what are two disadvantages of selective breeding

Ingredients that Americans consume, such cornstarch, high fructose corn, corn oil, soybean oil, olive oil, or granulated sugar, are made from several GMO crops.

A living thing is referred to as an organism. In general, molecules make up both living organisms and non-living objects. Nonetheless, a living creature can be distinguished from an inanimate object by its defining traits. One or more cells, for instance, make up an organism.

Biological Organisms: Living creatures with the ability to respond to stimuli, reproduce, grow, and maintain homeostasis. Organisms are categorized by taxonomy into specific groupings, such as multicellular animals, plants, and fungi, or unicellular microbes like protists, bacteria, and archaea.

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Answer:

Parasitism

Explanation:

One is benefit on the other hand the other is harmed

Dolphins are friendly animals to humans on the other hand humans can harm or torture dolphins by training them on force or kill them

Answer:

Human insulin is now made with a biotechnology called [genetic engineering/selective breeding]. (Genetic engineering)

• After scientists [copy/remove] the gene for insulin from a human cell, the gene is inserted into the DNA of [a bacterial/another human] cell. (Copy, a bacterial)

• After the combined DNA is placed inside a [bacterial/human] cell, it becomes a [bioreactor/transgenic] organism that makes human insulin. (bacterial, bioreactor)

Answer:

D. The difference in specific heat between altitude

Explanation:

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Answer: Ocean waters increase the rate of decomposition of garbage.

Explanation: I took the quiz

Answer:

the acquisition of genetic material from an ancestor.

Explanation:

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If one parent of a couple has Huntington's disease , 50 percent  of their children that would be expected to develop the disease  if both parents were heterozygous.

Huntington's disease is a brain condition in which brain cells, or neurons, in specific areas of the brain begin to degrade. As the neurons degenerate, the illness can cause hormonal disturbances, cognitive decline, and uncontrolled movements. Huntington's disease is a hereditary condition. It is handed down from generation to generation. If one of the parents has Huntington's disease, the child has a 50% risk of developing it as well. If the child does not contract the disease, he or she will not pass it on to their offspring. There is no family history of Huntington disease in 1% to 3% of individuals who have the disease.

In genetics, heterozygous means having received different versions (alleles) of a genomic marker from each biological parent. As a result, a person who is heterozygous for a genomic marker has two distinct forms of that marker.

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The term for the process by which mRNA is used to make a protein is "translation".

Translation is a key process in gene expression, whereby the sequence of nucleotides in mRNA is read and used to synthesize a protein. During translation, the mRNA is read by ribosomes, which use the sequence of nucleotides to assemble a specific sequence of amino acids into a protein. The sequence of amino acids determines the structure and function of the protein, and ultimately its role in the cell or organism.

The process of translation involves a complex series of steps, including the recognition and binding of mRNA by ribosomes, the selection and assembly of amino acids, and the folding and modification of the protein. Understanding the process of translation is essential for understanding the fundamental workings of cells and organisms, and has important implications for fields such as biotechnology and medicine.

Answer: This is because they might not have any predators or there NATURAL ENVIROMENT IS DIFFICULT to find or destroy

Explanation:

Speciation is the evolutionary process by which new species arise from existing ones.

Speciation occurs when a group of organisms becomes reproductively isolated from the rest of their population, preventing gene flow between the two groups.

There are three key requirements for speciation to occur:

Genetic isolation: This occurs when a group of individuals becomes separated from the rest of their population, either geographically or ecologically, and is prevented from interbreeding with them. This can lead to the accumulation of genetic differences between the two groups.

Genetic divergence: Once genetic isolation occurs, the two populations can begin to evolve separately. This can happen as a result of genetic drift, natural selection, or other evolutionary mechanisms, leading to the accumulation of genetic differences between the two groups.

Reproductive isolation: Over time, the genetic differences between the two groups may become so pronounced that members of the two populations are no longer able to interbreed successfully, even if they are brought back into contact with one another.

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Answer:

Based on the context provided, Malala's dad likely meant that "It's a good thing to come in second" because "You should learn to be a good loser, not just a good winner."

Given that the allele for fuzzy peaches is recessive and has a frequency of 0.7. This means that the frequency of the dominant allele (F) will be (1-0.7) = 0.3.

Let's use the Hardy-Weinberg equation to calculate the expected number of fuzzy peaches in a sample of 500:

p^2 + 2pq + q^2 = 1

where

p = frequency of the dominant allele (F) = 0.3

q = frequency of the recessive allele (f) = 0.7

The genotype frequencies can be calculated as follows:

FF = p^2 = (0.3)^2 = 0.09

Ff = 2pq = 2(0.3)(0.7) = 0.42

ff = q^2 = (0.7)^2 = 0.49

The expected frequency of fuzzy peaches (ff) is 0.49. Therefore, the expected number of fuzzy peaches in a sample of 500 would be:

Number of fuzzy peaches = expected frequency of fuzzy peaches x sample size

= 0.49 x 500

= 245

Therefore, you would expect to find 245 fuzzy peaches in a sample of 500.

