生物医学方法指南

本书介绍了生物医学几个不同分支学科中有代表性的共同的研究方法。这些方法不仅使用最广泛，而且也是最基本的方法。书中概述了所介绍方法的目的、局限性，并提供了适用的替代方法。     

英国国际合作格局

该报告运用文献计量学方法，对英国及其主要合作伙伴国的国际合作格局做了全面的分析。所选
择的主要国家包括美国、加拿大、法国、德国、日本、澳大利亚、中国与印度；数据覆盖领域有临床、医药
卫生、生物科学、环境科学、数学、物质科学以及工程技术领域；数据时间分为1996－2000年与2001－2005
年两个时间段。结果显示：国际论文数量增长显著；英国国际合作论文份额的增长比G7 国家更加快速； 德
国和美国是英国最大的国际合作伙伴；英国国际合作论文的平均影响力显著高于其科研论文的总体影响力；
中国与英国合作发表的论文数量超过了与其他欧洲各国的合作论文数。     

Competition induces adaptive shifts in caste ratios of a polyembryonic wasp

An important transition in insect life-history evolution was the shift from a solitary existence to living in groups comprising specialized castes. Caste-forming species produce some individuals that reproduce and others with worker functions that have few or no offspring. Morphologically specialized castes are well known in eusocial species like ants and termites, but castes have also evolved in less-studied groups like thrips, aphids and polyembryonic wasps. Because selection acts at both the individual and the colony level, ratios of investment in different castes are predicted to vary with environmental factors like competition and resources. However, experimental evidence for adaptive shifts in caste ratios is limited owing to the experimental difficulty of manipulating factors thought to influence caste ratios, and because some species produce behaviourally flexible castes that switch tasks in response to colony needs. Unlike other caste-forming species, the broods of polyembryonic wasps develop clonally, so that increased production of one caste probably results in decreased production of the other. Here we show that the polyembryonic wasp Copidosoma floridanum alters caste ratios in response to interspecific competition. Our results reveal a distinct trade-off by C. floridanum between reproduction and defence, and show experimentally that caste ratios shift in an adaptive manner.     

Independent recruitment of a conserved developmental mechanism during leaf evolution

Vascular plants evolved in the Middle to Late Silurian period, about 420 million years ago. The fossil record indicates that these primitive plants had branched stems with sporangia but no leaves. Leaf-like lateral outgrowths subsequently evolved on at least two independent occasions. In extant plants, these events are represented by microphyllous leaves in lycophytes (clubmosses, spikemosses and quillworts) and megaphyllous leaves in euphyllophytes (ferns, gymnosperms and angiosperms). Our current understanding of how leaves develop is restricted to processes that operate during megaphyll formation. Because microphylls and megaphylls evolved independently, different mechanisms might be required for leaf formation. Here we show that this is not so. Gene expression data from a microphyllous lycophyte, phylogenetic analyses, and a cross-species complementation experiment all show that a common developmental mechanism can underpin both microphyll and megaphyll formation. We propose that this mechanism might have operated originally in the context of primitive plant apices to facilitate bifurcation. Recruitment of this pathway to form leaves occurred independently and in parallel in different plant lineages.     

科学新格局：英国科研及其国际合作

国际合作研究不仅可以利用其他国家的科研投资，而且能够产生具有轰动效应的创新型结果。由
于语言文化的相似性，英国与美国及欧洲国家有着较为广泛的联系，他们之间的合作是英国科学研究合作的
主体。随着科学研究及技术革新的发展更多地转向东方，以及中国和印度这两大科技力量的迅猛发展，英国
应该更加重视与这两个国家的合作。文章指出：应该就英国及其新伙伴之间的关系进行详细的研究，从而深
入理解中英两国间的合作并建立成功的合作模式。     

Genetic contributions to stability and change in intelligence from childhood to old age

Understanding the determinants of healthy mental ageing is a priority for society today. So far, we know that intelligence differences show high stability from childhood to old age and there are estimates of the genetic contribution to intelligence at different ages. However, attempts to discover whether genetic causes contribute to differences in cognitive ageing have been relatively uninformative. Here we provide an estimate of the genetic and environmental contributions to stability and change in intelligence across most of the human lifetime. We used genome-wide single nucleotide polymorphism (SNP) data from 1,940 unrelated individuals whose intelligence was measured in childhood (age 11 years) and again in old age (age 65, 70 or 79 years). We use a statistical method that allows genetic (co)variance to be estimated from SNP data on unrelated individuals. We estimate that causal genetic variants in linkage disequilibrium with common SNPs account for 0.24 of the variation in cognitive ability change from childhood to old age. Using bivariate analysis, we estimate a genetic correlation between intelligence at age 11 years and in old age of 0.62. These estimates, derived from rarely available data on lifetime cognitive measures, warrant the search for genetic causes of cognitive stability and change.