Asystem is simply a combination ofcomponents that function together. A biologist can srudy a system at any level of organization. A single leaf cell can be considered a system, as can a frog, an ant colony, or a desert ecosytem_ To understand how such systems work, it is not enough to have a "parts list", even a complete one. Realizing this, many researchers are now complementing the reductionist approach with new strategies for studying whole systems. This changing perspective is analogous to moving from ground level on a street corner to a helicopter high above a city, from which you can see how variables such as time of day, construction projects, accidents, and traffic-signal malfunctions affect traffic throughout the city.
The goal of systems biology is to construct models for the dynamic behavior of whole biological systems. Successful models enable biologists to predict how a change in one or more variables will affect other components and the whole system. Thus, the systems approach enables us to pose new kinds of questions. How might a drug that lowers blood pressure affect the functions of organs throughout the human body? How might increasing a crop's water supply affect processes in the plants, such as the storage of molecules essential for human nutrition? How might a gradual increase in atmospheric carbon dioxide alter ecosystems and the entire biosphere? The ultimate aim of systems biology is to answer big questions like the last one.
Systems biology is relevant to the study of life at all levels. During the early years of the 20th century, biologists studying animal physiology (functioning) began integrating data on how multiple organs coordinate processes such as the regulation of sugar concentration in the blood. And in the 1960s, scientists investigating ecosystems pioneered a more mathematically sophisticated systems approach with elaborate models diagramming the network of interactions between organisms and nonliving components of ecosystems such as salt marshes. Such models have already been useful for predicting the responses of these systems to changing variables. More recently, systems biology has taken hold at the cellular and molecular levels, as we'll describe later when we discuss DNA.
Theme: Organisms interact with their environments, exchanging matter and energy
Turn back again to Figure 1.4, this time focusing on the forest. In this or any other ecosystem, each organism interacts continuously with its environment, which includes both nonliving factors and other organisms. A tree, for example, absorbs water and minerals from the soil, through its roots. At the same time, its leaves take in carbon dioxide from the air and
use sunlight absorbed by chlorophyll to drive photosynthesis, converting water and carbon dioxide to sugar and oxygen. The tree releases oxygen to the air, and its roots help form soil by breaking up rocks. Both organism and environment are affected by the interactions between them. The tree also interacts with other organisms, such as soil microorganisms associated with its roots and animals that eat its leaves and fruit.
Ecosystem Dynamics
The operation ofany ecosystem involves two major processes. One process is the cycling of nutrients. For example, minerals acquired by a tree will eventually be returned to the soil by organisms that decompose leaf litter, dead roots, and other organic debris. The second major process in an ecosystem is the one-way flow of energy from sunlight to producers to consumers. Producers are plants and other photosynthetic organisms, which use light energy to make sugar. Consumers are organisms, such as animals, that feed on producers and other consumers. The diagram in Figure 1.5 outlines the two processes acting in an African ecosystem.
Energy Conversion
Moving, growing, reproducing, and the other activities of life are work, and work requires energy. The exchange of energy between an organism and its surroundings often involves the transformation of one form ofenergy to another. For example, the leaves ofa plant absorb light energy and convert it to chemical energy stored in sugar molecules. When an animal's muscle
cells use sugar as fuel to power movements, they convert chemical energy to kinetic energy, the energy of motion. And in all these energy conversions, some ofthe energy is converted to thermal energy, which dissipates to the surroundings as heat. In contrast to chemical nutrients, which recycle within an ecosystem, energy flows through an ecosystem, usually entering
as light and exiting as heat (see Figure 1.5).
source: Campbell and Reece book
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