Emerging horizons for industrial applications of predatory bacteria

26 p.-4 fig.-2 tab. The Ecology of Predation at the Microscale pp 173-194This chapter reviews the potential of the predatory bacteria Bdellovibrio bacteriovorus, an obligate predator of other gram-negative bacteria, as a biotechnological tool. Due to the unique lifestyle and the different applications, predatory bacteria have awakened interest to be developed as a lytic tool. The lack of physiological and metabolic information makes difficult this development. However, in the last years, different approaches have been described in order to understand the physiology, morphology, and metabolism of the predators, as well as the population dynamics of the prey-predator interactions. Besides its potential of “living antibiotic”, predatory bacteria have been proposed as a biocontrol agent in the food industry or aquaculture. A recent work using B. bacteriovorus as a biological lytic tool for the recovery of intracellular bioproducts highlighted the potential use of predators in industrial bioprocesses. The bottlenecks of using other Bdellovibrio and like organisms (BALOs) have been also considered and discussed during this chapter.This work was supported by the European Union’s Horizon 2020 Research and Innovation Programme, grant agreement no. 760994-2 (ENGICOIN), the Spanish Ministry of Science, Innovation and Universities (BIO2017-83448-R) and the Community of Madrid (P2018/ NMT4389).Peer reviewe

Landscape Genomics: Understanding Relationships Between Environmental Heterogeneity and Genomic Characteristics of Populations

Landscape genomics is a rapidly advancing research field that combines population genomics, landscape ecology, and spatial analytical techniques to explicitly quantify the effects of environmental heterogeneity on neutral and adaptive genetic variation and underlying processes. Landscape genomics has tremendous potential for addressing fundamental and applied research questions in various research fields, including ecology, evolution, and conservation biology. However, the unique combination of different scientific disciplines and analytical approaches also constitute a challenge to most researchers wishing to apply landscape genomics. Here, we present an introductory overview of important concepts and methods used in current landscape genomics. For this, we first define the field and explain basic concepts and methods to capture different hypotheses of landscape influences on neutral genetic variation. Next, we highlight established and emerging genomic tools for quantifying adaptive genetic variation in landscape genomic studies. To illustrate the covered topics and to demonstrate the potential of landscape genomics, we provide empirical examples addressing a variety of research question, i.e., the investigation of evolutionary processes driving population differentiation, the landscape genomics of range expanding species, and landscape genomic patterns in organisms of special interest, including species inhabiting aquatic and terrestrial environments. We conclude by outlining remaining challenges and future research avenues in landscape genomics