New ways of looking at synapses

Current concepts of synaptic fine-structure are derived from electron microscopic studies of tissue fixed by chemical fixation using aldehydes. However, chemical fixation with glutaraldehyde and paraformaldehyde and subsequent dehydration in ethanol result in uncontrolled tissue shrinkage. While electron microscopy allows for the unequivocal identification of synaptic contacts, it cannot be used for real-time analysis of structural changes at synapses. For the latter purpose advanced fluorescence microscopy techniques are to be applied which, however, do not allow for the identification of synaptic contacts. Here, two approaches are described that may overcome, at least in part, some of these drawbacks in the study of synapses. By focusing on a characteristic, easily identifiable synapse, the mossy fiber synapse in the hippocampus, we first describe high-pressure freezing of fresh tissue as a method that may be applied to study subtle changes in synaptic ultrastructure associated with functional synaptic plasticity. Next, we propose to label presynaptic mossy fiber terminals and postsynaptic complex spines on CA3 pyramidal neurons by different fluorescent dyes to allow for the real-time monitoring of these synapses in living tissue over extended periods of time. We expect these approaches to lead to new insights into the structure and function of central synapses. Robert Feulgen Lecture presented at the 49th Symposium of the Society for Histochemistry in Freiburg i.Br., Germany, 26-29 September 2007.     

Epigenomic communication systems in humans and honey bees: From molecules to behavior

A 2010 Nature editorial entitled “Time for the Epigenome” trumpets the appearance of the International Human Epigenome Consortium and likens it to Biology's equivalent of the Large Hadron Collider. It strongly endorses the viewpoint that selective modifications of “marks” on DNA and histones constitute the crucial codes of life, a proposition which is hotly contested (Ptashne et al., in 2010). This proposition reflects the current mindset that DNA and histone modifications are the prime movers in gene regulation during evolution. This claim is perplexing, since the well characterized organisms, Drosophila melanogaster and Caenorhabditis elegans, lack methylated DNA “marks” and the DNA methytransferase enzymology. Despite their complete absence, D. melanogaster nevertheless has extensive gene regulatory networks which drive sophisticated development, gastrulation, migration of germ cells and yield a nervous system with significant neural attributes. In stark contrast, the honey bee Apis mellifera deploys its human-type DNA methyltransferase enzymology to “mark” its DNA and it too has sophisticated development. What roles therefore is DNA methylation playing in different animals? The honey bee brings a fresh perspective to this question. Its combinatorial chemistry of pheromones, tergal and cuticular exudates provide an exquisite communication system between thousands of individuals. The development of queen and worker is strictly controlled by differential feeding of royal jelly and their adult behaviors are accompanied by epigenomic changes. Their interfaces with different “environments” are extensive, allowing an evaluation of the roles of epigenomes in behavior in a natural environment, in the space of a few weeks, and at requisite levels of experimental rigor.     

Pollinator attraction: the importance of looking good and smelling nice

Flowers entice animal pollinators using a complex array of attractions. Reciprocal transfer of traits between Petunia species now shows that colour and scent are equally important to hawkmoths in choosing between different flowers.     

Exine development: the importance of looking through a colloid chemistry ``window'

Most biological construction systems operate within the colloidal dimension. In view of this, it seems reasonable to reassess what is known of the early stages of exine development in the light of a brief excursion into colloid and micelle behaviour. The results of this analysis show remarkable similarity of structures and suggest that almost all of the features seen during early pollen wall development can be easily interpreted using simple, established colloidal principles. This study of exine framework and endexine development offers the possibility that growth of the early exine progresses by successive transitory mesophases of a constrained micellar system. The self-assembling micelle mesophases will all be clearly recognized as constituents of the developing exine. They include spherical, cylindrical, continuous layers of hexagonally-packed cylindrical units and lamellar mesophases which most probably correspond to future granules, columellae, complex columellar (and alveolar) microarchitecture and ``white-line-centred' lamellae. Furthermore, the various types of micelle involved have the potential to perform the functions previously loosely assigned to the exine.     

