Mendel's Peas and Hawkweeds

A study of Mendel's peas and Hawkweed has been cited and many scientists have contributed to the field of genetics. However, basic research on today's modern genetics can be found in a single person, Gregor Mendel's research. Many scientists have tried to answer the same question in front of him, but no one can conclude about his success. Before Mendel's experiments there are many other theories that can answer questions about the reasons we look like parents. Many of these beliefs are myths, and because creation is the belief of most people, there is no real reason behind the inquiry quest.

After peas. Mendel kept interest in science for several years since he was published. He attempted a cross test between Mr. Eagle and Mr. Bee and became a detailed record holder of weather data and astronomical data. He was elected as his Diocese abbot in 1868 and became a political activist in his later years, during which he protested against taxing his parish. At the age of 61, he died of renal failure

Mendel also tried Hawkweed (Hieracium) and a bee. He published a report on his collaboration with Hawkweed, a group of plants scientists were very interested at that time due to their diversity. But Mendel's genetic research in the hawks was different from his results on peas; the first generation has changed significantly, and many of their descendants were the same as maternal parents. In communication with CarlNägeli, he talked about his results but could not explain them. Until the end of the nineteenth century, many wild plant species were asexual, producing most of the seeds through asexual reproduction.

In the middle of Mendel's life, Mendel did a new job of genetic theory. By using pea sheath plants, Mendel studied the seven basic features of pea sheath plants. By tracking these characteristics Mendel discovered three basic rules that control the functions passed from members.

This outdated idea comes from seeds planted 150 years ago by Gregor Mendel in the Pea Valley. Mendel spent seven years cultivating peas in the garden of a five-acre monastery in the town of Brno (now part of the Czech Republic). He mated with rumpled peas and smooth pea plants, making a total of 29,000 plants. When he finished and when he already ran the number, he exposed the gene. Of course, Mendel published a conceptual gene, not a physical gene (which will appear in the first century). The conceptual gene clarified by this mathematically friendly monk's table and calculation seems to be neatly neat agent. Thousands of ports in Mendel indicate that he studied that property - for example, a wrinkled smooth skin, or a white purple flower - appears or disappears in a definite formula that determines a consistent ratio . Inheritance seems to work algebraically. All mathematically easy-to-handle things need to be driven with discrete integers.

For decades, by a selfish genetic metaphor, we were able to see evolution with new clarity. Does it surprise us now?