|
Microbial biogeography is a subset of biogeography, a field that concerns the distribution of organisms across space and time. Although biogeography traditionally focused on plants and larger animals, recent studies have broadened this field to include distribution patterns of microorganisms. This extension of biogeography to smaller scales—known as "microbial biogeography"—is enabled by ongoing advances in genetic technologies. The aim of microbial biogeography is to reveal where microorganisms live, at what abundance, and why. Microbial biogeography can therefore provide insight into the underlying mechanisms that generate and hinder biodiversity. Microbial biogeography also enables predictions of where certain organisms can survive and how they respond to changing environments, making it applicable to several other fields such as climate change research. == Microbial vs macro-organism biogeography == The biogeography of macro-organisms (i.e., plants and animals that can be seen with the naked eye) has been studied since the eighteenth century. For macro-organisms, biogeographical patterns (i.e., which organism assemblages appear in specific places and times) appear to arise from both past and current environments. For example, polar bears live in the Arctic but not the Antarctic, while the reverse is true for penguins; although both polar bears and penguins have adapted to cold climates over many generations (the result of past environments), the distance and warmer climates between the north and south poles prevent these species from spreading to the opposite hemisphere (the result of current environments). This demonstrates the biogeographical pattern known as "isolation with geographic distance" by which the limited ability of a species to physically disperse across space (rather than any selective genetic reasons) restricts the geographical range over which it can be found. The biogeography of microorganisms (i.e., organisms that cannot be seen with the naked eye, such as fungi and bacteria) is an emerging field enabled by ongoing advancements in genetic technologies, in particular cheaper DNA sequencing with higher throughput that now allows analysis of global datasets on microbial biology at the molecular level. When scientists began studying microbial biogeography, they anticipated a lack of biogeographic patterns due to the high dispersability and large population sizes of microbes, which were expected to ultimately render geographical distance irrelevant. Indeed, in microbial ecology the oft-repeated saying by Lourens Baas Becking that “everything is everywhere, but the environment selects” has come to mean that as long as the environment is ecologically appropriate, geological barriers are irrelevant. However, recent studies show clear evidence for biogeographical patterns in microbial life, which challenge this common interpretation: the existence of microbial biogeographic patterns disputes the idea that “everything is everywhere” while also supporting the idea that environmental selection includes geography as well as historical events that can leave lasting signatures on microbial communities.〔 Microbial biogeographic patterns are often similar to those of macro-organisms. Microbes generally follow well-known patterns such as the distance decay relationship, the abundance-range relationship, and Rapoport's rule. This is surprising given the many disparities between microorganisms and macro-organisms, in particular their size (micrometers vs. meters), time between generations (minutes vs. years), and dispersabilitiy (global vs. local). However, important differences between the biogeographical patterns of microorganism and macro-organism do exist, and likely result from differences in their underlying biogeographic processes (e.g., drift, dispersal, selection, and mutation). For example, dispersal is an important biogeographical process for both microbes and larger organisms, but small microbes can disperse across much greater ranges and at much greater speeds by traveling through the atmosphere (for larger animals dispersal is much more constrained due to their size).〔 As a result, many microbial species can be found in both northern and southern hemispheres, while larger animals are typically found only at one pole rather than both. 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Microbial biogeography」の詳細全文を読む スポンサード リンク
|