Fungi cell walls are made of chitin and other polysaccharides, not cellulose (Plants) or protein (Animals). Therefore your answer is-
"The cell walls of fungi are different than the cell walls of plants because they contain the hard material of chitin"
Unfortunately I don’t think your question was typed correctly unfortunately. But I’ll try my best!
Interphase, Prophase, Metaphase, Anaphase, Telophase and Cytokinesis (these tend to be lumped together in my classes.)
I remember them in a weird way.
Interphase- In rest/chaos (depending on how you want to look at it). The DNA is all jumbled up inside the nucleus, just chilling and doing its normal stuff.
Prophase-proper. The DNA now decides hey, time to get our stuff together and get into our chromosomes.
Metaphase-middle. The chromosomes line up at the metaphasal plate, ready to get splitting (and a bunch of other junk, depending on which mitosis we’re talking about.)
Anaphase- apart. Now that the chromosomes have done their duties, we now have chromaTIDS (tidbit chromosomes) who get pulled to opposite ends of the cell.
Telophase/Cytokinesis- “tear apart” and a new cytoplasm! Now we’ve got new daughter cells!
Answer:
Used cross breeding to purposely breed plants. Studied a variety of pea plant traits. studied several generations of pea plants.
Explanation:
Answer:
B. runoff of nitrates from fertilizers applied to the golf course
Explanation:
Algal bloom is defined as the rapid growth of algae in freshwater or marine water. Algal bloom is green or yellowish in color that cover the top layer of water systems.
Algal bloom in the given case is caused by the excess of nutrients that is nitrates from fertilizers into waters and higher concentrations of nitrates causes uncontrollable growth of algae.
Algal blooms are harmful for environment as they may produce toxins and can block the sunlight from reaching the plants and animals in the water systems.
Hence, the correct answer is "B. runoff of nitrates from fertilizers applied to the golf course".
Explanation:
Water mostly enters a tree through the roots by osmosis and any dissolved mineral nutrients will travel with it upward through the inner bark's xylem (using capillary action) and into the leaves.