (adaptive vs. maladaptive morph choice). Our candidate morph loci mapped to two genes, whereas our candidate plasticity loci mapped to 14 genes. In both cases, the identified genes tended to have functions related to their putative role in spadefoot tadpole biology. Our results thereby form the basis for future studies into the molecular mechanisms that mediate plasticity in spadefoots. More generally, these results illustrate how diverse loci might mediate adaptive plasticity.     

Molecular identification and phylogenetic relationships among the species of the genus Oligoryzomys (Rodentia, Cricetidae) present in Argentina, putative reservoirs of hantaviruses

The systematics and geographical distribution of the species of Oligoryzomys present in Argentina are poorly known. From some of the species different hantavirus genotypes have been recovered. In order to contribute to the accurate identification of those species and to infer their phylogenetic relationships, we analysed data of restriction sites and sequences of the mtDNA d -loop region. The samples used represent almost all Oligoryzomys species known to occur in Argentina. The trees obtained with the two types of data were similar, showing high bootstrap values for the majority of the nodes. Our results support the idea that the specific name Oligoryzomys longicaudatus should be applied only to individuals from the south of Argentina and Chile and confirm that O. nigripes and O. delticola are conspecific. Specimens identified as O. flavescens conform three related clades, probably belonging to a species complex. This study also emphasises that the use of a DNA fragment characterised by a high evolutionary rate compare with other mitochondrial segments as the d -loop, was appropriate to infer the phylogenetic relationships in a group originated by a rapid speciation process. We also suggest the following modifications in the rodent–hantavirus relationships: the only viral genotype associated to O. longicaudatus would be Andes Sout, while O. chacoensis would be the natural host of the genotype Oran. One of the forms of the O. flavescens complex would be the natural host of the genotype Bermejo. Our data are consistent with the hypothesis that each hantavirus genotype is associated with a specific rodent host.