TY  - JOUR
A1  - Krause, Sascha
A1  - Le Roux, Xavier
A1  - Niklaus, Pascal A.
A1  - Van Bodegom, Peter M.
A1  - Lennon, Jay T.
A1  - Bertilsson, Stefan
A1  - Grossart, Hans-Peter
A1  - Philippot, Laurent
A1  - Bodelier, Paul L. E.
T1  - Trait-based approaches for understanding microbial biodiversity and ecosystem functioning
JF  - Frontiers in microbiology
N2  - In ecology, biodiversity-ecosystem functioning (BEE) research has seen a shift in perspective from taxonomy to function in the last two decades, with successful application of trait-based approaches. This shift offers opportunities for a deeper mechanistic understanding of the role of biodiversity in maintaining multiple ecosystem processes and services. In this paper, we highlight studies that have focused on BEE of microbial communities with an emphasis on integrating trait-based approaches to microbial ecology. In doing so, we explore some of the inherent challenges and opportunities of understanding BEE using microbial systems. For example, microbial biologists characterize communities using gene phylogenies that are often unable to resolve functional traits. Additionally, experimental designs of existing microbial BEE studies are often inadequate to unravel BEE relationships. We argue that combining eco-physiological studies with contemporary molecular tools in a trait-based framework can reinforce our ability to link microbial diversity to ecosystem processes. We conclude that such trait-based approaches are a promising framework to increase the understanding of microbial BEE relationships and thus generating systematic principles in microbial ecology and more generally ecology.
KW  - functional traits
KW  - ecosystem function
KW  - ecological theory
KW  - study designs
KW  - microbial diversity
Y1  - 2014
U6  - https://doi.org/10.3389/fmicb.2014.00251
SN  - 1664-302X
VL  - 5
PB  - Frontiers Research Foundation
CY  - Lausanne
ER  - 
TY  - JOUR
A1  - Tang, Kam W.
A1  - Gladyshev, Michail I.
A1  - Dubovskaya, Olga P.
A1  - Kirillin, Georgiy
A1  - Grossart, Hans-Peter
T1  - Zooplankton carcasses and non-predatory mortality in freshwater and inland sea environments
JF  - Journal of plankton research
N2  - Zooplankton carcasses are ubiquitous in marine and freshwater systems, implicating the importance of non-predatory mortality, but both are often overlooked in ecological studies compared with predatory mortality. The development of several microscopic methods allows the distinction between live and dead zooplankton in field samples, and the reported percentages of dead zooplankton average 11.6 (minimum) to 59.8 (maximum) in marine environments, and 7.4 (minimum) to 47.6 (maximum) in fresh and inland waters. Common causes of non-predatory mortality among zooplankton include senescence, temperature change, physical and chemical stresses, parasitism and food-related factors. Carcasses resulting from non-predatory mortality may undergo decomposition leading to an increase in microbial production and a shift in microbial composition in the water column. Alternatively, sinking carcasses may contribute significantly to vertical carbon flux especially outside the phytoplankton growth seasons, and become a food source for the benthos. Global climate change is already altering freshwater ecosystems on multiple levels, and likely will have significant positive or negative effects on zooplankton non-predatory mortality. Better spatial and temporal studies of zooplankton carcasses and non-predatory mortality rates will improve our understanding of this important but under-appreciated topic.
KW  - carbon flux
KW  - inland waters
KW  - lakes
KW  - live
KW  - dead sorting
KW  - non-predatory mortality
KW  - zooplankton carcasses
Y1  - 2014
U6  - https://doi.org/10.1093/plankt/fbu014
SN  - 0142-7873
SN  - 1464-3774
VL  - 36
IS  - 3
SP  - 597
EP  - 612
PB  - Oxford Univ. Press
CY  - Oxford
ER  - 
TY  - JOUR
A1  - Hepworth, Jo
A1  - Lenhard, Michael
T1  - Regulation of plant lateral-organ growth by modulating cell number and size
JF  - Current opinion in plant biology
N2  - Leaves and floral organs grow to distinct, species-specific sizes and shapes. Research over the last few years has increased our understanding of how genetic pathways modulate cell proliferation and cell expansion to determine these sizes and shapes. In particular, the timing of proliferation arrest is an important point of control for organ size, and work on the regulators involved is showing how this control is achieved mechanistically and integrates environmental information. We are also beginning to understand how growth differs in different organs to produce their characteristic shapes, and how growth is integrated between different tissues that make up plant organs. Lastly, components of the general machinery in eukaryotic cells have been identified as having important roles in growth control.
Y1  - 2014
U6  - https://doi.org/10.1016/j.pbi.2013.11.005
SN  - 1369-5266
SN  - 1879-0356
VL  - 17
SP  - 36
EP  - 42
PB  - Elsevier
CY  - London
ER  - 
TY  - JOUR
A1  - Gechev, Tsanko S.
A1  - Hille, Jacques
A1  - Woerdenbag, Herman J.
A1  - Benina, Maria
A1  - Mehterov, Nikolay
A1  - Toneva, Valentina
A1  - Fernie, Alisdair
A1  - Müller-Röber, Bernd
T1  - Natural products from resurrection plants: Potential for medical applications
JF  - Biotechnology advances : an international review journal ; research reviews and patent abstracts
N2  - Resurrection species are a group of land plants that can tolerate extreme desiccation of their vegetative tissues during harsh drought stress, and still quickly often within hours regain normal physiological and metabolic functions following rehydration. At the molecular level, this desiccation tolerance is attributed to basal cellular mechanisms including the constitutive expression of stress-associated genes and high levels of protective metabolites present already in the absence of stress, as well as to transcriptome and metabolome reconfigurations rapidly occurring during the initial phases of drought stress. Parts of this response are conferred by unique metabolites, including a diverse array of sugars, phenolic compounds, and polyols, some of which accumulate to high concentrations within the plant cell. In addition to drought stress, these metabolites are proposed to contribute to the protection against other abiotic stresses and to an increased oxidative stress tolerance. Recently, extracts of resurrection species and particular secondary metabolites therein were reported to display biological activities of importance to medicine, with e.g. antibacterial, anticancer, antifungal, and antiviral activities, rendering them possible candidates for the development of novel drug substances as well as for cosmetics. Herein, we provide an overview of the metabolite composition of resurrection species, summarize the latest reports related to the use of natural products from resurrection plants, and outline their potential for medical applications. (C) 2014 The Authors. Published by Elsevier Inc. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/3.0/).
KW  - Antibacterial
KW  - Anticancer
KW  - Antifungal
KW  - Antiviral
KW  - Natural product
KW  - Resurrection plant
KW  - Secondary metabolite
KW  - Synthetic biology
Y1  - 2014
U6  - https://doi.org/10.1016/j.biotechadv.2014.03.005
SN  - 0734-9750
SN  - 1873-1899
VL  - 32
IS  - 6
SP  - 1091
EP  - 1101
PB  - Elsevier
CY  - Oxford
ER  -