Difference between revisions of "The History Of Free Evolution In 10 Milestones"

What is Free Evolution?

Free evolution is the concept that natural processes can cause organisms to develop over time. This includes the creation of new species and the transformation of the appearance of existing species.

Numerous examples have been offered of this, including different varieties of fish called sticklebacks that can be found in salt or fresh water, as well as walking stick insect varieties that prefer specific host plants. These typically reversible traits do not explain the fundamental changes in the body's basic plans.

Evolution through Natural Selection

Scientists have been fascinated by the evolution of all the living organisms that inhabit our planet for ages. The most well-known explanation is that of Charles Darwin's natural selection process, a process that occurs when better-adapted individuals survive and reproduce more successfully than those who are less well-adapted. Over time, a population of well adapted individuals grows and eventually creates a new species.

Natural selection is a process that is cyclical and involves the interaction of 3 factors: variation, reproduction and inheritance. Variation is caused by mutations and sexual reproduction both of which increase the genetic diversity of an animal species. Inheritance refers to the transmission of genetic traits, which include both dominant and recessive genes and their offspring. Reproduction is the process of producing viable, fertile offspring, which includes both asexual and sexual methods.

Natural selection can only occur when all these elements are in harmony. If, for instance an allele of a dominant gene causes an organism reproduce and survive more than the recessive allele, then the dominant allele will become more prevalent in a population. If the allele confers a negative survival advantage or lowers the fertility of the population, it will go away. This process is self-reinforcing meaning that an organism with a beneficial trait is more likely to survive and reproduce than one with an inadaptive trait. The more offspring an organism produces the better its fitness that is determined by its ability to reproduce itself and live. People with good characteristics, like having a longer neck in giraffes, or bright white colors in male peacocks are more likely to survive and produce offspring, which means they will make up the majority of the population over time.

Natural selection is only a factor in populations and not on individuals. This is a significant distinction from the Lamarckian theory of evolution which argues that animals acquire characteristics through use or disuse. For instance, if the animal's neck is lengthened by reaching out to catch prey its offspring will inherit a longer neck. The difference in neck size between generations will continue to grow until the giraffe is no longer able to breed with other giraffes.

Evolution by Genetic Drift

Genetic drift occurs when alleles of the same gene are randomly distributed in a group. In the end, one will attain fixation (become so common that it is unable to be removed by natural selection), while other alleles will fall to lower frequencies. In the extreme, this leads to a single allele dominance. The other alleles are eliminated, and 에볼루션 무료체험 heterozygosity falls to zero. In a small group it could lead to the total elimination of recessive allele. This scenario is called the bottleneck effect. It is typical of an evolutionary process that occurs whenever an enormous number of individuals move to form a group.

A phenotypic bottleneck may also occur when the survivors of a catastrophe such as an outbreak or a mass hunting incident are concentrated in an area of a limited size. The survivors will share an allele that is dominant and will have the same phenotype. This may be caused by a war, earthquake, or even a plague. Whatever the reason the genetically distinct group that remains is prone to genetic drift.

Walsh Lewens, Walsh, and Ariew define drift as a deviation from the expected value due to differences in fitness. They cite the famous example of twins that are genetically identical and share the same phenotype. However, 에볼루션 사이트 one is struck by lightning and dies, but the other continues to reproduce.

This kind of drift can be crucial in the evolution of the species. It is not the only method of evolution. The most common alternative is a process called natural selection, where the phenotypic diversity of a population is maintained by mutation and migration.

Stephens claims that there is a significant distinction between treating drift as a force or an underlying cause, 무료에볼루션 and treating other causes of evolution such as selection, mutation and migration as causes or causes. He argues that a causal mechanism account of drift allows us to distinguish it from the other forces, and 에볼루션 슬롯게임 that this distinction is crucial. He further argues that drift has a direction: that is it tends to eliminate heterozygosity, and that it also has a size, that is determined by the size of population.

Evolution by Lamarckism

Students of biology in high school are frequently introduced to Jean-Baptiste Lamarck's (1744-1829) work. His theory of evolution, also referred to as "Lamarckism which means that simple organisms develop into more complex organisms through adopting traits that are a product of the use and abuse of an organism. Lamarckism can be illustrated by an giraffe's neck stretching to reach higher levels of leaves in the trees. This causes the longer necks of giraffes to be passed to their offspring, who would then become taller.

Lamarck the French Zoologist, introduced an idea that was revolutionary in his opening lecture at the Museum of Natural History of Paris. He challenged the previous thinking on organic transformation. According to Lamarck, living creatures evolved from inanimate matter by a series of gradual steps. Lamarck wasn't the first to propose this but he was regarded as the first to give the subject a comprehensive and general explanation.

The dominant story is that Charles Darwin's theory on natural selection and Lamarckism were rivals in the 19th Century. Darwinism eventually won and led to the development of what biologists now call the Modern Synthesis. This theory denies acquired characteristics can be passed down and instead argues that organisms evolve through the influence of environment factors, including Natural Selection.

While Lamarck believed in the concept of inheritance through acquired characters and his contemporaries also paid lip-service to this notion, it was never a central element in any of their evolutionary theorizing. This is partly because it was never scientifically tested.

It's been over 200 years since the birth of Lamarck and in the field of age genomics there is a growing body of evidence that supports the heritability of acquired traits. This is referred to as "neo Lamarckism", or more generally epigenetic inheritance. It is a version of evolution that is just as relevant as the more popular Neo-Darwinian model.

Evolution by adaptation

One of the most common misconceptions about evolution is that it is driven by a sort of struggle to survive. In fact, this view is a misrepresentation of natural selection and ignores the other forces that determine the rate of evolution. The fight for survival can be more effectively described as a struggle to survive in a specific environment, which can be a struggle that involves not only other organisms but as well the physical environment.

To understand how evolution operates, it is helpful to consider what adaptation is. Adaptation is any feature that allows a living organism to survive in its environment and reproduce. It could be a physiological feature, like feathers or fur, or a behavioral trait such as a tendency to move to the shade during the heat or leaving at night to avoid cold.

The capacity of an organism to extract energy from its environment and interact with other organisms as well as their physical environment is essential to its survival. The organism must have the right genes to produce offspring, and must be able to access enough food and other resources. The organism must also be able to reproduce itself at a rate that is optimal for its niche.

These factors, in conjunction with mutations and gene flow can cause a shift in the proportion of different alleles in a population’s gene pool. This change in allele frequency can result in the emergence of novel traits and eventually new species as time passes.

Many of the features that we admire about animals and plants are adaptations, for example, the lungs or gills that extract oxygen from the air, feathers or fur for insulation and long legs for running away from predators, and camouflage for hiding. To understand the concept of adaptation it is crucial to discern between physiological and behavioral traits.

Physiological adaptations, such as thick fur or gills are physical traits, while behavioral adaptations, such as the desire to find companions or to move to shade in hot weather, are not. It is also important to remember that a lack of planning does not cause an adaptation. Inability to think about the implications of a choice even if it seems to be rational, may make it unadaptive.