冷冻透射电镜:从分子到系统

单颗粒电镜结合其他方法能够在(近)原子水平提供结构模型,已经成为一种研究大蛋白复合物的有效方法。该文将以两个大的蛋白裂解复合物——tripeptidyl peptidaseII(6MDa)和26S蛋白酶体(2.5MDa)举例说明。低温电子层析能进行非重复的超分子结构分析,如多核糖体和全细胞;能够为超分子组织提供前所未有的信息(可视化蛋白质组学)。     

Brown and beige fat: From molecules to physiology

The recent re-discovery of brown adipose tissue (BAT) and even more recent discovery of the browning of white adipose tissue (WAT) in humans have generated intense scientific interest in the role of adipose tissue as potential target against obesity and its metabolic complications. The purpose of this review is to: i) critically evaluate the current evidence on the physiological significance of BAT and the browning of WAT in metabolic function in humans and ii) discuss factors that have been reported to regulate BAT and/or the browning of WAT in humans. The current literature supports that BAT and the browning of WAT constitute promising emerging targets for interventions aiming to prevent and/or treat of obesity and its metabolic complications. Further research is needed to better understand the physiological significance of BAT and browning of WAT in health and disease along with the factors modulating their metabolic function in humans.     

C. elegans aging: proteolysis cuts both ways

Recent reports from two laboratories working on the nematode Caenorhabditis elegans have identified both positive and negative roles for ubiquitin-mediated proteolysis in the regulation of longevity by the insulin/insulin-like growth factor signaling pathway.     

Membrane fission: curvature-sensitive proteins cut it both ways

Boucrot et al. (2012) demonstrate a membrane fission mechanism independent of nucleotide hydrolysis that is based on membrane insertion of amphipathic helices. They show that, for N-BAR domain proteins, which promote membrane curvature but also contain amphipathic helices, fission is opposed by the BAR domain that stabilizes tubular membrane structures.     

From large networks to small molecules

Large-scale analysis of genetic and physical interaction networks has begun to reveal the global organization of the cell. Cellular phenotypes observed at the macroscopic level depend on the collective characteristics of protein and genetic interaction networks, which exhibit scale-free properties and are highly resistant to perturbation of a single node. The nascent field of chemical genetics promises a host of small-molecule probes to explore these emerging networks. Although the robust nature of cellular networks usually resists the action of single agents, they may be susceptible to rationally designed combinations of small molecules able to collectively shift network behavior.     

From molecules to dynamic biological communities

Microbial ecology is flourishing, and in the process, is making contributions to how the ecology and biology of large organisms is understood. Ongoing advances in sequencing technology and computational methods have enabled the collection and analysis of vast amounts of molecular data from diverse biological communities. While early studies focused on cataloguing microbial biodiversity in environments ranging from simple marine ecosystems to complex soil ecologies, more recent research is concerned with community functions and their dynamics over time. Models and concepts from traditional ecology have been used to generate new insight into microbial communities, and novel system-level models developed to explain and predict microbial interactions. The process of moving from molecular inventories to functional understanding is complex and challenging, and never more so than when many thousands of dynamic interactions are the phenomena of interest. We outline the process of how epistemic transitions are made from producing catalogues of molecules to achieving functional and predictive insight, and show how those insights not only revolutionize what is known about biological systems but also about how to do biology itself. Examples will be drawn primarily from analyses of different human microbiota, which are the microbial consortia found in and on areas of the human body, and their associated microbiomes (the genes of those communities). Molecular knowledge of these microbiomes is transforming microbiological knowledge, as well as broader aspects of human biology, health and disease.     

From Animaculum to single molecules: 300 years of the light microscope

Although not laying claim to being the inventor of the light microscope, Antonj van Leeuwenhoek (1632–1723) was arguably the first person to bring this new technological wonder of the age properly to the attention of natural scientists interested in the study of living things (people we might now term ‘biologists’). He was a Dutch draper with no formal scientific training. From using magnifying glasses to observe threads in cloth, he went on to develop over 500 simple single lens microscopes (Baker & Leeuwenhoek 1739 Phil. Trans. 41, 503–519. (doi:10.1098/rstl.1739.0085)) which he used to observe many different biological samples. He communicated his finding to the Royal Society in a series of letters (Leeuwenhoek 1800 The select works of Antony Van Leeuwenhoek, containing his microscopical discoveries in many of the works of nature, vol. 1) including the one republished in this edition of Open Biology. Our review here begins with the work of van Leeuwenhoek before summarizing the key developments over the last ca 300 years, which has seen the light microscope evolve from a simple single lens device of van Leeuwenhoek''s day into an instrument capable of observing the dynamics of single biological molecules inside living cells, and to tracking every cell nucleus in the development of whole embryos and plants.