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E. coli's hardiness, versatility, broad palate and ease of handling have made it the most intensively studied and best understood organism on the planet. However, research on E.coli has primarily examined it as a model organism, one that is abstracted from any natural history. But E. coli is far more than just a microbial lab rat. Rather, it is a highly diverse organism with a complex, multi-faceted niche in the wild. Recent studies of ‘wild’ E. coli have, for example, revealed a great deal about its presence in the environment, its diversity and genomic evolution, as well as its role in the human microbiome and disease. These findings have shed light on aspects of its biology and ecology that pose far-reaching questions and illustrate how an appreciation of E. coli's natural history can expand its value as a model organism.

Of all the non-human primate species studied by researchers, the rhesus macaque ( Macaca mulatta ) is likely the most widely used across biological disciplines. Rhesus macaques have thrived during the Anthropocene and now have the largest natural range of any non-human primate. They are highly social, exhibit marked genetic diversity, and display remarkable niche flexibility (which allows them to live in a range of habitats and survive on a variety of diets). These characteristics mean that rhesus macaques are well-suited for understanding the links between sociality, health and fitness, and also for investigating intra-specific variation, adaptation and other topics in evolutionary ecology.

The roundworm Caenorhabditis elegans has risen to the status of a top model organism for biological research in the last fifty years. Among laboratory animals, this tiny nematode is one of the simplest and easiest organisms to handle. And its life outside the laboratory is beginning to be unveiled. Like other model organisms, C. elegans has a boom-and-bust lifestyle. It feasts on ephemeral bacterial blooms in decomposing fruits and stems. After resource depletion, its young larvae enter a migratory diapause stage, called the dauer. Organisms known to be associated with C. elegans include migration vectors (such as snails, slugs and isopods) and pathogens (such as microsporidia, fungi, bacteria and viruses). By deepening our understanding of the natural history of C. elegans, we establish a broader context and improved tools for studying its biology.

From the northernmost tip of Scandinavia to the southernmost corner of Patagonia, and across six continents, house sparrows (Passer domesticus) inhabit most human-modified habitats of the globe. With over 7,000 articles published, the species has become a workhorse for not only the study of self-urbanized wildlife, but also for understanding life history and body size evolution, sexual selection and many other biological phenomena. Traditionally, house sparrows were studied for their adaptations to local biotic and climatic conditions, but more recently, the species has come to serve as a focus for studies seeking to reveal the genomic, epigenetic and physiological underpinnings of success among invasive vertebrate species. Here, we review the natural history of house sparrows, highlight what the study of these birds has meant to bioscience generally, and describe the many resources available for future work on this species.

The fern Ceratopteris richardii has been studied as a model organism for over 50 years because it is easy to grow and has a short life cycle. In particular, as the first homosporous vascular plant for which genomic resources were developed, C. richardii has been an important system for studying plant evolution. However, we know relatively little about the natural history of C. richardii. In this article, we summarize what is known about this aspect of C. richardii , and discuss how learning more about its natural history could greatly increase our understanding of the evolution of land plants.

Over the last two decades, the zebrafish has joined the ranks of premier model organisms for biomedical research, with a full suite of tools and genomic resources. Yet we still know comparatively little about its natural history. Here I review what is known about the natural history of the zebrafish, where significant gaps in our knowledge remain, and how a fuller appreciation of this organism's ecology and behavior, population genetics, and phylogeny can inform a variety of research endeavors.

The distribution of genomic variation across landscapes can provide insights into the complex interactions between the environment and the genome that influence the distribution of species, and mediate phenotypic adaptation to local conditions. High throughput sequencing technologies now offer unprecedented power to explore these interactions, allowing powerful inferences about historical processes of colonization, gene flow and divergence, as well as the identification of loci that mediate local adaptation. These ‘landscape genomic’ approaches have been validated in model species and are now being applied to nonmodel organisms, including foundation species that have substantial effects on ecosystem processes. Here we review the growing field of landscape genomics from a very broad perspective. In particular, we describe the inferential power that is gained by taking a genome-wide view of genetic variation, strategies for study design to best capture adaptive variation, and how to apply this information to practical challenges, such as restoration.

Despite the large variety of insect species with divergent morphological, developmental and physiological features questions on gene function could for a long time only be addressed in few model species. The adaption of the bacterial CRISPR-Cas system for genome editing in eukaryotic cells widened the scope of the field of functional genetics: for the first time the creation of heritable genetic changes had become possible in a very broad range of organisms. Since then, targeted genome editing using the CRISPR-Cas technology has greatly increased the possibilities for genetic manipulation in non-model insects where molecular genetic tools were little established. The technology allows for site-specific mutagenesis and germline transformation. Importantly, it can be used for the generation of gene knock-outs, and for the knock-in of transgenes and generation of gene-reporter fusions. CRISPR-Cas induced genome editing can thus be applied to address questions in basic research in various insect species and other study organisms. Notably, it can also be used in applied insect biotechnology to design new pest and vector control strategies such as gene drives and precision guided Sterile Insect Technique. However, establishing CRISPR in a new model requires several practical considerations that depend on the scientific questions and on the characteristics of the respective study organism. Therefore, this review is intended to give a literature overview on different CRISPR-Cas9 based methods that have already been established in diverse insects. After discussing some required pre-conditions of the study organism, we provide a guide through experimental considerations when planning to conduct CRISPR-Cas9 genome editing, such as the design and delivery of guide RNAs, and of Cas9 endonuclease. We discuss the use of different repair mechanisms including homology directed repair (HDR) for a defined insertion of genetic elements. Furthermore, we describe different molecular methods for genetic screening and the use of visible markers. We focus our review on experimental work in insects, but due to the ubiquitous functionality of the CRISPR-Cas system many considerations are transferable to other non-model organisms.

Investigating the Tad pilus nanomachine in a genetically tractable, non-pathogenic organism like Caulobacter crescentus provides a powerful model for elucidating the architecture and functional dynamics of this widespread system. Insights gained from studying the Tad machinery can improve our understanding of related Tad pilus systems in pathogenic bacteria such as Aggregatibacter actinomycetemcomitans , where Tad pili are a key determinant of biofilm formation and chronic infection. Additionally, the remarkable functional diversity of Tad systems, ranging from surface sensing in C. crescentus to bacterial predation in Myxococcus xanthus , highlights their broad biological relevance. By revealing the in situ architecture of the Tad pilus biosynthetic machinery, this study advances our understanding of a major class of bacterial nanomachines and may thus provide structural insights that could inform the development of new therapeutic strategies targeting pilus-mediated virulence.

Antagonistic interactions are key drivers of microbial community dynamics in hypersaline environments. Here, we report, for the first time, a fan-shaped growth inhibition zone—an atypical phenotypic signature—resulting from synergistic antagonism between two halophilic archaeal species against a sensitive haloarchaeal strain. Using the model haloarchaeon Haloferax mediterranei , we identified a secreted precursor protein (HFX_0892) that is cleaved by a serine protease (such as HlyR4) to release an active antagonistic peptide (0892N). This novel form of archaeal interaction is defined as synergistic antagonism. The antagonistic activity of HFX_0892 is mediated by two α-helical motifs in its N-terminus, and this region can confer antimicrobial function when fused to other proteins. Notably, H. mediterranei encodes additional precursor proteins with potential antagonistic functions beyond HFX_0892. Our work identifies and elucidates a previously uncharacterized antagonistic interaction among archaea, providing critical insights into the complex interspecific interactions and microbial community assembly in hypersaline ecosystems.