If a black Siberian Husky had pups with an English Mastiff, the offspring would inherit a combination of traits from both parents. In terms of dominant and recessive traits, it would depend on the specific genes involved.
In general, dominant traits are more likely to be expressed in the offspring. If the English Mastiff parent carries dominant traits for certain characteristics, such as size or coat color, those traits would likely be passed on to the puppies.
Recessive traits, on the other hand, are less likely to be expressed unless both parents contribute the recessive gene. If the black Siberian Husky parent carries recessive traits for certain characteristics, such as eye color or ear shape, the puppies would only inherit those traits if the English Mastiff parent also carries the recessive gene for them.
It's important to note that genetics is a complex subject and the inheritance of traits can vary greatly depending on the specific genes involved. Each puppy in the litter may inherit a different combination of traits from both parents, resulting in a unique appearance and characteristics.
To give you a clear example, let's say the black Siberian Husky parent carries the recessive gene for blue eyes, while the English Mastiff parent carries the dominant gene for brown eyes. If the English Mastiff also carries the recessive gene for blue eyes, there is a possibility that some of the puppies will have blue eyes. However, if the English Mastiff does not carry the recessive gene for blue eyes, all the puppies will likely have brown eyes.
In conclusion, when a black Siberian Husky and an English Mastiff have puppies, the resulting offspring will inherit a combination of traits from both parents. The expression of dominant and recessive traits will depend on the specific genes involved and the inheritance patterns of those genes.Answer:
Explanation:
The kingdom that includes the organism that causes Lyme disease would be monera.
Lyme disease is caused by bacteria in the Borrelia genus. The genus includes both burgdorferi and mayonii species.
Bacteria generally belong to the kingdom of organisms known as Monera. The kingdom is made up of unicellular organisms that are prokaryotic in nature. The cells of organisms in this kingdom lack nucleus as well as membrane-bound organelles.
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Answer:
b. the rotary flagella to change their rotation to allow the bacterium to change direction randomly
Explanation:
The bacterial flagella are made up of flagellin protein. The bacterial flagella is divided into three parts hook, filaments, and the basal body. Rotor is present in bacterial flagella which extends to the cytoplasm and makes C ring.
C ring contains several switch proteins that change the rotation of the flagella instantly in response to repellent or attractant which allows to change the direction of bacteria randomly. Bacterial Flagella can move clockwise and counterclockwise. Therefore the right answer is B.
b. tundra
c. humid continental
d. subarctic
Answer:
highland
Explanation:
I verified on a quiz that it is correct.
B) the carbon cycle is constantly repeating on earth's surface.
C) carbon changes form, but the total amount of carbon remains the same.
D) the carbon cycle includes many different steps and each step involves matter.
Answer:
The property of the carbon cycle that makes a good illustration of the conservation of matter is the C) carbon changes form, but the total amount of carbon remains the same.
Explanation:
The law of conservation of matter or conservation of mass states that the mass cannot be created or destroyed, only transformed. It means that the amount of mass is always the same in a closed system. In a chemistry reaction, the mass of reactants must be the same as the mass of the product.
The carbon cycle is composed of different carbon sinks: oceans, the atmosphere, the ground, and the below-ground superficies. Carbon circulates between different sink through chemical, physical, and geological processes that include photosynthesis, respiration, decomposition, and the burning of fossil fuels. Through these processes, carbon travels between sinks; but the sum of the quantity of carbon through all sinks are the same because the carbon cannot be created nor destroyed, only transformed.