Reproductive failure: a new paradigm for extinction

Extinction was recognized as a scientific fact 200 years ago, although no adequate paradigm has emerged to explain the process. Prevailing theory has focused on ‘cause(s)’ of extinction but has neglected ‘effect’ and ‘mechanism’. These omissions preclude the formulation of a functional paradigm necessary for remedial action in response to the impending anthropogenic mediated, worldwide extinction crisis. The new paradigm is defined as the multi‐generational, attritional loss of reproductive fitness. Stabilizing selection continuously adapts species to specific ecosystems, which often results in highly evolved species prone to extinction when environments shift. Some species survive by tracking the declining palaeoclimates in which they presumably evolved, often becoming relicts prior to extinction. Compelling new evidence shows that even mass extinctions are largely a result of environmental change leading to widespread, attritional reproductive decline, rather than a result of instantaneous global catastrophes.     

Quantum computing: a new paradigm for ecology

A global technology arms race is underway to build evermore powerful and precise quantum computers. Quantum computers have the potential to tackle certain quantitative problems quicker than classical computers. The current focus of quantum computing is on pushing the boundaries of fundamental quantum information and commercial applications in industrial sectors, financial services, and other profit-led sectors, particularly where improvements in optimisation and sampling can improve increased economic return. We believe that ecologists could exploit the computational power of quantum computers because the statistical approaches commonly used in ecology already have proven pathways on quantum computers. Moreover, quantum computing could ultimately leapfrog our understanding of complex ecological systems, if the hardware, opportunity, and creativity of quantitative ecologists all align.     

Targeting virulence: a new paradigm for antimicrobial therapy

Clinically significant antibiotic resistance has evolved against virtually every antibiotic deployed. Yet the development of new classes of antibiotics has lagged far behind our growing need for such drugs. Rather than focusing on therapeutics that target in vitro viability, much like conventional antibiotics, an alternative approach is to target functions essential for infection, such as virulence factors required to cause host damage and disease. This approach has several potential advantages including expanding the repertoire of bacterial targets, preserving the host endogenous microbiome, and exerting less selective pressure, which may result in decreased resistance. We review new approaches to targeting virulence, discuss their advantages and disadvantages, and propose that in addition to targeting virulence, new antimicrobial development strategies should be expanded to include targeting bacterial gene functions that are essential for in vivo viability. We highlight both new advances in identifying these functions and prospects for antimicrobial discovery targeting this unexploited area.     

The eco-field: A new paradigm for landscape ecology

In the spirit of the theory of biocomplexity and of the non-linear emergent characters of ecological systems, the eco-field is a new paradigm that integrates the vision of the landscape as a neutral matrix (like a habitat) in which organisms are living, and contemporarily as a product of the human mind. Eco-field is defined a cognitive field created by the interference between functional traits and the real world. Species-specific environmental suitability is the result of the quality of the different eco-fields and the landscape becomes a cognitive entity. The eco-field paradigm can be extended to the emergent properties of the systems. The eco-field of emergences is the geographic space in which the emergent properties appear. The eco-field of organisms and the eco-field of emergences, like results of aggregated entities, have in common the multidimensionality of landscapes, refusing the vision of landscape like a neutral geographic matrix for organisms and processes.     

The genetics of cystic fibrosis: a paradigm for uncovering new drug targets

A broad-based approach will be required for the development of new therapies for cystic fibrosis lung disease. Recently, rapid progress has been made in identifying and testing a number of gene transfer vectors, including adenoviral vectors and liposomes. Major problems, however, have been identified with respect to the efficiency of these systems. Preliminary studies suggest that small molecules (e.g. amelioride and UTP) may normalize the clearance of secretions from the cystic fibrosis lung. The concept of recombinant protein based therapy for cystic fibrosis has now been realized with the successful application of DNase in clinical trials.     

Venomics: a new paradigm for natural products-based drug discovery

The remarkable potency and pharmacological diversity of animal venoms has made them an increasingly valuable source of lead molecules for drug and insecticide discovery. Nevertheless, most of the chemical diversity encoded within these venoms remains uncharacterized, despite decades of research, in part because of the small quantities of venom available. However, recent advances in the miniaturization of bioassays and improvements in the sensitivity of mass spectrometry and NMR spectroscopy have allowed unprecedented access to the molecular diversity of animal venoms. Here, we discuss these technological developments in the context of establishing a high-throughput pipeline for venoms-based drug discovery.     

