Answer:
Material A b
Explanation:
You can tell when they collide
The ecumenical thought of utilizing the trophic level with conventional parasites (fleas, ticks, and tapeworms) Would be that parasites are consumers. A symbiotic-relationship, a procedure enacted to survive. Parasitism is the act of one parasite surviving off of another organism (host). Parasites may affect hosts differently than predators affect prey. While a predatory animal murder copious individuals during its life, a parasite prevails sustenance from an undivided host during a life stage. Similar to omnivores, some parasites can extend their dependencies with their nutrients and prefer multiple trophic levels, not just one.
(Psst, I hope I facilitated you with the explanation. I am moderately atrocious at explicating matters, dismal.)
Multiple choice---
The answer to number two, would be "D", as "transpiration" is the diametric occurrence to all the other processes. Rather bounteously returning carbon dioxide, it actually holds the carbon dioxide, happening in the stomata, opening itself up to "breathing in" the carbon dioxide, and release oxygen.
The result to number three, would be "D", as "change of seasons" would not be possible for such things like forests. The alteration would not occur in an antecedently damaged area, for change has been interrupted and requires time to fixate.
The solution to number four, would be "B", as plant-life occurrences is an augury of a primary succession and that an environment has begun commencement or is now fixated.
Answer:
Nervous systems become clearly unique in their communication properties only at the tissue and organ level, where billions of cells can work together as an intricately organized interconnected circuit. It is through the organization of cells in these neural circuits that the brain supports the great diversity of animal behavior, up to and including human consciousness, cognition, and emotion.
Explanation:
Communication, the effective delivery of information, is essential for life at all scales and species. Nervous systems (by necessity) can adapt more specifically between biological tissues for the high speed and complexity of the information transmitted, and therefore, the properties of neural tissue and the principles of its circuit organization can illuminate the capabilities and limitations of biological communication. Here, we consider recent developments in tools to study neural circuits with special attention to defining neural cell types using input and output information flows, that is, how they communicate. Complementing the approaches that define cell types by virtue of the properties of the genetic promoter / enhancer, this communication-based approach to define cell types operably by the structure and function of linkages of input / output relationships (E / S), solves the difficulties associated with defining unique genetic characteristics. , leverages technology to observe and test the importance of precisely these I / O ratios in intact brains, and maps processes through which behavior can adapt during development, experience, and evolution.
No beacuse the other layer may be to cold or hot for humans to survive in