Without numeric data or a data table, we can't calculate the percentage. However, generally the percentage is found by dividing the number predicted to lose habitat by the total, then multiply by 100.

The provided question does not contain any numerical data or a data table, thus we can't calculate the percentage of species predicted to lose habitat by 2050. However, assuming you have the necessary data from the study including the total number of species and the number predicted to lose habitat, you would divide the number of species predicted to lose habitat by the total number of species, then multiply the result by 100 to get the percentage. Ensure to round off your answer to the nearest whole percent as requested.

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Answer:

The five types of white blood cells are neutrophils, lymphocytes, monocytes, eosinophils, and basophils. They can be categorized into two groups based on their staining properties: granulocytes (neutrophils, eosinophils, and basophils) and agranulocytes (lymphocytes and monocytes).

Explanation:

Answer: E) The student should utilize a conceptual model that differentiates between the animal cell and plant cell in general and which type

of cell is better.

Explanation:

Structurally, plant and animal cells are very similar because they are both eukaryotic cells. They both contain membrane-bound organelles such as the nucleus, mitochondria, endoplasmic reticulum, golgi apparatus, lysosomes, and peroxisomes. Both also contain similar membranes, cytosol, and cytoskeletal elements.

Both animal and plant cells have mitochondria, but only plant cells have chloroplasts.

Animal cells have centrioles, centrosomes (discussed under the cytoskeleton), and lysosomes, whereas plant cells do not. Plant cells have a cell wall, chloroplasts, plasmodesmata, and plastids used for storage, and a large central vacuole, whereas animal cells do not.

The different types of plant cells include- collenchyma, sclerenchyma, parenchyma, xylem, and phloem.

Answer:

a group of people living in the same place or having a particular characteristic in common.

"the scientific community"

Explanation:

a forest of trees and undergrowth plants, inhabited by animals and rooted in soil containing bacteria and fungi

Answer:

Encouraging food growth for export would be one way to discourage food sovereignty

Explanation:

.This is because if the focus is on exporting food, it may lead to a situation where the domestic market is neglected, and food production is not geared towards meeting local needs. This could result in food shortages and make the local population dependent on imported food. In such a scenario, the control over food production and distribution would lie with external forces rather than local communities, which goes against the idea of food sovereignty.

The heliocentric theory of the cosmos, developed by Copernicus's theory, moved humans away from the actual centre of the universe. A theory of evolution was created by Charles Darwin.

It is possible to think of the Copernican and Darwinian Revolutions as the two phases of a single Scientific Revolution. Together, they marked the beginning of science in the contemporary sense: the study of natural laws as explanations.

According to the Darwinian Theory of Evolution, natural selection, which drives evolution, is skewed by the traits that organisms inherit from their ancestors. The capacity for adaptation is what aids organisms in natural selection-based evolution.

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Eat natural food. By reducing pesticide and fertilizer use, you at once assist in reducing the quantity of chemical contamination that affects many amphibian species. Avoid releasing environmental estrogens into the water.

A. Habitat A has greater living area that is suitable for bullfrogs.  O B. Habitat B has extra predators of bullfrogs.  O C. Habitat B consists of more sources for bullfrogs.  O D. Habitat A can aid a larger population of bullfrogs.

American bullfrogs occupy a extensive vary of each herbal and manmade habitats, inclusive of lakes, ponds, swamps, marshes, brackish waters, streams, rivers, ditches, and canals. They pick warm, sluggish or stagnant waters with abundant vegetation, however are additionally observed along the shores of lakes and banks of streams.

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The answer is 25 percent

Answer:

primate order and homo sapiens  

Explanation:

In the metaphase which is a meiotic stage crossing occurs.

Meiosis seems to be a process of cell division that typically results in the production of four gamete cells and just a 50% reduction in the number of chromosomes there in the parent cell. To develop the cells that makeup eggs and sperm during sexual reproduction, this procedure must be performed.

When every one of the chromosomes is lined up in the center of the cell during metaphase, attempting to cross over takes place. They can cross across because they are so close together. They can cross across because they are so close together. Crossing crossover occurs in anaphase on every pole of the animal cell where other chromosomes are crowded tightly.

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Answer:

Distance is the answer

Explanation:

According to the formula of work

Work: Force × Distance

Hence distance must be applied to perform work

Answer:

force

Explanation:

force is the application to apply potential energy to perform the work

This population is not in Hardy-Weinberg equilibrium, and there is some evolutionary force at work (such as mutation, selection, or genetic drift) causing the observed deviation from expected genotype frequencies.