Prodrugs as self-assembled hydrogels: a new paradigm for biomaterials

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Highlights► Development of prodrug-based self-assembled hydrogels as a new class of biomaterials. ► Design of prodrugs that can self-assemble to form hydrogels. ► These hydrogels overcome limitations such as low-drug loading and burst release of drugs. ► Locally injectable self-assembled hydrogels exhibit potential as effective therapeutics.     

Molecular anthropology: Toward a new evolutionary paradigm

Molecular anthropology: Toward a new evolutionary paradigm     

Weed-induced crop yield loss: a new paradigm and new challenges

Direct competition for resources is generally considered the primary mechanism for weed-induced yield loss. A re-evaluation of physiological evidence suggests weeds initially impact crop growth and development through resource-independent interference. We suggest weed perception by crops induce a shift in crop development, before resources become limited, which ultimately reduce crop yield, even if weeds are subsequently removed. We present the mechanisms by which crops perceive and respond to weeds and discuss the technologies used to identify these mechanisms. These data lead to a fundamental paradigm shift in our understanding of how weeds reduce crop yield and suggest new research directions and opportunities to manipulate or engineer crops and cropping systems to reduce weed-induced yield losses.     

Natural computing and biological evolution: a new paradigm

After a brief outline of the available hypotheses on the mechanism of biological evolution, attention is called on the global nature of the variations leading to the generation of new species. Integrated changes may hardly be attributed to beneficial random mutations of single traits even if assisted by a phylogenetic elimination of poorly adapted individuals. Rather, integrated variations are likely to reflect the outcome of cybernetic algorithms (natural computing) operating on organism's resources and impending environmental changes. As all organisms are endowed with computing capacities that modulate and integrate ontogenetic development and maintenance of biological functions, structures, and behaviors, these capacities are assumed to have moulded the evolutionary variations of organisms, and their transfer to the progeny.     

Artificial molecular sieves and filters: a new paradigm for biomolecule separation

Patterned regular sieves and filters with comparable molecular dimensions hold great promise as an alternative to conventional polymeric gels and fibrous membranes to improve biomolecule separation. Recent developments of microfabricated nanofluidic sieves and filters have demonstrated superior performance for both analytical and preparative separation of various physiologically relevant macromolecules, including proteins. The insights gained from designing these artificial molecular sieves and filters, along with the promising results gathered from their first applications, serve to illustrate the impact that they can have on improving future separation of complex biological samples. Further development of artificial sieves and filters with more elaborate geometrical constraints and tailored surface functionality is believed to provide more promising ideals and results for biomolecule separation, which has great implications for proteomic research and biomarker discovery.     

Seaweed attachment to bedrock: biophysical evidence for a new geophycology paradigm

Seaweeds are amongst the most obvious and ecologically important components of rocky shore communities worldwide but until now little has been known about the processes involved in their attachment. This multidisciplinary study investigated for the first time the interactions between marine macroalgal holdfasts and their underlying substrata, requiring the development of specialized sample preparation techniques to maintain the structural integrity of the holdfast–bedrock interface. Transmitted plane polarized light microscopy, scanning electron microscopy with energy dispersive spectroscopy and structured light illumination microscopy were used in the examination of the interface between Ascophyllum nodosum (Fucales, Heterokontophyta) and crustose red algae Lithothamnion sp. (Corallinales, Rhodophyta) on granite and limestone substrates. The new evidence presented here represents a paradigm shift in the way we view seaweed attachment because results show that the holdfasts exploit the physical characteristics of the rock-forming minerals in order to penetrate the bedrock and thus facilitate the attachment process. Mineral cleavage planes together with intercrystalline and intracrystalline boundaries and fractures provide penetration pathways for the holdfast tissue. This process causes disaggregation of rock-forming minerals to depths <10 mm and therefore assists in the bioerosion of coastal bedrock. It is concluded that seaweeds are able to cause weathering of natural rock and the term 'geophycology' is introduced to describe seaweed–bedrock interactions, including seaweed-induced weathering.