How law can help solve the collective action problem of antimicrobial resistance

Antimicrobial resistance is a global collective action problem with dire consequences for human health. This article considers how domestic and international legal mechanisms can be used to address antimicrobial resistance and overcome the governance and political economy challenges that accelerate it.     

Archaeal DNA replication: identifying the pieces to solve a puzzle.

Archaeal organisms are currently recognized as very exciting and useful experimental materials. A major challenge to molecular biologists studying the biology of Archaea is their DNA replication mechanism. Undoubtedly, a full understanding of DNA replication in Archaea requires the identification of all the proteins involved. In each of four completely sequenced genomes, only one DNA polymerase (Pol BI proposed in this review from family B enzyme) was reported. This observation suggested that either a single DNA polymerase performs the task of replicating the genome and repairing the mutations or these genomes contain other DNA polymerases that cannot be identified by amino acid sequence. Recently, a heterodimeric DNA polymerase (Pol II, or Pol D as proposed in this review) was discovered in the hyperthermophilic archaeon, Pyrococcus furiosus. The genes coding for DP1 and DP2, the subunits of this DNA polymerase, are highly conserved in the Euryarchaeota. Euryarchaeotic DP1, the small subunit of Pol II (Pol D), has sequence similarity with the small subunit of eukaryotic DNA polymerase delta. DP2 protein, the large subunit of Pol II (Pol D), seems to be a catalytic subunit. Despite possessing an excellent primer extension ability in vitro, Pol II (Pol D) may yet require accessory proteins to perform all of its functions in euryarchaeotic cells. This review summarizes our present knowledge about archaeal DNA polymerases and their relationship with those accessory proteins, which were predicted from the genome sequences.     

Mouse models to study inner ear development and hereditary hearing loss

Hereditary sensorineural hearing loss, derived from inner ear defects, is the most common hereditary disability with a prevalence of 1 in 1,000 children, although it can be present in up to 15% of births in isolated communities. The mouse serves as an ideal animal model to identify new deafness-related genes and to study their roles in vivo. This review describes mouse models for genes that have been linked with hearing impairment (HI) in humans. Mutations in several groups of genes have been linked with HI in both mice and humans. Mutant mice have been instrumental in elucidating the function and mechanisms of the inner ear. For example, the roles of collagens and tectorins in the tectorial membrane, as well as the necessity of intact links between the hair cell projections, stereocilia and kinocilia, have been discovered in mice. Accurate endolymph composition and the proteins which participate in its production were found to be crucial for inner ear function, as well as several motor proteins such as prestin and myosins. Two systematic projects, KOMP and EUCOMM, which are currently being carried out to create knock-out and conditional mutants for every gene in the mouse genome, promise that many additional deafness-related genes will be identified in the next years, providing models for all forms of human deafness.     

Bird–nest puzzle: can the study of unisexual flowers such as cucumber solve the problem of plant sex determination?

Unisexual flower development has long been used as a model system to understand the mechanism of plant sex determination. However, based on our investigation of the mechanisms regulating the development of unisexual cucumber flowers, we have realized that understanding how organ development is inhibited may not necessarily reveal how an organ is formed. We refer to this problem as a “bird–nest puzzle,” meaning one cannot understand how a bird lays and hatches its eggs by understanding how its nest is ruined. To understand the biological significance of unisexual flowers, we reexamine the original meaning of sex and its application in plants. Additionally, we propose that the fundamental biological advantage for the selection and maintenance of unisexual flowers during evolution is to promote cross pollination.     

A unique hairpin-type tail-anchored SNARE starts to solve a long-time puzzle

Macroautophagy mediates recycling of intracellular material by a multistep pathway, ultimately leading to the fusion of closed double-membrane structures, called autophagosomes, with the lysosome. This event ensures the degradation of the autophagosome content by lysosomal proteases followed by the release of macromolecules by permeases and, thus, it accomplishes the purpose of macroautophagy (hereafter referred to as autophagy). Because fusion of unclosed autophagosomes (i.e., phagophores) with the lysosome would fail to degrade the autophagic cargo, this critical step has to be tightly controlled. Yet, until recently, little was known about the regulation of this event and the factors orchestrating it. A punctum in this issue highlights the recent paper by Noboru Mizushima and his collaborators that answered the question of how premature fusion of phagophores with the lysosome is prevented prior to completion of autophagosome closure.     