To determine whether or not the population is in Hardy-Weinberg equilibrium, we can use the Hardy-Weinberg equation:

p²2 + 2pq + q² = 1

where p is the frequency of the dominant allele (in this case, the allele for bald peaches), q is the frequency of the recessive allele (the allele for fuzzy peaches), p² is the frequency of homozygous dominant individuals (bald-bald), 2pq is the frequency of heterozygous individuals (bald-fuzzy), and q² is the frequency of homozygous recessive individuals (fuzzy-fuzzy).

In this case, we are given that q (the frequency of the fuzzy allele) is 0.7. We can calculate p as:

p = 1 - q

p = 1 - 0.7

p = 0.3

We can then use the equation to calculate the expected frequencies of each genotype:

p² = (0.3)² = 0.09

2pq = 2(0.3)(0.7) = 0.42

q² = (0.7)² = 0.49

We can convert these expected frequencies to expected counts by multiplying by the total number of individuals:

Expected count of bald-bald (p²): 0.09 x 500 = 45

Expected count of bald-fuzzy (2pq): 0.42 x 500 = 210

Expected count of fuzzy-fuzzy (q²): 0.49 x 500 = 245

We can then compare these expected counts to the observed counts (250 fuzzy peaches and 250 bald peaches) to see if they are significantly different. We can use a chi-square goodness-of-fit test to make this comparison:

chi-square = ∑((observed - expected)² / expected)

chi-square = ((250 - 245)² / 245) + ((250 - 210)² / 210) + ((0 - 45)² / 45)

chi-square = 1.96 + 24.4 + 45

chi-square = 71.36

To determine if this chi-square value is significant, we need to compare it to the critical value from a chi-square distribution with 2 degrees of freedom (3 genotypes - 1). The critical value is 5.99 when the significance level is set to 0.05. We can rule out the null hypothesis that the population is in Hardy-Weinberg equilibrium since our computed chi-square value (71.36) is higher than the crucial value (5.99).

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Answer:

Abstract

Given the rapid development of plant genomic technologies, a lack of access to plant phenotyping capabilities limits our ability to dissect the genetics of quantitative traits. Effective, high-throughput phenotyping platforms have recently been developed to solve this problem. In high-throughput phenotyping platforms, a variety of imaging methodologies are being used to collect data for quantitative studies of complex traits related to the growth, yield and adaptation to biotic or abiotic stress (disease, insects, drought and salinity). These imaging techniques include visible imaging (machine vision), imaging spectroscopy (multispectral and hyperspectral remote sensing), thermal infrared imaging, fluorescence imaging, 3D imaging and tomographic imaging (MRT, PET and CT). This paper presents a brief review on these imaging techniques and their applications in plant phenotyping. The features used to apply these imaging techniques to plant phenotyping are described and discussed in this review.

Keywords: phenotyping phenotype, fluorescence imaging, thermal infrared imaging, visible light imaging, imaging spectroscopy, three dimensional imaging

1. Introduction

To ensure that crop production is sufficient to satisfy the needs of a human population that is expected to grow to more than 9 billion by 2050 is a tremendous challenge for plant science and crop improvement [1]. This goal is challenging primarily because the average rate of crop production increase is only 1.3% per year, and it cannot keep pace with population growth. By connecting the genotype to the phenotype, high yielding, stress-tolerant plants can be selected far more rapidly and efficiently than is currently possible. Advances in techniques such as next generation DNA sequencing can be made available to breeders to provide potential increases in the rate of genetic improvement by molecular breeding [2]. However, the lack of access to phenotyping capabilities limits our ability to dissect the genetics of quantitative traits related to growth, yield and adaptation to stress. Plant breeders and farmers were making selections based on phenotypes long before the discovery of DNA and molecular markers. To identify the best genetic variation, the more crosses and environments that are used for selection, the greater the probability of identifying a superior variation. To meet future requirements, there is a need to increase breeding efficiency. Advances in high throughput genotyping have offered fast and inexpensive genomic information and paved the way for the development of large mapping populations and diversity panels of thousands of recombinant inbred lines for phenotyping [3]. Although molecular breeding strategies have placed greater focus on selections based on genotypic information, they still require the following phenotypic data [4]: (1) phenotypes are used for selection and to train a prediction model in genomic selection; (2) a single phenotyping cycle is used to identify markers for subsequent selection through generations within the maker-assisted recurrent selection [5]; and (3) phenotyping is necessary to identify promising events in transgenic studies [6]. Phenotyping advances are essential for capitalizing on developments in conventional, molecular, and transgenic breeding.

Explanation: