Evolutionary explanations of emotions

Emotions can be explained as specialized states, shaped by natural selection, that increase fitness in specific situations. The physiological, psychological, and behavioral characteristics of a specific emotion can be analyzed as possible design features that increase the ability to cope with the threats and opportunities present in the corresponding situation. This approach to understanding the evolutionary functions of emotions is illustrated by the correspondence between (a) the subtypes of fear and the different kinds of threat; (b) the attributes of happiness and sadness and the changes that would be advantageous in propitious and unpropitious situations; and (c) the social emotions and the adaptive challenges of reciprocity relationships. In addition to addressing a core theoretical problem shared by evolutionary and cognitive psychology, explicit formulations of the evolutionary functions of specific emotions are of practical importance for understanding and treating emotional disorders.     

Pretreatment of cellulosic wastes to increase enzyme reactivity

The enzymatic hydrolysis of cellulose to glucose is generally a slow reaction. Different pretreatments, such as ball milling to a ?200 mesh or swelling in 1–2% NaOH are reported to increase the reactivity considerably. In this work a fiber fraction from cattle manure was treated in an autoclave for 5–30 min at temperatures ranging from 130–200°C. The reactivity of the cellulose, measured by incubating samples with a commercial cellulase preparation for one hour at 50°C and pH 4.8, was increased by a factor of 4–6 compared to NaOH treatment and 10–12 compared to untreated fiber. The increased reaction rate is probably mostly due to an increase in cellulose availability to enzymatic attack, as structural hemicellulose is hydrolyzed and removed during the treatment. Sugars, produced by hemicellulosis, hydrolysis, will react further to give caramelization products. These side reactions were shown to be suppressed by short treatment times. The treated fiber could support growth of a mixed culture of Trichoderma viride and Candida utilis only after washing, indicating the formation of water soluble inhibitory products during treatment. The treatment with high-temperature steam can probably be used also with other cellulosic materials to increase reactivity. This may be an attractive way to prepare low-valued wastes such as manure fibers, straw, stalks, or corn cobs for fermentation processes to increase the protein content or for use directly as ruminant animal feed.     

Natural selection and the elusiveness of happiness

The quest for happiness has expanded from a focus on relieving suffering to also considering how to promote happiness. However, both approaches have yet to be conducted in an evolutionary framework based on the situations that shaped the capacities for happiness and sadness. Because of this, the emphasis has almost all been on the disadvantages of negative states and the benefits of positive states, to the nearly total neglect of 'diagonal psychology', which also considers the dangers of unwarranted positive states and the benefits of negative emotions in certain situations. The situations that arise in goal pursuit contain adaptive challenges that have shaped domain-general positive and negative emotions that were partially differentiated by natural selection to cope with the more specific situations that arise in the pursuit of different kinds of goals. In cultures where large social groups give rise to specialized and competitive social roles, depression may be common because regulation systems are pushed far beyond the bounds for which they were designed. Research on the evolutionary origins of the capacities for positive and negative emotions is urgently needed to provide a foundation for sensible decisions about the use of new mood-manipulating technologies.     

Mitochondrial DNA Toxicity in Forebrain Neurons Causes Apoptosis,Neurodegeneration, and Impaired Behavior

Mitochondrial dysfunction underlying changes in neurodegenerative diseases is often associated with apoptosis and a progressive loss of neurons, and damage to the mitochondrial genome is proposed to be involved in such pathologies. In the present study we designed a mouse model that allows us to specifically induce mitochondrial DNA toxicity in the forebrain neurons of adult mice. This is achieved by CaMKIIα-regulated inducible expression of a mutated version of the mitochondrial UNG DNA repair enzyme (mutUNG1). This enzyme is capable of removing thymine from the mitochondrial genome. We demonstrate that a continual generation of apyrimidinic sites causes apoptosis and neuronal death. These defects are associated with behavioral alterations characterized by increased locomotor activity, impaired cognitive abilities, and lack of anxietylike responses. In summary, whereas mitochondrial base substitution and deletions previously have been shown to correlate with premature and natural aging, respectively, we show that a high level of apyrimidinic sites lead to mitochondrial DNA cytotoxicity, which causes apoptosis, followed by neurodegeneration.A variety of both exogenous and endogenous reactive compounds present a constant threat to the integrity of DNA in living cells. DNA damage introduced by such compounds can lead to high and deleterious mutation rates as well as DNA cytotoxicity, both to the nuclear and the mitochondrial genome. This has triggered the evolution of several different DNA repair pathways (28). One is the base excision repair (BER) pathway, which repairs small base alterations that do not distort the DNA helix. Repair of such highly abundant lesions by BER is performed by a multistep process that is initiated by a damage-specific DNA glycosylase, which removes the damaged base. One of these glycosylases is uracil-DNA glycosylase (UDG), which acts to preserve the genome by removing mutagenic uracil residues from the DNA. This glycosylase, as well as the OGG1 glycosylase that is specialized for the removal of oxidized bases, exists in a nuclear and mitochondrial splice form (1, 11, 37, 45). Accordingly, BER of a variety of lesions has been observed in mitochondria (26, 31).Damage to the mitochondrial DNA (mtDNA) can cause respiratory chain deficiency and lead to disorders that have varied phenotypes (35, 41). Many involve neurological features that are often associated with cell loss within specific brain regions. These pathologies, along with the increasing evidence of a decline in mitochondrial function with aging, have raised speculation that key changes in mitochondrial DNA sequences and functions could have a vital role in age-related neurodegenerative diseases (41). This has also been studied in several model organisms. Mouse models with respiratory chain deficient dopamine neurons have demonstrated adult onset Parkinsonism phenotype (16), and cell death induced by mitochondrial toxicity is likely to underlie Alzheimer disease (32). Mitochondrial oxidative stress and accumulation of mtDNA damage are believed to be particularly devastating to postmitotic differentiated tissue, including neurons (30). The mtDNA contains genetic information for 13 polypeptides that are a part of the electron transport chain and for rRNAs and tRNAs that are necessary for mitochondrial protein synthesis. Thus, damage to the mtDNA genome will affect the energetic capacities of the mitochondria and also influence the level of reactive oxygen species (ROS) and ultimately the susceptibility to apoptosis (30, 35).Some recent influential studies have assessed the effect of mtDNA mutagenesis, including small base-pair substitutions and larger mtDNA deletions, on the life span of mice. It was concluded that a massive increase in the frequency of mtDNA base-pair substitutions are required for inducing premature aging, whereas the number of mtDNA deletions coincides better with natural aging (25, 47-49).In the present study, we have combined two novel transgenic mouse models, which allow the induction of a high number of apyrimidinic (AP) sites specifically to the mitochondrial genome in adults simply by the addition of doxycycline to the diet. Such AP sites are created by the expression of a mutated version of mitochondrion-targeted human UDG (abbreviated here as mutUNG1), whereby an amino acid substitution results in an enzyme that removes thymine, in addition to uracil, from DNA (23). The CaMKIIα promoter restricts expression of the mutUNG1 to forebrain neurons (34). We demonstrate that a continuous generation of AP sites leads to apoptosis, accelerated neurodegeneration, and impaired behavior.     

Effects of Norspermidine and Spermidine on Biofilm Formation by Potentially Pathogenic Escherichia coli and Salmonella enterica Wild-Type Strains

Polyamines are present in all living cells. In bacteria, polyamines are involved in a variety of functions, including biofilm formation, thus indicating that polyamines may have potential in the control of unwanted biofilm. In the present study, the effects of the polyamines norspermidine and spermidine on biofilms of 10 potentially pathogenic wild-type strains of Escherichia coli serotype O103:H2, Salmonella enterica subsp. enterica serovar Typhimurium, and S. enterica serovar Agona were investigated. We found that exogenously supplied norspermidine and spermidine did not mediate disassembly of preformed biofilm of any of the E. coli and S. enterica strains. However, the polyamines did affect biofilm production. Interestingly, the two species reacted differently to the polyamines. Both polyamines reduced the amount of biofilm formed by E. coli but tended to increase biofilm formation by S. enterica. Whether the effects observed were due to the polyamines specifically targeting biofilm formation, being toxic for the cells, or maybe a combination of the two, is not known. However, there were no indications that the effect was mediated through binding to exopolysaccharides, as earlier suggested for E. coli. Our results indicate that norspermidine and spermidine do not have potential as inhibitors of S. enterica biofilm. Furthermore, we found that the commercial polyamines used contributed to the higher pH of the test medium. Failure to acknowledge and control this important phenomenon may lead to misinterpretation of the results.     

<Emphasis Type="Italic">Scoredist</Emphasis>: A simple and robust protein sequence distance estimator

Background  

Distance-based methods are popular for reconstructing evolutionary trees thanks to their speed and generality. A number of methods exist for estimating distances from sequence alignments, which often involves some sort of correction for multiple substitutions. The problem is to accurately estimate the number of true substitutions given an observed alignment. So far, the most accurate protein distance estimators have looked for the optimal matrix in a series of transition probability matrices, e.g. the Dayhoff series. The evolutionary distance between two aligned sequences is here estimated as the evolutionary distance of the optimal matrix. The optimal matrix can be found either by an iterative search for the Maximum Likelihood matrix, or by integration to find the Expected Distance. As a consequence, these methods are more complex to implement and computationally heavier than correction-based methods. Another problem is that the result may vary substantially depending on the evolutionary model used for the matrices. An ideal distance estimator should produce consistent and accurate distances independent of the evolutionary model used.