The concepts of asymmetric and symmetric power can help resolve the puzzle of altruistic and cooperative behaviour

Evolutionary theory predicts competition in nature yet altruistic and cooperative behaviour appears to reduce the ability to compete in order to help others compete better. This evolutionary puzzle is usually explained by kin selection where close relatives perform altruistic and cooperative acts to help each other and by reciprocity theory (i.e. direct, indirect and generalized reciprocity) among non‐kin. Here, it is proposed that the concepts of asymmetry and symmetry in power and dominance are critical if we are ever to resolve the puzzle of altruism and cooperation towards non‐kin. Asymmetry in power and dominance is likely to emerge under competition in nature as individuals strive to gain greater access to the scarce resources needed to survive and reproduce successfully. Yet asymmetric power presents serious problems for reciprocity theory in that a dominant individual faces a temptation to cheat in interactions with subordinates that is likely to far outweigh any individual selective benefits gained through reciprocal mechanisms. Furthermore, action taken by subordinates to deter non‐reciprocation by dominants is likely to prove prohibitively costly to their fitness, making successful enforcement of reciprocal mechanisms unlikely. It is also argued here that many apparently puzzling forms of cooperation observed in nature (e.g. cooperative breeding in which unrelated subordinates help dominants to breed) might be best explained by asymmetry in power and dominance. Once it is recognized that individuals in these cooperative interactions are subject to the constraints and opportunities imposed on them by asymmetric power then they can be seen as pursuing a ‘least bad’ strategy to promote individual fitness – one that is nevertheless consistent with evolutionary theory. The concept of symmetric power also provides important insights. It can inhibit reciprocal mechanisms in the sense that symmetric power makes it easier for a cheat to appropriate common resources while incurring fewer penalties. Nevertheless under certain restrictive conditions, symmetric power is seen as likely to promote direct reciprocity through ‘tit for tat’.     

Putting together the pieces of polio: how Dorothy Horstmann helped solve the puzzle

Dr. Dorothy Horstmann, epidemiologist, virologist, clinician, and educator, was the first woman appointed as a professor at the Yale School of Medicine. Horstmann made significant contributions to the fields of public health and virology, her most notable being the demonstration that poliovirus reached the central nervous system via the bloodstream, upsetting conventional wisdom and paving the way for polio vaccines. In 1961, she was appointed a professor at Yale School of Medicine, and in 1969, she became the first woman at Yale to receive an endowed chair, which was named in honor of her mentor, Dr. John Rodman Paul. In this review, the major scientific contributions of Dr. Dorothy Horstmann will be highlighted from her more than 50-year tenure at Yale School of Medicine.     

Predicted residue–residue contacts can help the scoring of 3D models

During the 7th Critical Assessment of Protein Structure Prediction (CASP7) experiment, it was suggested that the real value of predicted residue–residue contacts might lie in the scoring of 3D model structures. Here, we have carried out a detailed reassessment of the contact predictions made during the recent CASP8 experiment to determine whether predicted contacts might aid in the selection of close‐to‐native structures or be a useful tool for scoring 3D structural models. We used the contacts predicted by the CASP8 residue–residue contact prediction groups to select models for each target domain submitted to the experiment. We found that the information contained in the predicted residue–residue contacts would probably have helped in the selection of 3D models in the free modeling regime and over the harder comparative modeling targets. Indeed, in many cases, the models selected using just the predicted contacts had better GDT‐TS scores than all but the best 3D prediction groups. Despite the well‐known low accuracy of residue–residue contact predictions, it is clear that the predictive power of contacts can be useful in 3D model prediction strategies. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

A new mouse model of Canavan leukodystrophy displays hearing impairment due to central nervous system dysmyelination

Canavan disease is a leukodystrophy caused by mutations in the ASPA gene. This gene encodes the enzyme that converts N-acetylaspartate into acetate and aspartic acid. In Canavan disease, spongiform encephalopathy of the brain causes progressive mental retardation, motor deficit and death. We have isolated a mouse with a novel ethylnitrosourea-induced mutation in Aspa. This mutant, named deaf14, carries a c.516T>A mutation that is predicted to cause a p.Y172X protein truncation. No full-length ASPA protein is produced in deaf14 brain and there is extensive spongy degeneration. Interestingly, we found that deaf14 mice have an attenuated startle in response to loud noise. The first auditory brainstem response peak has normal latency and amplitude but peaks II, III, IV and V have increased latency and decreased amplitude in deaf14 mice. Our work reveals a hitherto unappreciated pathology in a mouse model of Canavan disease, implying that auditory brainstem response testing could be used in diagnosis and to monitor the progression of this disease.KEY WORDS: Canavan disease, Aspa, Aspartoacylase, Leukodystrophy, ENU mutagenesis, Myelin     

DFNA25, a novel locus for dominant nonsyndromic hereditary hearing impairment, maps to 12q21-24

Using linkage analysis, we identified a novel dominant locus, DFNA25, for delayed-onset, progressive, high-frequency, nonsyndromic sensorineural hearing loss in a large, multigenerational United States family of Czech descent. On the basis of recombinations in affected individuals, we determined that DFNA25 is located in a 20-cM region of chromosome 12q21-24 between D12S327 (centromeric) and D12S84 (telomeric), with a maximum two-point LOD score of 6.82, at recombination fraction.041, for D12S1030. Candidate genes in this region include ATP2A2, ATP2B1, UBE3B, and VR-OAC. DFNA25 may be the human ortholog of bronx waltzer (bv).